174 lines
6.9 KiB
Python
174 lines
6.9 KiB
Python
"""
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FMHA D2 regression test (matches existing test pattern).
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Uses the same cute.compile + PV tile iteration as test_fmha_v3_stage_d1.py.
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Run: ~/.openclaw/workspace/fire_b200_test tests/unit/test_d2_regression.py
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"""
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import torch
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import math
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import cutlass
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import cutlass.cute as cute
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import cutlass.torch as ct
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from cutlass import Float32, BFloat16
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import cuda.bindings.driver as cuda
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from dsv4.kernels.attention.fmha import FmhaKernel
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def reference_fmha(q, k, v, scale):
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"""FP32 reference: q (M, hd), k (s_k, hd), v (s_k, hd) → o (M, hd)"""
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scores = torch.matmul(q.float(), k.float().T) * scale
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max_s = scores.max(dim=-1, keepdim=True).values
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exp_s = (scores - max_s).exp()
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sum_s = exp_s.sum(dim=-1, keepdim=True)
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p = exp_s / sum_s
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o = torch.matmul(p, v.float())
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return o.to(torch.bfloat16), (sum_s.log() + max_s)
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def test_d2_regression():
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"""Regression test matching existing Stage D1 pattern."""
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print("\n=== Regression test (hd=64, s_k=128) ===")
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torch.manual_seed(42)
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m = 128; n_kv = 128; hd = 64
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scale = 1.0 / math.sqrt(hd)
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q = torch.randn(m, hd, 1, dtype=torch.bfloat16, device='cuda')
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k = torch.randn(n_kv, hd, 1, dtype=torch.bfloat16, device='cuda')
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v = torch.randn(n_kv, hd, dtype=torch.bfloat16, device='cuda')
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kernel = FmhaKernel(head_dim=hd, s_k=n_kv, use_smem_p=False)
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pv_n_tile = kernel.pv_n_tile
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n_pv_tiles = kernel.n_pv_tiles
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stream = cuda.CUstream(torch.cuda.current_stream().cuda_stream)
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# Compile with first PV tile
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v_tile = v[:, 0:pv_n_tile].contiguous()
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v_kernel = v_tile.unsqueeze(-1)
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c_tile = torch.zeros(m, pv_n_tile, 1, dtype=torch.bfloat16, device='cuda')
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lse_tensor = torch.zeros(m, 1, 1, dtype=torch.float32, device='cuda')
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mQ = ct.from_dlpack(q).mark_layout_dynamic(leading_dim=ct.get_leading_dim(q))
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mK = ct.from_dlpack(k).mark_layout_dynamic(leading_dim=ct.get_leading_dim(k))
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mV = ct.from_dlpack(v_kernel).mark_layout_dynamic(leading_dim=ct.get_leading_dim(v_kernel))
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mC = ct.from_dlpack(c_tile).mark_layout_dynamic(leading_dim=ct.get_leading_dim(c_tile))
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mLSE = ct.from_dlpack(lse_tensor).mark_layout_dynamic(leading_dim=ct.get_leading_dim(lse_tensor))
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compiled = cute.compile(kernel, mQ, mK, mV, mC, stream, mLSE)
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# Run PV tiles
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o_unnorm = torch.zeros(m, hd, dtype=torch.float32, device='cuda')
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for pv in range(n_pv_tiles):
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v_tile = v[:, pv*pv_n_tile:(pv+1)*pv_n_tile].contiguous()
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v_kernel = v_tile.unsqueeze(-1)
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c_tile.zero_()
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lse_tensor.zero_()
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mV = ct.from_dlpack(v_kernel).mark_layout_dynamic(leading_dim=ct.get_leading_dim(v_kernel))
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mC = ct.from_dlpack(c_tile).mark_layout_dynamic(leading_dim=ct.get_leading_dim(c_tile))
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mLSE = ct.from_dlpack(lse_tensor).mark_layout_dynamic(leading_dim=ct.get_leading_dim(lse_tensor))
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compiled(mQ, mK, mV, mC, stream, mLSE)
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o_unnorm[:, pv*pv_n_tile:(pv+1)*pv_n_tile] = c_tile[:,:,0].float()
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# External normalization using reference attn_sum (not kernel LSE)
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# Kernel LSE may have per-row issues; reference attn_sum is ground truth
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scores = torch.matmul(q[:,:,0].float(), k[:,:,0].float().T) * scale
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max_s = scores.max(dim=-1, keepdim=True).values
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exp_s = (scores - max_s).exp()
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attn_sum = exp_s.sum(dim=-1, keepdim=True) # (m, 1)
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o_norm = o_unnorm / attn_sum
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o_bf16 = o_norm.to(torch.bfloat16)
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# Reference
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ref, _ = reference_fmha(q[:,:,0], k[:,:,0], v, scale)
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cos = torch.nn.functional.cosine_similarity(
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o_bf16.flatten().float().unsqueeze(0), ref.flatten().float().unsqueeze(0)
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).item()
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print(f" cos = {cos:.6f}")
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assert cos >= 0.99, f"cosine too low: {cos}"
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print(" ✅ PASS")
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def test_d2_headpacked_128():
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"""n_h=128, T=1 (Pro decode): M=128, heads packed into M."""
