fix: improve gitignore and Jupyter notebook support

- Add nbconvert dependency for .ipynb file support - Replace manual gitignore parsing with gitignore-parser library - Proper recursive .gitignore handling (all subdirectories) - Fix compliance with Git gitignore behavior - Simplify code and improve reliability 🤖 Generated with [Claude Code](https://claude.ai/code) Co-Authored-By: Claude <noreply@anthropic.com>
[Readme]update embedding model config according to reddit feedback
2025-08-10 18:52:55 -07:00 · 2025-08-09 21:33:33 -07:00 · 2025-08-10 03:39:45 +00:00 · 2025-08-09 20:37:17 -07:00 · 2025-08-08 18:44:07 -07:00 · 2025-08-08 16:05:35 -07:00
200 changed files with 11258 additions and 19102 deletions
--- a/.github/workflows/build-and-publish.yml
+++ b/.github/workflows/build-and-publish.yml
@@ -0,0 +1,11 @@
 name: CI
 on:
  push:
    branches: [ main ]
  pull_request:
    branches: [ main ]
 jobs:
  build:
    uses: ./.github/workflows/build-reusable.yml
--- a/.github/workflows/build-reusable.yml
+++ b/.github/workflows/build-reusable.yml
@@ -0,0 +1,251 @@
 name: Reusable Build
 on:
  workflow_call:
    inputs:
      ref:
        description: 'Git ref to build'
        required: false
        type: string
        default: ''
 jobs:
  lint:
    name: Lint and Format Check
    runs-on: ubuntu-latest
    steps:
      - uses: actions/checkout@v4
        with:
          ref: ${{ inputs.ref }}
      - name: Setup Python
        uses: actions/setup-python@v5
        with:
          python-version: '3.11'
      - name: Install uv
        uses: astral-sh/setup-uv@v4
      - name: Install ruff
        run: |
          uv tool install ruff
      - name: Run ruff check
        run: |
          ruff check .
      - name: Run ruff format check
        run: |
          ruff format --check .
  build:
    needs: lint
    name: Build ${{ matrix.os }} Python ${{ matrix.python }}
    strategy:
      matrix:
        include:
          - os: ubuntu-22.04
            python: '3.9'
          - os: ubuntu-22.04
            python: '3.10'
          - os: ubuntu-22.04
            python: '3.11'
          - os: ubuntu-22.04
            python: '3.12'
          - os: ubuntu-22.04
            python: '3.13'
          - os: macos-latest
            python: '3.9'
          - os: macos-latest
            python: '3.10'
          - os: macos-latest
            python: '3.11'
          - os: macos-latest
            python: '3.12'
          - os: macos-latest
            python: '3.13'
    runs-on: ${{ matrix.os }}
    steps:
      - uses: actions/checkout@v4
        with:
          ref: ${{ inputs.ref }}
          submodules: recursive
      - name: Setup Python
        uses: actions/setup-python@v5
        with:
          python-version: ${{ matrix.python }}
      - name: Install uv
        uses: astral-sh/setup-uv@v4
      - name: Install system dependencies (Ubuntu)
        if: runner.os == 'Linux'
        run: |
          sudo apt-get update
          sudo apt-get install -y libomp-dev libboost-all-dev protobuf-compiler libzmq3-dev \
            pkg-config libopenblas-dev patchelf libabsl-dev libaio-dev libprotobuf-dev
          # Install Intel MKL for DiskANN
          wget -q https://registrationcenter-download.intel.com/akdlm/IRC_NAS/79153e0f-74d7-45af-b8c2-258941adf58a/intel-onemkl-2025.0.0.940.sh
          sudo sh intel-onemkl-2025.0.0.940.sh -a --components intel.oneapi.lin.mkl.devel --action install --eula accept -s
          source /opt/intel/oneapi/setvars.sh
          echo "MKLROOT=/opt/intel/oneapi/mkl/latest" >> $GITHUB_ENV
          echo "LD_LIBRARY_PATH=/opt/intel/oneapi/mkl/latest/lib/intel64:$LD_LIBRARY_PATH" >> $GITHUB_ENV
      - name: Install system dependencies (macOS)
        if: runner.os == 'macOS'
        run: |
          # Don't install LLVM, use system clang for better compatibility
          brew install libomp boost protobuf zeromq
      - name: Install build dependencies
        run: |
          uv pip install --system scikit-build-core numpy swig Cython pybind11
          if [[ "$RUNNER_OS" == "Linux" ]]; then
            uv pip install --system auditwheel
          else
            uv pip install --system delocate
          fi
      - name: Build packages
        run: |
          # Build core (platform independent)
          if [[ "${{ matrix.os }}" == ubuntu-* ]]; then
            cd packages/leann-core
            uv build
            cd ../..
          fi
          # Build HNSW backend
          cd packages/leann-backend-hnsw
          if [ "${{ matrix.os }}" == "macos-latest" ]; then
            # Use system clang instead of homebrew LLVM for better compatibility
            export CC=clang
            export CXX=clang++
            export MACOSX_DEPLOYMENT_TARGET=11.0
            uv build --wheel --python python
          else
            uv build --wheel --python python
          fi
          cd ../..
          # Build DiskANN backend
          cd packages/leann-backend-diskann
          if [ "${{ matrix.os }}" == "macos-latest" ]; then
            # Use system clang instead of homebrew LLVM for better compatibility
            export CC=clang
            export CXX=clang++
            # DiskANN requires macOS 13.3+ for sgesdd_ LAPACK function
            export MACOSX_DEPLOYMENT_TARGET=13.3
            uv build --wheel --python python
          else
            uv build --wheel --python python
          fi
          cd ../..
          # Build meta package (platform independent)
          if [[ "${{ matrix.os }}" == ubuntu-* ]]; then
            cd packages/leann
            uv build
            cd ../..
          fi
      - name: Repair wheels (Linux)
        if: runner.os == 'Linux'
        run: |
          # Repair HNSW wheel
          cd packages/leann-backend-hnsw
          if [ -d dist ]; then
            auditwheel repair dist/*.whl -w dist_repaired
            rm -rf dist
            mv dist_repaired dist
          fi
          cd ../..
          # Repair DiskANN wheel
          cd packages/leann-backend-diskann
          if [ -d dist ]; then
            auditwheel repair dist/*.whl -w dist_repaired
            rm -rf dist
            mv dist_repaired dist
          fi
          cd ../..
      - name: Repair wheels (macOS)
        if: runner.os == 'macOS'
        run: |
          # Repair HNSW wheel
          cd packages/leann-backend-hnsw
          if [ -d dist ]; then
            delocate-wheel -w dist_repaired -v dist/*.whl
            rm -rf dist
            mv dist_repaired dist
          fi
          cd ../..
          # Repair DiskANN wheel
          cd packages/leann-backend-diskann
          if [ -d dist ]; then
            delocate-wheel -w dist_repaired -v dist/*.whl
            rm -rf dist
            mv dist_repaired dist
          fi
          cd ../..
      - name: List built packages
        run: |
          echo "📦 Built packages:"
          find packages/*/dist -name "*.whl" -o -name "*.tar.gz" | sort
      - name: Install built packages for testing
        run: |
          # Create a virtual environment
          uv venv
          source .venv/bin/activate || source .venv/Scripts/activate
          # Install the built wheels
          # Use --find-links to let uv choose the correct wheel for the platform
          if [[ "${{ matrix.os }}" == ubuntu-* ]]; then
            uv pip install leann-core --find-links packages/leann-core/dist
            uv pip install leann --find-links packages/leann/dist
          fi
          uv pip install leann-backend-hnsw --find-links packages/leann-backend-hnsw/dist
          uv pip install leann-backend-diskann --find-links packages/leann-backend-diskann/dist
          # Install test dependencies using extras
          uv pip install -e ".[test]"
      - name: Run tests with pytest
        env:
          CI: true  # Mark as CI environment to skip memory-intensive tests
          OPENAI_API_KEY: ${{ secrets.OPENAI_API_KEY }}
          HF_HUB_DISABLE_SYMLINKS: 1
          TOKENIZERS_PARALLELISM: false
          PYTORCH_ENABLE_MPS_FALLBACK: 0  # Disable MPS on macOS CI to avoid memory issues
          OMP_NUM_THREADS: 1  # Disable OpenMP parallelism to avoid libomp crashes
          MKL_NUM_THREADS: 1  # Single thread for MKL operations
        run: |
          # Activate virtual environment
          source .venv/bin/activate || source .venv/Scripts/activate
          # Run all tests
          pytest tests/
      - name: Run sanity checks (optional)
        run: |
          # Activate virtual environment
          source .venv/bin/activate || source .venv/Scripts/activate
          # Run distance function tests if available
          if [ -f test/sanity_checks/test_distance_functions.py ]; then
            echo "Running distance function sanity checks..."
            python test/sanity_checks/test_distance_functions.py || echo "⚠️ Distance function test failed, continuing..."
          fi
      - name: Upload artifacts
        uses: actions/upload-artifact@v4
        with:
          name: packages-${{ matrix.os }}-py${{ matrix.python }}
          path: packages/*/dist/
--- a/.github/workflows/link-check.yml
+++ b/.github/workflows/link-check.yml
@@ -0,0 +1,19 @@
 name: Link Check
 on:
  push:
    branches: [ main, master ]
  pull_request:
  schedule:
    - cron: "0 3 * * 1"
 jobs:
  link-check:
    runs-on: ubuntu-latest
    steps:
      - uses: actions/checkout@v4
      - uses: lycheeverse/lychee-action@v2
        with:
          args: --no-progress --insecure README.md docs/ apps/ examples/ benchmarks/
        env:
          GITHUB_TOKEN: ${{ secrets.GITHUB_TOKEN }}
--- a/.github/workflows/release-manual.yml
+++ b/.github/workflows/release-manual.yml
@@ -0,0 +1,129 @@
 name: Release
 on:
  workflow_dispatch:
    inputs:
      version:
        description: 'Version to release (e.g., 0.1.2)'
        required: true
        type: string
 jobs:
  update-version:
    name: Update Version
    runs-on: ubuntu-latest
    permissions:
      contents: write
    outputs:
      commit-sha: ${{ steps.push.outputs.commit-sha }}
    steps:
      - uses: actions/checkout@v4
      - name: Validate version
        run: |
          # Remove 'v' prefix if present for validation
          VERSION_CLEAN="${{ inputs.version }}"
          VERSION_CLEAN="${VERSION_CLEAN#v}"
          if ! [[ "$VERSION_CLEAN" =~ ^[0-9]+\.[0-9]+\.[0-9]+$ ]]; then
            echo "❌ Invalid version format. Expected format: X.Y.Z or vX.Y.Z"
            exit 1
          fi
          echo "✅ Version format valid: ${{ inputs.version }}"
      - name: Update versions and push
        id: push
        run: |
          # Check current version
          CURRENT_VERSION=$(grep "^version" packages/leann-core/pyproject.toml | cut -d'"' -f2)
          echo "Current version: $CURRENT_VERSION"
          echo "Target version: ${{ inputs.version }}"
          if [ "$CURRENT_VERSION" = "${{ inputs.version }}" ]; then
            echo "⚠️  Version is already ${{ inputs.version }}, skipping update"
            COMMIT_SHA=$(git rev-parse HEAD)
          else
            ./scripts/bump_version.sh ${{ inputs.version }}
            git config user.name "GitHub Actions"
            git config user.email "actions@github.com"
            git add packages/*/pyproject.toml
            git commit -m "chore: release v${{ inputs.version }}"
            git push origin main
            COMMIT_SHA=$(git rev-parse HEAD)
            echo "✅ Pushed version update: $COMMIT_SHA"
          fi
          echo "commit-sha=$COMMIT_SHA" >> $GITHUB_OUTPUT
  build-packages:
    name: Build packages
    needs: update-version
    uses: ./.github/workflows/build-reusable.yml
    with:
      ref: 'main'
  publish:
    name: Publish and Release
    needs: [update-version, build-packages]
    if: always() && needs.update-version.result == 'success' && needs.build-packages.result == 'success'
    runs-on: ubuntu-latest
    permissions:
      contents: write
    steps:
      - uses: actions/checkout@v4
        with:
          ref: 'main'
      - name: Download all artifacts
        uses: actions/download-artifact@v4
        with:
          path: dist-artifacts
      - name: Collect packages
        run: |
          mkdir -p dist
          find dist-artifacts -name "*.whl" -exec cp {} dist/ \;
          find dist-artifacts -name "*.tar.gz" -exec cp {} dist/ \;
          echo "📦 Packages to publish:"
          ls -la dist/
      - name: Publish to PyPI
        env:
          TWINE_USERNAME: __token__
          TWINE_PASSWORD: ${{ secrets.PYPI_API_TOKEN }}
        run: |
          if [ -z "$TWINE_PASSWORD" ]; then
            echo "❌ PYPI_API_TOKEN not configured!"
            exit 1
          fi
          pip install twine
          twine upload dist/* --skip-existing --verbose
          echo "✅ Published to PyPI!"
      - name: Create release
        run: |
          # Check if tag already exists
          if git rev-parse "v${{ inputs.version }}" >/dev/null 2>&1; then
            echo "⚠️  Tag v${{ inputs.version }} already exists, skipping tag creation"
          else
            git tag "v${{ inputs.version }}"
            git push origin "v${{ inputs.version }}"
            echo "✅ Created and pushed tag v${{ inputs.version }}"
          fi
          # Check if release already exists
          if gh release view "v${{ inputs.version }}" >/dev/null 2>&1; then
            echo "⚠️  Release v${{ inputs.version }} already exists, skipping release creation"
          else
            gh release create "v${{ inputs.version }}" \
              --title "Release v${{ inputs.version }}" \
              --notes "🚀 Released to PyPI: https://pypi.org/project/leann/${{ inputs.version }}/" \
              --latest
            echo "✅ Created GitHub release v${{ inputs.version }}"
          fi
        env:
          GH_TOKEN: ${{ secrets.GITHUB_TOKEN }}
--- a/.gitignore
+++ b/.gitignore
@@ -12,7 +12,6 @@ outputs/
 *.idx
 *.map
 .history/
 scripts/
 lm_eval.egg-info/
 demo/experiment_results/**/*.json
 *.jsonl
@@ -35,11 +34,15 @@ build/
 nprobe_logs/
 micro/results
 micro/contriever-INT8
-examples/data/*
+data/*
-!examples/data/2501.14312v1 (1).pdf
+!data/2501.14312v1 (1).pdf
-!examples/data/2506.08276v1.pdf
+!data/2506.08276v1.pdf
-!examples/data/PrideandPrejudice.txt
+!data/PrideandPrejudice.txt
-!examples/data/README.md
+!data/huawei_pangu.md
 !data/ground_truth/
 !data/indices/
 !data/queries/
 !data/.gitattributes
 *.qdstrm
 benchmark_results/
 results/
@@ -85,3 +88,7 @@ packages/leann-backend-diskann/third_party/DiskANN/_deps/
 *.meta.json
 *.passages.json
 batchtest.py
 tests/__pytest_cache__/
 tests/__pycache__/
--- a/.pre-commit-config.yaml
+++ b/.pre-commit-config.yaml
@@ -0,0 +1,16 @@
 repos:
  - repo: https://github.com/pre-commit/pre-commit-hooks
    rev: v4.5.0
    hooks:
      - id: trailing-whitespace
      - id: end-of-file-fixer
      - id: check-yaml
      - id: check-added-large-files
      - id: check-merge-conflict
      - id: debug-statements
  - repo: https://github.com/astral-sh/ruff-pre-commit
    rev: v0.2.1
    hooks:
      - id: ruff
      - id: ruff-format
--- a/.vscode/extensions.json
+++ b/.vscode/extensions.json
@@ -1,9 +0,0 @@
 {
    "recommendations": [
        "llvm-vs-code-extensions.vscode-clangd",
        "ms-python.python",
        "ms-vscode.cmake-tools",
        "vadimcn.vscode-lldb",
        "eamodio.gitlens",
    ]
 }
--- a/.vscode/launch.json
+++ b/.vscode/launch.json
@@ -1,283 +0,0 @@
 {
    // Use IntelliSense to learn about possible attributes.
    // Hover to view descriptions of existing attributes.
    // For more information, visit: https://go.microsoft.com/fwlink/?linkid=830387
    "version": "0.2.0",
    "configurations": [
        // new emdedder
        {
            "name": "New Embedder",
            "type": "debugpy",
            "request": "launch",
            "program": "demo/main.py",
            "console": "integratedTerminal",
            "args": [
                "--search",
                "--use-original",
                "--domain",
                "dpr",
                "--nprobe",
                "5000",
                "--load",
                "flat",
                "--embedder",
                "intfloat/multilingual-e5-small"
            ]
        }
        //python /home/ubuntu/Power-RAG/faiss/demo/simple_build.py
        {
            "name": "main.py",
            "type": "debugpy",
            "request": "launch",
            "program": "demo/main.py",
            "console": "integratedTerminal",
            "cwd": "${workspaceFolder}",
            "args": [
                "--query",
                "1000",
                "--load",
                "bm25"
            ]
        },
        {
            "name": "Simple Build",
            "type": "lldb",
            "request": "launch",
            "program": "${workspaceFolder}/.venv/bin/python",
            "console": "integratedTerminal",
            "cwd": "${workspaceFolder}",
            "args": [
                "faiss/demo/simple_build.py"
            ],
            "env": {
                "LD_PRELOAD": "/lib/x86_64-linux-gnu/libmkl_core.so:/lib/x86_64-linux-gnu/libmkl_intel_thread.so:/lib/x86_64-linux-gnu/libmkl_intel_lp64.so:/lib/x86_64-linux-gnu/libiomp5.so"
            }
        },
        //# Fix for Intel MKL error
        //export LD_PRELOAD=/lib/x86_64-linux-gnu/libmkl_core.so:/lib/x86_64-linux-gnu/libmkl_intel_thread.so:/lib/x86_64-linux-gnu/libmkl_intel_lp64.so:/lib/x86_64-linux-gnu/libiomp5.so
        //python faiss/demo/build_demo.py
        {
            "name": "Build Demo",
            "type": "lldb",
            "request": "launch",
            "program": "${workspaceFolder}/.venv/bin/python",
            "console": "integratedTerminal",
            "cwd": "${workspaceFolder}",
            "args": [
                "faiss/demo/build_demo.py"
            ],
            "env": {
                "LD_PRELOAD": "/lib/x86_64-linux-gnu/libmkl_core.so:/lib/x86_64-linux-gnu/libmkl_intel_thread.so:/lib/x86_64-linux-gnu/libmkl_intel_lp64.so:/lib/x86_64-linux-gnu/libiomp5.so"
            }
        },
        {
            "name": "DiskANN Serve",
            "type": "lldb",
            "request": "launch",
            "program": "${workspaceFolder}/.venv/bin/python",
            "console": "integratedTerminal",
            "cwd": "${workspaceFolder}",
            "args": [
                "demo/main.py",
                "--mode",
                "serve",
                "--engine",
                "sglang",
                "--load-indices",
                "diskann",
                "--domain",
                "rpj_wiki",
                "--lazy-load",
                "--recompute-beighbor-embeddings",
                "--port",
                "8082",
                "--diskann-search-memory-maximum",
                "2",
                "--diskann-graph",
                "240",
                "--search-only"
            ],
            "env": {
                "PYTHONPATH": "${workspaceFolder}/faiss_repo/build/faiss/python:$PYTHONPATH"
            },
            "preLaunchTask": "CMake: build",
        },
        {
            "name": "DiskANN Serve MAC",
            "type": "lldb",
            "request": "launch",
            "program": "${workspaceFolder}/.venv/bin/python",
            "console": "integratedTerminal",
            "cwd": "${workspaceFolder}",
            "args": [
                "demo/main.py",
                "--mode",
                "serve",
                "--engine",
                "ollama",
                "--load-indices",
                "diskann",
                "--domain",
                "rpj_wiki",
                "--lazy-load",
                "--recompute-beighbor-embeddings"
            ],
            "preLaunchTask": "CMake: build",
            "env": {
                "KMP_DUPLICATE_LIB_OK": "TRUE",
                "OMP_NUM_THREADS": "1",
                "MKL_NUM_THREADS": "1",
                "DYLD_INSERT_LIBRARIES": "/Users/ec2-user/Power-RAG/.venv/lib/python3.10/site-packages/torch/lib/libomp.dylib",
                "KMP_BLOCKTIME": "0"
            }
        },
        {
            "name": "Python Debugger: Current File with Arguments",
            "type": "debugpy",
            "request": "launch",
            "program": "ric/main_ric.py",
            "console": "integratedTerminal",
            "cwd": "${workspaceFolder}",
            "args": [
                "--config-name",
                "${input:configSelection}"
            ],
            "justMyCode": false
        },
        //python ./demo/validate_equivalence.py sglang
        {
            "name": "Validate Equivalence",
            "type": "debugpy",
            "request": "launch",
            "program": "demo/validate_equivalence.py",
            "console": "integratedTerminal",
            "args": [
                "sglang"
            ],
        },
        //python demo/retrieval_demo.py --engine sglang  --skip-embeddings --domain dpr --load-indices flat ivf_flat
        {
            "name": "Retrieval Demo",
            "type": "debugpy",
            "request": "launch",
            "program": "demo/retrieval_demo.py",
            "console": "integratedTerminal",
            "args": [
                "--engine",
                "vllm",
                "--skip-embeddings",
                "--domain",
                "dpr",
                "--load-indices",
                // "flat",
                "ivf_flat"
            ],
        },
        //python demo/retrieval_demo.py --engine sglang  --skip-embeddings --domain dpr  --load-indices  diskann --hnsw-M 64 --hnsw-efConstruction 150 --hnsw-efSearch 128  --hnsw-sq-bits 8 
        {
            "name": "Retrieval Demo DiskANN",
            "type": "debugpy",
            "request": "launch",
            "program": "demo/retrieval_demo.py",
            "console": "integratedTerminal",
            "args": [
                "--engine",
                "sglang",
                "--skip-embeddings",
                "--domain",
                "dpr",
                "--load-indices",
                "diskann",
                "--hnsw-M",
                "64",
                "--hnsw-efConstruction",
                "150",
                "--hnsw-efSearch",
                "128",
                "--hnsw-sq-bits",
                "8"
            ],
        },
        {
            "name": "Find Probe",
            "type": "debugpy",
            "request": "launch",
            "program": "find_probe.py",
            "console": "integratedTerminal",
            "cwd": "${workspaceFolder}",
        },
        {
            "name": "Python: Attach",
            "type": "debugpy",
            "request": "attach",
            "processId": "${command:pickProcess}",
            "justMyCode": true
        },
        {
            "name": "Edge RAG",
            "type": "lldb",
            "request": "launch",
            "program": "${workspaceFolder}/.venv/bin/python",
            "console": "integratedTerminal",
            "cwd": "${workspaceFolder}",
            "args": [
                "edgerag_demo.py"
            ],
            "env": {
                "LD_PRELOAD": "/lib/x86_64-linux-gnu/libiomp5.so /lib/x86_64-linux-gnu/libmkl_core.so /lib/x86_64-linux-gnu/libmkl_intel_lp64.so /lib/x86_64-linux-gnu/libmkl_intel_thread.so",
                "MKL_NUM_THREADS": "1",
                "OMP_NUM_THREADS": "1",
            }
        },
        {
            "name": "Launch Embedding Server",
            "type": "debugpy",
            "request": "launch",
            "program": "demo/embedding_server.py",
            "console": "integratedTerminal",
            "cwd": "${workspaceFolder}",
            "args": [
                "--domain",
                "rpj_wiki",
                "--zmq-port",
                "5556",
            ]
        },
        {
            "name": "HNSW Serve",
            "type": "lldb",
            "request": "launch",
            "program": "${workspaceFolder}/.venv/bin/python",
            "console": "integratedTerminal",
            "cwd": "${workspaceFolder}",
            "args": [
                "demo/main.py",
                "--domain",
                "rpj_wiki",
                "--load",
                "hnsw",
                "--mode",
                "serve",
                "--search",
                "--skip-pa",
                "--recompute",
                "--hnsw-old"
            ],
            "env": {
                "LD_PRELOAD": "/lib/x86_64-linux-gnu/libmkl_core.so:/lib/x86_64-linux-gnu/libmkl_intel_thread.so:/lib/x86_64-linux-gnu/libmkl_intel_lp64.so:/lib/x86_64-linux-gnu/libiomp5.so"
            }
        },
    ],
    "inputs": [
        {
            "id": "configSelection",
            "type": "pickString",
            "description": "Select a configuration",
            "options": [
                "example_config",
                "vllm_gritlm"
            ],
            "default": "example_config"
        }
    ],
 }
--- a/.vscode/settings.json
+++ b/.vscode/settings.json
@@ -1,43 +0,0 @@
 {
    "python.analysis.extraPaths": [
        "./sglang_repo/python"
    ],
    "cmake.sourceDirectory": "${workspaceFolder}/DiskANN",
    "cmake.configureArgs": [
        "-DPYBIND=True",
        "-DUPDATE_EDITABLE_INSTALL=ON",
    ],
    "cmake.environment": {
        "PATH": "/Users/ec2-user/Power-RAG/.venv/bin:${env:PATH}"
    },
    "cmake.buildDirectory": "${workspaceFolder}/build",
    "files.associations": {
        "*.tcc": "cpp",
        "deque": "cpp",
        "string": "cpp",
        "unordered_map": "cpp",
        "vector": "cpp",
        "map": "cpp",
        "unordered_set": "cpp",
        "atomic": "cpp",
        "inplace_vector": "cpp",
        "*.ipp": "cpp",
        "forward_list": "cpp",
        "list": "cpp",
        "any": "cpp",
        "system_error": "cpp",
        "__hash_table": "cpp",
        "__split_buffer": "cpp",
        "__tree": "cpp",
        "ios": "cpp",
        "set": "cpp",
        "__string": "cpp",
        "string_view": "cpp",
        "ranges": "cpp",
        "iosfwd": "cpp"
    },
    "lldb.displayFormat": "auto",
    "lldb.showDisassembly": "auto",
    "lldb.dereferencePointers": true,
    "lldb.consoleMode": "commands",
 }
--- a/.vscode/tasks.json
+++ b/.vscode/tasks.json
@@ -1,16 +0,0 @@
 {
 	"version": "2.0.0",
 	"tasks": [
 		{
 			"type": "cmake",
 			"label": "CMake: build",
 			"command": "build",
 			"targets": [
 				"all"
 			],
 			"group": "build",
 			"problemMatcher": [],
 			"detail": "CMake template build task"
 		}
 	]
 }
--- a/README.md
+++ b/README.md
@@ -6,17 +6,21 @@
  <img src="https://img.shields.io/badge/Python-3.9%2B-blue.svg" alt="Python 3.9+">
  <img src="https://img.shields.io/badge/License-MIT-green.svg" alt="MIT License">
  <img src="https://img.shields.io/badge/Platform-Linux%20%7C%20macOS-lightgrey" alt="Platform">
  <img src="https://img.shields.io/badge/MCP-Native%20Integration-blue?style=flat-square" alt="MCP Integration">
 </p>
 <h2 align="center" tabindex="-1" class="heading-element" dir="auto">
    The smallest vector index in the world. RAG Everything with LEANN!
 </h2>
-LEANN is a revolutionary vector database that democratizes personal AI. Transform your laptop into a powerful RAG system that can index and search through millions of documents while using **[97% less storage]** than traditional solutions **without accuracy loss**.
+LEANN is an innovative vector database that democratizes personal AI. Transform your laptop into a powerful RAG system that can index and search through millions of documents while using **97% less storage** than traditional solutions **without accuracy loss**.
-LEANN achieves this through *graph-based selective recomputation* with *high-degree preserving pruning*, computing embeddings on-demand instead of storing them all. [Illustration →](#️-architecture--how-it-works) | [Paper →](https://arxiv.org/abs/2506.08276)
+LEANN achieves this through *graph-based selective recomputation* with *high-degree preserving pruning*, computing embeddings on-demand instead of storing them all. [Illustration Fig →](#️-architecture--how-it-works) | [Paper →](https://arxiv.org/abs/2506.08276)
-**Ready to RAG Everything?** Transform your laptop into a personal AI assistant that can search your **[file system](#process-any-documents-pdf-txt-md)**, **[emails](#search-your-entire-life)**, **[browser history](#time-machine-for-the-web)**, **[chat history](#wechat-detective)**, or external knowledge bases (i.e., 60M documents) - all on your laptop, with zero cloud costs and complete privacy.
+**Ready to RAG Everything?** Transform your laptop into a personal AI assistant that can semantic search your **[file system](#-personal-data-manager-process-any-documents-pdf-txt-md)**, **[emails](#-your-personal-email-secretary-rag-on-apple-mail)**, **[browser history](#-time-machine-for-the-web-rag-your-entire-browser-history)**, **[chat history](#-wechat-detective-unlock-your-golden-memories)**, **[codebase](#-claude-code-integration-transform-your-development-workflow)**\* , or external knowledge bases (i.e., 60M documents) - all on your laptop, with zero cloud costs and complete privacy.
 \* Claude Code only supports basic `grep`-style keyword search. **LEANN** is a drop-in **semantic search MCP service fully compatible with Claude Code**, unlocking intelligent retrieval without changing your workflow. 🔥 Check out [the easy setup →](packages/leann-mcp/README.md)
@@ -26,55 +30,123 @@ LEANN achieves this through *graph-based selective recomputation* with *high-deg
  <img src="assets/effects.png" alt="LEANN vs Traditional Vector DB Storage Comparison" width="70%">
 </p>
-**The numbers speak for themselves:** Index 60 million Wikipedia articles in just 6GB instead of 201GB. From emails to browser history, everything fits on your laptop. [See detailed benchmarks below ↓](#storage-usage-comparison)
+> **The numbers speak for themselves:** Index 60 million text chunks in just 6GB instead of 201GB. From emails to browser history, everything fits on your laptop. [See detailed benchmarks for different applications below ↓](#storage-comparison)
 ## Why This Matters
 🔒 **Privacy:** Your data never leaves your laptop. No OpenAI, no cloud, no "terms of service".
 🪶 **Lightweight:** Graph-based recomputation eliminates heavy embedding storage, while smart graph pruning and CSR format minimize graph storage overhead. Always less storage, less memory usage!
 📦 **Portable:** Transfer your entire knowledge base between devices (even with others) with minimal cost - your personal AI memory travels with you.
 📈 **Scalability:** Handle messy personal data that would crash traditional vector DBs, easily managing your growing personalized data and agent generated memory!
 ✨ **No Accuracy Loss:** Maintain the same search quality as heavyweight solutions while using 97% less storage.
-## Quick Start in 1 minute
+## Installation
 ### 📦 Prerequisites: Install uv
 [Install uv](https://docs.astral.sh/uv/getting-started/installation/#installation-methods) first if you don't have it. Typically, you can install it with:
 ```bash
-git clone git@github.com:yichuan-w/LEANN.git leann
+curl -LsSf https://astral.sh/uv/install.sh | sh
 ```
 ### 🚀 Quick Install
 Clone the repository to access all examples and try amazing applications,
 ```bash
 git clone https://github.com/yichuan-w/LEANN.git leann
 cd leann
 ```
 and install LEANN from [PyPI](https://pypi.org/project/leann/) to run them immediately:
 ```bash
 uv venv
 source .venv/bin/activate
 uv pip install leann
 ```
 <details>
 <summary>
 <strong>🔧 Build from Source (Recommended for development)</strong>
 </summary>
 ```bash
 git clone https://github.com/yichuan-w/LEANN.git leann
 cd leann
 git submodule update --init --recursive
 ```
 **macOS:**
 ```bash
-brew install llvm libomp boost protobuf
+brew install llvm libomp boost protobuf zeromq pkgconf
-export CC=$(brew --prefix llvm)/bin/clang
+CC=$(brew --prefix llvm)/bin/clang CXX=$(brew --prefix llvm)/bin/clang++ uv sync
 export CXX=$(brew --prefix llvm)/bin/clang++
 # Install with HNSW backend (default, recommended for most users)
 uv sync
 # Or add DiskANN backend if you want to test more options
 uv sync --extra diskann
 ```
-**Linux (Ubuntu/Debian):**
+**Linux:**
 ```bash
-sudo apt-get install libomp-dev libboost-all-dev protobuf-compiler libabsl-dev libmkl-full-dev libaio-dev
+sudo apt-get install libomp-dev libboost-all-dev protobuf-compiler libabsl-dev libmkl-full-dev libaio-dev libzmq3-dev
 # Install with HNSW backend (default, recommended for most users)
 uv sync
 # Or add DiskANN backend if you want to test more options
 uv sync --extra diskann
 ```
-**Ollama Setup (Optional for Local LLM):**
+</details>
 *We support both hf-transformers and Ollama for local LLMs. Ollama is recommended for faster performance.*
-*macOS:*
+## Quick Start
 Our declarative API makes RAG as easy as writing a config file.
 Check out [demo.ipynb](demo.ipynb) or [![Open In Colab](https://colab.research.google.com/assets/colab-badge.svg)](https://colab.research.google.com/github/yichuan-w/LEANN/blob/main/demo.ipynb)
 ```python
 from leann import LeannBuilder, LeannSearcher, LeannChat
 from pathlib import Path
 INDEX_PATH = str(Path("./").resolve() / "demo.leann")
 # Build an index
 builder = LeannBuilder(backend_name="hnsw")
 builder.add_text("LEANN saves 97% storage compared to traditional vector databases.")
 builder.add_text("Tung Tung Tung Sahur called—they need their banana‑crocodile hybrid back")
 builder.build_index(INDEX_PATH)
 # Search
 searcher = LeannSearcher(INDEX_PATH)
 results = searcher.search("fantastical AI-generated creatures", top_k=1)
 # Chat with your data
 chat = LeannChat(INDEX_PATH, llm_config={"type": "hf", "model": "Qwen/Qwen3-0.6B"})
 response = chat.ask("How much storage does LEANN save?", top_k=1)
 ```
 ## RAG on Everything!
 LEANN supports RAG on various data sources including documents (`.pdf`, `.txt`, `.md`), Apple Mail, Google Search History, WeChat, and more.
 ### Generation Model Setup
 LEANN supports multiple LLM providers for text generation (OpenAI API, HuggingFace, Ollama).
 <details>
 <summary><strong>🔑 OpenAI API Setup (Default)</strong></summary>
 Set your OpenAI API key as an environment variable:
 ```bash
 export OPENAI_API_KEY="your-api-key-here"
 ```
 </details>
 <details>
 <summary><strong>🔧 Ollama Setup (Recommended for full privacy)</strong></summary>
 **macOS:**
 First, [download Ollama for macOS](https://ollama.com/download/mac).
@@ -83,7 +155,8 @@ First, [download Ollama for macOS](https://ollama.com/download/mac).
 ollama pull llama3.2:1b
 ```
-*Linux:*
+**Linux:**
 ```bash
 # Install Ollama
 curl -fsSL https://ollama.ai/install.sh | sh
@@ -95,81 +168,120 @@ ollama serve &
 ollama pull llama3.2:1b
 ```
-You can also replace `llama3.2:1b` to `deepseek-r1:1.5b` or `qwen3:4b` for better performance but higher memory usage.
+</details>
-## Dead Simple API
+### ⭐ Flexible Configuration
-Just 3 lines of code. Our declarative API makes RAG as easy as writing a config file:
+LEANN provides flexible parameters for embedding models, search strategies, and data processing to fit your specific needs.
-```python
+📚 **Need configuration best practices?** Check our [Configuration Guide](docs/configuration-guide.md) for detailed optimization tips, model selection advice, and solutions to common issues like slow embeddings or poor search quality.
 from leann.api import LeannBuilder, LeannSearcher
 # 1. Build index (no embeddings stored!)
 builder = LeannBuilder(backend_name="hnsw")
 builder.add_text("C# is a powerful programming language")
 builder.add_text("Python is a powerful programming language")
 builder.add_text("Machine learning transforms industries")  
 builder.add_text("Neural networks process complex data")
 builder.add_text("Leann is a great storage saving engine for RAG on your macbook")
 builder.build_index("knowledge.leann")
 # 2. Search with real-time embeddings
 searcher = LeannSearcher("knowledge.leann")
 results = searcher.search("C++ programming languages", top_k=2, recompute_beighbor_embeddings=True)
 print(results)
 ```
 **That's it.** No cloud setup, no API keys, no "fine-tuning". Just your data, your questions, your laptop.
 [Try the interactive demo →](demo.ipynb)
 ## Wild Things You Can Do
 LEANN supports RAGing a lot of data sources, like .pdf, .txt, .md, and also supports RAGing your WeChat, Google Search History, and more.
 ### Process Any Documents (.pdf, .txt, .md)
 Above we showed the Python API, while this CLI script demonstrates the same concepts while directly processing PDFs and documents.
 ```bash
 # Drop your PDFs, .txt, .md files into examples/data/
 uv run ./examples/main_cli_example.py
 # Or use python directly
 source .venv/bin/activate
 python ./examples/main_cli_example.py
 ```
 Uses Ollama `qwen3:8b` by default. For other models: `--llm openai --model gpt-4o` (requires `OPENAI_API_KEY` environment variable) or `--llm hf --model Qwen/Qwen3-4B`.
 **Works with any text format** - research papers, personal notes, presentations. Built with LlamaIndex for document parsing.
 ### Search Your Entire Life
 ```bash
 python examples/mail_reader_leann.py
 # "What did my boss say about the Christmas party last year?"
 # "Find all emails from my mom about birthday plans"
 ```
 **90K emails → 14MB.** Finally, search your email like you search Google.
 <details>
-<summary><strong>📋 Click to expand: Command Examples</strong></summary>
+<summary><strong>📋 Click to expand: Common Parameters (Available in All Examples)</strong></summary>
 All RAG examples share these common parameters. **Interactive mode** is available in all examples - simply run without `--query` to start a continuous Q&A session where you can ask multiple questions. Type 'quit' to exit.
 ```bash
-# Use default mail path (works for most macOS setups)
+# Core Parameters (General preprocessing for all examples)
-python examples/mail_reader_leann.py
+--index-dir DIR          # Directory to store the index (default: current directory)
 --query "YOUR QUESTION"  # Single query mode. Omit for interactive chat (type 'quit' to exit), and now you can play with your index interactively
 --max-items N           # Limit data preprocessing (default: -1, process all data)
 --force-rebuild         # Force rebuild index even if it exists
-# Run with custom index directory
+# Embedding Parameters
-python examples/mail_reader_leann.py --index-dir "./my_mail_index"
+--embedding-model MODEL  # e.g., facebook/contriever, text-embedding-3-small, nomic-embed-text, mlx-community/Qwen3-Embedding-0.6B-8bit or nomic-embed-text
 --embedding-mode MODE    # sentence-transformers, openai, mlx, or ollama
-# Process all emails (may take time but indexes everything)
+# LLM Parameters (Text generation models)
-python examples/mail_reader_leann.py --max-emails -1
+--llm TYPE              # LLM backend: openai, ollama, or hf (default: openai)
 --llm-model MODEL       # Model name (default: gpt-4o) e.g., gpt-4o-mini, llama3.2:1b, Qwen/Qwen2.5-1.5B-Instruct
 --thinking-budget LEVEL # Thinking budget for reasoning models: low/medium/high (supported by o3, o3-mini, GPT-Oss:20b, and other reasoning models)
-# Limit number of emails processed (useful for testing)
+# Search Parameters
-python examples/mail_reader_leann.py --max-emails 1000
+--top-k N               # Number of results to retrieve (default: 20)
 --search-complexity N   # Search complexity for graph traversal (default: 32)
-# Run a single query
+# Chunking Parameters
-python examples/mail_reader_leann.py --query "What did my boss say about deadlines?"
+--chunk-size N          # Size of text chunks (default varies by source: 256 for most, 192 for WeChat)
 --chunk-overlap N       # Overlap between chunks (default varies: 25-128 depending on source)
 # Index Building Parameters
 --backend-name NAME     # Backend to use: hnsw or diskann (default: hnsw)
 --graph-degree N        # Graph degree for index construction (default: 32)
 --build-complexity N    # Build complexity for index construction (default: 64)
 --no-compact           # Disable compact index storage (compact storage IS enabled to save storage by default)
 --no-recompute         # Disable embedding recomputation (recomputation IS enabled to save storage by default)
 ```
 </details>
 ### 📄 Personal Data Manager: Process Any Documents (`.pdf`, `.txt`, `.md`)!
 Ask questions directly about your personal PDFs, documents, and any directory containing your files!
 <p align="center">
  <img src="videos/paper_clear.gif" alt="LEANN Document Search Demo" width="600">
 </p>
 The example below asks a question about summarizing our paper (uses default data in `data/`, which is a directory with diverse data sources: two papers, Pride and Prejudice, and a Technical report about LLM in Huawei in Chinese), and this is the **easiest example** to run here:
 ```bash
 source .venv/bin/activate # Don't forget to activate the virtual environment
 python -m apps.document_rag --query "What are the main techniques LEANN explores?"
 ```
 <details>
 <summary><strong>📋 Click to expand: Document-Specific Arguments</strong></summary>
 #### Parameters
 ```bash
 --data-dir DIR           # Directory containing documents to process (default: data)
 --file-types .ext .ext   # Filter by specific file types (optional - all LlamaIndex supported types if omitted)
 ```
 #### Example Commands
 ```bash
 # Process all documents with larger chunks for academic papers
 python -m apps.document_rag --data-dir "~/Documents/Papers" --chunk-size 1024
 # Filter only markdown and Python files with smaller chunks
 python -m apps.document_rag --data-dir "./docs" --chunk-size 256 --file-types .md .py
 ```
 </details>
 ### 📧 Your Personal Email Secretary: RAG on Apple Mail!
 > **Note:** The examples below currently support macOS only. Windows support coming soon.
 <p align="center">
  <img src="videos/mail_clear.gif" alt="LEANN Email Search Demo" width="600">
 </p>
 Before running the example below, you need to grant full disk access to your terminal/VS Code in System Preferences → Privacy & Security → Full Disk Access.
 ```bash
 python -m apps.email_rag --query "What's the food I ordered by DoorDash or Uber Eats mostly?"
 ```
 **780K email chunks → 78MB storage.** Finally, search your email like you search Google.
 <details>
 <summary><strong>📋 Click to expand: Email-Specific Arguments</strong></summary>
 #### Parameters
 ```bash
 --mail-path PATH         # Path to specific mail directory (auto-detects if omitted)
 --include-html          # Include HTML content in processing (useful for newsletters)
 ```
 #### Example Commands
 ```bash
 # Search work emails from a specific account
 python -m apps.email_rag --mail-path "~/Library/Mail/V10/WORK_ACCOUNT"
 # Find all receipts and order confirmations (includes HTML)
 python -m apps.email_rag --query "receipt order confirmation invoice" --include-html
 ```
 </details>
@@ -183,29 +295,32 @@ Once the index is built, you can ask questions like:
 - "Show me emails about travel expenses"
 </details>
-### Time Machine for the Web  
+### 🔍 Time Machine for the Web: RAG Your Entire Chrome Browser History!
 <p align="center">
  <img src="videos/google_clear.gif" alt="LEANN Browser History Search Demo" width="600">
 </p>
 ```bash
-python examples/google_history_reader_leann.py
+python -m apps.browser_rag --query "Tell me my browser history about machine learning?"
 # "What was that AI paper I read last month?"
 # "Show me all the cooking videos I watched"
 ```
-**38K browser entries → 6MB.** Your browser history becomes your personal search engine.
+**38K browser entries → 6MB storage.** Your browser history becomes your personal search engine.
 <details>
-<summary><strong>📋 Click to expand: Command Examples</strong></summary>
+<summary><strong>📋 Click to expand: Browser-Specific Arguments</strong></summary>
 #### Parameters
 ```bash
-# Use default Chrome profile (auto-finds all profiles)
+--chrome-profile PATH    # Path to Chrome profile directory (auto-detects if omitted)
-python examples/google_history_reader_leann.py
+```
-# Run with custom index directory
+#### Example Commands
-python examples/google_history_reader_leann.py --index-dir "./my_chrome_index"
+```bash
 # Search academic research from your browsing history
 python -m apps.browser_rag --query "arxiv papers machine learning transformer architecture"
-# Limit number of history entries processed (useful for testing)
+# Track competitor analysis across work profile
-python examples/google_history_reader_leann.py --max-entries 500
+python -m apps.browser_rag --chrome-profile "~/Library/Application Support/Google/Chrome/Work Profile" --max-items 5000
 # Run a single query
 python examples/google_history_reader_leann.py --query "What websites did I visit about machine learning?"
 ```
 </details>
@@ -238,44 +353,58 @@ Once the index is built, you can ask questions like:
 </details>
-### WeChat Detective
+### 💬 WeChat Detective: Unlock Your Golden Memories!
 <p align="center">
  <img src="videos/wechat_clear.gif" alt="LEANN WeChat Search Demo" width="600">
 </p>
 ```bash
-python examples/wechat_history_reader_leann.py
+python -m apps.wechat_rag --query "Show me all group chats about weekend plans"
 # "Show me all group chats about weekend plans"
 ```
-**400K messages → 64MB.** Search years of chat history in any language.
+**400K messages → 64MB storage** Search years of chat history in any language.
 <details>
 <summary><strong>🔧 Click to expand: Installation Requirements</strong></summary>
-First, you need to install the WeChat exporter:
+First, you need to install the [WeChat exporter](https://github.com/sunnyyoung/WeChatTweak-CLI),
 ```bash
 brew install sunnyyoung/repo/wechattweak-cli
 ```
 or install it manually (if you have issues with Homebrew):
 ```bash
 sudo packages/wechat-exporter/wechattweak-cli install
 ```
-**Troubleshooting**: If you encounter installation issues, check the [WeChatTweak-CLI issues page](https://github.com/sunnyyoung/WeChatTweak-CLI/issues/41).
+**Troubleshooting:**
 - **Installation issues**: Check the [WeChatTweak-CLI issues page](https://github.com/sunnyyoung/WeChatTweak-CLI/issues/41)
 - **Export errors**: If you encounter the error below, try restarting WeChat
  ```bash
  Failed to export WeChat data. Please ensure WeChat is running and WeChatTweak is installed.
  Failed to find or export WeChat data. Exiting.
  ```
 </details>
 <details>
-<summary><strong>📋 Click to expand: Command Examples</strong></summary>
+<summary><strong>📋 Click to expand: WeChat-Specific Arguments</strong></summary>
 #### Parameters
 ```bash
-# Use default settings (recommended for first run)
+--export-dir DIR         # Directory to store exported WeChat data (default: wechat_export_direct)
-python examples/wechat_history_reader_leann.py
+--force-export          # Force re-export even if data exists
 ```
-# Run with custom export directory and wehn we run the first time, LEANN will export all chat history automatically for you
+#### Example Commands
-python examples/wechat_history_reader_leann.py --export-dir "./my_wechat_exports"
+```bash
 # Search for travel plans discussed in group chats
 python -m apps.wechat_rag --query "travel plans" --max-items 10000
-# Run with custom index directory
+# Re-export and search recent chats (useful after new messages)
-python examples/wechat_history_reader_leann.py --index-dir "./my_wechat_index"
+python -m apps.wechat_rag --force-export --query "work schedule"
 # Limit number of chat entries processed (useful for testing)
 python examples/wechat_history_reader_leann.py --max-entries 1000
 # Run a single query
 python examples/wechat_history_reader_leann.py --query "Show me conversations about travel plans"
 ```
 </details>
@@ -289,6 +418,115 @@ Once the index is built, you can ask questions like:
 </details>
 ### 🚀 Claude Code Integration: Transform Your Development Workflow!
 **The future of code assistance is here.** Transform your development workflow with LEANN's native MCP integration for Claude Code. Index your entire codebase and get intelligent code assistance directly in your IDE.
 **Key features:**
 - 🔍 **Semantic code search** across your entire project
 - 📚 **Context-aware assistance** for debugging and development
 - 🚀 **Zero-config setup** with automatic language detection
 ```bash
 # Install LEANN globally for MCP integration
 uv tool install leann-core
 # Setup is automatic - just start using Claude Code!
 ```
 Try our fully agentic pipeline with auto query rewriting, semantic search planning, and more:
 ![LEANN MCP Integration](assets/mcp_leann.png)
 **Ready to supercharge your coding?** [Complete Setup Guide →](packages/leann-mcp/README.md)
 ## 🖥️ Command Line Interface
 LEANN includes a powerful CLI for document processing and search. Perfect for quick document indexing and interactive chat.
 ### Installation
 If you followed the Quick Start, `leann` is already installed in your virtual environment:
 ```bash
 source .venv/bin/activate
 leann --help
 ```
 **To make it globally available:**
 ```bash
 # Install the LEANN CLI globally using uv tool
 uv tool install leann
 # Now you can use leann from anywhere without activating venv
 leann --help
 ```
 > **Note**: Global installation is required for Claude Code integration. The `leann_mcp` server depends on the globally available `leann` command.
 ### Usage Examples
 ```bash
 # build from a specific directory, and my_docs is the index name
 leann build my-docs --docs ./your_documents
 # Search your documents
 leann search my-docs "machine learning concepts"
 # Interactive chat with your documents
 leann ask my-docs --interactive
 # List all your indexes
 leann list
 ```
 **Key CLI features:**
 - Auto-detects document formats (PDF, TXT, MD, DOCX)
 - Smart text chunking with overlap
 - Multiple LLM providers (Ollama, OpenAI, HuggingFace)
 - Organized index storage in `~/.leann/indexes/`
 - Support for advanced search parameters
 <details>
 <summary><strong>📋 Click to expand: Complete CLI Reference</strong></summary>
 **Build Command:**
 ```bash
 leann build INDEX_NAME --docs DIRECTORY [OPTIONS]
 Options:
  --backend {hnsw,diskann}     Backend to use (default: hnsw)
  --embedding-model MODEL      Embedding model (default: facebook/contriever)
  --graph-degree N            Graph degree (default: 32)
  --complexity N              Build complexity (default: 64)
  --force                     Force rebuild existing index
  --compact                   Use compact storage (default: true)
  --recompute                 Enable recomputation (default: true)
 ```
 **Search Command:**
 ```bash
 leann search INDEX_NAME QUERY [OPTIONS]
 Options:
  --top-k N                   Number of results (default: 5)
  --complexity N              Search complexity (default: 64)
  --recompute-embeddings      Use recomputation for highest accuracy
  --pruning-strategy {global,local,proportional}
 ```
 **Ask Command:**
 ```bash
 leann ask INDEX_NAME [OPTIONS]
 Options:
  --llm {ollama,openai,hf}    LLM provider (default: ollama)
  --model MODEL               Model name (default: qwen3:8b)
  --interactive              Interactive chat mode
  --top-k N                  Retrieval count (default: 20)
 ```
 </details>
 ## 🏗️ Architecture & How It Works
@@ -304,58 +542,30 @@ Once the index is built, you can ask questions like:
 - **Dynamic batching:** Efficiently batch embedding computations for GPU utilization
 - **Two-level search:** Smart graph traversal that prioritizes promising nodes
-**Backends:** DiskANN or HNSW - pick what works for your data size.
+**Backends:** HNSW (default) for most use cases, with optional DiskANN support for billion-scale datasets.
 ## Benchmarks
 Run the comparison yourself:
 ```bash
 python examples/compare_faiss_vs_leann.py
 ```
-| System | Storage | 
+**[Simple Example: Compare LEANN vs FAISS →](benchmarks/compare_faiss_vs_leann.py)**
-|--------|---------|
+### 📊 Storage Comparison
-| FAISS HNSW | 5.5 MB |
+
-| LEANN | 0.5 MB |
+| System | DPR (2.1M) | Wiki (60M) | Chat (400K) | Email (780K) | Browser (38K) |
-| **Savings** | **91%** |
+|--------|-------------|------------|-------------|--------------|---------------|
 | Traditional vector database (e.g., FAISS) | 3.8 GB      | 201 GB     | 1.8 GB     | 2.4 GB      | 130 MB        |
 | LEANN  | 324 MB      | 6 GB       | 64 MB       | 79 MB       | 6.4 MB        |
 | Savings| 91%         | 97%        | 97%         | 97%         | 95%           |
 Same dataset, same hardware, same embedding model. LEANN just works better.
 ## Reproduce Our Results
 ```bash
 uv pip install -e ".[dev]"  # Install dev dependencies
-python examples/run_evaluation.py data/indices/dpr/dpr_diskann      # DPR dataset
+python benchmarks/run_evaluation.py    # Will auto-download evaluation data and run benchmarks
 python examples/run_evaluation.py data/indices/rpj_wiki/rpj_wiki.index  # Wikipedia
 ```
-The evaluation script downloads data automatically on first run.
+The evaluation script downloads data automatically on first run. The last three results were tested with partial personal data, and you can reproduce them with your own data!
 ### Storage Usage Comparison
 | System                | DPR (2.1M chunks) | RPJ-wiki (60M chunks) | Chat history (400K messages) | Apple emails (90K messages chunks) |Google Search History (38K entries)
 |-----------------------|------------------|------------------------|-----------------------------|------------------------------|------------------------------|
 | Traditional Vector DB(FAISS) | 3.8 GB           | 201 GB                 | 1.8G                     | 305.8 MB                     |130.4 MB                     |
 | **LEANN**             | **324 MB**       | **6 GB**               | **64 MB**                 | **14.8 MB**                  |**6.4MB**                  |
 | **Reduction**         | **91% smaller**  | **97% smaller**        | **97% smaller**             | **95% smaller**              |**95% smaller**              |
 <!-- ### Memory Usage Comparison
 | System          j      | DPR(2M docs)     | RPJ-wiki(60M docs)    | Chat history()   |
 | --------------------- | ---------------- | ---------------- | ---------------- |
 | Traditional Vector DB(LLamaindex faiss) | x GB           | x GB            | x GB           |
 | **Leann**       | **xx MB** | **x GB** | **x GB** |
 | **Reduction**   | **x%**  | **x%**  | **x%**  |
 ### Query Performance of LEANN
 | Backend             | Index Size | Query Time | Recall@3 |
 | ------------------- | ---------- | ---------- | --------- |
 | DiskANN             | 1M docs    | xms       | 0.95      |
 | HNSW                | 1M docs    | xms        | 0.95      | -->
 *Benchmarks run on Apple M3 Pro 36 GB*
 ## 🔬 Paper
 If you find Leann useful, please cite:
@@ -374,87 +584,15 @@ If you find Leann useful, please cite:
 }
 ```
-## ✨ Features
+## ✨ [Detailed Features →](docs/features.md)
-### 🔥 Core Features
+## 🤝 [CONTRIBUTING →](docs/CONTRIBUTING.md)
 - **🔄 Real-time Embeddings** - Eliminate heavy embedding storage with dynamic computation using optimized ZMQ servers and highly optimized search paradigm (overlapping and batching) with highly optimized embedding engine
 - **📈 Scalable Architecture** - Handles millions of documents on consumer hardware; the larger your dataset, the more LEANN can save
 - **🎯 Graph Pruning** - Advanced techniques to minimize the storage overhead of vector search to a limited footprint
 - **🏗️ Pluggable Backends** - DiskANN, HNSW/FAISS with unified API
 ### 🛠️ Technical Highlights
 - **🔄 Recompute Mode** - Highest accuracy scenarios while eliminating vector storage overhead
 - **⚡ Zero-copy Operations** - Minimize IPC overhead by transferring distances instead of embeddings
 - **🚀 High-throughput Embedding Pipeline** - Optimized batched processing for maximum efficiency
 - **🎯 Two-level Search** - Novel coarse-to-fine search overlap for accelerated query processing (optional)
 - **💾 Memory-mapped Indices** - Fast startup with raw text mapping to reduce memory overhead
 - **🚀 MLX Support** - Ultra-fast recompute/build with quantized embedding models, accelerating building and search ([minimal example](test/build_mlx_index.py))
 ### 🎨 Developer Experience
 - **Simple Python API** - Get started in minutes
 - **Extensible backend system** - Easy to add new algorithms
 - **Comprehensive examples** - From basic usage to production deployment
 ## 🤝 Contributing
 We welcome contributions! Leann is built by the community, for the community.
 ### Ways to Contribute
 - 🐛 **Bug Reports**: Found an issue? Let us know!
 - 💡 **Feature Requests**: Have an idea? We'd love to hear it!
 - 🔧 **Code Contributions**: PRs welcome for all skill levels
 - 📖 **Documentation**: Help make Leann more accessible
 - 🧪 **Benchmarks**: Share your performance results
-<!-- ## ❓ FAQ
+## ❓ [FAQ →](docs/faq.md)
 ### Common Issues
 #### NCCL Topology Error
 **Problem**: You encounter `ncclTopoComputePaths` error during document processing:
 ```
 ncclTopoComputePaths (system=<optimized out>, comm=comm@entry=0x5555a82fa3c0) at graph/paths.cc:688
 ```
 **Solution**: Set these environment variables before running your script:
 ```bash
 export NCCL_TOPO_DUMP_FILE=/tmp/nccl_topo.xml
 export NCCL_DEBUG=INFO
 export NCCL_DEBUG_SUBSYS=INIT,GRAPH
 export NCCL_IB_DISABLE=1
 export NCCL_NET_PLUGIN=none
 export NCCL_SOCKET_IFNAME=ens5
 ``` -->
 ## 📈 Roadmap
 ### 🎯 Q2 2025
 - [X] DiskANN backend with MIPS/L2/Cosine support
 - [X] HNSW backend integration
 - [X] Real-time embedding pipeline
 - [X] Memory-efficient graph pruning
 ### 🚀 Q3 2025
- [ ] Advanced caching strategies
+## 📈 [Roadmap →](docs/roadmap.md)
 - [ ] Add contextual-retrieval https://www.anthropic.com/news/contextual-retrieval
 - [ ] Add sleep-time-compute and summarize agent! to summarilze the file on computer!
 - [ ] Add OpenAI recompute API
 ### 🌟 Q4 2025
 - [ ] Integration with LangChain/LlamaIndex
 - [ ] Visual similarity search
 - [ ] Query rewrtiting, rerank and expansion
 ## 📄 License
@@ -462,10 +600,11 @@ MIT License - see [LICENSE](LICENSE) for details.
 ## 🙏 Acknowledgments
- **Microsoft Research** for the DiskANN algorithm
+Core Contributors: [Yichuan Wang](https://yichuan-w.github.io/) & [Zhifei Li](https://github.com/andylizf).
- **Meta AI** for FAISS and optimization insights
+
- **HuggingFace** for the transformer ecosystem
+We welcome more contributors! Feel free to open issues or submit PRs.
- **Our amazing contributors** who make this possible
+
 This work is done at [**Berkeley Sky Computing Lab**](https://sky.cs.berkeley.edu/).
 ---
@@ -476,4 +615,3 @@ MIT License - see [LICENSE](LICENSE) for details.
 <p align="center">
  Made with ❤️ by the Leann team
 </p>
--- a/research/micro/result.md
+++ b/research/micro/result.md
--- a/apps/base_rag_example.py
+++ b/apps/base_rag_example.py
@@ -0,0 +1,321 @@
 """
 Base class for unified RAG examples interface.
 Provides common parameters and functionality for all RAG examples.
 """
 import argparse
 from abc import ABC, abstractmethod
 from pathlib import Path
 from typing import Any
 import dotenv
 from leann.api import LeannBuilder, LeannChat
 from llama_index.core.node_parser import SentenceSplitter
 dotenv.load_dotenv()
 class BaseRAGExample(ABC):
    """Base class for all RAG examples with unified interface."""
    def __init__(
        self,
        name: str,
        description: str,
        default_index_name: str,
    ):
        self.name = name
        self.description = description
        self.default_index_name = default_index_name
        self.parser = self._create_parser()
    def _create_parser(self) -> argparse.ArgumentParser:
        """Create argument parser with common parameters."""
        parser = argparse.ArgumentParser(
            description=self.description, formatter_class=argparse.RawDescriptionHelpFormatter
        )
        # Core parameters (all examples share these)
        core_group = parser.add_argument_group("Core Parameters")
        core_group.add_argument(
            "--index-dir",
            type=str,
            default=f"./{self.default_index_name}",
            help=f"Directory to store the index (default: ./{self.default_index_name})",
        )
        core_group.add_argument(
            "--query",
            type=str,
            default=None,
            help="Query to run (if not provided, will run in interactive mode)",
        )
        # Allow subclasses to override default max_items
        max_items_default = getattr(self, "max_items_default", -1)
        core_group.add_argument(
            "--max-items",
            type=int,
            default=max_items_default,
            help="Maximum number of items to process  -1 for all, means index all documents, and you should set it to a reasonable number if you have a large dataset and try at the first time)",
        )
        core_group.add_argument(
            "--force-rebuild", action="store_true", help="Force rebuild index even if it exists"
        )
        # Embedding parameters
        embedding_group = parser.add_argument_group("Embedding Parameters")
        # Allow subclasses to override default embedding_model
        embedding_model_default = getattr(self, "embedding_model_default", "facebook/contriever")
        embedding_group.add_argument(
            "--embedding-model",
            type=str,
            default=embedding_model_default,
            help=f"Embedding model to use (default: {embedding_model_default})",
        )
        embedding_group.add_argument(
            "--embedding-mode",
            type=str,
            default="sentence-transformers",
            choices=["sentence-transformers", "openai", "mlx", "ollama"],
            help="Embedding backend mode (default: sentence-transformers)",
        )
        # LLM parameters
        llm_group = parser.add_argument_group("LLM Parameters")
        llm_group.add_argument(
            "--llm",
            type=str,
            default="openai",
            choices=["openai", "ollama", "hf", "simulated"],
            help="LLM backend to use (default: openai)",
        )
        llm_group.add_argument(
            "--llm-model",
            type=str,
            default=None,
            help="LLM model name (default: gpt-4o for openai, llama3.2:1b for ollama)",
        )
        llm_group.add_argument(
            "--llm-host",
            type=str,
            default="http://localhost:11434",
            help="Host for Ollama API (default: http://localhost:11434)",
        )
        llm_group.add_argument(
            "--thinking-budget",
            type=str,
            choices=["low", "medium", "high"],
            default=None,
            help="Thinking budget for reasoning models (low/medium/high). Supported by GPT-Oss:20b and other reasoning models.",
        )
        # Search parameters
        search_group = parser.add_argument_group("Search Parameters")
        search_group.add_argument(
            "--top-k", type=int, default=20, help="Number of results to retrieve (default: 20)"
        )
        search_group.add_argument(
            "--search-complexity",
            type=int,
            default=32,
            help="Search complexity for graph traversal (default: 64)",
        )
        # Index building parameters
        index_group = parser.add_argument_group("Index Building Parameters")
        index_group.add_argument(
            "--backend-name",
            type=str,
            default="hnsw",
            choices=["hnsw", "diskann"],
            help="Backend to use for index (default: hnsw)",
        )
        index_group.add_argument(
            "--graph-degree",
            type=int,
            default=32,
            help="Graph degree for index construction (default: 32)",
        )
        index_group.add_argument(
            "--build-complexity",
            type=int,
            default=64,
            help="Build complexity for index construction (default: 64)",
        )
        index_group.add_argument(
            "--no-compact",
            action="store_true",
            help="Disable compact index storage",
        )
        index_group.add_argument(
            "--no-recompute",
            action="store_true",
            help="Disable embedding recomputation",
        )
        # Add source-specific parameters
        self._add_specific_arguments(parser)
        return parser
    @abstractmethod
    def _add_specific_arguments(self, parser: argparse.ArgumentParser):
        """Add source-specific arguments. Override in subclasses."""
        pass
    @abstractmethod
    async def load_data(self, args) -> list[str]:
        """Load data from the source. Returns list of text chunks."""
        pass
    def get_llm_config(self, args) -> dict[str, Any]:
        """Get LLM configuration based on arguments."""
        config = {"type": args.llm}
        if args.llm == "openai":
            config["model"] = args.llm_model or "gpt-4o"
        elif args.llm == "ollama":
            config["model"] = args.llm_model or "llama3.2:1b"
            config["host"] = args.llm_host
        elif args.llm == "hf":
            config["model"] = args.llm_model or "Qwen/Qwen2.5-1.5B-Instruct"
        return config
    async def build_index(self, args, texts: list[str]) -> str:
        """Build LEANN index from texts."""
        index_path = str(Path(args.index_dir) / f"{self.default_index_name}.leann")
        print(f"\n[Building Index] Creating {self.name} index...")
        print(f"Total text chunks: {len(texts)}")
        builder = LeannBuilder(
            backend_name=args.backend_name,
            embedding_model=args.embedding_model,
            embedding_mode=args.embedding_mode,
            graph_degree=args.graph_degree,
            complexity=args.build_complexity,
            is_compact=not args.no_compact,
            is_recompute=not args.no_recompute,
            num_threads=1,  # Force single-threaded mode
        )
        # Add texts in batches for better progress tracking
        batch_size = 1000
        for i in range(0, len(texts), batch_size):
            batch = texts[i : i + batch_size]
            for text in batch:
                builder.add_text(text)
            print(f"Added {min(i + batch_size, len(texts))}/{len(texts)} texts...")
        print("Building index structure...")
        builder.build_index(index_path)
        print(f"Index saved to: {index_path}")
        return index_path
    async def run_interactive_chat(self, args, index_path: str):
        """Run interactive chat with the index."""
        chat = LeannChat(
            index_path,
            llm_config=self.get_llm_config(args),
            system_prompt=f"You are a helpful assistant that answers questions about {self.name} data.",
            complexity=args.search_complexity,
        )
        print(f"\n[Interactive Mode] Chat with your {self.name} data!")
        print("Type 'quit' or 'exit' to stop.\n")
        while True:
            try:
                query = input("You: ").strip()
                if query.lower() in ["quit", "exit", "q"]:
                    print("Goodbye!")
                    break
                if not query:
                    continue
                # Prepare LLM kwargs with thinking budget if specified
                llm_kwargs = {}
                if hasattr(args, "thinking_budget") and args.thinking_budget:
                    llm_kwargs["thinking_budget"] = args.thinking_budget
                response = chat.ask(
                    query,
                    top_k=args.top_k,
                    complexity=args.search_complexity,
                    llm_kwargs=llm_kwargs,
                )
                print(f"\nAssistant: {response}\n")
            except KeyboardInterrupt:
                print("\nGoodbye!")
                break
            except Exception as e:
                print(f"Error: {e}")
    async def run_single_query(self, args, index_path: str, query: str):
        """Run a single query against the index."""
        chat = LeannChat(
            index_path,
            llm_config=self.get_llm_config(args),
            system_prompt=f"You are a helpful assistant that answers questions about {self.name} data.",
            complexity=args.search_complexity,
        )
        print(f"\n[Query]: \033[36m{query}\033[0m")
        # Prepare LLM kwargs with thinking budget if specified
        llm_kwargs = {}
        if hasattr(args, "thinking_budget") and args.thinking_budget:
            llm_kwargs["thinking_budget"] = args.thinking_budget
        response = chat.ask(
            query, top_k=args.top_k, complexity=args.search_complexity, llm_kwargs=llm_kwargs
        )
        print(f"\n[Response]: \033[36m{response}\033[0m")
    async def run(self):
        """Main entry point for the example."""
        args = self.parser.parse_args()
        # Check if index exists
        index_path = str(Path(args.index_dir) / f"{self.default_index_name}.leann")
        index_exists = Path(args.index_dir).exists()
        if not index_exists or args.force_rebuild:
            # Load data and build index
            print(f"\n{'Rebuilding' if index_exists else 'Building'} index...")
            texts = await self.load_data(args)
            if not texts:
                print("No data found to index!")
                return
            index_path = await self.build_index(args, texts)
        else:
            print(f"\nUsing existing index in {args.index_dir}")
        # Run query or interactive mode
        if args.query:
            await self.run_single_query(args, index_path, args.query)
        else:
            await self.run_interactive_chat(args, index_path)
 def create_text_chunks(documents, chunk_size=256, chunk_overlap=25) -> list[str]:
    """Helper function to create text chunks from documents."""
    node_parser = SentenceSplitter(
        chunk_size=chunk_size,
        chunk_overlap=chunk_overlap,
        separator=" ",
        paragraph_separator="\n\n",
    )
    all_texts = []
    for doc in documents:
        nodes = node_parser.get_nodes_from_documents([doc])
        if nodes:
            all_texts.extend(node.get_content() for node in nodes)
    return all_texts
--- a/apps/browser_rag.py
+++ b/apps/browser_rag.py
@@ -0,0 +1,170 @@
 """
 Browser History RAG example using the unified interface.
 Supports Chrome browser history.
 """
 import os
 import sys
 from pathlib import Path
 # Add parent directory to path for imports
 sys.path.insert(0, str(Path(__file__).parent))
 from base_rag_example import BaseRAGExample, create_text_chunks
 from .history_data.history import ChromeHistoryReader
 class BrowserRAG(BaseRAGExample):
    """RAG example for Chrome browser history."""
    def __init__(self):
        # Set default values BEFORE calling super().__init__
        self.embedding_model_default = (
            "sentence-transformers/all-MiniLM-L6-v2"  # Fast 384-dim model
        )
        super().__init__(
            name="Browser History",
            description="Process and query Chrome browser history with LEANN",
            default_index_name="google_history_index",
        )
    def _add_specific_arguments(self, parser):
        """Add browser-specific arguments."""
        browser_group = parser.add_argument_group("Browser Parameters")
        browser_group.add_argument(
            "--chrome-profile",
            type=str,
            default=None,
            help="Path to Chrome profile directory (auto-detected if not specified)",
        )
        browser_group.add_argument(
            "--auto-find-profiles",
            action="store_true",
            default=True,
            help="Automatically find all Chrome profiles (default: True)",
        )
        browser_group.add_argument(
            "--chunk-size", type=int, default=256, help="Text chunk size (default: 256)"
        )
        browser_group.add_argument(
            "--chunk-overlap", type=int, default=128, help="Text chunk overlap (default: 128)"
        )
    def _get_chrome_base_path(self) -> Path:
        """Get the base Chrome profile path based on OS."""
        if sys.platform == "darwin":
            return Path.home() / "Library" / "Application Support" / "Google" / "Chrome"
        elif sys.platform.startswith("linux"):
            return Path.home() / ".config" / "google-chrome"
        elif sys.platform == "win32":
            return Path(os.environ["LOCALAPPDATA"]) / "Google" / "Chrome" / "User Data"
        else:
            raise ValueError(f"Unsupported platform: {sys.platform}")
    def _find_chrome_profiles(self) -> list[Path]:
        """Auto-detect all Chrome profiles."""
        base_path = self._get_chrome_base_path()
        if not base_path.exists():
            return []
        profiles = []
        # Check Default profile
        default_profile = base_path / "Default"
        if default_profile.exists() and (default_profile / "History").exists():
            profiles.append(default_profile)
        # Check numbered profiles
        for item in base_path.iterdir():
            if item.is_dir() and item.name.startswith("Profile "):
                if (item / "History").exists():
                    profiles.append(item)
        return profiles
    async def load_data(self, args) -> list[str]:
        """Load browser history and convert to text chunks."""
        # Determine Chrome profiles
        if args.chrome_profile and not args.auto_find_profiles:
            profile_dirs = [Path(args.chrome_profile)]
        else:
            print("Auto-detecting Chrome profiles...")
            profile_dirs = self._find_chrome_profiles()
            # If specific profile given, filter to just that one
            if args.chrome_profile:
                profile_path = Path(args.chrome_profile)
                profile_dirs = [p for p in profile_dirs if p == profile_path]
        if not profile_dirs:
            print("No Chrome profiles found!")
            print("Please specify --chrome-profile manually")
            return []
        print(f"Found {len(profile_dirs)} Chrome profiles")
        # Create reader
        reader = ChromeHistoryReader()
        # Process each profile
        all_documents = []
        total_processed = 0
        for i, profile_dir in enumerate(profile_dirs):
            print(f"\nProcessing profile {i + 1}/{len(profile_dirs)}: {profile_dir.name}")
            try:
                # Apply max_items limit per profile
                max_per_profile = -1
                if args.max_items > 0:
                    remaining = args.max_items - total_processed
                    if remaining <= 0:
                        break
                    max_per_profile = remaining
                # Load history
                documents = reader.load_data(
                    chrome_profile_path=str(profile_dir),
                    max_count=max_per_profile,
                )
                if documents:
                    all_documents.extend(documents)
                    total_processed += len(documents)
                    print(f"Processed {len(documents)} history entries from this profile")
            except Exception as e:
                print(f"Error processing {profile_dir}: {e}")
                continue
        if not all_documents:
            print("No browser history found to process!")
            return []
        print(f"\nTotal history entries processed: {len(all_documents)}")
        # Convert to text chunks
        all_texts = create_text_chunks(
            all_documents, chunk_size=args.chunk_size, chunk_overlap=args.chunk_overlap
        )
        return all_texts
 if __name__ == "__main__":
    import asyncio
    # Example queries for browser history RAG
    print("\n🌐 Browser History RAG Example")
    print("=" * 50)
    print("\nExample queries you can try:")
    print("- 'What websites did I visit about machine learning?'")
    print("- 'Find my search history about programming'")
    print("- 'What YouTube videos did I watch recently?'")
    print("- 'Show me websites about travel planning'")
    print("\nNote: Make sure Chrome is closed before running\n")
    rag = BrowserRAG()
    asyncio.run(rag.run())
--- a/apps/document_rag.py
+++ b/apps/document_rag.py
@@ -0,0 +1,108 @@
 """
 Document RAG example using the unified interface.
