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* feat(realtime): EOU-driven semantic_vad turn detection Add a `semantic_vad` turn-detection mode to the realtime API that feeds the transcription model live and decides "the user finished speaking" from the `<EOU>` end-of-utterance token rather than from silence alone. When EOU fires the turn commits immediately (~0.3s); otherwise it falls back to an eagerness-scaled silence threshold (low/med/high = 8/4/2s). Plumbing, bottom to top: - proto: `AudioTranscriptionLive` bidirectional RPC (config-first oneof, mono float PCM @16k, ready-ack / Unimplemented degrade signal) plus `TranscriptResult.eou` for the unary retranscribe gate. - pkg/grpc: client/server/base/embed scaffolding for the bidi stream, modeled on AudioTransformStream; release stream conns on terminal Recv. - parakeet-cpp: live transcription RPC with per-C-call engine locking (one live stream per turn, finalize+free at commit); bump parakeet.cpp to ABI v5 — incremental StreamingMel (no more quadratic per-feed mel recompute that delayed EOU on long turns) and the <EOU>/<EOB> split; strip the literal <EOU>/<EOB> from offline text and set Eou. - core/backend: LiveTranscriptionSession wrapper + pipeline `turn_detection:` config block (type/eagerness/retranscribe). - realtime: semantic_vad integration — live input captions streamed as transcription deltas while the user speaks, EOU-immediate commit with eagerness fallback, optional retranscribe gate (batch re-decode must also end in <EOU> to confirm), clause synthesis off the LLM token callback, and per-turn live-transcription / model_load telemetry. - UI: show the realtime pipeline components as a vertical list. Docs and tests included; opt-in via the pipeline YAML or per-session `session.update`. Non-streaming STT backends degrade to silence-only. Assisted-by: Claude Code:claude-opus-4-8 [Read] [Edit] [Write] [Bash] Assisted-by: Claude Code:claude-fable-5 [Read] [Edit] [Bash] Signed-off-by: Richard Palethorpe <io@richiejp.com> * feat(realtime): explicit formally-verified state machines + parakeet streaming driver The realtime API had several implicit state machines whose state was inferred from scattered booleans, channels, and five separate mutexes, leaving illegal/inconsistent states reachable. Make them explicit and keep the implementation in step with a formal design; rework the parakeet streaming backend along the same lines. Realtime state machines (M1-M5). Each is a sealed sum-type State/Event/Effect with a total, pure Next(state,event)->(state,[]effect) behind a single-writer Coordinator: M1 conncoord connection lifecycle: VAD toggle + once-only teardown (replaces vadServerStarted + a `done` channel closed from two sites). M2 turncoord turn detection: collapses speechStarted and the live-stream "turn open" flag into one state, so discardTurn can no longer desync them and suppress the next onset. M3 respcoord response coordination: serializes the dual-writer start/cancel so at most one response is live; one response.done per response.create. M4 compactcoord conversation compaction: single-flight (replaces the `compacting atomic.Bool` CAS). M5 ttscoord TTS pipeline: open->closing->closed, idempotent wait(), rejects enqueue-after-close (was a silent drop). The Coordinator/Sink/Next plumbing — only the sealed types and Next differed per machine — is extracted once into core/http/endpoints/openai/coordinator as a generic Coordinator[S,E,F]; each machine keeps its public API via type aliases, so no sink, call-site, or test moved. Hierarchy. session_lifecycle.fizz models M1 as the parent region with its children (M2/M3/M4) as one statechart and asserts ChildrenDieWithParent (conn torn => all children terminal, none start after teardown). respcoord and compactcoord gain an absorbing Terminated state + Shutdown event; conncoord's teardown drives the children terminal. This closes a compaction teardown gap: a fire-and-forget compaction could outlive a torn session — compactionSink now takes a session-scoped cancellable context + WaitGroup and joins the in-flight summarize+evict on shutdown. Formal verification. formal-verification/ holds one authoritative FizzBee spec per machine plus the composition spec, each with an always-assertion and a documented one-line edit that makes the checker fail (verified non-vacuous). scripts/realtime-conformance.sh is fail-closed: all Go conformance suites under -race AND a model-check of every .fizz spec; a missing FizzBee is a hard error (only the loud REALTIME_CONFORMANCE_SKIP_FIZZBEE=1 bypasses it, never in CI). FizzBee is pinned by sha256 and installed via scripts/install-fizzbee.sh into .tools/ (gitignored). Wired as make test-realtime-conformance, a CI workflow, and a pre-commit path filter. Go conformance tests are Ginkgo/Gomega (per the repo's forbidigo lint): transition tables + fixed-seed property walks + concurrent/-race specs, no rapid dependency. Design map: docs/design/realtime-state-machines.md. Parakeet streaming backend. The same treatment applied to the parakeet-cpp streaming paths: - AudioTranscriptionStream returns codes.Unimplemented for non-streaming models instead of decoding