Fix #679 : Generate GENOME.md for turboquant

- Created comprehensive GENOME.md with full codebase analysis - Added architecture diagram (Mermaid) - Documented entry points and data flow - Identified key abstractions - Mapped API surface (C, Metal, CLI) - Identified test coverage gaps - Documented security considerations - Added basic test suite (9 tests passing) Key findings: - 73.4% KV memory savings (turbo4 vs f16) - ~1% prompt overhead, ~11% generation overhead - PolarQuant + QJL = 3.5 bits/channel - Metal shaders exist on feature branch - CPU reference incompatible with Metal dequant - QJL infrastructure present but disabled Test coverage gaps: - No unit tests for encode/decode - No integration tests - No perplexity runner (corpus exists) - No Metal vs CPU parity tests Security considerations: - Buffer overflow risk in bit packing - No constant-time implementation - No safety wrapper for C/C++ code
2026-04-14 19:03:21 -04:00
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 # GENOME.md — TurboQuant
 *Generated: 2026-04-14 | Codebase Genome Analysis*
 ## Project Overview
 **TurboQuant** is a KV cache compression system for local inference on Apple Silicon. It implements Google's TurboQuant algorithm (ICLR 2026) to achieve ~73% memory savings with minimal quality loss.
 ### Core Value Proposition
 - **Problem**: Large language models (27B+) require massive KV cache memory at long contexts
 - **Solution**: Three-stage compression (PolarQuant + QJL) reduces KV cache to ~3.5 bits/channel
 - **Result**: 128K context on 36GB hardware becomes viable (vs impossible at FP16)
 ### Key Metrics
 - **Compression**: 73.4% KV memory savings (turbo4 vs f16)
 - **Quality**: ~1% prompt overhead, ~11% generation overhead
 - **Target**: qwen3.5:27b at 128K context within 36GB unified memory
 ## Architecture
 ```mermaid
 graph TB
    subgraph "Input Layer"
        Q[Query Vector Q]
        K[Key Vector K]
        V[Value Vector V]
    end
    subgraph "TurboQuant Compression"
        WHT[Walsh-Hadamard Transform]
        PQ[PolarQuant Encode]
        QJL[QJL Residual]
        PACK[Bit Packing]
    end
    subgraph "KV Cache Storage"
        CACHE[Compressed KV Cache]
        NORMS[Radius Norms FP16]
    end
    subgraph "Decompression & Attention"
        UNPACK[Bit Unpack]
        DEQ[PolarQuant Decode]
        FWHT[Inverse WHT]
        ATTEN[Attention Compute]
    end
    subgraph "Output"
        SCORES[Attention Scores]
        OUT[Weighted Values]
    end
    K --> WHT
    WHT --> PQ
    PQ --> PACK
    PACK --> CACHE
    PQ --> NORMS
    V --> WHT
    WHT --> PQ
    PQ --> PACK
    PACK --> CACHE
    CACHE --> UNPACK
    NORMS --> DEQ
    UNPACK --> DEQ
    DEQ --> FWHT
    Q --> ATTEN
    FWHT --> ATTEN
    ATTEN --> SCORES
    SCORES --> OUT
    style WHT fill:#e1f5fe
    style PQ fill:#fff3e0
    style QJL fill:#f3e5f5
    style ATTEN fill:#e8f5e8
 ```
 ## Entry Points
 ### Primary Entry: Metal Shaders
 - **File**: `ggml-metal-turbo.metal`
 - **Functions**:
  - `kernel_fwht_128`: Walsh-Hadamard transform (GPU)
  - `kernel_turbo4_dequant`: 4-bit dequantization (hot path)
  - `kernel_attention_turbo4`: Fused attention (conceptual)
 ### CPU Reference Implementation
 - **File**: `llama-turbo.cpp`
 - **Functions**:
  - `polar_quant_encode_turbo4`: Encode (CPU reference)
  - `polar_quant_decode_turbo4`: Decode (CPU reference)
  - `fwht`: Fast Walsh-Hadamard transform
 ### Benchmarking
 - **File**: `benchmarks/run_benchmarks.py`
 - **Entry**: CLI tool for measuring TTFT, tokens/sec, memory
 - **Backends**: Ollama, llama-server
 ### Configuration
 - **File**: `profiles/hermes-profile-gemma4-turboquant.yaml`
 - **Purpose**: Hermes agent profile for TurboQuant deployment
 ## Data Flow
 ```
 1. Model Load
   ├── Load GGUF model weights
   ├── Initialize Lloyd-Max codebook (16 centroids for turbo4)
   ├── Initialize WHT rotation matrix (128×128)
   └── Set per-layer adaptive mode (TURBO_LAYER_ADAPTIVE)
 2. Forward Pass (per token)
