tests/test_quick_rand.py

"""Quick random test at N=32 K=32 — if cosize fix works, cosine should be ~1.0"""
import torch, sys
sys.path.insert(0, 'src')
from nvfp4_megamoe_kernel.cutlass_nvfp4_gemm.kernel import cutlass_nvfp4_blockscaled_gemm
from nvfp4_megamoe_kernel.nvfp4_mega_moe import _quantize_to_e2m1, _E2M1_MAGNITUDES

torch.manual_seed(42)
device = "cuda"
M, N, K = 1, 32, 32

x_bf16 = torch.randn(M, K, dtype=torch.bfloat16, device=device) * 2.0
w_bf16 = torch.randn(K, N, dtype=torch.bfloat16, device=device) * 0.5

x_fp4, x_sf = _quantize_to_e2m1(x_bf16.float())
w_fp4, w_sf = _quantize_to_e2m1(w_bf16.T.float())
w_fp4 = w_fp4.T; w_sf = w_sf.T

# Dequant
x_u8 = x_fp4.view(torch.uint8)
lo = (x_u8 & 0x0F).long(); hi = ((x_u8 >> 4) & 0x0F).long()
x_nib = torch.stack([lo, hi], dim=-1).reshape(M, -1)
x_deq = ((x_nib >> 3).float() * -2 + 1) * _E2M1_MAGNITUDES.to(device)[(x_nib & 0x07)]
x_recon = (x_deq * x_sf.to(torch.float32).repeat_interleave(16, dim=-1)).to(torch.bfloat16)

w_u8 = w_fp4.view(torch.uint8)
wlo = (w_u8 & 0x0F).long(); whi = ((w_u8 >> 4) & 0x0F).long()
w_nib = torch.stack([wlo, whi], dim=-1).reshape(w_u8.shape[0]*2, w_u8.shape[1])
w_deq = ((w_nib >> 3).float() * -2 + 1) * _E2M1_MAGNITUDES.to(device)[(w_nib & 0x07)]
w_recon = (w_deq * w_sf.to(torch.float32).repeat_interleave(16, dim=0)).to(torch.bfloat16)

quant_ref = torch.nn.functional.linear(x_recon, w_recon.T)
nvfp4_out = cutlass_nvfp4_blockscaled_gemm(x_fp4, x_sf, w_fp4, w_sf, M, N, K, alpha=1.0)
cos = torch.nn.functional.cosine_similarity(nvfp4_out.float(), quant_ref.float(), dim=-1).mean().item()
print(f"M={M} N={N} K={K} cosine={cos:.6f}")
print(f"NVFP4 first 8: {nvfp4_out[0,:8].tolist()}")
print(f"REF    first 8: {quant_ref[0,:8].tolist()}")
test: quick random test 2026-05-15 19:58:57 +00:00			`"""Quick random test at N=32 K=32 — if cosize fix works, cosine should be ~1.0"""`
			`import torch, sys`
			`sys.path.insert(0, 'src')`
			`from nvfp4_megamoe_kernel.cutlass_nvfp4_gemm.kernel import cutlass_nvfp4_blockscaled_gemm`
			`from nvfp4_megamoe_kernel.nvfp4_mega_moe import _quantize_to_e2m1, _E2M1_MAGNITUDES`

			`torch.manual_seed(42)`
			`device = "cuda"`
			`M, N, K = 1, 32, 32`

			`x_bf16 = torch.randn(M, K, dtype=torch.bfloat16, device=device) * 2.0`
			`w_bf16 = torch.randn(K, N, dtype=torch.bfloat16, device=device) * 0.5`

			`x_fp4, x_sf = _quantize_to_e2m1(x_bf16.float())`
			`w_fp4, w_sf = _quantize_to_e2m1(w_bf16.T.float())`
			`w_fp4 = w_fp4.T; w_sf = w_sf.T`

			`# Dequant`
			`x_u8 = x_fp4.view(torch.uint8)`
			`lo = (x_u8 & 0x0F).long(); hi = ((x_u8 >> 4) & 0x0F).long()`
			`x_nib = torch.stack([lo, hi], dim=-1).reshape(M, -1)`
			`x_deq = ((x_nib >> 3).float() * -2 + 1) * _E2M1_MAGNITUDES.to(device)[(x_nib & 0x07)]`
			`x_recon = (x_deq * x_sf.to(torch.float32).repeat_interleave(16, dim=-1)).to(torch.bfloat16)`

			`w_u8 = w_fp4.view(torch.uint8)`
			`wlo = (w_u8 & 0x0F).long(); whi = ((w_u8 >> 4) & 0x0F).long()`
			`w_nib = torch.stack([wlo, whi], dim=-1).reshape(w_u8.shape[0]*2, w_u8.shape[1])`
			`w_deq = ((w_nib >> 3).float() * -2 + 1) * _E2M1_MAGNITUDES.to(device)[(w_nib & 0x07)]`
			`w_recon = (w_deq * w_sf.to(torch.float32).repeat_interleave(16, dim=0)).to(torch.bfloat16)`

			`quant_ref = torch.nn.functional.linear(x_recon, w_recon.T)`
			`nvfp4_out = cutlass_nvfp4_blockscaled_gemm(x_fp4, x_sf, w_fp4, w_sf, M, N, K, alpha=1.0)`
			`cos = torch.nn.functional.cosine_similarity(nvfp4_out.float(), quant_ref.float(), dim=-1).mean().item()`
			`print(f"M={M} N={N} K={K} cosine={cos:.6f}")`
			`print(f"NVFP4 first 8: {nvfp4_out[0,:8].tolist()}")`
			`print(f"REF first 8: {quant_ref[0,:8].tolist()}")`