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- from functools import partial
- import math
- import torch
- import torch.nn as nn
- import torch.nn.functional as F
- import time
- try:
- import cudnn
- except ImportError:
- cudnn = None
- from einops import rearrange, repeat
- # from flash_attn.utils.benchmark import benchmark_forward, benchmark_backward, benchmark_combined, benchmark_all, benchmark_fwd_bwd, pytorch_profiler
- from flash_attn.utils.benchmark import benchmark_forward, benchmark_backward, benchmark_combined, benchmark_all, benchmark_fwd_bwd, pytorch_profiler
- from flash_attn.flash_attn_interface import flash_attn_func
- from flash_attn_interface import flash_attn_func as flash_attn_func_v3, flash_attn_varlen_func as flash_attn_varlen_func_v3
- # Need to install triton nightly:
- # pip install -U --index-url https://aiinfra.pkgs.visualstudio.com/PublicPackages/_packaging/Triton-Nightly/pypi/simple/ triton-nightly
- try:
- from triton_fused_attention import attention as triton_attention
- except ImportError:
- triton_attention = None
- def flops(batch, nheads, seqlen_q, seqlen_k, headdim, causal=False, mode='fwd'):
- assert mode in ["fwd", "bwd", "fwd_bwd"]
- f = 4 * batch * seqlen**2 * nheads * headdim // (2 if causal else 1)
- return f if mode == "fwd" else (2.5 * f if mode == "bwd" else 3.5 * f)
- def convert_to_cudnn_type(torch_type):
- if torch_type == torch.float16:
- return cudnn.data_type.HALF
- elif torch_type == torch.bfloat16:
- return cudnn.data_type.BFLOAT16
- elif torch_type == torch.float32:
- return cudnn.data_type.FLOAT
- elif torch_type == torch.int32:
- return cudnn.data_type.INT32
- elif torch_type == torch.int64:
- return cudnn.data_type.INT64
- else:
- raise ValueError("Unsupported tensor data type.")
- def cudnn_sdpa_setup(q, k, v, grad, causal=False):
- b, nheads, seqlen_q, headdim = q.shape
- _, _, seqlen_k, _ = k.shape
- assert v.shape == (b, nheads, seqlen_k, headdim)
- assert cudnn is not None, 'CUDNN is not available'
- q_gpu, k_gpu, v_gpu = q, k, v
- o_gpu = torch.empty_like(q_gpu)
- stats_gpu = torch.empty(b, nheads, seqlen_q, 1, dtype=torch.float32, device=q.device)
- graph_forward = cudnn.pygraph(
- io_data_type=convert_to_cudnn_type(q.dtype),
- intermediate_data_type=cudnn.data_type.FLOAT,
- compute_data_type=cudnn.data_type.FLOAT,
- )
- q_forward = graph_forward.tensor_like(q_gpu.detach())
- k_forward = graph_forward.tensor_like(k_gpu.detach())
- v_forward = graph_forward.tensor_like(v_gpu.detach())
- o_forward, stats_forward = graph_forward.sdpa(
- name="sdpa",
- q=q_forward,
- k=k_forward,
- v=v_forward,
- is_inference=False,
- attn_scale=1.0 / math.sqrt(headdim),
- use_causal_mask=causal,
- )
- o_forward.set_output(True).set_dim(o_gpu.shape).set_stride(o_gpu.stride())
- stats_forward.set_output(True).set_data_type(cudnn.data_type.FLOAT)
- graph_forward.validate()
- graph_forward.build_operation_graph()
- graph_forward.create_execution_plans([cudnn.heur_mode.A, cudnn.heur_mode.FALLBACK])
- graph_forward.check_support()
- graph_forward.build_plans()
- variant_pack_forward = {
- q_forward: q_gpu,
- k_forward: k_gpu,
- v_forward: v_gpu,
- o_forward: o_gpu,
- stats_forward: stats_gpu,
- }
- dQ_gpu = torch.empty_like(q_gpu)
- dK_gpu = torch.empty_like(k_gpu)
- dV_gpu = torch.empty_like(v_gpu)
- dO_gpu = grad
- graph_backward = cudnn.pygraph(
- io_data_type=cudnn.data_type.HALF,
- intermediate_data_type=cudnn.data_type.FLOAT,
- compute_data_type=cudnn.data_type.FLOAT,
- )
-
- q_backward = graph_backward.tensor_like(q_gpu.detach())
- k_backward = graph_backward.tensor_like(k_gpu.detach())
- v_backward = graph_backward.tensor_like(v_gpu.detach())
- o_backward = graph_backward.tensor_like(o_gpu.detach())
- dO_backward = graph_backward.tensor_like(dO_gpu.detach())
- stats_backward = graph_backward.tensor_like(stats_gpu.detach())
-
- dQ_backward, dK_backward, dV_backward = graph_backward.sdpa_backward(
