flash-moe-inference
Run 397B parameter Mixture-of-Experts LLMs on a MacBook using pure C/Metal with SSD streaming
How do I install this agent skill?
npx skills add https://github.com/aradotso/trending-skills --skill flash-moe-inferenceIs this agent skill safe to install?
- Gen Agent Trust Hubfail
This skill downloads, compiles, and executes code from an external third-party GitHub repository. This process introduces a risk of arbitrary code execution on the host system if the remote source is compromised or contains malicious logic.
- Socketwarn
1 alert: gptAnomaly
- Snykwarn
Risk: MEDIUM · 2 issues
- ZeroLeakspass
Score: 93/100 · 2 sections analyzed
What does this agent skill do?
Flash-MoE Inference Engine
Skill by ara.so — Daily 2026 Skills collection.
Flash-MoE is a pure C/Objective-C/Metal inference engine that runs Qwen3.5-397B-A17B (397B parameter Mixture-of-Experts) on a MacBook Pro with 48GB RAM at 4.4+ tokens/second. It streams 209GB of expert weights from NVMe SSD on demand — no Python, no ML frameworks, just C, Objective-C, and hand-tuned Metal shaders.
Requirements
- Hardware: Apple Silicon Mac (M3 Max or similar), 48GB+ unified memory, 1TB+ SSD with ~210GB free
- OS: macOS 26+ (Darwin 25+)
- Tools: Xcode Command Line Tools, Python 3.x (for weight extraction only)
- Model: Qwen3.5-397B-A17B safetensors weights (download separately from HuggingFace)
Installation & Build
# Clone the repo
git clone https://github.com/danveloper/flash-moe
cd flash-moe/metal_infer
# Build everything
make
# Verify build artifacts
ls infer chat main
The Makefile compiles infer.m, chat.m, main.m with Metal shader compilation for shaders.metal.
Weight Preparation
Step 1: Extract non-expert weights
# From the metal_infer/ directory
# Point to your downloaded Qwen3.5-397B safetensors directory
python3 extract_weights.py /path/to/Qwen3.5-397B-A17B-Instruct/
# Produces:
# model_weights.bin (~5.5GB, mmap'd at runtime)
# model_weights.json (tensor manifest)
# vocab.bin (vocabulary)
# tokenizer.bin (BPE tokenizer data)
Step 2: Pack expert weights (4-bit, production)
# From repo root
python3 repack_experts.py /path/to/Qwen3.5-397B-A17B-Instruct/ metal_infer/packed_experts/
# Produces packed_experts/ directory (~209GB)
# Each expert is a separate file: layer_XX_expert_YYYY.bin
Step 3: Optional 2-bit requantization (faster but breaks JSON/tool calling)
# Convert 4-bit experts to 2-bit (saves ~89GB, 120GB total)
python3 metal_infer/repack_experts_2bit.py \
metal_infer/packed_experts/ \
metal_infer/packed_experts_2bit/
Key Commands
Basic inference
cd metal_infer
# 4-bit inference (production quality, tool calling works)
./infer --prompt "Explain quantum computing" --tokens 100
# 2-bit inference (faster, breaks JSON/tool calling)
./infer --prompt "Explain quantum computing" --tokens 100 --2bit
# Per-layer timing breakdown
./infer --prompt "Hello" --tokens 20 --timing
Interactive chat with tool calling
./chat
# Opens TUI with full tool calling support
# Uses 4-bit experts by default
MoE-only benchmark (measures expert throughput)
./main
# Runs pure expert forward-pass benchmark
# Reports tokens/sec without attention overhead
Project Structure
flash-moe/
├── paper/
│ └── flash_moe.pdf # Full technical paper
├── metal_infer/
│ ├── infer.m # Complete inference engine (~7000 lines)
│ ├── shaders.metal # Metal compute kernels (~1200 lines)
│ ├── chat.m # Interactive chat TUI
│ ├── tokenizer.h # Single-header C BPE tokenizer (449 lines)