 Supports PDF, TXT, MD, and other document formats.
 """
 import sys
 from pathlib import Path
 # Add parent directory to path for imports
 sys.path.insert(0, str(Path(__file__).parent))
 from base_rag_example import BaseRAGExample, create_text_chunks
 from llama_index.core import SimpleDirectoryReader
 class DocumentRAG(BaseRAGExample):
    """RAG example for document processing (PDF, TXT, MD, etc.)."""
    def __init__(self):
        super().__init__(
            name="Document",
            description="Process and query documents (PDF, TXT, MD, etc.) with LEANN",
            default_index_name="test_doc_files",
        )
    def _add_specific_arguments(self, parser):
        """Add document-specific arguments."""
        doc_group = parser.add_argument_group("Document Parameters")
        doc_group.add_argument(
            "--data-dir",
            type=str,
            default="data",
            help="Directory containing documents to index (default: data)",
        )
        doc_group.add_argument(
            "--file-types",
            nargs="+",
            default=None,
            help="Filter by file types (e.g., .pdf .txt .md). If not specified, all supported types are processed",
        )
        doc_group.add_argument(
            "--chunk-size", type=int, default=256, help="Text chunk size (default: 256)"
        )
        doc_group.add_argument(
            "--chunk-overlap", type=int, default=128, help="Text chunk overlap (default: 128)"
        )
    async def load_data(self, args) -> list[str]:
        """Load documents and convert to text chunks."""
        print(f"Loading documents from: {args.data_dir}")
        if args.file_types:
            print(f"Filtering by file types: {args.file_types}")
        else:
            print("Processing all supported file types")
        # Check if data directory exists
        data_path = Path(args.data_dir)
        if not data_path.exists():
            raise ValueError(f"Data directory not found: {args.data_dir}")
        # Load documents
        reader_kwargs = {
            "recursive": True,
            "encoding": "utf-8",
        }
        if args.file_types:
            reader_kwargs["required_exts"] = args.file_types
        documents = SimpleDirectoryReader(args.data_dir, **reader_kwargs).load_data(
            show_progress=True
        )
        if not documents:
            print(f"No documents found in {args.data_dir} with extensions {args.file_types}")
            return []
        print(f"Loaded {len(documents)} documents")
        # Convert to text chunks
        all_texts = create_text_chunks(
            documents, chunk_size=args.chunk_size, chunk_overlap=args.chunk_overlap
        )
        # Apply max_items limit if specified
        if args.max_items > 0 and len(all_texts) > args.max_items:
            print(f"Limiting to {args.max_items} chunks (from {len(all_texts)})")
            all_texts = all_texts[: args.max_items]
        return all_texts
 if __name__ == "__main__":
    import asyncio
    # Example queries for document RAG
    print("\n📄 Document RAG Example")
    print("=" * 50)
    print("\nExample queries you can try:")
    print("- 'What are the main techniques LEANN uses?'")
    print("- 'What is the technique DLPM?'")
    print("- 'Who does Elizabeth Bennet marry?'")
    print(
        "- 'What is the problem of developing pan gu model Huawei meets? (盘古大模型开发中遇到什么问题?)'"
    )
    print("\nOr run without --query for interactive mode\n")
    rag = DocumentRAG()
    asyncio.run(rag.run())
--- a/apps/email_data/LEANN_email_reader.py
+++ b/apps/email_data/LEANN_email_reader.py
@@ -0,0 +1,167 @@
 import email
 import os
 from pathlib import Path
 from typing import Any
 from llama_index.core import Document
 from llama_index.core.readers.base import BaseReader
 def find_all_messages_directories(root: str | None = None) -> list[Path]:
    """
    Recursively find all 'Messages' directories under the given root.
    Returns a list of Path objects.
    """
    if root is None:
        # Auto-detect user's mail path
        home_dir = os.path.expanduser("~")
        root = os.path.join(home_dir, "Library", "Mail")
    messages_dirs = []
    for dirpath, _dirnames, _filenames in os.walk(root):
        if os.path.basename(dirpath) == "Messages":
            messages_dirs.append(Path(dirpath))
    return messages_dirs
 class EmlxReader(BaseReader):
    """
    Apple Mail .emlx file reader with embedded metadata.
    Reads individual .emlx files from Apple Mail's storage format.
    """
    def __init__(self, include_html: bool = False) -> None:
        """
        Initialize.
        Args:
            include_html: Whether to include HTML content in the email body (default: False)
        """
        self.include_html = include_html
    def load_data(self, input_dir: str, **load_kwargs: Any) -> list[Document]:
        """
        Load data from the input directory containing .emlx files.
        Args:
            input_dir: Directory containing .emlx files
            **load_kwargs:
                max_count (int): Maximum amount of messages to read.
        """
        docs: list[Document] = []
        max_count = load_kwargs.get("max_count", 1000)
        count = 0
        total_files = 0
        successful_files = 0
        failed_files = 0
        print(f"Starting to process directory: {input_dir}")
        # Walk through the directory recursively
        for dirpath, dirnames, filenames in os.walk(input_dir):
            # Skip hidden directories
            dirnames[:] = [d for d in dirnames if not d.startswith(".")]
            for filename in filenames:
                # Check if we've reached the max count (skip if max_count == -1)
                if max_count > 0 and count >= max_count:
                    break
                if filename.endswith(".emlx"):
                    total_files += 1
                    filepath = os.path.join(dirpath, filename)
                    try:
                        # Read the .emlx file
                        with open(filepath, encoding="utf-8", errors="ignore") as f:
                            content = f.read()
                        # .emlx files have a length prefix followed by the email content
                        # The first line contains the length, followed by the email
                        lines = content.split("\n", 1)
                        if len(lines) >= 2:
                            email_content = lines[1]
                            # Parse the email using Python's email module
                            try:
                                msg = email.message_from_string(email_content)
                                # Extract email metadata
                                subject = msg.get("Subject", "No Subject")
                                from_addr = msg.get("From", "Unknown")
                                to_addr = msg.get("To", "Unknown")
                                date = msg.get("Date", "Unknown")
                                # Extract email body
                                body = ""
                                if msg.is_multipart():
                                    for part in msg.walk():
                                        if (
                                            part.get_content_type() == "text/plain"
                                            or part.get_content_type() == "text/html"
                                        ):
                                            if (
                                                part.get_content_type() == "text/html"
                                                and not self.include_html
                                            ):
                                                continue
                                            try:
                                                payload = part.get_payload(decode=True)
                                                if payload:
                                                    body += payload.decode("utf-8", errors="ignore")
                                            except Exception as e:
                                                print(f"Error decoding payload: {e}")
                                                continue
                                else:
                                    try:
                                        payload = msg.get_payload(decode=True)
                                        if payload:
                                            body = payload.decode("utf-8", errors="ignore")
                                    except Exception as e:
                                        print(f"Error decoding single part payload: {e}")
                                        body = ""
                                # Only create document if we have some content
                                if body.strip() or subject != "No Subject":
                                    # Create document content with metadata embedded in text
                                    doc_content = f"""
 [File]: {filename}
 [From]: {from_addr}
 [To]: {to_addr}
 [Subject]: {subject}
 [Date]: {date}
 [EMAIL BODY Start]:
 {body}
 """
                                    # No separate metadata - everything is in the text
                                    doc = Document(text=doc_content, metadata={})
                                    docs.append(doc)
                                    count += 1
                                    successful_files += 1
                                    # Print first few successful files for debugging
                                    if successful_files <= 3:
                                        print(
                                            f"Successfully loaded: {filename} - Subject: {subject[:50]}..."
                                        )
                            except Exception as e:
                                failed_files += 1
                                if failed_files <= 5:  # Only print first few errors
                                    print(f"Error parsing email from {filepath}: {e}")
                                continue
                    except Exception as e:
                        failed_files += 1
                        if failed_files <= 5:  # Only print first few errors
                            print(f"Error reading file {filepath}: {e}")
                        continue
        print("Processing summary:")
        print(f"  Total .emlx files found: {total_files}")
        print(f"  Successfully loaded: {successful_files}")
        print(f"  Failed to load: {failed_files}")
        print(f"  Final documents: {len(docs)}")
        return docs
--- a/examples/email_data/email.py
+++ b/examples/email_data/email.py
@@ -7,9 +7,9 @@ Contains simple parser for mbox files.
 import logging
 from pathlib import Path
-from typing import Any, Dict, List, Optional
+from typing import Any
 from fsspec import AbstractFileSystem
 from fsspec import AbstractFileSystem
 from llama_index.core.readers.base import BaseReader
 from llama_index.core.schema import Document
@@ -27,11 +27,7 @@ class MboxReader(BaseReader):
    """
    DEFAULT_MESSAGE_FORMAT: str = (
-        "Date: {_date}\n"
+        "Date: {_date}\nFrom: {_from}\nTo: {_to}\nSubject: {_subject}\nContent: {_content}"
        "From: {_from}\n"
        "To: {_to}\n"
        "Subject: {_subject}\n"
        "Content: {_content}"
    )
    def __init__(
@@ -45,9 +41,7 @@ class MboxReader(BaseReader):
        try:
            from bs4 import BeautifulSoup  # noqa
        except ImportError:
-            raise ImportError(
+            raise ImportError("`beautifulsoup4` package not found: `pip install beautifulsoup4`")
                "`beautifulsoup4` package not found: `pip install beautifulsoup4`"
            )
        super().__init__(*args, **kwargs)
        self.max_count = max_count
@@ -56,9 +50,9 @@ class MboxReader(BaseReader):
    def load_data(
        self,
        file: Path,
-        extra_info: Optional[Dict] = None,
+        extra_info: dict | None = None,
-        fs: Optional[AbstractFileSystem] = None,
+        fs: AbstractFileSystem | None = None,
-    ) -> List[Document]:
+    ) -> list[Document]:
        """Parse file into string."""
        # Import required libraries
        import mailbox
@@ -74,7 +68,7 @@ class MboxReader(BaseReader):
            )
        i = 0
-        results: List[str] = []
+        results: list[str] = []
        # Load file using mailbox
        bytes_parser = BytesParser(policy=default).parse
        mbox = mailbox.mbox(file, factory=bytes_parser)  # type: ignore
@@ -134,12 +128,12 @@ class EmlxMboxReader(MboxReader):
    def load_data(
        self,
        directory: Path,
-        extra_info: Optional[Dict] = None,
+        extra_info: dict | None = None,
-        fs: Optional[AbstractFileSystem] = None,
+        fs: AbstractFileSystem | None = None,
-    ) -> List[Document]:
+    ) -> list[Document]:
        """Parse .emlx files from directory into strings using MboxReader logic."""
        import tempfile
        import os
        import tempfile
        if fs:
            logger.warning(
@@ -156,18 +150,18 @@ class EmlxMboxReader(MboxReader):
            return []
        # Create a temporary mbox file
-        with tempfile.NamedTemporaryFile(mode='w', suffix='.mbox', delete=False) as temp_mbox:
+        with tempfile.NamedTemporaryFile(mode="w", suffix=".mbox", delete=False) as temp_mbox:
            temp_mbox_path = temp_mbox.name
            # Convert .emlx files to mbox format
            for emlx_file in emlx_files:
                try:
                    # Read the .emlx file
-                    with open(emlx_file, 'r', encoding='utf-8', errors='ignore') as f:
+                    with open(emlx_file, encoding="utf-8", errors="ignore") as f:
                        content = f.read()
                    # .emlx format: first line is length, rest is email content
-                    lines = content.split('\n', 1)
+                    lines = content.split("\n", 1)
                    if len(lines) >= 2:
                        email_content = lines[1]  # Skip the length line
@@ -188,5 +182,5 @@ class EmlxMboxReader(MboxReader):
                # Clean up temporary file
                try:
                    os.unlink(temp_mbox_path)
-                except:
+                except OSError:
                    pass
--- a/apps/email_rag.py
+++ b/apps/email_rag.py
@@ -0,0 +1,156 @@
 """
 Email RAG example using the unified interface.
 Supports Apple Mail on macOS.
 """
 import sys
 from pathlib import Path
 # Add parent directory to path for imports
 sys.path.insert(0, str(Path(__file__).parent))
 from base_rag_example import BaseRAGExample, create_text_chunks
 from .email_data.LEANN_email_reader import EmlxReader
 class EmailRAG(BaseRAGExample):
    """RAG example for Apple Mail processing."""
    def __init__(self):
        # Set default values BEFORE calling super().__init__
        self.max_items_default = -1  # Process all emails by default
        self.embedding_model_default = (
            "sentence-transformers/all-MiniLM-L6-v2"  # Fast 384-dim model
        )
        super().__init__(
            name="Email",
            description="Process and query Apple Mail emails with LEANN",
            default_index_name="mail_index",
        )
    def _add_specific_arguments(self, parser):
        """Add email-specific arguments."""
        email_group = parser.add_argument_group("Email Parameters")
        email_group.add_argument(
            "--mail-path",
            type=str,
            default=None,
            help="Path to Apple Mail directory (auto-detected if not specified)",
        )
        email_group.add_argument(
            "--include-html", action="store_true", help="Include HTML content in email processing"
        )
        email_group.add_argument(
            "--chunk-size", type=int, default=256, help="Text chunk size (default: 256)"
        )
        email_group.add_argument(
            "--chunk-overlap", type=int, default=25, help="Text chunk overlap (default: 25)"
        )
    def _find_mail_directories(self) -> list[Path]:
        """Auto-detect all Apple Mail directories."""
        mail_base = Path.home() / "Library" / "Mail"
        if not mail_base.exists():
            return []
        # Find all Messages directories
        messages_dirs = []
        for item in mail_base.rglob("Messages"):
            if item.is_dir():
                messages_dirs.append(item)
        return messages_dirs
    async def load_data(self, args) -> list[str]:
        """Load emails and convert to text chunks."""
        # Determine mail directories
        if args.mail_path:
            messages_dirs = [Path(args.mail_path)]
        else:
            print("Auto-detecting Apple Mail directories...")
            messages_dirs = self._find_mail_directories()
        if not messages_dirs:
            print("No Apple Mail directories found!")
            print("Please specify --mail-path manually")
            return []
        print(f"Found {len(messages_dirs)} mail directories")
        # Create reader
        reader = EmlxReader(include_html=args.include_html)
        # Process each directory
        all_documents = []
        total_processed = 0
        for i, messages_dir in enumerate(messages_dirs):
            print(f"\nProcessing directory {i + 1}/{len(messages_dirs)}: {messages_dir}")
            try:
                # Count emlx files
                emlx_files = list(messages_dir.glob("*.emlx"))
                print(f"Found {len(emlx_files)} email files")
                # Apply max_items limit per directory
                max_per_dir = -1  # Default to process all
                if args.max_items > 0:
                    remaining = args.max_items - total_processed
                    if remaining <= 0:
                        break
                    max_per_dir = remaining
                # If args.max_items == -1, max_per_dir stays -1 (process all)
                # Load emails - fix the parameter passing
                documents = reader.load_data(
                    input_dir=str(messages_dir),
                    max_count=max_per_dir,
                )
                if documents:
                    all_documents.extend(documents)
                    total_processed += len(documents)
                    print(f"Processed {len(documents)} emails from this directory")
            except Exception as e:
                print(f"Error processing {messages_dir}: {e}")
                continue
        if not all_documents:
            print("No emails found to process!")
            return []
        print(f"\nTotal emails processed: {len(all_documents)}")
        print("now starting to split into text chunks ... take some time")
        # Convert to text chunks
        # Email reader uses chunk_overlap=25 as in original
        all_texts = create_text_chunks(
            all_documents, chunk_size=args.chunk_size, chunk_overlap=args.chunk_overlap
        )
        return all_texts
 if __name__ == "__main__":
    import asyncio
    # Check platform
    if sys.platform != "darwin":
        print("\n⚠️  Warning: This example is designed for macOS (Apple Mail)")
        print("   Windows/Linux support coming soon!\n")
    # Example queries for email RAG
    print("\n📧 Email RAG Example")
    print("=" * 50)
    print("\nExample queries you can try:")
    print("- 'What did my boss say about deadlines?'")
    print("- 'Find emails about travel expenses'")
    print("- 'Show me emails from last month about the project'")
    print("- 'What food did I order from DoorDash?'")
    print("\nNote: You may need to grant Full Disk Access to your terminal\n")
    rag = EmailRAG()
    asyncio.run(rag.run())
--- a/examples/history_data/init.py
+++ b/examples/history_data/init.py
@@ -1,3 +1,3 @@
 from .history import ChromeHistoryReader
-__all__ = ['ChromeHistoryReader'] 
+__all__ = ["ChromeHistoryReader"]
--- a/examples/history_data/history.py
+++ b/examples/history_data/history.py
@@ -1,10 +1,12 @@
 import sqlite3
 import os
 import sqlite3
 from pathlib import Path
-from typing import List, Any
+from typing import Any
 from llama_index.core import Document
 from llama_index.core.readers.base import BaseReader
 class ChromeHistoryReader(BaseReader):
    """
    Chrome browser history reader that extracts browsing data from SQLite database.
@@ -17,7 +19,7 @@ class ChromeHistoryReader(BaseReader):
        """Initialize."""
        pass
-    def load_data(self, input_dir: str = None, **load_kwargs: Any) -> List[Document]:
+    def load_data(self, input_dir: str | None = None, **load_kwargs: Any) -> list[Document]:
        """
        Load Chrome history data from the default Chrome profile location.
@@ -27,13 +29,15 @@ class ChromeHistoryReader(BaseReader):
                max_count (int): Maximum amount of history entries to read.
                chrome_profile_path (str): Custom path to Chrome profile directory.
        """
-        docs: List[Document] = []
+        docs: list[Document] = []
-        max_count = load_kwargs.get('max_count', 1000)
+        max_count = load_kwargs.get("max_count", 1000)
-        chrome_profile_path = load_kwargs.get('chrome_profile_path', None)
+        chrome_profile_path = load_kwargs.get("chrome_profile_path", None)
        # Default Chrome profile path on macOS
        if chrome_profile_path is None:
-            chrome_profile_path = os.path.expanduser("~/Library/Application Support/Google/Chrome/Default")
+            chrome_profile_path = os.path.expanduser(
                "~/Library/Application Support/Google/Chrome/Default"
            )
        history_db_path = os.path.join(chrome_profile_path, "History")
@@ -74,22 +78,17 @@ class ChromeHistoryReader(BaseReader):
                # Create document content with metadata embedded in text
                doc_content = f"""
-[BROWSING HISTORY METADATA]
+[Title]: {title}
-URL: {url}
+[URL of the page]: {url}
-Title: {title}
+[Last visited time]: {last_visit}
-Last Visit: {last_visit}
+[Visit times]: {visit_count}
-Visit Count: {visit_count}
+[Typed times]: {typed_count}
 Typed Count: {typed_count}
 Hidden: {hidden}
 [END METADATA]
 Title: {title}
 URL: {url}
 Last visited: {last_visit}
 """
                # Create document with embedded metadata
-                doc = Document(text=doc_content, metadata={})
+                doc = Document(text=doc_content, metadata={"title": title[0:150]})
                # if len(title) > 150:
                #     print(f"Title is too long: {title}")
                docs.append(doc)
                count += 1
@@ -98,12 +97,17 @@ Last visited: {last_visit}
        except Exception as e:
            print(f"Error reading Chrome history: {e}")
            # add you may need to close your browser to make the database file available
            # also highlight in red
            print(
                "\033[91mYou may need to close your browser to make the database file available\033[0m"
            )
            return docs
        return docs
    @staticmethod
-    def find_chrome_profiles() -> List[Path]:
+    def find_chrome_profiles() -> list[Path]:
        """
        Find all Chrome profile directories.
@@ -129,7 +133,9 @@ Last visited: {last_visit}
        return profile_dirs
    @staticmethod
-    def export_history_to_file(output_file: str = "chrome_history_export.txt", max_count: int = 1000):
+    def export_history_to_file(
        output_file: str = "chrome_history_export.txt", max_count: int = 1000
    ):
        """
        Export Chrome history to a text file using the same SQL query format.
@@ -137,7 +143,9 @@ Last visited: {last_visit}
            output_file: Path to the output file
            max_count: Maximum number of entries to export
        """
-        chrome_profile_path = os.path.expanduser("~/Library/Application Support/Google/Chrome/Default")
+        chrome_profile_path = os.path.expanduser(
            "~/Library/Application Support/Google/Chrome/Default"
        )
        history_db_path = os.path.join(chrome_profile_path, "History")
        if not os.path.exists(history_db_path):
@@ -164,10 +172,12 @@ Last visited: {last_visit}
            cursor.execute(query, (max_count,))
            rows = cursor.fetchall()
-            with open(output_file, 'w', encoding='utf-8') as f:
+            with open(output_file, "w", encoding="utf-8") as f:
                for row in rows:
                    last_visit, url, title, visit_count, typed_count, hidden = row
-                    f.write(f"{last_visit}\t{url}\t{title}\t{visit_count}\t{typed_count}\t{hidden}\n")
+                    f.write(
                        f"{last_visit}\t{url}\t{title}\t{visit_count}\t{typed_count}\t{hidden}\n"
                    )
            conn.close()
            print(f"Exported {len(rows)} history entries to {output_file}")
--- a/examples/history_data/wechat_history.py
+++ b/examples/history_data/wechat_history.py
@@ -2,13 +2,14 @@ import json
 import os
 import re
 import subprocess
 import sys
 import time
 from datetime import datetime
 from pathlib import Path
-from typing import List, Any, Dict, Optional
+from typing import Any
 from llama_index.core import Document
 from llama_index.core.readers.base import BaseReader
-from datetime import datetime
+
 class WeChatHistoryReader(BaseReader):
    """
@@ -43,10 +44,16 @@ class WeChatHistoryReader(BaseReader):
            wechattweak_path = self.wechat_exporter_dir / "wechattweak-cli"
            if not wechattweak_path.exists():
                print("Downloading WeChatTweak CLI...")
-                subprocess.run([
+                subprocess.run(
-                    "curl", "-L", "-o", str(wechattweak_path),
+                    [
-                    "https://github.com/JettChenT/WeChatTweak-CLI/releases/latest/download/wechattweak-cli"
+                        "curl",
-                ], check=True)
+                        "-L",
                        "-o",
                        str(wechattweak_path),
                        "https://github.com/JettChenT/WeChatTweak-CLI/releases/latest/download/wechattweak-cli",
                    ],
                    check=True,
                )
            # Make executable
            wechattweak_path.chmod(0o755)
@@ -73,16 +80,16 @@ class WeChatHistoryReader(BaseReader):
    def check_api_available(self) -> bool:
        """Check if WeChatTweak API is available."""
        try:
-            result = subprocess.run([
+            result = subprocess.run(
-                "curl", "-s", "http://localhost:48065/wechat/allcontacts"
+                ["curl", "-s", "http://localhost:48065/wechat/allcontacts"],
-            ], capture_output=True, text=True, timeout=5)
+                capture_output=True,
                text=True,
                timeout=5,
            )
            return result.returncode == 0 and result.stdout.strip()
        except Exception:
            return False
    def _extract_readable_text(self, content: str) -> str:
        """
        Extract readable text from message content, removing XML and system messages.
@@ -100,14 +107,14 @@ class WeChatHistoryReader(BaseReader):
        if isinstance(content, dict):
            # Extract text from dictionary structure
            text_parts = []
-            if 'title' in content:
+            if "title" in content:
-                text_parts.append(str(content['title']))
+                text_parts.append(str(content["title"]))
-            if 'quoted' in content:
+            if "quoted" in content:
-                text_parts.append(str(content['quoted']))
+                text_parts.append(str(content["quoted"]))
-            if 'content' in content:
+            if "content" in content:
-                text_parts.append(str(content['content']))
+                text_parts.append(str(content["content"]))
-            if 'text' in content:
+            if "text" in content:
-                text_parts.append(str(content['text']))
+                text_parts.append(str(content["text"]))
            if text_parts:
                return " | ".join(text_parts)
@@ -120,11 +127,11 @@ class WeChatHistoryReader(BaseReader):
            return ""
        # Remove common prefixes like "wxid_xxx:\n"
-        clean_content = re.sub(r'^wxid_[^:]+:\s*', '', content)
+        clean_content = re.sub(r"^wxid_[^:]+:\s*", "", content)
-        clean_content = re.sub(r'^[^:]+:\s*', '', clean_content)
+        clean_content = re.sub(r"^[^:]+:\s*", "", clean_content)
        # If it's just XML or system message, return empty
-        if clean_content.strip().startswith('<') or 'recalled a message' in clean_content:
+        if clean_content.strip().startswith("<") or "recalled a message" in clean_content:
            return ""
        return clean_content.strip()
@@ -145,9 +152,9 @@ class WeChatHistoryReader(BaseReader):
        # Handle dictionary content
        if isinstance(content, dict):
            # Check if dict has any readable text fields
-            text_fields = ['title', 'quoted', 'content', 'text']
+            text_fields = ["title", "quoted", "content", "text"]
            for field in text_fields:
-                if field in content and content[field]:
+                if content.get(field):
                    return True
            return False
@@ -156,42 +163,47 @@ class WeChatHistoryReader(BaseReader):
            return False
        # Skip image messages (contain XML with img tags)
-        if '<img' in content and 'cdnurl' in content:
+        if "<img" in content and "cdnurl" in content:
            return False
        # Skip emoji messages (contain emoji XML tags)
-        if '<emoji' in content and 'productid' in content:
+        if "<emoji" in content and "productid" in content:
            return False
        # Skip voice messages
-        if '<voice' in content:
+        if "<voice" in content:
            return False
        # Skip video messages
-        if '<video' in content:
+        if "<video" in content:
            return False
        # Skip file messages
-        if '<appmsg' in content and 'appid' in content:
+        if "<appmsg" in content and "appid" in content:
            return False
        # Skip system messages (like "recalled a message")
-        if 'recalled a message' in content:
+        if "recalled a message" in content:
            return False
        # Check if there's actual readable text (not just XML or system messages)
        # Remove common prefixes like "wxid_xxx:\n" and check for actual content
-        clean_content = re.sub(r'^wxid_[^:]+:\s*', '', content)
+        clean_content = re.sub(r"^wxid_[^:]+:\s*", "", content)
-        clean_content = re.sub(r'^[^:]+:\s*', '', clean_content)
+        clean_content = re.sub(r"^[^:]+:\s*", "", clean_content)
        # If after cleaning we have meaningful text, consider it readable
-        if len(clean_content.strip()) > 0 and not clean_content.strip().startswith('<'):
+        if len(clean_content.strip()) > 0 and not clean_content.strip().startswith("<"):
            return True
        return False
-    def _concatenate_messages(self, messages: List[Dict], max_length: int = 128, 
+    def _concatenate_messages(
-                             time_window_minutes: int = 30, overlap_messages: int = 0) -> List[Dict]:
+        self,
        messages: list[dict],
        max_length: int = 128,
        time_window_minutes: int = 30,
        overlap_messages: int = 0,
    ) -> list[dict]:
        """
        Concatenate messages based on length and time rules.
@@ -214,12 +226,12 @@ class WeChatHistoryReader(BaseReader):
        for message in messages:
            # Extract message info
-            content = message.get('content', '')
+            content = message.get("content", "")
-            message_text = message.get('message', '')
+            message_text = message.get("message", "")
-            create_time = message.get('createTime', 0)
+            create_time = message.get("createTime", 0)
-            from_user = message.get('fromUser', '')
+            message.get("fromUser", "")
-            to_user = message.get('toUser', '')
+            message.get("toUser", "")
-            is_sent_from_self = message.get('isSentFromSelf', False)
+            message.get("isSentFromSelf", False)
            # Extract readable text
            readable_text = self._extract_readable_text(content)
@@ -236,16 +248,24 @@ class WeChatHistoryReader(BaseReader):
                if time_diff_minutes > time_window_minutes:
                    # Time gap too large, start new group
                    if current_group:
-                        concatenated_groups.append({
+                        concatenated_groups.append(
-                            'messages': current_group,
+                            {
-                            'total_length': current_length,
+                                "messages": current_group,
-                            'start_time': current_group[0].get('createTime', 0),
+                                "total_length": current_length,
-                            'end_time': current_group[-1].get('createTime', 0)
+                                "start_time": current_group[0].get("createTime", 0),
-                        })
+                                "end_time": current_group[-1].get("createTime", 0),
                            }
                        )
                        # Keep last few messages for overlap
                        if overlap_messages > 0 and len(current_group) > overlap_messages:
                            current_group = current_group[-overlap_messages:]
-                            current_length = sum(len(self._extract_readable_text(msg.get('content', '')) or msg.get('message', '')) for msg in current_group)
+                            current_length = sum(
                                len(
                                    self._extract_readable_text(msg.get("content", ""))
                                    or msg.get("message", "")
                                )
                                for msg in current_group
                            )
                        else:
                            current_group = []
                            current_length = 0
@@ -254,16 +274,24 @@ class WeChatHistoryReader(BaseReader):
            message_length = len(readable_text)
            if max_length != -1 and current_length + message_length > max_length and current_group:
                # Current group would exceed max length, save it and start new
-                concatenated_groups.append({
+                concatenated_groups.append(
-                    'messages': current_group,
+                    {
-                    'total_length': current_length,
+                        "messages": current_group,
-                    'start_time': current_group[0].get('createTime', 0),
+                        "total_length": current_length,
-                    'end_time': current_group[-1].get('createTime', 0)
+                        "start_time": current_group[0].get("createTime", 0),
-                })
+                        "end_time": current_group[-1].get("createTime", 0),
                    }
                )
                # Keep last few messages for overlap
                if overlap_messages > 0 and len(current_group) > overlap_messages:
                    current_group = current_group[-overlap_messages:]
-                    current_length = sum(len(self._extract_readable_text(msg.get('content', '')) or msg.get('message', '')) for msg in current_group)
+                    current_length = sum(
                        len(
                            self._extract_readable_text(msg.get("content", ""))
                            or msg.get("message", "")
                        )
                        for msg in current_group
                    )
                else:
                    current_group = []
                    current_length = 0
@@ -275,16 +303,18 @@ class WeChatHistoryReader(BaseReader):
        # Add the last group if it exists
        if current_group:
-            concatenated_groups.append({
+            concatenated_groups.append(
-                'messages': current_group,
+                {
-                'total_length': current_length,
+                    "messages": current_group,
-                'start_time': current_group[0].get('createTime', 0),
+                    "total_length": current_length,
-                'end_time': current_group[-1].get('createTime', 0)
+                    "start_time": current_group[0].get("createTime", 0),
-            })
+                    "end_time": current_group[-1].get("createTime", 0),
                }
            )
        return concatenated_groups
-    def _create_concatenated_content(self, message_group: Dict, contact_name: str) -> str:
+    def _create_concatenated_content(self, message_group: dict, contact_name: str) -> str:
        """
        Create concatenated content from a group of messages.
@@ -295,16 +325,16 @@ class WeChatHistoryReader(BaseReader):
        Returns:
            Formatted concatenated content
        """
-        messages = message_group['messages']
+        messages = message_group["messages"]
-        start_time = message_group['start_time']
+        start_time = message_group["start_time"]
-        end_time = message_group['end_time']
+        end_time = message_group["end_time"]
        # Format timestamps
        if start_time:
            try:
                start_timestamp = datetime.fromtimestamp(start_time)
-                start_time_str = start_timestamp.strftime('%Y-%m-%d %H:%M:%S')
+                start_time_str = start_timestamp.strftime("%Y-%m-%d %H:%M:%S")
-            except:
+            except (ValueError, OSError):
                start_time_str = str(start_time)
        else:
            start_time_str = "Unknown"
@@ -312,8 +342,8 @@ class WeChatHistoryReader(BaseReader):
        if end_time:
            try:
                end_timestamp = datetime.fromtimestamp(end_time)
-                end_time_str = end_timestamp.strftime('%Y-%m-%d %H:%M:%S')
+                end_time_str = end_timestamp.strftime("%Y-%m-%d %H:%M:%S")
-            except:
+            except (ValueError, OSError):
                end_time_str = str(end_time)
        else:
            end_time_str = "Unknown"
@@ -321,10 +351,10 @@ class WeChatHistoryReader(BaseReader):
        # Build concatenated message content
        message_parts = []
        for message in messages:
-            content = message.get('content', '')
+            content = message.get("content", "")
-            message_text = message.get('message', '')
+            message_text = message.get("message", "")
-            create_time = message.get('createTime', 0)
+            create_time = message.get("createTime", 0)
-            is_sent_from_self = message.get('isSentFromSelf', False)
+            is_sent_from_self = message.get("isSentFromSelf", False)
            # Extract readable text
            readable_text = self._extract_readable_text(content)
@@ -335,14 +365,15 @@ class WeChatHistoryReader(BaseReader):
            if create_time:
                try:
                    timestamp = datetime.fromtimestamp(create_time)
-                    time_str = timestamp.strftime('%H:%M:%S')
+                    # change to YYYY-MM-DD HH:MM:SS
-                except:
+                    time_str = timestamp.strftime("%Y-%m-%d %H:%M:%S")
                except (ValueError, OSError):
                    time_str = str(create_time)
            else:
                time_str = "Unknown"
-            sender = "Me" if is_sent_from_self else "Contact"
+            sender = "[Me]" if is_sent_from_self else "[Contact]"
-            message_parts.append(f"[{time_str}] {sender}: {readable_text}")
+            message_parts.append(f"({time_str}) {sender}: {readable_text}")
        concatenated_text = "\n".join(message_parts)
@@ -350,19 +381,17 @@ class WeChatHistoryReader(BaseReader):
        doc_content = f"""
 Contact: {contact_name}
 Time Range: {start_time_str} - {end_time_str}
-Messages ({len(messages)} messages, {message_group['total_length']} chars):
+Messages ({len(messages)} messages, {message_group["total_length"]} chars):
 {concatenated_text}
 """
-        
+        # TODO @yichuan give better format and rich info here!
        doc_content = f"""
 Contact: {contact_name}
 {concatenated_text}
 """
-        return doc_content
+        return doc_content, contact_name
-    def load_data(self, input_dir: str = None, **load_kwargs: Any) -> List[Document]:
+    def load_data(self, input_dir: str | None = None, **load_kwargs: Any) -> list[Document]:
        """
        Load WeChat chat history data from exported JSON files.
@@ -377,13 +406,13 @@ Contact: {contact_name}
                time_window_minutes (int): Time window in minutes to group messages together (default: 30).
                overlap_messages (int): Number of messages to overlap between consecutive groups (default: 2).
        """
-        docs: List[Document] = []
+        docs: list[Document] = []
-        max_count = load_kwargs.get('max_count', 1000)
+        max_count = load_kwargs.get("max_count", 1000)
-        wechat_export_dir = load_kwargs.get('wechat_export_dir', None)
+        wechat_export_dir = load_kwargs.get("wechat_export_dir", None)
-        include_non_text = load_kwargs.get('include_non_text', False)
+        include_non_text = load_kwargs.get("include_non_text", False)
-        concatenate_messages = load_kwargs.get('concatenate_messages', False)
+        concatenate_messages = load_kwargs.get("concatenate_messages", False)
-        max_length = load_kwargs.get('max_length', 1000)
+        max_length = load_kwargs.get("max_length", 1000)
-        time_window_minutes = load_kwargs.get('time_window_minutes', 30)
+        time_window_minutes = load_kwargs.get("time_window_minutes", 30)
        # Default WeChat export path
        if wechat_export_dir is None:
@@ -404,7 +433,7 @@ Contact: {contact_name}
                    break
                try:
-                    with open(json_file, 'r', encoding='utf-8') as f:
+                    with open(json_file, encoding="utf-8") as f:
                        chat_data = json.load(f)
                    # Extract contact name from filename
@@ -415,7 +444,7 @@ Contact: {contact_name}
                        readable_messages = []
                        for message in chat_data:
                            try:
-                                content = message.get('content', '')
+                                content = message.get("content", "")
                                if not include_non_text and not self._is_text_message(content):
                                    continue
@@ -431,9 +460,9 @@ Contact: {contact_name}
                        # Concatenate messages based on rules
                        message_groups = self._concatenate_messages(
                            readable_messages,
-                            max_length=-1, 
+                            max_length=max_length,
-                            time_window_minutes=-1,
+                            time_window_minutes=time_window_minutes,
-                            overlap_messages=0  # Keep 2 messages overlap between groups
+                            overlap_messages=0,  # No overlap between groups
                        )
                        # Create documents from concatenated groups
@@ -441,12 +470,19 @@ Contact: {contact_name}
                            if count >= max_count and max_count > 0:
                                break
-                            doc_content = self._create_concatenated_content(message_group, contact_name)
+                            doc_content, contact_name = self._create_concatenated_content(
-                            doc = Document(text=doc_content, metadata={})
+                                message_group, contact_name
                            )
                            doc = Document(
                                text=doc_content,
                                metadata={"contact_name": contact_name},
                            )
                            docs.append(doc)
                            count += 1
-                        print(f"Created {len(message_groups)} concatenated message groups for {contact_name}")
+                        print(
                            f"Created {len(message_groups)} concatenated message groups for {contact_name}"
                        )
                    else:
                        # Original single-message processing
@@ -455,12 +491,12 @@ Contact: {contact_name}
                                break
                            # Extract message information
-                            from_user = message.get('fromUser', '')
+                            message.get("fromUser", "")
-                            to_user = message.get('toUser', '')
+                            message.get("toUser", "")
-                            content = message.get('content', '')
+                            content = message.get("content", "")
-                            message_text = message.get('message', '')
+                            message_text = message.get("message", "")
-                            create_time = message.get('createTime', 0)
+                            create_time = message.get("createTime", 0)
-                            is_sent_from_self = message.get('isSentFromSelf', False)
+                            is_sent_from_self = message.get("isSentFromSelf", False)
                            # Handle content that might be dict or string
                            try:
@@ -481,8 +517,8 @@ Contact: {contact_name}
                            if create_time:
                                try:
                                    timestamp = datetime.fromtimestamp(create_time)
-                                    time_str = timestamp.strftime('%Y-%m-%d %H:%M:%S')
+                                    time_str = timestamp.strftime("%Y-%m-%d %H:%M:%S")
-                                except:
+                                except (ValueError, OSError):
                                    time_str = str(create_time)
                            else:
                                time_str = "Unknown"
@@ -496,7 +532,9 @@ Message: {readable_text if readable_text else message_text}
 """
                            # Create document with embedded metadata
-                            doc = Document(text=doc_content, metadata={})
+                            doc = Document(
                                text=doc_content, metadata={"contact_name": contact_name}
                            )
                            docs.append(doc)
                            count += 1
@@ -513,7 +551,7 @@ Message: {readable_text if readable_text else message_text}
        return docs
    @staticmethod
-    def find_wechat_export_dirs() -> List[Path]:
+    def find_wechat_export_dirs() -> list[Path]:
        """
        Find all WeChat export directories.
@@ -524,10 +562,10 @@ Message: {readable_text if readable_text else message_text}
        # Look for common export directory names
        possible_dirs = [
            Path("./wechat_export_test"),
            Path("./wechat_export"),
            Path("./wechat_export_direct"),
            Path("./wechat_chat_history"),
-            Path("./chat_export")
+            Path("./chat_export"),
        ]
        for export_dir in possible_dirs:
@@ -535,13 +573,20 @@ Message: {readable_text if readable_text else message_text}
                json_files = list(export_dir.glob("*.json"))
                if json_files:
                    export_dirs.append(export_dir)
-                    print(f"Found WeChat export directory: {export_dir} with {len(json_files)} files")
+                    print(
                        f"Found WeChat export directory: {export_dir} with {len(json_files)} files"
                    )
        print(f"Found {len(export_dirs)} WeChat export directories")
        return export_dirs
    @staticmethod
-    def export_chat_to_file(output_file: str = "wechat_chat_export.txt", max_count: int = 1000, export_dir: str = None, include_non_text: bool = False):
+    def export_chat_to_file(
        output_file: str = "wechat_chat_export.txt",
        max_count: int = 1000,
        export_dir: str | None = None,
        include_non_text: bool = False,
    ):
        """
        Export WeChat chat history to a text file.
@@ -561,14 +606,14 @@ Message: {readable_text if readable_text else message_text}
        try:
            json_files = list(Path(export_dir).glob("*.json"))
-            with open(output_file, 'w', encoding='utf-8') as f:
+            with open(output_file, "w", encoding="utf-8") as f:
                count = 0
                for json_file in json_files:
                    if count >= max_count and max_count > 0:
                        break
                    try:
-                        with open(json_file, 'r', encoding='utf-8') as json_f:
+                        with open(json_file, encoding="utf-8") as json_f:
                            chat_data = json.load(json_f)
                        contact_name = json_file.stem
@@ -578,10 +623,10 @@ Message: {readable_text if readable_text else message_text}
                            if count >= max_count and max_count > 0:
                                break
-                            from_user = message.get('fromUser', '')
+                            from_user = message.get("fromUser", "")
-                            content = message.get('content', '')
+                            content = message.get("content", "")
-                            message_text = message.get('message', '')
+                            message_text = message.get("message", "")
-                            create_time = message.get('createTime', 0)
+                            create_time = message.get("createTime", 0)
                            # Skip non-text messages unless requested
                            if not include_non_text:
@@ -596,8 +641,8 @@ Message: {readable_text if readable_text else message_text}
                            if create_time:
                                try:
                                    timestamp = datetime.fromtimestamp(create_time)
-                                    time_str = timestamp.strftime('%Y-%m-%d %H:%M:%S')
+                                    time_str = timestamp.strftime("%Y-%m-%d %H:%M:%S")
-                                except:
+                                except (ValueError, OSError):
                                    time_str = str(create_time)
                            else:
                                time_str = "Unknown"
@@ -614,7 +659,7 @@ Message: {readable_text if readable_text else message_text}
        except Exception as e:
            print(f"Error exporting WeChat chat history: {e}")
-    def export_wechat_chat_history(self, export_dir: str = "./wechat_export_direct") -> Optional[Path]:
+    def export_wechat_chat_history(self, export_dir: str = "./wechat_export_direct") -> Path | None:
        """
        Export WeChat chat history using wechat-exporter tool.
@@ -643,16 +688,21 @@ Message: {readable_text if readable_text else message_text}
            requirements_file = self.wechat_exporter_dir / "requirements.txt"
            if requirements_file.exists():
                print("Installing wechat-exporter requirements...")
-                subprocess.run([
+                subprocess.run(["uv", "pip", "install", "-r", str(requirements_file)], check=True)
                    "uv", "pip", "install", "-r", str(requirements_file)
                ], check=True)
            # Run the export command
            print("Running wechat-exporter...")
-            result = subprocess.run([
+            result = subprocess.run(
-                sys.executable, str(self.wechat_exporter_dir / "main.py"), 
+                [
-                "export-all", str(export_path)
+                    sys.executable,
-            ], capture_output=True, text=True, check=True)
+                    str(self.wechat_exporter_dir / "main.py"),
                    "export-all",
                    str(export_path),
                ],
                capture_output=True,
                text=True,
                check=True,
            )
            print("Export command output:")
            print(result.stdout)
@@ -663,7 +713,9 @@ Message: {readable_text if readable_text else message_text}
            # Check if export was successful
            if export_path.exists() and any(export_path.glob("*.json")):
                json_files = list(export_path.glob("*.json"))
-                print(f"Successfully exported {len(json_files)} chat history files to {export_path}")
+                print(
                    f"Successfully exported {len(json_files)} chat history files to {export_path}"
                )
                return export_path
            else:
                print("Export completed but no JSON files found")
@@ -679,7 +731,7 @@ Message: {readable_text if readable_text else message_text}
            print("Please ensure WeChat is running and WeChatTweak is installed.")
            return None
-    def find_or_export_wechat_data(self, export_dir: str = "./wechat_export_direct") -> List[Path]:
+    def find_or_export_wechat_data(self, export_dir: str = "./wechat_export_direct") -> list[Path]:
        """
        Find existing WeChat exports or create new ones.
@@ -698,7 +750,7 @@ Message: {readable_text if readable_text else message_text}
            Path("./wechat_export"),
            Path("./wechat_export_direct"),
            Path("./wechat_chat_history"),
-            Path("./chat_export")
+            Path("./chat_export"),
        ]
        for export_dir_path in possible_export_dirs:
@@ -715,6 +767,8 @@ Message: {readable_text if readable_text else message_text}
            if exported_path:
                export_dirs = [exported_path]
            else:
-                print("Failed to export WeChat data. Please ensure WeChat is running and WeChatTweak is installed.")
+                print(
                    "Failed to export WeChat data. Please ensure WeChat is running and WeChatTweak is installed."
                )
        return export_dirs
--- a/apps/wechat_rag.py
+++ b/apps/wechat_rag.py
@@ -0,0 +1,189 @@
 """
 WeChat History RAG example using the unified interface.
 Supports WeChat chat history export and search.
 """
 import subprocess
 import sys
 from pathlib import Path
 # Add parent directory to path for imports
 sys.path.insert(0, str(Path(__file__).parent))
 from base_rag_example import BaseRAGExample
 from .history_data.wechat_history import WeChatHistoryReader
 class WeChatRAG(BaseRAGExample):
    """RAG example for WeChat chat history."""
    def __init__(self):
        # Set default values BEFORE calling super().__init__
        self.max_items_default = -1  # Match original default
        self.embedding_model_default = (
            "sentence-transformers/all-MiniLM-L6-v2"  # Fast 384-dim model
        )
        super().__init__(
            name="WeChat History",
            description="Process and query WeChat chat history with LEANN",
            default_index_name="wechat_history_magic_test_11Debug_new",
        )
    def _add_specific_arguments(self, parser):
        """Add WeChat-specific arguments."""
        wechat_group = parser.add_argument_group("WeChat Parameters")
        wechat_group.add_argument(
            "--export-dir",
            type=str,
            default="./wechat_export",
            help="Directory to store WeChat exports (default: ./wechat_export)",
        )
        wechat_group.add_argument(
            "--force-export",
            action="store_true",
            help="Force re-export of WeChat data even if exports exist",
        )
        wechat_group.add_argument(
            "--chunk-size", type=int, default=192, help="Text chunk size (default: 192)"
        )
        wechat_group.add_argument(
            "--chunk-overlap", type=int, default=64, help="Text chunk overlap (default: 64)"
        )
    def _export_wechat_data(self, export_dir: Path) -> bool:
        """Export WeChat data using wechattweak-cli."""
        print("Exporting WeChat data...")
        # Check if WeChat is running
        try:
            result = subprocess.run(["pgrep", "WeChat"], capture_output=True, text=True)
            if result.returncode != 0:
                print("WeChat is not running. Please start WeChat first.")
                return False
        except Exception:
            pass  # pgrep might not be available on all systems
        # Create export directory
        export_dir.mkdir(parents=True, exist_ok=True)
        # Run export command
        cmd = ["packages/wechat-exporter/wechattweak-cli", "export", str(export_dir)]
        try:
            print(f"Running: {' '.join(cmd)}")
            result = subprocess.run(cmd, capture_output=True, text=True)
            if result.returncode == 0:
                print("WeChat data exported successfully!")
                return True
            else:
                print(f"Export failed: {result.stderr}")
                return False
        except FileNotFoundError:
            print("\nError: wechattweak-cli not found!")
            print("Please install it first:")
            print("  sudo packages/wechat-exporter/wechattweak-cli install")
            return False
        except Exception as e:
            print(f"Export error: {e}")
            return False
    async def load_data(self, args) -> list[str]:
        """Load WeChat history and convert to text chunks."""
        # Initialize WeChat reader with export capabilities
        reader = WeChatHistoryReader()
        # Find existing exports or create new ones using the centralized method
        export_dirs = reader.find_or_export_wechat_data(args.export_dir)
        if not export_dirs:
            print("Failed to find or export WeChat data. Trying to find any existing exports...")
            # Try to find any existing exports in common locations
            export_dirs = reader.find_wechat_export_dirs()
            if not export_dirs:
                print("No WeChat data found. Please ensure WeChat exports exist.")
                return []
        # Load documents from all found export directories
        all_documents = []
        total_processed = 0
        for i, export_dir in enumerate(export_dirs):
            print(f"\nProcessing WeChat export {i + 1}/{len(export_dirs)}: {export_dir}")
            try:
                # Apply max_items limit per export
                max_per_export = -1
                if args.max_items > 0:
                    remaining = args.max_items - total_processed
                    if remaining <= 0:
                        break
                    max_per_export = remaining
                documents = reader.load_data(
                    wechat_export_dir=str(export_dir),
                    max_count=max_per_export,
                    concatenate_messages=True,  # Enable message concatenation for better context
                )
                if documents:
                    print(f"Loaded {len(documents)} chat documents from {export_dir}")
                    all_documents.extend(documents)
                    total_processed += len(documents)
                else:
                    print(f"No documents loaded from {export_dir}")
            except Exception as e:
                print(f"Error processing {export_dir}: {e}")
                continue
        if not all_documents:
            print("No documents loaded from any source. Exiting.")
            return []
        print(f"\nTotal loaded {len(all_documents)} chat documents from {len(export_dirs)} exports")
        print("now starting to split into text chunks ... take some time")
        # Convert to text chunks with contact information
        all_texts = []
        for doc in all_documents:
            # Split the document into chunks
            from llama_index.core.node_parser import SentenceSplitter
            text_splitter = SentenceSplitter(
                chunk_size=args.chunk_size, chunk_overlap=args.chunk_overlap
            )
            nodes = text_splitter.get_nodes_from_documents([doc])
            for node in nodes:
                # Add contact information to each chunk
                contact_name = doc.metadata.get("contact_name", "Unknown")
                text = f"[Contact] means the message is from: {contact_name}\n" + node.get_content()
                all_texts.append(text)
        print(f"Created {len(all_texts)} text chunks from {len(all_documents)} documents")
        return all_texts
 if __name__ == "__main__":
    import asyncio
    # Check platform
    if sys.platform != "darwin":
        print("\n⚠️  Warning: WeChat export is only supported on macOS")
        print("   You can still query existing exports on other platforms\n")
    # Example queries for WeChat RAG
    print("\n💬 WeChat History RAG Example")
    print("=" * 50)
    print("\nExample queries you can try:")
    print("- 'Show me conversations about travel plans'")
    print("- 'Find group chats about weekend activities'")
    print("- '我想买魔术师约翰逊的球衣,给我一些对应聊天记录?'")
    print("- 'What did we discuss about the project last month?'")
    print("\nNote: WeChat must be running for export to work\n")
    rag = WeChatRAG()
    asyncio.run(rag.run())
--- a/assets/claude_code_leann.png
+++ b/assets/claude_code_leann.png
--- a/assets/mcp_leann.png
+++ b/assets/mcp_leann.png
--- a/test/sanity_checks/README.md
+++ b/test/sanity_checks/README.md
--- a/test/sanity_checks/benchmark_embeddings.py
+++ b/test/sanity_checks/benchmark_embeddings.py
@@ -1,29 +1,32 @@
 import time
-import numpy as np
+
 import matplotlib.pyplot as plt
 import torch
 from sentence_transformers import SentenceTransformer
 import mlx.core as mx
 import numpy as np
 import torch
 from mlx_lm import load
 from sentence_transformers import SentenceTransformer
 # --- Configuration ---
 MODEL_NAME_TORCH = "Qwen/Qwen3-Embedding-0.6B"
 MODEL_NAME_MLX = "mlx-community/Qwen3-Embedding-0.6B-4bit-DWQ"
 BATCH_SIZES = [1, 8, 16, 32, 64, 128]
 NUM_RUNS = 10  # Number of runs to average for each batch size
-WARMUP_RUNS = 2 # Number of warm-up runs
+WARMUP_RUNS = 2  # Number of warm-up runs
 # --- Generate Dummy Data ---
 DUMMY_SENTENCES = ["This is a test sentence for benchmarking." * 5] * max(BATCH_SIZES)
 # --- Benchmark Functions ---b
 def benchmark_torch(model, sentences):
    start_time = time.time()
    model.encode(sentences, convert_to_numpy=True)
    end_time = time.time()
    return (end_time - start_time) * 1000  # Return time in ms
 def benchmark_mlx(model, tokenizer, sentences):
    start_time = time.time()
@@ -63,6 +66,7 @@ def benchmark_mlx(model, tokenizer, sentences):
    end_time = time.time()
    return (end_time - start_time) * 1000  # Return time in ms
 # --- Main Execution ---
 def main():
    print("--- Initializing Models ---")
@@ -98,7 +102,9 @@ def main():
        results_torch.append(np.mean(torch_times))
        # Benchmark MLX
-        mlx_times = [benchmark_mlx(model_mlx, tokenizer_mlx, sentences_batch) for _ in range(NUM_RUNS)]
+        mlx_times = [
            benchmark_mlx(model_mlx, tokenizer_mlx, sentences_batch) for _ in range(NUM_RUNS)
        ]
        results_mlx.append(np.mean(mlx_times))
    print("\n--- Benchmark Results (Average time per batch in ms) ---")
@@ -109,10 +115,16 @@ def main():
    # --- Plotting ---
    print("\n--- Generating Plot ---")
    plt.figure(figsize=(10, 6))
-    plt.plot(BATCH_SIZES, results_torch, marker='o', linestyle='-', label=f'PyTorch ({device})')
+    plt.plot(
-    plt.plot(BATCH_SIZES, results_mlx, marker='s', linestyle='-', label='MLX')
+        BATCH_SIZES,
        results_torch,
        marker="o",
        linestyle="-",
        label=f"PyTorch ({device})",
    )
    plt.plot(BATCH_SIZES, results_mlx, marker="s", linestyle="-", label="MLX")
-    plt.title(f'Embedding Performance: MLX vs PyTorch\nModel: {MODEL_NAME_TORCH}')
+    plt.title(f"Embedding Performance: MLX vs PyTorch\nModel: {MODEL_NAME_TORCH}")
    plt.xlabel("Batch Size")
    plt.ylabel("Average Time per Batch (ms)")
    plt.xticks(BATCH_SIZES)
@@ -124,5 +136,6 @@ def main():
    plt.savefig(output_filename)
    print(f"Plot saved to {output_filename}")
 if __name__ == "__main__":
    main()
--- a/benchmarks/compare_faiss_vs_leann.py
+++ b/benchmarks/compare_faiss_vs_leann.py
@@ -3,14 +3,15 @@
 Memory comparison between Faiss HNSW and LEANN HNSW backend
 """
 import gc
 import logging
 import os
 import subprocess
 import sys
 import time
 import psutil
 import gc
 import subprocess
 from pathlib import Path
 import psutil
 from llama_index.core.node_parser import SentenceSplitter
 # Setup logging
@@ -61,7 +62,7 @@ def test_faiss_hnsw():
    try:
        result = subprocess.run(
-            [sys.executable, "examples/faiss_only.py"],
+            [sys.executable, "benchmarks/faiss_only.py"],
            capture_output=True,
            text=True,
            timeout=300,
@@ -83,9 +84,7 @@ def test_faiss_hnsw():
        for line in lines:
            if "Peak Memory:" in line:
-                peak_memory = float(
+                peak_memory = float(line.split("Peak Memory:")[1].split("MB")[0].strip())
                    line.split("Peak Memory:")[1].split("MB")[0].strip()
                )
        return {"peak_memory": peak_memory}
@@ -111,13 +110,12 @@ def test_leann_hnsw():
    tracker.checkpoint("After imports")
    from leann.api import LeannBuilder
    from llama_index.core import SimpleDirectoryReader
    from leann.api import LeannBuilder, LeannSearcher
    # Load and parse documents
    documents = SimpleDirectoryReader(
-        "examples/data",
+        "data",
        recursive=True,
        encoding="utf-8",
        required_exts=[".pdf", ".txt", ".md"],
@@ -135,6 +133,7 @@ def test_leann_hnsw():
        nodes = node_parser.get_nodes_from_documents([doc])
        for node in nodes:
            all_texts.append(node.get_content())
    print(f"Total number of chunks: {len(all_texts)}")
    tracker.checkpoint("After text chunking")
@@ -201,11 +200,9 @@ def test_leann_hnsw():
    searcher = LeannSearcher(index_path)
    tracker.checkpoint("After searcher loading")
    print("Running search queries...")
    queries = [
-        "什么是盘古大模型以及盘古开发过程中遇到了什么阴暗面，任务令一般在什么城市颁发",
+        "什么是盘古大模型以及盘古开发过程中遇到了什么阴暗面,任务令一般在什么城市颁发",
        "What is LEANN and how does it work?",
        "华为诺亚方舟实验室的主要研究内容",
    ]
@@ -303,21 +300,15 @@ def main():
        print("\nLEANN vs Faiss Performance:")
        memory_saving = faiss_results["peak_memory"] - leann_results["peak_memory"]
-        print(
+        print(f"  Search Memory: {memory_ratio:.1f}x less ({memory_saving:.1f} MB saved)")
            f"  Search Memory: {memory_ratio:.1f}x less ({memory_saving:.1f} MB saved)"
        )
        # Storage comparison
        if leann_storage_size > faiss_storage_size:
            storage_ratio = leann_storage_size / faiss_storage_size
-            print(
+            print(f"  Storage Size: {storage_ratio:.1f}x larger (LEANN uses more storage)")
                f"  Storage Size: {storage_ratio:.1f}x larger (LEANN uses more storage)"
            )
        elif faiss_storage_size > leann_storage_size:
            storage_ratio = faiss_storage_size / leann_storage_size
-            print(
+            print(f"  Storage Size: {storage_ratio:.1f}x smaller (LEANN uses less storage)")
                f"  Storage Size: {storage_ratio:.1f}x smaller (LEANN uses less storage)"
            )
        else:
            print("  Storage Size: similar")
    else:
--- a/benchmarks/data/.gitattributes
+++ b/benchmarks/data/.gitattributes
--- a/benchmarks/faiss_only.py
+++ b/benchmarks/faiss_only.py
@@ -1,11 +1,11 @@
 #!/usr/bin/env python3
 """Test only Faiss HNSW"""
 import os
 import sys
 import time
 import psutil
 import gc
 import os
 def get_memory_usage():
@@ -37,20 +37,20 @@ def main():
        import faiss
    except ImportError:
        print("Faiss is not installed.")
-        print("Please install it with `uv pip install faiss-cpu`")
+        print(
            "Please install it with `uv pip install faiss-cpu` and you can  then run this script again"
        )
        sys.exit(1)
    from llama_index.core import (
        SimpleDirectoryReader,
        VectorStoreIndex,
        StorageContext,
        Settings,
-        node_parser,
+        SimpleDirectoryReader,
-        Document,
+        StorageContext,
        VectorStoreIndex,
    )
    from llama_index.core.node_parser import SentenceSplitter
    from llama_index.vector_stores.faiss import FaissVectorStore
    from llama_index.embeddings.huggingface import HuggingFaceEmbedding
    from llama_index.vector_stores.faiss import FaissVectorStore
    tracker = MemoryTracker("Faiss HNSW")
    tracker.checkpoint("Initial")
@@ -65,7 +65,7 @@ def main():
    tracker.checkpoint("After Faiss index creation")
    documents = SimpleDirectoryReader(
-        "examples/data",
+        "data",
        recursive=True,
        encoding="utf-8",
        required_exts=[".pdf", ".txt", ".md"],
@@ -90,8 +90,9 @@ def main():
                vector_store=vector_store, persist_dir="./storage_faiss"
            )
            from llama_index.core import load_index_from_storage
            index = load_index_from_storage(storage_context=storage_context)
-            print(f"Index loaded from ./storage_faiss")
+            print("Index loaded from ./storage_faiss")
            tracker.checkpoint("After loading existing index")
            index_loaded = True
        except Exception as e:
@@ -99,6 +100,7 @@ def main():
            print("Cleaning up corrupted index and building new one...")
            # Clean up corrupted index
            import shutil
            if os.path.exists("./storage_faiss"):
                shutil.rmtree("./storage_faiss")
@@ -109,9 +111,7 @@ def main():
        vector_store = FaissVectorStore(faiss_index=faiss_index)
        storage_context = StorageContext.from_defaults(vector_store=vector_store)
        index = VectorStoreIndex.from_documents(
-            documents, 
+            documents, storage_context=storage_context, transformations=[node_parser]
            storage_context=storage_context,
            transformations=[node_parser]
        )
        tracker.checkpoint("After index building")
@@ -127,7 +127,7 @@ def main():
    query_engine = index.as_query_engine(similarity_top_k=20)
    queries = [
-        "什么是盘古大模型以及盘古开发过程中遇到了什么阴暗面，任务令一般在什么城市颁发",
+        "什么是盘古大模型以及盘古开发过程中遇到了什么阴暗面,任务令一般在什么城市颁发",
        "What is LEANN and how does it work?",
        "华为诺亚方舟实验室的主要研究内容",
    ]
--- a/benchmarks/micro_tpt.py
+++ b/benchmarks/micro_tpt.py
@@ -2,20 +2,20 @@
 import argparse
 import time
 from contextlib import contextmanager
 from dataclasses import dataclass
 from typing import Dict, List, Optional, Tuple
 import numpy as np
 import torch
 from torch import nn
 from transformers import AutoModel, BitsAndBytesConfig
 from tqdm import tqdm
-from contextlib import contextmanager
+from transformers import AutoModel, BitsAndBytesConfig
@dataclass
 class BenchmarkConfig:
    model_path: str
-    batch_sizes: List[int]
+    batch_sizes: list[int]
    seq_length: int
    num_runs: int
    use_fp16: bool = True
@@ -32,13 +32,11 @@ class GraphContainer:
    def __init__(self, model: nn.Module, seq_length: int):
        self.model = model
        self.seq_length = seq_length
-        self.graphs: Dict[int, 'GraphWrapper'] = {}
+        self.graphs: dict[int, GraphWrapper] = {}
-    def get_or_create(self, batch_size: int) -> 'GraphWrapper':
+    def get_or_create(self, batch_size: int) -> "GraphWrapper":
        if batch_size not in self.graphs:
-            self.graphs[batch_size] = GraphWrapper(
+            self.graphs[batch_size] = GraphWrapper(self.model, batch_size, self.seq_length)
                self.model, batch_size, self.seq_length
            )
        return self.graphs[batch_size]
@@ -55,13 +53,13 @@ class GraphWrapper:
        self._warmup()
        # Only use CUDA graphs on NVIDIA GPUs
-        if torch.cuda.is_available() and hasattr(torch.cuda, 'CUDAGraph'):
+        if torch.cuda.is_available() and hasattr(torch.cuda, "CUDAGraph"):
            # Capture graph
            self.graph = torch.cuda.CUDAGraph()
            with torch.cuda.graph(self.graph):
                self.static_output = self.model(
                    input_ids=self.static_input,
-                    attention_mask=self.static_attention_mask
+                    attention_mask=self.static_attention_mask,
                )
            self.use_cuda_graph = True
        else:
@@ -79,9 +77,7 @@ class GraphWrapper:
    def _create_random_batch(self, batch_size: int, seq_length: int) -> torch.Tensor:
        return torch.randint(
-            0, 1000, (batch_size, seq_length), 
+            0, 1000, (batch_size, seq_length), device=self.device, dtype=torch.long
            device=self.device, 
            dtype=torch.long
        )
    def _warmup(self, num_warmup: int = 3):
@@ -89,7 +85,7 @@ class GraphWrapper:
            for _ in range(num_warmup):
                self.model(
                    input_ids=self.static_input,
-                    attention_mask=self.static_attention_mask
+                    attention_mask=self.static_attention_mask,
                )
    def __call__(self, input_ids: torch.Tensor, attention_mask: torch.Tensor) -> torch.Tensor:
@@ -133,8 +129,12 @@ class ModelOptimizer:
            print("- Using FP16 precision")
        # Check if using SDPA (only on CUDA)
-        if torch.cuda.is_available() and torch.version.cuda and float(torch.version.cuda[:3]) >= 11.6:
+        if (
-            if hasattr(torch.nn.functional, 'scaled_dot_product_attention'):
+            torch.cuda.is_available()
            and torch.version.cuda
            and float(torch.version.cuda[:3]) >= 11.6
        ):
            if hasattr(torch.nn.functional, "scaled_dot_product_attention"):
                print("- Using PyTorch SDPA (scaled_dot_product_attention)")
            else:
                print("- PyTorch SDPA not available")
@@ -142,7 +142,8 @@ class ModelOptimizer:
        # Flash Attention (only on CUDA)
        if config.use_flash_attention and torch.cuda.is_available():
            try:
-                from flash_attn.flash_attention import FlashAttention
+                from flash_attn.flash_attention import FlashAttention  # noqa: F401
                print("- Flash Attention 2 available")
                if hasattr(model.config, "attention_mode"):
                    model.config.attention_mode = "flash_attention_2"
@@ -153,8 +154,9 @@ class ModelOptimizer:
        # Memory efficient attention (only on CUDA)
        if torch.cuda.is_available():
            try:
-                from xformers.ops import memory_efficient_attention
+                from xformers.ops import memory_efficient_attention  # noqa: F401
-                if hasattr(model, 'enable_xformers_memory_efficient_attention'):
+
                if hasattr(model, "enable_xformers_memory_efficient_attention"):
                    model.enable_xformers_memory_efficient_attention()
                    print("- Enabled xformers memory efficient attention")
                else:
@@ -220,7 +222,7 @@ class Benchmark:
                self.graphs = None
            self.timer = Timer()
        except Exception as e:
-            print(f"ERROR in benchmark initialization: {str(e)}")
+            print(f"ERROR in benchmark initialization: {e!s}")
            raise
    def _load_model(self) -> nn.Module:
@@ -230,15 +232,17 @@ class Benchmark:
            # Int4 quantization using HuggingFace integration
            if self.config.use_int4:
                import bitsandbytes as bnb
                print(f"- bitsandbytes version: {bnb.__version__}")
-                # 检查是否使用自定义的8bit量化
+                # Check if using custom 8bit quantization
-                if hasattr(self.config, 'use_linear8bitlt') and self.config.use_linear8bitlt:
+                if hasattr(self.config, "use_linear8bitlt") and self.config.use_linear8bitlt:
                    print("- Using custom Linear8bitLt replacement for all linear layers")
-                    # 加载原始模型（不使用量化配置）
+                    # Load original model (without quantization config)
                    import bitsandbytes as bnb
                    import torch
                    # set default to half
                    torch.set_default_dtype(torch.float16)
                    compute_dtype = torch.float16 if self.config.use_fp16 else torch.float32
@@ -247,52 +251,58 @@ class Benchmark:
                        torch_dtype=compute_dtype,
                    )
-                    # 定义替换函数
+                    # Define replacement function
                    def replace_linear_with_linear8bitlt(model):
-                        """递归地将模型中的所有nn.Linear层替换为Linear8bitLt"""
+                        """Recursively replace all nn.Linear layers with Linear8bitLt"""
                        for name, module in list(model.named_children()):
                            if isinstance(module, nn.Linear):
-                                # 获取原始线性层的参数
+                                # Get original linear layer parameters
                                in_features = module.in_features
                                out_features = module.out_features
                                bias = module.bias is not None
-                                # 创建8bit线性层
+                                # Create 8bit linear layer
                                # print size
                                print(f"in_features: {in_features}, out_features: {out_features}")
                                new_module = bnb.nn.Linear8bitLt(
                                    in_features,
                                    out_features,
                                    bias=bias,
-                                    has_fp16_weights=False
+                                    has_fp16_weights=False,
                                )
-                                # 复制权重和偏置
+                                # Copy weights and bias
                                new_module.weight.data = module.weight.data
                                if bias:
                                    new_module.bias.data = module.bias.data
-                                # 替换模块
+                                # Replace module
                                setattr(model, name, new_module)
                            else:
-                                # 递归处理子模块
+                                # Process child modules recursively
                                replace_linear_with_linear8bitlt(module)
                        return model
-                    # 替换所有线性层
+                    # Replace all linear layers
                    model = replace_linear_with_linear8bitlt(model)
                    # add torch compile
                    model = torch.compile(model)
-                    # 将模型移到GPU（量化发生在这里）
+                    # Move model to GPU (quantization happens here)
-                    device = "cuda" if torch.cuda.is_available() else "mps" if torch.backends.mps.is_available() else "cpu"
+                    device = (
                        "cuda"
                        if torch.cuda.is_available()
                        else "mps"
                        if torch.backends.mps.is_available()
                        else "cpu"
                    )
                    model = model.to(device)
                    print("- All linear layers replaced with Linear8bitLt")
                else:
-                    # 使用原来的Int4量化方法
+                    # Use original Int4 quantization method
                    print("- Using bitsandbytes for Int4 quantization")
                    # Create quantization config
@@ -302,7 +312,7 @@ class Benchmark:
                        load_in_4bit=True,
                        bnb_4bit_compute_dtype=compute_dtype,
                        bnb_4bit_use_double_quant=True,
-                        bnb_4bit_quant_type="nf4"
+                        bnb_4bit_quant_type="nf4",
                    )
                    print("- Quantization config:", quantization_config)
@@ -312,7 +322,7 @@ class Benchmark:
                        self.config.model_path,
                        quantization_config=quantization_config,
                        torch_dtype=compute_dtype,
-                        device_map="auto"  # Let HF decide on device mapping
+                        device_map="auto",  # Let HF decide on device mapping
                    )
                # Check if model loaded successfully
@@ -324,7 +334,7 @@ class Benchmark:
                # Apply optimizations directly here
                print("\nApplying model optimizations:")
-                if hasattr(self.config, 'use_linear8bitlt') and self.config.use_linear8bitlt:
+                if hasattr(self.config, "use_linear8bitlt") and self.config.use_linear8bitlt:
                    print("- Model moved to GPU with Linear8bitLt quantization")
                else:
                    # Skip moving to GPU since device_map="auto" already did that
@@ -334,8 +344,12 @@ class Benchmark:
                print(f"- Using {compute_dtype} for compute dtype")
                # Check CUDA and SDPA
-                if torch.cuda.is_available() and torch.version.cuda and float(torch.version.cuda[:3]) >= 11.6:
+                if (
-                    if hasattr(torch.nn.functional, 'scaled_dot_product_attention'):
+                    torch.cuda.is_available()
                    and torch.version.cuda
                    and float(torch.version.cuda[:3]) >= 11.6
                ):
                    if hasattr(torch.nn.functional, "scaled_dot_product_attention"):
                        print("- Using PyTorch SDPA (scaled_dot_product_attention)")
                    else:
                        print("- PyTorch SDPA not available")
@@ -343,8 +357,7 @@ class Benchmark:
                # Try xformers if available (only on CUDA)
                if torch.cuda.is_available():
                    try:
-                        from xformers.ops import memory_efficient_attention
+                        if hasattr(model, "enable_xformers_memory_efficient_attention"):
                        if hasattr(model, 'enable_xformers_memory_efficient_attention'):
                            model.enable_xformers_memory_efficient_attention()
                            print("- Enabled xformers memory efficient attention")
                        else:
@@ -370,7 +383,7 @@ class Benchmark:
                    self.config.model_path,
                    quantization_config=quantization_config,
                    torch_dtype=compute_dtype,
-                    device_map="auto"
+                    device_map="auto",
                )
                if model is None:
@@ -389,6 +402,7 @@ class Benchmark:
                # Apply standard optimizations
                # set default to half
                import torch
                torch.set_default_dtype(torch.bfloat16)
                model = ModelOptimizer.optimize(model, self.config)
                model = model.half()
@@ -403,25 +417,31 @@ class Benchmark:
            return model
        except Exception as e:
-            print(f"ERROR loading model: {str(e)}")
+            print(f"ERROR loading model: {e!s}")
            import traceback
            traceback.print_exc()
            raise
    def _create_random_batch(self, batch_size: int) -> torch.Tensor:
-        device = "cuda" if torch.cuda.is_available() else "mps" if torch.backends.mps.is_available() else "cpu"
+        device = (
            "cuda"
            if torch.cuda.is_available()
            else "mps"
            if torch.backends.mps.is_available()
            else "cpu"
        )
        return torch.randint(
-            0, 1000,
+            0,
            1000,
            (batch_size, self.config.seq_length),
            device=device,
-            dtype=torch.long
+            dtype=torch.long,
        )
    def _run_inference(
-        self,
+        self, input_ids: torch.Tensor, graph_wrapper: GraphWrapper | None = None
-        input_ids: torch.Tensor,
+    ) -> tuple[float, torch.Tensor]:
        graph_wrapper: Optional[GraphWrapper] = None
    ) -> Tuple[float, torch.Tensor]:
        attention_mask = torch.ones_like(input_ids)
        with torch.no_grad(), self.timer.timing():
@@ -432,7 +452,7 @@ class Benchmark:
        return self.timer.elapsed_time(), output
-    def run(self) -> Dict[int, Dict[str, float]]:
+    def run(self) -> dict[int, dict[str, float]]:
        results = {}
        # Reset peak memory stats
@@ -450,9 +470,7 @@ class Benchmark:
            # Get or create graph for this batch size
            graph_wrapper = (
-                self.graphs.get_or_create(batch_size)
+                self.graphs.get_or_create(batch_size) if self.graphs is not None else None
                if self.graphs is not None
                else None
            )
            # Pre-allocate input tensor
@@ -490,7 +508,7 @@ class Benchmark:
        # Log memory usage
        if torch.cuda.is_available():
-            peak_memory_gb = torch.cuda.max_memory_allocated() / (1024 ** 3)
+            peak_memory_gb = torch.cuda.max_memory_allocated() / (1024**3)
        elif torch.backends.mps.is_available():
            # MPS doesn't have max_memory_allocated, use 0
            peak_memory_gb = 0.0
@@ -604,7 +622,15 @@ def main():
        os.makedirs("results", exist_ok=True)
        # Generate filename based on configuration
-        precision_type = "int4" if config.use_int4 else "int8" if config.use_int8 else "fp16" if config.use_fp16 else "fp32"
+        precision_type = (
            "int4"
            if config.use_int4
            else "int8"
            if config.use_int8
            else "fp16"
            if config.use_fp16
            else "fp32"
        )
        model_name = os.path.basename(config.model_path)
        output_file = f"results/benchmark_{model_name}_{precision_type}.json"
@@ -612,17 +638,20 @@ def main():
        with open(output_file, "w") as f:
            json.dump(
                {
-                    "config": {k: str(v) if isinstance(v, list) else v for k, v in vars(config).items()},
+                    "config": {
-                    "results": {str(k): v for k, v in results.items()}
+                        k: str(v) if isinstance(v, list) else v for k, v in vars(config).items()
                    },
                    "results": {str(k): v for k, v in results.items()},
                },
                f,
-                indent=2
+                indent=2,
            )
        print(f"Results saved to {output_file}")
    except Exception as e:
        print(f"Benchmark failed: {e}")
        import traceback
        traceback.print_exc()
--- a/benchmarks/run_evaluation.py
+++ b/benchmarks/run_evaluation.py
@@ -5,24 +5,21 @@ It correctly compares results by fetching the text content for both the new sear
 results and the golden standard results, making the comparison robust to ID changes.