- name="sdpa_backward",
- q=q_backward,
- k=k_backward,
- v=v_backward,
- o=o_backward,
- dO=dO_backward,
- stats=stats_backward,
- attn_scale=1.0 / math.sqrt(headdim),
- use_causal_mask=causal,
- )
-
- dQ_backward.set_output(True).set_dim(dQ_gpu.size()).set_stride(dQ_gpu.stride())
- dK_backward.set_output(True).set_dim(dK_gpu.size()).set_stride(dK_gpu.stride())
- dV_backward.set_output(True).set_dim(dV_gpu.size()).set_stride(dV_gpu.stride())
-
- graph_backward.validate()
- graph_backward.build_operation_graph()
- graph_backward.create_execution_plans([cudnn.heur_mode.A, cudnn.heur_mode.FALLBACK])
- graph_backward.check_support()
- graph_backward.build_plans()
- variant_pack_backward = {
- q_backward: q_gpu,
- k_backward: k_gpu,
- v_backward: v_gpu,
- o_backward: o_gpu,
- dO_backward: dO_gpu,
- stats_backward: stats_gpu,
- dQ_backward: dQ_gpu,
- dK_backward: dK_gpu,
- dV_backward: dV_gpu,
- }
- workspace = torch.empty(
- max(graph_forward.get_workspace_size(), graph_backward.get_workspace_size()),
- device="cuda", dtype=torch.uint8
- )
- def run_fwd(*args, **kwargs):
- graph_forward.execute(variant_pack_forward, workspace)
- return o_gpu, stats_gpu
- def run_bwd(*args, **kwargs):
- graph_backward.execute(variant_pack_backward, workspace)
- return dQ_gpu, dK_gpu, dV_gpu
- return run_fwd, run_bwd
- torch.manual_seed(0)
- repeats = 100
- dropout_p = 0.0
- causal = False
- dtype = torch.float16
- device = 'cuda'
- verbose = False
- batch_size = 2
- # seqlen = 2048
- seqlen = 8192
- # seqlen = 4096
- # seqlen = 2047
- dim = 2048
- # headdim = 128
- # headdim = 64
- headdim = 256
- # for mode in ['fwd', 'bwd']:
- for mode in ['fwd']:
- for headdim in [64, 128, 256]:
- # for headdim in [128]:
- for seqlen in [1024, 2048, 4096, 8192, 16384, 32768]:
- # for seqlen in [8192]:
- nheads = dim // headdim
- # nheads = 24
- # headdim = 64
- # batch_size = 64
- # seqlen = 512
- # nheads = 8
- # headdim = 128
- nheads_kv = nheads
-
- qkv = torch.randn(batch_size, seqlen, 3, nheads, headdim, device=device, dtype=dtype,
- requires_grad=True)
- q = torch.randn(batch_size, seqlen, nheads, headdim, device=device, dtype=dtype, requires_grad=True)
- k = torch.randn(batch_size, seqlen, nheads, headdim, device=device, dtype=dtype, requires_grad=True)
- v = torch.randn(batch_size, seqlen, nheads, headdim, device=device, dtype=dtype, requires_grad=True)
- q_t = q.transpose(1, 2).contiguous().detach().requires_grad_()
- k_t = k.transpose(1, 2).contiguous().detach().requires_grad_()
- v_t = k.transpose(1, 2).contiguous().detach().requires_grad_()
- grad = torch.randn(batch_size, seqlen, nheads, headdim, device=device, dtype=dtype)
- grad_t = grad.transpose(1, 2).contiguous()
-
- bench_fn = benchmark_forward if mode == 'fwd' else partial(benchmark_backward, grad=grad)
- for causal in [False, True]:
- # for causal in [True]:
- print(f"\n### {headdim = }, {seqlen = }, {causal = } ###")
- if headdim <= 128 and cudnn is not None:
- cudnn_sdpa_fwd, cudnn_sdpa_bwd = cudnn_sdpa_setup(q.transpose(1, 2), k.transpose(1, 2), v.transpose(1, 2), grad.transpose(1, 2), causal=causal)
- f = flops(batch_size, nheads, seqlen, seqlen, headdim, causal=causal, mode=mode)
- _, m0 = bench_fn(flash_attn_func, q, k, v, dropout_p, causal=causal, repeats=repeats, verbose=verbose, desc='Fav2')
- if mode == 'bwd':
- ref_dv, v.grad = v.grad.clone(), None
- ref_dk, k.grad = k.grad.clone(), None
- ref_dq, q.grad = q.grad.clone(), None
- # pytorch_profiler(flash_attn_func, q, k, v, dropout_p, causal=causal, backward=False)
- if headdim <= 128:
- if triton_attention is not None:
- if mode == 'fwd':
- time.sleep(1) # Sleep to avoid residual power throttling from the previous benchmark
- _, m3 = benchmark_forward(triton_attention, q_t, k_t, v_t, causal, 1 / math.sqrt(headdim), repeats=repeats, verbose=verbose, desc='Triton')
- # TODO: fix Triton numeric errors.
