#!/usr/bin/env python3 import time import numpy as np import pytest import torch from sglang.srt.layers.quantization.kvfp4_tensor import KVFP4QuantizeUtil def calculate_accuracy_metrics( original: torch.Tensor, reconstructed: torch.Tensor ) -> dict[str, float]: """Calculate accuracy metrics between original and reconstructed tensors.""" mse = torch.mean((original - reconstructed) ** 2).item() mae = torch.mean(torch.abs(original - reconstructed)).item() # PSNR calculation max_val = torch.max(torch.abs(original)).item() psnr = 20 * np.log10(max_val / np.sqrt(mse)) if mse > 0 else float("inf") # Relative error rel_error = torch.mean( torch.abs(original - reconstructed) / (torch.abs(original) + 1e-8) ).item() return {"MSE": mse, "MAE": mae, "PSNR": psnr, "Relative Error": rel_error} def run_benchmark(m, n, k, num_runs=100) -> dict[str, dict[str, float]]: """Run FP8 vs KVFP4 quantization benchmark and return metrics.""" tensor_bf16 = torch.randn(m, n, k, dtype=torch.bfloat16, device="cuda") # --- FP8 --- for _ in range(3): # warmup _ = tensor_bf16 * 2 torch.cuda.synchronize() start = time.time() for _ in range(num_runs): tensor_fp8 = tensor_bf16.to(torch.float8_e4m3fn) torch.cuda.synchronize() fp8_quant_time = (time.time() - start) / num_runs start = time.time() for _ in range(num_runs): tensor_fp8_dequant = tensor_fp8.to(torch.bfloat16) torch.cuda.synchronize() fp8_dequant_time = (time.time() - start) / num_runs fp8_metrics = calculate_accuracy_metrics(tensor_bf16, tensor_fp8_dequant) # --- KVFP4 --- tensor_fp4, scale_factors = KVFP4QuantizeUtil.batched_quantize(tensor_bf16) _ = KVFP4QuantizeUtil.batched_dequantize(tensor_fp4, scale_factors) start = time.time() for _ in range(num_runs): tensor_fp4, scale_factors = KVFP4QuantizeUtil.batched_quantize(tensor_bf16) torch.cuda.synchronize() fp4_quant_time = (time.time() - start) / num_runs start = time.time() for _ in range(num_runs): tensor_fp4_dequant = KVFP4QuantizeUtil.batched_dequantize( tensor_fp4, scale_factors ) torch.cuda.synchronize() fp4_dequant_time = (time.time() - start) / num_runs fp4_metrics = calculate_accuracy_metrics(tensor_bf16, tensor_fp4_dequant) return { "fp8": { "quant_time": fp8_quant_time, "dequant_time": fp8_dequant_time, **fp8_metrics, }, "fp4": { "quant_time": fp4_quant_time, "dequant_time": fp4_dequant_time, **fp4_metrics, }, } # default tensor shapes (m, n, k) # [M, 1, 576]: DeepSeekR1-FP4 MLA # [M, 8, 64]: gpt-oss-20b MHA MNK_FACTORS = [ (64, 1, 576), (512, 1, 576), (1024, 1, 576), (4096, 1, 576), (2868672, 1, 576), (64, 8, 64), (512, 8, 64), (1024, 8, 64), (4096, 8, 64), (2868672, 8, 64), ] @pytest.mark.parametrize("m,n,k", MNK_FACTORS) def test_kvfp4_quant_dequant(m, n, k): """Benchmark FP8 vs KVFP4 for predefined tensor shapes.""" print(f"\n=== Running benchmark for tensor shape: [{m}, {n}, {k}] ===") results = run_benchmark(m, n, k) print("FP8:", results["fp8"]) print("FP4:", results["fp4"]) # Basic assertions to make sure metrics are reasonable assert results["fp4"]["MSE"] < 1.0 assert results["fp8"]["MSE"] < 1.0