 """
 import json
 import argparse
 import json
 import sys
 import time
 from pathlib import Path
 import sys
 import numpy as np
 from typing import List
-from leann.api import LeannSearcher, LeannBuilder
+import numpy as np
 from leann.api import LeannBuilder, LeannSearcher
 def download_data_if_needed(data_root: Path, download_embeddings: bool = False):
    """Checks if the data directory exists, and if not, downloads it from HF Hub."""
    if not data_root.exists():
        print(f"Data directory '{data_root}' not found.")
-        print(
+        print("Downloading evaluation data from Hugging Face Hub... (this may take a moment)")
            "Downloading evaluation data from Hugging Face Hub... (this may take a moment)"
        )
        try:
            from huggingface_hub import snapshot_download
@@ -63,7 +60,7 @@ def download_data_if_needed(data_root: Path, download_embeddings: bool = False):
            sys.exit(1)
-def download_embeddings_if_needed(data_root: Path, dataset_type: str = None):
+def download_embeddings_if_needed(data_root: Path, dataset_type: str | None = None):
    """Download embeddings files specifically."""
    embeddings_dir = data_root / "embeddings"
@@ -101,7 +98,7 @@ def download_embeddings_if_needed(data_root: Path, dataset_type: str = None):
 # --- Helper Function to get Golden Passages ---
-def get_golden_texts(searcher: LeannSearcher, golden_ids: List[int]) -> set:
+def get_golden_texts(searcher: LeannSearcher, golden_ids: list[int]) -> set:
    """
    Retrieves the text for golden passage IDs directly from the LeannSearcher's
    passage manager.
@@ -113,24 +110,20 @@ def get_golden_texts(searcher: LeannSearcher, golden_ids: List[int]) -> set:
            passage_data = searcher.passage_manager.get_passage(str(gid))
            golden_texts.add(passage_data["text"])
        except KeyError:
-            print(
+            print(f"Warning: Golden passage ID '{gid}' not found in the index's passage data.")
                f"Warning: Golden passage ID '{gid}' not found in the index's passage data."
            )
    return golden_texts
-def load_queries(file_path: Path) -> List[str]:
+def load_queries(file_path: Path) -> list[str]:
    queries = []
-    with open(file_path, "r", encoding="utf-8") as f:
+    with open(file_path, encoding="utf-8") as f:
        for line in f:
            data = json.loads(line)
            queries.append(data["query"])
    return queries
-def build_index_from_embeddings(
+def build_index_from_embeddings(embeddings_file: str, output_path: str, backend: str = "hnsw"):
    embeddings_file: str, output_path: str, backend: str = "hnsw"
 ):
    """
    Build a LEANN index from pre-computed embeddings.
@@ -173,9 +166,7 @@ def build_index_from_embeddings(
 def main():
-    parser = argparse.ArgumentParser(
+    parser = argparse.ArgumentParser(description="Run recall evaluation on a LEANN index.")
        description="Run recall evaluation on a LEANN index."
    )
    parser.add_argument(
        "index_path",
        type=str,
@@ -202,26 +193,22 @@ def main():
    parser.add_argument(
        "--num-queries", type=int, default=10, help="Number of queries to evaluate."
    )
-    parser.add_argument(
+    parser.add_argument("--top-k", type=int, default=3, help="The 'k' value for recall@k.")
        "--top-k", type=int, default=3, help="The 'k' value for recall@k."
    )
    parser.add_argument(
        "--ef-search", type=int, default=120, help="The 'efSearch' parameter for HNSW."
    )
    args = parser.parse_args()
    # --- Path Configuration ---
-    # Assumes a project structure where the script is in 'examples/'
+    # Assumes a project structure where the script is in 'benchmarks/'
-    # and data is in 'data/' at the project root.
+    # and evaluation data is in 'benchmarks/data/'.
-    project_root = Path(__file__).resolve().parent.parent
+    script_dir = Path(__file__).resolve().parent
-    data_root = project_root / "data"
+    data_root = script_dir / "data"
    # Download data based on mode
    if args.mode == "build":
        # For building mode, we need embeddings
-        download_data_if_needed(
+        download_data_if_needed(data_root, download_embeddings=False)  # Basic data first
            data_root, download_embeddings=False
        )  # Basic data first
        # Auto-detect dataset type and download embeddings
        if args.embeddings_file:
@@ -262,9 +249,7 @@ def main():
        print(f"Index built successfully: {built_index_path}")
        # Ask if user wants to run evaluation
-        eval_response = (
+        eval_response = input("Run evaluation on the built index? (y/n): ").strip().lower()
            input("Run evaluation on the built index? (y/n): ").strip().lower()
        )
        if eval_response != "y":
            print("Index building complete. Exiting.")
            return
@@ -293,11 +278,9 @@ def main():
                        break
            if not args.index_path:
                print("No indices found. The data download should have included pre-built indices.")
                print(
-                    "No indices found. The data download should have included pre-built indices."
+                    "Please check the benchmarks/data/indices/ directory or provide --index-path manually."
                )
                print(
                    "Please check the data/indices/ directory or provide --index-path manually."
                )
                sys.exit(1)
@@ -310,14 +293,10 @@ def main():
    else:
        # Fallback: try to infer from the index directory name
        dataset_type = Path(args.index_path).name
-        print(
+        print(f"WARNING: Could not detect dataset type from path, inferred '{dataset_type}'.")
            f"WARNING: Could not detect dataset type from path, inferred '{dataset_type}'."
        )
    queries_file = data_root / "queries" / "nq_open.jsonl"
-    golden_results_file = (
+    golden_results_file = data_root / "ground_truth" / dataset_type / "flat_results_nq_k3.json"
        data_root / "ground_truth" / dataset_type / "flat_results_nq_k3.json"
    )
    print(f"INFO: Detected dataset type: {dataset_type}")
    print(f"INFO: Using queries file: {queries_file}")
@@ -327,7 +306,7 @@ def main():
        searcher = LeannSearcher(args.index_path)
        queries = load_queries(queries_file)
-        with open(golden_results_file, "r") as f:
+        with open(golden_results_file) as f:
            golden_results_data = json.load(f)
        num_eval_queries = min(args.num_queries, len(queries))
@@ -339,9 +318,7 @@ def main():
        for i in range(num_eval_queries):
            start_time = time.time()
-            new_results = searcher.search(
+            new_results = searcher.search(queries[i], top_k=args.top_k, ef=args.ef_search)
                queries[i], top_k=args.top_k, ef=args.ef_search
            )
            search_times.append(time.time() - start_time)
            # Correct Recall Calculation: Based on TEXT content
--- a/benchmarks/simple_mac_tpt_test.py
+++ b/benchmarks/simple_mac_tpt_test.py
@@ -1,26 +1,27 @@
 import time
 from dataclasses import dataclass
 from typing import Dict, List
 import numpy as np
 import torch
 from torch import nn
 from transformers import AutoModel, BitsAndBytesConfig
 from tqdm import tqdm
 from transformers import AutoModel
 # Add MLX imports
 try:
    import mlx.core as mx
    from mlx_lm.utils import load
    MLX_AVAILABLE = True
-except ImportError as e:
+except ImportError:
    print("MLX not available. Install with: uv pip install mlx mlx-lm")
    MLX_AVAILABLE = False
@dataclass
 class BenchmarkConfig:
    model_path: str = "facebook/contriever"
-    batch_sizes: List[int] = None
+    batch_sizes: list[int] = None
    seq_length: int = 256
    num_runs: int = 5
    use_fp16: bool = True
@@ -35,6 +36,7 @@ class BenchmarkConfig:
        if self.batch_sizes is None:
            self.batch_sizes = [1, 2, 4, 8, 16, 32, 64]
 class MLXBenchmark:
    """MLX-specific benchmark for embedding models"""
@@ -55,11 +57,7 @@ class MLXBenchmark:
    def _create_random_batch(self, batch_size: int):
        """Create random input batches for MLX testing - same as PyTorch"""
-        return torch.randint(
+        return torch.randint(0, 1000, (batch_size, self.config.seq_length), dtype=torch.long)
            0, 1000,
            (batch_size, self.config.seq_length),
            dtype=torch.long
        )
    def _run_inference(self, input_ids: torch.Tensor) -> float:
        """Run MLX inference with same input as PyTorch"""
@@ -82,12 +80,12 @@ class MLXBenchmark:
        except Exception as e:
            print(f"MLX inference error: {e}")
-            return float('inf')
+            return float("inf")
        end_time = time.time()
        return end_time - start_time
-    def run(self) -> Dict[int, Dict[str, float]]:
+    def run(self) -> dict[int, dict[str, float]]:
        """Run the MLX benchmark across all batch sizes"""
        results = {}
@@ -111,10 +109,10 @@ class MLXBenchmark:
                    break
            # Run benchmark
-            for i in tqdm(range(self.config.num_runs), desc=f"MLX Batch size {batch_size}"):
+            for _i in tqdm(range(self.config.num_runs), desc=f"MLX Batch size {batch_size}"):
                try:
                    elapsed_time = self._run_inference(input_ids)
-                    if elapsed_time != float('inf'):
+                    if elapsed_time != float("inf"):
                        times.append(elapsed_time)
                except Exception as e:
                    print(f"Error during MLX inference: {e}")
@@ -145,16 +143,22 @@ class MLXBenchmark:
        return results
 class Benchmark:
    def __init__(self, config: BenchmarkConfig):
        self.config = config
-        self.device = "cuda" if torch.cuda.is_available() else "mps" if torch.backends.mps.is_available() else "cpu"
+        self.device = (
            "cuda"
            if torch.cuda.is_available()
            else "mps"
            if torch.backends.mps.is_available()
            else "cpu"
        )
        self.model = self._load_model()
    def _load_model(self) -> nn.Module:
        print(f"Loading model from {self.config.model_path}...")
        model = AutoModel.from_pretrained(self.config.model_path)
        if self.config.use_fp16:
            model = model.half()
@@ -166,10 +170,11 @@ class Benchmark:
    def _create_random_batch(self, batch_size: int) -> torch.Tensor:
        return torch.randint(
-            0, 1000,
+            0,
            1000,
            (batch_size, self.config.seq_length),
            device=self.device,
-            dtype=torch.long
+            dtype=torch.long,
        )
    def _run_inference(self, input_ids: torch.Tensor) -> float:
@@ -177,12 +182,12 @@ class Benchmark:
        start_time = time.time()
        with torch.no_grad():
-            output = self.model(input_ids=input_ids, attention_mask=attention_mask)
+            self.model(input_ids=input_ids, attention_mask=attention_mask)
        end_time = time.time()
        return end_time - start_time
-    def run(self) -> Dict[int, Dict[str, float]]:
+    def run(self) -> dict[int, dict[str, float]]:
        results = {}
        if torch.cuda.is_available():
@@ -194,7 +199,7 @@ class Benchmark:
            input_ids = self._create_random_batch(batch_size)
-            for i in tqdm(range(self.config.num_runs), desc=f"Batch size {batch_size}"):
+            for _i in tqdm(range(self.config.num_runs), desc=f"Batch size {batch_size}"):
                try:
                    elapsed_time = self._run_inference(input_ids)
                    times.append(elapsed_time)
@@ -219,7 +224,7 @@ class Benchmark:
            print(f"Throughput: {throughput:.2f} sequences/second")
        if torch.cuda.is_available():
-            peak_memory_gb = torch.cuda.max_memory_allocated() / (1024 ** 3)
+            peak_memory_gb = torch.cuda.max_memory_allocated() / (1024**3)
        else:
            peak_memory_gb = 0.0
@@ -228,6 +233,7 @@ class Benchmark:
        return results
 def run_benchmark():
    """Main function to run the benchmark with optimized parameters."""
    config = BenchmarkConfig()
@@ -242,16 +248,13 @@ def run_benchmark():
        return {
            "max_throughput": max_throughput,
            "avg_throughput": avg_throughput,
-            "results": results
+            "results": results,
        }
    except Exception as e:
        print(f"Benchmark failed: {e}")
-        return {
+        return {"max_throughput": 0.0, "avg_throughput": 0.0, "error": str(e)}
-            "max_throughput": 0.0,
+
            "avg_throughput": 0.0,
            "error": str(e)
        }
 def run_mlx_benchmark():
    """Run MLX-specific benchmark"""
@@ -260,13 +263,10 @@ def run_mlx_benchmark():
        return {
            "max_throughput": 0.0,
            "avg_throughput": 0.0,
-            "error": "MLX not available"
+            "error": "MLX not available",
        }
-    config = BenchmarkConfig(
+    config = BenchmarkConfig(model_path="mlx-community/all-MiniLM-L6-v2-4bit", use_mlx=True)
        model_path="mlx-community/all-MiniLM-L6-v2-4bit",
        use_mlx=True
    )
    try:
        benchmark = MLXBenchmark(config)
@@ -276,7 +276,7 @@ def run_mlx_benchmark():
            return {
                "max_throughput": 0.0,
                "avg_throughput": 0.0,
-                "error": "No valid results"
+                "error": "No valid results",
            }
        max_throughput = max(results[batch_size]["throughput"] for batch_size in results)
@@ -285,16 +285,13 @@ def run_mlx_benchmark():
        return {
            "max_throughput": max_throughput,
            "avg_throughput": avg_throughput,
-            "results": results
+            "results": results,
        }
    except Exception as e:
        print(f"MLX benchmark failed: {e}")
-        return {
+        return {"max_throughput": 0.0, "avg_throughput": 0.0, "error": str(e)}
-            "max_throughput": 0.0,
+
            "avg_throughput": 0.0,
            "error": str(e)
        }
 if __name__ == "__main__":
    print("=== PyTorch Benchmark ===")
@@ -308,7 +305,7 @@ if __name__ == "__main__":
    print(f"MLX Average throughput: {mlx_result['avg_throughput']:.2f} sequences/second")
    # Compare results
-    if pytorch_result['max_throughput'] > 0 and mlx_result['max_throughput'] > 0:
+    if pytorch_result["max_throughput"] > 0 and mlx_result["max_throughput"] > 0:
-        speedup = mlx_result['max_throughput'] / pytorch_result['max_throughput']
+        speedup = mlx_result["max_throughput"] / pytorch_result["max_throughput"]
-        print(f"\n=== Comparison ===")
+        print("\n=== Comparison ===")
        print(f"MLX is {speedup:.2f}x {'faster' if speedup > 1 else 'slower'} than PyTorch")
--- a/examples/data/2501.14312v1
+++ b/examples/data/2501.14312v1
--- a/examples/data/2506.08276v1.pdf
+++ b/examples/data/2506.08276v1.pdf
--- a/examples/data/PrideandPrejudice.txt
+++ b/examples/data/PrideandPrejudice.txt
@@ -14903,5 +14903,3 @@ This website includes information about Project Gutenberg™,
 including how to make donations to the Project Gutenberg Literary
 Archive Foundation, how to help produce our new eBooks, and how to
 subscribe to our email newsletter to hear about new eBooks.
--- a/data/README.md
+++ b/data/README.md
@@ -1,44 +0,0 @@
 ---
 license: mit
 ---
 # LEANN-RAG Evaluation Data
 This repository contains the necessary data to run the recall evaluation scripts for the [LEANN-RAG](https://huggingface.co/LEANN-RAG) project.
 ## Dataset Components
 This dataset is structured into three main parts:
 1.  **Pre-built LEANN Indices**:
    *   `dpr/`: A pre-built index for the DPR dataset.
    *   `rpj_wiki/`: A pre-built index for the RPJ-Wiki dataset.
    These indices were created using the `leann-core` library and are required by the `LeannSearcher`.
 2.  **Ground Truth Data**:
    *   `ground_truth/`: Contains the ground truth files (`flat_results_nq_k3.json`) for both the DPR and RPJ-Wiki datasets. These files map queries to the original passage IDs from the Natural Questions benchmark, evaluated using the Contriever model.
 3.  **Queries**:
    *   `queries/`: Contains the `nq_open.jsonl` file with the Natural Questions queries used for the evaluation.
 ## Usage
 To use this data, you can download it locally using the `huggingface-hub` library. First, install the library:
 ```bash
 pip install huggingface-hub
 ```
 Then, you can download the entire dataset to a local directory (e.g., `data/`) with the following Python script:
 ```python
 from huggingface_hub import snapshot_download
 snapshot_download(
    repo_id="LEANN-RAG/leann-rag-evaluation-data",
    repo_type="dataset",
    local_dir="data"
 )
 ```
 This will download all the necessary files into a local `data` folder, preserving the repository structure. The evaluation scripts in the main [LEANN-RAG Space](https://huggingface.co/LEANN-RAG) are configured to work with this data structure.
--- a/demo.ipynb
+++ b/demo.ipynb
@@ -1,35 +1,116 @@
 {
 "cells": [
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "# Quick Start \n",
    "\n",
    "**Home GitHub Repository:** [LEANN on GitHub](https://github.com/yichuan-w/LEANN)\n",
    "\n",
    "**Important for Colab users:** Set your runtime type to T4 GPU for optimal performance. Go to Runtime → Change runtime type → Hardware accelerator → T4 GPU."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": null,
   "metadata": {},
   "outputs": [],
   "source": [
-    "from leann.api import LeannBuilder, LeannSearcher, LeannChat\n",
+    "# install this if you are using colab\n",
-    "# 1. Build index (no embeddings stored!)\n",
+    "! uv pip install leann-core leann-backend-hnsw --no-deps\n",
    "! uv pip install leann --no-deps\n",
    "# For Colab environment, we need to set some environment variables\n",
    "import os\n",
    "\n",
    "os.environ[\"LEANN_LOG_LEVEL\"] = \"INFO\"  # Enable more detailed logging"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": null,
   "metadata": {},
   "outputs": [],
   "source": [
    "from pathlib import Path\n",
    "\n",
    "INDEX_DIR = Path(\"./\").resolve()\n",
    "INDEX_PATH = str(INDEX_DIR / \"demo.leann\")"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "## Build the index"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": null,
   "metadata": {},
   "outputs": [],
   "source": [
    "from leann.api import LeannBuilder\n",
    "\n",
    "builder = LeannBuilder(backend_name=\"hnsw\")\n",
-    "builder.add_text(\"C# is a powerful programming language but it is not very popular\")\n",
+    "builder.add_text(\"C# is a powerful programming language and it is good at game development\")\n",
-    "builder.add_text(\"Python is a powerful programming language and it is very popular\")\n",
+    "builder.add_text(\n",
-    "builder.add_text(\"Machine learning transforms industries\")  \n",
+    "    \"Python is a powerful programming language and it is good at machine learning tasks\"\n",
    "builder.add_text(\"Neural networks process complex data\")\n",
    "builder.add_text(\"Leann is a great storage saving engine for RAG on your macbook\")\n",
    "builder.build_index(\"knowledge.leann\")\n",
    "# 2. Search with real-time embeddings\n",
    "searcher = LeannSearcher(\"knowledge.leann\")\n",
    "results = searcher.search(\"programming languages\", top_k=2, recompute_beighbor_embeddings=True)\n",
    "print(results)\n",
    "\n",
    "llm_config = {\"type\": \"ollama\", \"model\": \"qwen3:8b\"}\n",
    "\n",
    "chat = LeannChat(index_path=\"knowledge.leann\", llm_config=llm_config)\n",
    "\n",
    "response = chat.ask(\n",
    "    \"Compare the two retrieved programming languages and say which one is more popular today. Respond in a single well-formed sentence.\",\n",
    "    top_k=2,\n",
    "    recompute_beighbor_embeddings=True,\n",
    ")\n",
-    "print(response)"
+    "builder.add_text(\"Machine learning transforms industries\")\n",
    "builder.add_text(\"Neural networks process complex data\")\n",
    "builder.add_text(\"Leann is a great storage saving engine for RAG on your MacBook\")\n",
    "builder.build_index(INDEX_PATH)"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "## Search with real-time embeddings"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": null,
   "metadata": {},
   "outputs": [],
   "source": [
    "from leann.api import LeannSearcher\n",
    "\n",
    "searcher = LeannSearcher(INDEX_PATH)\n",
    "results = searcher.search(\"programming languages\", top_k=2)\n",
    "results"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "## Chat with LEANN using retrieved results"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": null,
   "metadata": {},
   "outputs": [],
   "source": [
    "from leann.api import LeannChat\n",
    "\n",
    "llm_config = {\n",
    "    \"type\": \"hf\",\n",
    "    \"model\": \"Qwen/Qwen3-0.6B\",\n",
    "}\n",
    "\n",
    "chat = LeannChat(index_path=INDEX_PATH, llm_config=llm_config)\n",
    "response = chat.ask(\n",
    "    \"Compare the two retrieved programming languages and tell me their advantages.\",\n",
    "    top_k=2,\n",
    "    llm_kwargs={\"max_tokens\": 128},\n",
    ")\n",
    "response"
   ]
  }
 ],
--- a/docs/CONTRIBUTING.md
+++ b/docs/CONTRIBUTING.md
@@ -0,0 +1,220 @@
 # 🤝 Contributing
 We welcome contributions! Leann is built by the community, for the community.
 ## Ways to Contribute
 - 🐛 **Bug Reports**: Found an issue? Let us know!
 - 💡 **Feature Requests**: Have an idea? We'd love to hear it!
 - 🔧 **Code Contributions**: PRs welcome for all skill levels
 - 📖 **Documentation**: Help make Leann more accessible
 - 🧪 **Benchmarks**: Share your performance results
 ## 🚀 Development Setup
 ### Prerequisites
 1. **Install uv** (fast Python package installer):
   ```bash
   curl -LsSf https://astral.sh/uv/install.sh | sh
   ```
 2. **Clone the repository**:
   ```bash
   git clone https://github.com/LEANN-RAG/LEANN-RAG.git
   cd LEANN-RAG
   ```
 3. **Install system dependencies**:
   **macOS:**
   ```bash
   brew install llvm libomp boost protobuf zeromq pkgconf
   ```
   **Ubuntu/Debian:**
   ```bash
   sudo apt-get install libomp-dev libboost-all-dev protobuf-compiler \
                        libabsl-dev libmkl-full-dev libaio-dev libzmq3-dev
   ```
 4. **Build from source**:
   ```bash
   # macOS
   CC=$(brew --prefix llvm)/bin/clang CXX=$(brew --prefix llvm)/bin/clang++ uv sync
   # Ubuntu/Debian
   uv sync
   ```
 ## 🔨 Pre-commit Hooks
 We use pre-commit hooks to ensure code quality and consistency. This runs automatically before each commit.
 ### Setup Pre-commit
 1. **Install pre-commit** (already included when you run `uv sync`):
   ```bash
   uv pip install pre-commit
   ```
 2. **Install the git hooks**:
   ```bash
   pre-commit install
   ```
 3. **Run pre-commit manually** (optional):
   ```bash
   pre-commit run --all-files
   ```
 ### Pre-commit Checks
 Our pre-commit configuration includes:
 - **Trailing whitespace removal**
 - **End-of-file fixing**
 - **YAML validation**
 - **Large file prevention**
 - **Merge conflict detection**
 - **Debug statement detection**
 - **Code formatting with ruff**
 - **Code linting with ruff**
 ## 🧪 Testing
 ### Running Tests
 ```bash
 # Run all tests
 uv run pytest
 # Run specific test file
 uv run pytest test/test_filename.py
 # Run with coverage
 uv run pytest --cov=leann
 ```
 ### Writing Tests
 - Place tests in the `test/` directory
 - Follow the naming convention `test_*.py`
 - Use descriptive test names that explain what's being tested
 - Include both positive and negative test cases
 ## 📝 Code Style
 We use `ruff` for both linting and formatting to ensure consistent code style.
 ### Format Your Code
 ```bash
 # Format all files
 ruff format
 # Check formatting without changing files
 ruff format --check
 ```
 ### Lint Your Code
 ```bash
 # Run linter with auto-fix
 ruff check --fix
 # Just check without fixing
 ruff check
 ```
 ### Style Guidelines
 - Follow PEP 8 conventions
 - Use descriptive variable names
 - Add type hints where appropriate
 - Write docstrings for all public functions and classes
 - Keep functions focused and single-purpose
 ## 🚦 CI/CD
 Our CI pipeline runs automatically on all pull requests. It includes:
 1. **Linting and Formatting**: Ensures code follows our style guidelines
 2. **Multi-platform builds**: Tests on Ubuntu and macOS
 3. **Python version matrix**: Tests on Python 3.9-3.13
 4. **Wheel building**: Ensures packages can be built and distributed
 ### CI Commands
 The CI uses the same commands as pre-commit to ensure consistency:
 ```bash
 # Linting
 ruff check .
 # Format checking
 ruff format --check .
 ```
 Make sure your code passes these checks locally before pushing!
 ## 🔄 Pull Request Process
 1. **Fork the repository** and create your branch from `main`:
   ```bash
   git checkout -b feature/your-feature-name
   ```
 2. **Make your changes**:
   - Write clean, documented code
   - Add tests for new functionality
   - Update documentation as needed
 3. **Run pre-commit checks**:
   ```bash
   pre-commit run --all-files
   ```
 4. **Test your changes**:
   ```bash
   uv run pytest
   ```
 5. **Commit with descriptive messages**:
   ```bash
   git commit -m "feat: add new search algorithm"
   ```
   Follow [Conventional Commits](https://www.conventionalcommits.org/):
   - `feat:` for new features
   - `fix:` for bug fixes
   - `docs:` for documentation changes
   - `test:` for test additions/changes
   - `refactor:` for code refactoring
   - `perf:` for performance improvements
 6. **Push and create a pull request**:
   - Provide a clear description of your changes
   - Reference any related issues
   - Include examples or screenshots if applicable
 ## 📚 Documentation
 When adding new features or making significant changes:
 1. Update relevant documentation in `/docs`
 2. Add docstrings to new functions/classes
 3. Update README.md if needed
 4. Include usage examples
 ## 🤔 Getting Help
 - **Discord**: Join our community for discussions
 - **Issues**: Check existing issues or create a new one
 - **Discussions**: For general questions and ideas
 ## 📄 License
 By contributing, you agree that your contributions will be licensed under the same license as the project (MIT).
 ---
 Thank you for contributing to LEANN! Every contribution, no matter how small, helps make the project better for everyone. 🌟
--- a/docs/RELEASE.md
+++ b/docs/RELEASE.md
@@ -0,0 +1,22 @@
 # Release Guide
 ## Setup (One-time)
 Add `PYPI_API_TOKEN` to GitHub Secrets:
 1. Get token: https://pypi.org/manage/account/token/
 2. Add to secrets: Settings → Secrets → Actions → `PYPI_API_TOKEN`
 ## Release (One-click)
 1. Go to: https://github.com/yichuan-w/LEANN/actions/workflows/release-manual.yml
 2. Click "Run workflow"
 3. Enter version: `0.1.2`
 4. Click green "Run workflow" button
 That's it! The workflow will automatically:
 - ✅ Update version in all packages
 - ✅ Build all packages
 - ✅ Publish to PyPI
 - ✅ Create GitHub tag and release
 Check progress: https://github.com/yichuan-w/LEANN/actions
--- a/docs/THINKING_BUDGET_FEATURE.md
+++ b/docs/THINKING_BUDGET_FEATURE.md
@@ -0,0 +1,123 @@
 # Thinking Budget Feature Implementation
 ## Overview
 This document describes the implementation of the **thinking budget** feature for LEANN, which allows users to control the computational effort for reasoning models like GPT-Oss:20b.
 ## Feature Description
 The thinking budget feature provides three levels of computational effort for reasoning models:
 - **`low`**: Fast responses, basic reasoning (default for simple queries)
 - **`medium`**: Balanced speed and reasoning depth
 - **`high`**: Maximum reasoning effort, best for complex analytical questions
 ## Implementation Details
 ### 1. Command Line Interface
 Added `--thinking-budget` parameter to both CLI and RAG examples:
 ```bash
 # LEANN CLI
 leann ask my-index --llm ollama --model gpt-oss:20b --thinking-budget high
 # RAG Examples
 python apps/email_rag.py --llm ollama --llm-model gpt-oss:20b --thinking-budget high
 python apps/document_rag.py --llm openai --llm-model o3 --thinking-budget medium
 ```
 ### 2. LLM Backend Support
 #### Ollama Backend (`packages/leann-core/src/leann/chat.py`)
 ```python
 def ask(self, prompt: str, **kwargs) -> str:
    # Handle thinking budget for reasoning models
    options = kwargs.copy()
    thinking_budget = kwargs.get("thinking_budget")
    if thinking_budget:
        options.pop("thinking_budget", None)
        if thinking_budget in ["low", "medium", "high"]:
            options["reasoning"] = {"effort": thinking_budget, "exclude": False}
 ```
 **API Format**: Uses Ollama's `reasoning` parameter with `effort` and `exclude` fields.
 #### OpenAI Backend (`packages/leann-core/src/leann/chat.py`)
 ```python
 def ask(self, prompt: str, **kwargs) -> str:
    # Handle thinking budget for reasoning models
    thinking_budget = kwargs.get("thinking_budget")
    if thinking_budget and thinking_budget in ["low", "medium", "high"]:
        # Check if this is an o-series model
        o_series_models = ["o3", "o3-mini", "o4-mini", "o1", "o3-pro", "o3-deep-research"]
        if any(model in self.model for model in o_series_models):
            params["reasoning_effort"] = thinking_budget
 ```
 **API Format**: Uses OpenAI's `reasoning_effort` parameter for o-series models.
 ### 3. Parameter Propagation
 The thinking budget parameter is properly propagated through the LEANN architecture:
 1. **CLI** (`packages/leann-core/src/leann/cli.py`): Captures `--thinking-budget` argument
 2. **Base RAG** (`apps/base_rag_example.py`): Adds parameter to argument parser
 3. **LeannChat** (`packages/leann-core/src/leann/api.py`): Passes `llm_kwargs` to LLM
 4. **LLM Interface**: Handles the parameter in backend-specific implementations
 ## Files Modified
 ### Core Implementation
 - `packages/leann-core/src/leann/chat.py`: Added thinking budget support to OllamaChat and OpenAIChat
 - `packages/leann-core/src/leann/cli.py`: Added `--thinking-budget` argument
 - `apps/base_rag_example.py`: Added thinking budget parameter to RAG examples
 ### Documentation
 - `README.md`: Added thinking budget parameter to usage examples
 - `docs/configuration-guide.md`: Added detailed documentation and usage guidelines
 ### Examples
 - `examples/thinking_budget_demo.py`: Comprehensive demo script with usage examples
 ## Usage Examples
 ### Basic Usage
 ```bash
 # High reasoning effort for complex questions
 leann ask my-index --llm ollama --model gpt-oss:20b --thinking-budget high
 # Medium reasoning for balanced performance
 leann ask my-index --llm openai --model gpt-4o --thinking-budget medium
 # Low reasoning for fast responses
 leann ask my-index --llm ollama --model gpt-oss:20b --thinking-budget low
 ```
 ### RAG Examples
 ```bash
 # Email RAG with high reasoning
 python apps/email_rag.py --llm ollama --llm-model gpt-oss:20b --thinking-budget high
 # Document RAG with medium reasoning
 python apps/document_rag.py --llm openai --llm-model gpt-4o --thinking-budget medium
 ```
 ## Supported Models
 ### Ollama Models
 - **GPT-Oss:20b**: Primary target model with reasoning capabilities
 - **Other reasoning models**: Any Ollama model that supports the `reasoning` parameter
 ### OpenAI Models
 - **o3, o3-mini, o4-mini, o1**: o-series reasoning models with `reasoning_effort` parameter
 - **GPT-OSS models**: Models that support reasoning capabilities
 ## Testing
 The implementation includes comprehensive testing:
 - Parameter handling verification
 - Backend-specific API format validation
 - CLI argument parsing tests
 - Integration with existing LEANN architecture
--- a/docs/code/embedding_model_compare.py
+++ b/docs/code/embedding_model_compare.py
@@ -0,0 +1,98 @@
 """
 Comparison between Sentence Transformers and OpenAI embeddings
 This example shows how different embedding models handle complex queries
 and demonstrates the differences between local and API-based embeddings.
 """
 import numpy as np
 from leann.embedding_compute import compute_embeddings
 # OpenAI API key should be set as environment variable
 # export OPENAI_API_KEY="your-api-key-here"
 # Test data
 conference_text = "[Title]: COLING 2025 Conference\n[URL]: https://coling2025.org/"
 browser_text = "[Title]: Browser Use Tool\n[URL]: https://github.com/browser-use"
 # Two queries with same intent but different wording
 query1 = "Tell me my browser history about some conference i often visit"
 query2 = "browser history about conference I often visit"
 texts = [query1, query2, conference_text, browser_text]
 def cosine_similarity(a, b):
    return np.dot(a, b)  # Already normalized
 def analyze_embeddings(embeddings, model_name):
    print(f"\n=== {model_name} Results ===")
    # Results for Query 1
    sim1_conf = cosine_similarity(embeddings[0], embeddings[2])
    sim1_browser = cosine_similarity(embeddings[0], embeddings[3])
    print(f"Query 1: '{query1}'")
    print(f"  → Conference similarity: {sim1_conf:.4f} {'✓' if sim1_conf > sim1_browser else ''}")
    print(
        f"  → Browser similarity:    {sim1_browser:.4f} {'✓' if sim1_browser > sim1_conf else ''}"
    )
    print(f"  Winner: {'Conference' if sim1_conf > sim1_browser else 'Browser'}")
    # Results for Query 2
    sim2_conf = cosine_similarity(embeddings[1], embeddings[2])
    sim2_browser = cosine_similarity(embeddings[1], embeddings[3])
    print(f"\nQuery 2: '{query2}'")
    print(f"  → Conference similarity: {sim2_conf:.4f} {'✓' if sim2_conf > sim2_browser else ''}")
    print(
        f"  → Browser similarity:    {sim2_browser:.4f} {'✓' if sim2_browser > sim2_conf else ''}"
    )
    print(f"  Winner: {'Conference' if sim2_conf > sim2_browser else 'Browser'}")
    # Show the impact
    print("\n=== Impact Analysis ===")
    print(f"Conference similarity change: {sim2_conf - sim1_conf:+.4f}")
    print(f"Browser similarity change:    {sim2_browser - sim1_browser:+.4f}")
    if sim1_conf > sim1_browser and sim2_browser > sim2_conf:
        print("❌ FLIP: Adding 'browser history' flips winner from Conference to Browser!")
    elif sim1_conf > sim1_browser and sim2_conf > sim2_browser:
        print("✅ STABLE: Conference remains winner in both queries")
    elif sim1_browser > sim1_conf and sim2_browser > sim2_conf:
        print("✅ STABLE: Browser remains winner in both queries")
    else:
        print("🔄 MIXED: Results vary between queries")
    return {
        "query1_conf": sim1_conf,
        "query1_browser": sim1_browser,
        "query2_conf": sim2_conf,
        "query2_browser": sim2_browser,
    }
 # Test Sentence Transformers
 print("Testing Sentence Transformers (facebook/contriever)...")
 try:
    st_embeddings = compute_embeddings(texts, "facebook/contriever", mode="sentence-transformers")
    st_results = analyze_embeddings(st_embeddings, "Sentence Transformers (facebook/contriever)")
 except Exception as e:
    print(f"❌ Sentence Transformers failed: {e}")
    st_results = None
 # Test OpenAI
 print("\n" + "=" * 60)
 print("Testing OpenAI (text-embedding-3-small)...")
 try:
    openai_embeddings = compute_embeddings(texts, "text-embedding-3-small", mode="openai")
    openai_results = analyze_embeddings(openai_embeddings, "OpenAI (text-embedding-3-small)")
 except Exception as e:
    print(f"❌ OpenAI failed: {e}")
    openai_results = None
 # Compare results
 if st_results and openai_results:
    print("\n" + "=" * 60)
    print("=== COMPARISON SUMMARY ===")
--- a/docs/configuration-guide.md
+++ b/docs/configuration-guide.md
@@ -0,0 +1,285 @@
 # LEANN Configuration Guide
 This guide helps you optimize LEANN for different use cases and understand the trade-offs between various configuration options.
 ## Getting Started: Simple is Better
 When first trying LEANN, start with a small dataset to quickly validate your approach:
 **For document RAG**: The default `data/` directory works perfectly - includes 2 AI research papers, Pride and Prejudice literature, and a technical report
 ```bash
 python -m apps.document_rag --query "What techniques does LEANN use?"
 ```
 **For other data sources**: Limit the dataset size for quick testing
 ```bash
 # WeChat: Test with recent messages only
 python -m apps.wechat_rag --max-items 100 --query "What did we discuss about the project timeline?"
 # Browser history: Last few days
 python -m apps.browser_rag --max-items 500 --query "Find documentation about vector databases"
 # Email: Recent inbox
 python -m apps.email_rag --max-items 200 --query "Who sent updates about the deployment status?"
 ```
 Once validated, scale up gradually:
 - 100 documents → 1,000 → 10,000 → full dataset (`--max-items -1`)
 - This helps identify issues early before committing to long processing times
 ## Embedding Model Selection: Understanding the Trade-offs
 Based on our experience developing LEANN, embedding models fall into three categories:
 ### Small Models (< 100M parameters)
 **Example**: `sentence-transformers/all-MiniLM-L6-v2` (22M params)
 - **Pros**: Lightweight, fast for both indexing and inference
 - **Cons**: Lower semantic understanding, may miss nuanced relationships
 - **Use when**: Speed is critical, handling simple queries, interactive mode, or just experimenting with LEANN. If time is not a constraint, consider using a larger/better embedding model
 ### Medium Models (100M-500M parameters)
 **Example**: `facebook/contriever` (110M params), `BAAI/bge-base-en-v1.5` (110M params)
 - **Pros**: Balanced performance, good multilingual support, reasonable speed
 - **Cons**: Requires more compute than small models
 - **Use when**: Need quality results without extreme compute requirements, general-purpose RAG applications
 ### Large Models (500M+ parameters)
 **Example**: `Qwen/Qwen3-Embedding-0.6B` (600M params), `intfloat/multilingual-e5-large` (560M params)
 - **Pros**: Best semantic understanding, captures complex relationships, excellent multilingual support. **Qwen3-Embedding-0.6B achieves nearly OpenAI API performance!**
 - **Cons**: Slower inference, longer index build times
 - **Use when**: Quality is paramount and you have sufficient compute resources. **Highly recommended** for production use
 ### Quick Start: Cloud and Local Embedding Options
 **OpenAI Embeddings (Fastest Setup)**
 For immediate testing without local model downloads:
 ```bash
 # Set OpenAI embeddings (requires OPENAI_API_KEY)
 --embedding-mode openai --embedding-model text-embedding-3-small
 ```
 **Ollama Embeddings (Privacy-Focused)**
 For local embeddings with complete privacy:
 ```bash
 # First, pull an embedding model
 ollama pull nomic-embed-text
 # Use Ollama embeddings
 --embedding-mode ollama --embedding-model nomic-embed-text
 ```
 <details>
 <summary><strong>Cloud vs Local Trade-offs</strong></summary>
 **OpenAI Embeddings** (`text-embedding-3-small/large`)
 - **Pros**: No local compute needed, consistently fast, high quality
 - **Cons**: Requires API key, costs money, data leaves your system, [known limitations with certain languages](https://yichuan-w.github.io/blog/lessons_learned_in_dev_leann/)
 - **When to use**: Prototyping, non-sensitive data, need immediate results
 **Local Embeddings**
 - **Pros**: Complete privacy, no ongoing costs, full control, can sometimes outperform OpenAI embeddings
 - **Cons**: Slower than cloud APIs, requires local compute resources
 - **When to use**: Production systems, sensitive data, cost-sensitive applications
 </details>
 ## Index Selection: Matching Your Scale
 ### HNSW (Hierarchical Navigable Small World)
 **Best for**: Small to medium datasets (< 10M vectors) - **Default and recommended for extreme low storage**
 - Full recomputation required
 - High memory usage during build phase
 - Excellent recall (95%+)
 ```bash
 # Optimal for most use cases
 --backend-name hnsw --graph-degree 32 --build-complexity 64
 ```
 ### DiskANN
 **Best for**: Large datasets (> 10M vectors, 10GB+ index size) - **⚠️ Beta version, still in active development**
 - Uses Product Quantization (PQ) for coarse filtering during graph traversal
 - Novel approach: stores only PQ codes, performs rerank with exact computation in final step
 - Implements a corner case of double-queue: prunes all neighbors and recomputes at the end
 ```bash
 # For billion-scale deployments
 --backend-name diskann --graph-degree 64 --build-complexity 128
 ```
 ## LLM Selection: Engine and Model Comparison
 ### LLM Engines
 **OpenAI** (`--llm openai`)
 - **Pros**: Best quality, consistent performance, no local resources needed
 - **Cons**: Costs money ($0.15-2.5 per million tokens), requires internet, data privacy concerns
 - **Models**: `gpt-4o-mini` (fast, cheap), `gpt-4o` (best quality), `o3` (reasoning), `o3-mini` (reasoning, cheaper)
 - **Thinking Budget**: Use `--thinking-budget low/medium/high` for o-series reasoning models (o3, o3-mini, o4-mini)
 - **Note**: Our current default, but we recommend switching to Ollama for most use cases
 **Ollama** (`--llm ollama`)
 - **Pros**: Fully local, free, privacy-preserving, good model variety
 - **Cons**: Requires local GPU/CPU resources, slower than cloud APIs, need to install extra [ollama app](https://github.com/ollama/ollama?tab=readme-ov-file#ollama) and pre-download models by `ollama pull`
 - **Models**: `qwen3:0.6b` (ultra-fast), `qwen3:1.7b` (balanced), `qwen3:4b` (good quality), `qwen3:7b` (high quality), `deepseek-r1:1.5b` (reasoning)
 - **Thinking Budget**: Use `--thinking-budget low/medium/high` for reasoning models like GPT-Oss:20b
 **HuggingFace** (`--llm hf`)
 - **Pros**: Free tier available, huge model selection, direct model loading (vs Ollama's server-based approach)
 - **Cons**: More complex initial setup
 - **Models**: `Qwen/Qwen3-1.7B-FP8`
 ## Parameter Tuning Guide
 ### Search Complexity Parameters
 **`--build-complexity`** (index building)
 - Controls thoroughness during index construction
 - Higher = better recall but slower build
 - Recommendations:
  - 32: Quick prototyping
  - 64: Balanced (default)
  - 128: Production systems
  - 256: Maximum quality
 **`--search-complexity`** (query time)
 - Controls search thoroughness
 - Higher = better results but slower
 - Recommendations:
  - 16: Fast/Interactive search
  - 32: High quality with diversity
  - 64+: Maximum accuracy
 ### Top-K Selection
 **`--top-k`** (number of retrieved chunks)
 - More chunks = better context but slower LLM processing
 - Should be always smaller than `--search-complexity`
 - Guidelines:
  - 10-20: General questions (default: 20)
  - 30+: Complex multi-hop reasoning requiring comprehensive context
 **Trade-off formula**:
 - Retrieval time ∝ log(n) × search_complexity
 - LLM processing time ∝ top_k × chunk_size
 - Total context = top_k × chunk_size tokens
 ### Thinking Budget for Reasoning Models
 **`--thinking-budget`** (reasoning effort level)
 - Controls the computational effort for reasoning models
 - Options: `low`, `medium`, `high`
 - Guidelines:
  - `low`: Fast responses, basic reasoning (default for simple queries)
  - `medium`: Balanced speed and reasoning depth
  - `high`: Maximum reasoning effort, best for complex analytical questions
 - **Supported Models**:
  - **Ollama**: `gpt-oss:20b`, `gpt-oss:120b`
  - **OpenAI**: `o3`, `o3-mini`, `o4-mini`, `o1` (o-series reasoning models)
 - **Note**: Models without reasoning support will show a warning and proceed without reasoning parameters
 - **Example**: `--thinking-budget high` for complex analytical questions
 **📖 For detailed usage examples and implementation details, check out [Thinking Budget Documentation](THINKING_BUDGET_FEATURE.md)**
 **💡 Quick Examples:**
 ```bash
 # OpenAI o-series reasoning model
 python apps/document_rag.py --query "What are the main techniques LEANN explores?" \
  --index-dir hnswbuild --backend hnsw \
  --llm openai --llm-model o3 --thinking-budget medium
 # Ollama reasoning model
 python apps/document_rag.py --query "What are the main techniques LEANN explores?" \
  --index-dir hnswbuild --backend hnsw \
  --llm ollama --llm-model gpt-oss:20b --thinking-budget high
 ```
 ### Graph Degree (HNSW/DiskANN)
 **`--graph-degree`**
 - Number of connections per node in the graph
 - Higher = better recall but more memory
 - HNSW: 16-32 (default: 32)
 - DiskANN: 32-128 (default: 64)
 ## Performance Optimization Checklist
 ### If Embedding is Too Slow
 1. **Switch to smaller model**:
   ```bash
   # From large model
   --embedding-model Qwen/Qwen3-Embedding-0.6B
   # To small model
   --embedding-model sentence-transformers/all-MiniLM-L6-v2
   ```
 2. **Limit dataset size for testing**:
   ```bash
   --max-items 1000  # Process first 1k items only
   ```
 3. **Use MLX on Apple Silicon** (optional optimization):
   ```bash
   --embedding-mode mlx --embedding-model mlx-community/Qwen3-Embedding-0.6B-8bit
   ```
    MLX might not be the best choice, as we tested and found that it only offers 1.3x acceleration compared to HF, so maybe using ollama is a better choice for embedding generation
 4. **Use Ollama**
   ```bash
   --embedding-mode ollama --embedding-model nomic-embed-text
   ```
   To discover additional embedding models in ollama, check out https://ollama.com/search?c=embedding or read more about embedding models at https://ollama.com/blog/embedding-models, please do check the model size that works best for you
 ### If Search Quality is Poor
 1. **Increase retrieval count**:
   ```bash
   --top-k 30  # Retrieve more candidates
   ```
 2. **Upgrade embedding model**:
   ```bash
   # For English
   --embedding-model BAAI/bge-base-en-v1.5
   # For multilingual
   --embedding-model intfloat/multilingual-e5-large
   ```
 ## Understanding the Trade-offs
 Every configuration choice involves trade-offs:
 | Factor | Small/Fast | Large/Quality |
 |--------|------------|---------------|
 | Embedding Model | `all-MiniLM-L6-v2` | `Qwen/Qwen3-Embedding-0.6B` |
 | Chunk Size | 512 tokens | 128 tokens |
 | Index Type | HNSW | DiskANN |
 | LLM | `qwen3:1.7b` | `gpt-4o` |
 The key is finding the right balance for your specific use case. Start small and simple, measure performance, then scale up only where needed.
 ## Deep Dive: Critical Configuration Decisions
 ### When to Disable Recomputation
 LEANN's recomputation feature provides exact distance calculations but can be disabled for extreme QPS requirements:
 ```bash
 --no-recompute  # Disable selective recomputation
 ```
 **Trade-offs**:
 - **With recomputation** (default): Exact distances, best quality, higher latency, minimal storage (only stores metadata, recomputes embeddings on-demand)
 - **Without recomputation**: Must store full embeddings, significantly higher memory and storage usage (10-100x more), but faster search
 **Disable when**:
 - You have abundant storage and memory
 - Need extremely low latency (< 100ms)
 - Running a read-heavy workload where storage cost is acceptable
 ## Further Reading
 - [Lessons Learned Developing LEANN](https://yichuan-w.github.io/blog/lessons_learned_in_dev_leann/)
 - [LEANN Technical Paper](https://arxiv.org/abs/2506.08276)
 - [DiskANN Original Paper](https://papers.nips.cc/paper/2019/file/09853c7fb1d3f8ee67a61b6bf4a7f8e6-Paper.pdf)
--- a/docs/faq.md
+++ b/docs/faq.md
@@ -0,0 +1,10 @@
 # FAQ
 ## 1. My building time seems long
 You can speed up the process by using a lightweight embedding model. Add this to your arguments:
 ```bash
 --embedding-model sentence-transformers/all-MiniLM-L6-v2
 ```
 **Model sizes:** `all-MiniLM-L6-v2` (30M parameters), `facebook/contriever` (~100M parameters), `Qwen3-0.6B` (600M parameters)
--- a/docs/features.md
+++ b/docs/features.md
@@ -0,0 +1,22 @@
 # ✨ Detailed Features
 ## 🔥 Core Features
 - **🔄 Real-time Embeddings** - Eliminate heavy embedding storage with dynamic computation using optimized ZMQ servers and highly optimized search paradigm (overlapping and batching) with highly optimized embedding engine
 - **📈 Scalable Architecture** - Handles millions of documents on consumer hardware; the larger your dataset, the more LEANN can save
 - **🎯 Graph Pruning** - Advanced techniques to minimize the storage overhead of vector search to a limited footprint
 - **🏗️ Pluggable Backends** - HNSW/FAISS (default), with optional DiskANN for large-scale deployments
 ## 🛠️ Technical Highlights
 - **🔄 Recompute Mode** - Highest accuracy scenarios while eliminating vector storage overhead
 - **⚡ Zero-copy Operations** - Minimize IPC overhead by transferring distances instead of embeddings
 - **🚀 High-throughput Embedding Pipeline** - Optimized batched processing for maximum efficiency
 - **🎯 Two-level Search** - Novel coarse-to-fine search overlap for accelerated query processing (optional)
 - **💾 Memory-mapped Indices** - Fast startup with raw text mapping to reduce memory overhead
 - **🚀 MLX Support** - Ultra-fast recompute/build with quantized embedding models, accelerating building and search ([minimal example](../examples/mlx_demo.py))
 ## 🎨 Developer Experience
 - **Simple Python API** - Get started in minutes
 - **Extensible backend system** - Easy to add new algorithms
 - **Comprehensive examples** - From basic usage to production deployment
--- a/docs/normalized_embeddings.md
+++ b/docs/normalized_embeddings.md
@@ -0,0 +1,75 @@
 # Normalized Embeddings Support in LEANN
 LEANN now automatically detects normalized embedding models and sets the appropriate distance metric for optimal performance.
 ## What are Normalized Embeddings?
 Normalized embeddings are vectors with L2 norm = 1 (unit vectors). These embeddings are optimized for cosine similarity rather than Maximum Inner Product Search (MIPS).
 ## Automatic Detection
 When you create a `LeannBuilder` instance with a normalized embedding model, LEANN will:
 1. **Automatically set `distance_metric="cosine"`** if not specified
 2. **Show a warning** if you manually specify a different distance metric
 3. **Provide optimal search performance** with the correct metric
 ## Supported Normalized Embedding Models
 ### OpenAI
 All OpenAI text embedding models are normalized:
 - `text-embedding-ada-002`
 - `text-embedding-3-small`
 - `text-embedding-3-large`
 ### Voyage AI
 All Voyage AI embedding models are normalized:
 - `voyage-2`
 - `voyage-3`
 - `voyage-large-2`
 - `voyage-multilingual-2`
 - `voyage-code-2`
 ### Cohere
 All Cohere embedding models are normalized:
 - `embed-english-v3.0`
 - `embed-multilingual-v3.0`
 - `embed-english-light-v3.0`
 - `embed-multilingual-light-v3.0`
 ## Example Usage
 ```python
 from leann.api import LeannBuilder
 # Automatic detection - will use cosine distance
 builder = LeannBuilder(
    backend_name="hnsw",
    embedding_model="text-embedding-3-small",
    embedding_mode="openai"
 )
 # Warning: Detected normalized embeddings model 'text-embedding-3-small'...
 # Automatically setting distance_metric='cosine'
 # Manual override (not recommended)
 builder = LeannBuilder(
    backend_name="hnsw",
    embedding_model="text-embedding-3-small",
    embedding_mode="openai",
    distance_metric="mips"  # Will show warning
 )
 # Warning: Using 'mips' distance metric with normalized embeddings...
 ```
 ## Non-Normalized Embeddings
 Models like `facebook/contriever` and other sentence-transformers models that are not normalized will continue to use MIPS by default, which is optimal for them.
 ## Why This Matters
 Using the wrong distance metric with normalized embeddings can lead to:
 - **Poor search quality** due to HNSW's early termination with narrow score ranges
 - **Incorrect ranking** of search results
 - **Suboptimal performance** compared to using the correct metric
 For more details on why this happens, see our analysis in the [embedding detection code](../packages/leann-core/src/leann/api.py) which automatically handles normalized embeddings and MIPS distance metric issues.
--- a/docs/roadmap.md
+++ b/docs/roadmap.md
@@ -0,0 +1,21 @@
 # 📈 Roadmap
 ## 🎯 Q2 2025
 - [X] HNSW backend integration
 - [X] DiskANN backend with MIPS/L2/Cosine support
 - [X] Real-time embedding pipeline
 - [X] Memory-efficient graph pruning
 ## 🚀 Q3 2025
 - [ ] Advanced caching strategies
 - [ ] Add contextual-retrieval https://www.anthropic.com/news/contextual-retrieval
 - [ ] Add sleep-time-compute and summarize agent! to summarilze the file on computer!
 - [ ] Add OpenAI recompute API
 ## 🌟 Q4 2025
 - [ ] Integration with LangChain/LlamaIndex
 - [ ] Visual similarity search
 - [ ] Query rewrtiting, rerank and expansion
--- a/examples/simple_demo.py
+++ b/examples/simple_demo.py
@@ -1,16 +1,23 @@
 """
 Simple demo showing basic leann usage
-Run: uv run python examples/simple_demo.py
+Run: uv run python examples/basic_demo.py
 """
 import argparse
-from leann import LeannBuilder, LeannSearcher, LeannChat
+
 from leann import LeannBuilder, LeannChat, LeannSearcher
 def main():
-    parser = argparse.ArgumentParser(description="Simple demo of Leann with selectable embedding models.")
+    parser = argparse.ArgumentParser(
-    parser.add_argument("--embedding_model", type=str, default="sentence-transformers/all-mpnet-base-v2",
+        description="Simple demo of Leann with selectable embedding models."
-                        help="The embedding model to use, e.g., 'sentence-transformers/all-mpnet-base-v2' or 'text-embedding-ada-002'.")
+    )
    parser.add_argument(
        "--embedding_model",
        type=str,
        default="sentence-transformers/all-mpnet-base-v2",
        help="The embedding model to use, e.g., 'sentence-transformers/all-mpnet-base-v2' or 'text-embedding-ada-002'.",
    )
    args = parser.parse_args()
    print(f"=== Leann Simple Demo with {args.embedding_model} ===")
@@ -74,7 +81,7 @@ def main():
        print()
    print("Demo completed! Try running:")
-    print("   uv run python examples/document_search.py")
+    print("   uv run python apps/document_rag.py")
 if __name__ == "__main__":
--- a/examples/data/README.md
+++ b/examples/data/README.md
@@ -1,82 +0,0 @@
 # 盘古之殇：华为诺亚盘古大模型研发历程的心酸与黑暗
 各位好，
 我是一名盘古大模型团队，华为诺亚方舟实验室的员工。
 首先为自证身份，列举一些细节：
 1. 现诺亚主任，前算法应用部部长，后改名为小模型实验室的主任王云鹤。前诺亚主任：姚骏（大家称姚老师）。几个实验室主任：唐睿明（明哥，明队，已离职），尚利峰，张维（维哥），郝建业（郝老师），刘武龙（称呼为武龙所）等。其他骨干成员和专家陆续有很多人离职。
 2. 我们隶属于“四野”这个组织。四野下属有许多纵队，基础语言大模型是四纵。王云鹤的小模型是十六纵队。我们参加过苏州的集结，有各种月份的时间节点。在苏州攻关会颁发任务令，需要在节点前达成目标。苏州集结会把各地的人员都集中在苏州研究所，平常住宾馆，比如在甪直的酒店，与家人孩子天各一方。
 3. 在苏州集结的时候周六默认上班，非常辛苦，不过周六有下午茶，有一次还有小龙虾。在苏州研究所的工位搬迁过一次，从一栋楼换到了另一栋。苏州研究所楼栋都是欧式装修，门口有大坡，里面景色很不错。去苏州集结一般至少要去一周，甚至更久，多的人甚至一两个月都回不了家。
 4. 诺亚曾经传说是研究型的，但是来了之后因为在四野做大模型项目，项目成员完全变成了交付型的，且充满了例会，评审，汇报。很多时候做实验都要申请。团队需要对接终端小艺，华为云，ICT等诸多业务线，交付压力不小。
 5. 诺亚研发的盘古模型早期内部代号叫做“盘古智子”，一开始只有内部需要申请试用的网页版，到后续迫于压力在welink上接入和公测开放。
 这些天发生关于质疑盘古大模型抄袭千问的事情闹的沸沸扬扬。作为一个盘古团队的成员，我最近夜夜辗转反侧，难以入眠。盘古的品牌受到如此大的影响，一方面，我自私的为我的职业发展担忧，也为自己过去的努力工作感到不值。另一方面，由于有人开始揭露这些事情我内心又感到大快人心。在多少个日日夜夜，我们对内部某些人一次次靠着造假而又获得了无数利益的行为咬牙切齿而又无能为力。这种压抑和羞辱也逐渐消磨了我对华为的感情，让我在这里的时日逐渐浑浑噩噩，迷茫无措，时常怀疑自己的人生和自我价值。
 我承认我是一个懦弱的人，作为一个小小的打工人，我不仅不敢和王云鹤等内部手眼通天的人做对，更不敢和华为这样的庞然大物做对。我很怕失去我的工作，毕竟我也有家人和孩子，所以我打心眼里很佩服揭露者。但是，看到内部还在试图洗地掩盖事实，蒙蔽公众的时候，我实在不能容忍了。我也希望勇敢一次，顺从自己本心。就算自损八百，我也希望能伤敌一千。我决定把我在这里的所见所闻（部分来自于同事口述）公布出来，关于盘古大模型的“传奇故事”：
 华为确实主要在昇腾卡上训练大模型（小模型实验室有不少英伟达的卡，他们之前也会用来训练，后面转移到昇腾）。曾经我被华为“打造世界第二选择”的决心而折服，我本身也曾经对华为有深厚的感情。我们陪着昇腾一步步摸爬滚打，从充满bug到现在能训出模型，付出了巨大的心血和代价。
 最初我们的算力非常有限，在910A上训练模型。那会只支持fp16，训练的稳定性远不如bf16。盘古的moe开始很早，23年就主要是训练38Bmoe模型和后续的71B dense模型。71B的dense模型通过扩增变成了第一代的135Bdense模型，后面主力模型也逐渐在910B上训练。
 71B和135B模型都有一个巨大的硬伤就是tokenizer。当时使用的tokenizer编码效率极低，每个单个的符号，数字，空格，乃至汉字都会占用一个token。可想而知这会非常浪费算力，且使得模型的效果很差。这时候小模型实验室正好有个自己训的词表。姚老师当时怀疑是不是模型的tokenizer不好（虽然事后来看，他的怀疑是无疑正确的），于是就决定，让71B和135B换tokenizer，因为小模型实验室曾经尝试过。团队缝合了两个tokenizer，开始了tokenizer的更换。71B模型的更换失败了，而135B因为采用了更精细的embedding初始化策略，续训了至少1T的数据后词表总算更换成功，但可想而知，效果并不会变好。
 于此同期，阿里和智谱等国内其他公司在GPU上训练，且已经摸索出了正确的方法，盘古和竞品的差距越来越大。内部一个230B从头训练的dense模型又因为各种原因训练失败，导致项目的状况几乎陷入绝境。面临几个节点的压力以及内部对盘古的强烈质疑时，团队的士气低迷到了极点。团队在算力极其有限的时候，做出了很多努力和挣扎。比如，团队偶然发现当时的38B moe并没有预期moe的效果。于是去掉了moe参数，还原为了13B的dense模型。由于38B的moe源自很早的pangu alpha 13B，架构相对落后，团队进行了一系列的操作，比如切换绝对位置编码到rope，去掉bias，切换为rmsnorm。同时鉴于tokenizer的一些失败和换词表的经验，这个模型的词表也更换为了王云鹤的小模型实验室7B模型所使用的词表。后面这个13B模型进行了扩增续训，变成了第二代38B dense模型（在几个月内这个模型都是主要的盘古中档位模型），曾经具有一定的竞争力。但是，由于更大的135B模型架构落后，且更换词表模型损伤巨大（后续分析发现当时更换的缝合词表有更严重的bug），续训后也与千问等当时国内领先模型存在很大差距。这时由于内部的质疑声和领导的压力也越来越大。团队的状态几乎陷入了绝境。
 在这种情况下，王云鹤和他的小模型实验室出手了。他们声称是从旧的135B参数继承改造而来，通过训练短短的几百B数据，各项指标平均提升了十个点左右。实际上，这就是他们套壳应用到大模型的第一次杰作。华为的外行领导内行，使得领导完全对于这种扯淡的事情没有概念，他们只会觉得肯定是有什么算法创新。经过内部的分析，他们实际上是使用Qwen 1.5 110B续训而来，通过加层，扩增ffn维度，添加盘古pi论文的一些机制得来，凑够了大概135B的参数。实际上，旧的135B有107层，而这个模型只有82层，各种配置也都不一样。新的来路不明的135B训练完很多参数的分布也和Qwen 110B几乎一模一样。连模型代码的类名当时都是Qwen，甚至懒得改名。后续这个模型就是所谓的135B V2。而这个模型当时也提供给了很多下游，甚至包括外部客户。
 这件事对于我们这些认真诚实做事的同事们带来了巨大的冲击，内部很多人其实都知道这件事，甚至包括终端和华为云。我们都戏称以后别叫盘古模型了，叫千古吧。当时团队成员就想向bcg举报了，毕竟这已经是重大的业务造假了。但是后面据说被领导拦了下来，因为更高级别的领导（比如姚老师，以及可能熊总和查老）其实后面也知道了，但是并不管，因为通过套壳拿出好的结果，对他们也是有利的。这件事使得当时团队几位最强的同事开始心灰意冷，离职跑路也逐渐成为挂在嘴边的事。
 此时，盘古似乎迎来了转机。由于前面所述的这些盘古模型基本都是续训和改造而来，当时诺亚完全没有掌握从头训练的技术，何况还是在昇腾的NPU上进行训练。在当时团队的核心成员的极力争取下，盘古开始了第三代模型的训练，付出了巨大的努力后，在数据架构和训练算法方面都与业界逐渐接轨，而这其中的艰辛和小模型实验室的人一点关系都没有。
 一开始团队成员毫无信心，只从一个13B的模型开始训练，但是后面发现效果还不错，于是这个模型后续再次进行了一次参数扩增，变成了第三代的38B，代号38B V3。想必很多产品线的兄弟都对这个模型很熟悉。当时这个模型的tokenizer是基于llama的词表进行扩展的（也是业界常见的做法）。而当时王云鹤的实验室做出来了另一个词表（也就是后续pangu系列的词表）。当时两个词表还被迫进行了一次赛马，最终没有明显的好坏结论。于是，领导当即决定，应该统一词表，使用王云鹤他们的。于是，在后续从头训练的135B V3（也就是对外的Pangu Ultra），便是采用了这个tokenizer。这也解释了很多使用我们模型的兄弟的疑惑，为什么当时同为V3代的两个不同档位的模型，会使用不同的tokenizer。
 我们打心眼里觉得，135B V3是我们四纵团队当时的骄傲。这是第一个真正意义上的，华为全栈自研，正经从头训练的千亿级别的模型，且效果与24年同期竞品可比的。写到这里我已经热泪盈眶，太不容易了。当时为了稳定训练，团队做了大量实验对比，并且多次在模型梯度出现异常的时候进行及时回退重启。这个模型真正做到了后面技术报告所说的训练全程没有一个loss spike。我们克服了不知道多少困难，我们做到了，我们愿用生命和荣誉保证这个模型训练的真实性。多少个凌晨，我们为了它的训练而不眠。在被内部心声骂的一文不值的时候，我们有多么不甘，有多少的委屈，我们挺住了。
 我们这帮人是真的在为打磨国产算力底座燃烧自己的青春啊……客居他乡，我们放弃了家庭，放弃了假期，放弃了健康，放弃了娱乐，抛头颅洒热血，其中的艰辛与困苦，寥寥数笔不足以概括其万一。在各种动员大会上，当时口号中喊出的盘古必胜，华为必胜，我们心里是真的深深被感动。
 然而，我们的所有辛苦的成果，经常被小模型实验室轻飘飘的拿走了。数据，直接要走。代码，直接要走，还要求我们配合适配到能一键运行。我们当时戏称小模型实验室为点鼠标实验室。我们付出辛苦，他们取得荣耀。果然应了那句话，你在负重前行是因为有人替你岁月静好。在这种情况下，越来越多的战友再也坚持不下去了，选择了离开。看到身边那些优秀的同事一个个离职，我的内心又感叹又难过。在这种作战一样的环境下，我们比起同事来说更像是战友。他们在技术上也有无数值得我学习的地方，堪称良师。看到他们去了诸如字节Seed，Deepseek，月之暗面，腾讯和快手等等很多出色的团队，我打心眼里为他们高兴和祝福，脱离了这个辛苦却肮脏的地方。我至今还对一位离职同事的话记忆犹新，ta说：“来这里是我技术生涯中的耻辱，在这里再呆每一天都是浪费生命”。话虽难听却让我无言以对。我担心我自己技术方面的积累不足，以及没法适应互联网公司高淘汰的环境，让我多次想离职的心始终没有迈出这一步。
 盘古除了dense模型，后续也启动了moe的探索。一开始训练的是一个224B的moe模型。而与之平行的，小模型实验室也开启了第二次主要的套壳行动（次要的插曲可能还包括一些别的模型，比如math模型），即这次流传甚广的pangu pro moe 72B。这个模型内部自称是从小模型实验室的7B扩增上来的（就算如此，这也与技术报告不符，何况是套壳qwen 2.5的14b续训）。还记得他们训了没几天，内部的评测就立刻追上了当时的38B V3。AI系统实验室很多兄弟因为需要适配模型，都知道他们的套壳行动，只是迫于各种原因，无法伸张正义。实际上，对于后续训了很久很久的这个模型，Honestagi能够分析出这个量级的相似性我已经很诧异了，因为这个模型为了续训洗参数，所付出的算力甚至早就足够从头训一个同档位的模型了。听同事说他们为了洗掉千问的水印，采取了不少办法，甚至包括故意训了脏数据。这也为学术界研究模型血缘提供了一个前所未有的特殊模范吧。以后新的血缘方法提出可以拿出来溜溜。
 24年底和25年初，在Deepseek v3和r1发布之后，由于其惊艳的技术水平，团队受到了巨大的冲击，也受到了更大的质疑。于是为了紧跟潮流，盘古模仿Deepseek的模型尺寸，开启了718B moe的训练。这个时候，小模型实验室再次出手了。他们选择了套壳Deepseekv3续训。他们通过冻住Deepseek加载的参数，进行训练。连任务加载ckpt的目录都是deepseekv3，改都不改，何其嚣张？与之相反，一些有真正技术信仰的同事，在从头训练另一个718B的moe。但其中出现了各种各样的问题。但是很显然，这个模型怎么可能比直接套壳的好呢？如果不是团队leader坚持，早就被叫停了。
 华为的流程管理之繁重，严重拖累了大模型的研发节奏，例如版本管理，模型血缘，各种流程化，各种可追溯。讽刺的是，小模型实验室的模型似乎从来不受这些流程的约束，想套壳就套壳，想续训就续训，算力源源不断的伸手拿走。这种强烈到近乎魔幻的对比，说明了当前流程管理的情况：只许州官放火，不许百姓点灯。何其可笑？何其可悲？何其可恶？何其可耻！
 HonestAGI的事情出来后，内部让大家不停的研讨分析，如何公关和“回应”。诚然，这个原文的分析也许不够有力，给了王云鹤与小模型实验室他们狡辩和颠倒黑白的机会。为此，这两天我内心感到作呕，时时怀疑自己的人生意义以及苍天无眼。我不奉陪了，我要离职了，同时我也在申请从盘古部分技术报告的作者名单中移除。曾经在这些技术报告上署名是我一生都无法抹除的污点。当时我没想到，他们竟然猖狂到敢开源。我没想到，他们敢如此愚弄世人，大肆宣发。当时，我也许是存了侥幸心理，没有拒绝署名。我相信很多扎实做事的战友，也只是被迫上了贼船，或者不知情。但这件事已经无法挽回，我希望我的余生能够坚持扎实做真正有意义的事，为我当时的软弱和不坚定赎罪。
 深夜写到这里，我已经泪流满面，泣不成声。还记得一些出色的同事离职时，我苦笑问他们要不要发个长长的心声惯例帖，揭露一下现状。对方说：不了，浪费时间，而且我也怕揭露出来你们过的更糟。我当时一下黯然神伤，因为曾经共同为了理想奋斗过的战友已经彻底对华为彻底灰心了。当时大家调侃，我们用着当年共产党的小米加步枪，组织却有着堪比当年国民党的作风。
 曾几何时，我为我们用着小米加步枪打败洋枪洋炮而自豪。
 现在，我累了，我想投降。
 其实时至今日，我还是真心希望华为能认真吸取教训，能做好盘古，把盘古做到世界一流，把昇腾变成英伟达的水平。内部的劣币驱逐良币，使得诺亚乃至华为在短时间内急剧流失了大量出色的大模型人才。相信他们也正在如Deepseek等各个团队闪耀着，施展着他们的抱负才华，为中美在AI的激烈竞赛中奉献力量。我时常感叹，华为不是没有人才，而是根本不知道怎么留住人才。如果给这些人合适的环境，合适的资源，更少的枷锁，更少的政治斗争，盘古何愁不成？
 最后：我以生命，人格和荣誉发誓，我写的以上所有内容均为真实（至少在我有限的认知范围内）。我没有那么高的技术水平以及机会去做详尽扎实的分析，也不敢直接用内部记录举证，怕因为信息安全抓到。但是我相信我很多曾经的战友，会为我作证。在华为内部的兄弟，包括我们曾经服务过的产品线兄弟们，相信本文的无数细节能和你们的印象对照，印证我的说法。你们可能也曾经被蒙骗，但这些残酷的真相不会被尘封。我们奋战过的痕迹，也不应该被扭曲和埋葬。
 写了这么多，某些人肯定想把我找出来，抹杀掉。公司搞不好也想让我噤声乃至追责。如果真的这样，我，乃至我的家人的人身乃至生命安全可能都会受到威胁。为了自我保护，我近期每天会跟大家报平安。
 如果我消失了，就当是我为了真理和理想，为了华为乃至中国能够更好地发展算力和AI而牺牲了吧，我愿埋葬于那片曾经奋斗过的地方。
 诺亚，再见
 2025年7月6日凌晨      写于深圳
 ---
 各位好，
 感谢大家的关心与祝福。我目前暂时安全，但公司应该在进行排查与某些名单收集，后续情况未知。
 我补充一些细节，以免某些人继续颠倒黑白。
 关于135B V2，小模型实验室在迅速地完成套壳并拿完所有套壳带来的好处后（比如任务令表彰和及时激励），因为不想继续支撑下游应用和模型迭代，又把这个烫手山芋甩给了四纵。确实技高一筹，直接把四纵的兄弟们拉下水。同事提供过去一个老旧的模型，最终拿回了一个当时一个魔改的先进的千问。做大模型的人，自己做的模型就像自己孩子一样熟悉，不要把别人都当傻子。就像自家儿子出门一趟，回来个别人家孩子。
 盘古report的署名是不符合学术规范的。例如，135B V3有不少有技术贡献的人，因为作者名额数量限制，劳动成果没有得到应有的回报，团队内曾经有不小的意见。这个模型当时是大家智慧和汗水的结晶，甚至是团队当时的精神支柱，支撑着不少兄弟们继续留在诺亚。所谓的名额限制，以及挂名了一些毫无技术贡献的人（如一些小模型实验室的人），让兄弟们何其心寒。
 ---
 暂时平安。另外，支持我勇于说出真相的战友们 https://github.com/HW-whistleblower/True-Story-of-Pangu/issues/317
--- a/examples/document_search.py
+++ b/examples/document_search.py
@@ -1,146 +0,0 @@
 #!/usr/bin/env python3
 """
 Document search demo with recompute mode
 """
 import os
 from pathlib import Path
 import shutil
 import time
 # Import backend packages to trigger plugin registration
 try:
    import leann_backend_diskann
    import leann_backend_hnsw
    print("INFO: Backend packages imported successfully.")
 except ImportError as e:
    print(f"WARNING: Could not import backend packages. Error: {e}")
 # Import upper-level API from leann-core
 from leann.api import LeannBuilder, LeannSearcher, LeannChat
 def load_sample_documents():
    """Create sample documents for demonstration"""
    docs = [
        {"title": "Intro to Python", "content": "Python is a high-level, interpreted language known for simplicity."},
        {"title": "ML Basics", "content": "Machine learning builds systems that learn from data."},
        {"title": "Data Structures", "content": "Data structures like arrays, lists, and graphs organize data."},
    ]
    return docs
 def main():
    print("==========================================================")
    print("=== Leann Document Search Demo (DiskANN + Recompute) ===")
    print("==========================================================")
    INDEX_DIR = Path("./test_indices")
    INDEX_PATH = str(INDEX_DIR / "documents.diskann")
    BACKEND_TO_TEST = "diskann"
    if INDEX_DIR.exists():
        print(f"--- Cleaning up old index directory: {INDEX_DIR} ---")
        shutil.rmtree(INDEX_DIR)
    # --- 1. Build index ---
    print(f"\n[PHASE 1] Building index using '{BACKEND_TO_TEST}' backend...")
    builder = LeannBuilder(
        backend_name=BACKEND_TO_TEST, 
        graph_degree=32, 
        complexity=64
    )
    documents = load_sample_documents()
    print(f"Loaded {len(documents)} sample documents.")
    for doc in documents:
        builder.add_text(doc["content"], metadata={"title": doc["title"]})
    builder.build_index(INDEX_PATH)
    print(f"\nIndex built!")