- # if mode == 'bwd':
- # dv, v_t.grad = v_t.grad.clone(), None
- # dk, k_t.grad = k_t.grad.clone(), None
- # dq, q_t.grad = q_t.grad.clone(), None
- # torch.testing.assert_close(ref_dv, dv.transpose(1, 2), atol=0.05, rtol=0.05)
- # torch.testing.assert_close(ref_dk, dk.transpose(1, 2), atol=0.05, rtol=0.05)
- # torch.testing.assert_close(ref_dq, dq.transpose(1, 2), atol=0.05, rtol=0.05)
- if cudnn is not None:
- time.sleep(1) # Sleep to avoid residual power throttling from the previous benchmark
- if mode == 'fwd':
- _, m2 = benchmark_forward(cudnn_sdpa_fwd, repeats=repeats, verbose=verbose, desc='CuDNN')
- else:
- cudnn_sdpa_fwd()
- _, m2 = benchmark_forward(cudnn_sdpa_bwd, repeats=repeats, verbose=verbose, desc='CuDNN')
- dq, dk, dv = cudnn_sdpa_bwd()
- torch.testing.assert_close(ref_dv, dv.transpose(1, 2), atol=0.05, rtol=0.05)
- torch.testing.assert_close(ref_dk, dk.transpose(1, 2), atol=0.05, rtol=0.05)
- torch.testing.assert_close(ref_dq, dq.transpose(1, 2), atol=0.05, rtol=0.05)
- # pytorch_profiler(cudnn_sdpa, backward=False)
- if headdim == 128 or mode == 'fwd':
- time.sleep(1)
- _, m1 = bench_fn(flash_attn_func_v3, q, k, v, causal=causal, repeats=repeats, verbose=verbose, desc='Fav3')
- q_var = q.reshape(-1, q.shape[-2], q.shape[-1])
- k_var = k.reshape(-1, k.shape[-2], k.shape[-1])
- v_var = v.reshape(-1, v.shape[-2], v.shape[-1])
- lens = torch.full([q.shape[0]], seqlen, dtype=torch.int32)
- cu_seqlens = torch.cat([torch.tensor([0], dtype=torch.int32), torch.cumsum(lens, dim=0, dtype=torch.int32)]).cuda()
- time.sleep(1)
- _, m1_var = bench_fn(flash_attn_varlen_func_v3, q_var, k_var, v_var, cu_seqlens, cu_seqlens, seqlen, seqlen, causal=causal, repeats=repeats, verbose=verbose, desc='Fav3 var len')
- if mode == 'bwd':
- dv, v.grad = v.grad.clone(), None
- dk, k.grad = k.grad.clone(), None
- dq, q.grad = q.grad.clone(), None
- torch.testing.assert_close(ref_dv, dv, atol=0.05, rtol=0.05)
- torch.testing.assert_close(ref_dk, dk, atol=0.05, rtol=0.05)
- torch.testing.assert_close(ref_dq, dq, atol=0.05, rtol=0.05)
-
- # pytorch_profiler(flash_attn_func_v3, q, k, v, causal=causal, backward=False)
- print(f'Fav2: {m0.mean * 1e3:.3f}ms, {(f / m0.mean * 1e-12):.1f} TFLOPS')
- if headdim <= 128:
- if triton_attention is not None:
- print(f'Triton: {m3.mean * 1e3:.3f}ms, {(f / m3.mean * 1e-12):.1f} TFLOPS')
- if cudnn is not None:
- print(f'CuDNN: {m2.mean * 1e3:.3f}ms, {(f / m2.mean * 1e-12):.1f} TFLOPS')
- if headdim == 128 or mode == 'fwd':
- print(f'Fav3: {m1.mean * 1e3:.3f}ms, {(f / m1.mean * 1e-12):.1f} TFLOPS')
- print(f'Fav3 varlen: {m1_var.mean * 1e3:.3f}ms, {(f / m1_var.mean * 1e-12):.1f} TFLOPS')
-
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