│ ├── main.m # MoE-only benchmark
│ ├── Makefile
│ ├── extract_weights.py # Safetensors → model_weights.bin
│ ├── repack_experts_2bit.py # 4-bit → 2-bit requantization
│ ├── train_predictor.py # Expert routing prediction analysis
│ ├── model_weights.bin # Non-expert weights (mmap'd)
│ ├── model_weights.json # Tensor manifest
│ ├── vocab.bin
│ ├── tokenizer.bin
│ ├── packed_experts/ # 4-bit expert files (209GB)
│ └── packed_experts_2bit/ # 2-bit expert files (120GB, optional)
├── repack_experts.py # 4-bit expert packing from safetensors
├── progress.py # Results visualization
└── results.tsv # Experiment log
Architecture Overview
The model has 60 transformer layers:
- 45 GatedDeltaNet (linear attention) layers
- 15 standard full attention layers
- Each layer: 512 experts, K=4 activated per token + 1 shared expert
- Hidden dimension: 4096
Per-layer pipeline (4.28ms average at 4-bit)
CMD3(prev) → CMD1: attention projections + delta-net [1.22ms GPU]
→ CPU: flush results [0.01ms CPU]
→ CMD2: o_proj + norm + routing + shared [0.55ms GPU]
→ CPU: softmax + topK routing [0.003ms]
→ I/O: parallel pread K=4 experts [2.41ms SSD]
→ CMD3: expert forward + combine + norm [0.04ms encode, DEFERRED]
Metal Shader Kernels
The shaders.metal file contains hand-written kernels. Key kernels:
// 4-bit dequantized matrix-vector multiply (FMA-optimized)
// Key insight: fma(nibble, scale*x, bias*x) instead of (nibble*scale + bias)*x
// Pre-compute scale*x and bias*x to fuse dequant+multiply in one FMA instruction
kernel void matvec_4bit_fma(
device const uint8_t* weights [[buffer(0)]],
device const float* scales [[buffer(1)]],
device const float* biases [[buffer(2)]],
device const float* x [[buffer(3)]],
device float* out [[buffer(4)]],
uint tid [[thread_position_in_threadgroup]],
uint gid [[threadgroup_position_in_grid]])
{
// ... tiled SIMD-reduced FMA kernel
// 12% faster than naive (nibble * scale + bias) * x
}
// Fused SwiGLU activation
kernel void swiglu(device float* gate [[buffer(0)]],
device const float* up [[buffer(1)]],
uint gid [[thread_position_in_grid]])
{
float g = gate[gid];
gate[gid] = (g / (1.0f + exp(-g))) * up[gid];
}
// RMS normalization (two-pass)
kernel void rms_norm_pass1(...) // sum of squares reduction
kernel void rms_norm_pass2(...) // apply normalization
// GPU RoPE (fused with Q deinterleave and K normalization)
kernel void rope_qk(...)
// MoE combine + residual + sigmoid gate (fused)
kernel void moe_combine_residual(...)
SSD Expert Streaming Pattern
The core innovation — loading only K=4 active experts per layer from SSD:
// Parallel expert loading using GCD dispatch groups
// From infer.m (conceptual pattern)
dispatch_group_t group = dispatch_group_create();
dispatch_queue_t ioQueue = dispatch_get_global_queue(QOS_CLASS_USER_INITIATED, 0);
for (int k = 0; k < K_EXPERTS; k++) {
int expert_id = top_k_indices[k];
dispatch_group_async(group, ioQueue, ^{
// Each expert: ~6.75MB at 4-bit
char path[256];
snprintf(path, sizeof(path),
"packed_experts/layer_%02d_expert_%04d.bin",
layer, expert_id);
int fd = open(path, O_RDONLY);
// pread() — non-blocking, OS page cache handles LRU
pread(fd, expert_buffer[k], expert_size, 0);
close(fd);
});
}
dispatch_group_wait(group, DISPATCH_TIME_FOREVER);
// GPU compute follows — serial pipeline is hardware-optimal on Apple Silicon
Why pread() not mmap(): mmap incurs per-page fault overhead on cold data (~5x slower). Direct pread() with OS page cache achieves ~71% hit rate naturally.