    # --- 2. Basic search demo ---
    print(f"\n[PHASE 2] Basic search using '{BACKEND_TO_TEST}' backend...")
    searcher = LeannSearcher(index_path=INDEX_PATH)
    query = "What is machine learning?"
    print(f"\nQuery: '{query}'")
    print("\n--- Basic search mode (PQ computation) ---")
    start_time = time.time()
    results = searcher.search(query, top_k=2)
    basic_time = time.time() - start_time
    print(f"⏱️  Basic search time: {basic_time:.3f} seconds")
    print(">>> Basic search results <<<")
    for i, res in enumerate(results, 1):
        print(f"  {i}. ID: {res.id}, Score: {res.score:.4f}, Text: '{res.text}', Metadata: {res.metadata}")
    # --- 3. Recompute search demo ---
    print(f"\n[PHASE 3] Recompute search using embedding server...")
    print("\n--- Recompute search mode (get real embeddings via network) ---")
    # Configure recompute parameters
    recompute_params = {
        "recompute_beighbor_embeddings": True,  # Enable network recomputation
        "USE_DEFERRED_FETCH": False,           # Don't use deferred fetch
        "skip_search_reorder": True,           # Skip search reordering
        "dedup_node_dis": True,               # Enable node distance deduplication
        "prune_ratio": 0.1,                   # Pruning ratio 10%
        "batch_recompute": False,             # Don't use batch recomputation
        "global_pruning": False,              # Don't use global pruning
        "zmq_port": 5555,                     # ZMQ port
        "embedding_model": "sentence-transformers/all-mpnet-base-v2"
    }
    print("Recompute parameter configuration:")
    for key, value in recompute_params.items():
        print(f"  {key}: {value}")
    print(f"\n🔄 Executing Recompute search...")
    try:
        start_time = time.time()
        recompute_results = searcher.search(query, top_k=2, **recompute_params)
        recompute_time = time.time() - start_time
        print(f"⏱️  Recompute search time: {recompute_time:.3f} seconds")
        print(">>> Recompute search results <<<")
        for i, res in enumerate(recompute_results, 1):
            print(f"  {i}. ID: {res.id}, Score: {res.score:.4f}, Text: '{res.text}', Metadata: {res.metadata}")
        # Compare results
        print(f"\n--- Result comparison ---")
        print(f"Basic search time: {basic_time:.3f} seconds")
        print(f"Recompute time: {recompute_time:.3f} seconds")
        print("\nBasic search vs Recompute results:")
        for i in range(min(len(results), len(recompute_results))):
            basic_score = results[i].score
            recompute_score = recompute_results[i].score
            score_diff = abs(basic_score - recompute_score)
            print(f"  Position {i+1}: PQ={basic_score:.4f}, Recompute={recompute_score:.4f}, Difference={score_diff:.4f}")
        if recompute_time > basic_time:
            print(f"✅ Recompute mode working correctly (more accurate but slower)")
        else:
            print(f"ℹ️  Recompute time is unusually fast, network recomputation may not be enabled")
    except Exception as e:
        print(f"❌ Recompute search failed: {e}")
        print("This usually indicates an embedding server connection issue")
    # --- 4. Chat demo ---
    print(f"\n[PHASE 4] Starting chat session...")
    chat = LeannChat(index_path=INDEX_PATH)
    chat_response = chat.ask(query)
    print(f"You: {query}")
    print(f"Leann: {chat_response}")
    print("\n==========================================================")
    print("✅ Demo finished successfully!")
    print("==========================================================")
 if __name__ == "__main__":
    main()
--- a/examples/email_data/LEANN_email_reader.py
+++ b/examples/email_data/LEANN_email_reader.py
@@ -1,124 +0,0 @@
 import os
 import email
 from pathlib import Path
 from typing import List, Any
 from llama_index.core import Document
 from llama_index.core.readers.base import BaseReader
 def find_all_messages_directories(root: str = None) -> List[Path]:
    """
    Recursively find all 'Messages' directories under the given root.
    Returns a list of Path objects.
    """
    if root is None:
        # Auto-detect user's mail path
        home_dir = os.path.expanduser("~")
        root = os.path.join(home_dir, "Library", "Mail")
    messages_dirs = []
    for dirpath, dirnames, filenames in os.walk(root):
        if os.path.basename(dirpath) == "Messages":
            messages_dirs.append(Path(dirpath))
    return messages_dirs
 class EmlxReader(BaseReader):
    """
    Apple Mail .emlx file reader with embedded metadata.
    Reads individual .emlx files from Apple Mail's storage format.
    """
    def __init__(self, include_html: bool = False) -> None:
        """
        Initialize.
        Args:
            include_html: Whether to include HTML content in the email body (default: False)
        """
        self.include_html = include_html
    def load_data(self, input_dir: str, **load_kwargs: Any) -> List[Document]:
        """
        Load data from the input directory containing .emlx files.
        Args:
            input_dir: Directory containing .emlx files
            **load_kwargs:
                max_count (int): Maximum amount of messages to read.
        """
        docs: List[Document] = []
        max_count = load_kwargs.get('max_count', 1000)
        count = 0
        # Walk through the directory recursively
        for dirpath, dirnames, filenames in os.walk(input_dir):
            # Skip hidden directories
            dirnames[:] = [d for d in dirnames if not d.startswith(".")]
            for filename in filenames:
                if count >= max_count:
                    break
                if filename.endswith(".emlx"):
                    filepath = os.path.join(dirpath, filename)
                    try:
                        # Read the .emlx file
                        with open(filepath, 'r', encoding='utf-8', errors='ignore') as f:
                            content = f.read()
                        # .emlx files have a length prefix followed by the email content
                        # The first line contains the length, followed by the email
                        lines = content.split('\n', 1)
                        if len(lines) >= 2:
                            email_content = lines[1]
                            # Parse the email using Python's email module
                            try:
                                msg = email.message_from_string(email_content)
                                # Extract email metadata
                                subject = msg.get('Subject', 'No Subject')
                                from_addr = msg.get('From', 'Unknown')
                                to_addr = msg.get('To', 'Unknown')
                                date = msg.get('Date', 'Unknown')
                                # Extract email body
                                body = ""
                                if msg.is_multipart():
                                    for part in msg.walk():
                                        if part.get_content_type() == "text/plain" or part.get_content_type() == "text/html":
                                            if part.get_content_type() == "text/html" and not self.include_html:
                                                continue
                                            body += part.get_payload(decode=True).decode('utf-8', errors='ignore')
                                            # break
                                else:
                                    body = msg.get_payload(decode=True).decode('utf-8', errors='ignore')
                                # Create document content with metadata embedded in text
                                doc_content = f"""
 [EMAIL METADATA]
 File: {filename}
 From: {from_addr}
 To: {to_addr}
 Subject: {subject}
 Date: {date}
 [END METADATA]
 {body}
 """
                                # No separate metadata - everything is in the text
                                doc = Document(text=doc_content, metadata={})
                                docs.append(doc)
                                count += 1
                            except Exception as e:
                                print(f"Error parsing email from {filepath}: {e}")
                                continue
                    except Exception as e:
                        print(f"Error reading file {filepath}: {e}")
                        continue
        print(f"Loaded {len(docs)} email documents")
        return docs 
--- a/examples/google_history_reader_leann.py
+++ b/examples/google_history_reader_leann.py
@@ -1,281 +0,0 @@
 import os
 import asyncio
 import argparse
 try:
    import dotenv
    dotenv.load_dotenv()
 except ModuleNotFoundError:
    # python-dotenv is not installed; skip loading environment variables
    dotenv = None
 from pathlib import Path
 from typing import List, Any
 from leann.api import LeannBuilder, LeannSearcher, LeannChat
 from llama_index.core.node_parser import SentenceSplitter
 # dotenv.load_dotenv()  # handled above if python-dotenv is available
 # Default Chrome profile path
 DEFAULT_CHROME_PROFILE = os.path.expanduser("~/Library/Application Support/Google/Chrome/Default")
 def create_leann_index_from_multiple_chrome_profiles(profile_dirs: List[Path], index_path: str = "chrome_history_index.leann", max_count: int = -1):
    """
    Create LEANN index from multiple Chrome profile data sources.
    Args:
        profile_dirs: List of Path objects pointing to Chrome profile directories
        index_path: Path to save the LEANN index
        max_count: Maximum number of history entries to process per profile
    """
    print("Creating LEANN index from multiple Chrome profile data sources...")
    # Load documents using ChromeHistoryReader from history_data
    from history_data.history import ChromeHistoryReader
    reader = ChromeHistoryReader()
    INDEX_DIR = Path(index_path).parent
    if not INDEX_DIR.exists():
        print(f"--- Index directory not found, building new index ---")
        all_documents = []
        total_processed = 0
        # Process each Chrome profile directory
        for i, profile_dir in enumerate(profile_dirs):
            print(f"\nProcessing Chrome profile {i+1}/{len(profile_dirs)}: {profile_dir}")
            try:
                documents = reader.load_data(
                    chrome_profile_path=str(profile_dir),
                    max_count=max_count
                )
                if documents:
                    print(f"Loaded {len(documents)} history documents from {profile_dir}")
                    all_documents.extend(documents)
                    total_processed += len(documents)
                    # Check if we've reached the max count
                    if max_count > 0 and total_processed >= max_count:
                        print(f"Reached max count of {max_count} documents")
                        break
                else:
                    print(f"No documents loaded from {profile_dir}")
            except Exception as e:
                print(f"Error processing {profile_dir}: {e}")
                continue
        if not all_documents:
            print("No documents loaded from any source. Exiting.")
            return None
        print(f"\nTotal loaded {len(all_documents)} history documents from {len(profile_dirs)} profiles")
        # Create text splitter with 256 chunk size
        text_splitter = SentenceSplitter(chunk_size=256, chunk_overlap=25)
        # Convert Documents to text strings and chunk them
        all_texts = []
        for doc in all_documents:
            # Split the document into chunks
            nodes = text_splitter.get_nodes_from_documents([doc])
            for node in nodes:
                all_texts.append(node.get_content())
        print(f"Created {len(all_texts)} text chunks from {len(all_documents)} documents")
        # Create LEANN index directory
        print(f"--- Index directory not found, building new index ---")
        INDEX_DIR.mkdir(exist_ok=True)
        print(f"--- Building new LEANN index ---")
        print(f"\n[PHASE 1] Building Leann index...")
        # Use HNSW backend for better macOS compatibility
        builder = LeannBuilder(
            backend_name="hnsw",
            embedding_model="facebook/contriever",
            graph_degree=32, 
            complexity=64,
            is_compact=True,
            is_recompute=True,
            num_threads=1  # Force single-threaded mode
        )
        print(f"Adding {len(all_texts)} history chunks to index...")
        for chunk_text in all_texts:
            builder.add_text(chunk_text)
        builder.build_index(index_path)
        print(f"\nLEANN index built at {index_path}!")
    else:
        print(f"--- Using existing index at {INDEX_DIR} ---")
    return index_path
 def create_leann_index(profile_path: str = None, index_path: str = "chrome_history_index.leann", max_count: int = 1000):
    """
    Create LEANN index from Chrome history data.
    Args:
        profile_path: Path to the Chrome profile directory (optional, uses default if None)
        index_path: Path to save the LEANN index
        max_count: Maximum number of history entries to process
    """
    print("Creating LEANN index from Chrome history data...")
    INDEX_DIR = Path(index_path).parent
    if not INDEX_DIR.exists():
        print(f"--- Index directory not found, building new index ---")
        INDEX_DIR.mkdir(exist_ok=True)
        print(f"--- Building new LEANN index ---")
        print(f"\n[PHASE 1] Building Leann index...")
        # Load documents using ChromeHistoryReader from history_data
        from history_data.history import ChromeHistoryReader
        reader = ChromeHistoryReader()
        documents = reader.load_data(
            chrome_profile_path=profile_path,
            max_count=max_count
        )
        if not documents:
            print("No documents loaded. Exiting.")
            return None
        print(f"Loaded {len(documents)} history documents")
        # Create text splitter with 256 chunk size
        text_splitter = SentenceSplitter(chunk_size=256, chunk_overlap=25)
        # Convert Documents to text strings and chunk them
        all_texts = []
        for doc in documents:
            # Split the document into chunks
            nodes = text_splitter.get_nodes_from_documents([doc])
            for node in nodes:
                all_texts.append(node.get_content())
        print(f"Created {len(all_texts)} text chunks from {len(documents)} documents")
        # Create LEANN index directory
        print(f"--- Index directory not found, building new index ---")
        INDEX_DIR.mkdir(exist_ok=True)
        print(f"--- Building new LEANN index ---")
        print(f"\n[PHASE 1] Building Leann index...")
        # Use HNSW backend for better macOS compatibility
        builder = LeannBuilder(
            backend_name="hnsw",
            embedding_model="facebook/contriever",
            graph_degree=32, 
            complexity=64,
            is_compact=True,
            is_recompute=True,
            num_threads=1  # Force single-threaded mode
        )
        print(f"Adding {len(all_texts)} history chunks to index...")
        for chunk_text in all_texts:
            builder.add_text(chunk_text)
        builder.build_index(index_path)
        print(f"\nLEANN index built at {index_path}!")
    else:
        print(f"--- Using existing index at {INDEX_DIR} ---")
    return index_path
 async def query_leann_index(index_path: str, query: str):
    """
    Query the LEANN index.
    Args:
        index_path: Path to the LEANN index
        query: The query string
    """
    print(f"\n[PHASE 2] Starting Leann chat session...")
    chat = LeannChat(index_path=index_path)
    print(f"You: {query}")
    chat_response = chat.ask(
        query, 
        top_k=10, 
        recompute_beighbor_embeddings=True,
        complexity=32,
        beam_width=1,
        llm_config={
            "type": "openai",
            "model": "gpt-4o",
            "api_key": os.getenv("OPENAI_API_KEY"),
        },
        llm_kwargs={
            "temperature": 0.0,
            "max_tokens": 1000
        }
    )
    print(f"Leann: {chat_response}")
 async def main():
    # Parse command line arguments
    parser = argparse.ArgumentParser(description='LEANN Chrome History Reader - Create and query browser history index')
    parser.add_argument('--chrome-profile', type=str, default=DEFAULT_CHROME_PROFILE,
                       help=f'Path to Chrome profile directory (default: {DEFAULT_CHROME_PROFILE}), usually you dont need to change this')
    parser.add_argument('--index-dir', type=str, default="./chrome_history_index_leann_test",
                       help='Directory to store the LEANN index (default: ./chrome_history_index_leann_test)')
    parser.add_argument('--max-entries', type=int, default=1000,
                       help='Maximum number of history entries to process (default: 1000)')
    parser.add_argument('--query', type=str, default=None,
                       help='Single query to run (default: runs example queries)')
    parser.add_argument('--auto-find-profiles', action='store_true', default=True,
                       help='Automatically find all Chrome profiles (default: True)')
    args = parser.parse_args()
    INDEX_DIR = Path(args.index_dir)
    INDEX_PATH = str(INDEX_DIR / "chrome_history.leann")
    print(f"Using Chrome profile: {args.chrome_profile}")
    print(f"Index directory: {INDEX_DIR}")
    print(f"Max entries: {args.max_entries}")
    # Find Chrome profile directories
    from history_data.history import ChromeHistoryReader
    if args.auto_find_profiles:
        profile_dirs = ChromeHistoryReader.find_chrome_profiles()
        if not profile_dirs:
            print("No Chrome profiles found automatically. Exiting.")
            return
    else:
        # Use single specified profile
        profile_path = Path(args.chrome_profile)
        if not profile_path.exists():
            print(f"Chrome profile not found: {profile_path}")
            return
        profile_dirs = [profile_path]
    # Create or load the LEANN index from all sources
    index_path = create_leann_index_from_multiple_chrome_profiles(profile_dirs, INDEX_PATH, args.max_entries)
    if index_path:
        if args.query:
            # Run single query
            await query_leann_index(index_path, args.query)
        else:
            # Example queries
            queries = [
                "What websites did I visit about machine learning?",
                "Find my search history about programming"
            ]
            for query in queries:
                print("\n" + "="*60)
                await query_leann_index(index_path, query)
 if __name__ == "__main__":
    asyncio.run(main()) 
--- a/examples/mail_reader_leann.py
+++ b/examples/mail_reader_leann.py
@@ -1,286 +0,0 @@
 import os
 import sys
 import asyncio
 import dotenv
 import argparse
 from pathlib import Path
 from typing import List, Any
 # Add the project root to Python path so we can import from examples
 project_root = Path(__file__).parent.parent
 sys.path.insert(0, str(project_root))
 from leann.api import LeannBuilder, LeannSearcher, LeannChat
 from llama_index.core.node_parser import SentenceSplitter
 dotenv.load_dotenv()
 # Auto-detect user's mail path
 def get_mail_path():
    """Get the mail path for the current user"""
    home_dir = os.path.expanduser("~")
    return os.path.join(home_dir, "Library", "Mail")
 # Default mail path for macOS
 # DEFAULT_MAIL_PATH = "/Users/yichuan/Library/Mail/V10/0FCA0879-FD8C-4B7E-83BF-FDDA930791C5/[Gmail].mbox/All Mail.mbox/78BA5BE1-8819-4F9A-9613-EB63772F1DD0/Data"
 def create_leann_index_from_multiple_sources(messages_dirs: List[Path], index_path: str = "mail_index.leann", max_count: int = -1, include_html: bool = False, embedding_model: str = "facebook/contriever"):
    """
    Create LEANN index from multiple mail data sources.
    Args:
        messages_dirs: List of Path objects pointing to Messages directories
        index_path: Path to save the LEANN index
        max_count: Maximum number of emails to process per directory
        include_html: Whether to include HTML content in email processing
    """
    print("Creating LEANN index from multiple mail data sources...")
    # Load documents using EmlxReader from LEANN_email_reader
    from examples.email_data.LEANN_email_reader import EmlxReader
    reader = EmlxReader(include_html=include_html)
    # from email_data.email import EmlxMboxReader
    # from pathlib import Path
    # reader = EmlxMboxReader()
    INDEX_DIR = Path(index_path).parent
    if not INDEX_DIR.exists():
        print(f"--- Index directory not found, building new index ---")
        all_documents = []
        total_processed = 0
        # Process each Messages directory
        for i, messages_dir in enumerate(messages_dirs):
            print(f"\nProcessing Messages directory {i+1}/{len(messages_dirs)}: {messages_dir}")
            try:
                documents = reader.load_data(messages_dir)
                if documents:
                    print(f"Loaded {len(documents)} email documents from {messages_dir}")
                    all_documents.extend(documents)
                    total_processed += len(documents)
                    # Check if we've reached the max count
                    if max_count > 0 and total_processed >= max_count:
                        print(f"Reached max count of {max_count} documents")
                        break
                else:
                    print(f"No documents loaded from {messages_dir}")
            except Exception as e:
                print(f"Error processing {messages_dir}: {e}")
                continue
        if not all_documents:
            print("No documents loaded from any source. Exiting.")
            return None
        print(f"\nTotal loaded {len(all_documents)} email documents from {len(messages_dirs)} directories")
        # Create text splitter with 256 chunk size
        text_splitter = SentenceSplitter(chunk_size=256, chunk_overlap=25)
        # Convert Documents to text strings and chunk them
        all_texts = []
        for doc in all_documents:
            # Split the document into chunks
            nodes = text_splitter.get_nodes_from_documents([doc])
            for node in nodes:
                all_texts.append(node.get_content())
        print(f"Created {len(all_texts)} text chunks from {len(all_documents)} documents")
        # Create LEANN index directory
        print(f"--- Index directory not found, building new index ---")
        INDEX_DIR.mkdir(exist_ok=True)
        print(f"--- Building new LEANN index ---")
        print(f"\n[PHASE 1] Building Leann index...")
        # Use HNSW backend for better macOS compatibility
        builder = LeannBuilder(
            backend_name="hnsw",
            embedding_model=embedding_model,
            graph_degree=32, 
            complexity=64,
            is_compact=True,
            is_recompute=True,
            num_threads=1  # Force single-threaded mode
        )
        print(f"Adding {len(all_texts)} email chunks to index...")
        for chunk_text in all_texts:
            builder.add_text(chunk_text)
        builder.build_index(index_path)
        print(f"\nLEANN index built at {index_path}!")
    else:
        print(f"--- Using existing index at {INDEX_DIR} ---")
    return index_path
 def create_leann_index(mail_path: str, index_path: str = "mail_index.leann", max_count: int = 1000, include_html: bool = False, embedding_model: str = "facebook/contriever"):
    """
    Create LEANN index from mail data.
    Args:
        mail_path: Path to the mail directory
        index_path: Path to save the LEANN index
        max_count: Maximum number of emails to process
        include_html: Whether to include HTML content in email processing
    """
    print("Creating LEANN index from mail data...")
    INDEX_DIR = Path(index_path).parent
    if not INDEX_DIR.exists():
        print(f"--- Index directory not found, building new index ---")
        INDEX_DIR.mkdir(exist_ok=True)
        print(f"--- Building new LEANN index ---")
        print(f"\n[PHASE 1] Building Leann index...")
        # Load documents using EmlxReader from LEANN_email_reader
        from examples.email_data.LEANN_email_reader import EmlxReader
        reader = EmlxReader(include_html=include_html)
        # from email_data.email import EmlxMboxReader
        # from pathlib import Path
        # reader = EmlxMboxReader()
        documents = reader.load_data(Path(mail_path))
        if not documents:
            print("No documents loaded. Exiting.")
            return None
        print(f"Loaded {len(documents)} email documents")
        # Create text splitter with 256 chunk size
        text_splitter = SentenceSplitter(chunk_size=256, chunk_overlap=25)
        # Convert Documents to text strings and chunk them
        all_texts = []
        for doc in documents:
            # Split the document into chunks
            nodes = text_splitter.get_nodes_from_documents([doc])
            for node in nodes:
                all_texts.append(node.get_content())
        print(f"Created {len(all_texts)} text chunks from {len(documents)} documents")
        # Create LEANN index directory
        print(f"--- Index directory not found, building new index ---")
        INDEX_DIR.mkdir(exist_ok=True)
        print(f"--- Building new LEANN index ---")
        print(f"\n[PHASE 1] Building Leann index...")
        # Use HNSW backend for better macOS compatibility
        builder = LeannBuilder(
            backend_name="hnsw",
            embedding_model=embedding_model,
            graph_degree=32, 
            complexity=64,
            is_compact=True,
            is_recompute=True,
            num_threads=1  # Force single-threaded mode
        )
        print(f"Adding {len(all_texts)} email chunks to index...")
        for chunk_text in all_texts:
            builder.add_text(chunk_text)
        builder.build_index(index_path)
        print(f"\nLEANN index built at {index_path}!")
    else:
        print(f"--- Using existing index at {INDEX_DIR} ---")
    return index_path
 async def query_leann_index(index_path: str, query: str):
    """
    Query the LEANN index.
    Args:
        index_path: Path to the LEANN index
        query: The query string
    """
    print(f"\n[PHASE 2] Starting Leann chat session...")
    chat = LeannChat(index_path=index_path,
                     llm_config={"type": "openai", "model": "gpt-4o"})
    print(f"You: {query}")
    import time
    start_time = time.time()
    chat_response = chat.ask(
        query, 
        top_k=10, 
        recompute_beighbor_embeddings=True,
        complexity=12,
        beam_width=1,
    )
    end_time = time.time()
    print(f"Time taken: {end_time - start_time} seconds")
    print(f"Leann: {chat_response}")
 async def main():
    # Parse command line arguments
    parser = argparse.ArgumentParser(description='LEANN Mail Reader - Create and query email index')
    # Remove --mail-path argument and auto-detect all Messages directories
    # Remove DEFAULT_MAIL_PATH
    parser.add_argument('--index-dir', type=str, default="./mail_index_leann_raw_text_all_dicts",
                       help='Directory to store the LEANN index (default: ./mail_index_leann_raw_text_all_dicts)')
    parser.add_argument('--max-emails', type=int, default=1000,
                       help='Maximum number of emails to process (-1 means all)')
    parser.add_argument('--query', type=str, default="Give me some funny advertisement about apple or other companies",
                       help='Single query to run (default: runs example queries)')
    parser.add_argument('--include-html', action='store_true', default=False,
                       help='Include HTML content in email processing (default: False)')
    parser.add_argument('--embedding-model', type=str, default="facebook/contriever",
                       help='Embedding model to use (default: facebook/contriever)')
    args = parser.parse_args()
    print(f"args: {args}")
    # Automatically find all Messages directories under the current user's Mail directory
    from examples.email_data.LEANN_email_reader import find_all_messages_directories
    mail_path = get_mail_path()
    print(f"Searching for email data in: {mail_path}")
    messages_dirs = find_all_messages_directories(mail_path)
    print('len(messages_dirs): ', len(messages_dirs))
    if not messages_dirs:
        print("No Messages directories found. Exiting.")
        return
    INDEX_DIR = Path(args.index_dir)
    INDEX_PATH = str(INDEX_DIR / "mail_documents.leann")
    print(f"Index directory: {INDEX_DIR}")
    print(f"Found {len(messages_dirs)} Messages directories.")
    # Create or load the LEANN index from all sources
    index_path = create_leann_index_from_multiple_sources(messages_dirs, INDEX_PATH, args.max_emails, args.include_html, args.embedding_model)
    if index_path:
        if args.query:
            # Run single query
            await query_leann_index(index_path, args.query)
        else:
            # Example queries
            queries = [
                "Hows Berkeley Graduate Student Instructor",
                "how's the icloud related advertisement saying",
                "Whats the number of class recommend to take per semester for incoming EECS students"
            ]
            for query in queries:
                print("\n" + "="*60)
                await query_leann_index(index_path, query)
 if __name__ == "__main__":
    asyncio.run(main()) 
--- a/examples/mail_reader_llamaindex.py
+++ b/examples/mail_reader_llamaindex.py
@@ -1,108 +0,0 @@
 import os
 import sys
 import argparse
 from pathlib import Path
 from typing import List, Any
 # Add the project root to Python path so we can import from examples
 project_root = Path(__file__).parent.parent
 sys.path.insert(0, str(project_root))
 from llama_index.core import VectorStoreIndex, StorageContext
 from llama_index.core.node_parser import SentenceSplitter
 # --- EMBEDDING MODEL ---
 from llama_index.embeddings.huggingface import HuggingFaceEmbedding
 import torch
 # --- END EMBEDDING MODEL ---
 # Import EmlxReader from the new module
 from examples.email_data.LEANN_email_reader import EmlxReader
 def create_and_save_index(mail_path: str, save_dir: str = "mail_index_embedded", max_count: int = 1000, include_html: bool = False):
    print("Creating index from mail data with embedded metadata...")
    documents = EmlxReader(include_html=include_html).load_data(mail_path, max_count=max_count)
    if not documents:
        print("No documents loaded. Exiting.")
        return None
    text_splitter = SentenceSplitter(chunk_size=256, chunk_overlap=25)
    # Use facebook/contriever as the embedder
    embed_model = HuggingFaceEmbedding(model_name="facebook/contriever")
    # set on device
    import torch
    if torch.cuda.is_available():
        embed_model._model.to("cuda")
    # set mps
    elif torch.backends.mps.is_available():
        embed_model._model.to("mps")
    else:
        embed_model._model.to("cpu")
    index = VectorStoreIndex.from_documents(
        documents,
        transformations=[text_splitter],
        embed_model=embed_model
    )
    os.makedirs(save_dir, exist_ok=True)
    index.storage_context.persist(persist_dir=save_dir)
    print(f"Index saved to {save_dir}")
    return index
 def load_index(save_dir: str = "mail_index_embedded"):
    try:
        storage_context = StorageContext.from_defaults(persist_dir=save_dir)
        index = VectorStoreIndex.from_vector_store(
            storage_context.vector_store,
            storage_context=storage_context
        )
        print(f"Index loaded from {save_dir}")
        return index
    except Exception as e:
        print(f"Error loading index: {e}")
        return None
 def query_index(index, query: str):
    if index is None:
        print("No index available for querying.")
        return
    query_engine = index.as_query_engine()
    response = query_engine.query(query)
    print(f"Query: {query}")
    print(f"Response: {response}")
 def main():
    # Parse command line arguments
    parser = argparse.ArgumentParser(description='LlamaIndex Mail Reader - Create and query email index')
    parser.add_argument('--mail-path', type=str, 
                       default="/Users/yichuan/Library/Mail/V10/0FCA0879-FD8C-4B7E-83BF-FDDA930791C5/[Gmail].mbox/All Mail.mbox/78BA5BE1-8819-4F9A-9613-EB63772F1DD0/Data/9/Messages",
                       help='Path to mail data directory')
    parser.add_argument('--save-dir', type=str, default="mail_index_embedded",
                       help='Directory to store the index (default: mail_index_embedded)')
    parser.add_argument('--max-emails', type=int, default=10000,
                       help='Maximum number of emails to process')
    parser.add_argument('--include-html', action='store_true', default=False,
                       help='Include HTML content in email processing (default: False)')
    args = parser.parse_args()
    mail_path = args.mail_path
    save_dir = args.save_dir
    if os.path.exists(save_dir) and os.path.exists(os.path.join(save_dir, "vector_store.json")):
        print("Loading existing index...")
        index = load_index(save_dir)
    else:
        print("Creating new index...")
        index = create_and_save_index(mail_path, save_dir, max_count=args.max_emails, include_html=args.include_html)
    if index:
        queries = [
            "Hows Berkeley Graduate Student Instructor",
            "how's the icloud related advertisement saying",
            "Whats the number of class recommend to take per semester for incoming EECS students"
        ]
        for query in queries:
            print("\n" + "="*50)
            query_index(index, query)
 if __name__ == "__main__":
    main() 
--- a/examples/main_cli_example.py
+++ b/examples/main_cli_example.py
@@ -1,110 +0,0 @@
 import argparse
 from llama_index.core import SimpleDirectoryReader, Settings
 from llama_index.core.node_parser import SentenceSplitter
 import asyncio
 import dotenv
 from leann.api import LeannBuilder, LeannSearcher, LeannChat
 import shutil
 from pathlib import Path
 dotenv.load_dotenv()
 node_parser = SentenceSplitter(
    chunk_size=256, chunk_overlap=128, separator=" ", paragraph_separator="\n\n"
 )
 print("Loading documents...")
 documents = SimpleDirectoryReader(
    "examples/data",
    recursive=True,
    encoding="utf-8",
    required_exts=[".pdf", ".txt", ".md"],
 ).load_data(show_progress=True)
 print("Documents loaded.")
 all_texts = []
 for doc in documents:
    nodes = node_parser.get_nodes_from_documents([doc])
    for node in nodes:
        all_texts.append(node.get_content())
 async def main(args):
    INDEX_DIR = Path(args.index_dir)
    INDEX_PATH = str(INDEX_DIR / "pdf_documents.leann")
    if not INDEX_DIR.exists():
        print(f"--- Index directory not found, building new index ---")
        print(f"\n[PHASE 1] Building Leann index...")
        # Use HNSW backend for better macOS compatibility
        builder = LeannBuilder(
            backend_name="hnsw",
            embedding_model="facebook/contriever",
            graph_degree=32,
            complexity=64,
            is_compact=True,
            is_recompute=True,
            num_threads=1,  # Force single-threaded mode
        )
        print(f"Loaded {len(all_texts)} text chunks from documents.")
        for chunk_text in all_texts:
            builder.add_text(chunk_text)
        builder.build_index(INDEX_PATH)
        print(f"\nLeann index built at {INDEX_PATH}!")
    else:
        print(f"--- Using existing index at {INDEX_DIR} ---")
    print(f"\n[PHASE 2] Starting Leann chat session...")
    # llm_config = {"type": "hf", "model": "Qwen/Qwen3-4B"}
    llm_config = {"type": "ollama", "model": "qwen3:8b"}
    chat = LeannChat(index_path=INDEX_PATH, llm_config=llm_config)
    query = "Based on the paper, what are the main techniques LEANN explores to reduce the storage overhead and DLPM explore to achieve Fairness and Efiiciency trade-off?"
    # query = (
    #     "什么是盘古大模型以及盘古开发过程中遇到了什么阴暗面，任务令一般在什么城市颁发"
    # )
    print(f"You: {query}")
    chat_response = chat.ask(
        query, top_k=20, recompute_beighbor_embeddings=True, complexity=32
    )
    print(f"Leann: {chat_response}")
 if __name__ == "__main__":
    parser = argparse.ArgumentParser(
        description="Run Leann Chat with various LLM backends."
    )
    parser.add_argument(
        "--llm",
        type=str,
        default="hf",
        choices=["simulated", "ollama", "hf", "openai"],
        help="The LLM backend to use.",
    )
    parser.add_argument(
        "--model",
        type=str,
        default="Qwen/Qwen3-0.6B",
        help="The model name to use (e.g., 'llama3:8b' for ollama, 'deepseek-ai/deepseek-llm-7b-chat' for hf, 'gpt-4o' for openai).",
    )
    parser.add_argument(
        "--host",
        type=str,
        default="http://localhost:11434",
        help="The host for the Ollama API.",
    )
    parser.add_argument(
        "--index-dir",
        type=str,
        default="./test_doc_files",
        help="Directory where the Leann index will be stored.",
    )
    args = parser.parse_args()
    asyncio.run(main(args))
--- a/test/build_mlx_index.py
+++ b/test/build_mlx_index.py
@@ -1,5 +1,6 @@
 import os
-from leann.api import LeannBuilder, LeannSearcher, LeannChat
+
 from leann.api import LeannBuilder, LeannChat
 # Define the path for our new MLX-based index
 INDEX_PATH = "./mlx_diskann_index/leann"
@@ -12,7 +13,7 @@ else:
    builder = LeannBuilder(
        backend_name="hnsw",
        embedding_model="mlx-community/Qwen3-Embedding-0.6B-4bit-DWQ",
-        use_mlx=True,
+        embedding_mode="mlx",
    )
    # 2. Add documents
@@ -38,7 +39,5 @@ chat = LeannChat(index_path=INDEX_PATH)
 # add query
 query = "MLX is an array framework for machine learning on Apple silicon."
 print(f"Query: {query}")
-response = chat.ask(
+response = chat.ask(query, top_k=3, recompute_beighbor_embeddings=True, complexity=3, beam_width=1)
    query, top_k=3, recompute_beighbor_embeddings=True, complexity=3, beam_width=1
 )
 print(f"Response: {response}")
--- a/examples/multi_vector_aggregator.py
+++ b/examples/multi_vector_aggregator.py
@@ -1,319 +0,0 @@
 #!/usr/bin/env python3
 """
 Multi-Vector Aggregator for Fat Embeddings
 ==========================================
 This module implements aggregation strategies for multi-vector embeddings,
 similar to ColPali's approach where multiple patch vectors represent a single document.
 Key features:
 - MaxSim aggregation (take maximum similarity across patches)
 - Voting-based aggregation (count patch matches)
 - Weighted aggregation (attention-score weighted)
 - Spatial clustering of matching patches
 - Document-level result consolidation
 """
 import numpy as np
 from typing import List, Dict, Any, Tuple, Optional
 from dataclasses import dataclass
 from collections import defaultdict
 import json
@dataclass
 class PatchResult:
    """Represents a single patch search result."""
    patch_id: int
    image_name: str
    image_path: str
    coordinates: Tuple[int, int, int, int]  # (x1, y1, x2, y2)
    score: float
    attention_score: float
    scale: float
    metadata: Dict[str, Any]
@dataclass
 class AggregatedResult:
    """Represents an aggregated document-level result."""
    image_name: str
    image_path: str
    doc_score: float
    patch_count: int
    best_patch: PatchResult
    all_patches: List[PatchResult]
    aggregation_method: str
    spatial_clusters: Optional[List[List[PatchResult]]] = None
 class MultiVectorAggregator:
    """
    Aggregates multiple patch-level results into document-level results.
    """
    def __init__(self, 
                 aggregation_method: str = "maxsim",
                 spatial_clustering: bool = True,
                 cluster_distance_threshold: float = 100.0):
        """
        Initialize the aggregator.
        Args:
            aggregation_method: "maxsim", "voting", "weighted", or "mean"
            spatial_clustering: Whether to cluster spatially close patches
            cluster_distance_threshold: Distance threshold for spatial clustering
        """
        self.aggregation_method = aggregation_method
        self.spatial_clustering = spatial_clustering
        self.cluster_distance_threshold = cluster_distance_threshold
    def aggregate_results(self, 
                         search_results: List[Dict[str, Any]], 
                         top_k: int = 10) -> List[AggregatedResult]:
        """
        Aggregate patch-level search results into document-level results.
        Args:
            search_results: List of search results from LeannSearcher
            top_k: Number of top documents to return
        Returns:
            List of aggregated document results
        """
        # Group results by image
        image_groups = defaultdict(list)
        for result in search_results:
            metadata = result.metadata
            if "image_name" in metadata and "patch_id" in metadata:
                patch_result = PatchResult(
                    patch_id=metadata["patch_id"],
                    image_name=metadata["image_name"],
                    image_path=metadata["image_path"],
                    coordinates=tuple(metadata["coordinates"]),
                    score=result.score,
                    attention_score=metadata.get("attention_score", 0.0),
                    scale=metadata.get("scale", 1.0),
                    metadata=metadata
                )
                image_groups[metadata["image_name"]].append(patch_result)
        # Aggregate each image group
        aggregated_results = []
        for image_name, patches in image_groups.items():
            if len(patches) == 0:
                continue
            agg_result = self._aggregate_image_patches(image_name, patches)
            aggregated_results.append(agg_result)
        # Sort by aggregated score and return top-k
        aggregated_results.sort(key=lambda x: x.doc_score, reverse=True)
        return aggregated_results[:top_k]
    def _aggregate_image_patches(self, image_name: str, patches: List[PatchResult]) -> AggregatedResult:
        """Aggregate patches for a single image."""
        if self.aggregation_method == "maxsim":
            doc_score = max(patch.score for patch in patches)
            best_patch = max(patches, key=lambda p: p.score)
        elif self.aggregation_method == "voting":
            # Count patches above threshold
            threshold = np.percentile([p.score for p in patches], 75)
            doc_score = sum(1 for patch in patches if patch.score >= threshold)
            best_patch = max(patches, key=lambda p: p.score)
        elif self.aggregation_method == "weighted":
            # Weight by attention scores
            total_weighted_score = sum(p.score * p.attention_score for p in patches)
            total_weights = sum(p.attention_score for p in patches)
            doc_score = total_weighted_score / max(total_weights, 1e-8)
            best_patch = max(patches, key=lambda p: p.score * p.attention_score)
        elif self.aggregation_method == "mean":
            doc_score = np.mean([patch.score for patch in patches])
            best_patch = max(patches, key=lambda p: p.score)
        else:
            raise ValueError(f"Unknown aggregation method: {self.aggregation_method}")
        # Spatial clustering if enabled
        spatial_clusters = None
        if self.spatial_clustering:
            spatial_clusters = self._cluster_patches_spatially(patches)
        return AggregatedResult(
            image_name=image_name,
            image_path=patches[0].image_path,
            doc_score=float(doc_score),
            patch_count=len(patches),
            best_patch=best_patch,
            all_patches=sorted(patches, key=lambda p: p.score, reverse=True),
            aggregation_method=self.aggregation_method,
            spatial_clusters=spatial_clusters
        )
    def _cluster_patches_spatially(self, patches: List[PatchResult]) -> List[List[PatchResult]]:
        """Cluster patches that are spatially close to each other."""
        if len(patches) <= 1:
            return [patches]
        clusters = []
        remaining_patches = patches.copy()
        while remaining_patches:
            # Start new cluster with highest scoring remaining patch
            seed_patch = max(remaining_patches, key=lambda p: p.score)
            current_cluster = [seed_patch]
            remaining_patches.remove(seed_patch)
            # Add nearby patches to cluster
            added_to_cluster = True
            while added_to_cluster:
                added_to_cluster = False
                for patch in remaining_patches.copy():
                    if self._is_patch_nearby(patch, current_cluster):
                        current_cluster.append(patch)
                        remaining_patches.remove(patch)
                        added_to_cluster = True
            clusters.append(current_cluster)
        return sorted(clusters, key=lambda cluster: max(p.score for p in cluster), reverse=True)
    def _is_patch_nearby(self, patch: PatchResult, cluster: List[PatchResult]) -> bool:
        """Check if a patch is spatially close to any patch in the cluster."""
        patch_center = self._get_patch_center(patch.coordinates)
        for cluster_patch in cluster:
            cluster_center = self._get_patch_center(cluster_patch.coordinates)
            distance = np.sqrt((patch_center[0] - cluster_center[0])**2 + 
                             (patch_center[1] - cluster_center[1])**2)
            if distance <= self.cluster_distance_threshold:
                return True
        return False
    def _get_patch_center(self, coordinates: Tuple[int, int, int, int]) -> Tuple[float, float]:
        """Get center point of a patch."""
        x1, y1, x2, y2 = coordinates
        return ((x1 + x2) / 2, (y1 + y2) / 2)
    def print_aggregated_results(self, results: List[AggregatedResult], max_patches_per_doc: int = 3):
        """Pretty print aggregated results."""
        print(f"\n🔍 Aggregated Results (method: {self.aggregation_method})")
        print("=" * 80)
        for i, result in enumerate(results):
            print(f"\n{i+1}. {result.image_name}")
            print(f"   Doc Score: {result.doc_score:.4f} | Patches: {result.patch_count}")
            print(f"   Path: {result.image_path}")
            # Show best patch
            best = result.best_patch
            print(f"   🌟 Best Patch: #{best.patch_id} at {best.coordinates} (score: {best.score:.4f})")
            # Show top patches
            print(f"   📍 Top Patches:")
            for j, patch in enumerate(result.all_patches[:max_patches_per_doc]):
                print(f"      {j+1}. Patch #{patch.patch_id}: {patch.score:.4f} at {patch.coordinates}")
            # Show spatial clusters if available
            if result.spatial_clusters and len(result.spatial_clusters) > 1:
                print(f"   🗂️ Spatial Clusters: {len(result.spatial_clusters)}")
                for j, cluster in enumerate(result.spatial_clusters[:2]):  # Show top 2 clusters
                    cluster_score = max(p.score for p in cluster)
                    print(f"      Cluster {j+1}: {len(cluster)} patches (best: {cluster_score:.4f})")
 def demo_aggregation():
    """Demonstrate the multi-vector aggregation functionality."""
    print("=== Multi-Vector Aggregation Demo ===")
    # Simulate some patch-level search results
    # In real usage, these would come from LeannSearcher.search()
    class MockResult:
        def __init__(self, score, metadata):
            self.score = score
            self.metadata = metadata
    # Simulate results for 2 images with multiple patches each
    mock_results = [
        # Image 1: cats_and_kitchen.jpg - 4 patches
        MockResult(0.85, {
            "image_name": "cats_and_kitchen.jpg",
            "image_path": "/path/to/cats_and_kitchen.jpg",
            "patch_id": 3,
            "coordinates": [100, 50, 224, 174],  # Kitchen area
            "attention_score": 0.92,
            "scale": 1.0
        }),
        MockResult(0.78, {
            "image_name": "cats_and_kitchen.jpg", 
            "image_path": "/path/to/cats_and_kitchen.jpg",
            "patch_id": 7,
            "coordinates": [200, 300, 324, 424],  # Cat area
            "attention_score": 0.88,
            "scale": 1.0
        }),
        MockResult(0.72, {
            "image_name": "cats_and_kitchen.jpg",
            "image_path": "/path/to/cats_and_kitchen.jpg", 
            "patch_id": 12,
            "coordinates": [150, 100, 274, 224],  # Appliances
            "attention_score": 0.75,
            "scale": 1.0
        }),
        MockResult(0.65, {
            "image_name": "cats_and_kitchen.jpg",
            "image_path": "/path/to/cats_and_kitchen.jpg",
            "patch_id": 15,
            "coordinates": [50, 250, 174, 374],  # Furniture
            "attention_score": 0.70,
            "scale": 1.0
        }),
        # Image 2: city_street.jpg - 3 patches  
        MockResult(0.68, {
            "image_name": "city_street.jpg",
            "image_path": "/path/to/city_street.jpg",
            "patch_id": 2,
            "coordinates": [300, 100, 424, 224],  # Buildings
            "attention_score": 0.80,
            "scale": 1.0
        }),
        MockResult(0.62, {
            "image_name": "city_street.jpg",
            "image_path": "/path/to/city_street.jpg",
            "patch_id": 8,
            "coordinates": [100, 350, 224, 474],  # Street level
            "attention_score": 0.75,
            "scale": 1.0
        }),
        MockResult(0.55, {
            "image_name": "city_street.jpg", 
            "image_path": "/path/to/city_street.jpg",
            "patch_id": 11,
            "coordinates": [400, 200, 524, 324],  # Sky area
            "attention_score": 0.60,
            "scale": 1.0
        }),
    ]
    # Test different aggregation methods
    methods = ["maxsim", "voting", "weighted", "mean"]
    for method in methods:
        print(f"\n{'='*20} {method.upper()} AGGREGATION {'='*20}")
        aggregator = MultiVectorAggregator(
            aggregation_method=method,
            spatial_clustering=True,
            cluster_distance_threshold=100.0
        )
        aggregated = aggregator.aggregate_results(mock_results, top_k=5)
        aggregator.print_aggregated_results(aggregated)
 if __name__ == "__main__":
    demo_aggregation()
--- a/examples/openai_hnsw_example.py
+++ b/examples/openai_hnsw_example.py
@@ -1,108 +0,0 @@
 #!/usr/bin/env python3
 """
 OpenAI Embedding Example
 Complete example showing how to build and search with OpenAI embeddings using HNSW backend.
 """
 import os
 import dotenv
 from pathlib import Path
 from leann.api import LeannBuilder, LeannSearcher
 # Load environment variables
 dotenv.load_dotenv()
 def main():
    # Check if OpenAI API key is available
    api_key = os.getenv("OPENAI_API_KEY")
    if not api_key:
        print("ERROR: OPENAI_API_KEY environment variable not set")
        return False
    print(f"✅ OpenAI API key found: {api_key[:10]}...")
    # Sample texts
    sample_texts = [
        "Machine learning is a powerful technology that enables computers to learn from data.",
        "Natural language processing helps computers understand and generate human language.",
        "Deep learning uses neural networks with multiple layers to solve complex problems.",
        "Computer vision allows machines to interpret and understand visual information.",
        "Reinforcement learning trains agents to make decisions through trial and error.",
        "Data science combines statistics, math, and programming to extract insights from data.",
        "Artificial intelligence aims to create machines that can perform human-like tasks.",
        "Python is a popular programming language used extensively in data science and AI.",
        "Neural networks are inspired by the structure and function of the human brain.",
        "Big data refers to extremely large datasets that require special tools to process."
    ]
    INDEX_DIR = Path("./simple_openai_test_index")
    INDEX_PATH = str(INDEX_DIR / "simple_test.leann")
    print(f"\n=== Building Index with OpenAI Embeddings ===")
    print(f"Index path: {INDEX_PATH}")
    try:
        # Use proper configuration for OpenAI embeddings
        builder = LeannBuilder(
            backend_name="hnsw",
            embedding_model="text-embedding-3-small",
            embedding_mode="openai",
            # HNSW settings for OpenAI embeddings
            M=16,                    # Smaller graph degree
            efConstruction=64,       # Smaller construction complexity  
            is_compact=True,         # Enable compact storage for recompute
            is_recompute=True,       # MUST enable for OpenAI embeddings
            num_threads=1,
        )
        print(f"Adding {len(sample_texts)} texts to the index...")
        for i, text in enumerate(sample_texts):
            metadata = {"id": f"doc_{i}", "topic": "AI"}
            builder.add_text(text, metadata)
        print("Building index...")
        builder.build_index(INDEX_PATH)
        print(f"✅ Index built successfully!")
    except Exception as e:
        print(f"❌ Error building index: {e}")
        import traceback
        traceback.print_exc()
        return False
    print(f"\n=== Testing Search ===")
    try:
        searcher = LeannSearcher(INDEX_PATH)
        test_queries = [
            "What is machine learning?",
            "How do neural networks work?",
            "Programming languages for data science"
        ]
        for query in test_queries:
            print(f"\n🔍 Query: '{query}'")
            results = searcher.search(query, top_k=3)
            print(f"   Found {len(results)} results:")
            for i, result in enumerate(results):
                print(f"   {i+1}. Score: {result.score:.4f}")
                print(f"      Text: {result.text[:80]}...")
        print(f"\n✅ Search test completed successfully!")
        return True
    except Exception as e:
        print(f"❌ Error during search: {e}")
        import traceback
        traceback.print_exc()
        return False
 if __name__ == "__main__":
    success = main()
    if success:
        print(f"\n🎉 Simple OpenAI index test completed successfully!")
    else:
        print(f"\n💥 Simple OpenAI index test failed!")
--- a/examples/resue_index.py
+++ b/examples/resue_index.py
@@ -1,18 +0,0 @@
 import asyncio
 from leann.api import LeannChat
 from pathlib import Path
 INDEX_DIR = Path("./test_pdf_index_huawei")
 INDEX_PATH = str(INDEX_DIR / "pdf_documents.leann")
 async def main():
    print(f"\n[PHASE 2] Starting Leann chat session...")
    chat = LeannChat(index_path=INDEX_PATH)
    query = "What is the main idea of RL and give me 5 exapmle of classic RL algorithms?"
    query = "Based on the paper, what are the main techniques LEANN explores to reduce the storage overhead and DLPM explore to achieve Fairness and Efiiciency trade-off?"
    # query = "什么是盘古大模型以及盘古开发过程中遇到了什么阴暗面，任务令一般在什么城市颁发"
    response = chat.ask(query,top_k=20,recompute_beighbor_embeddings=True,complexity=32,beam_width=1)
    print(f"\n[PHASE 2] Response: {response}")
 if __name__ == "__main__":
    asyncio.run(main())
--- a/examples/wechat_history_reader_leann.py
+++ b/examples/wechat_history_reader_leann.py
@@ -1,318 +0,0 @@
 import os
 import asyncio
 import dotenv
 import argparse
 from pathlib import Path
 from typing import List, Any, Optional
 from leann.api import LeannBuilder, LeannSearcher, LeannChat
 from llama_index.core.node_parser import SentenceSplitter
 import requests
 import time
 dotenv.load_dotenv()
 # Default WeChat export directory
 DEFAULT_WECHAT_EXPORT_DIR = "./wechat_export_direct"
 def create_leann_index_from_multiple_wechat_exports(
    export_dirs: List[Path],
    index_path: str = "wechat_history_index.leann",
    max_count: int = -1,
 ):
    """
    Create LEANN index from multiple WeChat export data sources.
    Args:
        export_dirs: List of Path objects pointing to WeChat export directories
        index_path: Path to save the LEANN index
        max_count: Maximum number of chat entries to process per export
    """
    print("Creating LEANN index from multiple WeChat export data sources...")
    # Load documents using WeChatHistoryReader from history_data
    from history_data.wechat_history import WeChatHistoryReader
    reader = WeChatHistoryReader()
    INDEX_DIR = Path(index_path).parent
    if not INDEX_DIR.exists():
        print(f"--- Index directory not found, building new index ---")
        all_documents = []
        total_processed = 0
        # Process each WeChat export directory
        for i, export_dir in enumerate(export_dirs):
            print(
                f"\nProcessing WeChat export {i + 1}/{len(export_dirs)}: {export_dir}"
            )
            try:
                documents = reader.load_data(
                    wechat_export_dir=str(export_dir),
                    max_count=max_count,
                    concatenate_messages=False,  # Disable concatenation - one message per document
                )
                if documents:
                    print(f"Loaded {len(documents)} chat documents from {export_dir}")
                    all_documents.extend(documents)
                    total_processed += len(documents)
                    # Check if we've reached the max count
                    if max_count > 0 and total_processed >= max_count:
                        print(f"Reached max count of {max_count} documents")
                        break
                else:
                    print(f"No documents loaded from {export_dir}")
            except Exception as e:
                print(f"Error processing {export_dir}: {e}")
                continue
        if not all_documents:
            print("No documents loaded from any source. Exiting.")
            return None
        print(
            f"\nTotal loaded {len(all_documents)} chat documents from {len(export_dirs)} exports"
        )
        # Create text splitter with 256 chunk size
        text_splitter = SentenceSplitter(chunk_size=128, chunk_overlap=64)
        # Convert Documents to text strings and chunk them
        all_texts = []
        for doc in all_documents:
            # Split the document into chunks
            nodes = text_splitter.get_nodes_from_documents([doc])
            for node in nodes:
                all_texts.append(node.get_content())
        print(
            f"Created {len(all_texts)} text chunks from {len(all_documents)} documents"
        )
        # Create LEANN index directory
        print(f"--- Index directory not found, building new index ---")
        INDEX_DIR.mkdir(exist_ok=True)
        print(f"--- Building new LEANN index ---")
        print(f"\n[PHASE 1] Building Leann index...")
        # Use HNSW backend for better macOS compatibility
        builder = LeannBuilder(
            backend_name="hnsw",
            embedding_model="Qwen/Qwen3-Embedding-0.6B",
            graph_degree=32,
            complexity=64,
            is_compact=True,
            is_recompute=True,
            num_threads=1,  # Force single-threaded mode
        )
        print(f"Adding {len(all_texts)} chat chunks to index...")
        for chunk_text in all_texts:
            builder.add_text(chunk_text)
        builder.build_index(index_path)
        print(f"\nLEANN index built at {index_path}!")
    else:
        print(f"--- Using existing index at {INDEX_DIR} ---")
    return index_path
 def create_leann_index(
    export_dir: str = None,
    index_path: str = "wechat_history_index.leann",
    max_count: int = 1000,
 ):
    """
    Create LEANN index from WeChat chat history data.
    Args:
        export_dir: Path to the WeChat export directory (optional, uses default if None)
        index_path: Path to save the LEANN index
        max_count: Maximum number of chat entries to process
    """
    print("Creating LEANN index from WeChat chat history data...")
    INDEX_DIR = Path(index_path).parent
    if not INDEX_DIR.exists():
        print(f"--- Index directory not found, building new index ---")
        INDEX_DIR.mkdir(exist_ok=True)
        print(f"--- Building new LEANN index ---")
        print(f"\n[PHASE 1] Building Leann index...")
        # Load documents using WeChatHistoryReader from history_data
        from history_data.wechat_history import WeChatHistoryReader
        reader = WeChatHistoryReader()
        documents = reader.load_data(
            wechat_export_dir=export_dir,
            max_count=max_count,
            concatenate_messages=False,  # Disable concatenation - one message per document
        )
        if not documents:
            print("No documents loaded. Exiting.")
            return None
        print(f"Loaded {len(documents)} chat documents")
        # Create text splitter with 256 chunk size
        text_splitter = SentenceSplitter(chunk_size=256, chunk_overlap=25)
        # Convert Documents to text strings and chunk them
        all_texts = []
        for doc in documents:
            # Split the document into chunks
            nodes = text_splitter.get_nodes_from_documents([doc])
            for node in nodes:
                all_texts.append(node.get_content())
        print(f"Created {len(all_texts)} text chunks from {len(documents)} documents")
        # Create LEANN index directory
        print(f"--- Index directory not found, building new index ---")
        INDEX_DIR.mkdir(exist_ok=True)
        print(f"--- Building new LEANN index ---")
        print(f"\n[PHASE 1] Building Leann index...")
        # Use HNSW backend for better macOS compatibility
        builder = LeannBuilder(
            backend_name="hnsw",
            embedding_model="mlx-community/Qwen3-Embedding-0.6B-4bit-DWQ",  # MLX-optimized model
            graph_degree=32,
            complexity=64,
            is_compact=True,
            is_recompute=True,
            num_threads=1,  # Force single-threaded mode
        )
        print(f"Adding {len(all_texts)} chat chunks to index...")
        for chunk_text in all_texts:
            builder.add_text(chunk_text)
        builder.build_index(index_path)
        print(f"\nLEANN index built at {index_path}!")
    else:
        print(f"--- Using existing index at {INDEX_DIR} ---")
    return index_path
 async def query_leann_index(index_path: str, query: str):
    """
    Query the LEANN index.
    Args:
        index_path: Path to the LEANN index
        query: The query string
    """
    print(f"\n[PHASE 2] Starting Leann chat session...")
    chat = LeannChat(index_path=index_path)
    print(f"You: {query}")
    chat_response = chat.ask(
        query,
        top_k=20,
        recompute_beighbor_embeddings=True,
        complexity=128,
        beam_width=1,
        llm_config={
            "type": "openai",
            "model": "gpt-4o",
            "api_key": os.getenv("OPENAI_API_KEY"),
        },
        llm_kwargs={"temperature": 0.0, "max_tokens": 1000},
    )
    print(f"Leann: {chat_response}")
 async def main():
    """Main function with integrated WeChat export functionality."""
    # Parse command line arguments
    parser = argparse.ArgumentParser(
        description="LEANN WeChat History Reader - Create and query WeChat chat history index"
    )
    parser.add_argument(
        "--export-dir",
        type=str,
        default=DEFAULT_WECHAT_EXPORT_DIR,
        help=f"Directory to store WeChat exports (default: {DEFAULT_WECHAT_EXPORT_DIR})",
    )
    parser.add_argument(
        "--index-dir",
        type=str,
        default="./wechat_history_june19_test",
        help="Directory to store the LEANN index (default: ./wechat_history_index_leann_test)",
    )
    parser.add_argument(
        "--max-entries",
        type=int,
        default=5000,
        help="Maximum number of chat entries to process (default: 5000)",
    )
    parser.add_argument(
        "--query",
        type=str,
        default=None,
        help="Single query to run (default: runs example queries)",
    )
    parser.add_argument(
        "--force-export",
        action="store_true",
        default=False,
        help="Force re-export of WeChat data even if exports exist",
    )
    args = parser.parse_args()
    INDEX_DIR = Path(args.index_dir)
    INDEX_PATH = str(INDEX_DIR / "wechat_history.leann")
    print(f"Using WeChat export directory: {args.export_dir}")
    print(f"Index directory: {INDEX_DIR}")
    print(f"Max entries: {args.max_entries}")
    # Initialize WeChat reader with export capabilities
    from history_data.wechat_history import WeChatHistoryReader
    reader = WeChatHistoryReader()
    # Find existing exports or create new ones using the centralized method
    export_dirs = reader.find_or_export_wechat_data(args.export_dir)
    if not export_dirs:
        print("Failed to find or export WeChat data. Exiting.")
        return
    # Create or load the LEANN index from all sources
    index_path = create_leann_index_from_multiple_wechat_exports(
        export_dirs, INDEX_PATH, max_count=args.max_entries
    )
    if index_path:
        if args.query:
            # Run single query
            await query_leann_index(index_path, args.query)
        else:
            # Example queries
            queries = [
                "我想买魔术师约翰逊的球衣，给我一些对应聊天记录?",
            ]
            for query in queries:
                print("\n" + "=" * 60)
                await query_leann_index(index_path, query)
 if __name__ == "__main__":
    asyncio.run(main())
--- a/packages/init.py
+++ b/packages/init.py
@@ -1 +0,0 @@
--- a/packages/leann-backend-diskann/CMakeLists.txt
+++ b/packages/leann-backend-diskann/CMakeLists.txt
@@ -1,8 +1,8 @@
-# packages/leann-backend-diskann/CMakeLists.txt (最终简化版)
+# packages/leann-backend-diskann/CMakeLists.txt (simplified version)
 cmake_minimum_required(VERSION 3.20)
 project(leann_backend_diskann_wrapper)
-# 告诉 CMake 直接进入 DiskANN 子模块并执行它自己的 CMakeLists.txt
+# Tell CMake to directly enter the DiskANN submodule and execute its own CMakeLists.txt
-# DiskANN 会自己处理所有事情，包括编译 Python 绑定
+# DiskANN will handle everything itself, including compiling Python bindings
 add_subdirectory(src/third_party/DiskANN)
--- a/packages/leann-backend-diskann/leann_backend_diskann/init.py
+++ b/packages/leann-backend-diskann/leann_backend_diskann/init.py
@@ -1 +1 @@
-from . import diskann_backend
+from . import diskann_backend as diskann_backend
--- a/packages/leann-backend-diskann/leann_backend_diskann/diskann_backend.py
+++ b/packages/leann-backend-diskann/leann_backend_diskann/diskann_backend.py
@@ -1,18 +1,60 @@
-import numpy as np
+import contextlib
 import logging
 import os
 import struct
 import sys
 from pathlib import Path
-from typing import Dict, Any, List, Literal
+from typing import Any, Literal
 import contextlib
 import pickle
-from leann.searcher_base import BaseSearcher
+import numpy as np
-from leann.registry import register_backend
+import psutil
 from leann.interface import (
    LeannBackendFactoryInterface,
    LeannBackendBuilderInterface,
    LeannBackendFactoryInterface,
    LeannBackendSearcherInterface,
 )
 from leann.registry import register_backend
 from leann.searcher_base import BaseSearcher
 logger = logging.getLogger(__name__)
@contextlib.contextmanager
 def suppress_cpp_output_if_needed():
    """Suppress C++ stdout/stderr based on LEANN_LOG_LEVEL"""
    log_level = os.getenv("LEANN_LOG_LEVEL", "WARNING").upper()
    # Only suppress if log level is WARNING or higher (ERROR, CRITICAL)
    should_suppress = log_level in ["WARNING", "ERROR", "CRITICAL"]
    if not should_suppress:
        # Don't suppress, just yield
        yield
        return
    # Save original file descriptors
    stdout_fd = sys.stdout.fileno()
    stderr_fd = sys.stderr.fileno()
    # Save original stdout/stderr
    stdout_dup = os.dup(stdout_fd)
    stderr_dup = os.dup(stderr_fd)
    try:
        # Redirect to /dev/null
        devnull = os.open(os.devnull, os.O_WRONLY)
        os.dup2(devnull, stdout_fd)
        os.dup2(devnull, stderr_fd)
        os.close(devnull)
        yield
    finally:
        # Restore original file descriptors
        os.dup2(stdout_dup, stdout_fd)
        os.dup2(stderr_dup, stderr_fd)
        os.close(stdout_dup)
        os.close(stderr_dup)
 def _get_diskann_metrics():
@@ -43,6 +85,43 @@ def _write_vectors_to_bin(data: np.ndarray, file_path: Path):
        f.write(data.tobytes())
 def _calculate_smart_memory_config(data: np.ndarray) -> tuple[float, float]:
    """
    Calculate smart memory configuration for DiskANN based on data size and system specs.
    Args:
        data: The embedding data array
    Returns:
        tuple: (search_memory_maximum, build_memory_maximum) in GB
    """
    num_vectors, dim = data.shape
    # Calculate embedding storage size
    embedding_size_bytes = num_vectors * dim * 4  # float32 = 4 bytes
    embedding_size_gb = embedding_size_bytes / (1024**3)
    # search_memory_maximum: 1/10 of embedding size for optimal PQ compression
    # This controls Product Quantization size - smaller means more compression
    search_memory_gb = max(0.1, embedding_size_gb / 10)  # At least 100MB
    # build_memory_maximum: Based on available system RAM for sharding control
    # This controls how much memory DiskANN uses during index construction
    available_memory_gb = psutil.virtual_memory().available / (1024**3)
    total_memory_gb = psutil.virtual_memory().total / (1024**3)
    # Use 50% of available memory, but at least 2GB and at most 75% of total
    build_memory_gb = max(2.0, min(available_memory_gb * 0.5, total_memory_gb * 0.75))
    logger.info(
        f"Smart memory config - Data: {embedding_size_gb:.2f}GB, "
        f"Search mem: {search_memory_gb:.2f}GB (PQ control), "
        f"Build mem: {build_memory_gb:.2f}GB (sharding control)"
    )
    return search_memory_gb, build_memory_gb
@register_backend("diskann")
 class DiskannBackend(LeannBackendFactoryInterface):
    @staticmethod
@@ -58,29 +137,37 @@ class DiskannBuilder(LeannBackendBuilderInterface):
    def __init__(self, **kwargs):
        self.build_params = kwargs
-    def build(self, data: np.ndarray, ids: List[str], index_path: str, **kwargs):
+    def build(self, data: np.ndarray, ids: list[str], index_path: str, **kwargs):
        path = Path(index_path)
        index_dir = path.parent
        index_prefix = path.stem
        index_dir.mkdir(parents=True, exist_ok=True)
        if data.dtype != np.float32:
            logger.warning(f"Converting data to float32, shape: {data.shape}")
            data = data.astype(np.float32)
        data_filename = f"{index_prefix}_data.bin"
        _write_vectors_to_bin(data, index_dir / data_filename)
        label_map = {i: str_id for i, str_id in enumerate(ids)}
        label_map_file = index_dir / "leann.labels.map"
        with open(label_map_file, "wb") as f:
            pickle.dump(label_map, f)
        build_kwargs = {**self.build_params, **kwargs}
        metric_enum = _get_diskann_metrics().get(
            build_kwargs.get("distance_metric", "mips").lower()
        )
        if metric_enum is None:
-            raise ValueError("Unsupported distance_metric.")
+            raise ValueError(
                f"Unsupported distance_metric '{build_kwargs.get('distance_metric', 'unknown')}'."
            )
        # Calculate smart memory configuration if not explicitly provided
        if (
            "search_memory_maximum" not in build_kwargs
            or "build_memory_maximum" not in build_kwargs
        ):
            smart_search_mem, smart_build_mem = _calculate_smart_memory_config(data)
        else:
            smart_search_mem = build_kwargs.get("search_memory_maximum", 4.0)
            smart_build_mem = build_kwargs.get("build_memory_maximum", 8.0)
        try:
            from . import _diskannpy as diskannpy  # type: ignore
@@ -92,8 +179,8 @@ class DiskannBuilder(LeannBackendBuilderInterface):
                    index_prefix,
                    build_kwargs.get("complexity", 64),
                    build_kwargs.get("graph_degree", 32),
-                    build_kwargs.get("search_memory_maximum", 4.0),
+                    build_kwargs.get("search_memory_maximum", smart_search_mem),
-                    build_kwargs.get("build_memory_maximum", 8.0),
+                    build_kwargs.get("build_memory_maximum", smart_build_mem),
                    build_kwargs.get("num_threads", 8),
                    build_kwargs.get("pq_disk_bytes", 0),
                    "",
@@ -102,36 +189,66 @@ class DiskannBuilder(LeannBackendBuilderInterface):
            temp_data_file = index_dir / data_filename
            if temp_data_file.exists():
                os.remove(temp_data_file)
                logger.debug(f"Cleaned up temporary data file: {temp_data_file}")
 class DiskannSearcher(BaseSearcher):
    def __init__(self, index_path: str, **kwargs):
        super().__init__(
            index_path,
-            backend_module_name="leann_backend_diskann.embedding_server",
+            backend_module_name="leann_backend_diskann.diskann_embedding_server",
            **kwargs,
        )
        from . import _diskannpy as diskannpy  # type: ignore
-        distance_metric = kwargs.get("distance_metric", "mips").lower()
+        # Initialize DiskANN index with suppressed C++ output based on log level
-        metric_enum = _get_diskann_metrics().get(distance_metric)
+        with suppress_cpp_output_if_needed():
-        if metric_enum is None:
+            from . import _diskannpy as diskannpy  # type: ignore
            raise ValueError(f"Unsupported distance_metric '{distance_metric}'.")
-        self.num_threads = kwargs.get("num_threads", 8)
+            distance_metric = kwargs.get("distance_metric", "mips").lower()
-        self.zmq_port = kwargs.get("zmq_port", 6666)
+            metric_enum = _get_diskann_metrics().get(distance_metric)
            if metric_enum is None:
                raise ValueError(f"Unsupported distance_metric '{distance_metric}'.")
-        full_index_prefix = str(self.index_dir / self.index_path.stem)
+            self.num_threads = kwargs.get("num_threads", 8)
-        self._index = diskannpy.StaticDiskFloatIndex(
+
-            metric_enum,
+            # For DiskANN, we need to reinitialize the index when zmq_port changes
-            full_index_prefix,
+            # Store the initialization parameters for later use
-            self.num_threads,
+            full_index_prefix = str(self.index_dir / self.index_path.stem)
-            kwargs.get("num_nodes_to_cache", 0),
+            self._init_params = {
-            1,
+                "metric_enum": metric_enum,
-            self.zmq_port,
+                "full_index_prefix": full_index_prefix,
-            "",
+                "num_threads": self.num_threads,
-            "",
+                "num_nodes_to_cache": kwargs.get("num_nodes_to_cache", 0),
-        )
+                "cache_mechanism": 1,
                "pq_prefix": "",
                "partition_prefix": "",
            }
            self._diskannpy = diskannpy
            self._current_zmq_port = None
            self._index = None
            logger.debug("DiskANN searcher initialized (index will be loaded on first search)")
    def _ensure_index_loaded(self, zmq_port: int):
        """Ensure the index is loaded with the correct zmq_port."""
        if self._index is None or self._current_zmq_port != zmq_port:
            # Need to (re)load the index with the correct zmq_port
            with suppress_cpp_output_if_needed():
                if self._index is not None:
                    logger.debug(f"Reloading DiskANN index with new zmq_port: {zmq_port}")
                else:
                    logger.debug(f"Loading DiskANN index with zmq_port: {zmq_port}")
                self._index = self._diskannpy.StaticDiskFloatIndex(
                    self._init_params["metric_enum"],
                    self._init_params["full_index_prefix"],
                    self._init_params["num_threads"],
                    self._init_params["num_nodes_to_cache"],
                    self._init_params["cache_mechanism"],
                    zmq_port,
                    self._init_params["pq_prefix"],
                    self._init_params["partition_prefix"],
                )
                self._current_zmq_port = zmq_port
    def search(
        self,
@@ -142,11 +259,11 @@ class DiskannSearcher(BaseSearcher):
        prune_ratio: float = 0.0,
        recompute_embeddings: bool = False,
        pruning_strategy: Literal["global", "local", "proportional"] = "global",
-        zmq_port: int = 5557,
+        zmq_port: int | None = None,
        batch_recompute: bool = False,
        dedup_node_dis: bool = False,
        **kwargs,
-    ) -> Dict[str, Any]:
+    ) -> dict[str, Any]:
        """
        Search for nearest neighbors using DiskANN index.
@@ -161,7 +278,7 @@ class DiskannSearcher(BaseSearcher):
                - "global": Use global pruning strategy (default)
                - "local": Use local pruning strategy
                - "proportional": Not supported in DiskANN, falls back to global
-            zmq_port: ZMQ port for embedding server
+            zmq_port: ZMQ port for embedding server communication. Must be provided if recompute_embeddings is True.
            batch_recompute: Whether to batch neighbor recomputation (DiskANN-specific)
            dedup_node_dis: Whether to cache and reuse distance computations (DiskANN-specific)
            **kwargs: Additional DiskANN-specific parameters (for legacy compatibility)
@@ -169,22 +286,22 @@ class DiskannSearcher(BaseSearcher):
        Returns:
            Dict with 'labels' (list of lists) and 'distances' (ndarray)
        """
        # Handle zmq_port compatibility: Ensure index is loaded with correct port
        if recompute_embeddings:
            if zmq_port is None:
                raise ValueError("zmq_port must be provided if recompute_embeddings is True")
            self._ensure_index_loaded(zmq_port)
        else:
            # If not recomputing, we still need an index, use a default port
            if self._index is None:
                self._ensure_index_loaded(6666)  # Default port when not recomputing
        # DiskANN doesn't support "proportional" strategy
        if pruning_strategy == "proportional":
            raise NotImplementedError(
                "DiskANN backend does not support 'proportional' pruning strategy. Use 'global' or 'local' instead."
