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* fix(qwen-asr): enable timestamp output when forced_aligner is configured Two bugs prevented timestamps from working in the qwen-asr backend: 1. transcribe() was called without return_time_stamps=True, so the forced aligner was loaded but never invoked. Now we pass return_time_stamps=True when a forced_aligner is present. 2. The timestamp parsing code expected (list, tuple) items, but the qwen_asr library returns ForcedAlignItem dataclass instances with .text, .start_time, .end_time attributes. Added hasattr() check to handle this correctly, falling back to tuple parsing for backward compatibility. * refactor: address Copilot review for qwen-asr timestamps - Wrap return_time_stamps kwarg in try/except TypeError for safety - Add defensive float() normalization for timestamp times - Use str() for text extraction to ensure string type * fix(qwen-asr): convert seconds to nanoseconds for Go time.Duration The Go server reads TranscriptSegment.start/end via time.Duration, which is in nanoseconds. Previously the backend sent milliseconds (* 1000), causing timestamps to be 1000x too small (e.g. 8e-8 instead of 0.08). Convert seconds → nanoseconds (* 1e9) instead. Also applies to the legacy tuple path for consistency. * feat(qwen-asr): respect timestamp_granularities (segment vs word) Read request.timestamp_granularities from the gRPC request. - 'word': return one segment per aligned item (character / word) - 'segment' (default): merge consecutive items at sentence boundaries Sentence boundaries detected via CJK punctuation (。!?;…) and Latin endings (. ! ? ;). This matches the OpenAI Whisper API contract where omitting the parameter defaults to segment-level. * fix(qwen-asr): escape smart quotes in punctuation set Unicode curly quotes (U+2018/2019) were being interpreted as Python string delimiters, causing SyntaxError. Use explicit unicode escapes. * fix(qwen-asr): use time-gap threshold for segment boundaries The forced aligner strips punctuation from its output, so text-based sentence detection doesn't work. Instead, detect segment boundaries by measuring time gaps between consecutive aligned items. Threshold = max(median_gap * 4, 0.3s). This cleanly separates intra-sentence gaps (< 0.24s) from inter-sentence gaps (> 0.3s) across Chinese, English, and other languages. * fix(qwen-asr): smart join with spaces for non-CJK tokens The forced aligner strips whitespace from tokenized text, so English words like ['hello', 'world'] were joined as 'helloworld'. Add _smart_join() that inserts spaces between non-CJK tokens while keeping CJK characters and punctuation unspaced. Works for Chinese, English, Korean, Japanese, and mixed-language text. --------- Co-authored-by: fqscfqj <fqsfqj@outlook.com>
Python Backends for LocalAI
This directory contains Python-based AI backends for LocalAI, providing support for various AI models and hardware acceleration targets.
Overview
The Python backends use a unified build system based on libbackend.sh that provides:
- Automatic virtual environment management with support for both
uvandpip - Hardware-specific dependency installation (CPU, CUDA, Intel, MLX, etc.)
- Portable Python support for standalone deployments
- Consistent backend execution across different environments
Available Backends
Core AI Models
- transformers - Hugging Face Transformers framework (PyTorch-based)
- vllm - High-performance LLM inference engine
- mlx - Apple Silicon optimized ML framework
Audio & Speech
- coqui - Coqui TTS models
- faster-whisper - Fast Whisper speech recognition
- kitten-tts - Lightweight TTS
- mlx-audio - Apple Silicon audio processing
- chatterbox - TTS model
- kokoro - TTS models
Computer Vision
- diffusers - Stable Diffusion and image generation
- mlx-vlm - Vision-language models for Apple Silicon
- rfdetr - Object detection models
Specialized
- rerankers - Text reranking models
Quick Start
Prerequisites
- Python 3.10+ (default: 3.10.18)
uvpackage manager (recommended) orpip- Appropriate hardware drivers for your target (CUDA, Intel, etc.)
Installation
Each backend can be installed individually:
# Navigate to a specific backend
cd backend/python/transformers
# Install dependencies
make transformers
# or
bash install.sh
# Run the backend
make run
# or
bash run.sh
Using the Unified Build System
The libbackend.sh script provides consistent commands across all backends:
# Source the library in your backend script
source $(dirname $0)/../common/libbackend.sh
# Install requirements (automatically handles hardware detection)
installRequirements
# Start the backend server
startBackend $@
# Run tests
runUnittests
Hardware Targets
The build system automatically detects and configures for different hardware:
- CPU - Standard CPU-only builds
- CUDA - NVIDIA GPU acceleration (supports CUDA 12/13)
- Intel - Intel XPU/GPU optimization
- MLX - Apple Silicon (M1/M2/M3) optimization
- HIP - AMD GPU acceleration
Target-Specific Requirements
Backends can specify hardware-specific dependencies:
requirements.txt- Base requirementsrequirements-cpu.txt- CPU-specific packagesrequirements-cublas12.txt- CUDA 12 packagesrequirements-cublas13.txt- CUDA 13 packagesrequirements-intel.txt- Intel-optimized packagesrequirements-mps.txt- Apple Silicon packages
Configuration Options
Environment Variables
PYTHON_VERSION- Python version (default: 3.10)PYTHON_PATCH- Python patch version (default: 18)BUILD_TYPE- Force specific build targetUSE_PIP- Use pip instead of uv (default: false)PORTABLE_PYTHON- Enable portable Python buildsLIMIT_TARGETS- Restrict backend to specific targets
Example: CUDA 12 Only Backend
# In your backend script
LIMIT_TARGETS="cublas12"
source $(dirname $0)/../common/libbackend.sh
Example: Intel-Optimized Backend
# In your backend script
LIMIT_TARGETS="intel"
source $(dirname $0)/../common/libbackend.sh
Development
Adding a New Backend
- Create a new directory in
backend/python/ - Copy the template structure from
common/template/ - Implement your
backend.pywith the required gRPC interface - Add appropriate requirements files for your target hardware
- Use
libbackend.shfor consistent build and execution
Testing
# Run backend tests
make test
# or
bash test.sh
Building
# Install dependencies
make <backend-name>
# Clean build artifacts
make clean
Architecture
Each backend follows a consistent structure:
backend-name/
├── backend.py # Main backend implementation
├── requirements.txt # Base dependencies
├── requirements-*.txt # Hardware-specific dependencies
├── install.sh # Installation script
├── run.sh # Execution script
├── test.sh # Test script
├── Makefile # Build targets
└── test.py # Unit tests
Troubleshooting
Common Issues
- Missing dependencies: Ensure all requirements files are properly configured
- Hardware detection: Check that
BUILD_TYPEmatches your system - Python version: Verify Python 3.10+ is available
- Virtual environment: Use
ensureVenvto create/activate environments
Contributing
When adding new backends or modifying existing ones:
- Follow the established directory structure
- Use
libbackend.shfor consistent behavior - Include appropriate requirements files for all target hardware
- Add comprehensive tests
- Update this README if adding new backend types