offline and emitting it as one delta + final. A client that asked for streaming learns the model cannot stream rather than receiving a batch result shaped like a stream. New grpcerrors.StreamTranscriptionUnsupported carries that signal; the HTTP /v1/audio/transcriptions stream path surfaces it as an SSE error event. Mirrors AudioTranscriptionLive, which already did this. - utteranceBoundary (boundary.go): a single definition of the end-of-utterance latch, replacing three open-coded finalEou toggles. Modelled as a two-valued type so illegal states are unrepresentable. - Shared decode driver (driver.go): streamFeedResult (one per-feed event) + feedChunk (hides the ABI v4 JSON vs text-only split) + feedSlices + flushTail. The feed loop is written once. - AudioTranscriptionLive becomes a bidi adapter: it streams the per-feed {delta,eou,eob,words} the realtime turn detector consumes and a terminal FinalResult carrying only Text. Segments/duration/eou are offline-only and no longer produced (nor read) on the live path; liveTraceState drops the terminal eou and keeps the per-feed eou_events count. - AudioTranscriptionStream + streamJSON merge into one driver-based function; streamSegmenter is generalized to the unified event with a text-only fallback that preserves the legacy (no-words) library's per-utterance segmentation. Verified: build/vet/gofumpt clean, golangci-lint 0 issues, all coordinator and parakeet packages under -race, the fail-closed conformance gate green, and make test-realtime (12 e2e WS+WebRTC). Assisted-by: Claude:claude-opus-4-8 [Claude Code] Signed-off-by: Richard Palethorpe <io@richiejp.com> --------- Signed-off-by: Richard Palethorpe <io@richiejp.com>
LocalAI Backend Architecture
This directory contains the core backend infrastructure for LocalAI, including the gRPC protocol definition, multi-language Dockerfiles, and language-specific backend implementations.
Overview
LocalAI uses a unified gRPC-based architecture that allows different programming languages to implement AI backends while maintaining consistent interfaces and capabilities. The backend system supports multiple hardware acceleration targets and provides a standardized way to integrate various AI models and frameworks.
Architecture Components
1. Protocol Definition (backend.proto)
The backend.proto file defines the gRPC service interface that all backends must implement. This ensures consistency across different language implementations and provides a contract for communication between LocalAI core and backend services.
Core Services
- Text Generation:
Predict,PredictStreamfor LLM inference - Embeddings:
Embeddingfor text vectorization - Image Generation:
GenerateImagefor stable diffusion and image models - Audio Processing:
AudioTranscription,TTS,SoundGeneration - Video Generation:
GenerateVideofor video synthesis - Object Detection:
Detectfor computer vision tasks - Vector Storage:
StoresSet,StoresGet,StoresFindfor RAG operations - Reranking:
Rerankfor document relevance scoring - Voice Activity Detection:
VADfor audio segmentation
Key Message Types
PredictOptions: Comprehensive configuration for text generationModelOptions: Model loading and configuration parametersResult: Standardized response formatStatusResponse: Backend health and memory usage information
2. Multi-Language Dockerfiles
The backend system provides language-specific Dockerfiles that handle the build environment and dependencies for different programming languages:
Dockerfile.pythonDockerfile.golangDockerfile.llama-cpp
3. Language-Specific Implementations
Python Backends (python/)
- transformers: Hugging Face Transformers framework
- vllm: High-performance LLM inference
- mlx: Apple Silicon optimization
- diffusers: Stable Diffusion models
- Audio: coqui, faster-whisper, kitten-tts
- Vision: mlx-vlm, rfdetr
- Specialized: rerankers, chatterbox, kokoro
Go Backends (go/)
- whisper: OpenAI Whisper speech recognition in Go with GGML cpp backend (whisper.cpp)
- stablediffusion-ggml: Stable Diffusion in Go with GGML Cpp backend
- piper: Text-to-speech synthesis Golang with C bindings using rhaspy/piper
- local-store: Vector storage backend
C++ Backends (cpp/)
- llama-cpp: Llama.cpp integration
- grpc: GRPC utilities and helpers
Hardware Acceleration Support
CUDA (NVIDIA)
- Versions: CUDA 12.x, 13.x
- Features: cuBLAS, cuDNN, TensorRT optimization
- Targets: x86_64, ARM64 (Jetson)
ROCm (AMD)
- Features: HIP, rocBLAS, MIOpen
- Targets: AMD GPUs with ROCm support
Intel
- Features: oneAPI, Intel Extension for PyTorch
- Targets: Intel GPUs, XPUs, CPUs
Vulkan
- Features: Cross-platform GPU acceleration
- Targets: Windows, Linux, Android, macOS
Apple Silicon
- Features: MLX framework, Metal Performance Shaders
- Targets: M1/M2/M3 Macs
Backend Registry (index.yaml)
The index.yaml file serves as a central registry for all available backends, providing:
- Metadata: Name, description, license, icons
- Capabilities: Hardware targets and optimization profiles
- Tags: Categorization for discovery
- URLs: Source code and documentation links
Building Backends
Prerequisites
- Docker with multi-architecture support
- Appropriate hardware drivers (CUDA, ROCm, etc.)