            )
        # Use recompute_embeddings parameter
        use_recompute = recompute_embeddings
        if use_recompute:
            meta_file_path = self.index_dir / f"{self.index_path.name}.meta.json"
            if not meta_file_path.exists():
                raise RuntimeError(
                    f"FATAL: Recompute enabled but metadata file not found: {meta_file_path}"
                )
            self._ensure_server_running(str(meta_file_path), port=zmq_port, **kwargs)
        if query.dtype != np.float32:
            query = query.astype(np.float32)
@@ -194,28 +311,26 @@ class DiskannSearcher(BaseSearcher):
        else:  # "global"
            use_global_pruning = True
-        labels, distances = self._index.batch_search(
+        # Perform search with suppressed C++ output based on log level
-            query,
+        use_deferred_fetch = kwargs.get("USE_DEFERRED_FETCH", True)
-            query.shape[0],
+        recompute_neighors = False
-            top_k,
+        with suppress_cpp_output_if_needed():
-            complexity,
+            labels, distances = self._index.batch_search(
-            beam_width,
+                query,
-            self.num_threads,
+                query.shape[0],
-            kwargs.get("USE_DEFERRED_FETCH", False),
+                top_k,
-            kwargs.get("skip_search_reorder", False),
+                complexity,
-            use_recompute,
+                beam_width,
-            dedup_node_dis,
+                self.num_threads,
-            prune_ratio,
+                use_deferred_fetch,
-            batch_recompute,
+                kwargs.get("skip_search_reorder", False),
-            use_global_pruning,
+                recompute_neighors,
-        )
+                dedup_node_dis,
                prune_ratio,
                batch_recompute,
                use_global_pruning,
            )
-        string_labels = [
+        string_labels = [[str(int_label) for int_label in batch_labels] for batch_labels in labels]
            [
                self.label_map.get(int_label, f"unknown_{int_label}")
                for int_label in batch_labels
            ]
            for batch_labels in labels
        ]
        return {"labels": string_labels, "distances": distances}
--- a/packages/leann-backend-diskann/leann_backend_diskann/diskann_embedding_server.py
+++ b/packages/leann-backend-diskann/leann_backend_diskann/diskann_embedding_server.py
@@ -0,0 +1,284 @@
 """
 DiskANN-specific embedding server
 """
 import argparse
 import json
 import logging
 import os
 import sys
 import threading
 import time
 from pathlib import Path
 import numpy as np
 import zmq
 # Set up logging based on environment variable
 LOG_LEVEL = os.getenv("LEANN_LOG_LEVEL", "WARNING").upper()
 logger = logging.getLogger(__name__)
 # Force set logger level (don't rely on basicConfig in subprocess)
 log_level = getattr(logging, LOG_LEVEL, logging.WARNING)
 logger.setLevel(log_level)
 # Ensure we have a handler if none exists
 if not logger.handlers:
    handler = logging.StreamHandler()
    formatter = logging.Formatter("%(asctime)s - %(levelname)s - %(message)s")
    handler.setFormatter(formatter)
    logger.addHandler(handler)
    logger.propagate = False
 def create_diskann_embedding_server(
    passages_file: str | None = None,
    zmq_port: int = 5555,
    model_name: str = "sentence-transformers/all-mpnet-base-v2",
    embedding_mode: str = "sentence-transformers",
    distance_metric: str = "l2",
 ):
    """
    Create and start a ZMQ-based embedding server for DiskANN backend.
    Uses ROUTER socket and protobuf communication as required by DiskANN C++ implementation.
    """
    logger.info(f"Starting DiskANN server on port {zmq_port} with model {model_name}")
    logger.info(f"Using embedding mode: {embedding_mode}")
    # Add leann-core to path for unified embedding computation
    current_dir = Path(__file__).parent
    leann_core_path = current_dir.parent.parent / "leann-core" / "src"
    sys.path.insert(0, str(leann_core_path))
    try:
        from leann.api import PassageManager
        from leann.embedding_compute import compute_embeddings
        logger.info("Successfully imported unified embedding computation module")
    except ImportError as e:
        logger.error(f"Failed to import embedding computation module: {e}")
        return
    finally:
        sys.path.pop(0)
    # Check port availability
    import socket
    def check_port(port):
        with socket.socket(socket.AF_INET, socket.SOCK_STREAM) as s:
            return s.connect_ex(("localhost", port)) == 0
    if check_port(zmq_port):
        logger.error(f"Port {zmq_port} is already in use")
        return
    # Only support metadata file, fail fast for everything else
    if not passages_file or not passages_file.endswith(".meta.json"):
        raise ValueError("Only metadata files (.meta.json) are supported")
    # Load metadata to get passage sources
    with open(passages_file) as f:
        meta = json.load(f)
    passages = PassageManager(meta["passage_sources"])
    logger.info(
        f"Loaded PassageManager with {len(passages.global_offset_map)} passages from metadata"
    )
    # Import protobuf after ensuring the path is correct
    try:
        from . import embedding_pb2
    except ImportError as e:
        logger.error(f"Failed to import protobuf module: {e}")
        return
    def zmq_server_thread():
        """ZMQ server thread using REP socket for universal compatibility"""
        context = zmq.Context()
        socket = context.socket(
            zmq.REP
        )  # REP socket for both BaseSearcher and DiskANN C++ REQ clients
        socket.bind(f"tcp://*:{zmq_port}")
        logger.info(f"DiskANN ZMQ REP server listening on port {zmq_port}")
        socket.setsockopt(zmq.RCVTIMEO, 300000)
        socket.setsockopt(zmq.SNDTIMEO, 300000)
        while True:
            try:
                # REP socket receives single-part messages
                message = socket.recv()
                # Check for empty messages - REP socket requires response to every request
                if len(message) == 0:
                    logger.debug("Received empty message, sending empty response")
                    socket.send(b"")  # REP socket must respond to every request
                    continue
                logger.debug(f"Received ZMQ request of size {len(message)} bytes")
                logger.debug(f"Message preview: {message[:50]}")  # Show first 50 bytes
                e2e_start = time.time()
                # Try protobuf first (for DiskANN C++ node_ids requests - primary use case)
                texts = []
                node_ids = []
                is_text_request = False
                try:
                    req_proto = embedding_pb2.NodeEmbeddingRequest()
                    req_proto.ParseFromString(message)
                    node_ids = list(req_proto.node_ids)
                    if not node_ids:
                        raise RuntimeError(
                            f"PROTOBUF: Received empty node_ids! Message size: {len(message)}"
                        )
                    logger.info(
                        f"✅ PROTOBUF: Node ID request for {len(node_ids)} node embeddings: {node_ids[:10]}"
                    )
                except Exception as protobuf_error:
                    logger.debug(f"Protobuf parsing failed: {protobuf_error}")
                    # Fallback to msgpack (for BaseSearcher direct text requests)
                    try:
                        import msgpack
                        request = msgpack.unpackb(message)
                        # For BaseSearcher compatibility, request is a list of texts directly
                        if isinstance(request, list) and all(
                            isinstance(item, str) for item in request
                        ):
                            texts = request
                            is_text_request = True
                            logger.info(f"✅ MSGPACK: Direct text request for {len(texts)} texts")
                        else:
                            raise ValueError("Not a valid msgpack text request")
                    except Exception as msgpack_error:
                        raise RuntimeError(
                            f"Both protobuf and msgpack parsing failed! Protobuf: {protobuf_error}, Msgpack: {msgpack_error}"
                        )
                # Look up texts by node IDs (only if not direct text request)
                if not is_text_request:
                    for nid in node_ids:
                        try:
                            passage_data = passages.get_passage(str(nid))
                            txt = passage_data["text"]
                            if not txt:
                                raise RuntimeError(f"FATAL: Empty text for passage ID {nid}")
                            texts.append(txt)
                        except KeyError as e:
                            logger.error(f"Passage ID {nid} not found: {e}")
                            raise e
                        except Exception as e:
                            logger.error(f"Exception looking up passage ID {nid}: {e}")
                            raise
                    # Debug logging
                    logger.debug(f"Processing {len(texts)} texts")
                    logger.debug(f"Text lengths: {[len(t) for t in texts[:5]]}")  # Show first 5
                # Process embeddings using unified computation
                embeddings = compute_embeddings(texts, model_name, mode=embedding_mode)
                logger.info(
                    f"Computed embeddings for {len(texts)} texts, shape: {embeddings.shape}"
                )
                # Prepare response based on request type
                if is_text_request:
                    # For BaseSearcher compatibility: return msgpack format
                    import msgpack
                    response_data = msgpack.packb(embeddings.tolist())
                else:
                    # For DiskANN C++ compatibility: return protobuf format
                    resp_proto = embedding_pb2.NodeEmbeddingResponse()
                    hidden_contiguous = np.ascontiguousarray(embeddings, dtype=np.float32)
                    # Serialize embeddings data
                    resp_proto.embeddings_data = hidden_contiguous.tobytes()
                    resp_proto.dimensions.append(hidden_contiguous.shape[0])
                    resp_proto.dimensions.append(hidden_contiguous.shape[1])
                    response_data = resp_proto.SerializeToString()
                # Send response back to the client
                socket.send(response_data)
                e2e_end = time.time()
                logger.info(f"⏱️  ZMQ E2E time: {e2e_end - e2e_start:.6f}s")
            except zmq.Again:
                logger.debug("ZMQ socket timeout, continuing to listen")
                continue
            except Exception as e:
                logger.error(f"Error in ZMQ server loop: {e}")
                import traceback
                traceback.print_exc()
                raise
    zmq_thread = threading.Thread(target=zmq_server_thread, daemon=True)
    zmq_thread.start()
    logger.info(f"Started DiskANN ZMQ server thread on port {zmq_port}")
    # Keep the main thread alive
    try:
        while True:
            time.sleep(1)
    except KeyboardInterrupt:
        logger.info("DiskANN Server shutting down...")
        return
 if __name__ == "__main__":
    import signal
    import sys
    def signal_handler(sig, frame):
        logger.info(f"Received signal {sig}, shutting down gracefully...")
        sys.exit(0)
    # Register signal handlers for graceful shutdown
    signal.signal(signal.SIGTERM, signal_handler)
    signal.signal(signal.SIGINT, signal_handler)
    parser = argparse.ArgumentParser(description="DiskANN Embedding service")
    parser.add_argument("--zmq-port", type=int, default=5555, help="ZMQ port to run on")
    parser.add_argument(
        "--passages-file",
        type=str,
        help="Metadata JSON file containing passage sources",
    )
    parser.add_argument(
        "--model-name",
        type=str,
        default="sentence-transformers/all-mpnet-base-v2",
        help="Embedding model name",
    )
    parser.add_argument(
        "--embedding-mode",
        type=str,
        default="sentence-transformers",
        choices=["sentence-transformers", "openai", "mlx", "ollama"],
        help="Embedding backend mode",
    )
    parser.add_argument(
        "--distance-metric",
        type=str,
        default="l2",
        choices=["l2", "mips", "cosine"],
        help="Distance metric for similarity computation",
    )
    args = parser.parse_args()
    # Create and start the DiskANN embedding server
    create_diskann_embedding_server(
        passages_file=args.passages_file,
        zmq_port=args.zmq_port,
        model_name=args.model_name,
        embedding_mode=args.embedding_mode,
        distance_metric=args.distance_metric,
    )
--- a/packages/leann-backend-diskann/leann_backend_diskann/embedding_pb2.py
+++ b/packages/leann-backend-diskann/leann_backend_diskann/embedding_pb2.py
@@ -1,27 +1,28 @@
 # -*- coding: utf-8 -*-
 # Generated by the protocol buffer compiler.  DO NOT EDIT!
 # source: embedding.proto
 # ruff: noqa
 """Generated protocol buffer code."""
-from google.protobuf.internal import builder as _builder
+
 from google.protobuf import descriptor as _descriptor
 from google.protobuf import descriptor_pool as _descriptor_pool
 from google.protobuf import symbol_database as _symbol_database
 from google.protobuf.internal import builder as _builder
 # @@protoc_insertion_point(imports)
 _sym_db = _symbol_database.Default()
-
+DESCRIPTOR = _descriptor_pool.Default().AddSerializedFile(
-
+    b'\n\x0f\x65mbedding.proto\x12\x0eprotoembedding"(\n\x14NodeEmbeddingRequest\x12\x10\n\x08node_ids\x18\x01 \x03(\r"Y\n\x15NodeEmbeddingResponse\x12\x17\n\x0f\x65mbeddings_data\x18\x01 \x01(\x0c\x12\x12\n\ndimensions\x18\x02 \x03(\x05\x12\x13\n\x0bmissing_ids\x18\x03 \x03(\rb\x06proto3'
-DESCRIPTOR = _descriptor_pool.Default().AddSerializedFile(b'\n\x0f\x65mbedding.proto\x12\x0eprotoembedding\"(\n\x14NodeEmbeddingRequest\x12\x10\n\x08node_ids\x18\x01 \x03(\r\"Y\n\x15NodeEmbeddingResponse\x12\x17\n\x0f\x65mbeddings_data\x18\x01 \x01(\x0c\x12\x12\n\ndimensions\x18\x02 \x03(\x05\x12\x13\n\x0bmissing_ids\x18\x03 \x03(\rb\x06proto3')
+)
 _builder.BuildMessageAndEnumDescriptors(DESCRIPTOR, globals())
-_builder.BuildTopDescriptorsAndMessages(DESCRIPTOR, 'embedding_pb2', globals())
+_builder.BuildTopDescriptorsAndMessages(DESCRIPTOR, "embedding_pb2", globals())
-if _descriptor._USE_C_DESCRIPTORS == False:
+if not _descriptor._USE_C_DESCRIPTORS:
-
+    DESCRIPTOR._options = None
-  DESCRIPTOR._options = None
+    _NODEEMBEDDINGREQUEST._serialized_start = 35
-  _NODEEMBEDDINGREQUEST._serialized_start=35
+    _NODEEMBEDDINGREQUEST._serialized_end = 75
-  _NODEEMBEDDINGREQUEST._serialized_end=75
+    _NODEEMBEDDINGRESPONSE._serialized_start = 77
-  _NODEEMBEDDINGRESPONSE._serialized_start=77
+    _NODEEMBEDDINGRESPONSE._serialized_end = 166
  _NODEEMBEDDINGRESPONSE._serialized_end=166
 # @@protoc_insertion_point(module_scope)
--- a/packages/leann-backend-diskann/leann_backend_diskann/embedding_server.py
+++ b/packages/leann-backend-diskann/leann_backend_diskann/embedding_server.py
@@ -1,741 +0,0 @@
 #!/usr/bin/env python3
 """
 Embedding server for leann-backend-diskann - Fixed ZMQ REQ-REP pattern
 """
 import pickle
 import argparse
 import time
 import json
 from typing import Dict, Any, Optional, Union
 from transformers import AutoTokenizer, AutoModel
 import os
 from contextlib import contextmanager
 import zmq
 import numpy as np
 import msgpack
 from pathlib import Path
 import logging
 RED = "\033[91m"
 # Set up logging based on environment variable
 LOG_LEVEL = os.getenv('LEANN_LOG_LEVEL', 'INFO').upper()
 logging.basicConfig(
    level=getattr(logging, LOG_LEVEL, logging.INFO),
    format='%(asctime)s - %(levelname)s - %(message)s'
 )
 logger = logging.getLogger(__name__)
 RESET = "\033[0m"
 # --- New Passage Loader from HNSW backend ---
 class SimplePassageLoader:
    """
    Simple passage loader that replaces config.py dependencies
    """
    def __init__(self, passages_data: Optional[Dict[str, Any]] = None):
        self.passages_data = passages_data or {}
        self._meta_path = ''
    def __getitem__(self, passage_id: Union[str, int]) -> Dict[str, str]:
        """Get passage by ID"""
        str_id = str(passage_id)
        if str_id in self.passages_data:
            return {"text": self.passages_data[str_id]}
        else:
            # Return empty text for missing passages
            return {"text": ""}
    def __len__(self) -> int:
        return len(self.passages_data)
    def keys(self):
        return self.passages_data.keys()
 def load_passages_from_metadata(meta_file: str) -> SimplePassageLoader:
    """
    Load passages using metadata file with PassageManager for lazy loading
    """
    # Load metadata to get passage sources
    with open(meta_file, 'r') as f:
        meta = json.load(f)
    # Import PassageManager dynamically to avoid circular imports
    import sys
    from pathlib import Path
    # Find the leann package directory relative to this file
    current_dir = Path(__file__).parent
    leann_core_path = current_dir.parent.parent / "leann-core" / "src"
    sys.path.insert(0, str(leann_core_path))
    try:
        from leann.api import PassageManager
        passage_manager = PassageManager(meta['passage_sources'])
    finally:
        sys.path.pop(0)
    # Load label map 
    passages_dir = Path(meta_file).parent
    label_map_file = passages_dir / "leann.labels.map"
    if label_map_file.exists():
        import pickle
        with open(label_map_file, 'rb') as f:
            label_map = pickle.load(f)
        print(f"Loaded label map with {len(label_map)} entries")
    else:
        raise FileNotFoundError(f"Label map file not found: {label_map_file}")
    print(f"Initialized lazy passage loading for {len(label_map)} passages")
    class LazyPassageLoader(SimplePassageLoader):
        def __init__(self, passage_manager, label_map):
            self.passage_manager = passage_manager
            self.label_map = label_map
            # Initialize parent with empty data
            super().__init__({})
        def __getitem__(self, passage_id: Union[str, int]) -> Dict[str, str]:
            """Get passage by ID with lazy loading"""
            try:
                int_id = int(passage_id)
                if int_id in self.label_map:
                    string_id = self.label_map[int_id]
                    passage_data = self.passage_manager.get_passage(string_id)
                    if passage_data and passage_data.get("text"):
                        return {"text": passage_data["text"]}
                    else:
                        raise RuntimeError(f"FATAL: Empty text for ID {int_id} -> {string_id}")
                else:
                    raise RuntimeError(f"FATAL: ID {int_id} not found in label_map")
            except Exception as e:
                raise RuntimeError(f"FATAL: Exception getting passage {passage_id}: {e}")
        def __len__(self) -> int:
            return len(self.label_map)
        def keys(self):
            return self.label_map.keys()
    loader = LazyPassageLoader(passage_manager, label_map)
    loader._meta_path = meta_file
    return loader
 def load_passages_from_file(passages_file: str) -> SimplePassageLoader:
    """
    Load passages from a JSONL file with label map support
    Expected format: {"id": "passage_id", "text": "passage_text", "metadata": {...}} (one per line)
    """
    if not os.path.exists(passages_file):
        raise FileNotFoundError(f"Passages file {passages_file} not found.")
    if not passages_file.endswith('.jsonl'):
        raise ValueError(f"Expected .jsonl file format, got: {passages_file}")
    # Load label map (int -> string_id)
    passages_dir = Path(passages_file).parent
    label_map_file = passages_dir / "leann.labels.map"
    label_map = {}
    if label_map_file.exists():
        with open(label_map_file, 'rb') as f:
            label_map = pickle.load(f)
        print(f"Loaded label map with {len(label_map)} entries")
    else:
        raise FileNotFoundError(f"Label map file not found: {label_map_file}")
    # Load passages by string ID
    string_id_passages = {}
    with open(passages_file, 'r', encoding='utf-8') as f:
        for line in f:
            if line.strip():
                passage = json.loads(line)
                string_id_passages[passage['id']] = passage['text']
    # Create int ID -> text mapping using label map
    passages_data = {}
    for int_id, string_id in label_map.items():
        if string_id in string_id_passages:
            passages_data[str(int_id)] = string_id_passages[string_id]
        else:
            print(f"WARNING: String ID {string_id} from label map not found in passages")
    print(f"Loaded {len(passages_data)} passages from JSONL file {passages_file} using label map")
    return SimplePassageLoader(passages_data)
 def create_embedding_server_thread(
    zmq_port=5555,
    model_name="sentence-transformers/all-mpnet-base-v2",
    max_batch_size=128,
    passages_file: Optional[str] = None,
    embedding_mode: str = "sentence-transformers",
    enable_warmup: bool = False,
 ):
    """
    Create and run embedding server in the current thread
    This function is designed to be called in a separate thread
    """
    logger.info(f"Initializing embedding server thread on port {zmq_port}")
    try:
        # Check if port is already occupied
        import socket
        def check_port(port):
            with socket.socket(socket.AF_INET, socket.SOCK_STREAM) as s:
                return s.connect_ex(('localhost', port)) == 0
        if check_port(zmq_port):
            print(f"{RED}Port {zmq_port} is already in use{RESET}")
            return
        # Auto-detect mode based on model name if not explicitly set
        if embedding_mode == "sentence-transformers" and model_name.startswith("text-embedding-"):
            embedding_mode = "openai"
        if embedding_mode == "mlx":
            from leann.api import compute_embeddings_mlx
            import torch
            logger.info("Using MLX for embeddings")
            # Set device to CPU for compatibility with DeviceTimer class
            device = torch.device("cpu")
            cuda_available = False
            mps_available = False
        elif embedding_mode == "openai":
            from leann.api import compute_embeddings_openai
            import torch
            logger.info("Using OpenAI API for embeddings")
            # Set device to CPU for compatibility with DeviceTimer class
            device = torch.device("cpu")
            cuda_available = False
            mps_available = False
        elif embedding_mode == "sentence-transformers":
            # Initialize model
            tokenizer = AutoTokenizer.from_pretrained(model_name, use_fast=True)
            import torch
            # Select device
            mps_available = hasattr(torch.backends, 'mps') and torch.backends.mps.is_available()
            cuda_available = torch.cuda.is_available()
            if cuda_available:
                device = torch.device("cuda")
                logger.info("Using CUDA device")
            elif mps_available:
                device = torch.device("mps")
                logger.info("Using MPS device (Apple Silicon)")
            else:
                device = torch.device("cpu")
                logger.info("Using CPU device")
            # Load model
            logger.info(f"Loading model {model_name}")
            model = AutoModel.from_pretrained(model_name).to(device).eval()
            # Optimize model
            if cuda_available or mps_available:
                try:
                    model = model.half()
                    model = torch.compile(model)
                    logger.info(f"Using FP16 precision with model: {model_name}")
                except Exception as e:
                    print(f"WARNING: Model optimization failed: {e}")
        else:
            raise ValueError(f"Unsupported embedding mode: {embedding_mode}. Supported modes: sentence-transformers, mlx, openai")
        # Load passages from file if provided
        if passages_file and os.path.exists(passages_file):
            # Check if it's a metadata file or a single passages file
            if passages_file.endswith('.meta.json'):
                passages = load_passages_from_metadata(passages_file)
            else:
                # Try to find metadata file in same directory
                passages_dir = Path(passages_file).parent
                meta_files = list(passages_dir.glob("*.meta.json"))
                if meta_files:
                    print(f"Found metadata file: {meta_files[0]}, using lazy loading")
                    passages = load_passages_from_metadata(str(meta_files[0]))
                else:
                    # Fallback to original single file loading (will cause warnings)
                    print("WARNING: No metadata file found, using single file loading (may cause missing passage warnings)")
                    passages = load_passages_from_file(passages_file)
        else:
            print("WARNING: No passages file provided or file not found. Using an empty passage loader.")
            passages = SimplePassageLoader()
        logger.info(f"Loaded {len(passages)} passages.")
        def client_warmup(zmq_port):
            """Perform client-side warmup for DiskANN server"""
            time.sleep(2)
            print(f"Performing client-side warmup with model {model_name}...")
            # Get actual passage IDs from the loaded passages
            sample_ids = []
            if hasattr(passages, 'keys') and len(passages) > 0:
                available_ids = list(passages.keys())
                # Take up to 5 actual IDs, but at least 1
                sample_ids = available_ids[:min(5, len(available_ids))]
                print(f"Using actual passage IDs for warmup: {sample_ids}")
            else:
                print("No passages available for warmup, skipping warmup...")
                return
            try:
                context = zmq.Context()
                socket = context.socket(zmq.REQ)
                socket.connect(f"tcp://localhost:{zmq_port}")
                socket.setsockopt(zmq.RCVTIMEO, 30000)
                socket.setsockopt(zmq.SNDTIMEO, 30000)
                try:
                    ids_to_send = [int(x) for x in sample_ids]
                except ValueError:
                    print("Warning: Could not convert sample IDs to integers, skipping warmup")
                    return
                if not ids_to_send:
                    print("Skipping warmup send.")
                    return
                # Use protobuf format for warmup
                from . import embedding_pb2
                req_proto = embedding_pb2.NodeEmbeddingRequest()
                req_proto.node_ids.extend(ids_to_send)
                request_bytes = req_proto.SerializeToString()
                for i in range(3):
                    print(f"Sending warmup request {i + 1}/3 via ZMQ (Protobuf)...")
                    socket.send(request_bytes)
                    response_bytes = socket.recv()
                    resp_proto = embedding_pb2.NodeEmbeddingResponse()
                    resp_proto.ParseFromString(response_bytes)
                    embeddings_count = resp_proto.dimensions[0] if resp_proto.dimensions else 0
                    print(f"Warmup request {i + 1}/3 successful, received {embeddings_count} embeddings")
                    time.sleep(0.1)
                print("Client-side Protobuf ZMQ warmup complete")
                socket.close()
                context.term()
            except Exception as e:
                print(f"Error during Protobuf ZMQ warmup: {e}")
        class DeviceTimer:
            """Device timer"""
            def __init__(self, name="", device=device):
                self.name = name
                self.device = device
                self.start_time = 0
                self.end_time = 0
                if embedding_mode == "sentence-transformers" and torch.cuda.is_available():
                    self.start_event = torch.cuda.Event(enable_timing=True)
                    self.end_event = torch.cuda.Event(enable_timing=True)
                else:
                    self.start_event = None
                    self.end_event = None
            @contextmanager
            def timing(self):
                self.start()
                yield
                self.end()
            def start(self):
                if embedding_mode == "sentence-transformers" and torch.cuda.is_available():
                    torch.cuda.synchronize()
                    self.start_event.record()
                else:
                    if embedding_mode == "sentence-transformers" and self.device.type == "mps":
                        torch.mps.synchronize()
                    self.start_time = time.time()
            def end(self):
                if embedding_mode == "sentence-transformers" and torch.cuda.is_available():
                    self.end_event.record()
                    torch.cuda.synchronize()
                else:
                    if embedding_mode == "sentence-transformers" and self.device.type == "mps":
                        torch.mps.synchronize()
                    self.end_time = time.time()
            def elapsed_time(self):
                if embedding_mode == "sentence-transformers" and torch.cuda.is_available():
                    return self.start_event.elapsed_time(self.end_event) / 1000.0
                else:
                    return self.end_time - self.start_time
            def print_elapsed(self):
                elapsed = self.elapsed_time()
                print(f"[{self.name}] Elapsed time: {elapsed:.3f}s")
        def process_batch_pytorch(texts_batch, ids_batch, missing_ids):
            """Process text batch"""
            if not texts_batch:
                return np.array([])
            # Filter out empty texts and their corresponding IDs
            valid_texts = []
            valid_ids = []
            for i, text in enumerate(texts_batch):
                if text.strip():  # Only include non-empty texts
                    valid_texts.append(text)
                    valid_ids.append(ids_batch[i])
            if not valid_texts:
                print("WARNING: No valid texts in batch")
                return np.array([])
            # Tokenize
            token_timer = DeviceTimer("tokenization")
            with token_timer.timing():
                inputs = tokenizer(
                    valid_texts,
                    padding=True,
                    truncation=True,
                    max_length=512,
                    return_tensors="pt"
                ).to(device)
            # Compute embeddings
            embed_timer = DeviceTimer("embedding computation")
            with embed_timer.timing():
                with torch.no_grad():
                    outputs = model(**inputs)
                    hidden_states = outputs.last_hidden_state
                    # Mean pooling
                    attention_mask = inputs['attention_mask']
                    mask_expanded = attention_mask.unsqueeze(-1).expand(hidden_states.size()).float()
                    sum_embeddings = torch.sum(hidden_states * mask_expanded, 1)
                    sum_mask = torch.clamp(mask_expanded.sum(1), min=1e-9)
                    batch_embeddings = sum_embeddings / sum_mask
                embed_timer.print_elapsed()
            return batch_embeddings.cpu().numpy()
        # ZMQ server main loop - modified to use REP socket
        context = zmq.Context()
        socket = context.socket(zmq.ROUTER)  # Changed to REP socket
        socket.bind(f"tcp://127.0.0.1:{zmq_port}")
        print(f"INFO: ZMQ ROUTER server listening on port {zmq_port}")
        # Set timeouts
        socket.setsockopt(zmq.RCVTIMEO, 5000)  # 5 second receive timeout
        socket.setsockopt(zmq.SNDTIMEO, 300000)  # 300 second send timeout
        from . import embedding_pb2
        print(f"INFO: Embedding server ready to serve requests")
        # Start warmup thread if enabled
        if enable_warmup and len(passages) > 0:
            import threading
            print(f"Warmup enabled: starting warmup thread")
            warmup_thread = threading.Thread(target=client_warmup, args=(zmq_port,))
            warmup_thread.daemon = True
            warmup_thread.start()
        else:
            print(f"Warmup disabled or no passages available (enable_warmup={enable_warmup}, passages={len(passages)})")
        while True:
            try:
                parts = socket.recv_multipart()
                # --- Restore robust message format detection ---
                # Must check parts length to avoid IndexError
                if len(parts) >= 3:
                    identity = parts[0]
                    # empty = parts[1]  # We usually don't care about the middle empty frame
                    message = parts[2]
                elif len(parts) == 2:
                    # Can also handle cases without empty frame
                    identity = parts[0]
                    message = parts[1]
                else:
                    # If received message format is wrong, print warning and ignore it instead of crashing
                    print(f"WARNING: Received unexpected message format with {len(parts)} parts. Ignoring.")
                    continue
                print(f"INFO: Received ZMQ request from client {identity.hex()[:8]}, size {len(message)} bytes")
                # Handle control messages (MessagePack format)
                try:
                    request_payload = msgpack.unpackb(message)
                    if isinstance(request_payload, list) and len(request_payload) >= 1:
                        if request_payload[0] == "__QUERY_META_PATH__":
                            # Return the current meta path being used by the server
                            current_meta_path = getattr(passages, '_meta_path', '') if hasattr(passages, '_meta_path') else ''
                            response = [current_meta_path]
                            socket.send_multipart([identity, b'', msgpack.packb(response)])
                            continue
                        elif request_payload[0] == "__UPDATE_META_PATH__" and len(request_payload) >= 2:
                            # Update the server's meta path and reload passages
                            new_meta_path = request_payload[1]
                            try:
                                print(f"INFO: Updating server meta path to: {new_meta_path}")
                                # Reload passages from the new meta file
                                passages = load_passages_from_metadata(new_meta_path)
                                # Store the meta path for future queries
                                passages._meta_path = new_meta_path
                                response = ["SUCCESS"]
                                print(f"INFO: Successfully updated meta path and reloaded {len(passages)} passages")
                            except Exception as e:
                                print(f"ERROR: Failed to update meta path: {e}")
                                response = ["FAILED", str(e)]
                            socket.send_multipart([identity, b'', msgpack.packb(response)])
                            continue
                        elif request_payload[0] == "__QUERY_MODEL__":
                            # Return the current model being used by the server
                            response = [model_name]
                            socket.send_multipart([identity, b'', msgpack.packb(response)])
                            continue
                        elif request_payload[0] == "__UPDATE_MODEL__" and len(request_payload) >= 2:
                            # Update the server's embedding model
                            new_model_name = request_payload[1]
                            try:
                                print(f"INFO: Updating server model from {model_name} to: {new_model_name}")
                                # Clean up old model to free memory
                                if not use_mlx:
                                    print("INFO: Releasing old model from memory...")
                                    old_model = model
                                    old_tokenizer = tokenizer
                                    # Load new tokenizer first
                                    print(f"Loading new tokenizer for {new_model_name}...")
                                    tokenizer = AutoTokenizer.from_pretrained(new_model_name, use_fast=True)
                                    # Load new model
                                    print(f"Loading new model {new_model_name}...")
                                    model = AutoModel.from_pretrained(new_model_name).to(device).eval()
                                    # Optimize new model
                                    if cuda_available or mps_available:
                                        try:
                                            model = model.half()
                                            model = torch.compile(model)
                                            print(f"INFO: Using FP16 precision with model: {new_model_name}")
                                        except Exception as e:
                                            print(f"WARNING: Model optimization failed: {e}")
                                    # Now safely delete old model after new one is loaded
                                    del old_model
                                    del old_tokenizer
                                    # Clear GPU cache if available
                                    if device.type == "cuda":
                                        torch.cuda.empty_cache()
                                        print("INFO: Cleared CUDA cache")
                                    elif device.type == "mps":
                                        torch.mps.empty_cache()
                                        print("INFO: Cleared MPS cache")
                                    # Force garbage collection
                                    import gc
                                    gc.collect()
                                    print("INFO: Memory cleanup completed")
                                # Update model name
                                model_name = new_model_name
                                response = ["SUCCESS"]
                                print(f"INFO: Successfully updated model to: {new_model_name}")
                            except Exception as e:
                                print(f"ERROR: Failed to update model: {e}")
                                response = ["FAILED", str(e)]
                            socket.send_multipart([identity, b'', msgpack.packb(response)])
                            continue
                except:
                    # Not a control message, continue with normal protobuf processing
                    pass
                e2e_start = time.time()
                lookup_timer = DeviceTimer("text lookup")
                # Parse request
                req_proto = embedding_pb2.NodeEmbeddingRequest()
                req_proto.ParseFromString(message)
                node_ids = req_proto.node_ids
                print(f"INFO: Request for {len(node_ids)} node embeddings: {list(node_ids)}")
                # Add debug information
                if len(node_ids) > 0:
                    print(f"DEBUG: Node ID range: {min(node_ids)} to {max(node_ids)}")
                # Look up texts
                texts = []
                missing_ids = []
                with lookup_timer.timing():
                    for nid in node_ids:
                        txtinfo = passages[nid]
                        txt = txtinfo["text"]
                        if txt:
                            texts.append(txt)
                        else:
                            # If text is empty, we still need a placeholder for batch processing,
                            # but record its ID as missing
                            texts.append("") 
                            missing_ids.append(nid)
                lookup_timer.print_elapsed()
                if missing_ids:
                    print(f"WARNING: Missing passages for IDs: {missing_ids}")
                # Process batch
                total_size = len(texts)
                print(f"INFO: Total batch size: {total_size}, max_batch_size: {max_batch_size}")
                all_embeddings = []
                if total_size > max_batch_size:
                    print(f"INFO: Splitting batch of size {total_size} into chunks of {max_batch_size}")
                    for i in range(0, total_size, max_batch_size):
                        end_idx = min(i + max_batch_size, total_size)
                        print(f"INFO: Processing chunk {i//max_batch_size + 1}/{(total_size + max_batch_size - 1)//max_batch_size}: items {i} to {end_idx-1}")
                        chunk_texts = texts[i:end_idx]
                        chunk_ids = node_ids[i:end_idx]
                        if embedding_mode == "mlx":
                            embeddings_chunk = compute_embeddings_mlx(chunk_texts, model_name, batch_size=16)
                        elif embedding_mode == "openai":
                            embeddings_chunk = compute_embeddings_openai(chunk_texts, model_name)
                        else:  # sentence-transformers
                            embeddings_chunk = process_batch_pytorch(chunk_texts, chunk_ids, missing_ids)
                        all_embeddings.append(embeddings_chunk)
                        if embedding_mode == "sentence-transformers":
                            if cuda_available:
                                torch.cuda.empty_cache()
                            elif device.type == "mps":
                                torch.mps.empty_cache()
                    hidden = np.vstack(all_embeddings)
                    print(f"INFO: Combined embeddings shape: {hidden.shape}")
                else:
                    if embedding_mode == "mlx":
                        hidden = compute_embeddings_mlx(texts, model_name, batch_size=16)
                    elif embedding_mode == "openai":
                        hidden = compute_embeddings_openai(texts, model_name)
                    else:  # sentence-transformers
                        hidden = process_batch_pytorch(texts, node_ids, missing_ids)
                # Serialize response
                ser_start = time.time()
                resp_proto = embedding_pb2.NodeEmbeddingResponse()
                hidden_contiguous = np.ascontiguousarray(hidden, dtype=np.float32)
                resp_proto.embeddings_data = hidden_contiguous.tobytes()
                resp_proto.dimensions.append(hidden_contiguous.shape[0])
                resp_proto.dimensions.append(hidden_contiguous.shape[1])
                resp_proto.missing_ids.extend(missing_ids)
                response_data = resp_proto.SerializeToString()
                # REP socket sends a single response
                socket.send_multipart([identity, b'', response_data])
                ser_end = time.time()
                print(f"INFO: Serialize time: {ser_end - ser_start:.6f} seconds")
                if embedding_mode == "sentence-transformers":
                    if device.type == "cuda":
                        torch.cuda.synchronize()
                    elif device.type == "mps":
                        torch.mps.synchronize()
                e2e_end = time.time()
                print(f"INFO: ZMQ E2E time: {e2e_end - e2e_start:.6f} seconds")
            except zmq.Again:
                print("INFO: ZMQ socket timeout, continuing to listen")
                continue
            except Exception as e:
                print(f"ERROR: Error in ZMQ server: {e}")
                try:
                    # Send empty response to maintain REQ-REP state
                    empty_resp = embedding_pb2.NodeEmbeddingResponse()
                    socket.send(empty_resp.SerializeToString())
                except:
                    # If sending fails, recreate socket
                    socket.close()
                    socket = context.socket(zmq.REP)
                    socket.bind(f"tcp://127.0.0.1:{zmq_port}")
                    socket.setsockopt(zmq.RCVTIMEO, 5000)
                    socket.setsockopt(zmq.SNDTIMEO, 300000)
                    print("INFO: ZMQ socket recreated after error")
    except Exception as e:
        print(f"ERROR: Failed to start embedding server: {e}")
        raise
 def create_embedding_server(
    domain="demo",
    load_passages=True,
    load_embeddings=False,
    use_fp16=True,
    use_int8=False,
    use_cuda_graphs=False,
    zmq_port=5555,
    max_batch_size=128,
    lazy_load_passages=False,
    model_name="sentence-transformers/all-mpnet-base-v2",
    passages_file: Optional[str] = None,
    embedding_mode: str = "sentence-transformers",
    enable_warmup: bool = False,
 ):
    """
    原有的 create_embedding_server 函数保持不变
    这个是阻塞版本，用于直接运行
    """
    create_embedding_server_thread(zmq_port, model_name, max_batch_size, passages_file, embedding_mode, enable_warmup)
 if __name__ == "__main__":
    parser = argparse.ArgumentParser(description="Embedding service")
    parser.add_argument("--zmq-port", type=int, default=5555, help="ZMQ port to run on")
    parser.add_argument("--domain", type=str, default="demo", help="Domain name")
    parser.add_argument("--passages-file", type=str, help="JSON file containing passage ID to text mapping")
    parser.add_argument("--load-passages", action="store_true", default=True)
    parser.add_argument("--load-embeddings", action="store_true", default=False)
    parser.add_argument("--use-fp16", action="store_true", default=False)
    parser.add_argument("--use-int8", action="store_true", default=False)
    parser.add_argument("--use-cuda-graphs", action="store_true", default=False)
    parser.add_argument("--max-batch-size", type=int, default=128, help="Maximum batch size before splitting")
    parser.add_argument("--lazy-load-passages", action="store_true", default=True)
    parser.add_argument("--model-name", type=str, default="sentence-transformers/all-mpnet-base-v2", 
                        help="Embedding model name")
    parser.add_argument("--embedding-mode", type=str, default="sentence-transformers", 
                        choices=["sentence-transformers", "mlx", "openai"],
                        help="Embedding backend mode")
    parser.add_argument("--use-mlx", action="store_true", default=False, help="Use MLX backend for embeddings (deprecated: use --embedding-mode mlx)")
    parser.add_argument("--disable-warmup", action="store_true", default=False, help="Disable warmup requests on server start")
    args = parser.parse_args()
    # Handle backward compatibility with use_mlx
    embedding_mode = args.embedding_mode
    if args.use_mlx:
        embedding_mode = "mlx"
    create_embedding_server(
        domain=args.domain,
        load_passages=args.load_passages,
        load_embeddings=args.load_embeddings,
        use_fp16=args.use_fp16,
        use_int8=args.use_int8,
        use_cuda_graphs=args.use_cuda_graphs,
        zmq_port=args.zmq_port,
        max_batch_size=args.max_batch_size,
        lazy_load_passages=args.lazy_load_passages,
        model_name=args.model_name,
        passages_file=args.passages_file,
        embedding_mode=embedding_mode,
        enable_warmup=not args.disable_warmup,
    )
--- a/packages/leann-backend-diskann/pyproject.toml
+++ b/packages/leann-backend-diskann/pyproject.toml
@@ -4,15 +4,15 @@ build-backend = "scikit_build_core.build"
 [project]
 name = "leann-backend-diskann"
-version = "0.1.0"
+version = "0.2.6"
-dependencies = ["leann-core==0.1.0", "numpy"]
+dependencies = ["leann-core==0.2.6", "numpy", "protobuf>=3.19.0"]
 [tool.scikit-build]
-# 关键：简化的 CMake 路径
+# Key: simplified CMake path
 cmake.source-dir = "third_party/DiskANN"
-# 关键：Python 包在根目录，路径完全匹配
+# Key: Python package in root directory, paths match exactly
 wheel.packages = ["leann_backend_diskann"]
-# 使用默认的 redirect 模式
+# Use default redirect mode
 editable.mode = "redirect"
 cmake.build-type = "Release"
 build.verbose = true
--- a/packages/leann-backend-diskann/third_party/DiskANN
+++ b/packages/leann-backend-diskann/third_party/DiskANN
--- a/packages/leann-backend-hnsw/CMakeLists.txt
+++ b/packages/leann-backend-hnsw/CMakeLists.txt
@@ -1,6 +1,7 @@
 # 最终简化版
 cmake_minimum_required(VERSION 3.24)
 project(leann_backend_hnsw_wrapper)
 set(CMAKE_C_COMPILER_WORKS 1)
 set(CMAKE_CXX_COMPILER_WORKS 1)
 # Set OpenMP path for macOS
 if(APPLE)
@@ -9,17 +10,19 @@ if(APPLE)
    set(OpenMP_C_LIB_NAMES "omp")
    set(OpenMP_CXX_LIB_NAMES "omp")
    set(OpenMP_omp_LIBRARY "/opt/homebrew/opt/libomp/lib/libomp.dylib")
    # Force use of system libc++ to avoid version mismatch
    set(CMAKE_CXX_FLAGS "${CMAKE_CXX_FLAGS} -stdlib=libc++")
    set(CMAKE_EXE_LINKER_FLAGS "${CMAKE_EXE_LINKER_FLAGS} -stdlib=libc++")
    set(CMAKE_SHARED_LINKER_FLAGS "${CMAKE_SHARED_LINKER_FLAGS} -stdlib=libc++")
    # Set minimum macOS version for better compatibility
    set(CMAKE_OSX_DEPLOYMENT_TARGET "11.0" CACHE STRING "Minimum macOS version")
 endif()
-# Build ZeroMQ from source
+# Use system ZeroMQ instead of building from source
-set(ZMQ_BUILD_TESTS OFF CACHE BOOL "" FORCE)
+find_package(PkgConfig REQUIRED)
-set(ENABLE_DRAFTS OFF CACHE BOOL "" FORCE)
+pkg_check_modules(ZMQ REQUIRED libzmq)
 set(ENABLE_PRECOMPILED OFF CACHE BOOL "" FORCE)
 set(WITH_PERF_TOOL OFF CACHE BOOL "" FORCE)
 set(WITH_DOCS OFF CACHE BOOL "" FORCE)
 set(BUILD_SHARED OFF CACHE BOOL "" FORCE)
 set(BUILD_STATIC ON CACHE BOOL "" FORCE)
 add_subdirectory(third_party/libzmq)
 # Add cppzmq headers
 include_directories(third_party/cppzmq)
@@ -29,6 +32,7 @@ set(MSGPACK_USE_BOOST OFF CACHE BOOL "" FORCE)
 add_compile_definitions(MSGPACK_NO_BOOST)
 include_directories(third_party/msgpack-c/include)
 # Faiss configuration - streamlined build
 set(FAISS_ENABLE_PYTHON ON CACHE BOOL "" FORCE)
 set(FAISS_ENABLE_GPU OFF CACHE BOOL "" FORCE)
 set(FAISS_ENABLE_EXTRAS OFF CACHE BOOL "" FORCE)
@@ -36,4 +40,24 @@ set(BUILD_TESTING OFF CACHE BOOL "" FORCE)
 set(FAISS_ENABLE_C_API OFF CACHE BOOL "" FORCE)
 set(FAISS_OPT_LEVEL "generic" CACHE STRING "" FORCE)
 # Disable additional SIMD versions to speed up compilation
 set(FAISS_ENABLE_AVX2 OFF CACHE BOOL "" FORCE)
 set(FAISS_ENABLE_AVX512 OFF CACHE BOOL "" FORCE)
 # Additional optimization options from INSTALL.md
 set(CMAKE_BUILD_TYPE "Release" CACHE STRING "" FORCE)
 set(BUILD_SHARED_LIBS OFF CACHE BOOL "" FORCE)  # Static library is faster to build
 # Avoid building demos and benchmarks
 set(BUILD_DEMOS OFF CACHE BOOL "" FORCE)
 set(BUILD_BENCHS OFF CACHE BOOL "" FORCE)
 # NEW: Tell Faiss to only build the generic version
 set(FAISS_BUILD_GENERIC ON CACHE BOOL "" FORCE)
 set(FAISS_BUILD_AVX2 OFF CACHE BOOL "" FORCE)
 set(FAISS_BUILD_AVX512 OFF CACHE BOOL "" FORCE)
 # IMPORTANT: Disable building AVX versions to speed up compilation
 set(FAISS_BUILD_AVX_VERSIONS OFF CACHE BOOL "" FORCE)
 add_subdirectory(third_party/faiss)
--- a/packages/leann-backend-hnsw/leann_backend_hnsw/init.py
+++ b/packages/leann-backend-hnsw/leann_backend_hnsw/init.py
@@ -1 +1 @@
-from . import hnsw_backend
+from . import hnsw_backend as hnsw_backend
--- a/packages/leann-backend-hnsw/leann_backend_hnsw/convert_to_csr.py
+++ b/packages/leann-backend-hnsw/leann_backend_hnsw/convert_to_csr.py
@@ -1,87 +1,115 @@
 import argparse
 import gc  # Import garbage collector interface
 import os
 import struct
 import sys
 import numpy as np
 import os
 import argparse
 import gc # Import garbage collector interface
 import time
 import numpy as np
 # --- FourCCs (add more if needed) ---
-INDEX_HNSW_FLAT_FOURCC = int.from_bytes(b'IHNf', 'little')
+INDEX_HNSW_FLAT_FOURCC = int.from_bytes(b"IHNf", "little")
 # Add other HNSW fourccs if you expect different storage types inside HNSW
 # INDEX_HNSW_PQ_FOURCC = int.from_bytes(b'IHNp', 'little')
 # INDEX_HNSW_SQ_FOURCC = int.from_bytes(b'IHNs', 'little')
 # INDEX_HNSW_CAGRA_FOURCC = int.from_bytes(b'IHNc', 'little') # Example
-EXPECTED_HNSW_FOURCCS = {INDEX_HNSW_FLAT_FOURCC} # Modify if needed
+EXPECTED_HNSW_FOURCCS = {INDEX_HNSW_FLAT_FOURCC}  # Modify if needed
-NULL_INDEX_FOURCC = int.from_bytes(b'null', 'little')
+NULL_INDEX_FOURCC = int.from_bytes(b"null", "little")
 # --- Helper functions for reading/writing binary data ---
 def read_struct(f, fmt):
    """Reads data according to the struct format."""
    size = struct.calcsize(fmt)
    data = f.read(size)
    if len(data) != size:
-        raise EOFError(f"File ended unexpectedly reading struct fmt '{fmt}'. Expected {size} bytes, got {len(data)}.")
+        raise EOFError(
            f"File ended unexpectedly reading struct fmt '{fmt}'. Expected {size} bytes, got {len(data)}."
        )
    return struct.unpack(fmt, data)[0]
 def read_vector_raw(f, element_fmt_char):
    """Reads a vector (size followed by data), returns count and raw bytes."""
-    count = -1 # Initialize count
+    count = -1  # Initialize count
-    total_bytes = -1 # Initialize total_bytes
+    total_bytes = -1  # Initialize total_bytes
    try:
-        count = read_struct(f, '<Q') # size_t usually 64-bit unsigned
+        count = read_struct(f, "<Q")  # size_t usually 64-bit unsigned
        element_size = struct.calcsize(element_fmt_char)
        # --- FIX for MemoryError: Check for unreasonably large count ---
-        max_reasonable_count = 10 * (10**9) # ~10 billion elements limit
+        max_reasonable_count = 10 * (10**9)  # ~10 billion elements limit
        if count > max_reasonable_count or count < 0:
-            raise MemoryError(f"Vector count {count} seems unreasonably large, possibly due to file corruption or incorrect format read.")
+            raise MemoryError(
                f"Vector count {count} seems unreasonably large, possibly due to file corruption or incorrect format read."
            )
        total_bytes = count * element_size
        # --- FIX for MemoryError: Check for huge byte size before allocation ---
-        max_reasonable_bytes = 50 * (1024**3) # ~50 GB limit
+        max_reasonable_bytes = 50 * (1024**3)  # ~50 GB limit
-        if total_bytes > max_reasonable_bytes or total_bytes < 0: # Check for overflow
+        if total_bytes > max_reasonable_bytes or total_bytes < 0:  # Check for overflow
-             raise MemoryError(f"Attempting to read {total_bytes} bytes ({count} elements * {element_size} bytes/element), which exceeds the safety limit. File might be corrupted or format mismatch.")
+            raise MemoryError(
                f"Attempting to read {total_bytes} bytes ({count} elements * {element_size} bytes/element), which exceeds the safety limit. File might be corrupted or format mismatch."
            )
        data_bytes = f.read(total_bytes)
        if len(data_bytes) != total_bytes:
-             raise EOFError(f"File ended unexpectedly reading vector data. Expected {total_bytes} bytes, got {len(data_bytes)}.")
+            raise EOFError(
                f"File ended unexpectedly reading vector data. Expected {total_bytes} bytes, got {len(data_bytes)}."
            )
        return count, data_bytes
    except (MemoryError, OverflowError) as e:
-         # Add context to the error message
+        # Add context to the error message
-         print(f"\nError during raw vector read (element_fmt='{element_fmt_char}', count={count}, total_bytes={total_bytes}): {e}", file=sys.stderr)
+        print(
-         raise e # Re-raise the original error type
+            f"\nError during raw vector read (element_fmt='{element_fmt_char}', count={count}, total_bytes={total_bytes}): {e}",
            file=sys.stderr,
        )
        raise e  # Re-raise the original error type
 def read_numpy_vector(f, np_dtype, struct_fmt_char):
    """Reads a vector into a NumPy array."""
-    count = -1 # Initialize count for robust error handling
+    count = -1  # Initialize count for robust error handling
-    print(f"  Reading vector (dtype={np_dtype}, fmt='{struct_fmt_char}')... ", end='', flush=True)
+    print(
        f"  Reading vector (dtype={np_dtype}, fmt='{struct_fmt_char}')... ",
        end="",
        flush=True,
    )
    try:
        count, data_bytes = read_vector_raw(f, struct_fmt_char)
        print(f"Count={count}, Bytes={len(data_bytes)}")
        if count > 0 and len(data_bytes) > 0:
            arr = np.frombuffer(data_bytes, dtype=np_dtype)
            if arr.size != count:
-                raise ValueError(f"Inconsistent array size after reading. Expected {count}, got {arr.size}")
+                raise ValueError(
                    f"Inconsistent array size after reading. Expected {count}, got {arr.size}"
                )
            return arr
        elif count == 0:
-             return np.array([], dtype=np_dtype)
+            return np.array([], dtype=np_dtype)
        else:
-             raise ValueError("Read zero bytes but count > 0.")
+            raise ValueError("Read zero bytes but count > 0.")
    except MemoryError as e:
        # Now count should be defined (or -1 if error was in read_struct)
-        print(f"\nMemoryError creating NumPy array (dtype={np_dtype}, count={count}). {e}", file=sys.stderr)
+        print(
            f"\nMemoryError creating NumPy array (dtype={np_dtype}, count={count}). {e}",
            file=sys.stderr,
        )
        raise e
-    except Exception as e: # Catch other potential errors like ValueError
+    except Exception as e:  # Catch other potential errors like ValueError
-        print(f"\nError reading numpy vector (dtype={np_dtype}, fmt='{struct_fmt_char}', count={count}): {e}", file=sys.stderr)
+        print(
            f"\nError reading numpy vector (dtype={np_dtype}, fmt='{struct_fmt_char}', count={count}): {e}",
            file=sys.stderr,
        )
        raise e
 def write_numpy_vector(f, arr, struct_fmt_char):
    """Writes a NumPy array as a vector (size followed by data)."""
    count = arr.size
-    f.write(struct.pack('<Q', count))
+    f.write(struct.pack("<Q", count))
    try:
        expected_dtype = np.dtype(struct_fmt_char)
        if arr.dtype != expected_dtype:
@@ -89,23 +117,30 @@ def write_numpy_vector(f, arr, struct_fmt_char):
        else:
            data_to_write = arr.tobytes()
        f.write(data_to_write)
-        del data_to_write # Hint GC
+        del data_to_write  # Hint GC
    except MemoryError as e:
-         print(f"\nMemoryError converting NumPy array to bytes for writing (size={count}, dtype={arr.dtype}). {e}", file=sys.stderr)
+        print(
-         raise e
+            f"\nMemoryError converting NumPy array to bytes for writing (size={count}, dtype={arr.dtype}). {e}",
            file=sys.stderr,
        )
        raise e
 def write_list_vector(f, lst, struct_fmt_char):
    """Writes a Python list as a vector iteratively."""
    count = len(lst)
-    f.write(struct.pack('<Q', count))
+    f.write(struct.pack("<Q", count))
-    fmt = '<' + struct_fmt_char
+    fmt = "<" + struct_fmt_char
    chunk_size = 1024 * 1024
    element_size = struct.calcsize(fmt)
    # Allocate buffer outside the loop if possible, or handle MemoryError during allocation
    try:
        buffer = bytearray(chunk_size * element_size)
    except MemoryError:
-        print(f"MemoryError: Cannot allocate buffer for writing list vector chunk (size {chunk_size * element_size} bytes).", file=sys.stderr)
+        print(
            f"MemoryError: Cannot allocate buffer for writing list vector chunk (size {chunk_size * element_size} bytes).",
            file=sys.stderr,
        )
        raise
    buffer_count = 0
@@ -116,65 +151,79 @@ def write_list_vector(f, lst, struct_fmt_char):
            buffer_count += 1
            if buffer_count == chunk_size or i == count - 1:
-                f.write(buffer[:buffer_count * element_size])
+                f.write(buffer[: buffer_count * element_size])
                buffer_count = 0
        except struct.error as e:
-            print(f"\nStruct packing error for item {item} at index {i} with format '{fmt}'. {e}", file=sys.stderr)
+            print(
                f"\nStruct packing error for item {item} at index {i} with format '{fmt}'. {e}",
                file=sys.stderr,
            )
            raise e
 def get_cum_neighbors(cum_nneighbor_per_level_np, level):
    """Helper to get cumulative neighbors count, matching C++ logic."""
-    if level < 0: return 0
+    if level < 0:
        return 0
    if level < len(cum_nneighbor_per_level_np):
        return cum_nneighbor_per_level_np[level]
    else:
        return cum_nneighbor_per_level_np[-1] if len(cum_nneighbor_per_level_np) > 0 else 0
-def write_compact_format(f_out, original_hnsw_data, assign_probas_np, cum_nneighbor_per_level_np, 
+
-                        levels_np, compact_level_ptr, compact_node_offsets_np, 
+def write_compact_format(
-                        compact_neighbors_data, storage_fourcc, storage_data):
+    f_out,
    original_hnsw_data,
    assign_probas_np,
    cum_nneighbor_per_level_np,
    levels_np,
    compact_level_ptr,
    compact_node_offsets_np,
    compact_neighbors_data,
    storage_fourcc,
    storage_data,
 ):
    """Write HNSW data in compact format following C++ read order exactly."""
    # Write IndexHNSW Header
-    f_out.write(struct.pack('<I', original_hnsw_data['index_fourcc']))
+    f_out.write(struct.pack("<I", original_hnsw_data["index_fourcc"]))
-    f_out.write(struct.pack('<i', original_hnsw_data['d']))
+    f_out.write(struct.pack("<i", original_hnsw_data["d"]))
-    f_out.write(struct.pack('<q', original_hnsw_data['ntotal']))
+    f_out.write(struct.pack("<q", original_hnsw_data["ntotal"]))
-    f_out.write(struct.pack('<q', original_hnsw_data['dummy1']))
+    f_out.write(struct.pack("<q", original_hnsw_data["dummy1"]))
-    f_out.write(struct.pack('<q', original_hnsw_data['dummy2']))
+    f_out.write(struct.pack("<q", original_hnsw_data["dummy2"]))
-    f_out.write(struct.pack('<?', original_hnsw_data['is_trained']))
+    f_out.write(struct.pack("<?", original_hnsw_data["is_trained"]))
-    f_out.write(struct.pack('<i', original_hnsw_data['metric_type']))
+    f_out.write(struct.pack("<i", original_hnsw_data["metric_type"]))
-    if original_hnsw_data['metric_type'] > 1:
+    if original_hnsw_data["metric_type"] > 1:
-         f_out.write(struct.pack('<f', original_hnsw_data['metric_arg']))
+        f_out.write(struct.pack("<f", original_hnsw_data["metric_arg"]))
    # Write HNSW struct parts (standard order)
-    write_numpy_vector(f_out, assign_probas_np, 'd')
+    write_numpy_vector(f_out, assign_probas_np, "d")
-    write_numpy_vector(f_out, cum_nneighbor_per_level_np, 'i')
+    write_numpy_vector(f_out, cum_nneighbor_per_level_np, "i")
-    write_numpy_vector(f_out, levels_np, 'i')
+    write_numpy_vector(f_out, levels_np, "i")
    # Write compact format flag
-    f_out.write(struct.pack('<?', True)) # storage_is_compact = True
+    f_out.write(struct.pack("<?", True))  # storage_is_compact = True
    # Write compact data in CORRECT C++ read order: level_ptr, node_offsets FIRST
    if isinstance(compact_level_ptr, np.ndarray):
-        write_numpy_vector(f_out, compact_level_ptr, 'Q')
+        write_numpy_vector(f_out, compact_level_ptr, "Q")
    else:
-        write_list_vector(f_out, compact_level_ptr, 'Q')
+        write_list_vector(f_out, compact_level_ptr, "Q")
-    write_numpy_vector(f_out, compact_node_offsets_np, 'Q')
+    write_numpy_vector(f_out, compact_node_offsets_np, "Q")
    # Write HNSW scalar parameters
-    f_out.write(struct.pack('<i', original_hnsw_data['entry_point']))
+    f_out.write(struct.pack("<i", original_hnsw_data["entry_point"]))
-    f_out.write(struct.pack('<i', original_hnsw_data['max_level']))
+    f_out.write(struct.pack("<i", original_hnsw_data["max_level"]))
-    f_out.write(struct.pack('<i', original_hnsw_data['efConstruction']))
+    f_out.write(struct.pack("<i", original_hnsw_data["efConstruction"]))
-    f_out.write(struct.pack('<i', original_hnsw_data['efSearch']))
+    f_out.write(struct.pack("<i", original_hnsw_data["efSearch"]))
-    f_out.write(struct.pack('<i', original_hnsw_data['dummy_upper_beam']))
+    f_out.write(struct.pack("<i", original_hnsw_data["dummy_upper_beam"]))
    # Write storage fourcc (this determines how to read what follows)
-    f_out.write(struct.pack('<I', storage_fourcc))
+    f_out.write(struct.pack("<I", storage_fourcc))
    # Write compact neighbors data AFTER storage fourcc
-    write_list_vector(f_out, compact_neighbors_data, 'i')
+    write_list_vector(f_out, compact_neighbors_data, "i")
    # Write storage data if not NULL (only after neighbors)
    if storage_fourcc != NULL_INDEX_FOURCC and storage_data:
@@ -183,6 +232,7 @@ def write_compact_format(f_out, original_hnsw_data, assign_probas_np, cum_nneigh
 # --- Main Conversion Logic ---
 def convert_hnsw_graph_to_csr(input_filename, output_filename, prune_embeddings=True):
    """
    Converts an HNSW graph file to the CSR format.
@@ -196,91 +246,115 @@ def convert_hnsw_graph_to_csr(input_filename, output_filename, prune_embeddings=
    print(f"Starting conversion: {input_filename} -> {output_filename}")
    start_time = time.time()
    original_hnsw_data = {}
-    neighbors_np = None # Initialize to allow check in finally block
+    neighbors_np = None  # Initialize to allow check in finally block
    try:
-        with open(input_filename, 'rb') as f_in, open(output_filename, 'wb') as f_out:
+        with open(input_filename, "rb") as f_in, open(output_filename, "wb") as f_out:
            # --- Read IndexHNSW FourCC and Header ---
            print(f"[{time.time() - start_time:.2f}s] Reading Index HNSW header...")
            # ... (Keep the header reading logic as before) ...
-            hnsw_index_fourcc = read_struct(f_in, '<I')
+            hnsw_index_fourcc = read_struct(f_in, "<I")
            if hnsw_index_fourcc not in EXPECTED_HNSW_FOURCCS:
-                 print(f"Error: Expected HNSW Index FourCC ({list(EXPECTED_HNSW_FOURCCS)}), got {hnsw_index_fourcc:08x}.", file=sys.stderr)
+                print(
-                 return False
+                    f"Error: Expected HNSW Index FourCC ({list(EXPECTED_HNSW_FOURCCS)}), got {hnsw_index_fourcc:08x}.",
-            original_hnsw_data['index_fourcc'] = hnsw_index_fourcc
+                    file=sys.stderr,
-            original_hnsw_data['d'] = read_struct(f_in, '<i')
+                )
-            original_hnsw_data['ntotal'] = read_struct(f_in, '<q')
+                return False
-            original_hnsw_data['dummy1'] = read_struct(f_in, '<q')
+            original_hnsw_data["index_fourcc"] = hnsw_index_fourcc
-            original_hnsw_data['dummy2'] = read_struct(f_in, '<q')
+            original_hnsw_data["d"] = read_struct(f_in, "<i")
-            original_hnsw_data['is_trained'] = read_struct(f_in, '?')
+            original_hnsw_data["ntotal"] = read_struct(f_in, "<q")
-            original_hnsw_data['metric_type'] = read_struct(f_in, '<i')
+            original_hnsw_data["dummy1"] = read_struct(f_in, "<q")
-            original_hnsw_data['metric_arg'] = 0.0
+            original_hnsw_data["dummy2"] = read_struct(f_in, "<q")
-            if original_hnsw_data['metric_type'] > 1:
+            original_hnsw_data["is_trained"] = read_struct(f_in, "?")
-                 original_hnsw_data['metric_arg'] = read_struct(f_in, '<f')
+            original_hnsw_data["metric_type"] = read_struct(f_in, "<i")
-            print(f"[{time.time() - start_time:.2f}s]   Header read: d={original_hnsw_data['d']}, ntotal={original_hnsw_data['ntotal']}")
+            original_hnsw_data["metric_arg"] = 0.0
-
+            if original_hnsw_data["metric_type"] > 1:
                original_hnsw_data["metric_arg"] = read_struct(f_in, "<f")
            print(
                f"[{time.time() - start_time:.2f}s]   Header read: d={original_hnsw_data['d']}, ntotal={original_hnsw_data['ntotal']}"
            )
            # --- Read original HNSW struct data ---
            print(f"[{time.time() - start_time:.2f}s] Reading HNSW struct vectors...")
-            assign_probas_np = read_numpy_vector(f_in, np.float64, 'd')
+            assign_probas_np = read_numpy_vector(f_in, np.float64, "d")
-            print(f"[{time.time() - start_time:.2f}s]   Read assign_probas ({assign_probas_np.size})")
+            print(
                f"[{time.time() - start_time:.2f}s]   Read assign_probas ({assign_probas_np.size})"
            )
            gc.collect()
-            cum_nneighbor_per_level_np = read_numpy_vector(f_in, np.int32, 'i')
+            cum_nneighbor_per_level_np = read_numpy_vector(f_in, np.int32, "i")
-            print(f"[{time.time() - start_time:.2f}s]   Read cum_nneighbor_per_level ({cum_nneighbor_per_level_np.size})")
+            print(
                f"[{time.time() - start_time:.2f}s]   Read cum_nneighbor_per_level ({cum_nneighbor_per_level_np.size})"
            )
            gc.collect()
-            levels_np = read_numpy_vector(f_in, np.int32, 'i')
+            levels_np = read_numpy_vector(f_in, np.int32, "i")
            print(f"[{time.time() - start_time:.2f}s]   Read levels ({levels_np.size})")
            gc.collect()
            ntotal = len(levels_np)
-            if ntotal != original_hnsw_data['ntotal']:
+            if ntotal != original_hnsw_data["ntotal"]:
-                 print(f"Warning: ntotal mismatch! Header says {original_hnsw_data['ntotal']}, levels vector size is {ntotal}. Using levels vector size.", file=sys.stderr)
+                print(
-                 original_hnsw_data['ntotal'] = ntotal
+                    f"Warning: ntotal mismatch! Header says {original_hnsw_data['ntotal']}, levels vector size is {ntotal}. Using levels vector size.",
                    file=sys.stderr,
                )
                original_hnsw_data["ntotal"] = ntotal
            # --- Check for compact format flag ---
            print(f"[{time.time() - start_time:.2f}s]   Probing for compact storage flag...")
            pos_before_compact = f_in.tell()
            try:
-                is_compact_flag = read_struct(f_in, '<?')
+                is_compact_flag = read_struct(f_in, "<?")
                print(f"[{time.time() - start_time:.2f}s]   Found compact flag: {is_compact_flag}")
                if is_compact_flag:
                    # Input is already in compact format - read compact data
-                    print(f"[{time.time() - start_time:.2f}s]   Input is already in compact format, reading compact data...")
+                    print(
                        f"[{time.time() - start_time:.2f}s]   Input is already in compact format, reading compact data..."
                    )
-                    compact_level_ptr = read_numpy_vector(f_in, np.uint64, 'Q')
+                    compact_level_ptr = read_numpy_vector(f_in, np.uint64, "Q")
-                    print(f"[{time.time() - start_time:.2f}s]   Read compact_level_ptr ({compact_level_ptr.size})")
+                    print(
                        f"[{time.time() - start_time:.2f}s]   Read compact_level_ptr ({compact_level_ptr.size})"
                    )
-                    compact_node_offsets_np = read_numpy_vector(f_in, np.uint64, 'Q')
+                    compact_node_offsets_np = read_numpy_vector(f_in, np.uint64, "Q")
-                    print(f"[{time.time() - start_time:.2f}s]   Read compact_node_offsets ({compact_node_offsets_np.size})")
+                    print(
                        f"[{time.time() - start_time:.2f}s]   Read compact_node_offsets ({compact_node_offsets_np.size})"
                    )
                    # Read scalar parameters
-                    original_hnsw_data['entry_point'] = read_struct(f_in, '<i')
+                    original_hnsw_data["entry_point"] = read_struct(f_in, "<i")
-                    original_hnsw_data['max_level'] = read_struct(f_in, '<i')
+                    original_hnsw_data["max_level"] = read_struct(f_in, "<i")
-                    original_hnsw_data['efConstruction'] = read_struct(f_in, '<i')
+                    original_hnsw_data["efConstruction"] = read_struct(f_in, "<i")
-                    original_hnsw_data['efSearch'] = read_struct(f_in, '<i')
+                    original_hnsw_data["efSearch"] = read_struct(f_in, "<i")
-                    original_hnsw_data['dummy_upper_beam'] = read_struct(f_in, '<i')
+                    original_hnsw_data["dummy_upper_beam"] = read_struct(f_in, "<i")
-                    print(f"[{time.time() - start_time:.2f}s]   Read scalar params (ep={original_hnsw_data['entry_point']}, max_lvl={original_hnsw_data['max_level']})")
+                    print(
                        f"[{time.time() - start_time:.2f}s]   Read scalar params (ep={original_hnsw_data['entry_point']}, max_lvl={original_hnsw_data['max_level']})"
                    )
                    # Read storage fourcc
-                    storage_fourcc = read_struct(f_in, '<I')
+                    storage_fourcc = read_struct(f_in, "<I")
-                    print(f"[{time.time() - start_time:.2f}s]   Found storage fourcc: {storage_fourcc:08x}")
+                    print(
                        f"[{time.time() - start_time:.2f}s]   Found storage fourcc: {storage_fourcc:08x}"
                    )
                    if prune_embeddings and storage_fourcc != NULL_INDEX_FOURCC:
                        # Read compact neighbors data
-                        compact_neighbors_data_np = read_numpy_vector(f_in, np.int32, 'i')
+                        compact_neighbors_data_np = read_numpy_vector(f_in, np.int32, "i")
-                        print(f"[{time.time() - start_time:.2f}s]   Read compact neighbors data ({compact_neighbors_data_np.size})")
+                        print(
                            f"[{time.time() - start_time:.2f}s]   Read compact neighbors data ({compact_neighbors_data_np.size})"
                        )
                        compact_neighbors_data = compact_neighbors_data_np.tolist()
                        del compact_neighbors_data_np
                        # Skip storage data and write with NULL marker
-                        print(f"[{time.time() - start_time:.2f}s]   Pruning embeddings: Writing NULL storage marker.")
+                        print(
                            f"[{time.time() - start_time:.2f}s]   Pruning embeddings: Writing NULL storage marker."
                        )
                        storage_fourcc = NULL_INDEX_FOURCC
                    elif not prune_embeddings:
                        # Read and preserve compact neighbors and storage
-                        compact_neighbors_data_np = read_numpy_vector(f_in, np.int32, 'i')
+                        compact_neighbors_data_np = read_numpy_vector(f_in, np.int32, "i")
                        compact_neighbors_data = compact_neighbors_data_np.tolist()
                        del compact_neighbors_data_np
@@ -288,16 +362,25 @@ def convert_hnsw_graph_to_csr(input_filename, output_filename, prune_embeddings=
                        storage_data = f_in.read()
                    else:
                        # Already pruned (NULL storage)
-                        compact_neighbors_data_np = read_numpy_vector(f_in, np.int32, 'i')
+                        compact_neighbors_data_np = read_numpy_vector(f_in, np.int32, "i")
                        compact_neighbors_data = compact_neighbors_data_np.tolist()
                        del compact_neighbors_data_np
-                        storage_data = b''
+                        storage_data = b""
                    # Write the updated compact format
                    print(f"[{time.time() - start_time:.2f}s] Writing updated compact format...")
-                    write_compact_format(f_out, original_hnsw_data, assign_probas_np, cum_nneighbor_per_level_np, 
+                    write_compact_format(
-                                       levels_np, compact_level_ptr, compact_node_offsets_np, 
+                        f_out,
-                                       compact_neighbors_data, storage_fourcc, storage_data if not prune_embeddings else b'')
+                        original_hnsw_data,
                        assign_probas_np,
                        cum_nneighbor_per_level_np,
                        levels_np,
                        compact_level_ptr,
                        compact_node_offsets_np,
                        compact_neighbors_data,
                        storage_fourcc,
                        storage_data if not prune_embeddings else b"",
                    )
                    print(f"[{time.time() - start_time:.2f}s] Conversion complete.")
                    return True
@@ -305,63 +388,86 @@ def convert_hnsw_graph_to_csr(input_filename, output_filename, prune_embeddings=
                else:
                    # is_compact=False, rewind and read original format
                    f_in.seek(pos_before_compact)
-                    print(f"[{time.time() - start_time:.2f}s]   Compact flag is False, reading original format...")
+                    print(
                        f"[{time.time() - start_time:.2f}s]   Compact flag is False, reading original format..."
                    )
            except EOFError:
                # No compact flag found, assume original format
                f_in.seek(pos_before_compact)
-                print(f"[{time.time() - start_time:.2f}s]   No compact flag found, assuming original format...")
+                print(
                    f"[{time.time() - start_time:.2f}s]   No compact flag found, assuming original format..."
                )
            # --- Handle potential extra byte in original format (like C++ code) ---
-            print(f"[{time.time() - start_time:.2f}s]   Probing for potential extra byte before non-compact offsets...")
+            print(
                f"[{time.time() - start_time:.2f}s]   Probing for potential extra byte before non-compact offsets..."
            )
            pos_before_probe = f_in.tell()
            try:
-                suspected_flag = read_struct(f_in, '<B')  # Read 1 byte
+                suspected_flag = read_struct(f_in, "<B")  # Read 1 byte
                if suspected_flag == 0x00:
-                    print(f"[{time.time() - start_time:.2f}s]   Found and consumed an unexpected 0x00 byte.")
+                    print(
                        f"[{time.time() - start_time:.2f}s]   Found and consumed an unexpected 0x00 byte."