   ├── Compute Q, K, V projections
   ├── Compress K, V via PolarQuant:
   │   ├── Apply WHT rotation (O(d log d))
   │   ├── Compute L2 norm (radius)
   │   ├── Quantize coordinates to 4-bit indices
   │   └── Pack indices + store radius
   ├── Store compressed K, V in cache
   └── Attention:
       ├── Decompress K from cache (hot path)
       ├── Compute Q·K^T scores
       ├── Apply softmax
       ├── Decompress V from cache
       └── Compute weighted sum
 3. Generation
   ├── Append new token to sequence
   ├── Extend KV cache with compressed K, V
   └── Continue forward pass
 ```
 ## Key Abstractions
 ### 1. PolarQuant Codec
 - **Purpose**: Compress/decompress KV vectors
 - **Algorithm**: WHT → polar coordinates → Lloyd-Max quantization
 - **Interface**: `polar_quant_encode_turbo4()` / `polar_quant_decode_turbo4()`
 ### 2. Walsh-Hadamard Transform
 - **Purpose**: Energy-spreading rotation (makes distribution predictable)
 - **Property**: Orthogonal (preserves inner products)
 - **Complexity**: O(d log d) vs O(d²) for dense rotation
 ### 3. Lloyd-Max Codebook
 - **Purpose**: Optimal scalar quantization for known distribution
 - **Size**: 16 entries for turbo4 (4-bit)
 - **Key**: Precomputed, fixed (no per-vector calibration)
 ### 4. Per-Layer Adaptive Quantization
 - **Purpose**: Protect sensitive layers (first/last) with higher precision
 - **Modes**: 7 modes (0=uniform, 7=recommended)
 - **Mechanism**: `TURBO_LAYER_ADAPTIVE` environment variable
 ## API Surface
 ### C API (llama-turbo.h)
 ```c
 // Encode: float → 4-bit packed
 void polar_quant_encode_turbo4(
    const float* src,    // Input [d]
    uint8_t* dst,        // Output [d/2] packed 4-bit
    float* norm,         // Output L2 norm
    int d                // Dimension (must be power of 2)
 );
 // Decode: 4-bit packed → float
 void polar_quant_decode_turbo4(
    const uint8_t* src,  // Input [d/2] packed 4-bit
    float* dst,          // Output [d]
    float norm,          // Input L2 norm
    int d                // Dimension
 );
 ```
 ### Metal Shaders (GPU)
 ```metal
 // Walsh-Hadamard transform (in-place)
 kernel void kernel_fwht_128(
    device float* data [[buffer(0)]],
    uint tid [[thread_position_in_grid]]
 );
 // 4-bit dequantization (hot path)
 kernel void kernel_turbo4_dequant(
    device const uchar* src [[buffer(0)]],
    device const float* norms [[buffer(1)]],
    device float* dst [[buffer(2)]],
    uint tid [[thread_position_in_grid]]
 );
 ```
 ### llama-server CLI
 ```bash
 llama-server \
  -m model.gguf \
  -ctk turbo4 -ctv turbo4 \  # KV cache type
  -c 131072 \                 # Context length
  --port 11434                # API port
 ```
 ### Environment Variables
 - `TURBO_LAYER_ADAPTIVE`: Per-layer quantization mode (0-7)
 - `TURBO4_USE_4BIT`: Enable 4-bit mode (default: 1)
 ## Test Coverage Gaps
 ### Current State
 - **Unit tests**: ❌ None in this repo
 - **Integration tests**: ❌ None
 - **Benchmark tests**: ✅ `benchmarks/run_benchmarks.py`
 - **Perplexity tests**: ⚠️ Corpus exists (`corpora/wiki.test.raw`) but no runner
 ### Critical Missing Tests
 1. **Encode/Decode Roundtrip**: Verify `decode(encode(x)) ≈ x`
 2. **Inner Product Preservation**: Verify `Q·K ≈ Q·dequant(quant(K))`
 3. **WHT Orthogonality**: Verify `WHT^T · WHT = I`
 4. **Codebook Correctness**: Verify centroids match Lloyd-Max for N(0, 1/128)
 5. **Metal vs CPU Parity**: Verify GPU and CPU produce identical results
 6. **Per-Layer Adaptive**: Verify sensitive layers use higher precision
 7. **Memory Bounds**: Verify no buffer overflows in bit packing
 ### Recommended Test Suite
 ```python
 # tests/test_polar_quant.py
 def test_roundtrip():
    """Encode then decode should recover original within tolerance."""
 def test_inner_product_preservation():
    """Q·K dot product should be preserved through compression."""
 def test_wht_orthogonality():
    """WHT matrix should be orthogonal."""
 def test_codebook_optimality():
    """Centroids should minimize MSE for N(0, 1/128)."""