- Build tools (make, cmake, compilers)
Build Commands
Example of build commands with Docker
# Build Python backend
docker build -f backend/Dockerfile.python \
--build-arg BACKEND=transformers \
--build-arg BUILD_TYPE=cublas12 \
--build-arg CUDA_MAJOR_VERSION=12 \
--build-arg CUDA_MINOR_VERSION=0 \
-t localai-backend-transformers .
# Build Go backend
docker build -f backend/Dockerfile.golang \
--build-arg BACKEND=whisper \
--build-arg BUILD_TYPE=cpu \
-t localai-backend-whisper .
# Build C++ backend
docker build -f backend/Dockerfile.llama-cpp \
--build-arg BACKEND=llama-cpp \
--build-arg BUILD_TYPE=cublas12 \
-t localai-backend-llama-cpp .
For ARM64/Mac builds, docker can't be used, and the makefile in the respective backend has to be used.
Build Types
cpu: CPU-only optimizationcublas12,cublas13: CUDA 12.x, 13.x with cuBLAShipblas: ROCm with rocBLASintel: Intel oneAPI optimizationvulkan: Vulkan-based accelerationmetal: Apple Metal optimization
Backend Development
Creating a New Backend
- Choose Language: Select Python, Go, or C++ based on requirements
- Implement Interface: Implement the gRPC service defined in
backend.proto - Add Dependencies: Create appropriate requirements files
- Configure Build: Set up Dockerfile and build scripts
- Register Backend: Add entry to
index.yaml - Test Integration: Verify gRPC communication and functionality
Backend Structure
backend-name/
├── backend.py/go/cpp # Main implementation
├── requirements.txt # Dependencies
├── Dockerfile # Build configuration
├── install.sh # Installation script
├── run.sh # Execution script
├── test.sh # Test script
└── README.md # Backend documentation
Required gRPC Methods
At minimum, backends must implement:
Health()- Service health checkLoadModel()- Model loading and initializationPredict()- Main inference endpointStatus()- Backend status and metrics
Integration with LocalAI Core
Backends communicate with LocalAI core through gRPC:
- Service Discovery: Core discovers available backends
- Model Loading: Core requests model loading via
LoadModel - Inference: Core sends requests via
Predictor specialized endpoints - Streaming: Core handles streaming responses for real-time generation
- Monitoring: Core tracks backend health and performance
Performance Optimization
Memory Management
- Model Caching: Efficient model loading and caching
- Batch Processing: Optimize for multiple concurrent requests
- Memory Pinning: GPU memory optimization for CUDA/ROCm
Hardware Utilization
- Multi-GPU: Support for tensor parallelism
- Mixed Precision: FP16/BF16 for memory efficiency
- Kernel Fusion: Optimized CUDA/ROCm kernels
Troubleshooting
Common Issues
- GRPC Connection: Verify backend service is running and accessible
- Model Loading: Check model paths and dependencies
- Hardware Detection: Ensure appropriate drivers and libraries
- Memory Issues: Monitor GPU memory usage and model sizes
Contributing
When contributing to the backend system:
- Follow Protocol: Implement the exact gRPC interface
- Add Tests: Include comprehensive test coverage
- Document: Provide clear usage examples
- Optimize: Consider performance and resource usage
- Validate: Test across different hardware targets