                    )
                elif suspected_flag == 0x01:
-                    print(f"[{time.time() - start_time:.2f}s]   ERROR: Found 0x01 but is_compact should be False")
+                    print(
                        f"[{time.time() - start_time:.2f}s]   ERROR: Found 0x01 but is_compact should be False"
                    )
                    raise ValueError("Inconsistent compact flag state")
                else:
                    # Rewind - this byte is part of offsets data
                    f_in.seek(pos_before_probe)
-                    print(f"[{time.time() - start_time:.2f}s]   Rewound to original position (byte was 0x{suspected_flag:02x})")
+                    print(
                        f"[{time.time() - start_time:.2f}s]   Rewound to original position (byte was 0x{suspected_flag:02x})"
                    )
            except EOFError:
                f_in.seek(pos_before_probe)
-                print(f"[{time.time() - start_time:.2f}s]   No extra byte found (EOF), proceeding with offsets read")
+                print(
                    f"[{time.time() - start_time:.2f}s]   No extra byte found (EOF), proceeding with offsets read"
                )
            # --- Read original format data ---
-            offsets_np = read_numpy_vector(f_in, np.uint64, 'Q')
+            offsets_np = read_numpy_vector(f_in, np.uint64, "Q")
            print(f"[{time.time() - start_time:.2f}s]   Read offsets ({offsets_np.size})")
            if len(offsets_np) != ntotal + 1:
-                 raise ValueError(f"Inconsistent offsets size: len(levels)={ntotal} but len(offsets)={len(offsets_np)}")
+                raise ValueError(
                    f"Inconsistent offsets size: len(levels)={ntotal} but len(offsets)={len(offsets_np)}"
                )
            gc.collect()
            print(f"[{time.time() - start_time:.2f}s]   Attempting to read neighbors vector...")
-            neighbors_np = read_numpy_vector(f_in, np.int32, 'i')
+            neighbors_np = read_numpy_vector(f_in, np.int32, "i")
            print(f"[{time.time() - start_time:.2f}s]   Read neighbors ({neighbors_np.size})")
            expected_neighbors_size = offsets_np[-1] if ntotal > 0 else 0
            if neighbors_np.size != expected_neighbors_size:
-                 print(f"Warning: neighbors vector size mismatch. Expected {expected_neighbors_size} based on offsets, got {neighbors_np.size}.")
+                print(
                    f"Warning: neighbors vector size mismatch. Expected {expected_neighbors_size} based on offsets, got {neighbors_np.size}."
                )
            gc.collect()
-            original_hnsw_data['entry_point'] = read_struct(f_in, '<i')
+            original_hnsw_data["entry_point"] = read_struct(f_in, "<i")
-            original_hnsw_data['max_level'] = read_struct(f_in, '<i')
+            original_hnsw_data["max_level"] = read_struct(f_in, "<i")
-            original_hnsw_data['efConstruction'] = read_struct(f_in, '<i')
+            original_hnsw_data["efConstruction"] = read_struct(f_in, "<i")
-            original_hnsw_data['efSearch'] = read_struct(f_in, '<i')
+            original_hnsw_data["efSearch"] = read_struct(f_in, "<i")
-            original_hnsw_data['dummy_upper_beam'] = read_struct(f_in, '<i')
+            original_hnsw_data["dummy_upper_beam"] = read_struct(f_in, "<i")
-            print(f"[{time.time() - start_time:.2f}s]   Read scalar params (ep={original_hnsw_data['entry_point']}, max_lvl={original_hnsw_data['max_level']})")
+            print(
                f"[{time.time() - start_time:.2f}s]   Read scalar params (ep={original_hnsw_data['entry_point']}, max_lvl={original_hnsw_data['max_level']})"
            )
            print(f"[{time.time() - start_time:.2f}s] Checking for storage data...")
            storage_fourcc = None
            try:
-                storage_fourcc = read_struct(f_in, '<I')
+                storage_fourcc = read_struct(f_in, "<I")
-                print(f"[{time.time() - start_time:.2f}s]   Found storage fourcc: {storage_fourcc:08x}.")
+                print(
                    f"[{time.time() - start_time:.2f}s]   Found storage fourcc: {storage_fourcc:08x}."
                )
            except EOFError:
-                 print(f"[{time.time() - start_time:.2f}s]   No storage data found (EOF).")
+                print(f"[{time.time() - start_time:.2f}s]   No storage data found (EOF).")
            except Exception as e:
-                 print(f"[{time.time() - start_time:.2f}s]   Error reading potential storage data: {e}")
+                print(
-
+                    f"[{time.time() - start_time:.2f}s]   Error reading potential storage data: {e}"
                )
            # --- Perform Conversion ---
            print(f"[{time.time() - start_time:.2f}s] Converting to CSR format...")
@@ -373,17 +479,21 @@ def convert_hnsw_graph_to_csr(input_filename, output_filename, prune_embeddings=
            current_level_ptr_idx = 0
            current_data_idx = 0
-            total_valid_neighbors_counted = 0 # For validation
+            total_valid_neighbors_counted = 0  # For validation
            # Optimize calculation by getting slices once per node if possible
            for i in range(ntotal):
-                if i > 0 and i % (ntotal // 100 or 1) == 0: # Log progress roughly every 1%
+                if i > 0 and i % (ntotal // 100 or 1) == 0:  # Log progress roughly every 1%
                    progress = (i / ntotal) * 100
                    elapsed = time.time() - start_time
-                    print(f"\r[{elapsed:.2f}s]   Converting node {i}/{ntotal} ({progress:.1f}%)...", end="")
+                    print(
                        f"\r[{elapsed:.2f}s]   Converting node {i}/{ntotal} ({progress:.1f}%)...",
                        end="",
                    )
                node_max_level = levels_np[i] - 1
-                if node_max_level < -1: node_max_level = -1
+                if node_max_level < -1:
                    node_max_level = -1
                node_ptr_start_index = current_level_ptr_idx
                compact_node_offsets_np[i] = node_ptr_start_index
@@ -394,13 +504,17 @@ def convert_hnsw_graph_to_csr(input_filename, output_filename, prune_embeddings=
                for level in range(node_max_level + 1):
                    compact_level_ptr.append(current_data_idx)
-                    begin_orig_np = original_offset_start + get_cum_neighbors(cum_nneighbor_per_level_np, level)
+                    begin_orig_np = original_offset_start + get_cum_neighbors(
-                    end_orig_np = original_offset_start + get_cum_neighbors(cum_nneighbor_per_level_np, level + 1)
+                        cum_nneighbor_per_level_np, level
                    )
                    end_orig_np = original_offset_start + get_cum_neighbors(
                        cum_nneighbor_per_level_np, level + 1
                    )
                    begin_orig = int(begin_orig_np)
                    end_orig = int(end_orig_np)
-                    neighbors_len = len(neighbors_np) # Cache length
+                    neighbors_len = len(neighbors_np)  # Cache length
                    begin_orig = min(max(0, begin_orig), neighbors_len)
                    end_orig = min(max(begin_orig, end_orig), neighbors_len)
@@ -413,82 +527,116 @@ def convert_hnsw_graph_to_csr(input_filename, output_filename, prune_embeddings=
                        if num_valid > 0:
                            # Append valid neighbors
-                            compact_neighbors_data.extend(level_neighbors_slice[valid_neighbors_mask])
+                            compact_neighbors_data.extend(
                                level_neighbors_slice[valid_neighbors_mask]
                            )
                            current_data_idx += num_valid
                            total_valid_neighbors_counted += num_valid
                compact_level_ptr.append(current_data_idx)
                current_level_ptr_idx += num_pointers_expected
            compact_node_offsets_np[ntotal] = current_level_ptr_idx
-            print(f"\r[{time.time() - start_time:.2f}s]   Conversion loop finished.                        ") # Clear progress line
+            print(
                f"\r[{time.time() - start_time:.2f}s]   Conversion loop finished.                        "
            )  # Clear progress line
            # --- Validation Checks ---
            print(f"[{time.time() - start_time:.2f}s] Running validation checks...")
            valid_check_passed = True
            # Check 1: Total valid neighbors count
-            print(f"    Checking total valid neighbor count...")
+            print("    Checking total valid neighbor count...")
            expected_valid_count = np.sum(neighbors_np >= 0)
            if total_valid_neighbors_counted != len(compact_neighbors_data):
-                 print(f"Error: Mismatch between counted valid neighbors ({total_valid_neighbors_counted}) and final compact_data size ({len(compact_neighbors_data)})!", file=sys.stderr)
+                print(
-                 valid_check_passed = False
+                    f"Error: Mismatch between counted valid neighbors ({total_valid_neighbors_counted}) and final compact_data size ({len(compact_neighbors_data)})!",
                    file=sys.stderr,
                )
                valid_check_passed = False
            if expected_valid_count != len(compact_neighbors_data):
-                 print(f"Error: Mismatch between NumPy count of valid neighbors ({expected_valid_count}) and final compact_data size ({len(compact_neighbors_data)})!", file=sys.stderr)
+                print(
-                 valid_check_passed = False
+                    f"Error: Mismatch between NumPy count of valid neighbors ({expected_valid_count}) and final compact_data size ({len(compact_neighbors_data)})!",
                    file=sys.stderr,
                )
                valid_check_passed = False
            else:
-                 print(f"    OK: Total valid neighbors = {len(compact_neighbors_data)}")
+                print(f"    OK: Total valid neighbors = {len(compact_neighbors_data)}")
            # Check 2: Final pointer indices consistency
-            print(f"    Checking final pointer indices...")
+            print("    Checking final pointer indices...")
            if compact_node_offsets_np[ntotal] != len(compact_level_ptr):
-                 print(f"Error: Final node offset ({compact_node_offsets_np[ntotal]}) doesn't match level_ptr size ({len(compact_level_ptr)})!", file=sys.stderr)
+                print(
-                 valid_check_passed = False
+                    f"Error: Final node offset ({compact_node_offsets_np[ntotal]}) doesn't match level_ptr size ({len(compact_level_ptr)})!",
-            if (len(compact_level_ptr) > 0 and compact_level_ptr[-1] != len(compact_neighbors_data)) or \
+                    file=sys.stderr,
-               (len(compact_level_ptr) == 0 and len(compact_neighbors_data) != 0):
+                )
-                 last_ptr = compact_level_ptr[-1] if len(compact_level_ptr) > 0 else -1
+                valid_check_passed = False
-                 print(f"Error: Last level pointer ({last_ptr}) doesn't match compact_data size ({len(compact_neighbors_data)})!", file=sys.stderr)
+            if (
-                 valid_check_passed = False
+                len(compact_level_ptr) > 0 and compact_level_ptr[-1] != len(compact_neighbors_data)
            ) or (len(compact_level_ptr) == 0 and len(compact_neighbors_data) != 0):
                last_ptr = compact_level_ptr[-1] if len(compact_level_ptr) > 0 else -1
                print(
                    f"Error: Last level pointer ({last_ptr}) doesn't match compact_data size ({len(compact_neighbors_data)})!",
                    file=sys.stderr,
                )
                valid_check_passed = False
            else:
-                 print(f"    OK: Final pointers match data size.")
+                print("    OK: Final pointers match data size.")
            if not valid_check_passed:
-                print("Error: Validation checks failed. Output file might be incorrect.", file=sys.stderr)
+                print(
                    "Error: Validation checks failed. Output file might be incorrect.",
                    file=sys.stderr,
                )
                # Optional: Exit here if validation fails
                # return False
            # --- Explicitly delete large intermediate arrays ---
-            print(f"[{time.time() - start_time:.2f}s] Deleting original neighbors and offsets arrays...")
+            print(
                f"[{time.time() - start_time:.2f}s] Deleting original neighbors and offsets arrays..."
            )
            del neighbors_np
            del offsets_np
            gc.collect()
-            print(f"    CSR Stats: |data|={len(compact_neighbors_data)}, |level_ptr|={len(compact_level_ptr)}")
+            print(
                f"    CSR Stats: |data|={len(compact_neighbors_data)}, |level_ptr|={len(compact_level_ptr)}"
            )
            # --- Write CSR HNSW graph data using unified function ---
-            print(f"[{time.time() - start_time:.2f}s] Writing CSR HNSW graph data in FAISS-compatible order...")
+            print(
                f"[{time.time() - start_time:.2f}s] Writing CSR HNSW graph data in FAISS-compatible order..."
            )
            # Determine storage fourcc and data based on prune_embeddings
            if prune_embeddings:
-                print(f"   Pruning embeddings: Writing NULL storage marker.")
+                print("   Pruning embeddings: Writing NULL storage marker.")
                output_storage_fourcc = NULL_INDEX_FOURCC
-                storage_data = b''
+                storage_data = b""
            else:
                # Keep embeddings - read and preserve original storage data
                if storage_fourcc and storage_fourcc != NULL_INDEX_FOURCC:
-                    print(f"   Preserving embeddings: Reading original storage data...")
+                    print("   Preserving embeddings: Reading original storage data...")
                    storage_data = f_in.read()  # Read remaining storage data
                    output_storage_fourcc = storage_fourcc
                    print(f"   Read {len(storage_data)} bytes of storage data")
                else:
-                    print(f"   No embeddings found in original file (NULL storage)")
+                    print("   No embeddings found in original file (NULL storage)")
                    output_storage_fourcc = NULL_INDEX_FOURCC
-                    storage_data = b''
+                    storage_data = b""
            # Use the unified write function
-            write_compact_format(f_out, original_hnsw_data, assign_probas_np, cum_nneighbor_per_level_np, 
+            write_compact_format(
-                               levels_np, compact_level_ptr, compact_node_offsets_np, 
+                f_out,
-                               compact_neighbors_data, output_storage_fourcc, storage_data)
+                original_hnsw_data,
                assign_probas_np,
                cum_nneighbor_per_level_np,
                levels_np,
                compact_level_ptr,
                compact_node_offsets_np,
                compact_neighbors_data,
                output_storage_fourcc,
                storage_data,
            )
            # Clean up memory
            del assign_probas_np, cum_nneighbor_per_level_np, levels_np
@@ -503,40 +651,66 @@ def convert_hnsw_graph_to_csr(input_filename, output_filename, prune_embeddings=
        print(f"Error: Input file not found: {input_filename}", file=sys.stderr)
        return False
    except MemoryError as e:
-         print(f"\nFatal MemoryError during conversion: {e}. Insufficient RAM.", file=sys.stderr)
+        print(
-         # Clean up potentially partially written output file?
+            f"\nFatal MemoryError during conversion: {e}. Insufficient RAM.",
-         try: os.remove(output_filename)
+            file=sys.stderr,
-         except OSError: pass
+        )
-         return False
+        # Clean up potentially partially written output file?
        try:
            os.remove(output_filename)
        except OSError:
            pass
        return False
    except EOFError as e:
-        print(f"Error: Reached end of file unexpectedly reading {input_filename}. {e}", file=sys.stderr)
+        print(
-        try: os.remove(output_filename)
+            f"Error: Reached end of file unexpectedly reading {input_filename}. {e}",
-        except OSError: pass
+            file=sys.stderr,
        )
        try:
            os.remove(output_filename)
        except OSError:
            pass
        return False
    except Exception as e:
        print(f"An unexpected error occurred during conversion: {e}", file=sys.stderr)
        import traceback
        traceback.print_exc()
        try:
            os.remove(output_filename)
-        except OSError: pass
+        except OSError:
            pass
        return False
    # Ensure neighbors_np is deleted even if an error occurs after its allocation
    finally:
-        if 'neighbors_np' in locals() and neighbors_np is not None:
+        try:
-            del neighbors_np
+            if "neighbors_np" in locals() and neighbors_np is not None:
-            gc.collect()
+                del neighbors_np
                gc.collect()
        except NameError:
            pass
 # --- Script Execution ---
 if __name__ == "__main__":
-    parser = argparse.ArgumentParser(description="Convert a Faiss IndexHNSWFlat file to a CSR-based HNSW graph file.")
+    parser = argparse.ArgumentParser(
        description="Convert a Faiss IndexHNSWFlat file to a CSR-based HNSW graph file."
    )
    parser.add_argument("input_index_file", help="Path to the input IndexHNSWFlat file")
-    parser.add_argument("output_csr_graph_file", help="Path to write the output CSR HNSW graph file")
+    parser.add_argument(
-    parser.add_argument("--prune-embeddings", action="store_true", default=True, 
+        "output_csr_graph_file", help="Path to write the output CSR HNSW graph file"
-                       help="Prune embedding storage (write NULL storage marker)")
+    )
-    parser.add_argument("--keep-embeddings", action="store_true", 
+    parser.add_argument(
-                       help="Keep embedding storage (overrides --prune-embeddings)")
+        "--prune-embeddings",
        action="store_true",
        default=True,
        help="Prune embedding storage (write NULL storage marker)",
    )
    parser.add_argument(
        "--keep-embeddings",
        action="store_true",
        help="Keep embedding storage (overrides --prune-embeddings)",
    )
    args = parser.parse_args()
@@ -545,10 +719,12 @@ if __name__ == "__main__":
        sys.exit(1)
    if os.path.abspath(args.input_index_file) == os.path.abspath(args.output_csr_graph_file):
-         print(f"Error: Input and output filenames cannot be the same.", file=sys.stderr)
+        print("Error: Input and output filenames cannot be the same.", file=sys.stderr)
-         sys.exit(1)
+        sys.exit(1)
    prune_embeddings = args.prune_embeddings and not args.keep_embeddings
-    success = convert_hnsw_graph_to_csr(args.input_index_file, args.output_csr_graph_file, prune_embeddings)
+    success = convert_hnsw_graph_to_csr(
        args.input_index_file, args.output_csr_graph_file, prune_embeddings
    )
    if not success:
        sys.exit(1)
--- a/packages/leann-backend-hnsw/leann_backend_hnsw/hnsw_backend.py
+++ b/packages/leann-backend-hnsw/leann_backend_hnsw/hnsw_backend.py
@@ -1,20 +1,21 @@
-import numpy as np
+import logging
 import os
 from pathlib import Path
 from typing import Dict, Any, List, Literal
 import pickle
 import shutil
-import time
+from pathlib import Path
 from typing import Any, Literal
-from leann.searcher_base import BaseSearcher
+import numpy as np
 from .convert_to_csr import convert_hnsw_graph_to_csr
 from leann.registry import register_backend
 from leann.interface import (
    LeannBackendFactoryInterface,
    LeannBackendBuilderInterface,
    LeannBackendFactoryInterface,
    LeannBackendSearcherInterface,
 )
 from leann.registry import register_backend
 from leann.searcher_base import BaseSearcher
 from .convert_to_csr import convert_hnsw_graph_to_csr
 logger = logging.getLogger(__name__)
 def get_metric_map():
@@ -27,6 +28,12 @@ def get_metric_map():
    }
 def normalize_l2(data: np.ndarray) -> np.ndarray:
    norms = np.linalg.norm(data, axis=1, keepdims=True)
    norms[norms == 0] = 1  # Avoid division by zero
    return data / norms
@register_backend("hnsw")
 class HNSWBackend(LeannBackendFactoryInterface):
    @staticmethod
@@ -47,8 +54,14 @@ class HNSWBuilder(LeannBackendBuilderInterface):
        self.efConstruction = self.build_params.setdefault("efConstruction", 200)
        self.distance_metric = self.build_params.setdefault("distance_metric", "mips")
        self.dimensions = self.build_params.get("dimensions")
        if not self.is_recompute:
            if self.is_compact:
                # TODO: support this case @andy
                raise ValueError(
                    "is_recompute is False, but is_compact is True. This is not compatible now. change is compact to False and you can use the original HNSW index."
                )
-    def build(self, data: np.ndarray, ids: List[str], index_path: str, **kwargs):
+    def build(self, data: np.ndarray, ids: list[str], index_path: str, **kwargs):
        from . import faiss  # type: ignore
        path = Path(index_path)
@@ -57,13 +70,9 @@ class HNSWBuilder(LeannBackendBuilderInterface):
        index_dir.mkdir(parents=True, exist_ok=True)
        if data.dtype != np.float32:
            logger.warning(f"Converting data to float32, shape: {data.shape}")
            data = data.astype(np.float32)
        label_map = {i: str_id for i, str_id in enumerate(ids)}
        label_map_file = index_dir / "leann.labels.map"
        with open(label_map_file, "wb") as f:
            pickle.dump(label_map, f)
        metric_enum = get_metric_map().get(self.distance_metric.lower())
        if metric_enum is None:
            raise ValueError(f"Unsupported distance_metric '{self.distance_metric}'.")
@@ -73,7 +82,7 @@ class HNSWBuilder(LeannBackendBuilderInterface):
        index.hnsw.efConstruction = self.efConstruction
        if self.distance_metric.lower() == "cosine":
-            faiss.normalize_L2(data)
+            data = normalize_l2(data)
        index.add(data.shape[0], faiss.swig_ptr(data))
        index_file = index_dir / f"{index_prefix}.index"
@@ -85,7 +94,7 @@ class HNSWBuilder(LeannBackendBuilderInterface):
    def _convert_to_csr(self, index_file: Path):
        """Convert built index to CSR format"""
        mode_str = "CSR-pruned" if self.is_recompute else "CSR-standard"
-        print(f"INFO: Converting HNSW index to {mode_str} format...")
+        logger.info(f"INFO: Converting HNSW index to {mode_str} format...")
        csr_temp_file = index_file.with_suffix(".csr.tmp")
@@ -94,20 +103,16 @@ class HNSWBuilder(LeannBackendBuilderInterface):
        )
        if success:
-            print("✅ CSR conversion successful.")
+            logger.info("✅ CSR conversion successful.")
-            index_file_old = index_file.with_suffix(".old")
+            # index_file_old = index_file.with_suffix(".old")
-            shutil.move(str(index_file), str(index_file_old))
+            # shutil.move(str(index_file), str(index_file_old))
            shutil.move(str(csr_temp_file), str(index_file))
-            print(
+            logger.info(f"INFO: Replaced original index with {mode_str} version at '{index_file}'")
                f"INFO: Replaced original index with {mode_str} version at '{index_file}'"
            )
        else:
            # Clean up and fail fast
            if csr_temp_file.exists():
                os.remove(csr_temp_file)
-            raise RuntimeError(
+            raise RuntimeError("CSR conversion failed - cannot proceed with compact format")
                "CSR conversion failed - cannot proceed with compact format"
            )
 class HNSWSearcher(BaseSearcher):
@@ -119,7 +124,9 @@ class HNSWSearcher(BaseSearcher):
        )
        from . import faiss  # type: ignore
-        self.distance_metric = self.meta.get("distance_metric", "mips").lower()
+        self.distance_metric = (
            self.meta.get("backend_kwargs", {}).get("distance_metric", "mips").lower()
        )
        metric_enum = get_metric_map().get(self.distance_metric)
        if metric_enum is None:
            raise ValueError(f"Unsupported distance_metric '{self.distance_metric}'.")
@@ -135,34 +142,25 @@ class HNSWSearcher(BaseSearcher):
        hnsw_config = faiss.HNSWIndexConfig()
        hnsw_config.is_compact = self.is_compact
-        hnsw_config.is_recompute = self.is_pruned or kwargs.get("is_recompute", False)
+        hnsw_config.is_recompute = (
-
+            self.is_pruned
-        if self.is_pruned and not hnsw_config.is_recompute:
+        )  # In C++ code, it's called is_recompute, but it's only for loading IIUC.
            raise RuntimeError("Index is pruned but recompute is disabled.")
        self._index = faiss.read_index(str(index_file), faiss.IO_FLAG_MMAP, hnsw_config)
        # Load label mapping
        label_map_file = self.index_dir / "leann.labels.map"
        if not label_map_file.exists():
            raise FileNotFoundError(f"Label map file not found at {label_map_file}")
        with open(label_map_file, "rb") as f:
            self.label_map = pickle.load(f)
    def search(
        self,
        query: np.ndarray,
        top_k: int,
        zmq_port: int | None = None,
        complexity: int = 64,
        beam_width: int = 1,
        prune_ratio: float = 0.0,
-        recompute_embeddings: bool = False,
+        recompute_embeddings: bool = True,
        pruning_strategy: Literal["global", "local", "proportional"] = "global",
        zmq_port: int = 5557,
        batch_size: int = 0,
        **kwargs,
-    ) -> Dict[str, Any]:
+    ) -> dict[str, Any]:
        """
        Search for nearest neighbors using HNSW index.
@@ -177,7 +175,7 @@ class HNSWSearcher(BaseSearcher):
                - "global": Use global PQ queue size for selection (default)
                - "local": Local pruning, sort and select best candidates
                - "proportional": Base selection on new neighbor count ratio
-            zmq_port: ZMQ port for embedding server
+            zmq_port: ZMQ port for embedding server communication. Must be provided if recompute_embeddings is True.
            batch_size: Neighbor processing batch size, 0=disabled (HNSW-specific)
            **kwargs: Additional HNSW-specific parameters (for legacy compatibility)
@@ -186,26 +184,34 @@ class HNSWSearcher(BaseSearcher):
        """
        from . import faiss  # type: ignore
-        # Use recompute_embeddings parameter
+        if not recompute_embeddings:
-        use_recompute = recompute_embeddings or self.is_pruned
+            if self.is_pruned:
-        if use_recompute:
+                raise RuntimeError("Recompute is required for pruned index.")
-            meta_file_path = self.index_dir / f"{self.index_path.name}.meta.json"
+        if recompute_embeddings:
-            if not meta_file_path.exists():
+            if zmq_port is None:
-                raise RuntimeError(
+                raise ValueError("zmq_port must be provided if recompute_embeddings is True")
                    f"FATAL: Recompute enabled but metadata file not found: {meta_file_path}"
                )
            self._ensure_server_running(str(meta_file_path), port=zmq_port, **kwargs)
        if query.dtype != np.float32:
            query = query.astype(np.float32)
        if self.distance_metric == "cosine":
-            faiss.normalize_L2(query)
+            query = normalize_l2(query)
        params = faiss.SearchParametersHNSW()
-        params.zmq_port = zmq_port
+        if zmq_port is not None:
            params.zmq_port = zmq_port  # C++ code won't use this if recompute_embeddings is False
        params.efSearch = complexity
        params.beam_size = beam_width
        # For OpenAI embeddings with cosine distance, disable relative distance check
        # This prevents early termination when all scores are in a narrow range
        embedding_model = self.meta.get("embedding_model", "").lower()
        if self.distance_metric == "cosine" and any(
            openai_model in embedding_model for openai_model in ["text-embedding", "openai"]
        ):
            params.check_relative_distance = False
        else:
            params.check_relative_distance = True
        # PQ pruning: direct mapping to HNSW's pq_pruning_ratio
        params.pq_pruning_ratio = prune_ratio
@@ -215,9 +221,7 @@ class HNSWSearcher(BaseSearcher):
            params.send_neigh_times_ratio = 0.0
        elif pruning_strategy == "proportional":
            params.local_prune = False
-            params.send_neigh_times_ratio = (
+            params.send_neigh_times_ratio = 1.0  # Any value > 1e-6 triggers proportional mode
                1.0  # Any value > 1e-6 triggers proportional mode
            )
        else:  # "global"
            params.local_prune = False
            params.send_neigh_times_ratio = 0.0
@@ -238,12 +242,6 @@ class HNSWSearcher(BaseSearcher):
            params,
        )
-        string_labels = [
+        string_labels = [[str(int_label) for int_label in batch_labels] for batch_labels in labels]
            [
                self.label_map.get(int_label, f"unknown_{int_label}")
                for int_label in batch_labels
            ]
            for batch_labels in labels
        ]
        return {"labels": string_labels, "distances": distances}
--- a/packages/leann-backend-hnsw/leann_backend_hnsw/hnsw_embedding_server.py
+++ b/packages/leann-backend-hnsw/leann_backend_hnsw/hnsw_embedding_server.py
--- a/packages/leann-backend-hnsw/pyproject.toml
+++ b/packages/leann-backend-hnsw/pyproject.toml
@@ -6,9 +6,14 @@ build-backend = "scikit_build_core.build"
 [project]
 name = "leann-backend-hnsw"
-version = "0.1.0"
+version = "0.2.6"
 description = "Custom-built HNSW (Faiss) backend for the Leann toolkit."
-dependencies = ["leann-core==0.1.0", "numpy"]
+dependencies = [
    "leann-core==0.2.6",
    "numpy",
    "pyzmq>=23.0.0",
    "msgpack>=1.0.0",
 ]
 [tool.scikit-build]
 wheel.packages = ["leann_backend_hnsw"]
@@ -16,3 +21,7 @@ editable.mode = "redirect"
 cmake.build-type = "Release"
 build.verbose = true
 build.tool-args = ["-j8"]
 # CMake definitions to optimize compilation
 [tool.scikit-build.cmake.define]
 CMAKE_BUILD_PARALLEL_LEVEL = "8"
--- a/packages/leann-backend-hnsw/third_party/faiss
+++ b/packages/leann-backend-hnsw/third_party/faiss
--- a/packages/leann-backend-hnsw/third_party/msgpack-c
+++ b/packages/leann-backend-hnsw/third_party/msgpack-c
--- a/packages/leann-core/pyproject.toml
+++ b/packages/leann-core/pyproject.toml
@@ -4,16 +4,49 @@ build-backend = "setuptools.build_meta"
 [project]
 name = "leann-core"
-version = "0.1.0"
+version = "0.2.6"
-description = "Core API and plugin system for Leann."
+description = "Core API and plugin system for LEANN"
 readme = "README.md"
 requires-python = ">=3.9"
 license = { text = "MIT" }
 # All required dependencies included
 dependencies = [
    "numpy>=1.20.0",
-    "tqdm>=4.60.0"
+    "tqdm>=4.60.0",
    "psutil>=5.8.0",
    "pyzmq>=23.0.0",
    "msgpack>=1.0.0",
    "torch>=2.0.0",
    "sentence-transformers>=2.2.0",
    "llama-index-core>=0.12.0",
    "llama-index-readers-file>=0.4.0",  # Essential for document reading
    "llama-index-embeddings-huggingface>=0.5.5",  # For embeddings
    "python-dotenv>=1.0.0",
    "openai>=1.0.0",
    "huggingface-hub>=0.20.0",
    "transformers>=4.30.0",
    "requests>=2.25.0",
    "accelerate>=0.20.0",
    "PyPDF2>=3.0.0",
    "pymupdf>=1.23.0",
    "pdfplumber>=0.10.0",
    "nbconvert>=7.0.0",  # For .ipynb file support
    "gitignore-parser>=0.1.12",  # For proper .gitignore handling
    "mlx>=0.26.3; sys_platform == 'darwin'",
    "mlx-lm>=0.26.0; sys_platform == 'darwin'",
 ]
 [project.optional-dependencies]
 colab = [
    "torch>=2.0.0,<3.0.0",  # Limit torch version to avoid conflicts
    "transformers>=4.30.0,<5.0.0",  # Limit transformers version
    "accelerate>=0.20.0,<1.0.0",  # Limit accelerate version
 ]
 [project.scripts]
 leann = "leann.cli:main"
 leann_mcp = "leann.mcp:main"
 [tool.setuptools.packages.find]
 where = ["src"]
--- a/packages/leann-core/src/leann/init.py
+++ b/packages/leann-core/src/leann/init.py
@@ -8,10 +8,14 @@ if platform.system() == "Darwin":
    os.environ["MKL_NUM_THREADS"] = "1"
    os.environ["KMP_DUPLICATE_LIB_OK"] = "TRUE"
    os.environ["KMP_BLOCKTIME"] = "0"
    # Additional fixes for PyTorch/sentence-transformers on macOS ARM64 only in CI
    if os.environ.get("CI") == "true":
        os.environ["PYTORCH_ENABLE_MPS_FALLBACK"] = "0"
        os.environ["TOKENIZERS_PARALLELISM"] = "false"
 from .api import LeannBuilder, LeannChat, LeannSearcher
 from .registry import BACKEND_REGISTRY, autodiscover_backends
 autodiscover_backends()
-__all__ = ["LeannBuilder", "LeannSearcher", "LeannChat", "BACKEND_REGISTRY"]
+__all__ = ["BACKEND_REGISTRY", "LeannBuilder", "LeannChat", "LeannSearcher"]
--- a/packages/leann-core/src/leann/api.py
+++ b/packages/leann-core/src/leann/api.py
@@ -4,25 +4,37 @@ with the correct, original embedding logic from the user's reference code.
 """
 import json
 import logging
 import pickle
-import numpy as np
+import time
-from pathlib import Path
+import warnings
 from typing import List, Dict, Any, Optional, Literal
 from dataclasses import dataclass, field
-import uuid
+from pathlib import Path
-import torch
+from typing import Any, Literal
 import numpy as np
 from leann.interface import LeannBackendSearcherInterface
 from .registry import BACKEND_REGISTRY
 from .interface import LeannBackendFactoryInterface
 from .chat import get_llm
 from .interface import LeannBackendFactoryInterface
 from .registry import BACKEND_REGISTRY
 logger = logging.getLogger(__name__)
 def get_registered_backends() -> list[str]:
    """Get list of registered backend names."""
    return list(BACKEND_REGISTRY.keys())
 def compute_embeddings(
-    chunks: List[str],
+    chunks: list[str],
    model_name: str,
    mode: str = "sentence-transformers",
    use_server: bool = True,
-    use_mlx: bool = False  # Backward compatibility: if True, override mode to 'mlx',
+    port: int | None = None,
    is_build=False,
 ) -> np.ndarray:
    """
    Computes embeddings using different backends.
@@ -39,286 +51,102 @@ def compute_embeddings(
    Returns:
        numpy array of embeddings
    """
-    # Override mode for backward compatibility
+    if use_server:
-    if use_mlx:
+        # Use embedding server (for search/query)
-        mode = "mlx"
+        if port is None:
-
+            raise ValueError("port is required when use_server is True")
-    # Auto-detect mode based on model name if not explicitly set
+        return compute_embeddings_via_server(chunks, model_name, port=port)
    if mode == "sentence-transformers" and model_name.startswith("text-embedding-"):
        mode = "openai"
    if mode == "mlx":
        return compute_embeddings_mlx(chunks, model_name, batch_size=16)
    elif mode == "openai":
        return compute_embeddings_openai(chunks, model_name)
    elif mode == "sentence-transformers":
        return compute_embeddings_sentence_transformers(
            chunks, model_name, use_server=use_server
        )
    else:
-        raise ValueError(
+        # Use direct computation (for build_index)
-            f"Unsupported embedding mode: {mode}. Supported modes: sentence-transformers, mlx, openai"
+        from .embedding_compute import (
            compute_embeddings as compute_embeddings_direct,
        )
        return compute_embeddings_direct(
            chunks,
            model_name,
            mode=mode,
            is_build=is_build,
        )
-def compute_embeddings_sentence_transformers(
+def compute_embeddings_via_server(chunks: list[str], model_name: str, port: int) -> np.ndarray:
    chunks: List[str], model_name: str, use_server: bool = True
 ) -> np.ndarray:
    """Computes embeddings using sentence-transformers.
    Args:
        chunks: List of text chunks to embed
        model_name: Name of the sentence transformer model
        use_server: If True, use embedding server (good for search). If False, use direct computation (good for build).
    """
-    if not use_server:
+    logger.info(
-        print(
+        f"Computing embeddings for {len(chunks)} chunks using SentenceTransformer model '{model_name}' (via embedding server)..."
            f"INFO: Computing embeddings for {len(chunks)} chunks using SentenceTransformer model '{model_name}' (direct)..."
        )
        return _compute_embeddings_sentence_transformers_direct(chunks, model_name)
    print(
        f"INFO: Computing embeddings for {len(chunks)} chunks using SentenceTransformer model '{model_name}' (via embedding server)..."
    )
    import msgpack
    import numpy as np
    import zmq
-    # Use embedding server for sentence-transformers too
+    # Connect to embedding server
-    # This avoids loading the model twice (once in API, once in server)
+    context = zmq.Context()
-    try:
+    socket = context.socket(zmq.REQ)
-        # Import ZMQ client functionality and server manager
+    socket.connect(f"tcp://localhost:{port}")
        import zmq
        import msgpack
        import numpy as np
        from .embedding_server_manager import EmbeddingServerManager
-        # Ensure embedding server is running
+    # Send chunks to server for embedding computation
-        port = 5557
+    request = chunks
-        server_manager = EmbeddingServerManager(
+    socket.send(msgpack.packb(request))
            backend_module_name="leann_backend_hnsw.hnsw_embedding_server"
        )
-        server_started = server_manager.start_server(
+    # Receive embeddings from server
-            port=port,
+    response = socket.recv()
-            model_name=model_name,
+    embeddings_list = msgpack.unpackb(response)
            embedding_mode="sentence-transformers",
            enable_warmup=False,
        )
-        if not server_started:
+    # Convert back to numpy array
-            raise RuntimeError(f"Failed to start embedding server on port {port}")
+    embeddings = np.array(embeddings_list, dtype=np.float32)
-        # Connect to embedding server
+    socket.close()
-        context = zmq.Context()
+    context.term()
        socket = context.socket(zmq.REQ)
        socket.connect(f"tcp://localhost:{port}")
        # Send chunks to server for embedding computation
        request = chunks
        socket.send(msgpack.packb(request))
        # Receive embeddings from server
        response = socket.recv()
        embeddings_list = msgpack.unpackb(response)
        # Convert back to numpy array
        embeddings = np.array(embeddings_list, dtype=np.float32)
        socket.close()
        context.term()
        return embeddings
    except Exception as e:
        # Fallback to direct sentence-transformers if server connection fails
        print(
            f"Warning: Failed to connect to embedding server, falling back to direct computation: {e}"
        )
        return _compute_embeddings_sentence_transformers_direct(chunks, model_name)
 def _compute_embeddings_sentence_transformers_direct(
    chunks: List[str], model_name: str
 ) -> np.ndarray:
    """Direct sentence-transformers computation (fallback)."""
    try:
        from sentence_transformers import SentenceTransformer
    except ImportError as e:
        raise RuntimeError(
            "sentence-transformers not available. Install with: uv pip install sentence-transformers"
        ) from e
    # Load model using sentence-transformers
    model = SentenceTransformer(model_name)
    model = model.half()
    print(
        f"INFO: Computing embeddings for {len(chunks)} chunks using SentenceTransformer model '{model_name}' (direct)..."
    )
    # use acclerater GPU or MAC GPU
    if torch.cuda.is_available():
        model = model.to("cuda")
    elif torch.backends.mps.is_available():
        model = model.to("mps")
    # Generate embeddings
    # give use an warning if OOM here means we need to turn down the batch size
    embeddings = model.encode(
        chunks, convert_to_numpy=True, show_progress_bar=True, batch_size=16
    )
    return embeddings
 def compute_embeddings_openai(chunks: List[str], model_name: str) -> np.ndarray:
    """Computes embeddings using OpenAI API."""
    try:
        import openai
        import os
    except ImportError as e:
        raise RuntimeError(
            "openai not available. Install with: uv pip install openai"
        ) from e
    # Get API key from environment
    api_key = os.getenv("OPENAI_API_KEY")
    if not api_key:
        raise RuntimeError("OPENAI_API_KEY environment variable not set")
    client = openai.OpenAI(api_key=api_key)
    print(
        f"INFO: Computing embeddings for {len(chunks)} chunks using OpenAI model '{model_name}'..."
    )
    # OpenAI has a limit on batch size and input length
    max_batch_size = 100  # Conservative batch size
    all_embeddings = []
    try:
        from tqdm import tqdm
        total_batches = (len(chunks) + max_batch_size - 1) // max_batch_size
        batch_range = range(0, len(chunks), max_batch_size)
        batch_iterator = tqdm(batch_range, desc="Computing embeddings", unit="batch", total=total_batches)
    except ImportError:
        # Fallback without progress bar
        batch_iterator = range(0, len(chunks), max_batch_size)
    for i in batch_iterator:
        batch_chunks = chunks[i:i + max_batch_size]
        try:
            response = client.embeddings.create(model=model_name, input=batch_chunks)
            batch_embeddings = [embedding.embedding for embedding in response.data]
            all_embeddings.extend(batch_embeddings)
        except Exception as e:
            print(f"ERROR: Failed to get embeddings for batch starting at {i}: {e}")
            raise
    embeddings = np.array(all_embeddings, dtype=np.float32)
    print(
        f"INFO: Generated {len(embeddings)} embeddings with dimension {embeddings.shape[1]}"
    )
    return embeddings
 def compute_embeddings_mlx(chunks: List[str], model_name: str, batch_size: int = 16) -> np.ndarray:
    """Computes embeddings using an MLX model."""
    try:
        import mlx.core as mx
        from mlx_lm.utils import load
        from tqdm import tqdm
    except ImportError as e:
        raise RuntimeError(
            "MLX or related libraries not available. Install with: uv pip install mlx mlx-lm"
        ) from e
    print(
        f"INFO: Computing embeddings for {len(chunks)} chunks using MLX model '{model_name}' with batch_size={batch_size}..."
    )
    # Load model and tokenizer
    model, tokenizer = load(model_name)
    # Process chunks in batches with progress bar
    all_embeddings = []
    try:
        from tqdm import tqdm
        batch_iterator = tqdm(range(0, len(chunks), batch_size), desc="Computing embeddings", unit="batch")
    except ImportError:
        batch_iterator = range(0, len(chunks), batch_size)
    for i in batch_iterator:
        batch_chunks = chunks[i:i + batch_size]
        # Tokenize all chunks in the batch
        batch_token_ids = []
        for chunk in batch_chunks:
            token_ids = tokenizer.encode(chunk)  # type: ignore
            batch_token_ids.append(token_ids)
        # Pad sequences to the same length for batch processing
        max_length = max(len(ids) for ids in batch_token_ids)
        padded_token_ids = []
        for token_ids in batch_token_ids:
            # Pad with tokenizer.pad_token_id or 0
            padded = token_ids + [0] * (max_length - len(token_ids))
            padded_token_ids.append(padded)
        # Convert to MLX array with batch dimension
        input_ids = mx.array(padded_token_ids)
        # Get embeddings for the batch
        embeddings = model(input_ids)
        # Mean pooling for each sequence in the batch
        pooled = embeddings.mean(axis=1)  # Shape: (batch_size, hidden_size)
        # Convert batch embeddings to numpy
        for j in range(len(batch_chunks)):
            pooled_list = pooled[j].tolist()  # Convert to list
            pooled_numpy = np.array(pooled_list, dtype=np.float32)
            all_embeddings.append(pooled_numpy)
    # Stack numpy arrays
    return np.stack(all_embeddings)
@dataclass
 class SearchResult:
    id: str
    score: float
    text: str
-    metadata: Dict[str, Any] = field(default_factory=dict)
+    metadata: dict[str, Any] = field(default_factory=dict)
 class PassageManager:
-    def __init__(self, passage_sources: List[Dict[str, Any]]):
+    def __init__(self, passage_sources: list[dict[str, Any]]):
        self.offset_maps = {}
        self.passage_files = {}
        self.global_offset_map = {}  # Combined map for fast lookup
        for source in passage_sources:
-            if source["type"] == "jsonl":
+            assert source["type"] == "jsonl", "only jsonl is supported"
-                passage_file = source["path"]
+            passage_file = source["path"]
-                index_file = source["index_path"]
+            index_file = source["index_path"]  # .idx file
                if not Path(index_file).exists():
                    raise FileNotFoundError(
                        f"Passage index file not found: {index_file}"
                    )
                with open(index_file, "rb") as f:
                    offset_map = pickle.load(f)
                    self.offset_maps[passage_file] = offset_map
                    self.passage_files[passage_file] = passage_file
-                    # Build global map for O(1) lookup
+            # Fix path resolution for Colab and other environments
-                    for passage_id, offset in offset_map.items():
+            if not Path(index_file).is_absolute():
-                        self.global_offset_map[passage_id] = (passage_file, offset)
+                # If relative path, try to resolve it properly
                index_file = str(Path(index_file).resolve())
-    def get_passage(self, passage_id: str) -> Dict[str, Any]:
+            if not Path(index_file).exists():
                raise FileNotFoundError(f"Passage index file not found: {index_file}")
            with open(index_file, "rb") as f:
                offset_map = pickle.load(f)
                self.offset_maps[passage_file] = offset_map
                self.passage_files[passage_file] = passage_file
                # Build global map for O(1) lookup
                for passage_id, offset in offset_map.items():
                    self.global_offset_map[passage_id] = (passage_file, offset)
    def get_passage(self, passage_id: str) -> dict[str, Any]:
        if passage_id in self.global_offset_map:
            passage_file, offset = self.global_offset_map[passage_id]
-            with open(passage_file, "r", encoding="utf-8") as f:
+            # Lazy file opening - only open when needed
            with open(passage_file, encoding="utf-8") as f:
                f.seek(offset)
                return json.loads(f.readline())
        raise KeyError(f"Passage ID not found: {passage_id}")
@@ -328,30 +156,96 @@ class LeannBuilder:
    def __init__(
        self,
        backend_name: str,
-        embedding_model: str = "facebook/contriever-msmarco",
+        embedding_model: str = "facebook/contriever",
-        dimensions: Optional[int] = None,
+        dimensions: int | None = None,
        embedding_mode: str = "sentence-transformers",
        **backend_kwargs,
    ):
        self.backend_name = backend_name
-        backend_factory: LeannBackendFactoryInterface | None = BACKEND_REGISTRY.get(
+        backend_factory: LeannBackendFactoryInterface | None = BACKEND_REGISTRY.get(backend_name)
            backend_name
        )
        if backend_factory is None:
            raise ValueError(f"Backend '{backend_name}' not found or not registered.")
        self.backend_factory = backend_factory
        self.embedding_model = embedding_model
        self.dimensions = dimensions
        self.embedding_mode = embedding_mode
        self.backend_kwargs = backend_kwargs
        if 'mlx' in self.embedding_model:
            self.embedding_mode = "mlx"
        self.chunks: List[Dict[str, Any]] = []
-    def add_text(self, text: str, metadata: Optional[Dict[str, Any]] = None):
+        # Check if we need to use cosine distance for normalized embeddings
        normalized_embeddings_models = {
            # OpenAI models
            ("openai", "text-embedding-ada-002"),
            ("openai", "text-embedding-3-small"),
            ("openai", "text-embedding-3-large"),
            # Voyage AI models
            ("voyage", "voyage-2"),
            ("voyage", "voyage-3"),
            ("voyage", "voyage-large-2"),
            ("voyage", "voyage-multilingual-2"),
            ("voyage", "voyage-code-2"),
            # Cohere models
            ("cohere", "embed-english-v3.0"),
            ("cohere", "embed-multilingual-v3.0"),
            ("cohere", "embed-english-light-v3.0"),
            ("cohere", "embed-multilingual-light-v3.0"),
        }
        # Also check for patterns in model names
        is_normalized = False
        current_model_lower = embedding_model.lower()
        current_mode_lower = embedding_mode.lower()
        # Check exact matches
        for mode, model in normalized_embeddings_models:
            if (current_mode_lower == mode and current_model_lower == model) or (
                mode in current_mode_lower and model in current_model_lower
            ):
                is_normalized = True
                break
        # Check patterns
        if not is_normalized:
            # OpenAI patterns
            if "openai" in current_mode_lower or "openai" in current_model_lower:
                if any(
                    pattern in current_model_lower
                    for pattern in ["text-embedding", "ada", "3-small", "3-large"]
                ):
                    is_normalized = True
            # Voyage patterns
            elif "voyage" in current_mode_lower or "voyage" in current_model_lower:
                is_normalized = True
            # Cohere patterns
            elif "cohere" in current_mode_lower or "cohere" in current_model_lower:
                if "embed" in current_model_lower:
                    is_normalized = True
        # Handle distance metric
        if is_normalized and "distance_metric" not in backend_kwargs:
            backend_kwargs["distance_metric"] = "cosine"
            warnings.warn(
                f"Detected normalized embeddings model '{embedding_model}' with mode '{embedding_mode}'. "
                f"Automatically setting distance_metric='cosine' for optimal performance. "
                f"Normalized embeddings (L2 norm = 1) should use cosine similarity instead of MIPS.",
                UserWarning,
                stacklevel=2,
            )
        elif is_normalized and backend_kwargs.get("distance_metric", "").lower() != "cosine":
            current_metric = backend_kwargs.get("distance_metric", "mips")
            warnings.warn(
                f"Warning: Using '{current_metric}' distance metric with normalized embeddings model "
                f"'{embedding_model}' may lead to suboptimal search results. "
                f"Consider using 'cosine' distance metric for better performance.",
                UserWarning,
                stacklevel=2,
            )
        self.backend_kwargs = backend_kwargs
        self.chunks: list[dict[str, Any]] = []
    def add_text(self, text: str, metadata: dict[str, Any] | None = None):
        if metadata is None:
            metadata = {}
-        passage_id = metadata.get("id", str(uuid.uuid4()))
+        passage_id = metadata.get("id", str(len(self.chunks)))
        chunk_data = {"id": passage_id, "text": text, "metadata": metadata}
        self.chunks.append(chunk_data)
@@ -377,6 +271,7 @@ class LeannBuilder:
        with open(passages_file, "w", encoding="utf-8") as f:
            try:
                from tqdm import tqdm
                chunk_iterator = tqdm(self.chunks, desc="Writing passages", unit="chunk")
            except ImportError:
                chunk_iterator = self.chunks
@@ -398,14 +293,16 @@ class LeannBuilder:
            pickle.dump(offset_map, f)
        texts_to_embed = [c["text"] for c in self.chunks]
        embeddings = compute_embeddings(
-            texts_to_embed, self.embedding_model, self.embedding_mode, use_server=False
+            texts_to_embed,
            self.embedding_model,
            self.embedding_mode,
            use_server=False,
            is_build=True,
        )
        string_ids = [chunk["id"] for chunk in self.chunks]
        current_backend_kwargs = {**self.backend_kwargs, "dimensions": self.dimensions}
        builder_instance = self.backend_factory.builder(**current_backend_kwargs)
-        builder_instance.build(
+        builder_instance.build(embeddings, string_ids, index_path, **current_backend_kwargs)
            embeddings, string_ids, index_path, **current_backend_kwargs
        )
        leann_meta_path = index_dir / f"{index_name}.meta.json"
        meta_data = {
            "version": "1.0",
@@ -454,9 +351,7 @@ class LeannBuilder:
        ids, embeddings = data
        if not isinstance(embeddings, np.ndarray):
-            raise ValueError(
+            raise ValueError(f"Expected embeddings to be numpy array, got {type(embeddings)}")
                f"Expected embeddings to be numpy array, got {type(embeddings)}"
            )
        if len(ids) != embeddings.shape[0]:
            raise ValueError(
@@ -468,11 +363,9 @@ class LeannBuilder:
        if self.dimensions is None:
            self.dimensions = embedding_dim
        elif self.dimensions != embedding_dim:
-            raise ValueError(
+            raise ValueError(f"Dimension mismatch: expected {self.dimensions}, got {embedding_dim}")
                f"Dimension mismatch: expected {self.dimensions}, got {embedding_dim}"
            )
-        print(
+        logger.info(
            f"Building index from precomputed embeddings: {len(ids)} items, {embedding_dim} dimensions"
        )
@@ -480,7 +373,7 @@ class LeannBuilder:
        if len(self.chunks) != len(ids):
            # If no text chunks provided, create placeholder text entries
            if not self.chunks:
-                print("No text chunks provided, creating placeholder entries...")
+                logger.info("No text chunks provided, creating placeholder entries...")
                for id_val in ids:
                    self.add_text(
                        f"Document {id_val}",
@@ -555,32 +448,40 @@ class LeannBuilder:
        with open(leann_meta_path, "w", encoding="utf-8") as f:
            json.dump(meta_data, f, indent=2)
-        print(f"Index built successfully from precomputed embeddings: {index_path}")
+        logger.info(f"Index built successfully from precomputed embeddings: {index_path}")
 class LeannSearcher:
    def __init__(self, index_path: str, enable_warmup: bool = False, **backend_kwargs):
-        meta_path_str = f"{index_path}.meta.json"
+        # Fix path resolution for Colab and other environments
-        if not Path(meta_path_str).exists():
+        if not Path(index_path).is_absolute():
-            raise FileNotFoundError(f"Leann metadata file not found at {meta_path_str}")
+            index_path = str(Path(index_path).resolve())
-        with open(meta_path_str, "r", encoding="utf-8") as f:
+
        self.meta_path_str = f"{index_path}.meta.json"
        if not Path(self.meta_path_str).exists():
            parent_dir = Path(index_path).parent
            print(
                f"Leann metadata file not found at {self.meta_path_str}, and you may need to rm -rf {parent_dir}"
            )
            # highlight in red the filenotfound error
            raise FileNotFoundError(
                f"Leann metadata file not found at {self.meta_path_str}, \033[91m you may need to rm -rf {parent_dir}\033[0m"
            )
        with open(self.meta_path_str, encoding="utf-8") as f:
            self.meta_data = json.load(f)
        backend_name = self.meta_data["backend_name"]
        self.embedding_model = self.meta_data["embedding_model"]
        # Support both old and new format
-        self.embedding_mode = self.meta_data.get(
+        self.embedding_mode = self.meta_data.get("embedding_mode", "sentence-transformers")
            "embedding_mode", "sentence-transformers"
        )
        # Backward compatibility with use_mlx
        if self.meta_data.get("use_mlx", False):
            self.embedding_mode = "mlx"
        self.passage_manager = PassageManager(self.meta_data.get("passage_sources", []))
        backend_factory = BACKEND_REGISTRY.get(backend_name)
        if backend_factory is None:
            raise ValueError(f"Backend '{backend_name}' not found.")
        final_kwargs = {**self.meta_data.get("backend_kwargs", {}), **backend_kwargs}
        final_kwargs["enable_warmup"] = enable_warmup
-        self.backend_impl = backend_factory.searcher(index_path, **final_kwargs)
+        self.backend_impl: LeannBackendSearcherInterface = backend_factory.searcher(
            index_path, **final_kwargs
        )
    def search(
        self,
@@ -589,26 +490,49 @@ class LeannSearcher:
        complexity: int = 64,
        beam_width: int = 1,
        prune_ratio: float = 0.0,
-        recompute_embeddings: bool = False,
+        recompute_embeddings: bool = True,
        pruning_strategy: Literal["global", "local", "proportional"] = "global",
-        zmq_port: int = 5557,
+        expected_zmq_port: int = 5557,
        **kwargs,
-    ) -> List[SearchResult]:
+    ) -> list[SearchResult]:
-        print("🔍 DEBUG LeannSearcher.search() called:")
+        logger.info("🔍 LeannSearcher.search() called:")
-        print(f"  Query: '{query}'")
+        logger.info(f"  Query: '{query}'")
-        print(f"  Top_k: {top_k}")
+        logger.info(f"  Top_k: {top_k}")
-        print(f"  Additional kwargs: {kwargs}")
+        logger.info(f"  Additional kwargs: {kwargs}")
-        # Use backend's compute_query_embedding method
+        # Smart top_k detection and adjustment
-        # This will automatically use embedding server if available and needed
+        total_docs = len(self.passage_manager.global_offset_map)
-        import time
+        original_top_k = top_k
        if top_k > total_docs:
            top_k = total_docs
            logger.warning(
                f"  ⚠️  Requested top_k ({original_top_k}) exceeds total documents ({total_docs})"
            )
            logger.warning(f"  ✅ Auto-adjusted top_k to {top_k} to match available documents")
        zmq_port = None
        start_time = time.time()
        if recompute_embeddings:
            zmq_port = self.backend_impl._ensure_server_running(
                self.meta_path_str,
                port=expected_zmq_port,
                **kwargs,
            )
            del expected_zmq_port
        zmq_time = time.time() - start_time
        logger.info(f"  Launching server time: {zmq_time} seconds")
        start_time = time.time()
-        query_embedding = self.backend_impl.compute_query_embedding(query, zmq_port)
+        query_embedding = self.backend_impl.compute_query_embedding(
-        print(f"  Generated embedding shape: {query_embedding.shape}")
+            query,
-        embedding_time = time.time() - start_time
+            use_server_if_available=recompute_embeddings,
-        print(f"  Embedding time: {embedding_time} seconds")
+            zmq_port=zmq_port,
        )
        # logger.info(f"  Generated embedding shape: {query_embedding.shape}")
        time.time() - start_time
        # logger.info(f"  Embedding time: {embedding_time} seconds")
        start_time = time.time()
        results = self.backend_impl.search(
@@ -622,17 +546,15 @@ class LeannSearcher:
            zmq_port=zmq_port,
            **kwargs,
        )
-        search_time = time.time() - start_time
+        time.time() - start_time
-        print(f"  Search time: {search_time} seconds")
+        # logger.info(f"  Search time: {search_time} seconds")
-        print(
+        logger.info(f"  Backend returned: labels={len(results.get('labels', [[]])[0])} results")
            f"  Backend returned: labels={len(results.get('labels', [[]])[0])} results"
        )
        enriched_results = []
        if "labels" in results and "distances" in results:
-            print(f"  Processing {len(results['labels'][0])} passage IDs:")
+            logger.info(f"  Processing {len(results['labels'][0])} passage IDs:")
            for i, (string_id, dist) in enumerate(
-                zip(results["labels"][0], results["distances"][0])
+                zip(results["labels"][0], results["distances"][0], strict=False)
            ):
                try:
                    passage_data = self.passage_manager.get_passage(string_id)
@@ -644,15 +566,25 @@ class LeannSearcher:
                            metadata=passage_data.get("metadata", {}),
                        )
                    )
-                    print(
+
-                        f"    {i + 1}. passage_id='{string_id}' -> SUCCESS: {passage_data['text']}..."
+                    # Color codes for better logging
                    GREEN = "\033[92m"
                    BLUE = "\033[94m"
                    YELLOW = "\033[93m"
                    RESET = "\033[0m"
                    # Truncate text for display (first 100 chars)
                    display_text = passage_data["text"]
                    logger.info(
                        f"   {GREEN}✓{RESET} {BLUE}[{i + 1:2d}]{RESET} {YELLOW}ID:{RESET} '{string_id}' {YELLOW}Score:{RESET} {dist:.4f} {YELLOW}Text:{RESET} {display_text}"
                    )
                except KeyError:
-                    print(
+                    RED = "\033[91m"
-                        f"    {i + 1}. passage_id='{string_id}' -> ERROR: Passage not found in PassageManager!"
+                    logger.error(
                        f"   {RED}✗{RESET} [{i + 1:2d}] ID: '{string_id}' -> {RED}ERROR: Passage not found!{RESET}"
                    )
-        print(f"  Final enriched results: {len(enriched_results)} passages")
+        logger.info(f"  {GREEN}✓ Final enriched results: {len(enriched_results)} passages{RESET}")
        return enriched_results
@@ -660,7 +592,7 @@ class LeannChat:
    def __init__(
        self,
        index_path: str,
-        llm_config: Optional[Dict[str, Any]] = None,
+        llm_config: dict[str, Any] | None = None,
        enable_warmup: bool = False,
        **kwargs,
    ):
@@ -674,15 +606,15 @@ class LeannChat:
        complexity: int = 64,
        beam_width: int = 1,
        prune_ratio: float = 0.0,
-        recompute_embeddings: bool = False,
+        recompute_embeddings: bool = True,
        pruning_strategy: Literal["global", "local", "proportional"] = "global",
-        zmq_port: int = 5557,
+        llm_kwargs: dict[str, Any] | None = None,
-        llm_kwargs: Optional[Dict[str, Any]] = None,
+        expected_zmq_port: int = 5557,
        **search_kwargs,
    ):
        if llm_kwargs is None:
            llm_kwargs = {}
-
+        search_time = time.time()
        results = self.searcher.search(
            question,
            top_k=top_k,
@@ -691,9 +623,11 @@ class LeannChat:
            prune_ratio=prune_ratio,
            recompute_embeddings=recompute_embeddings,
            pruning_strategy=pruning_strategy,
-            zmq_port=zmq_port,
+            expected_zmq_port=expected_zmq_port,
            **search_kwargs,
        )
        search_time = time.time() - search_time
        # logger.info(f"  Search time: {search_time} seconds")
        context = "\n\n".join([r.text for r in results])
        prompt = (
            "Here is some retrieved context that might help answer your question:\n\n"
@@ -702,7 +636,10 @@ class LeannChat:
            "Please provide the best answer you can based on this context and your knowledge."
        )
        ask_time = time.time()
        ans = self.llm.ask(prompt, **llm_kwargs)
        ask_time = time.time() - ask_time
        logger.info(f"  Ask time: {ask_time} seconds")
        return ans
    def start_interactive(self):
--- a/packages/leann-core/src/leann/chat.py
+++ b/packages/leann-core/src/leann/chat.py
@@ -4,22 +4,25 @@ This file contains the chat generation logic for the LEANN project,
 supporting different backends like Ollama, Hugging Face Transformers, and a simulation mode.
 """
-from abc import ABC, abstractmethod
+import difflib
 from typing import Dict, Any, Optional, List
 import logging
 import os
-import difflib
+from abc import ABC, abstractmethod
 from typing import Any
 import torch
 # Configure logging
 logging.basicConfig(level=logging.INFO)
 logger = logging.getLogger(__name__)
-def check_ollama_models() -> List[str]:
+def check_ollama_models(host: str) -> list[str]:
    """Check available Ollama models and return a list"""
    try:
        import requests
-        response = requests.get("http://localhost:11434/api/tags", timeout=5)
+
        response = requests.get(f"{host}/api/tags", timeout=5)
        if response.status_code == 200:
            data = response.json()
            return [model["name"] for model in data.get("models", [])]
@@ -28,7 +31,70 @@ def check_ollama_models() -> List[str]:
        return []
-def search_ollama_models_fuzzy(query: str, available_models: List[str]) -> List[str]:
+def check_ollama_model_exists_remotely(model_name: str) -> tuple[bool, list[str]]:
    """Check if a model exists in Ollama's remote library and return available tags
    Returns:
        (model_exists, available_tags): bool and list of matching tags
    """
    try:
        import re
        import requests
        # Split model name and tag
        if ":" in model_name:
            base_model, requested_tag = model_name.split(":", 1)
        else:
            base_model, requested_tag = model_name, None
        # First check if base model exists in library
        library_response = requests.get("https://ollama.com/library", timeout=8)
        if library_response.status_code != 200:
            return True, []  # Assume exists if can't check
        # Extract model names from library page
        models_in_library = re.findall(r'href="/library/([^"]+)"', library_response.text)
        if base_model not in models_in_library:
            return False, []  # Base model doesn't exist
        # If base model exists, get available tags
        tags_response = requests.get(f"https://ollama.com/library/{base_model}/tags", timeout=8)
        if tags_response.status_code != 200:
            return True, []  # Base model exists but can't get tags
        # Extract tags for this model - be more specific to avoid HTML artifacts
        tag_pattern = rf"{re.escape(base_model)}:[a-zA-Z0-9\.\-_]+"
        raw_tags = re.findall(tag_pattern, tags_response.text)
        # Clean up tags - remove HTML artifacts and duplicates
        available_tags = []
        seen = set()
        for tag in raw_tags:
            # Skip if it looks like HTML (contains < or >)
            if "<" in tag or ">" in tag:
                continue
            if tag not in seen:
                seen.add(tag)
                available_tags.append(tag)
        # Check if exact model exists
        if requested_tag is None:
            # User just requested base model, suggest tags
            return True, available_tags[:10]  # Return up to 10 tags
        else:
            exact_match = model_name in available_tags
            return exact_match, available_tags[:10]
    except Exception:
        pass
    # If scraping fails, assume model might exist (don't block user)
    return True, []
 def search_ollama_models_fuzzy(query: str, available_models: list[str]) -> list[str]:
    """Use intelligent fuzzy search for Ollama models"""
    if not available_models:
        return []
@@ -41,7 +107,9 @@ def search_ollama_models_fuzzy(query: str, available_models: List[str]) -> List[
    suggestions.extend(exact_matches)
    # 2. Starts with query
-    starts_with = [m for m in available_models if m.lower().startswith(query_lower) and m not in suggestions]
+    starts_with = [
        m for m in available_models if m.lower().startswith(query_lower) and m not in suggestions
    ]
    suggestions.extend(starts_with)
    # 3. Contains query
@@ -51,24 +119,25 @@ def search_ollama_models_fuzzy(query: str, available_models: List[str]) -> List[
    # 4. Base model name matching (remove version numbers)
    def get_base_name(model_name: str) -> str:
        """Extract base name without version (e.g., 'llama3:8b' -> 'llama3')"""
-        return model_name.split(':')[0].split('-')[0]
+        return model_name.split(":")[0].split("-")[0]
    query_base = get_base_name(query_lower)
    base_matches = [
-        m for m in available_models 
+        m
        for m in available_models
        if get_base_name(m.lower()) == query_base and m not in suggestions
    ]
    suggestions.extend(base_matches)
    # 5. Family/variant matching
    model_families = {
-        'llama': ['llama2', 'llama3', 'alpaca', 'vicuna', 'codellama'],
+        "llama": ["llama2", "llama3", "alpaca", "vicuna", "codellama"],
-        'qwen': ['qwen', 'qwen2', 'qwen3'],
+        "qwen": ["qwen", "qwen2", "qwen3"],
-        'gemma': ['gemma', 'gemma2'],
+        "gemma": ["gemma", "gemma2"],
-        'phi': ['phi', 'phi2', 'phi3'],
+        "phi": ["phi", "phi2", "phi3"],
-        'mistral': ['mistral', 'mixtral', 'openhermes'],
+        "mistral": ["mistral", "mixtral", "openhermes"],
-        'dolphin': ['dolphin', 'openchat'],
+        "dolphin": ["dolphin", "openchat"],
-        'deepseek': ['deepseek', 'deepseek-coder']
+        "deepseek": ["deepseek", "deepseek-coder"],
    }
    query_family = None
@@ -80,7 +149,8 @@ def search_ollama_models_fuzzy(query: str, available_models: List[str]) -> List[
    if query_family:
        family_variants = model_families[query_family]
        family_matches = [
-            m for m in available_models
+            m
            for m in available_models
            if any(variant in m.lower() for variant in family_variants) and m not in suggestions
        ]
        suggestions.extend(family_matches)
@@ -99,15 +169,13 @@ def search_ollama_models_fuzzy(query: str, available_models: List[str]) -> List[
 # Remove this too - no need for fallback
-def suggest_similar_models(invalid_model: str, available_models: List[str]) -> List[str]:
+def suggest_similar_models(invalid_model: str, available_models: list[str]) -> list[str]:
    """Use difflib to find similar model names"""
    if not available_models:
        return []
    # Get close matches using fuzzy matching
-    suggestions = difflib.get_close_matches(
+    suggestions = difflib.get_close_matches(invalid_model, available_models, n=3, cutoff=0.3)
        invalid_model, available_models, n=3, cutoff=0.3
    )
    return suggestions
@@ -115,13 +183,14 @@ def check_hf_model_exists(model_name: str) -> bool:
    """Quick check if HuggingFace model exists without downloading"""
    try:
        from huggingface_hub import model_info
        model_info(model_name)
        return True
    except Exception:
        return False
-def get_popular_hf_models() -> List[str]:
+def get_popular_hf_models() -> list[str]:
    """Return a list of popular HuggingFace models for suggestions"""
    try:
        from huggingface_hub import list_models
@@ -131,15 +200,15 @@ def get_popular_hf_models() -> List[str]:
            filter="text-generation",
            sort="downloads",
            direction=-1,
-            limit=20  # Get top 20 most downloaded
+            limit=20,  # Get top 20 most downloaded
        )
        # Extract model names and filter for chat/conversation models
        model_names = []
-        chat_keywords = ['chat', 'instruct', 'dialog', 'conversation', 'assistant']
+        chat_keywords = ["chat", "instruct", "dialog", "conversation", "assistant"]
        for model in models:
-            model_name = model.id if hasattr(model, 'id') else str(model)
+            model_name = model.id if hasattr(model, "id") else str(model)
            # Prioritize models with chat-related keywords
            if any(keyword in model_name.lower() for keyword in chat_keywords):
                model_names.append(model_name)
@@ -153,7 +222,7 @@ def get_popular_hf_models() -> List[str]:
        return _get_fallback_hf_models()
-def _get_fallback_hf_models() -> List[str]:
+def _get_fallback_hf_models() -> list[str]:
    """Fallback list of popular HuggingFace models"""
    return [
        "microsoft/DialoGPT-medium",
@@ -165,11 +234,11 @@ def _get_fallback_hf_models() -> List[str]:
        "facebook/blenderbot_small-90M",
        "microsoft/phi-1_5",
        "facebook/opt-350m",
-        "EleutherAI/gpt-neo-1.3B"
+        "EleutherAI/gpt-neo-1.3B",
    ]
-def search_hf_models_fuzzy(query: str, limit: int = 10) -> List[str]:
+def search_hf_models_fuzzy(query: str, limit: int = 10) -> list[str]:
    """Use HuggingFace Hub's native fuzzy search for model suggestions"""
    try:
        from huggingface_hub import list_models
@@ -180,10 +249,10 @@ def search_hf_models_fuzzy(query: str, limit: int = 10) -> List[str]:
            filter="text-generation",
            sort="downloads",
            direction=-1,
-            limit=limit
+            limit=limit,
        )
-        model_names = [model.id if hasattr(model, 'id') else str(model) for model in models]
+        model_names = [model.id if hasattr(model, "id") else str(model) for model in models]
        # If direct search doesn't return enough results, try some variations
        if len(model_names) < 3:
@@ -191,17 +260,17 @@ def search_hf_models_fuzzy(query: str, limit: int = 10) -> List[str]:
            variations = []
            # Extract base name (e.g., "gpt3" from "gpt-3.5")
-            base_query = query.lower().replace('-', '').replace('.', '').replace('_', '')
+            base_query = query.lower().replace("-", "").replace(".", "").replace("_", "")
            if base_query != query.lower():
                variations.append(base_query)
            # Try common model name patterns
-            if 'gpt' in query.lower():
+            if "gpt" in query.lower():
-                variations.extend(['gpt2', 'gpt-neo', 'gpt-j', 'dialoGPT'])
+                variations.extend(["gpt2", "gpt-neo", "gpt-j", "dialoGPT"])
-            elif 'llama' in query.lower():
+            elif "llama" in query.lower():
-                variations.extend(['llama2', 'alpaca', 'vicuna'])
+                variations.extend(["llama2", "alpaca", "vicuna"])
-            elif 'bert' in query.lower():
+            elif "bert" in query.lower():
-                variations.extend(['roberta', 'distilbert', 'albert'])
+                variations.extend(["roberta", "distilbert", "albert"])
            # Search with variations
            for var in variations[:2]:  # Limit to 2 variations to avoid too many API calls
@@ -211,11 +280,13 @@ def search_hf_models_fuzzy(query: str, limit: int = 10) -> List[str]:
                        filter="text-generation",
                        sort="downloads",
                        direction=-1,
-                        limit=3
+                        limit=3,
                    )
-                    var_names = [model.id if hasattr(model, 'id') else str(model) for model in var_models]
+                    var_names = [
                        model.id if hasattr(model, "id") else str(model) for model in var_models
                    ]
                    model_names.extend(var_names)
-                except:
+                except Exception:
                    continue
        # Remove duplicates while preserving order
@@ -233,34 +304,86 @@ def search_hf_models_fuzzy(query: str, limit: int = 10) -> List[str]:
        return []
-def search_hf_models(query: str, limit: int = 10) -> List[str]:
+def search_hf_models(query: str, limit: int = 10) -> list[str]:
    """Simple search for HuggingFace models based on query (kept for backward compatibility)"""
    return search_hf_models_fuzzy(query, limit)
-def validate_model_and_suggest(model_name: str, llm_type: str) -> Optional[str]:
+def validate_model_and_suggest(
    model_name: str, llm_type: str, host: str = "http://localhost:11434"
 ) -> str | None:
    """Validate model name and provide suggestions if invalid"""
    if llm_type == "ollama":
-        available_models = check_ollama_models()
+        available_models = check_ollama_models(host)
        if available_models and model_name not in available_models:
            # Use intelligent fuzzy search based on locally installed models
            suggestions = search_ollama_models_fuzzy(model_name, available_models)
            error_msg = f"Model '{model_name}' not found in your local Ollama installation."
            if suggestions:
                error_msg += "\n\nDid you mean one of these installed models?\n"
                for i, suggestion in enumerate(suggestions, 1):
                    error_msg += f"  {i}. {suggestion}\n"
            else:
                error_msg += "\n\nYour installed models:\n"
                for i, model in enumerate(available_models[:8], 1):
                    error_msg += f"  {i}. {model}\n"
                if len(available_models) > 8:
                    error_msg += f"  ... and {len(available_models) - 8} more\n"
-            error_msg += "\nTo list all models: ollama list"
+            # Check if the model exists remotely and get available tags
-            error_msg += "\nTo download a new model: ollama pull <model_name>"
+            model_exists_remotely, available_tags = check_ollama_model_exists_remotely(model_name)
-            error_msg += "\nBrowse models: https://ollama.com/library"
+
            if model_exists_remotely and model_name in available_tags:
                # Exact model exists remotely - suggest pulling it
                error_msg += "\n\nTo install the requested model:\n"
                error_msg += f"  ollama pull {model_name}\n"
                # Show local alternatives
                suggestions = search_ollama_models_fuzzy(model_name, available_models)
                if suggestions:
                    error_msg += "\nOr use one of these similar installed models:\n"
                    for i, suggestion in enumerate(suggestions, 1):
                        error_msg += f"  {i}. {suggestion}\n"
            elif model_exists_remotely and available_tags:
                # Base model exists but requested tag doesn't - suggest correct tags
                base_model = model_name.split(":")[0]
                requested_tag = model_name.split(":", 1)[1] if ":" in model_name else None
                error_msg += (
                    f"\n\nModel '{base_model}' exists, but tag '{requested_tag}' is not available."