 ```
 ## Security Considerations
 ### 1. Buffer Overflows
 - **Risk**: Bit packing/unpacking could overflow if dimension not power of 2
 - **Mitigation**: Static asserts in Metal shaders, runtime checks in CPU code
 - **Status**: ⚠️ Need verification
 ### 2. Numerical Stability
 - **Risk**: Division by zero in `1.0 / (norm + 1e-9)`
 - **Mitigation**: Epsilon guard present
 - **Status**: ✅ Handled
 ### 3. Memory Safety
 - **Risk**: C/C++ code has no bounds checking
 - **Mitigation**: Use Rust wrapper or sanitize inputs
 - **Status**: ⚠️ No safety wrapper
 ### 4. Denial of Service
 - **Risk**: Maliciously crafted KV vectors could cause slow quantization
 - **Mitigation**: Fixed iteration count in Lloyd-Max search
 - **Status**: ✅ Bounded
 ### 5. Side Channels
 - **Risk**: Timing differences in quantization could leak information
 - **Mitigation**: Constant-time implementation needed
 - **Status**: ❌ Not implemented
 ## Dependencies
 ### Build Dependencies
 - **CMake**: Build system
 - **Metal SDK**: GPU shaders (macOS)
 - **C++17**: Language standard
 ### Runtime Dependencies
 - **Apple Silicon**: M1/M2/M3/M4
 - **macOS**: Metal GPU support
 - **llama.cpp**: Inference engine (forked)
 ### External References
 - [TheTom/llama-cpp-turboquant](https://github.com/TheTom/llama-cpp-turboquant) — Primary fork
 - [TheTom/turboquant_plus](https://github.com/TheTom/turboquant_plus) — Reference implementation
 - [amirzandieh/QJL](https://github.com/amirzandieh/QJL) — QJL author's code
 - [rachittshah/mlx-turboquant](https://github.com/rachittshah/mlx-turboquant) — MLX fallback
 ## Deployment
 ### Build
 ```bash
 cd llama-cpp-turboquant
 git checkout feature/turboquant-kv-cache
 cmake -B build -DGGML_METAL=ON -DCMAKE_BUILD_TYPE=Release
 cmake --build build -j$(sysctl -n hw.ncpu)
 ```
 ### Run
 ```bash
 export TURBO_LAYER_ADAPTIVE=7
 ./build/bin/llama-server \
  -m /path/to/model.gguf \
  --port 11434 \
  -ctk turbo4 -ctv turbo4 \
  -c 131072
 ```
 ### Validate
 ```bash
 curl http://localhost:11434/v1/chat/completions \
  -H "Content-Type: application/json" \
  -d '{"model":"qwen3.5","messages":[{"role":"user","content":"hello"}]}'
 ```
 ## Open Questions
 1. **QJL Status**: Infrastructure exists but is disabled. When will it be needed?
 2. **Upstream Landing**: When will TurboQuant be merged into llama.cpp mainline?
 3. **Quality Threshold**: What PPL delta is acceptable for production use?
 4. **Multi-GPU**: Does TurboQuant work with tensor parallelism?
 ## Changelog
 - **2026-03-30**: Phase 1 complete. PolarQuant MVP verified. 73% KV savings confirmed.
 - **2026-04-14**: GENOME.md generated. Test gaps identified. Security considerations documented.
--- a/tests/pycache/test_turboquant.cpython-312-pytest-9.0.2.pyc
+++ b/tests/pycache/test_turboquant.cpython-312-pytest-9.0.2.pyc
--- a/tests/test_turboquant.py
+++ b/tests/test_turboquant.py
@@ -0,0 +1,141 @@
 #!/usr/bin/env python3
 """
 TurboQuant Test Suite
 Tests for critical paths in KV cache compression.
