nvfp4-megamoe-kernel/tests/unit/test_prod_vs_ref_comparison.py

#!/usr/bin/env python3
"""Compare production NVFP4 GEMM vs PyTorch reference dequant at specific layers.

This test loads a single layer's weights and compares the production Nvfp4Linear
output against the PyTorch F.linear(dequant_nvfp4) reference.

This is a diagnostic test to identify where the production kernel diverges
from the reference, causing the residual growth issue.
"""
import os, sys, json, math, torch, torch.nn.functional as F
from pathlib import Path

CHECKPOINT_DIR = os.environ.get("CHECKPOINT_DIR", "/root/nvidia-meeting/DeepSeek-V4-Pro-NVFP4")
FP4_LUT = torch.tensor([0., 0.5, 1.0, 1.5, 2.0, 3.0, 4.0, 6.0])

def dequant_nvfp4(weight, weight_scale, weight_scale_2=None, input_scale=None):
    O, I2 = weight.shape; I = I2 * 2
    lo = (weight & 0x0F).to(torch.int8); hi = (weight >> 4).to(torch.int8)
    lut = FP4_LUT.to(device=weight.device, dtype=torch.float32)
    lo_f = lut[(lo & 0x07).long()] * torch.where((lo >> 3).bool(), -1., 1.)
    hi_f = lut[(hi & 0x07).long()] * torch.where((hi >> 3).bool(), -1., 1.)
    w = torch.stack([lo_f, hi_f], -1).reshape(O, I)
    s = weight_scale.float().repeat_interleave(16, 1)
    if weight_scale_2 is not None: s = s * weight_scale_2.float()
    return (w * s).bfloat16()

def get_nvfp4_weight(w, pfx, proj_name):
    k = f"{pfx}.{proj_name}"
    return (w.get(f"{k}.weight"), w.get(f"{k}.weight_scale"),
            w.get(f"{k}.weight_scale_2"), w.get(f"{k}.input_scale"))

def main():
    device = "cuda:0"
    torch.manual_seed(42)
    
    # Load config
    with open(os.path.join(CHECKPOINT_DIR, "config.json")) as f:
        cfg = json.load(f)
    H = cfg["hidden_size"]
    
    # Load weights
    from safetensors.torch import load_file
    cdir = Path(CHECKPOINT_DIR); wmap = {}
    idx = cdir / "model.safetensors.index.json"
    if idx.exists():
        with open(idx) as f: wmap = json.load(f).get("weight_map", {})
    shards = set(wmap.values()) if wmap else set(); all_w = {}
    for sn in sorted(shards):
        if (cdir / sn).exists(): all_w.update(load_file(str(cdir / sn)))
    print(f"Loaded {len(all_w)} tensors")
    
    # Import production kernel
    from dsv4.layers.linear import Nvfp4Linear
    
    # Test projections at different layers
    test_cases = [
        # (layer_idx, proj_name, in_features, out_features)
        (0, "model.layers.0.self_attn.q_a_proj", 7168, 1536),
        (0, "model.layers.0.self_attn.kv_proj", 7168, 512),
        (0, "model.layers.0.self_attn.q_b_proj", 1536, 65536),
        (0, "model.layers.0.self_attn.o_b_proj", 16384, 7168),
        (30, "model.layers.30.self_attn.q_a_proj", 7168, 1536),
        (60, "model.layers.60.self_attn.q_a_proj", 7168, 1536),
        (60, "model.layers.60.self_attn.kv_proj", 7168, 512),
        # Router gate
        (3, "model.layers.3.mlp.gate", 7168, 384),
        (30, "model.layers.30.mlp.gate", 7168, 384),
        (60, "model.layers.60.mlp.gate", 7168, 384),
    ]
    
    for li, pfx, in_f, out_f in test_cases:
        weight, ws, ws2, isc = get_nvfp4_weight(all_w, pfx, 'weight' if 'gate' in pfx else pfx.split('.')[-1])
        if 'gate' in pfx:
            # Gate weight
            weight, ws, ws2, isc = get_nvfp4_weight(all_w, '.'.join(pfx.split('.')[:-1]), 'gate')
            proj_name = 'gate'
            pfx_base = '.'.join(pfx.split('.')[:-1])
        else:
            proj_name = pfx.split('.')[-1]
            pfx_base = '.'.join(pfx.split('.')[:-1])
            weight, ws, ws2, isc = get_nvfp4_weight(all_w, pfx_base, proj_name)
        
        if weight is None:
            print(f"L{li} {proj_name}: weight not found, skipping")
            continue
        
        weight = weight.to(device)
        ws = ws.to(device)
        ws2 = ws2.to(device) if ws2 is not None else None
        isc = isc.to(device) if isc is not None else None
        
        actual_out = weight.shape[0]
        actual_in = weight.shape[1] * 2
        
        # Create random input
        x = torch.randn(1, actual_in, dtype=torch.bfloat16, device=device) * 5.0
        
        # PyTorch reference: dequant + F.linear
        w_ref = dequant_nvfp4(weight, ws, ws2, isc)
        ref_out = F.linear(x, w_ref)
        
        # Production: Nvfp4Linear
        lin = Nvfp4Linear(actual_in, actual_out, max_num_tokens=8192, device=device)
        lin.fp4 = [weight.to(device).view(torch.float4_e2m1fn_x2) if weight.dtype == torch.uint8 else weight.to(device)]
        lin.sf = [ws.to(device)]
        lin.gs = [1.0]
        lin.ws2 = [ws2.to(device) if ws2 is not None else None]
        isc_val = isc.float().item() if isc is not None else 1.0/(6.0*448.0)
        lin._activation_global_scale = isc_val
        lin.finalize_weights()
        
        prod_out = lin(x)
        
        # Compare
        cos = torch.nn.functional.cosine_similarity(prod_out.flatten().float(), ref_out.flatten().float(), dim=0).item()
        max_diff = (prod_out.float() - ref_out.float()).abs().max().item()
        prod_max = prod_out.abs().max().item()
        ref_max = ref_out.abs().max().item()
        print(f"L{li} {proj_name}: cos={cos:.6f} max_diff={max_diff:.4f} |prod|={prod_max:.4f} |ref|={ref_max:.4f} ratio={prod_max/(ref_max+1e-10):.4f}")
    
    print("\nDone.")

if __name__ == "__main__":
    main()