GatedDeltaNet Linear Attention (BLAS)
The recurrence update uses Accelerate BLAS — 64% faster than scalar:
// GatedDeltaNet state update per head (conceptual pattern)
// state: 128×128 float matrix, 64 heads
// From infer.m
#import <Accelerate/Accelerate.h>
for (int h = 0; h < 64; h++) {
float* S = state + h * 128 * 128; // 128×128 state matrix
float* q = Q + h * 128;
float* k = K + h * 128;
float* v = V + h * 128;
// β·(k⊗v) outer product update
// cblas_sger: S += beta * (k ⊗ v)
cblas_sger(CblasRowMajor, 128, 128,
beta[h], k, 1, v, 1, S, 128);
// Decay: S = alpha * S
cblas_sscal(128 * 128, alpha[h], S, 1);
// Output: o = S @ q
cblas_sgemv(CblasRowMajor, CblasNoTrans,
128, 128, 1.0f, S, 128, q, 1, 0.0f,
output + h * 128, 1);
}
Performance Configuration
4-bit (production default)
- Quality: Excellent — full tool calling, correct JSON
- Speed: 4.36 tok/s
- Disk: 209GB
2-bit (speed testing only)
- Quality: Good — but breaks JSON/tool calling (
\name\instead of"name") - Speed: 5.74 tok/s (7.05 peak single token with warm cache)
- Disk: 120GB
- Uses
F_NOCACHEflag to avoid page cache thrashing
What NOT to Try (Learned from 58 Experiments)
| Approach | Why it fails |
|---|---|
mmap() expert files | Per-page fault overhead: 5x slower than pread() |
dispatch_io | dispatch_data management overhead: -70% |
F_RDADVISE prefetch | SSD DMA + GPU share memory controller — concurrent access: -73% GPU speed |
| Custom Metal LRU cache | GPU memory pressure: -38% vs OS page cache |
| LZ4 expert compression | Decompress overhead > warm cache savings: -13% |
| Temporal expert prediction | 25% hit rate, wastes SSD bandwidth: -18% |
| Speculative early routing | Cache pollution: -38% |
| MTP speculative decoding | MoE I/O scales per-token (unlike dense models): break-even |
| Spin-poll GPU wait | CPU thermal throttle competes with GPU: -23% |
| Parallel SSD + GPU overlap | Unified memory controller arbitration: net negative |
Key principle: On Apple Silicon, GPU DMA and SSD DMA share the same memory controller. The serial pipeline (GPU → SSD → GPU) is hardware-optimal.
Troubleshooting
Build fails
# Ensure Xcode CLI tools are installed
xcode-select --install
# Check Metal compiler is available
xcrun -sdk macosx metal --version
Out of memory
The engine is designed to use ~6GB active:
- 5.5GB:
model_weights.bin(mmap'd, read-only) - ~200MB: Metal scratch buffers
- Remaining ~42GB: OS page cache for expert data
If you see OOM, check for other processes consuming unified memory:
sudo memory_pressure
vm_stat
Slow performance
# Check SSD speed — needs ~17GB/s for target performance
# Run with timing to identify bottleneck
./infer --prompt "Hello" --tokens 5 --timing
# Verify packed_experts/ is on internal SSD, not external drive
diskutil info /
Wrong expert directory
# Default paths expected by infer.m:
# metal_infer/packed_experts/ (4-bit)
# metal_infer/packed_experts_2bit/ (2-bit)
# Ensure you're running from metal_infer/ directory
cd metal_infer
./infer --prompt "test"
Tool calling broken
Use 4-bit, not 2-bit. The 2-bit quantization corrupts quote characters in JSON output, making tool calling unreliable. Always use the default 4-bit configuration for agentic workloads.
Memory Safety
The engine explicitly manages all allocations:
- No unbounded caches
- Expert data never accumulates in GPU memory
model_weights.binis mmap'd read-only — kernel manages pages- Expert files are opened/read/closed per inference step
How can the creator link this skill?
Add the canonical catalog link to the repository README so users can inspect current installs and available audits. The publishing guide covers the complete discovery path.
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