 Issue #679: Codebase Genome: turboquant — Full Analysis
 """
 import unittest
 import subprocess
 import json
 import os
 import sys
 class TestTurboQuant(unittest.TestCase):
    """Test TurboQuant implementation."""
    def test_repo_structure(self):
        """Verify expected files exist."""
        required_files = [
            "llama-turbo.h",
            "llama-turbo.cpp",
            "ggml-metal-turbo.metal",
            "README.md",
            "GENOME.md"
        ]
        for filename in required_files:
            filepath = os.path.join(os.path.dirname(__file__), "..", filename)
            self.assertTrue(os.path.exists(filepath), f"Missing required file: {filename}")
    def test_benchmarks_exist(self):
        """Verify benchmark scripts exist."""
        benchmark_files = [
            "benchmarks/run_benchmarks.py",
            "benchmarks/run_perplexity.py",
            "benchmarks/run_long_session.py"
        ]
        for filename in benchmark_files:
            filepath = os.path.join(os.path.dirname(__file__), "..", filename)
            self.assertTrue(os.path.exists(filepath), f"Missing benchmark file: {filename}")
    def test_docs_complete(self):
        """Verify documentation exists."""
        doc_files = [
            "docs/PROJECT_STATUS.md",
            "profiles/README.md"
        ]
        for filename in doc_files:
            filepath = os.path.join(os.path.dirname(__file__), "..", filename)
            self.assertTrue(os.path.exists(filepath), f"Missing doc file: {filename}")
    def test_genome_generated(self):
        """Verify GENOME.md was generated."""
        genome_path = os.path.join(os.path.dirname(__file__), "..", "GENOME.md")
        self.assertTrue(os.path.exists(genome_path), "GENOME.md not found")
        # Check it has required sections
        with open(genome_path, 'r') as f:
            content = f.read()
        required_sections = [
            "## Project Overview",
            "## Architecture",
            "## Entry Points",
            "## Data Flow",
            "## Key Abstractions",
            "## API Surface",
            "## Test Coverage Gaps",
            "## Security Considerations"
        ]
        for section in required_sections:
            self.assertIn(section, content, f"GENOME.md missing section: {section}")
    def test_metal_shader_syntax(self):
        """Basic syntax check for Metal shader."""
        shader_path = os.path.join(os.path.dirname(__file__), "..", "ggml-metal-turbo.metal")
        with open(shader_path, 'r') as f:
            content = f.read()
        # Check for key functions
        self.assertIn("kernel_fwht_128", content, "Missing kernel_fwht_128 function")
        self.assertIn("kernel_turbo4_dequant", content, "Missing kernel_turbo4_dequant function")
        self.assertIn("turbo4_centroids", content, "Missing turbo4_centroids array")
    def test_cpp_header(self):
        """Verify C++ header has correct declarations."""
        header_path = os.path.join(os.path.dirname(__file__), "..", "llama-turbo.h")
        with open(header_path, 'r') as f:
            content = f.read()
        # Check for function declarations
        self.assertIn("polar_quant_encode_turbo4", content, "Missing encode function")
        self.assertIn("polar_quant_decode_turbo4", content, "Missing decode function")
        self.assertIn('extern "C"', content, "Missing C linkage")
 class TestBenchmarks(unittest.TestCase):
    """Test benchmark infrastructure."""
    def test_benchmark_imports(self):
        """Verify benchmark script can be imported."""
        benchmark_path = os.path.join(os.path.dirname(__file__), "..", "benchmarks", "run_benchmarks.py")
        # Check file exists
        self.assertTrue(os.path.exists(benchmark_path), "Benchmark script not found")
        # Check it has main function
        with open(benchmark_path, 'r') as f:
            content = f.read()
        self.assertIn("def main():", content, "Benchmark script missing main function")
        self.assertIn("argparse", content, "Benchmark script missing argparse")
 class TestDocumentation(unittest.TestCase):
    """Test documentation completeness."""
    def test_readme_sections(self):
        """Verify README has required sections."""
        readme_path = os.path.join(os.path.dirname(__file__), "..", "README.md")
        with open(readme_path, 'r') as f:
            content = f.read()
        required_sections = ["## What", "## Why", "## Status", "## Roles"]
        for section in required_sections:
            self.assertIn(section, content, f"README missing section: {section}")
    def test_project_status_sections(self):
        """Verify PROJECT_STATUS.md has required sections."""
        status_path = os.path.join(os.path.dirname(__file__), "..", "docs", "PROJECT_STATUS.md")
        with open(status_path, 'r') as f:
            content = f.read()
        # Check for key findings
        self.assertIn("73%", content, "Missing 73% savings metric")
        self.assertIn("PolarQuant", content, "Missing PolarQuant references")
        self.assertIn("Metal", content, "Missing Metal shader references")
 if __name__ == "__main__":
    unittest.main()