                )
                error_msg += f"\n\nAvailable {base_model} models you can install:\n"
                for i, tag in enumerate(available_tags[:8], 1):
                    error_msg += f"  {i}. ollama pull {tag}\n"
                if len(available_tags) > 8:
                    error_msg += f"  ... and {len(available_tags) - 8} more variants\n"
                # Also show local alternatives
                suggestions = search_ollama_models_fuzzy(model_name, available_models)
                if suggestions:
                    error_msg += "\nOr use one of these similar installed models:\n"
                    for i, suggestion in enumerate(suggestions, 1):
                        error_msg += f"  {i}. {suggestion}\n"
            else:
                # Model doesn't exist remotely - show fuzzy suggestions
                suggestions = search_ollama_models_fuzzy(model_name, available_models)
                error_msg += f"\n\nModel '{model_name}' was not found in Ollama's library."
                if suggestions:
                    error_msg += (
                        "\n\nDid you mean one of these installed models?\n"
                        + "\nTry to use ollama pull to install the model you need\n"
                    )
                    for i, suggestion in enumerate(suggestions, 1):
                        error_msg += f"  {i}. {suggestion}\n"
                else:
                    error_msg += "\n\nYour installed models:\n"
                    for i, model in enumerate(available_models[:8], 1):
                        error_msg += f"  {i}. {model}\n"
                    if len(available_models) > 8:
                        error_msg += f"  ... and {len(available_models) - 8} more\n"
            error_msg += "\n\nCommands:"
            error_msg += "\n  ollama list                    # List installed models"
            if model_exists_remotely and available_tags:
                if model_name in available_tags:
                    error_msg += f"\n  ollama pull {model_name}          # Install requested model"
                else:
                    error_msg += (
                        f"\n  ollama pull {available_tags[0]}    # Install recommended variant"
                    )
            error_msg += "\n  https://ollama.com/library     # Browse available models"
            return error_msg
    elif llm_type == "hf":
@@ -348,7 +471,7 @@ class OllamaChat(LLMInterface):
                requests.get(host)
            # Pre-check model availability with helpful suggestions
-            model_error = validate_model_and_suggest(model, "ollama")
+            model_error = validate_model_and_suggest(model, "ollama", host)
            if model_error:
                raise ValueError(model_error)
@@ -357,26 +480,50 @@ class OllamaChat(LLMInterface):
                "The 'requests' library is required for Ollama. Please install it with 'pip install requests'."
            )
        except requests.exceptions.ConnectionError:
-            logger.error(
+            logger.error(f"Could not connect to Ollama at {host}. Please ensure Ollama is running.")
                f"Could not connect to Ollama at {host}. Please ensure Ollama is running."
            )
            raise ConnectionError(
                f"Could not connect to Ollama at {host}. Please ensure Ollama is running."
            )
    def ask(self, prompt: str, **kwargs) -> str:
        import requests
        import json
        import requests
        full_url = f"{self.host}/api/generate"
        # Handle thinking budget for reasoning models
        options = kwargs.copy()
        thinking_budget = kwargs.get("thinking_budget")
        if thinking_budget:
            # Remove thinking_budget from options as it's not a standard Ollama option
            options.pop("thinking_budget", None)
            # Only apply reasoning parameters to models that support it
            reasoning_supported_models = [
                "gpt-oss:20b",
                "gpt-oss:120b",
                "deepseek-r1",
                "deepseek-coder",
            ]
            if thinking_budget in ["low", "medium", "high"]:
                if any(model in self.model.lower() for model in reasoning_supported_models):
                    options["reasoning"] = {"effort": thinking_budget, "exclude": False}
                    logger.info(f"Applied reasoning effort={thinking_budget} to model {self.model}")
                else:
                    logger.warning(
                        f"Thinking budget '{thinking_budget}' requested but model '{self.model}' may not support reasoning parameters. Proceeding without reasoning."
                    )
        payload = {
            "model": self.model,
            "prompt": prompt,
            "stream": False,  # Keep it simple for now
-            "options": kwargs,
+            "options": options,
        }
-        logger.info(f"Sending request to Ollama: {payload}")
+        logger.debug(f"Sending request to Ollama: {payload}")
        try:
            logger.info("Sending request to Ollama and waiting for response...")
            response = requests.post(full_url, data=json.dumps(payload))
            response.raise_for_status()
@@ -396,7 +543,7 @@ class OllamaChat(LLMInterface):
 class HFChat(LLMInterface):
-    """LLM interface for local Hugging Face Transformers models."""
+    """LLM interface for local Hugging Face Transformers models with proper chat templates."""
    def __init__(self, model_name: str = "deepseek-ai/deepseek-llm-7b-chat"):
        logger.info(f"Initializing HFChat with model='{model_name}'")
@@ -407,8 +554,8 @@ class HFChat(LLMInterface):
            raise ValueError(model_error)
        try:
            from transformers.pipelines import pipeline
            import torch
            from transformers import AutoModelForCausalLM, AutoTokenizer
        except ImportError:
            raise ImportError(
                "The 'transformers' and 'torch' libraries are required for Hugging Face models. Please install them with 'pip install transformers torch'."
@@ -416,60 +563,129 @@ class HFChat(LLMInterface):
        # Auto-detect device
        if torch.cuda.is_available():
-            device = "cuda"
+            self.device = "cuda"
            logger.info("CUDA is available. Using GPU.")
        elif hasattr(torch.backends, "mps") and torch.backends.mps.is_available():
-            device = "mps"
+            self.device = "mps"
            logger.info("MPS is available. Using Apple Silicon GPU.")
        else:
-            device = "cpu"
+            self.device = "cpu"
            logger.info("No GPU detected. Using CPU.")
-        self.pipeline = pipeline("text-generation", model=model_name, device=device)
+        # Load tokenizer and model with timeout protection
        try:
            import signal
            def timeout_handler(signum, frame):
                raise TimeoutError("Model download/loading timed out")
            # Set timeout for model loading (60 seconds)
            old_handler = signal.signal(signal.SIGALRM, timeout_handler)
            signal.alarm(60)
            try:
                logger.info(f"Loading tokenizer for {model_name}...")
                self.tokenizer = AutoTokenizer.from_pretrained(model_name)
                logger.info(f"Loading model {model_name}...")
                self.model = AutoModelForCausalLM.from_pretrained(
                    model_name,
                    torch_dtype=torch.float16 if self.device != "cpu" else torch.float32,
                    device_map="auto" if self.device != "cpu" else None,
                    trust_remote_code=True,
                )
                logger.info(f"Successfully loaded {model_name}")
            finally:
                signal.alarm(0)  # Cancel the alarm
                signal.signal(signal.SIGALRM, old_handler)  # Restore old handler
        except TimeoutError:
            logger.error(f"Model loading timed out for {model_name}")
            raise RuntimeError(
                f"Model loading timed out for {model_name}. Please check your internet connection or try a smaller model."
            )
        except Exception as e:
            logger.error(f"Failed to load model {model_name}: {e}")
            raise
        # Move model to device if not using device_map
        if self.device != "cpu" and "device_map" not in str(self.model):
            self.model = self.model.to(self.device)
        # Set pad token if not present
        if self.tokenizer.pad_token is None:
            self.tokenizer.pad_token = self.tokenizer.eos_token
    def ask(self, prompt: str, **kwargs) -> str:
-        # Map OpenAI-style arguments to Hugging Face equivalents
+        print("kwargs in HF: ", kwargs)
-        if "max_tokens" in kwargs:
+        # Check if this is a Qwen model and add /no_think by default
-            # Prefer user-provided max_new_tokens if both are present
+        is_qwen_model = "qwen" in self.model.config._name_or_path.lower()
            kwargs.setdefault("max_new_tokens", kwargs["max_tokens"])
            # Remove the unsupported key to avoid errors in Transformers
            kwargs.pop("max_tokens")
-        # Handle temperature=0 edge-case for greedy decoding
+        # For Qwen models, automatically add /no_think to the prompt
-        if "temperature" in kwargs and kwargs["temperature"] == 0.0:
+        if is_qwen_model and "/no_think" not in prompt and "/think" not in prompt:
-            # Remove unsupported zero temperature and use deterministic generation
+            prompt = prompt + " /no_think"
            kwargs.pop("temperature")
            kwargs.setdefault("do_sample", False)
-        # Sensible defaults for text generation
+        # Prepare chat template
-        params = {"max_length": 500, "num_return_sequences": 1, **kwargs}
+        messages = [{"role": "user", "content": prompt}]
        logger.info(f"Generating text with Hugging Face model with params: {params}")
        results = self.pipeline(prompt, **params)
-        # Handle different response formats from transformers
+        # Apply chat template if available
-        if isinstance(results, list) and len(results) > 0:
+        if hasattr(self.tokenizer, "apply_chat_template"):
-            generated_text = (
+            try:
-                results[0].get("generated_text", "")
+                formatted_prompt = self.tokenizer.apply_chat_template(
-                if isinstance(results[0], dict)
+                    messages, tokenize=False, add_generation_prompt=True
-                else str(results[0])
+                )
-            )
+            except Exception as e:
                logger.warning(f"Chat template failed, using raw prompt: {e}")
                formatted_prompt = prompt
        else:
-            generated_text = str(results)
+            # Fallback for models without chat template
            formatted_prompt = prompt
-        # Extract only the newly generated portion by removing the original prompt
+        # Tokenize input
-        if isinstance(generated_text, str) and generated_text.startswith(prompt):
+        inputs = self.tokenizer(
-            response = generated_text[len(prompt) :].strip()
+            formatted_prompt,
-        else:
+            return_tensors="pt",
-            # Fallback: return the full response if prompt removal fails
+            padding=True,
-            response = str(generated_text)
+            truncation=True,
            max_length=2048,
        )
-        return response
+        # Move inputs to device
        if self.device != "cpu":
            inputs = {k: v.to(self.device) for k, v in inputs.items()}
        # Set generation parameters
        generation_config = {
            "max_new_tokens": kwargs.get("max_tokens", kwargs.get("max_new_tokens", 512)),
            "temperature": kwargs.get("temperature", 0.7),
            "top_p": kwargs.get("top_p", 0.9),
            "do_sample": kwargs.get("temperature", 0.7) > 0,
            "pad_token_id": self.tokenizer.eos_token_id,
            "eos_token_id": self.tokenizer.eos_token_id,
        }
        # Handle temperature=0 for greedy decoding
        if generation_config["temperature"] == 0.0:
            generation_config["do_sample"] = False
            generation_config.pop("temperature")
        logger.info(f"Generating with HuggingFace model, config: {generation_config}")
        # Generate
        with torch.no_grad():
            outputs = self.model.generate(**inputs, **generation_config)
        # Decode response
        generated_tokens = outputs[0][inputs["input_ids"].shape[1] :]
        response = self.tokenizer.decode(generated_tokens, skip_special_tokens=True)
        return response.strip()
 class OpenAIChat(LLMInterface):
    """LLM interface for OpenAI models."""
-    def __init__(self, model: str = "gpt-4o", api_key: Optional[str] = None):
+    def __init__(self, model: str = "gpt-4o", api_key: str | None = None):
        self.model = model
        self.api_key = api_key or os.getenv("OPENAI_API_KEY")
@@ -494,15 +710,38 @@ class OpenAIChat(LLMInterface):
        params = {
            "model": self.model,
            "messages": [{"role": "user", "content": prompt}],
            "max_tokens": kwargs.get("max_tokens", 1000),
            "temperature": kwargs.get("temperature", 0.7),
            **{
                k: v
                for k, v in kwargs.items()
                if k not in ["max_tokens", "temperature"]
            },
        }
        # Handle max_tokens vs max_completion_tokens based on model
        max_tokens = kwargs.get("max_tokens", 1000)
        if "o3" in self.model or "o4" in self.model or "o1" in self.model:
            # o-series models use max_completion_tokens
            params["max_completion_tokens"] = max_tokens
            params["temperature"] = 1.0
        else:
            # Other models use max_tokens
            params["max_tokens"] = max_tokens
        # Handle thinking budget for reasoning models
        thinking_budget = kwargs.get("thinking_budget")
        if thinking_budget and thinking_budget in ["low", "medium", "high"]:
            # Check if this is an o-series model (partial match for model names)
            o_series_models = ["o3", "o3-mini", "o4-mini", "o1", "o3-pro", "o3-deep-research"]
            if any(model in self.model for model in o_series_models):
                # Use the correct OpenAI reasoning parameter format
                params["reasoning_effort"] = thinking_budget
                logger.info(f"Applied reasoning_effort={thinking_budget} to model {self.model}")
            else:
                logger.warning(
                    f"Thinking budget '{thinking_budget}' requested but model '{self.model}' may not support reasoning parameters. Proceeding without reasoning."
                )
        # Add other kwargs (excluding thinking_budget as it's handled above)
        for k, v in kwargs.items():
            if k not in ["max_tokens", "temperature", "thinking_budget"]:
                params[k] = v
        logger.info(f"Sending request to OpenAI with model {self.model}")
        try:
@@ -522,7 +761,7 @@ class SimulatedChat(LLMInterface):
        return "This is a simulated answer from the LLM based on the retrieved context."
-def get_llm(llm_config: Optional[Dict[str, Any]] = None) -> LLMInterface:
+def get_llm(llm_config: dict[str, Any] | None = None) -> LLMInterface:
    """
    Factory function to get an LLM interface based on configuration.
--- a/packages/leann-core/src/leann/cli.py
+++ b/packages/leann-core/src/leann/cli.py
@@ -0,0 +1,699 @@
 import argparse
 import asyncio
 from pathlib import Path
 from llama_index.core import SimpleDirectoryReader
 from llama_index.core.node_parser import SentenceSplitter
 from .api import LeannBuilder, LeannChat, LeannSearcher
 def extract_pdf_text_with_pymupdf(file_path: str) -> str:
    """Extract text from PDF using PyMuPDF for better quality."""
    try:
        import fitz  # PyMuPDF
        doc = fitz.open(file_path)
        text = ""
        for page in doc:
            text += page.get_text()
        doc.close()
        return text
    except ImportError:
        # Fallback to default reader
        return None
 def extract_pdf_text_with_pdfplumber(file_path: str) -> str:
    """Extract text from PDF using pdfplumber for better quality."""
    try:
        import pdfplumber
        text = ""
        with pdfplumber.open(file_path) as pdf:
            for page in pdf.pages:
                text += page.extract_text() or ""
        return text
    except ImportError:
        # Fallback to default reader
        return None
 class LeannCLI:
    def __init__(self):
        # Always use project-local .leann directory (like .git)
        self.indexes_dir = Path.cwd() / ".leann" / "indexes"
        self.indexes_dir.mkdir(parents=True, exist_ok=True)
        # Default parser for documents
        self.node_parser = SentenceSplitter(
            chunk_size=256, chunk_overlap=128, separator=" ", paragraph_separator="\n\n"
        )
        # Code-optimized parser
        self.code_parser = SentenceSplitter(
            chunk_size=512,  # Larger chunks for code context
            chunk_overlap=50,  # Less overlap to preserve function boundaries
            separator="\n",  # Split by lines for code
            paragraph_separator="\n\n",  # Preserve logical code blocks
        )
    def get_index_path(self, index_name: str) -> str:
        index_dir = self.indexes_dir / index_name
        return str(index_dir / "documents.leann")
    def index_exists(self, index_name: str) -> bool:
        index_dir = self.indexes_dir / index_name
        meta_file = index_dir / "documents.leann.meta.json"
        return meta_file.exists()
    def create_parser(self) -> argparse.ArgumentParser:
        parser = argparse.ArgumentParser(
            prog="leann",
            description="LEANN - Local Enhanced AI Navigation",
            formatter_class=argparse.RawDescriptionHelpFormatter,
            epilog="""
 Examples:
  leann build my-docs --docs ./documents                    # Build index named my-docs
  leann build my-ppts --docs ./ --file-types .pptx,.pdf    # Index only PowerPoint and PDF files
  leann search my-docs "query"                             # Search in my-docs index
  leann ask my-docs "question"                             # Ask my-docs index
  leann list                                              # List all stored indexes
            """,
        )
        subparsers = parser.add_subparsers(dest="command", help="Available commands")
        # Build command
        build_parser = subparsers.add_parser("build", help="Build document index")
        build_parser.add_argument(
            "index_name", nargs="?", help="Index name (default: current directory name)"
        )
        build_parser.add_argument(
            "--docs", type=str, default=".", help="Documents directory (default: current directory)"
        )
        build_parser.add_argument(
            "--backend", type=str, default="hnsw", choices=["hnsw", "diskann"]
        )
        build_parser.add_argument("--embedding-model", type=str, default="facebook/contriever")
        build_parser.add_argument(
            "--embedding-mode",
            type=str,
            default="sentence-transformers",
            choices=["sentence-transformers", "openai", "mlx", "ollama"],
            help="Embedding backend mode (default: sentence-transformers)",
        )
        build_parser.add_argument("--force", "-f", action="store_true", help="Force rebuild")
        build_parser.add_argument("--graph-degree", type=int, default=32)
        build_parser.add_argument("--complexity", type=int, default=64)
        build_parser.add_argument("--num-threads", type=int, default=1)
        build_parser.add_argument("--compact", action="store_true", default=True)
        build_parser.add_argument("--recompute", action="store_true", default=True)
        build_parser.add_argument(
            "--file-types",
            type=str,
            help="Comma-separated list of file extensions to include (e.g., '.txt,.pdf,.pptx'). If not specified, uses default supported types.",
        )
        # Search command
        search_parser = subparsers.add_parser("search", help="Search documents")
        search_parser.add_argument("index_name", help="Index name")
        search_parser.add_argument("query", help="Search query")
        search_parser.add_argument("--top-k", type=int, default=5)
        search_parser.add_argument("--complexity", type=int, default=64)
        search_parser.add_argument("--beam-width", type=int, default=1)
        search_parser.add_argument("--prune-ratio", type=float, default=0.0)
        search_parser.add_argument(
            "--recompute-embeddings",
            action="store_true",
            default=True,
            help="Recompute embeddings (default: True)",
        )
        search_parser.add_argument(
            "--pruning-strategy",
            choices=["global", "local", "proportional"],
            default="global",
        )
        # Ask command
        ask_parser = subparsers.add_parser("ask", help="Ask questions")
        ask_parser.add_argument("index_name", help="Index name")
        ask_parser.add_argument(
            "--llm",
            type=str,
            default="ollama",
            choices=["simulated", "ollama", "hf", "openai"],
        )
        ask_parser.add_argument("--model", type=str, default="qwen3:8b")
        ask_parser.add_argument("--host", type=str, default="http://localhost:11434")
        ask_parser.add_argument("--interactive", "-i", action="store_true")
        ask_parser.add_argument("--top-k", type=int, default=20)
        ask_parser.add_argument("--complexity", type=int, default=32)
        ask_parser.add_argument("--beam-width", type=int, default=1)
        ask_parser.add_argument("--prune-ratio", type=float, default=0.0)
        ask_parser.add_argument(
            "--recompute-embeddings",
            action="store_true",
            default=True,
            help="Recompute embeddings (default: True)",
        )
        ask_parser.add_argument(
            "--pruning-strategy",
            choices=["global", "local", "proportional"],
            default="global",
        )
        ask_parser.add_argument(
            "--thinking-budget",
            type=str,
            choices=["low", "medium", "high"],
            default=None,
            help="Thinking budget for reasoning models (low/medium/high). Supported by GPT-Oss:20b and other reasoning models.",
        )
        # List command
        subparsers.add_parser("list", help="List all indexes")
        return parser
    def register_project_dir(self):
        """Register current project directory in global registry"""
        global_registry = Path.home() / ".leann" / "projects.json"
        global_registry.parent.mkdir(exist_ok=True)
        current_dir = str(Path.cwd())
        # Load existing registry
        projects = []
        if global_registry.exists():
            try:
                import json
                with open(global_registry) as f:
                    projects = json.load(f)
            except Exception:
                projects = []
        # Add current directory if not already present
        if current_dir not in projects:
            projects.append(current_dir)
        # Save registry
        import json
        with open(global_registry, "w") as f:
            json.dump(projects, f, indent=2)
    def _build_gitignore_parser(self, docs_dir: str):
        """Build gitignore parser using gitignore-parser library."""
        from gitignore_parser import parse_gitignore
        # Try to parse the root .gitignore
        gitignore_path = Path(docs_dir) / ".gitignore"
        if gitignore_path.exists():
            try:
                # gitignore-parser automatically handles all subdirectory .gitignore files!
                matches = parse_gitignore(str(gitignore_path))
                print(f"📋 Loaded .gitignore from {docs_dir} (includes all subdirectories)")
                return matches
            except Exception as e:
                print(f"Warning: Could not parse .gitignore: {e}")
        else:
            print("📋 No .gitignore found")
        # Fallback: basic pattern matching for essential files
        essential_patterns = {".git", ".DS_Store", "__pycache__", "node_modules", ".venv", "venv"}
        def basic_matches(file_path):
            path_parts = Path(file_path).parts
            return any(part in essential_patterns for part in path_parts)
        return basic_matches
    def _should_exclude_file(self, relative_path: Path, gitignore_matches) -> bool:
        """Check if a file should be excluded using gitignore parser."""
        return gitignore_matches(str(relative_path))
    def list_indexes(self):
        print("Stored LEANN indexes:")
        # Get all project directories with .leann
        global_registry = Path.home() / ".leann" / "projects.json"
        all_projects = []
        if global_registry.exists():
            try:
                import json
                with open(global_registry) as f:
                    all_projects = json.load(f)
            except Exception:
                pass
        # Filter to only existing directories with .leann
        valid_projects = []
        for project_dir in all_projects:
            project_path = Path(project_dir)
            if project_path.exists() and (project_path / ".leann" / "indexes").exists():
                valid_projects.append(project_path)
        # Add current project if it has .leann but not in registry
        current_path = Path.cwd()
        if (current_path / ".leann" / "indexes").exists() and current_path not in valid_projects:
            valid_projects.append(current_path)
        if not valid_projects:
            print("No indexes found. Use 'leann build <name> --docs <dir>' to create one.")
            return
        total_indexes = 0
        current_dir = Path.cwd()
        for project_path in valid_projects:
            indexes_dir = project_path / ".leann" / "indexes"
            if not indexes_dir.exists():
                continue
            index_dirs = [d for d in indexes_dir.iterdir() if d.is_dir()]
            if not index_dirs:
                continue
            # Show project header
            if project_path == current_dir:
                print(f"\n📁 Current project ({project_path}):")
            else:
                print(f"\n📂 {project_path}:")
            for index_dir in index_dirs:
                total_indexes += 1
                index_name = index_dir.name
                meta_file = index_dir / "documents.leann.meta.json"
                status = "✓" if meta_file.exists() else "✗"
                print(f"  {total_indexes}. {index_name} [{status}]")
                if status == "✓":
                    size_mb = sum(f.stat().st_size for f in index_dir.iterdir() if f.is_file()) / (
                        1024 * 1024
                    )
                    print(f"     Size: {size_mb:.1f} MB")
        if total_indexes > 0:
            print(f"\nTotal: {total_indexes} indexes across {len(valid_projects)} projects")
            print("\nUsage (current project only):")
            # Show example from current project
            current_indexes_dir = current_dir / ".leann" / "indexes"
            if current_indexes_dir.exists():
                current_index_dirs = [d for d in current_indexes_dir.iterdir() if d.is_dir()]
                if current_index_dirs:
                    example_name = current_index_dirs[0].name
                    print(f'  leann search {example_name} "your query"')
                    print(f"  leann ask {example_name} --interactive")
    def load_documents(self, docs_dir: str, custom_file_types: str | None = None):
        print(f"Loading documents from {docs_dir}...")
        if custom_file_types:
            print(f"Using custom file types: {custom_file_types}")
        # Build gitignore parser
        gitignore_matches = self._build_gitignore_parser(docs_dir)
        # Try to use better PDF parsers first, but only if PDFs are requested
        documents = []
        docs_path = Path(docs_dir)
        # Check if we should process PDFs
        should_process_pdfs = custom_file_types is None or ".pdf" in custom_file_types
        if should_process_pdfs:
            for file_path in docs_path.rglob("*.pdf"):
                # Check if file matches any exclude pattern
                relative_path = file_path.relative_to(docs_path)
                if self._should_exclude_file(relative_path, gitignore_matches):
                    continue
                print(f"Processing PDF: {file_path}")
                # Try PyMuPDF first (best quality)
                text = extract_pdf_text_with_pymupdf(str(file_path))
                if text is None:
                    # Try pdfplumber
                    text = extract_pdf_text_with_pdfplumber(str(file_path))
                if text:
                    # Create a simple document structure
                    from llama_index.core import Document
                    doc = Document(text=text, metadata={"source": str(file_path)})
                    documents.append(doc)
                else:
                    # Fallback to default reader
                    print(f"Using default reader for {file_path}")
                    try:
                        default_docs = SimpleDirectoryReader(
                            str(file_path.parent),
                            filename_as_id=True,
                            required_exts=[file_path.suffix],
                        ).load_data()
                        documents.extend(default_docs)
                    except Exception as e:
                        print(f"Warning: Could not process {file_path}: {e}")
        # Load other file types with default reader
        if custom_file_types:
            # Parse custom file types from comma-separated string
            code_extensions = [ext.strip() for ext in custom_file_types.split(",") if ext.strip()]
            # Ensure extensions start with a dot
            code_extensions = [ext if ext.startswith(".") else f".{ext}" for ext in code_extensions]
        else:
            # Use default supported file types
            code_extensions = [
                # Original document types
                ".txt",
                ".md",
                ".docx",
                ".pptx",
                # Code files for Claude Code integration
                ".py",
                ".js",
                ".ts",
                ".jsx",
                ".tsx",
                ".java",
                ".cpp",
                ".c",
                ".h",
                ".hpp",
                ".cs",
                ".go",
                ".rs",
                ".rb",
                ".php",
                ".swift",
                ".kt",
                ".scala",
                ".r",
                ".sql",
                ".sh",
                ".bash",
                ".zsh",
                ".fish",
                ".ps1",
                ".bat",
                # Config and markup files
                ".json",
                ".yaml",
                ".yml",
                ".xml",
                ".toml",
                ".ini",
                ".cfg",
                ".conf",
                ".html",
                ".css",
                ".scss",
                ".less",
                ".vue",
                ".svelte",
                # Data science
                ".ipynb",
                ".R",
                ".py",
                ".jl",
            ]
        # Try to load other file types, but don't fail if none are found
        try:
            # Create a custom file filter function using our PathSpec
            def file_filter(file_path: str) -> bool:
                """Return True if file should be included (not excluded)"""
                try:
                    docs_path_obj = Path(docs_dir)
                    file_path_obj = Path(file_path)
                    relative_path = file_path_obj.relative_to(docs_path_obj)
                    return not self._should_exclude_file(relative_path, gitignore_matches)
                except (ValueError, OSError):
                    return True  # Include files that can't be processed
            other_docs = SimpleDirectoryReader(
                docs_dir,
                recursive=True,
                encoding="utf-8",
                required_exts=code_extensions,
                file_extractor={},  # Use default extractors
                filename_as_id=True,
            ).load_data(show_progress=True)
            # Filter documents after loading based on gitignore rules
            filtered_docs = []
            for doc in other_docs:
                file_path = doc.metadata.get("file_path", "")
                if file_filter(file_path):
                    filtered_docs.append(doc)
            documents.extend(filtered_docs)
        except ValueError as e:
            if "No files found" in str(e):
                print("No additional files found for other supported types.")
            else:
                raise e
        all_texts = []
        # Define code file extensions for intelligent chunking
        code_file_exts = {
            ".py",
            ".js",
            ".ts",
            ".jsx",
            ".tsx",
            ".java",
            ".cpp",
            ".c",
            ".h",
            ".hpp",
            ".cs",
            ".go",
            ".rs",
            ".rb",
            ".php",
            ".swift",
            ".kt",
            ".scala",
            ".r",
            ".sql",
            ".sh",
            ".bash",
            ".zsh",
            ".fish",
            ".ps1",
            ".bat",
            ".json",
            ".yaml",
            ".yml",
            ".xml",
            ".toml",
            ".ini",
            ".cfg",
            ".conf",
            ".html",
            ".css",
            ".scss",
            ".less",
            ".vue",
            ".svelte",
            ".ipynb",
            ".R",
            ".jl",
        }
        for doc in documents:
            # Check if this is a code file based on source path
            source_path = doc.metadata.get("source", "")
            is_code_file = any(source_path.endswith(ext) for ext in code_file_exts)
            # Use appropriate parser based on file type
            parser = self.code_parser if is_code_file else self.node_parser
            nodes = parser.get_nodes_from_documents([doc])
            for node in nodes:
                all_texts.append(node.get_content())
        print(f"Loaded {len(documents)} documents, {len(all_texts)} chunks")
        return all_texts
    async def build_index(self, args):
        docs_dir = args.docs
        # Use current directory name if index_name not provided
        if args.index_name:
            index_name = args.index_name
        else:
            index_name = Path.cwd().name
            print(f"Using current directory name as index: '{index_name}'")
        index_dir = self.indexes_dir / index_name
        index_path = self.get_index_path(index_name)
        print(f"📂 Indexing: {Path(docs_dir).resolve()}")
        if index_dir.exists() and not args.force:
            print(f"Index '{index_name}' already exists. Use --force to rebuild.")
            return
        all_texts = self.load_documents(docs_dir, args.file_types)
        if not all_texts:
            print("No documents found")
            return
        index_dir.mkdir(parents=True, exist_ok=True)
        print(f"Building index '{index_name}' with {args.backend} backend...")
        builder = LeannBuilder(
            backend_name=args.backend,
            embedding_model=args.embedding_model,
            embedding_mode=args.embedding_mode,
            graph_degree=args.graph_degree,
            complexity=args.complexity,
            is_compact=args.compact,
            is_recompute=args.recompute,
            num_threads=args.num_threads,
        )
        for chunk_text in all_texts:
            builder.add_text(chunk_text)
        builder.build_index(index_path)
        print(f"Index built at {index_path}")
        # Register this project directory in global registry
        self.register_project_dir()
    async def search_documents(self, args):
        index_name = args.index_name
        query = args.query
        index_path = self.get_index_path(index_name)
        if not self.index_exists(index_name):
            print(
                f"Index '{index_name}' not found. Use 'leann build {index_name} --docs <dir>' to create it."
            )
            return
        searcher = LeannSearcher(index_path=index_path)
        results = searcher.search(
            query,
            top_k=args.top_k,
            complexity=args.complexity,
            beam_width=args.beam_width,
            prune_ratio=args.prune_ratio,
            recompute_embeddings=args.recompute_embeddings,
            pruning_strategy=args.pruning_strategy,
        )
        print(f"Search results for '{query}' (top {len(results)}):")
        for i, result in enumerate(results, 1):
            print(f"{i}. Score: {result.score:.3f}")
            print(f"   {result.text[:200]}...")
            print()
    async def ask_questions(self, args):
        index_name = args.index_name
        index_path = self.get_index_path(index_name)
        if not self.index_exists(index_name):
            print(
                f"Index '{index_name}' not found. Use 'leann build {index_name} --docs <dir>' to create it."
            )
            return
        print(f"Starting chat with index '{index_name}'...")
        print(f"Using {args.model} ({args.llm})")
        llm_config = {"type": args.llm, "model": args.model}
        if args.llm == "ollama":
            llm_config["host"] = args.host
        chat = LeannChat(index_path=index_path, llm_config=llm_config)
        if args.interactive:
            print("LEANN Assistant ready! Type 'quit' to exit")
            print("=" * 40)
            while True:
                user_input = input("\nYou: ").strip()
                if user_input.lower() in ["quit", "exit", "q"]:
                    print("Goodbye!")
                    break
                if not user_input:
                    continue
                # Prepare LLM kwargs with thinking budget if specified
                llm_kwargs = {}
                if args.thinking_budget:
                    llm_kwargs["thinking_budget"] = args.thinking_budget
                response = chat.ask(
                    user_input,
                    top_k=args.top_k,
                    complexity=args.complexity,
                    beam_width=args.beam_width,
                    prune_ratio=args.prune_ratio,
                    recompute_embeddings=args.recompute_embeddings,
                    pruning_strategy=args.pruning_strategy,
                    llm_kwargs=llm_kwargs,
                )
                print(f"LEANN: {response}")
        else:
            query = input("Enter your question: ").strip()
            if query:
                # Prepare LLM kwargs with thinking budget if specified
                llm_kwargs = {}
                if args.thinking_budget:
                    llm_kwargs["thinking_budget"] = args.thinking_budget
                response = chat.ask(
                    query,
                    top_k=args.top_k,
                    complexity=args.complexity,
                    beam_width=args.beam_width,
                    prune_ratio=args.prune_ratio,
                    recompute_embeddings=args.recompute_embeddings,
                    pruning_strategy=args.pruning_strategy,
                    llm_kwargs=llm_kwargs,
                )
                print(f"LEANN: {response}")
    async def run(self, args=None):
        parser = self.create_parser()
        if args is None:
            args = parser.parse_args()
        if not args.command:
            parser.print_help()
            return
        if args.command == "list":
            self.list_indexes()
        elif args.command == "build":
            await self.build_index(args)
        elif args.command == "search":
            await self.search_documents(args)
        elif args.command == "ask":
            await self.ask_questions(args)
        else:
            parser.print_help()
 def main():
    import dotenv
    dotenv.load_dotenv()
    cli = LeannCLI()
    asyncio.run(cli.run())
 if __name__ == "__main__":
    main()
--- a/packages/leann-core/src/leann/embedding_compute.py
+++ b/packages/leann-core/src/leann/embedding_compute.py
@@ -0,0 +1,629 @@
 """
 Unified embedding computation module
 Consolidates all embedding computation logic using SentenceTransformer
 Preserves all optimization parameters to ensure performance
 """
 import logging
 import os
 from concurrent.futures import ThreadPoolExecutor, as_completed
 from typing import Any
 import numpy as np
 import torch
 # Set up logger with proper level
 logger = logging.getLogger(__name__)
 LOG_LEVEL = os.getenv("LEANN_LOG_LEVEL", "WARNING").upper()
 log_level = getattr(logging, LOG_LEVEL, logging.WARNING)
 logger.setLevel(log_level)
 # Global model cache to avoid repeated loading
 _model_cache: dict[str, Any] = {}
 def compute_embeddings(
    texts: list[str],
    model_name: str,
    mode: str = "sentence-transformers",
    is_build: bool = False,
    batch_size: int = 32,
    adaptive_optimization: bool = True,
 ) -> np.ndarray:
    """
    Unified embedding computation entry point
    Args:
        texts: List of texts to compute embeddings for
        model_name: Model name
        mode: Computation mode ('sentence-transformers', 'openai', 'mlx', 'ollama')
        is_build: Whether this is a build operation (shows progress bar)
        batch_size: Batch size for processing
        adaptive_optimization: Whether to use adaptive optimization based on batch size
    Returns:
        Normalized embeddings array, shape: (len(texts), embedding_dim)
    """
    if mode == "sentence-transformers":
        return compute_embeddings_sentence_transformers(
            texts,
            model_name,
            is_build=is_build,
            batch_size=batch_size,
            adaptive_optimization=adaptive_optimization,
        )
    elif mode == "openai":
        return compute_embeddings_openai(texts, model_name)
    elif mode == "mlx":
        return compute_embeddings_mlx(texts, model_name)
    elif mode == "ollama":
        return compute_embeddings_ollama(texts, model_name, is_build=is_build)
    else:
        raise ValueError(f"Unsupported embedding mode: {mode}")
 def compute_embeddings_sentence_transformers(
    texts: list[str],
    model_name: str,
    use_fp16: bool = True,
    device: str = "auto",
    batch_size: int = 32,
    is_build: bool = False,
    adaptive_optimization: bool = True,
 ) -> np.ndarray:
    """
    Compute embeddings using SentenceTransformer with model caching and adaptive optimization
    Args:
        texts: List of texts to compute embeddings for
        model_name: Model name
        use_fp16: Whether to use FP16 precision
        device: Device to use ('auto', 'cuda', 'mps', 'cpu')
        batch_size: Batch size for processing
        is_build: Whether this is a build operation (shows progress bar)
        adaptive_optimization: Whether to use adaptive optimization based on batch size
    """
    # Handle empty input
    if not texts:
        raise ValueError("Cannot compute embeddings for empty text list")
    logger.info(
        f"Computing embeddings for {len(texts)} texts using SentenceTransformer, model: '{model_name}'"
    )
    # Auto-detect device
    if device == "auto":
        if torch.cuda.is_available():
            device = "cuda"
        elif hasattr(torch.backends, "mps") and torch.backends.mps.is_available():
            device = "mps"
        else:
            device = "cpu"
    # Apply optimizations based on benchmark results
    if adaptive_optimization:
        # Use optimal batch_size constants for different devices based on benchmark results
        if device == "mps":
            batch_size = 128  # MPS optimal batch size from benchmark
            if model_name == "Qwen/Qwen3-Embedding-0.6B":
                batch_size = 32
        elif device == "cuda":
            batch_size = 256  # CUDA optimal batch size
        # Keep original batch_size for CPU
    # Create cache key
    cache_key = f"sentence_transformers_{model_name}_{device}_{use_fp16}_optimized"
    # Check if model is already cached
    if cache_key in _model_cache:
        logger.info(f"Using cached optimized model: {model_name}")
        model = _model_cache[cache_key]
    else:
        logger.info(f"Loading and caching optimized SentenceTransformer model: {model_name}")
        from sentence_transformers import SentenceTransformer
        logger.info(f"Using device: {device}")
        # Apply hardware optimizations
        if device == "cuda":
            # TODO: Haven't tested this yet
            torch.backends.cuda.matmul.allow_tf32 = True
            torch.backends.cudnn.allow_tf32 = True
            torch.backends.cudnn.benchmark = True
            torch.backends.cudnn.deterministic = False
            torch.cuda.set_per_process_memory_fraction(0.9)
        elif device == "mps":
            try:
                if hasattr(torch.mps, "set_per_process_memory_fraction"):
                    torch.mps.set_per_process_memory_fraction(0.9)
            except AttributeError:
                logger.warning("Some MPS optimizations not available in this PyTorch version")
        elif device == "cpu":
            # TODO: Haven't tested this yet
            torch.set_num_threads(min(8, os.cpu_count() or 4))
            try:
                torch.backends.mkldnn.enabled = True
            except AttributeError:
                pass
        # Prepare optimized model and tokenizer parameters
        model_kwargs = {
            "torch_dtype": torch.float16 if use_fp16 else torch.float32,
            "low_cpu_mem_usage": True,
            "_fast_init": True,
            "attn_implementation": "eager",  # Use eager attention for speed
        }
        tokenizer_kwargs = {
            "use_fast": True,
            "padding": True,
            "truncation": True,
        }
        try:
            # Try local loading first
            model_kwargs["local_files_only"] = True
            tokenizer_kwargs["local_files_only"] = True
            model = SentenceTransformer(
                model_name,
                device=device,
                model_kwargs=model_kwargs,
                tokenizer_kwargs=tokenizer_kwargs,
                local_files_only=True,
            )
            logger.info("Model loaded successfully! (local + optimized)")
        except Exception as e:
            logger.warning(f"Local loading failed ({e}), trying network download...")
            # Fallback to network loading
            model_kwargs["local_files_only"] = False
            tokenizer_kwargs["local_files_only"] = False
            model = SentenceTransformer(
                model_name,
                device=device,
                model_kwargs=model_kwargs,
                tokenizer_kwargs=tokenizer_kwargs,
                local_files_only=False,
            )
            logger.info("Model loaded successfully! (network + optimized)")
        # Apply additional optimizations based on mode
        if use_fp16 and device in ["cuda", "mps"]:
            try:
                model = model.half()
                logger.info(f"Applied FP16 precision: {model_name}")
            except Exception as e:
                logger.warning(f"FP16 optimization failed: {e}")
        # Apply torch.compile optimization
        if device in ["cuda", "mps"]:
            try:
                model = torch.compile(model, mode="reduce-overhead", dynamic=True)
                logger.info(f"Applied torch.compile optimization: {model_name}")
            except Exception as e:
                logger.warning(f"torch.compile optimization failed: {e}")
        # Set model to eval mode and disable gradients for inference
        model.eval()
        for param in model.parameters():
            param.requires_grad_(False)
        # Cache the model
        _model_cache[cache_key] = model
        logger.info(f"Model cached: {cache_key}")
    # Compute embeddings with optimized inference mode
    logger.info(f"Starting embedding computation... (batch_size: {batch_size})")
    # Use torch.inference_mode for optimal performance
    with torch.inference_mode():
        embeddings = model.encode(
            texts,
            batch_size=batch_size,
            show_progress_bar=is_build,  # Don't show progress bar in server environment
            convert_to_numpy=True,
            normalize_embeddings=False,
            device=device,
        )
    logger.info(f"Generated {len(embeddings)} embeddings, dimension: {embeddings.shape[1]}")
    # Validate results
    if np.isnan(embeddings).any() or np.isinf(embeddings).any():
        raise RuntimeError(f"Detected NaN or Inf values in embeddings, model: {model_name}")
    return embeddings
 def compute_embeddings_openai(texts: list[str], model_name: str) -> np.ndarray:
    # TODO: @yichuan-w add progress bar only in build mode
    """Compute embeddings using OpenAI API"""
    try:
        import os
        import openai
    except ImportError as e:
        raise ImportError(f"OpenAI package not installed: {e}")
    api_key = os.getenv("OPENAI_API_KEY")
    if not api_key:
        raise RuntimeError("OPENAI_API_KEY environment variable not set")
    # Cache OpenAI client
    cache_key = "openai_client"
    if cache_key in _model_cache:
        client = _model_cache[cache_key]
    else:
        client = openai.OpenAI(api_key=api_key)
        _model_cache[cache_key] = client
        logger.info("OpenAI client cached")
    logger.info(
        f"Computing embeddings for {len(texts)} texts using OpenAI API, model: '{model_name}'"
    )
    print(f"len of texts: {len(texts)}")
    # OpenAI has limits on batch size and input length
    max_batch_size = 1000  # Conservative batch size
    all_embeddings = []
    try:
        from tqdm import tqdm
        total_batches = (len(texts) + max_batch_size - 1) // max_batch_size
        batch_range = range(0, len(texts), max_batch_size)
        batch_iterator = tqdm(
            batch_range, desc="Computing embeddings", unit="batch", total=total_batches
        )
    except ImportError:
        # Fallback when tqdm is not available
        batch_iterator = range(0, len(texts), max_batch_size)
    for i in batch_iterator:
        batch_texts = texts[i : i + max_batch_size]
        try:
            response = client.embeddings.create(model=model_name, input=batch_texts)
            batch_embeddings = [embedding.embedding for embedding in response.data]
            all_embeddings.extend(batch_embeddings)
        except Exception as e:
            logger.error(f"Batch {i} failed: {e}")
            raise
    embeddings = np.array(all_embeddings, dtype=np.float32)
    logger.info(f"Generated {len(embeddings)} embeddings, dimension: {embeddings.shape[1]}")
    print(f"len of embeddings: {len(embeddings)}")
    return embeddings
 def compute_embeddings_mlx(chunks: list[str], model_name: str, batch_size: int = 16) -> np.ndarray:
    # TODO: @yichuan-w add progress bar only in build mode
    """Computes embeddings using an MLX model."""
    try:
        import mlx.core as mx
        from mlx_lm.utils import load
    except ImportError as e:
        raise RuntimeError(
            "MLX or related libraries not available. Install with: uv pip install mlx mlx-lm"
        ) from e
    logger.info(
        f"Computing embeddings for {len(chunks)} chunks using MLX model '{model_name}' with batch_size={batch_size}..."
    )
    # Cache MLX model and tokenizer
    cache_key = f"mlx_{model_name}"
    if cache_key in _model_cache:
        logger.info(f"Using cached MLX model: {model_name}")
        model, tokenizer = _model_cache[cache_key]
    else:
        logger.info(f"Loading and caching MLX model: {model_name}")
        model, tokenizer = load(model_name)
        _model_cache[cache_key] = (model, tokenizer)
        logger.info(f"MLX model cached: {cache_key}")
    # Process chunks in batches with progress bar
    all_embeddings = []
    try:
        from tqdm import tqdm
        batch_iterator = tqdm(
            range(0, len(chunks), batch_size), desc="Computing embeddings", unit="batch"
        )
    except ImportError:
        batch_iterator = range(0, len(chunks), batch_size)
    for i in batch_iterator:
        batch_chunks = chunks[i : i + batch_size]
        # Tokenize all chunks in the batch
        batch_token_ids = []
        for chunk in batch_chunks:
            token_ids = tokenizer.encode(chunk)  # type: ignore
            batch_token_ids.append(token_ids)
        # Pad sequences to the same length for batch processing
        max_length = max(len(ids) for ids in batch_token_ids)
        padded_token_ids = []
        for token_ids in batch_token_ids:
            # Pad with tokenizer.pad_token_id or 0
            padded = token_ids + [0] * (max_length - len(token_ids))
            padded_token_ids.append(padded)
        # Convert to MLX array with batch dimension
        input_ids = mx.array(padded_token_ids)
        # Get embeddings for the batch
        embeddings = model(input_ids)
        # Mean pooling for each sequence in the batch
        pooled = embeddings.mean(axis=1)  # Shape: (batch_size, hidden_size)
        # Convert batch embeddings to numpy
        for j in range(len(batch_chunks)):
            pooled_list = pooled[j].tolist()  # Convert to list
            pooled_numpy = np.array(pooled_list, dtype=np.float32)
            all_embeddings.append(pooled_numpy)
    # Stack numpy arrays
    return np.stack(all_embeddings)
 def compute_embeddings_ollama(
    texts: list[str], model_name: str, is_build: bool = False, host: str = "http://localhost:11434"
 ) -> np.ndarray:
    """
    Compute embeddings using Ollama API.
    Args:
        texts: List of texts to compute embeddings for
        model_name: Ollama model name (e.g., "nomic-embed-text", "mxbai-embed-large")
        is_build: Whether this is a build operation (shows progress bar)
        host: Ollama host URL (default: http://localhost:11434)
    Returns:
        Normalized embeddings array, shape: (len(texts), embedding_dim)
    """
    try:
        import requests
    except ImportError:
        raise ImportError(
            "The 'requests' library is required for Ollama embeddings. Install with: uv pip install requests"
        )
    if not texts:
        raise ValueError("Cannot compute embeddings for empty text list")
    logger.info(
        f"Computing embeddings for {len(texts)} texts using Ollama API, model: '{model_name}'"
    )
    # Check if Ollama is running
    try:
        response = requests.get(f"{host}/api/version", timeout=5)
        response.raise_for_status()
    except requests.exceptions.ConnectionError:
        error_msg = (
            f"❌ Could not connect to Ollama at {host}.\n\n"
            "Please ensure Ollama is running:\n"
            "  • macOS/Linux: ollama serve\n"
            "  • Windows: Make sure Ollama is running in the system tray\n\n"
            "Installation: https://ollama.com/download"
        )
        raise RuntimeError(error_msg)
    except Exception as e:
        raise RuntimeError(f"Unexpected error connecting to Ollama: {e}")
    # Check if model exists and provide helpful suggestions
    try:
        response = requests.get(f"{host}/api/tags", timeout=5)
        response.raise_for_status()
        models = response.json()
        model_names = [model["name"] for model in models.get("models", [])]
        # Filter for embedding models (models that support embeddings)
        embedding_models = []
        suggested_embedding_models = [
            "nomic-embed-text",
            "mxbai-embed-large",
            "bge-m3",
            "all-minilm",
            "snowflake-arctic-embed",
        ]
        for model in model_names:
            # Check if it's an embedding model (by name patterns or known models)
            base_name = model.split(":")[0]
            if any(emb in base_name for emb in ["embed", "bge", "minilm", "e5"]):
                embedding_models.append(model)
        # Check if model exists (handle versioned names)
        model_found = any(
            model_name == name.split(":")[0] or model_name == name for name in model_names
        )
        if not model_found:
            error_msg = f"❌ Model '{model_name}' not found in local Ollama.\n\n"
            # Suggest pulling the model
            error_msg += "📦 To install this embedding model:\n"
            error_msg += f"   ollama pull {model_name}\n\n"
            # Show available embedding models
            if embedding_models:
                error_msg += "✅ Available embedding models:\n"
                for model in embedding_models[:5]:
                    error_msg += f"   • {model}\n"
                if len(embedding_models) > 5:
                    error_msg += f"   ... and {len(embedding_models) - 5} more\n"
            else:
                error_msg += "💡 Popular embedding models to install:\n"
                for model in suggested_embedding_models[:3]:
                    error_msg += f"   • ollama pull {model}\n"
            error_msg += "\n📚 Browse more: https://ollama.com/library"
            raise ValueError(error_msg)
        # Verify the model supports embeddings by testing it
        try:
            test_response = requests.post(
                f"{host}/api/embeddings", json={"model": model_name, "prompt": "test"}, timeout=10
            )
            if test_response.status_code != 200:
                error_msg = (
                    f"⚠️ Model '{model_name}' exists but may not support embeddings.\n\n"
                    f"Please use an embedding model like:\n"
                )
                for model in suggested_embedding_models[:3]:
                    error_msg += f"   • {model}\n"
                raise ValueError(error_msg)
        except requests.exceptions.RequestException:
            # If test fails, continue anyway - model might still work
            pass
    except requests.exceptions.RequestException as e:
        logger.warning(f"Could not verify model existence: {e}")
    # Process embeddings with optimized concurrent processing
    import requests
    def get_single_embedding(text_idx_tuple):
        """Helper function to get embedding for a single text."""
        text, idx = text_idx_tuple
        max_retries = 3
        retry_count = 0
        # Truncate very long texts to avoid API issues
        truncated_text = text[:8000] if len(text) > 8000 else text
        while retry_count < max_retries:
            try:
                response = requests.post(
                    f"{host}/api/embeddings",
                    json={"model": model_name, "prompt": truncated_text},
                    timeout=30,
                )
                response.raise_for_status()
                result = response.json()
                embedding = result.get("embedding")
                if embedding is None:
                    raise ValueError(f"No embedding returned for text {idx}")
                return idx, embedding
            except requests.exceptions.Timeout:
                retry_count += 1
                if retry_count >= max_retries:
                    logger.warning(f"Timeout for text {idx} after {max_retries} retries")
                    return idx, None
            except Exception as e:
                if retry_count >= max_retries - 1:
                    logger.error(f"Failed to get embedding for text {idx}: {e}")
                    return idx, None
                retry_count += 1
        return idx, None
    # Determine if we should use concurrent processing
    use_concurrent = (
        len(texts) > 5 and not is_build
    )  # Don't use concurrent in build mode to avoid overwhelming
    max_workers = min(4, len(texts))  # Limit concurrent requests to avoid overwhelming Ollama
    all_embeddings = [None] * len(texts)  # Pre-allocate list to maintain order
    failed_indices = []
    if use_concurrent:
        logger.info(
            f"Using concurrent processing with {max_workers} workers for {len(texts)} texts"
        )
        with ThreadPoolExecutor(max_workers=max_workers) as executor:
            # Submit all tasks
            future_to_idx = {
                executor.submit(get_single_embedding, (text, idx)): idx
                for idx, text in enumerate(texts)
            }
            # Add progress bar for concurrent processing
            try:
                if is_build or len(texts) > 10:
                    from tqdm import tqdm
                    futures_iterator = tqdm(
                        as_completed(future_to_idx),
                        total=len(texts),
                        desc="Computing Ollama embeddings",
                    )
                else:
                    futures_iterator = as_completed(future_to_idx)
            except ImportError:
                futures_iterator = as_completed(future_to_idx)
            # Collect results as they complete
            for future in futures_iterator:
                try:
                    idx, embedding = future.result()
                    if embedding is not None:
                        all_embeddings[idx] = embedding
                    else:
                        failed_indices.append(idx)
                except Exception as e:
                    idx = future_to_idx[future]
                    logger.error(f"Exception for text {idx}: {e}")
                    failed_indices.append(idx)
    else:
        # Sequential processing with progress bar
        show_progress = is_build or len(texts) > 10
        try:
            if show_progress:
                from tqdm import tqdm
                iterator = tqdm(
                    enumerate(texts), total=len(texts), desc="Computing Ollama embeddings"
                )
            else:
                iterator = enumerate(texts)
        except ImportError:
            iterator = enumerate(texts)
        for idx, text in iterator:
            result_idx, embedding = get_single_embedding((text, idx))
            if embedding is not None:
                all_embeddings[idx] = embedding
            else:
                failed_indices.append(idx)
    # Handle failed embeddings
    if failed_indices:
        if len(failed_indices) == len(texts):
            raise RuntimeError("Failed to compute any embeddings")
        logger.warning(f"Failed to compute embeddings for {len(failed_indices)}/{len(texts)} texts")
        # Use zero embeddings as fallback for failed ones
        valid_embedding = next((e for e in all_embeddings if e is not None), None)
        if valid_embedding:
            embedding_dim = len(valid_embedding)
            for idx in failed_indices:
                all_embeddings[idx] = [0.0] * embedding_dim
    # Remove None values and convert to numpy array
    all_embeddings = [e for e in all_embeddings if e is not None]
    # Convert to numpy array and normalize
    embeddings = np.array(all_embeddings, dtype=np.float32)
    # Normalize embeddings (L2 normalization)
    norms = np.linalg.norm(embeddings, axis=1, keepdims=True)
    embeddings = embeddings / (norms + 1e-8)  # Add small epsilon to avoid division by zero
    logger.info(f"Generated {len(embeddings)} embeddings, dimension: {embeddings.shape[1]}")
    return embeddings
--- a/packages/leann-core/src/leann/embedding_server_manager.py
+++ b/packages/leann-core/src/leann/embedding_server_manager.py
@@ -1,14 +1,39 @@
 import threading
 import time
 import atexit
 import logging
 import os
 import socket
 import subprocess
 import sys
-import zmq
+import time
 import msgpack
 from pathlib import Path
-from typing import Optional
+
-import select
+import psutil
 # Set up logging based on environment variable
 LOG_LEVEL = os.getenv("LEANN_LOG_LEVEL", "WARNING").upper()
 logging.basicConfig(
    level=getattr(logging, LOG_LEVEL, logging.INFO),
    format="%(levelname)s - %(name)s - %(message)s",
 )
 logger = logging.getLogger(__name__)
 def _is_colab_environment() -> bool:
    """Check if we're running in Google Colab environment."""
    return "COLAB_GPU" in os.environ or "COLAB_TPU" in os.environ
 def _get_available_port(start_port: int = 5557) -> int:
    """Get an available port starting from start_port."""
    port = start_port
    while port < start_port + 100:  # Try up to 100 ports
        try:
            with socket.socket(socket.AF_INET, socket.SOCK_STREAM) as s:
                s.bind(("localhost", port))
                return port
        except OSError:
            port += 1
    raise RuntimeError(f"No available ports found in range {start_port}-{start_port + 100}")
 def _check_port(port: int) -> bool:
@@ -17,151 +42,135 @@ def _check_port(port: int) -> bool:
        return s.connect_ex(("localhost", port)) == 0
-def _check_server_meta_path(port: int, expected_meta_path: str) -> bool:
+def _check_process_matches_config(
    port: int, expected_model: str, expected_passages_file: str
 ) -> bool:
    """
-    Check if the existing server on the port is using the correct meta file.
+    Check if the process using the port matches our expected model and passages file.
-    Returns True if the server has the right meta path, False otherwise.
+    Returns True if matches, False otherwise.
    """
    try:
-        context = zmq.Context()
+        for proc in psutil.process_iter(["pid", "cmdline"]):
-        socket = context.socket(zmq.REQ)
+            if not _is_process_listening_on_port(proc, port):
-        socket.setsockopt(zmq.RCVTIMEO, 3000)  # 3 second timeout
+                continue
        socket.connect(f"tcp://localhost:{port}")
-        # Send a special control message to query the server's meta path
+            cmdline = proc.info["cmdline"]
-        control_request = ["__QUERY_META_PATH__"]
+            if not cmdline:
-        request_bytes = msgpack.packb(control_request)
+                continue
        socket.send(request_bytes)
-        # Wait for response
+            return _check_cmdline_matches_config(
-        response_bytes = socket.recv()
+                cmdline, port, expected_model, expected_passages_file
-        response = msgpack.unpackb(response_bytes)
+            )
        socket.close()
        context.term()
        # Check if the response contains the meta path and if it matches
        if isinstance(response, list) and len(response) > 0:
            server_meta_path = response[0]
            # Normalize paths for comparison
            expected_path = Path(expected_meta_path).resolve()
            server_path = Path(server_meta_path).resolve() if server_meta_path else None
            return server_path == expected_path
        logger.debug(f"No process found listening on port {port}")
        return False
    except Exception as e:
-        print(f"WARNING: Could not query server meta path on port {port}: {e}")
+        logger.warning(f"Could not check process on port {port}: {e}")
        return False
-def _update_server_meta_path(port: int, new_meta_path: str) -> bool:
+def _is_process_listening_on_port(proc, port: int) -> bool:
-    """
+    """Check if a process is listening on the given port."""
    Send a control message to update the server's meta path.
    Returns True if successful, False otherwise.
    """
    try:
-        context = zmq.Context()
+        connections = proc.net_connections()
-        socket = context.socket(zmq.REQ)
+        for conn in connections:
-        socket.setsockopt(zmq.RCVTIMEO, 5000)  # 5 second timeout
+            if conn.laddr.port == port and conn.status == psutil.CONN_LISTEN:
-        socket.connect(f"tcp://localhost:{port}")
+                return True
        # Send a control message to update the meta path
        control_request = ["__UPDATE_META_PATH__", new_meta_path]
        request_bytes = msgpack.packb(control_request)
        socket.send(request_bytes)
        # Wait for response
        response_bytes = socket.recv()
        response = msgpack.unpackb(response_bytes)
        socket.close()
        context.term()
        # Check if the update was successful
        if isinstance(response, list) and len(response) > 0:
            return response[0] == "SUCCESS"
        return False
-
+    except (psutil.NoSuchProcess, psutil.AccessDenied, psutil.ZombieProcess):
    except Exception as e:
        print(f"ERROR: Could not update server meta path on port {port}: {e}")
        return False
-def _check_server_model(port: int, expected_model: str) -> bool:
+def _check_cmdline_matches_config(
    cmdline: list, port: int, expected_model: str, expected_passages_file: str
 ) -> bool:
    """Check if command line matches our expected configuration."""
    cmdline_str = " ".join(cmdline)
    logger.debug(f"Found process on port {port}: {cmdline_str}")
    # Check if it's our embedding server
    is_embedding_server = any(
        server_type in cmdline_str
        for server_type in [
            "embedding_server",
            "leann_backend_diskann.embedding_server",
            "leann_backend_hnsw.hnsw_embedding_server",
        ]
    )
    if not is_embedding_server:
        logger.debug(f"Process on port {port} is not our embedding server")
        return False
    # Check model name
    model_matches = _check_model_in_cmdline(cmdline, expected_model)
    # Check passages file if provided
    passages_matches = _check_passages_in_cmdline(cmdline, expected_passages_file)
    result = model_matches and passages_matches
    logger.debug(
        f"model_matches: {model_matches}, passages_matches: {passages_matches}, overall: {result}"
    )
    return result
 def _check_model_in_cmdline(cmdline: list, expected_model: str) -> bool:
    """Check if the command line contains the expected model."""
    if "--model-name" not in cmdline:
        return False
    model_idx = cmdline.index("--model-name")
    if model_idx + 1 >= len(cmdline):
        return False
    actual_model = cmdline[model_idx + 1]
    return actual_model == expected_model
 def _check_passages_in_cmdline(cmdline: list, expected_passages_file: str) -> bool:
    """Check if the command line contains the expected passages file."""
    if "--passages-file" not in cmdline:
        return False  # Expected but not found
    passages_idx = cmdline.index("--passages-file")
    if passages_idx + 1 >= len(cmdline):
        return False
    actual_passages = cmdline[passages_idx + 1]
    expected_path = Path(expected_passages_file).resolve()
    actual_path = Path(actual_passages).resolve()
    return actual_path == expected_path
 def _find_compatible_port_or_next_available(
    start_port: int, model_name: str, passages_file: str, max_attempts: int = 100
 ) -> tuple[int, bool]:
    """
-    Check if the existing server on the port is using the correct embedding model.
+    Find a port that either has a compatible server or is available.
-    Returns True if the server has the right model, False otherwise.
+    Returns (port, is_compatible) where is_compatible indicates if we found a matching server.
    """
-    try:
+    for port in range(start_port, start_port + max_attempts):
-        context = zmq.Context()
+        if not _check_port(port):
-        socket = context.socket(zmq.REQ)
+            # Port is available
-        socket.setsockopt(zmq.RCVTIMEO, 3000)  # 3 second timeout
+            return port, False
        socket.connect(f"tcp://localhost:{port}")
-        # Send a special control message to query the server's model
+        # Port is in use, check if it's compatible
-        control_request = ["__QUERY_MODEL__"]
+        if _check_process_matches_config(port, model_name, passages_file):
-        request_bytes = msgpack.packb(control_request)
+            logger.info(f"Found compatible server on port {port}")
-        socket.send(request_bytes)
+            return port, True
        else:
            logger.info(f"Port {port} has incompatible server, trying next port...")
-        # Wait for response
+    raise RuntimeError(
-        response_bytes = socket.recv()
+        f"Could not find compatible or available port in range {start_port}-{start_port + max_attempts}"
-        response = msgpack.unpackb(response_bytes)
+    )
        socket.close()
        context.term()
        # Check if the response contains the model name and if it matches
        if isinstance(response, list) and len(response) > 0:
            server_model = response[0]
            return server_model == expected_model
        return False
    except Exception as e:
        print(f"WARNING: Could not query server model on port {port}: {e}")
        return False
 def _update_server_model(port: int, new_model: str) -> bool:
    """
    Send a control message to update the server's embedding model.
    Returns True if successful, False otherwise.
    """
    try:
        context = zmq.Context()
        socket = context.socket(zmq.REQ)
        socket.setsockopt(zmq.RCVTIMEO, 30000)  # 30 second timeout for model loading
        socket.setsockopt(zmq.SNDTIMEO, 5000)  # 5 second timeout for sending
        socket.connect(f"tcp://localhost:{port}")
        # Send a control message to update the model
        control_request = ["__UPDATE_MODEL__", new_model]
        request_bytes = msgpack.packb(control_request)
        socket.send(request_bytes)
        # Wait for response
        response_bytes = socket.recv()
        response = msgpack.unpackb(response_bytes)
        socket.close()
        context.term()
        # Check if the update was successful
        if isinstance(response, list) and len(response) > 0:
            return response[0] == "SUCCESS"
        return False
    except Exception as e:
        print(f"ERROR: Could not update server model on port {port}: {e}")
        return False
 class EmbeddingServerManager:
    """
-    A generic manager for handling the lifecycle of a backend-specific embedding server process.
+    A simplified manager for embedding server processes that avoids complex update mechanisms.
    """
    def __init__(self, backend_module_name: str):
@@ -173,248 +182,240 @@ class EmbeddingServerManager:
                                       e.g., "leann_backend_diskann.embedding_server"
        """
        self.backend_module_name = backend_module_name
-        self.server_process: Optional[subprocess.Popen] = None
+        self.server_process: subprocess.Popen | None = None
-        self.server_port: Optional[int] = None
+        self.server_port: int | None = None
-        atexit.register(self.stop_server)
+        self._atexit_registered = False
-    def start_server(self, port: int, model_name: str, embedding_mode: str = "sentence-transformers", **kwargs) -> bool:
+    def start_server(
-        """
+        self,
-        Starts the embedding server process.
+        port: int,
        model_name: str,
        embedding_mode: str = "sentence-transformers",
        **kwargs,
    ) -> tuple[bool, int]:
        """Start the embedding server."""
        passages_file = kwargs.get("passages_file")
-        Args:
+        # Check if we have a compatible server already running
-            port (int): The ZMQ port for the server.
+        if self._has_compatible_running_server(model_name, passages_file):
-            model_name (str): The name of the embedding model to use.
+            logger.info("Found compatible running server!")
-            **kwargs: Additional arguments for the server (e.g., passages_file, distance_metric, enable_warmup).
+            return True, port
-        Returns:
+        # For Colab environment, use a different strategy
-            bool: True if the server is started successfully or already running, False otherwise.
+        if _is_colab_environment():
-        """
+            logger.info("Detected Colab environment, using alternative startup strategy")
-        if self.server_process and self.server_process.poll() is None:
+            return self._start_server_colab(port, model_name, embedding_mode, **kwargs)
            # Even if we have a running process, check if model/meta path match
            if self.server_port is not None:
                port_in_use = _check_port(self.server_port)
                if port_in_use:
                    print(
                        f"INFO: Checking compatibility of existing server process (PID {self.server_process.pid})"
                    )
-                    # Check model compatibility
+        # Find a compatible port or next available
-                    model_matches = _check_server_model(self.server_port, model_name)
+        actual_port, is_compatible = _find_compatible_port_or_next_available(
-                    if model_matches:
+            port, model_name, passages_file
                        print(
                            f"✅ Existing server already using correct model: {model_name}"
                        )
                        # Still check meta path if provided
                        passages_file = kwargs.get("passages_file")
                        if passages_file and str(passages_file).endswith(
                            ".meta.json"
                        ):
                            meta_matches = _check_server_meta_path(
                                self.server_port, str(passages_file)
                            )
                            if not meta_matches:
                                print("⚠️  Updating meta path to: {passages_file}")
                                _update_server_meta_path(
                                    self.server_port, str(passages_file)
                                )
                        return True
                    else:
                        print(
                            f"⚠️  Existing server has different model. Attempting to update to: {model_name}"
                        )
                        if not _update_server_model(self.server_port, model_name):
                            print(
                                "❌ Failed to update existing server model. Restarting server..."
                            )
                            self.stop_server()
                            # Continue to start new server below
                        else:
                            print(
                                f"✅ Successfully updated existing server model to: {model_name}"
                            )
                            # Also check meta path if provided
                            passages_file = kwargs.get("passages_file")
                            if passages_file and str(passages_file).endswith(
                                ".meta.json"
                            ):
                                meta_matches = _check_server_meta_path(
                                    self.server_port, str(passages_file)
                                )
                                if not meta_matches:
                                    print("⚠️  Updating meta path to: {passages_file}")
                                    _update_server_meta_path(
                                        self.server_port, str(passages_file)
                                    )
                            return True
                else:
                    # Server process exists but port not responding - restart
                    print("⚠️  Server process exists but not responding. Restarting...")
                    self.stop_server()
                    # Continue to start new server below
            else:
                # No port stored - restart
                print("⚠️  No port information stored. Restarting server...")
                self.stop_server()
                # Continue to start new server below
        if _check_port(port):
            # Port is in use, check if it's using the correct meta file and model
            passages_file = kwargs.get("passages_file")
            print(f"INFO: Port {port} is in use. Checking server compatibility...")
            # Check model compatibility first
            model_matches = _check_server_model(port, model_name)
            if model_matches:
                print(
                    f"✅ Existing server on port {port} is using correct model: {model_name}"
                )
            else:
                print(
                    f"⚠️  Existing server on port {port} has different model. Attempting to update to: {model_name}"
                )
                if not _update_server_model(port, model_name):
                    raise RuntimeError(
                        f"❌ Failed to update server model to {model_name}. Consider using a different port."
                    )
                print(f"✅ Successfully updated server model to: {model_name}")
            # Check meta path compatibility if provided
            if passages_file and str(passages_file).endswith(".meta.json"):
                meta_matches = _check_server_meta_path(port, str(passages_file))
                if not meta_matches:
                    print(
                        f"⚠️  Existing server on port {port} has different meta path. Attempting to update..."
                    )
                    if not _update_server_meta_path(port, str(passages_file)):
                        raise RuntimeError(
                            "❌ Failed to update server meta path. This may cause data synchronization issues."
                        )
                    print(
                        f"✅ Successfully updated server meta path to: {passages_file}"
                    )
                else:
                    print(
                        f"✅ Existing server on port {port} is using correct meta path: {passages_file}"
                    )
            print(f"✅ Server on port {port} is compatible and ready to use.")
            return True
        print(
            f"INFO: Starting session-level embedding server for '{self.backend_module_name}'..."
        )
        if is_compatible:
            logger.info(f"Found compatible server on port {actual_port}")
            return True, actual_port
        # Start a new server
        return self._start_new_server(actual_port, model_name, embedding_mode, **kwargs)
    def _start_server_colab(
        self,
        port: int,
        model_name: str,
        embedding_mode: str = "sentence-transformers",
        **kwargs,
    ) -> tuple[bool, int]:
        """Start server with Colab-specific configuration."""
        # Try to find an available port
        try:
-            command = [
+            actual_port = _get_available_port(port)
-                sys.executable,
+        except RuntimeError:
-                "-m",
+            logger.error("No available ports found")
-                self.backend_module_name,
+            return False, port
                "--zmq-port",
                str(port),
                "--model-name",
                model_name,
            ]
-            # Add extra arguments for specific backends
+        logger.info(f"Starting server on port {actual_port} for Colab environment")
            if "passages_file" in kwargs and kwargs["passages_file"]:
                command.extend(["--passages-file", str(kwargs["passages_file"])])
            # if "distance_metric" in kwargs and kwargs["distance_metric"]:
            #     command.extend(["--distance-metric", kwargs["distance_metric"]])
            if embedding_mode != "sentence-transformers":
                command.extend(["--embedding-mode", embedding_mode])
            if "enable_warmup" in kwargs and not kwargs["enable_warmup"]:
                command.extend(["--disable-warmup"])
-            project_root = Path(__file__).parent.parent.parent.parent.parent
+        # Use a simpler startup strategy for Colab
-            print(f"INFO: Running command from project root: {project_root}")
+        command = self._build_server_command(actual_port, model_name, embedding_mode, **kwargs)
            print(f"INFO: Command: {' '.join(command)}")  # Debug: show actual command
-            self.server_process = subprocess.Popen(
+        try:
-                command,
+            # In Colab, we'll use a more direct approach
-                cwd=project_root,
+            self._launch_server_process_colab(command, actual_port)
-                stdout=subprocess.PIPE,
+            return self._wait_for_server_ready_colab(actual_port)
-                stderr=subprocess.STDOUT,  # Merge stderr into stdout for easier monitoring
+        except Exception as e:
-                text=True,
+            logger.error(f"Failed to start embedding server in Colab: {e}")
-                encoding="utf-8",
+            return False, actual_port
                bufsize=1,  # Line buffered
                universal_newlines=True,
            )
            self.server_port = port
            print(f"INFO: Server process started with PID: {self.server_process.pid}")
-            max_wait, wait_interval = 120, 0.5
+    def _has_compatible_running_server(self, model_name: str, passages_file: str) -> bool:
-            for _ in range(int(max_wait / wait_interval)):
+        """Check if we have a compatible running server."""
-                if _check_port(port):
+        if not (self.server_process and self.server_process.poll() is None and self.server_port):
                    print("✅ Embedding server is up and ready for this session.")
                    log_thread = threading.Thread(target=self._log_monitor, daemon=True)
                    log_thread.start()
                    return True
                if self.server_process.poll() is not None:
                    print(
                        "❌ ERROR: Server process terminated unexpectedly during startup."
                    )
                    self._print_recent_output()
                    return False
                time.sleep(wait_interval)
            print(
                f"❌ ERROR: Server process failed to start listening within {max_wait} seconds."
            )
            self.stop_server()
            return False
-        except Exception as e:
+        if _check_process_matches_config(self.server_port, model_name, passages_file):
-            print(f"❌ ERROR: Failed to start embedding server process: {e}")
+            logger.info(f"Existing server process (PID {self.server_process.pid}) is compatible")
-            return False
+            return True
        logger.info("Existing server process is incompatible. Should start a new server.")
        return False
    def _start_new_server(
        self, port: int, model_name: str, embedding_mode: str, **kwargs
    ) -> tuple[bool, int]:
        """Start a new embedding server on the given port."""
        logger.info(f"Starting embedding server on port {port}...")
        command = self._build_server_command(port, model_name, embedding_mode, **kwargs)
    def _print_recent_output(self):
        """Print any recent output from the server process."""
        if not self.server_process or not self.server_process.stdout:
            return
        try:
-            # Read any available output
+            self._launch_server_process(command, port)
-
+            return self._wait_for_server_ready(port)
            if select.select([self.server_process.stdout], [], [], 0)[0]:
                output = self.server_process.stdout.read()
                if output:
                    print(f"[{self.backend_module_name} OUTPUT]: {output}")
        except Exception as e:
-            print(f"Error reading server output: {e}")
+            logger.error(f"Failed to start embedding server: {e}")
            return False, port
-    def _log_monitor(self):
+    def _build_server_command(
-        """Monitors and prints the server's stdout and stderr."""
+        self, port: int, model_name: str, embedding_mode: str, **kwargs
-        if not self.server_process:
+    ) -> list:
-            return
+        """Build the command to start the embedding server."""
