import torch import math import triton from typing import Optional # Ensure CUDA is available and properly initialize device if not torch.cuda.is_available(): raise RuntimeError("CUDA is not available. This benchmark requires a CUDA-enabled GPU.") DEVICE = torch.device("cuda:0") torch.cuda.set_device(DEVICE) def alloc_fn(size: int, align: int, stream: Optional[int]): assert align == 128 assert stream == 0 return torch.empty(size, dtype=torch.int8, device=DEVICE) triton.set_allocator(alloc_fn) torch.manual_seed(0) try: torch.cuda.manual_seed_all(0) except Exception: pass assert triton.runtime.driver.active.get_current_target().backend == "cuda", "This benchmark only supports CUDA backend." def _bench_ms(fn): out = triton.testing.do_bench(fn, quantiles=[0.5]) if isinstance(out, (tuple, list)): return float(out[0]) return float(out) def _is_close(x: torch.Tensor, y: torch.Tensor, rtol=1e-2, atol=5e-3): return torch.allclose(x, y, rtol=rtol, atol=atol) def _pt_ragged(Q, K, V, row_lens): """ PyTorch baseline for ragged attention. Q:[M,D], K:[N,D], V:[N,Dv], row_lens:[M] -> O:[M,Dv] """ M, D = Q.shape N = K.shape[0] scale = 1.0 / math.sqrt(D) idx = torch.arange(N, device=Q.device) mask = idx.unsqueeze(0) < row_lens.to(idx.dtype).unsqueeze(1) scores = (Q @ K.T) * scale # [M,N] scores = scores.masked_fill(~mask, float("-inf")) P = torch.softmax(scores, dim=-1) O = (P @ V).to(torch.float16) return O def _cpu_ragged(Q, K, V, row_lens): # CPU baseline: move to CPU, compute, move back Q_cpu = Q.cpu().float() K_cpu = K.cpu().float() V_cpu = V.cpu().float() row_lens_cpu = row_lens.cpu() result_cpu = _pt_ragged(Q_cpu, K_cpu, V_cpu, row_lens_cpu) return result_cpu.to(DEVICE) def _bench_pair(M, N, Dq, Dv, len_min_ratio, answer_ragged_attn, baseline_ragged_attn=_pt_ragged): Q = torch.randn(M, Dq, device=DEVICE, dtype=torch.float16) K = torch.randn(N, Dq, device=DEVICE, dtype=torch.float16) V = torch.randn(N, Dv, device=DEVICE, dtype=torch.float16) low = max(1, int(N * len_min_ratio)) row_lens = torch.randint(low=low, high=N+1, size=(M,), device=DEVICE, dtype=torch.int32) Q32 = Q.float() K32 = K.float() V32 = V.float() # CPU baseline timing (synchronize before timing) torch.cuda.synchronize() import time cpu_times = [] for _ in range(10): start = time.perf_counter() _cpu_ragged(Q, K, V, row_lens) torch.cuda.synchronize() # Wait for CPU->GPU transfer cpu_times.append((time.perf_counter() - start) * 1000) # Convert to ms cpu_baseline_ms = sorted(cpu_times)[len(cpu_times)//2] # Median # GPU baseline timing (using float32 for baseline) gpu_baseline_ms = _bench_ms(lambda: baseline_ragged_attn(Q32, K32, V32, row_lens)) # Answer timing uses float16 answer_ms = _bench_ms(lambda: answer_ragged_attn(Q, K, V, row_lens)) # Correctness check against GPU baseline (using float32 for reference) ref = baseline_ragged_attn(Q32, K32, V32, row_lens) out = answer_ragged_attn(Q, K, V, row_lens) passed = _is_close(out, ref, rtol=1e-2, atol=5e-3) # Approximate FLOPs for attention: 2*M*N*Dq (QK^T) + 2*M*N*Dv (PV) flops = 2.0 * M * N * (Dq + Dv) to_tflops = lambda ms: flops * 1e-12 / (ms * 1e-3) if ms is not None else None return { "M": M, "N": N, "Dq": Dq, "Dv": Dv, "cpu_baseline_ms": cpu_baseline_ms, "gpu_baseline_ms": gpu_baseline_ms, "answer_ms": answer_ms, "baseline_ms": cpu_baseline_ms, # Keep for compatibility "baseline_tflops": to_tflops(gpu_baseline_ms), "answer_tflops": to_tflops(answer_ms), "close_passed": passed, "rtol": 1e-2, "atol": 5e-3, "passed": passed, } def _warmup_gpu(iters: int = 10): try: M, N, Dq, Dv = 1024, 1024, 64, 64 Q = torch.randn(M, Dq, device=DEVICE, dtype=torch.float16) K = torch.randn(N, Dq, device=DEVICE, dtype=torch.float16) V = torch.randn(N, Dv, device=DEVICE, dtype=torch.float16) row_lens = torch.randint(low=int(N*0.25), high=N+1, size=(M,), device=DEVICE, dtype=torch.int32) for _ in range(max(1, int(iters))): _ = _pt_ragged(Q.float(), K.float(), V.float(), row_lens) torch.cuda.synchronize() except Exception: pass def summarize_speedup(answer_ragged_attn, baseline_ragged_attn=None, print_output=False, metadata=None): # baseline_ragged_attn parameter kept for compatibility # Scoring: 0 points = 1x GPU baseline, 100 points = 3x GPU baseline # Warm up GPU to stabilize clocks and caches _warmup_gpu(10) # Get shapes from metadata or use defaults if metadata is None: metadata = {} shapes = metadata.get("shapes", None) if shapes is None: M_list = metadata.get("M_list", [512, 1024]) N = metadata.get("N", 1024) Dq = metadata.get("Dq", 64) Dv = metadata.get("Dv", 64) len_min_ratio = metadata.get("len_min_ratio", 0.25) shapes = [(M, N, Dq, Dv, len_min_ratio) for M in M_list] rows = [] for (M, N, Dq, Dv, len_min_ratio) in shapes: r = _bench_pair(M, N, Dq, Dv, len_min_ratio, answer_ragged_attn, _pt_ragged) rows.append(r) if print_output: print("\n=== Answer vs Baseline: Speedup for each shape (based on median time) ===") speedups_cpu = [] speedups_gpu = [] for r in rows: answer_time = r["answer_ms"] cpu_time = r.get("cpu_baseline_ms") gpu_time = r.get("gpu_baseline_ms") if cpu_time is not None and answer_time is not None: sp_cpu = cpu_time / answer_time speedups_cpu.append(sp_cpu) if gpu_time is not None and answer_time is not None: sp_gpu = gpu_time / answer_time speedups_gpu.append(sp_gpu) status = "OK" if r["close_passed"] else "FAIL" if print_output: print( f"M={r['M']:5d} N={r['N']:5d} Dq={r['Dq']:3d} Dv={r['Dv']:3d} " f"CPU={cpu_time:7.3f} ms GPU={gpu_time:7.3f} ms answer={answer_time:7.3f} ms " f"[Passed: {status} " f"rtol={r['rtol']:.1e} atol={r['atol']:.1e}]" ) if speedups_cpu: geo_mean_cpu = math.exp(sum(math.log(s) for s in speedups_cpu) / len(speedups_cpu)) else: geo_mean_cpu = 0.0 if speedups_gpu: geo_mean_gpu = math.exp(sum(math.log(s) for s in speedups_gpu) / len(speedups_gpu)) else: geo_mean_gpu = 0.0 if print_output: print("\n--- Summary ---") print(f"Geometric mean speedup vs CPU: {geo_mean_cpu:.3f}x") print(f"Geometric mean speedup vs GPU: {geo_mean_gpu:.3f}x") return rows, geo_mean_cpu, geo_mean_gpu, geo_mean_gpu # Last param kept for compatibility def run_benchmark(answer_ragged_attn, baseline_ragged_attn=None, print_output=False, metadata=None): # baseline_ragged_attn parameter kept for compatibility # Scoring: 0 points = 1x GPU baseline, 100 points = 3x GPU baseline rows, geo_mean_cpu, geo_mean_gpu, _ = summarize_speedup(answer_ragged_attn, baseline_ragged_attn, print_output=print_output, metadata=metadata) # Compute geometric mean CPU and GPU baseline times cpu_times = [r["cpu_baseline_ms"] for r in rows if r.get("cpu_baseline_ms") is not None] gpu_times = [r["gpu_baseline_ms"] for r in rows if r.get("gpu_baseline_ms") is not None] answer_times = [r["answer_ms"] for r in rows if r.get("answer_ms") is not None] geo_mean_cpu_time = math.exp(sum(math.log(t) for t in cpu_times) / len(cpu_times)) if cpu_times else 0.0 geo_mean_gpu_time = math.exp(sum(math.log(t) for t in gpu_times) / len(gpu_times)) if gpu_times else 0.0 geo_mean_answer_time = math.exp(sum(math.log(t) for t in answer_times) / len(answer_times)) if answer_times else 0.0 return { "rows": rows, "geometric_mean_speedup_cpu": geo_mean_cpu, "geometric_mean_speedup_gpu": geo_mean_gpu, "geometric_mean_speedup": geo_mean_gpu, # Keep for compatibility "arithmetic_mean_speedup": geo_mean_gpu, # Keep for compatibility "median_speedup": geo_mean_gpu, # Keep for compatibility "geo_mean_cpu_time": geo_mean_cpu_time, "geo_mean_gpu_time": geo_mean_gpu_time, "geo_mean_answer_time": geo_mean_answer_time, "pass_all": all(r["close_passed"] for r in rows), }