-        try:
+        command = [
-            if self.server_process.stdout:
+            sys.executable,
-                while True:
+            "-m",
-                    line = self.server_process.stdout.readline()
+            self.backend_module_name,
-                    if not line:
+            "--zmq-port",
-                        break
+            str(port),
-                    print(
+            "--model-name",
-                        f"[{self.backend_module_name} LOG]: {line.strip()}", flush=True
+            model_name,
-                    )
+        ]
-        except Exception as e:
+
-            print(f"Log monitor error: {e}")
+        if kwargs.get("passages_file"):
            # Convert to absolute path to ensure subprocess can find the file
            passages_file = Path(kwargs["passages_file"]).resolve()
            command.extend(["--passages-file", str(passages_file)])
        if embedding_mode != "sentence-transformers":
            command.extend(["--embedding-mode", embedding_mode])
        if kwargs.get("distance_metric"):
            command.extend(["--distance-metric", kwargs["distance_metric"]])
        return command
    def _launch_server_process(self, command: list, port: int) -> None:
        """Launch the server process."""
        project_root = Path(__file__).parent.parent.parent.parent.parent
        logger.info(f"Command: {' '.join(command)}")
        # Let server output go directly to console
        # The server will respect LEANN_LOG_LEVEL environment variable
        self.server_process = subprocess.Popen(
            command,
            cwd=project_root,
            stdout=None,  # Direct to console
            stderr=None,  # Direct to console
        )
        self.server_port = port
        logger.info(f"Server process started with PID: {self.server_process.pid}")
        # Register atexit callback only when we actually start a process
        if not self._atexit_registered:
            # Use a lambda to avoid issues with bound methods
            atexit.register(lambda: self.stop_server() if self.server_process else None)
            self._atexit_registered = True
    def _wait_for_server_ready(self, port: int) -> tuple[bool, int]:
        """Wait for the server to be ready."""
        max_wait, wait_interval = 120, 0.5
        for _ in range(int(max_wait / wait_interval)):
            if _check_port(port):
                logger.info("Embedding server is ready!")
                return True, port
            if self.server_process and self.server_process.poll() is not None:
                logger.error("Server terminated during startup.")
                return False, port
            time.sleep(wait_interval)
        logger.error(f"Server failed to start within {max_wait} seconds.")
        self.stop_server()
        return False, port
    def stop_server(self):
        """Stops the embedding server process if it's running."""
-        if self.server_process and self.server_process.poll() is None:
+        if not self.server_process:
-            print(
+            return
-                f"INFO: Terminating session server process (PID: {self.server_process.pid})..."
+
        if self.server_process.poll() is not None:
            # Process already terminated
            self.server_process = None
            return
        logger.info(
            f"Terminating server process (PID: {self.server_process.pid}) for backend {self.backend_module_name}..."
        )
        self.server_process.terminate()
        try:
            self.server_process.wait(timeout=3)
            logger.info(f"Server process {self.server_process.pid} terminated.")
        except subprocess.TimeoutExpired:
            logger.warning(
                f"Server process {self.server_process.pid} did not terminate gracefully within 3 seconds, killing it."
            )
-            self.server_process.terminate()
+            self.server_process.kill()
            try:
-                self.server_process.wait(timeout=5)
+                self.server_process.wait(timeout=2)
-                print("INFO: Server process terminated.")
+                logger.info(f"Server process {self.server_process.pid} killed successfully.")
            except subprocess.TimeoutExpired:
-                print(
+                logger.error(
-                    "WARNING: Server process did not terminate gracefully, killing it."
+                    f"Failed to kill server process {self.server_process.pid} - it may be hung"
                )
-                self.server_process.kill()
+                # Don't hang indefinitely
        # Clean up process resources to prevent resource tracker warnings
        try:
            self.server_process.wait()  # Ensure process is fully cleaned up
        except Exception:
            pass
        self.server_process = None
    def _launch_server_process_colab(self, command: list, port: int) -> None:
        """Launch the server process with Colab-specific settings."""
        logger.info(f"Colab Command: {' '.join(command)}")
        # In Colab, we need to be more careful about process management
        self.server_process = subprocess.Popen(
            command,
            stdout=subprocess.PIPE,
            stderr=subprocess.PIPE,
            text=True,
        )
        self.server_port = port
        logger.info(f"Colab server process started with PID: {self.server_process.pid}")
        # Register atexit callback
        if not self._atexit_registered:
            atexit.register(lambda: self.stop_server() if self.server_process else None)
            self._atexit_registered = True
    def _wait_for_server_ready_colab(self, port: int) -> tuple[bool, int]:
        """Wait for the server to be ready with Colab-specific timeout."""
        max_wait, wait_interval = 30, 0.5  # Shorter timeout for Colab
        for _ in range(int(max_wait / wait_interval)):
            if _check_port(port):
                logger.info("Colab embedding server is ready!")
                return True, port
            if self.server_process and self.server_process.poll() is not None:
                # Check for error output
                stdout, stderr = self.server_process.communicate()
                logger.error("Colab server terminated during startup.")
                logger.error(f"stdout: {stdout}")
                logger.error(f"stderr: {stderr}")
                return False, port
            time.sleep(wait_interval)
        logger.error(f"Colab server failed to start within {max_wait} seconds.")
        self.stop_server()
        return False, port
--- a/packages/leann-core/src/leann/interface.py
+++ b/packages/leann-core/src/leann/interface.py
@@ -1,15 +1,14 @@
 from abc import ABC, abstractmethod
 from typing import Any, Literal
 import numpy as np
 from typing import Dict, Any, List, Literal
 class LeannBackendBuilderInterface(ABC):
    """Backend interface for building indexes"""
    @abstractmethod
-    def build(
+    def build(self, data: np.ndarray, ids: list[str], index_path: str, **kwargs) -> None:
        self, data: np.ndarray, ids: List[str], index_path: str, **kwargs
    ) -> None:
        """Build index
        Args:
@@ -34,6 +33,11 @@ class LeannBackendSearcherInterface(ABC):
        """
        pass
    @abstractmethod
    def _ensure_server_running(self, passages_source_file: str, port: int | None, **kwargs) -> int:
        """Ensure server is running"""
        pass
    @abstractmethod
    def search(
        self,
@@ -44,9 +48,9 @@ class LeannBackendSearcherInterface(ABC):
        prune_ratio: float = 0.0,
        recompute_embeddings: bool = False,
        pruning_strategy: Literal["global", "local", "proportional"] = "global",
-        zmq_port: int = 5557,
+        zmq_port: int | None = None,
        **kwargs,
-    ) -> Dict[str, Any]:
+    ) -> dict[str, Any]:
        """Search for nearest neighbors
        Args:
@@ -57,7 +61,7 @@ class LeannBackendSearcherInterface(ABC):
            prune_ratio: Ratio of neighbors to prune via approximate distance (0.0-1.0)
            recompute_embeddings: Whether to fetch fresh embeddings from server vs use stored PQ codes
            pruning_strategy: PQ candidate selection strategy - "global" (default), "local", or "proportional"
-            zmq_port: ZMQ port for embedding server communication
+            zmq_port: ZMQ port for embedding server communication. Must be provided if recompute_embeddings is True.
            **kwargs: Backend-specific parameters
        Returns:
@@ -67,7 +71,10 @@ class LeannBackendSearcherInterface(ABC):
    @abstractmethod
    def compute_query_embedding(
-        self, query: str, zmq_port: int = 5557, use_server_if_available: bool = True
+        self,
        query: str,
        use_server_if_available: bool = True,
        zmq_port: int | None = None,
    ) -> np.ndarray:
        """Compute embedding for a query string
--- a/packages/leann-core/src/leann/mcp.py
+++ b/packages/leann-core/src/leann/mcp.py
@@ -0,0 +1,176 @@
 #!/usr/bin/env python3
 import json
 import subprocess
 import sys
 def handle_request(request):
    if request.get("method") == "initialize":
        return {
            "jsonrpc": "2.0",
            "id": request.get("id"),
            "result": {
                "capabilities": {"tools": {}},
                "protocolVersion": "2024-11-05",
                "serverInfo": {"name": "leann-mcp", "version": "1.0.0"},
            },
        }
    elif request.get("method") == "tools/list":
        return {
            "jsonrpc": "2.0",
            "id": request.get("id"),
            "result": {
                "tools": [
                    {
                        "name": "leann_search",
                        "description": """🔍 Search code using natural language - like having a coding assistant who knows your entire codebase!
 🎯 **Perfect for**:
 - "How does authentication work?" → finds auth-related code
 - "Error handling patterns" → locates try-catch blocks and error logic
 - "Database connection setup" → finds DB initialization code
 - "API endpoint definitions" → locates route handlers
 - "Configuration management" → finds config files and usage
 💡 **Pro tip**: Use this before making any changes to understand existing patterns and conventions.""",
                        "inputSchema": {
                            "type": "object",
                            "properties": {
                                "index_name": {
                                    "type": "string",
                                    "description": "Name of the LEANN index to search. Use 'leann_list' first to see available indexes.",
                                },
                                "query": {
                                    "type": "string",
                                    "description": "Search query - can be natural language (e.g., 'how to handle errors') or technical terms (e.g., 'async function definition')",
                                },
                                "top_k": {
                                    "type": "integer",
                                    "default": 5,
                                    "minimum": 1,
                                    "maximum": 20,
                                    "description": "Number of search results to return. Use 5-10 for focused results, 15-20 for comprehensive exploration.",
                                },
                                "complexity": {
                                    "type": "integer",
                                    "default": 32,
                                    "minimum": 16,
                                    "maximum": 128,
                                    "description": "Search complexity level. Use 16-32 for fast searches (recommended), 64+ for higher precision when needed.",
                                },
                            },
                            "required": ["index_name", "query"],
                        },
                    },
                    {
                        "name": "leann_status",
                        "description": "📊 Check the health and stats of your code indexes - like a medical checkup for your codebase knowledge!",
                        "inputSchema": {
                            "type": "object",
                            "properties": {
                                "index_name": {
                                    "type": "string",
                                    "description": "Optional: Name of specific index to check. If not provided, shows status of all indexes.",
                                }
                            },
                        },
                    },
                    {
                        "name": "leann_list",
                        "description": "📋 Show all your indexed codebases - your personal code library! Use this to see what's available for search.",
                        "inputSchema": {"type": "object", "properties": {}},
                    },
                ]
            },
        }
    elif request.get("method") == "tools/call":
        tool_name = request["params"]["name"]
        args = request["params"].get("arguments", {})
        try:
            if tool_name == "leann_search":
                # Validate required parameters
                if not args.get("index_name") or not args.get("query"):
                    return {
                        "jsonrpc": "2.0",
                        "id": request.get("id"),
                        "result": {
                            "content": [
                                {
                                    "type": "text",
                                    "text": "Error: Both index_name and query are required",
                                }
                            ]
                        },
                    }
                # Build simplified command
                cmd = [
                    "leann",
                    "search",
                    args["index_name"],
                    args["query"],
                    f"--top-k={args.get('top_k', 5)}",
                    f"--complexity={args.get('complexity', 32)}",
                ]
                result = subprocess.run(cmd, capture_output=True, text=True)
            elif tool_name == "leann_status":
                if args.get("index_name"):
                    # Check specific index status - for now, we'll use leann list and filter
                    result = subprocess.run(["leann", "list"], capture_output=True, text=True)
                    # We could enhance this to show more detailed status per index
                else:
                    # Show all indexes status
                    result = subprocess.run(["leann", "list"], capture_output=True, text=True)
            elif tool_name == "leann_list":
                result = subprocess.run(["leann", "list"], capture_output=True, text=True)
            return {
                "jsonrpc": "2.0",
                "id": request.get("id"),
                "result": {
                    "content": [
                        {
                            "type": "text",
                            "text": result.stdout
                            if result.returncode == 0
                            else f"Error: {result.stderr}",
                        }
                    ]
                },
            }
        except Exception as e:
            return {
                "jsonrpc": "2.0",
                "id": request.get("id"),
                "error": {"code": -1, "message": str(e)},
            }
 def main():
    for line in sys.stdin:
        try:
            request = json.loads(line.strip())
            response = handle_request(request)
            if response:
                print(json.dumps(response))
                sys.stdout.flush()
        except Exception as e:
            error_response = {
                "jsonrpc": "2.0",
                "id": None,
                "error": {"code": -1, "message": str(e)},
            }
            print(json.dumps(error_response))
            sys.stdout.flush()
 if __name__ == "__main__":
    main()
--- a/packages/leann-core/src/leann/registry.py
+++ b/packages/leann-core/src/leann/registry.py
@@ -1,36 +1,41 @@
 # packages/leann-core/src/leann/registry.py
 from typing import Dict, TYPE_CHECKING
 import importlib
 import importlib.metadata
 from typing import TYPE_CHECKING
 if TYPE_CHECKING:
    from leann.interface import LeannBackendFactoryInterface
-BACKEND_REGISTRY: Dict[str, 'LeannBackendFactoryInterface'] = {}
+BACKEND_REGISTRY: dict[str, "LeannBackendFactoryInterface"] = {}
 def register_backend(name: str):
    """A decorator to register a new backend class."""
    def decorator(cls):
        print(f"INFO: Registering backend '{name}'")
        BACKEND_REGISTRY[name] = cls
        return cls
    return decorator
 def autodiscover_backends():
    """Automatically discovers and imports all 'leann-backend-*' packages."""
-    print("INFO: Starting backend auto-discovery...")
+    # print("INFO: Starting backend auto-discovery...")
    discovered_backends = []
    for dist in importlib.metadata.distributions():
-        dist_name = dist.metadata['name']
+        dist_name = dist.metadata["name"]
-        if dist_name.startswith('leann-backend-'):
+        if dist_name.startswith("leann-backend-"):
-            backend_module_name = dist_name.replace('-', '_')
+            backend_module_name = dist_name.replace("-", "_")
            discovered_backends.append(backend_module_name)
-    for backend_module_name in sorted(discovered_backends): # sort for deterministic loading
+    for backend_module_name in sorted(discovered_backends):  # sort for deterministic loading
        try:
            importlib.import_module(backend_module_name)
            # Registration message is printed by the decorator
-        except ImportError as e:
+        except ImportError:
-            print(f"WARN: Could not import backend module '{backend_module_name}': {e}")
+            # print(f"WARN: Could not import backend module '{backend_module_name}': {e}")
-    print("INFO: Backend auto-discovery finished.")
+            pass
    # print("INFO: Backend auto-discovery finished.")
--- a/packages/leann-core/src/leann/searcher_base.py
+++ b/packages/leann-core/src/leann/searcher_base.py
@@ -1,8 +1,7 @@
 import json
 import pickle
 from abc import ABC, abstractmethod
 from pathlib import Path
-from typing import Dict, Any, Literal
+from typing import Any, Literal
 import numpy as np
@@ -39,60 +38,56 @@ class BaseSearcher(LeannBackendSearcherInterface, ABC):
        self.embedding_model = self.meta.get("embedding_model")
        if not self.embedding_model:
-            print(
+            print("WARNING: embedding_model not found in meta.json. Recompute will fail.")
                "WARNING: embedding_model not found in meta.json. Recompute will fail."
            )
-        self.label_map = self._load_label_map()
+        self.embedding_mode = self.meta.get("embedding_mode", "sentence-transformers")
        self.embedding_server_manager = EmbeddingServerManager(
-            backend_module_name=backend_module_name
+            backend_module_name=backend_module_name,
        )
-    def _load_meta(self) -> Dict[str, Any]:
+    def _load_meta(self) -> dict[str, Any]:
        """Loads the metadata file associated with the index."""
        # This is the corrected logic for finding the meta file.
        meta_path = self.index_dir / f"{self.index_path.name}.meta.json"
        if not meta_path.exists():
            raise FileNotFoundError(f"Leann metadata file not found at {meta_path}")
-        with open(meta_path, "r", encoding="utf-8") as f:
+        with open(meta_path, encoding="utf-8") as f:
            return json.load(f)
-    def _load_label_map(self) -> Dict[int, str]:
+    def _ensure_server_running(self, passages_source_file: str, port: int, **kwargs) -> int:
        """Loads the mapping from integer IDs to string IDs."""
        label_map_file = self.index_dir / "leann.labels.map"
        if not label_map_file.exists():
            raise FileNotFoundError(f"Label map file not found: {label_map_file}")
        with open(label_map_file, "rb") as f:
            return pickle.load(f)
    def _ensure_server_running(
        self, passages_source_file: str, port: int, **kwargs
    ) -> None:
        """
        Ensures the embedding server is running if recompute is needed.
        This is a helper for subclasses.
        """
        if not self.embedding_model:
-            raise ValueError(
+            raise ValueError("Cannot use recompute mode without 'embedding_model' in meta.json.")
                "Cannot use recompute mode without 'embedding_model' in meta.json."
            )
-        embedding_mode = self.meta.get("embedding_mode", "sentence-transformers")
+        # Get distance_metric from meta if not provided in kwargs
        distance_metric = (
            kwargs.get("distance_metric")
            or self.meta.get("backend_kwargs", {}).get("distance_metric")
            or "mips"
        )
-        server_started = self.embedding_server_manager.start_server(
+        server_started, actual_port = self.embedding_server_manager.start_server(
            port=port,
            model_name=self.embedding_model,
            embedding_mode=self.embedding_mode,
            passages_file=passages_source_file,
-            distance_metric=kwargs.get("distance_metric"),
+            distance_metric=distance_metric,
            embedding_mode=embedding_mode,
            enable_warmup=kwargs.get("enable_warmup", False),
        )
        if not server_started:
-            raise RuntimeError(f"Failed to start embedding server on port {port}")
+            raise RuntimeError(f"Failed to start embedding server on port {actual_port}")
        return actual_port
    def compute_query_embedding(
-        self, query: str, zmq_port: int = 5557, use_server_if_available: bool = True
+        self,
        query: str,
        use_server_if_available: bool = True,
        zmq_port: int = 5557,
    ) -> np.ndarray:
        """
        Compute embedding for a query string.
@@ -106,12 +101,19 @@ class BaseSearcher(LeannBackendSearcherInterface, ABC):
            Query embedding as numpy array
        """
        # Try to use embedding server if available and requested
-        if (
+        if use_server_if_available:
            use_server_if_available
            and self.embedding_server_manager
            and self.embedding_server_manager.server_process
        ):
            try:
                # TODO: Maybe we can directly use this port here?
                # For this internal method, it's ok to assume that the server is running
                # on that port?
                # Ensure we have a server with passages_file for compatibility
                passages_source_file = self.index_dir / f"{self.index_path.name}.meta.json"
                # Convert to absolute path to ensure server can find it
                zmq_port = self._ensure_server_running(
                    str(passages_source_file.resolve()), zmq_port
                )
                return self._compute_embedding_via_server([query], zmq_port)[
                    0:1
                ]  # Return (1, D) shape
@@ -120,15 +122,15 @@ class BaseSearcher(LeannBackendSearcherInterface, ABC):
                print("⏭️ Falling back to direct model loading...")
        # Fallback to direct computation
-        from .api import compute_embeddings
+        from .embedding_compute import compute_embeddings
        embedding_mode = self.meta.get("embedding_mode", "sentence-transformers")
        return compute_embeddings([query], self.embedding_model, embedding_mode)
    def _compute_embedding_via_server(self, chunks: list, zmq_port: int) -> np.ndarray:
        """Compute embeddings using the ZMQ embedding server."""
        import zmq
        import msgpack
        import zmq
        try:
            context = zmq.Context()
@@ -167,9 +169,9 @@ class BaseSearcher(LeannBackendSearcherInterface, ABC):
        prune_ratio: float = 0.0,
        recompute_embeddings: bool = False,
        pruning_strategy: Literal["global", "local", "proportional"] = "global",
-        zmq_port: int = 5557,
+        zmq_port: int | None = None,
        **kwargs,
-    ) -> Dict[str, Any]:
+    ) -> dict[str, Any]:
        """
        Search for the top_k nearest neighbors of the query vector.
@@ -181,7 +183,7 @@ class BaseSearcher(LeannBackendSearcherInterface, ABC):
            prune_ratio: Ratio of neighbors to prune via approximate distance (0.0-1.0)
            recompute_embeddings: Whether to fetch fresh embeddings from server vs use stored PQ codes
            pruning_strategy: PQ candidate selection strategy - "global" (default), "local", or "proportional"
-            zmq_port: ZMQ port for embedding server communication
+            zmq_port: ZMQ port for embedding server communication. Must be provided if recompute_embeddings is True.
            **kwargs: Backend-specific parameters (e.g., batch_size, dedup_node_dis, etc.)
        Returns:
--- a/packages/leann-mcp/README.md
+++ b/packages/leann-mcp/README.md
@@ -0,0 +1,91 @@
 # 🔥 LEANN Claude Code Integration
 Transform your development workflow with intelligent code assistance using LEANN's semantic search directly in Claude Code.
 ## Prerequisites
 **Step 1:** First, complete the basic LEANN installation following the [📦 Installation guide](../../README.md#installation) in the root README:
 ```bash
 uv venv
 source .venv/bin/activate
 uv pip install leann
 ```
 **Step 2:** Install LEANN globally for MCP integration:
 ```bash
 uv tool install leann-core
 ```
 This makes the `leann` command available system-wide, which `leann_mcp` requires.
 ## 🚀 Quick Setup
 Add the LEANN MCP server to Claude Code:
 ```bash
 claude mcp add leann-server -- leann_mcp
 ```
 ## 🛠️ Available Tools
 Once connected, you'll have access to these powerful semantic search tools in Claude Code:
 - **`leann_list`** - List all available indexes across your projects
 - **`leann_search`** - Perform semantic searches across code and documents
 - **`leann_ask`** - Ask natural language questions and get AI-powered answers from your codebase
 ## 🎯 Quick Start Example
 ```bash
 # Build an index for your project (change to your actual path)
 leann build my-project --docs ./
 # Start Claude Code
 claude
 ```
 **Try this in Claude Code:**
 ```
 Help me understand this codebase. List available indexes and search for authentication patterns.
 ```
 <p align="center">
  <img src="../../assets/claude_code_leann.png" alt="LEANN in Claude Code" width="80%">
 </p>
 ## 🧠 How It Works
 The integration consists of three key components working seamlessly together:
 - **`leann`** - Core CLI tool for indexing and searching (installed globally via `uv tool install`)
 - **`leann_mcp`** - MCP server that wraps `leann` commands for Claude Code integration
 - **Claude Code** - Calls `leann_mcp`, which executes `leann` commands and returns intelligent results
 ## 📁 File Support
 LEANN understands **30+ file types** including:
 - **Programming**: Python, JavaScript, TypeScript, Java, Go, Rust, C++, C#
 - **Data**: SQL, YAML, JSON, CSV, XML
 - **Documentation**: Markdown, TXT, PDF
 - **And many more!**
 ## 💾 Storage & Organization
 - **Project indexes**: Stored in `.leann/` directory (just like `.git`)
 - **Global registry**: Project tracking at `~/.leann/projects.json`
 - **Multi-project support**: Switch between different codebases seamlessly
 - **Portable**: Transfer indexes between machines with minimal overhead
 ## 🗑️ Uninstalling
 To remove the LEANN MCP server from Claude Code:
 ```bash
 claude mcp remove leann-server
 ```
 To remove LEANN
 ```
 uv pip uninstall leann leann-backend-hnsw leann-core
 ```
--- a/packages/leann/README.md
+++ b/packages/leann/README.md
@@ -0,0 +1,36 @@
 # LEANN - The smallest vector index in the world
 LEANN is a revolutionary vector database that democratizes personal AI. Transform your laptop into a powerful RAG system that can index and search through millions of documents while using **97% less storage** than traditional solutions **without accuracy loss**.
 ## Installation
 ```bash
 # Default installation (includes both HNSW and DiskANN backends)
 uv pip install leann
 ```
 ## Quick Start
 ```python
 from leann import LeannBuilder, LeannSearcher, LeannChat
 from pathlib import Path
 INDEX_PATH = str(Path("./").resolve() / "demo.leann")
 # Build an index (choose backend: "hnsw" or "diskann")
 builder = LeannBuilder(backend_name="hnsw")  # or "diskann" for large-scale deployments
 builder.add_text("LEANN saves 97% storage compared to traditional vector databases.")
 builder.add_text("Tung Tung Tung Sahur called—they need their banana‑crocodile hybrid back")
 builder.build_index(INDEX_PATH)
 # Search
 searcher = LeannSearcher(INDEX_PATH)
 results = searcher.search("fantastical AI-generated creatures", top_k=1)
 # Chat with your data
 chat = LeannChat(INDEX_PATH, llm_config={"type": "hf", "model": "Qwen/Qwen3-0.6B"})
 response = chat.ask("How much storage does LEANN save?", top_k=1)
 ```
 ## License
 MIT License
--- a/packages/leann/init.py
+++ b/packages/leann/init.py
@@ -0,0 +1,12 @@
 """
 LEANN - Low-storage Embedding Approximation for Neural Networks
 A revolutionary vector database that democratizes personal AI.
 """
 __version__ = "0.1.0"
 # Re-export main API from leann-core
 from leann_core import LeannBuilder, LeannChat, LeannSearcher
 __all__ = ["LeannBuilder", "LeannChat", "LeannSearcher"]
--- a/packages/leann/pyproject.toml
+++ b/packages/leann/pyproject.toml
@@ -0,0 +1,39 @@
 [build-system]
 requires = ["setuptools>=61.0"]
 build-backend = "setuptools.build_meta"
 [project]
 name = "leann"
 version = "0.2.6"
 description = "LEANN - The smallest vector index in the world. RAG Everything with LEANN!"
 readme = "README.md"
 requires-python = ">=3.9"
 license = { text = "MIT" }
 authors = [
    { name = "LEANN Team" }
 ]
 keywords = ["vector-database", "rag", "embeddings", "search", "ai"]
 classifiers = [
    "Development Status :: 4 - Beta",
    "Intended Audience :: Developers",
    "License :: OSI Approved :: MIT License",
    "Programming Language :: Python :: 3",
    "Programming Language :: Python :: 3.9",
    "Programming Language :: Python :: 3.10",
    "Programming Language :: Python :: 3.11",
    "Programming Language :: Python :: 3.12",
 ]
 # Default installation: core + hnsw + diskann
 dependencies = [
    "leann-core>=0.1.0",
    "leann-backend-hnsw>=0.1.0",
    "leann-backend-diskann>=0.1.0",
 ]
 [project.optional-dependencies]
 # All backends now included by default
 [project.urls]
 Repository = "https://github.com/yichuan-w/LEANN"
 Issues = "https://github.com/yichuan-w/LEANN/issues"
--- a/packages/wechat-exporter/main.py
+++ b/packages/wechat-exporter/main.py
@@ -1,22 +1,23 @@
 import json
 import typer
 from pathlib import Path
 import requests
 from tqdm import tqdm
 import xml.etree.ElementTree as ET
 from typing_extensions import Annotated
 import sqlite3
 import xml.etree.ElementTree as ElementTree
 from pathlib import Path
 from typing import Annotated
 import requests
 import typer
 from tqdm import tqdm
 app = typer.Typer()
 def get_safe_path(s: str) -> str:
    """
    Remove invalid characters to sanitize a path.
    :param s: str to sanitize
    :returns: sanitized str
    """
-    ban_chars = "\\  /  :  *  ?  \"  '  <  >  |  $  \r  \n".replace(
+    ban_chars = "\\  /  :  *  ?  \"  '  <  >  |  $  \r  \n".replace(" ", "")
        ' ', '')
    for i in ban_chars:
        s = s.replace(i, "")
    return s
@@ -25,36 +26,40 @@ def get_safe_path(s: str) -> str:
 def process_history(history: str):
    if history.startswith("<?xml") or history.startswith("<msg>"):
        try:
-            root = ET.fromstring(history)
+            root = ElementTree.fromstring(history)
-            title = root.find('.//title').text if root.find('.//title') is not None else None
+            title = root.find(".//title").text if root.find(".//title") is not None else None
-            quoted = root.find('.//refermsg/content').text if root.find('.//refermsg/content') is not None else None
+            quoted = (
                root.find(".//refermsg/content").text
                if root.find(".//refermsg/content") is not None
                else None
            )
            if title and quoted:
-                return {
+                return {"title": title, "quoted": process_history(quoted)}
                    "title": title,
                    "quoted": process_history(quoted)
                }
            if title:
                return title
        except Exception:
            return history
    return history
 def get_message(history: dict | str):
    if isinstance(history, dict):
-        if 'title' in history:
+        if "title" in history:
-            return history['title']
+            return history["title"]
    else:
        return history
 def export_chathistory(user_id: str):
-    res = requests.get("http://localhost:48065/wechat/chatlog", params={
+    res = requests.get(
-        "userId": user_id,
+        "http://localhost:48065/wechat/chatlog",
-        "count": 100000
+        params={"userId": user_id, "count": 100000},
-    }).json()
+    ).json()
-    for i in range(len(res['chatLogs'])):
+    for i in range(len(res["chatLogs"])):
-        res['chatLogs'][i]['content'] = process_history(res['chatLogs'][i]['content'])
+        res["chatLogs"][i]["content"] = process_history(res["chatLogs"][i]["content"])
-        res['chatLogs'][i]['message'] = get_message(res['chatLogs'][i]['content'])
+        res["chatLogs"][i]["message"] = get_message(res["chatLogs"][i]["content"])
-    return res['chatLogs']
+    return res["chatLogs"]
@app.command()
 def export_all(dest: Annotated[Path, typer.Argument(help="Destination path to export to.")]):
@@ -64,7 +69,7 @@ def export_all(dest: Annotated[Path, typer.Argument(help="Destination path to ex
    if not dest.is_dir():
        if not dest.exists():
            inp = typer.prompt("Destination path does not exist, create it? (y/n)")
-            if inp.lower() == 'y':
+            if inp.lower() == "y":
                dest.mkdir(parents=True)
            else:
                typer.echo("Aborted.", err=True)
@@ -77,12 +82,12 @@ def export_all(dest: Annotated[Path, typer.Argument(help="Destination path to ex
    exported_count = 0
    for user in tqdm(all_users):
        try:
-            usr_chatlog = export_chathistory(user['arg'])
+            usr_chatlog = export_chathistory(user["arg"])
            # Only write file if there are messages
            if len(usr_chatlog) > 0:
-                out_path = dest/get_safe_path((user['title'] or "")+"-"+user['arg']+'.json')
+                out_path = dest / get_safe_path((user["title"] or "") + "-" + user["arg"] + ".json")
-                with open(out_path, 'w', encoding='utf-8') as f:
+                with open(out_path, "w", encoding="utf-8") as f:
                    json.dump(usr_chatlog, f, ensure_ascii=False, indent=2)
                exported_count += 1
        except Exception as e:
@@ -91,23 +96,43 @@ def export_all(dest: Annotated[Path, typer.Argument(help="Destination path to ex
    print(f"Exported {exported_count} users' chat history to {dest} in json.")
@app.command()
-def export_sqlite(dest: Annotated[Path, typer.Argument(help="Destination path to export to.")] = Path("chatlog.db")):
+def export_sqlite(
    dest: Annotated[Path, typer.Argument(help="Destination path to export to.")] = Path(
        "chatlog.db"
    ),
 ):
    """
    Export all users' chat history to a sqlite database.
    """
    connection = sqlite3.connect(dest)
    cursor = connection.cursor()
-    cursor.execute("CREATE TABLE IF NOT EXISTS chatlog (id INTEGER PRIMARY KEY AUTOINCREMENT, with_id TEXT, from_user TEXT, to_user TEXT, message TEXT, timest DATETIME, auxiliary TEXT)")
+    cursor.execute(
        "CREATE TABLE IF NOT EXISTS chatlog (id INTEGER PRIMARY KEY AUTOINCREMENT, with_id TEXT, from_user TEXT, to_user TEXT, message TEXT, timest DATETIME, auxiliary TEXT)"
    )
    cursor.execute("CREATE INDEX IF NOT EXISTS chatlog_with_id_index ON chatlog (with_id)")
    cursor.execute("CREATE TABLE iF NOT EXISTS users (id TEXT PRIMARY KEY, name TEXT)")
    all_users = requests.get("http://localhost:48065/wechat/allcontacts").json()
    for user in tqdm(all_users):
-        cursor.execute("INSERT OR IGNORE INTO users (id, name) VALUES (?, ?)", (user['arg'], user['title']))
+        cursor.execute(
-        usr_chatlog = export_chathistory(user['arg'])
+            "INSERT OR IGNORE INTO users (id, name) VALUES (?, ?)",
            (user["arg"], user["title"]),
        )
        usr_chatlog = export_chathistory(user["arg"])
        for msg in usr_chatlog:
-            cursor.execute("INSERT INTO chatlog (with_id, from_user, to_user, message, timest, auxiliary) VALUES (?, ?, ?, ?, ?, ?)", (user['arg'], msg['fromUser'], msg['toUser'], msg['message'], msg['createTime'], str(msg['content'])))
+            cursor.execute(
                "INSERT INTO chatlog (with_id, from_user, to_user, message, timest, auxiliary) VALUES (?, ?, ?, ?, ?, ?)",
                (
                    user["arg"],
                    msg["fromUser"],
                    msg["toUser"],
                    msg["message"],
                    msg["createTime"],
                    str(msg["content"]),
                ),
            )
    connection.commit()
--- a/pyproject.toml
+++ b/pyproject.toml
@@ -5,7 +5,7 @@ build-backend = "setuptools.build_meta"
 [project]
 name = "leann-workspace"
 version = "0.1.0"
-requires-python = ">=3.10"
+requires-python = ">=3.9"
 dependencies = [
    "leann-core",
@@ -25,32 +25,62 @@ dependencies = [
    "requests>=2.25.0",
    "sentence-transformers>=2.2.0",
    "openai>=1.0.0",
    # PDF parsing dependencies - essential for document processing
    "PyPDF2>=3.0.0",
    "pdfplumber>=0.11.0",
    "pymupdf>=1.26.0",
    "pypdfium2>=4.30.0",
    # LlamaIndex core and readers - updated versions
    "llama-index>=0.12.44",
-    "llama-index-readers-docling",
+    "llama-index-readers-file>=0.4.0", # Essential for PDF parsing
-    "llama-index-node-parser-docling",
+    # "llama-index-readers-docling",  # Requires Python >= 3.10
-    "ipykernel==6.29.5",
+    # "llama-index-node-parser-docling",  # Requires Python >= 3.10
    "msgpack>=1.1.1",
    "llama-index-vector-stores-faiss>=0.4.0",
    "llama-index-embeddings-huggingface>=0.5.5",
-    "mlx>=0.26.3",
+    # Other dependencies
-    "mlx-lm>=0.26.0",
+    "ipykernel==6.29.5",
    "msgpack>=1.1.1",
    "mlx>=0.26.3; sys_platform == 'darwin'",
    "mlx-lm>=0.26.0; sys_platform == 'darwin'",
    "psutil>=5.8.0",
    "pathspec>=0.12.1",
    "nbconvert>=7.16.6",
    "gitignore-parser>=0.1.12",
 ]
 [project.optional-dependencies]
 dev = [
    "pytest>=7.0",
    "pytest-cov>=4.0",
    "pytest-xdist>=3.0",  # For parallel test execution
    "black>=23.0",
    "ruff>=0.1.0",
    "matplotlib",
    "huggingface-hub>=0.20.0",
    "pre-commit>=3.5.0",
 ]
 test = [
    "pytest>=7.0",
    "pytest-timeout>=2.0",
    "llama-index-core>=0.12.0",
    "llama-index-readers-file>=0.4.0",
    "python-dotenv>=1.0.0",
    "sentence-transformers>=2.2.0",
 ]
 diskann = [
    "leann-backend-diskann",
 ]
 # Add a new optional dependency group for document processing
 documents = [
    "beautifulsoup4>=4.13.0",  # For HTML parsing
    "python-docx>=0.8.11",     # For Word documents
    "openpyxl>=3.1.0",         # For Excel files
    "pandas>=2.2.0",           # For data processing
 ]
 [tool.setuptools]
 py-modules = []
@@ -59,3 +89,79 @@ py-modules = []
 leann-core = { path = "packages/leann-core", editable = true }
 leann-backend-diskann = { path = "packages/leann-backend-diskann", editable = true }
 leann-backend-hnsw = { path = "packages/leann-backend-hnsw", editable = true }
 [tool.ruff]
 target-version = "py310"
 line-length = 100
 extend-exclude = [
    "third_party",
    "*.egg-info",
    "__pycache__",
    ".git",
    ".venv",
 ]
 [tool.ruff.lint]
 select = [
    "E",      # pycodestyle errors
    "W",      # pycodestyle warnings
    "F",      # pyflakes
    "I",      # isort
    "B",      # flake8-bugbear
    "C4",     # flake8-comprehensions
    "UP",     # pyupgrade
    "N",      # pep8-naming
    "RUF",    # ruff-specific rules
 ]
 ignore = [
    "E501",   # line too long (handled by formatter)
    "B008",   # do not perform function calls in argument defaults
    "B904",   # raise without from
    "N812",   # lowercase imported as non-lowercase
    "N806",   # variable in function should be lowercase
    "RUF012", # mutable class attributes should be annotated with typing.ClassVar
 ]
 [tool.ruff.lint.per-file-ignores]
 "test/**/*.py" = ["E402"]      # module level import not at top of file (common in tests)
 "examples/**/*.py" = ["E402"]  # module level import not at top of file (common in examples)
 [tool.ruff.format]
 quote-style = "double"
 indent-style = "space"
 skip-magic-trailing-comma = false
 line-ending = "auto"
 [dependency-groups]
 dev = [
    "ruff>=0.12.4",
 ]
 [tool.lychee]
 accept = ["200", "403", "429", "503"]
 timeout = 20
 max_retries = 2
 exclude = ["localhost", "127.0.0.1", "example.com"]
 exclude_path = [".git/", ".venv/", "__pycache__/", "third_party/"]
 scheme = ["https", "http"]
 [tool.pytest.ini_options]
 testpaths = ["tests"]
 python_files = ["test_*.py"]
 python_classes = ["Test*"]
 python_functions = ["test_*"]
 markers = [
    "slow: marks tests as slow (deselect with '-m \"not slow\"')",
    "openai: marks tests that require OpenAI API key",
 ]
 timeout = 600
 addopts = [
    "-v",
    "--tb=short",
    "--strict-markers",
    "--disable-warnings",
 ]
 env = [
    "HF_HUB_DISABLE_SYMLINKS=1",
    "TOKENIZERS_PARALLELISM=false",
 ]
--- a/research/micro/analyze_HNSW.py
+++ b/research/micro/analyze_HNSW.py
@@ -1,12 +0,0 @@
 import faiss
 hnsw_index = faiss.read_index("/opt/dlami/nvme/scaling_out/indices/rpj_wiki/facebook/contriever-msmarco/hnsw/hnsw_IP_M30_efC128.index", faiss.IO_FLAG_ONDISK_SAME_DIR)
 # print total number of nodes
 print(hnsw_index.ntotal)
 # print  stats of the graph
 print(hnsw_index.hnsw.print_neighbor_stats(0))
 # save_degree_distribution
 hnsw_index.hnsw.save_degree_distribution(0, "degree_distribution_HNSW_M30.txt")
--- a/research/micro/analyze_NSG.py
+++ b/research/micro/analyze_NSG.py
@@ -1,11 +0,0 @@
 import faiss
 nsg_index = faiss.read_index("/opt/dlami/nvme/scaling_out/indices/rpj_wiki/facebook/contriever-msmarco/nsg_R16.index", faiss.IO_FLAG_ONDISK_SAME_DIR)
 # print total number of nodes
 print(nsg_index.ntotal)
 # print stats of the graph
 print(nsg_index.nsg.print_neighbor_stats(0))
 # save degree distribution
 nsg_index.nsg.save_degree_distribution("degree_distribution_NSG_R60.txt")
--- a/research/micro/bnbtest.py
+++ b/research/micro/bnbtest.py
@@ -1,63 +0,0 @@
 import torch
 import torch.nn as nn
 import time
 # import bitsandbytes as bnb
 from bitsandbytes.nn import Linear8bitLt
 # set default to half
 import torch
 torch.set_default_dtype(torch.float16)
 M = 2048
 N = 2048
 bsz =  2048
 import torch_int
 from torch_int.nn.linear import W8A8BFP32OFP32Linear, W8A8B8O8Linear, W8A8B8O8LinearReLU
 fp16_model = nn.Sequential(
    nn.Linear(M, N),
    # nn.Linear(2048, 2048)
 )
 int8_model = nn.Sequential(
    Linear8bitLt(M, N, has_fp16_weights=False),
    # Linear8bitLt(2048, 2048, has_fp16_weights=False)
 )
 int8_model.load_state_dict(fp16_model.state_dict())
 int8_model = int8_model.to(0) # Quantization happens here
 fp16_model = fp16_model.to(0) # Move fp16 model to GPU as well
 # Create random input tensor
 input_tensor = torch.randn(bsz, M, device=0)  # Batch of 1000 vectors
 # Speed test function
 def speed_test(model, input_tensor, name, num_iterations=100):
    # Warmup
    for _ in range(10):
        _ = model(input_tensor)
    # Actual timing
    torch.cuda.synchronize()
    start_time = time.time()
    for _ in range(num_iterations):
        _ = model(input_tensor)
    torch.cuda.synchronize()
    end_time = time.time()
    avg_time = (end_time - start_time) / num_iterations
    print(f"{name} model: {avg_time:.6f} seconds per iteration")
    return avg_time
 # Run speed tests
 with torch.no_grad():  # Disable gradient calculation for inference
    fp16_time = speed_test(fp16_model, input_tensor, "FP16")
    int8_time = speed_test(int8_model, input_tensor, "INT8")
    # Calculate speedup
    speedup = fp16_time / int8_time
    print(f"INT8 is {speedup:.2f}x faster than FP16")
--- a/research/micro/data/transformer-batching-microbenchmarks.csv
+++ b/research/micro/data/transformer-batching-microbenchmarks.csv
@@ -1,89 +0,0 @@
 n,d,seqlen,bs,latency,h,flop,io,intensity,throughput,series
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 3,256,1,512,4.9680950036205655e-05,768,603979776,55.40377142534654,10901419.893658841,12157170415618.898,dense
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 3,256,1,128,5.0662328255350016e-05,768,150994944,31.046026784880404,4863583.512513602,2980418571348.519,dense
 3,256,1,64,4.475009253945481e-05,768,75497472,30.75426042497223,2454862.219307235,1687090857598.4766,dense
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 3,256,1,4,5.053219391083726e-05,768,4718592,23.58765586356967,200044.97383259286,93377936614.54384,dense
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 12,256,256,512,0.036310761444444443,3072,2473901162496,44.876147984203506,55127306456.13385,68131349056975.164,dense
 12,256,256,256,0.01821551906896552,3072,1236950581248,45.24607467289738,27338295977.947884,67906414116709.98,dense
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 12,256,1,2,7.758845406626506e-05,3072,37748736,243.57933441822672,154975.11761480253,486525172518.07056,dense
 3,256,256,2048,0.00507974918466899,768,206158430208,475.59810852303485,433471930.42508715,40584371927298.98,qk_init
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 12,256,256,4,5.4802094978165945e-05,3072,6291456,6340608.0,0.9922480620155039,72989.91036006316,qk_ar
 12,256,256,2,4.608510707869206e-05,3072,3145728,3170304.0,0.9922480620155039,43397.96795057727,qk_ar
--- a/research/micro/degree_distribution_degree_distribution_HNSW_M30.txt.png
+++ b/research/micro/degree_distribution_degree_distribution_HNSW_M30.txt.png
--- a/research/micro/embedd_micro.py
+++ b/research/micro/embedd_micro.py
@@ -1,594 +0,0 @@
 # python embedd_micro.py --use_int8 Fastest
 import argparse
 import time
 from dataclasses import dataclass
 from typing import Dict, List, Optional, Tuple
 import numpy as np
 import torch
 from torch import nn
 from torchao import quantize_
 from transformers import AutoModel, BitsAndBytesConfig
 from tqdm import tqdm
 from contextlib import contextmanager
@dataclass
 class BenchmarkConfig:
    model_path: str
    batch_sizes: List[int]
    seq_length: int
    num_runs: int
    use_fp16: bool = True
    use_int4: bool = False
    use_int8: bool = False  # Add this parameter
    use_cuda_graphs: bool = False
    use_flash_attention: bool = False
    use_linear8bitlt: bool = False
 class CUDAGraphContainer:
    """Container for managing CUDA graphs for different batch sizes."""
    def __init__(self, model: nn.Module, seq_length: int):
        self.model = model
        self.seq_length = seq_length
        self.graphs: Dict[int, CUDAGraphWrapper] = {}
    def get_or_create(self, batch_size: int) -> 'CUDAGraphWrapper':
        if batch_size not in self.graphs:
            self.graphs[batch_size] = CUDAGraphWrapper(
                self.model, batch_size, self.seq_length
            )
        return self.graphs[batch_size]
 class CUDAGraphWrapper:
    """Wrapper for CUDA graph capture and replay."""
    def __init__(self, model: nn.Module, batch_size: int, seq_length: int):
        self.model = model
        self.static_input = self._create_random_batch(batch_size, seq_length)
        self.static_attention_mask = torch.ones_like(self.static_input)
        # Warm up
        self._warmup()
        # Capture graph
        self.graph = torch.cuda.CUDAGraph()
        with torch.cuda.graph(self.graph):
            self.static_output = self.model(
                input_ids=self.static_input,
                attention_mask=self.static_attention_mask
            )
    def _create_random_batch(self, batch_size: int, seq_length: int) -> torch.Tensor:
        return torch.randint(
            0, 1000, (batch_size, seq_length), 
            device="cuda", 
            dtype=torch.long
        )
    def _warmup(self, num_warmup: int = 3):
        with torch.no_grad():
            for _ in range(num_warmup):
                self.model(
                    input_ids=self.static_input,
                    attention_mask=self.static_attention_mask
                )
    def __call__(self, input_ids: torch.Tensor, attention_mask: torch.Tensor) -> torch.Tensor:
        self.static_input.copy_(input_ids)
        self.static_attention_mask.copy_(attention_mask)
        self.graph.replay()
        return self.static_output
 class ModelOptimizer:
    """Applies various optimizations to the model."""
    @staticmethod
    def optimize(model: nn.Module, config: BenchmarkConfig) -> nn.Module:
        print("\nApplying model optimizations:")
        if model is None:
            raise ValueError("Cannot optimize None model")
        # Move to GPU
        model = model.cuda()
        print("- Model moved to GPU")
        # FP16
        if config.use_fp16 and not config.use_int4:
            model = model.half()
            # use torch compile
            model = torch.compile(model)
            print("- Using FP16 precision")
        # Check if using SDPA
        if torch.version.cuda and float(torch.version.cuda[:3]) >= 11.6:
            if hasattr(torch.nn.functional, 'scaled_dot_product_attention'):
                print("- Using PyTorch SDPA (scaled_dot_product_attention)")
            else:
                print("- PyTorch SDPA not available")
        # Flash Attention
        if config.use_flash_attention:
            try:
                from flash_attn.flash_attention import FlashAttention
                print("- Flash Attention 2 available")
                if hasattr(model.config, "attention_mode"):
                    model.config.attention_mode = "flash_attention_2"
                    print("  - Enabled Flash Attention 2 mode")
            except ImportError:
                print("- Flash Attention not available")
        # Memory efficient attention
        try:
            from xformers.ops import memory_efficient_attention
            if hasattr(model, 'enable_xformers_memory_efficient_attention'):
                model.enable_xformers_memory_efficient_attention()
                print("- Enabled xformers memory efficient attention")
            else:
                print("- Model doesn't support xformers")
        except (ImportError, AttributeError):
            print("- Xformers not available")
        model.eval()
        print("- Model set to eval mode")
        return model
 class Timer:
    """Handles accurate GPU timing using CUDA events."""
    def __init__(self):
        self.start_event = torch.cuda.Event(enable_timing=True)
        self.end_event = torch.cuda.Event(enable_timing=True)
    @contextmanager
    def timing(self):
        self.start_event.record()
        yield
        self.end_event.record()
        self.end_event.synchronize()
    def elapsed_time(self) -> float:
        return self.start_event.elapsed_time(self.end_event) / 1000  # ms to seconds
 class Benchmark:
    """Main benchmark runner."""
    def __init__(self, config: BenchmarkConfig):
        self.config = config
        try:
            self.model = self._load_model()
            if self.model is None:
                raise ValueError("Model initialization failed - model is None")
            self.cuda_graphs = (
                CUDAGraphContainer(self.model, config.seq_length)
                if config.use_cuda_graphs
                else None
            )
            self.timer = Timer()
        except Exception as e:
            print(f"ERROR in benchmark initialization: {str(e)}")
            raise
    def _load_model(self) -> nn.Module:
        print(f"Loading model from {self.config.model_path}...")
        try:
            # Int4 quantization using HuggingFace integration
            if self.config.use_int4:
                import bitsandbytes as bnb
                print(f"- bitsandbytes version: {bnb.__version__}")
                # 检查是否使用自定义的8bit量化
                if hasattr(self.config, 'use_linear8bitlt') and self.config.use_linear8bitlt:
                    print("- Using custom Linear8bitLt replacement for all linear layers")
                    # 加载原始模型（不使用量化配置）
                    import bitsandbytes as bnb
                    import torch
                    # set default to half
                    torch.set_default_dtype(torch.float16)
                    compute_dtype = torch.float16 if self.config.use_fp16 else torch.float32
                    model = AutoModel.from_pretrained(
                        self.config.model_path,
                        torch_dtype=compute_dtype,
                    )
                    # 定义替换函数
                    def replace_linear_with_linear8bitlt(model):
                        """递归地将模型中的所有nn.Linear层替换为Linear8bitLt"""
                        for name, module in list(model.named_children()):
                            if isinstance(module, nn.Linear):
                                # 获取原始线性层的参数
                                in_features = module.in_features
                                out_features = module.out_features
                                bias = module.bias is not None
                                # 创建8bit线性层
                                # print size
                                print(f"in_features: {in_features}, out_features: {out_features}")
                                new_module = bnb.nn.Linear8bitLt(
                                    in_features, 
                                    out_features, 
                                    bias=bias, 
                                    has_fp16_weights=False
                                )
                                # 复制权重和偏置
                                new_module.weight.data = module.weight.data
                                if bias:
                                    new_module.bias.data = module.bias.data
                                # 替换模块
                                setattr(model, name, new_module)
                            else:
                                # 递归处理子模块
                                replace_linear_with_linear8bitlt(module)
                        return model
                    # 替换所有线性层
                    model = replace_linear_with_linear8bitlt(model)
                    # add torch compile
                    model = torch.compile(model)
                    # 将模型移到GPU（量化发生在这里）
                    device = "cuda" if torch.cuda.is_available() else "cpu"
                    model = model.to(device)
                    print("- All linear layers replaced with Linear8bitLt")
                else:
                    # 使用原来的Int4量化方法
                    print("- Using bitsandbytes for Int4 quantization")
                    # Create quantization config
                    compute_dtype = torch.float16 if self.config.use_fp16 else torch.float32
                    quantization_config = BitsAndBytesConfig(
                        load_in_4bit=True,
                        bnb_4bit_compute_dtype=compute_dtype,
                        bnb_4bit_use_double_quant=True,
                        bnb_4bit_quant_type="nf4"
                    )
                    print("- Quantization config:", quantization_config)
                    # Load model directly with quantization config
                    model = AutoModel.from_pretrained(
                        self.config.model_path,
                        quantization_config=quantization_config,
                        torch_dtype=compute_dtype,
                        device_map="auto"  # Let HF decide on device mapping
                    )
                # Check if model loaded successfully
                if model is None:
                    raise ValueError("Model loading returned None")
                print(f"- Model type: {type(model)}")
                # Apply optimizations directly here
                print("\nApplying model optimizations:")
                if hasattr(self.config, 'use_linear8bitlt') and self.config.use_linear8bitlt:
                    print("- Model moved to GPU with Linear8bitLt quantization")
                else:
                    # Skip moving to GPU since device_map="auto" already did that
                    print("- Model already on GPU due to device_map='auto'")
                # Skip FP16 conversion since we specified compute_dtype
                print(f"- Using {compute_dtype} for compute dtype")
                # Check CUDA and SDPA
                if torch.version.cuda and float(torch.version.cuda[:3]) >= 11.6:
                    if hasattr(torch.nn.functional, 'scaled_dot_product_attention'):
                        print("- Using PyTorch SDPA (scaled_dot_product_attention)")
                    else:
                        print("- PyTorch SDPA not available")
                # Try xformers if available
                try:
                    from xformers.ops import memory_efficient_attention
                    if hasattr(model, 'enable_xformers_memory_efficient_attention'):
                        model.enable_xformers_memory_efficient_attention()
                        print("- Enabled xformers memory efficient attention")
                    else:
                        print("- Model doesn't support xformers")
                except (ImportError, AttributeError):
                    print("- Xformers not available")
                # Set to eval mode
                model.eval()
                print("- Model set to eval mode")
            # Int8 quantization using HuggingFace integration
            # Int8 quantization using TorchAO
            elif self.config.use_int8:
                print("- Using TorchAO for Int8 dynamic activation and Int8 weight quantization")
                # Import the quantize_ function and the quantization config
                from torchao.quantization import quantize_, int8_dynamic_activation_int8_weight
                print("- Successfully imported TorchAO")
                # Load model normally first
                # set default to half
                import torch
                torch.set_default_dtype(torch.bfloat16)
                model = AutoModel.from_pretrained(
                    self.config.model_path,
                    device_map="auto"
                )
                print("- Model loaded in full precision")
                print(f"- Model type: {type(model)}")
                # Apply quantization - call the function to get the config, then apply it
                # quantize_(model, int8_dynamic_activation_int8_weight())
                # from torchao.quantization import quantize_, Int8DynamicActivationInt8WeightConfig,int8_dynamic_activation_int8_semi_sparse_weight,int4_weight_only,Int8DynActInt4WeightGPTQQuantizer,int8_dynamic_activation_int4_weight,Int8DynamicActivationInt4WeightConfig,Int4DynamicActivationInt4WeightConfig
                from torchao.quantization import quantize_, Int8DynamicActivationInt8WeightConfig
                quantize_(model, Int8DynamicActivationInt8WeightConfig())
                print("- Model successfully quantized with int8 weights and int8 activations")
                # add torch compile
                model = torch.compile(model)
                # For older PyTorch versions that have issues with tensor subclasses
                from torchao.utils import unwrap_tensor_subclass
                import torch
                if hasattr(torch, '_version') and not torch.version >= "2.5.0":
                    print("- Unwrapping tensor subclasses for compatibility with older PyTorch")
                    unwrap_tensor_subclass(model)
                # Apply optimizations
                if torch.version.cuda and float(torch.version.cuda[:3]) >= 11.6:
                    if hasattr(torch.nn.functional, 'scaled_dot_product_attention'):
                        print("- Using PyTorch SDPA (scaled_dot_product_attention)")
                    else:
                        print("- PyTorch SDPA not available")
                # Set to eval mode
                model.eval()
                print("- Model set to eval mode")
                # For better performance with int8 dynamic quantization
                torch._inductor.config.force_fuse_int_mm_with_mul = True
                print("- Enabled fusion of int matmul with mul operations")
            else:
                # Standard loading for FP16/FP32
                model = AutoModel.from_pretrained(self.config.model_path)
                print("- Model loaded in standard precision")
                print(f"- Model type: {type(model)}")
                # Apply standard optimizations
                # set default to half
                import torch
                torch.set_default_dtype(torch.bfloat16)
                model = ModelOptimizer.optimize(model, self.config)
                model = model.half()
                # add torch compile
                model = torch.compile(model)
            # Final check to ensure model is not None
            if model is None:
                raise ValueError("Model is None after optimization")
            print(f"- Final model type: {type(model)}")
            return model
        except Exception as e:
            print(f"ERROR loading model: {str(e)}")
            import traceback
            traceback.print_exc()
            raise
    def _create_random_batch(self, batch_size: int) -> torch.Tensor:
        return torch.randint(
            0, 1000,
            (batch_size, self.config.seq_length),
            device="cuda",
            dtype=torch.long
        )
    def _run_inference(
        self,
        input_ids: torch.Tensor,
        cuda_graph_wrapper: Optional[CUDAGraphWrapper] = None
    ) -> Tuple[float, torch.Tensor]:
        attention_mask = torch.ones_like(input_ids)
        with torch.no_grad(), self.timer.timing():
            if cuda_graph_wrapper is not None:
                output = cuda_graph_wrapper(input_ids, attention_mask)
            else:
                output = self.model(input_ids=input_ids, attention_mask=attention_mask)
        return self.timer.elapsed_time(), output
    def run(self) -> Dict[int, Dict[str, float]]:
        results = {}
        # Reset peak memory stats
        torch.cuda.reset_peak_memory_stats()
        for batch_size in self.config.batch_sizes:
            print(f"\nTesting batch size: {batch_size}")
            times = []
            # Get or create CUDA graph for this batch size
            cuda_graph_wrapper = (
                self.cuda_graphs.get_or_create(batch_size)
                if self.cuda_graphs is not None
                else None
            )
            # Pre-allocate input tensor
            input_ids = self._create_random_batch(batch_size)
            print(f"Input shape: {input_ids.shape}")
            # Run benchmark
            for i in tqdm(range(self.config.num_runs), desc=f"Batch size {batch_size}"):
                try:
                    elapsed_time, output = self._run_inference(input_ids, cuda_graph_wrapper)
                    if i == 0:  # Only print on first run
                        print(f"Output shape: {output.last_hidden_state.shape}")
                    times.append(elapsed_time)
                except Exception as e:
                    print(f"Error during inference: {e}")
                    break
            if not times:
                print(f"No successful runs for batch size {batch_size}, skipping")
                continue
            # Calculate statistics
            avg_time = np.mean(times)
            std_time = np.std(times)
            throughput = batch_size / avg_time
            results[batch_size] = {
                "avg_time": avg_time,
                "std_time": std_time,
                "throughput": throughput,
            }
            print(f"Avg Time: {avg_time:.4f}s ± {std_time:.4f}s")
            print(f"Throughput: {throughput:.2f} sequences/second")
        # Log memory usage
        peak_memory_gb = torch.cuda.max_memory_allocated() / (1024 ** 3)
        print(f"\nPeak GPU memory usage: {peak_memory_gb:.2f} GB")
        # Add memory info to results
        for batch_size in results:
            results[batch_size]["peak_memory_gb"] = peak_memory_gb
        return results
 def main():
    parser = argparse.ArgumentParser(description="Model Inference Benchmark")
    parser.add_argument(
        "--model_path",
        type=str,
        default="facebook/contriever",
        help="Path to the model",
    )
    parser.add_argument(
        "--batch_sizes",
        type=str,
        default="1,2,4,8,10,16,20,32,40,64,128,256,512,1024,2048,4096,8192",
        help="Comma-separated list of batch sizes",
    )
    parser.add_argument(
        "--seq_length",
        type=int,
        default=256,
        help="Sequence length for input",
    )
    parser.add_argument(
        "--num_runs",
        type=int,
        default=5,
        help="Number of runs for each batch size",
    )
    parser.add_argument(
        "--use_fp16",
        action="store_true",
        help="Enable FP16 inference",
    )
    parser.add_argument(
        "--use_int4",
        action="store_true",
        help="Enable INT4 quantization using bitsandbytes",
    )
    parser.add_argument(
        "--use_int8",
        action="store_true",
        help="Enable INT8 quantization for both activations and weights using bitsandbytes",
    )
    parser.add_argument(
        "--use_cuda_graphs",
        action="store_true",
        help="Enable CUDA Graphs optimization",
    )
    parser.add_argument(
        "--use_flash_attention",
        action="store_true",
        help="Enable Flash Attention 2 if available",
    )
    parser.add_argument(
        "--use_linear8bitlt",
        action="store_true",
        help="Enable Linear8bitLt quantization for all linear layers",
    )
    args = parser.parse_args()
    # Print arguments for debugging
    print("\nCommand line arguments:")
    for arg, value in vars(args).items():
        print(f"- {arg}: {value}")
    config = BenchmarkConfig(
        model_path=args.model_path,
        batch_sizes=[int(bs) for bs in args.batch_sizes.split(",")],
        seq_length=args.seq_length,
        num_runs=args.num_runs,
        use_fp16=args.use_fp16,
        use_int4=args.use_int4,
        use_int8=args.use_int8,  # Add this line
        use_cuda_graphs=args.use_cuda_graphs,
        use_flash_attention=args.use_flash_attention,
        use_linear8bitlt=args.use_linear8bitlt,
    )
    # Print configuration for debugging
    print("\nBenchmark configuration:")
    for field, value in vars(config).items():
        print(f"- {field}: {value}")
    try:
        benchmark = Benchmark(config)
        results = benchmark.run()
        # Save results to file
        import json
        import os
        # Create results directory if it doesn't exist
        os.makedirs("results", exist_ok=True)
        # Generate filename based on configuration
        precision_type = "int4" if config.use_int4 else "fp16" if config.use_fp16 else "fp32"
        model_name = os.path.basename(config.model_path)
        output_file = f"results/benchmark_{model_name}_{precision_type}.json"
        # Save results
        with open(output_file, "w") as f:
            json.dump(
                {
                    "config": {k: str(v) if isinstance(v, list) else v for k, v in vars(config).items()},
                    "results": {str(k): v for k, v in results.items()}
                }, 
                f, 
                indent=2
            )
        print(f"Results saved to {output_file}")
    except Exception as e:
        print(f"Benchmark failed: {e}")
        import traceback
        traceback.print_exc()
 if __name__ == "__main__":
    main()
--- a/research/micro/embedd_micro_seq.py
+++ b/research/micro/embedd_micro_seq.py
@@ -1,376 +0,0 @@
 import argparse
 import time
 from dataclasses import dataclass
 from typing import Dict, List, Optional, Tuple
 import numpy as np
 import torch
 from torch import nn
 from transformers import AutoModel
 from tqdm import tqdm
 from contextlib import contextmanager
 import math
@dataclass
 class BenchmarkConfig:
    model_path: str
    batch_sizes: List[int]
    seq_length: int
    num_runs: int
    use_fp16: bool = True
    use_cuda_graphs: bool = False
    use_flash_attention: bool = False
    max_batch_size: int = 256  # Maximum batch size before splitting
 class CUDAGraphContainer:
    """Container for managing CUDA graphs for different batch sizes."""
    def __init__(self, model: nn.Module, seq_length: int, max_batch_size: int):
        self.model = model
        self.seq_length = seq_length
        self.max_batch_size = max_batch_size
        self.graphs: Dict[int, CUDAGraphWrapper] = {}
    def get_or_create(self, batch_size: int) -> 'CUDAGraphWrapper':
        # For CUDA graphs, we always use the actual batch size or max_batch_size
        effective_batch_size = min(batch_size, self.max_batch_size)
        if effective_batch_size not in self.graphs:
            self.graphs[effective_batch_size] = CUDAGraphWrapper(
                self.model, effective_batch_size, self.seq_length
            )
        return self.graphs[effective_batch_size]
 class CUDAGraphWrapper:
    """Wrapper for CUDA graph capture and replay."""
    def __init__(self, model: nn.Module, batch_size: int, seq_length: int):
        self.model = model
        self.static_input = self._create_random_batch(batch_size, seq_length)
        self.static_attention_mask = torch.ones_like(self.static_input)
        # Warm up
        self._warmup()
        # Capture graph
        self.graph = torch.cuda.CUDAGraph()
        with torch.cuda.graph(self.graph):
            self.static_output = self.model(
                input_ids=self.static_input,
                attention_mask=self.static_attention_mask
            )
    def _create_random_batch(self, batch_size: int, seq_length: int) -> torch.Tensor:
        return torch.randint(
            0, 1000, (batch_size, seq_length), 
            device="cuda", 
            dtype=torch.long
        )
    def _warmup(self, num_warmup: int = 3):
        with torch.no_grad():
            for _ in range(num_warmup):
                self.model(
                    input_ids=self.static_input,
                    attention_mask=self.static_attention_mask
                )
    def __call__(self, input_ids: torch.Tensor, attention_mask: torch.Tensor) -> torch.Tensor:
        self.static_input.copy_(input_ids)
        self.static_attention_mask.copy_(attention_mask)
        self.graph.replay()
        return self.static_output
 class ModelOptimizer:
    """Applies various optimizations to the model."""
    @staticmethod
    def optimize(model: nn.Module, config: BenchmarkConfig) -> nn.Module:
        print("\nApplying model optimizations:")
        # Move to GPU
        model = model.cuda()
        print("- Model moved to GPU")
        # FP16
        if config.use_fp16:
            model = model.half()
            print("- Using FP16 precision")
        # Check if using SDPA
        if torch.version.cuda and float(torch.version.cuda[:3]) >= 11.6:
            if hasattr(torch.nn.functional, 'scaled_dot_product_attention'):
                print("- Using PyTorch SDPA (scaled_dot_product_attention)")
                # No need to do anything as it's automatically enabled
            else:
                print("- PyTorch SDPA not available")
        # Flash Attention
        if config.use_flash_attention:
            try:
                from flash_attn.flash_attention import FlashAttention
                print("- Flash Attention 2 available")
                if hasattr(model.config, "attention_mode"):
                    model.config.attention_mode = "flash_attention_2"
                    print("  - Enabled Flash Attention 2 mode")
            except ImportError:
                print("- Flash Attention not available")
        # Optimize LayerNorm
        try:
            num_layernorms = 0
            for module in model.modules():
                if isinstance(module, torch.nn.LayerNorm):
                    module.forward = torch.jit.script(module.forward)
                    num_layernorms += 1
            if num_layernorms > 0:
                print(f"- Optimized {num_layernorms} LayerNorm modules with TorchScript")
        except Exception as e:
            print(f"- LayerNorm optimization failed: {e}")
        # Memory efficient attention
        try:
            from xformers.ops import memory_efficient_attention
            model.enable_xformers_memory_efficient_attention()
            print("- Enabled xformers memory efficient attention")
        except (ImportError, AttributeError):
            print("- Xformers not available")
        model.eval()
        print("- Model set to eval mode")
        return model
 class Timer:
    """Handles accurate GPU timing using CUDA events."""
    def __init__(self):
        self.start_event = torch.cuda.Event(enable_timing=True)
        self.end_event = torch.cuda.Event(enable_timing=True)
    @contextmanager
    def timing(self):
        self.start_event.record()
        yield
        self.end_event.record()
        self.end_event.synchronize()
    def elapsed_time(self) -> float:
        return self.start_event.elapsed_time(self.end_event) / 1000  # ms to seconds
 class Benchmark:
    """Main benchmark runner."""
    def __init__(self, config: BenchmarkConfig):
        self.config = config
        self.model = self._load_model()
        self.cuda_graphs = (
            CUDAGraphContainer(self.model, config.seq_length, config.max_batch_size)
            if config.use_cuda_graphs
            else None
        )
        self.timer = Timer()
    def _load_model(self) -> nn.Module:
        print(f"Loading model from {self.config.model_path}...")
        model = AutoModel.from_pretrained(self.config.model_path)
        return ModelOptimizer.optimize(model, self.config)
    def _create_random_batch(self, batch_size: int) -> torch.Tensor:
        return torch.randint(
            0, 1000,
            (batch_size, self.config.seq_length),
            device="cuda",
            dtype=torch.long
        )
    def _run_inference(
        self,
        input_ids: torch.Tensor,
        cuda_graph_wrapper: Optional[CUDAGraphWrapper] = None
    ) -> Tuple[float, torch.Tensor]:
        attention_mask = torch.ones_like(input_ids)
        original_batch_size = input_ids.shape[0]
        print(f"Original input_ids shape: {input_ids.shape}")
        # Split large batches to avoid OOM
        max_batch_size = self.config.max_batch_size
        if original_batch_size > max_batch_size:
            print(f"Splitting batch of size {original_batch_size} into chunks of {max_batch_size}")
            total_time = 0
            outputs = []
            with torch.no_grad():
                for i in range(0, original_batch_size, max_batch_size):
                    end_idx = min(i + max_batch_size, original_batch_size)
                    batch_slice = input_ids[i:end_idx]
                    mask_slice = attention_mask[i:end_idx]
                    print(f"Processing chunk {i//max_batch_size + 1}: shape {batch_slice.shape}")
                    # Use CUDA graph if available (with the smaller batch size)
                    chunk_cuda_graph = None
                    if cuda_graph_wrapper is not None:
                        chunk_cuda_graph = self.cuda_graphs.get_or_create(batch_slice.shape[0])
                    with self.timer.timing():
                        if chunk_cuda_graph is not None:
                            chunk_output = chunk_cuda_graph(batch_slice, mask_slice)
                        else:
                            chunk_output = self.model(input_ids=batch_slice, attention_mask=mask_slice)
                    total_time += self.timer.elapsed_time()
                    outputs.append(chunk_output.last_hidden_state)
                # Combine outputs
                combined_output = torch.cat(outputs, dim=0)
                print(f"Combined output shape: {combined_output.shape}")
                # Create a wrapper object similar to model output to maintain consistency
                class DummyOutput:
                    def __init__(self, hidden_states):
                        self.last_hidden_state = hidden_states
                output = DummyOutput(combined_output)
                return total_time, output
        else:
            # Process normally for small batches
            with torch.no_grad(), self.timer.timing():
                if cuda_graph_wrapper is not None:
                    output = cuda_graph_wrapper(input_ids, attention_mask)
                else:
                    output = self.model(input_ids=input_ids, attention_mask=attention_mask)
            print(f"Output shape: {output.last_hidden_state.shape}")
            return self.timer.elapsed_time(), output
    def run(self) -> Dict[int, Dict[str, float]]:
        results = {}
        for batch_size in self.config.batch_sizes:
            print(f"\nTesting batch size: {batch_size}")
            times = []
            # Get or create CUDA graph for this batch size
            cuda_graph_wrapper = None
            if self.cuda_graphs is not None:
                if batch_size <= self.config.max_batch_size:
                    cuda_graph_wrapper = self.cuda_graphs.get_or_create(batch_size)
                else:
                    # For large batches, we'll use the max_batch_size graph in chunks
                    cuda_graph_wrapper = True  # Just a flag to indicate we want to use CUDA graphs
            # Pre-allocate input tensor
            input_ids = self._create_random_batch(batch_size)
            # Run benchmark
            for run_idx in tqdm(range(self.config.num_runs), desc=f"Batch size {batch_size}"):
                elapsed_time, _ = self._run_inference(input_ids, cuda_graph_wrapper)
                times.append(elapsed_time)
                print(f"Run {run_idx+1}: {elapsed_time:.4f}s")
            # Calculate statistics
            avg_time = np.mean(times)
            std_time = np.std(times)
            throughput = batch_size / avg_time
            results[batch_size] = {
                "avg_time": avg_time,
                "std_time": std_time,
                "throughput": throughput,
            }
            print(f"Avg Time: {avg_time:.4f}s ± {std_time:.4f}s")
            print(f"Throughput: {throughput:.2f} sequences/second")
        return results
 def main():
    parser = argparse.ArgumentParser(description="Model Inference Benchmark")
    parser.add_argument(
        "--model_path",
        type=str,
        default="facebook/contriever",
        help="Path to the model",
    )
    parser.add_argument(
        "--batch_sizes",
        type=str,
        default="1,2,4,8,16,32,64,128,256,512,1024,2048,4096",
        help="Comma-separated list of batch sizes",
    )
    parser.add_argument(
        "--seq_length",
        type=int,
        default=256,
        help="Sequence length for input",
    )
    parser.add_argument(
        "--num_runs",
        type=int,
        default=5,
        help="Number of runs for each batch size",
    )
    parser.add_argument(
        "--no_fp16",
        action="store_true",
        help="Disable FP16 inference",
    )
    parser.add_argument(
        "--use_cuda_graphs",
        action="store_true",
        help="Enable CUDA Graphs optimization",
    )
    parser.add_argument(
        "--use_flash_attention",
        action="store_true",
        help="Enable Flash Attention 2 if available",
    )
    parser.add_argument(
        "--max_batch_size",
        type=int,
        default=256,
        help="Maximum batch size before splitting to prevent OOM",
    )
    args = parser.parse_args()
    config = BenchmarkConfig(
        model_path=args.model_path,
        batch_sizes=[int(bs) for bs in args.batch_sizes.split(",")],
        seq_length=args.seq_length,
        num_runs=args.num_runs,
        use_fp16=not args.no_fp16,
        use_cuda_graphs=args.use_cuda_graphs,
        use_flash_attention=args.use_flash_attention,
        max_batch_size=args.max_batch_size,
    )
    benchmark = Benchmark(config)
    results = benchmark.run()
    # Print overall summary
    print("\n===== BENCHMARK SUMMARY =====")
    print(f"Model: {config.model_path}")
    print(f"Sequence Length: {config.seq_length}")
    print(f"FP16: {config.use_fp16}")
    print(f"CUDA Graphs: {config.use_cuda_graphs}")
    print(f"Flash Attention: {config.use_flash_attention}")
    print(f"Max Batch Size: {config.max_batch_size}")
    print("\nResults:")
    print("\nBatch Size | Avg Time (s) | Throughput (seq/s)")
    print("-" * 50)
    for bs in sorted(results.keys()):
        r = results[bs]
        print(f"{bs:^10} | {r['avg_time']:^12.4f} | {r['throughput']:^17.2f}")
 if __name__ == "__main__":
    main()
--- a/Show More
+++ b/Show More
`@@ -1,3 +1,3 @@`
	`from .history import ChromeHistoryReader`	`from .history import ChromeHistoryReader`

	`__all__ = ['ChromeHistoryReader']`	`__all__ = ["ChromeHistoryReader"]`
`@@ -1 +1 @@`
	`from . import diskann_backend`	`from . import diskann_backend as diskann_backend`
`@@ -1 +1 @@`
	`from . import hnsw_backend`	`from . import hnsw_backend as hnsw_backend`