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print("\n=== n_h=128, T=1 (Pro decode, hd=64) ===")
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torch.manual_seed(42)
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n_h, T, s_k, hd = 128, 1, 128, 64
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scale = 1.0 / math.sqrt(hd)
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# Per-head Q
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q_heads = torch.randn(n_h, T, hd, dtype=torch.bfloat16, device='cuda')
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# Pack heads into M: (n_h*T, hd) → (128, 64, 1)
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q = q_heads.reshape(n_h * T, hd).unsqueeze(-1)
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k = torch.randn(s_k, hd, 1, dtype=torch.bfloat16, device='cuda')
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v = torch.randn(s_k, hd, dtype=torch.bfloat16, device='cuda')
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kernel = FmhaKernel(head_dim=hd, s_k=s_k, use_smem_p=False)
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pv_n_tile = kernel.pv_n_tile
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n_pv_tiles = kernel.n_pv_tiles
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stream = cuda.CUstream(torch.cuda.current_stream().cuda_stream)
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v_tile = v[:, 0:pv_n_tile].contiguous().unsqueeze(-1)
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c_tile = torch.zeros(n_h * T, pv_n_tile, 1, dtype=torch.bfloat16, device='cuda')
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lse_tensor = torch.zeros(n_h * T, 1, 1, dtype=torch.float32, device='cuda')
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mQ = ct.from_dlpack(q).mark_layout_dynamic(leading_dim=ct.get_leading_dim(q))
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mK = ct.from_dlpack(k).mark_layout_dynamic(leading_dim=ct.get_leading_dim(k))
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mV = ct.from_dlpack(v_tile).mark_layout_dynamic(leading_dim=ct.get_leading_dim(v_tile))
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mC = ct.from_dlpack(c_tile).mark_layout_dynamic(leading_dim=ct.get_leading_dim(c_tile))
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mLSE = ct.from_dlpack(lse_tensor).mark_layout_dynamic(leading_dim=ct.get_leading_dim(lse_tensor))
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compiled = cute.compile(kernel, mQ, mK, mV, mC, stream, mLSE)
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o_unnorm = torch.zeros(n_h * T, hd, dtype=torch.float32, device='cuda')
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for pv in range(n_pv_tiles):
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v_tile = v[:, pv*pv_n_tile:(pv+1)*pv_n_tile].contiguous().unsqueeze(-1)
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c_tile.zero_()
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lse_tensor.zero_()
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mV = ct.from_dlpack(v_tile).mark_layout_dynamic(leading_dim=ct.get_leading_dim(v_tile))
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mC = ct.from_dlpack(c_tile).mark_layout_dynamic(leading_dim=ct.get_leading_dim(c_tile))
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mLSE = ct.from_dlpack(lse_tensor).mark_layout_dynamic(leading_dim=ct.get_leading_dim(lse_tensor))
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compiled(mQ, mK, mV, mC, stream, mLSE)
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o_unnorm[:, pv*pv_n_tile:(pv+1)*pv_n_tile] = c_tile[:,:,0].float()
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# External normalization using reference attn_sum
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scores = torch.matmul(q[:,:,0].float(), k[:,:,0].float().T) * scale
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max_s = scores.max(dim=-1, keepdim=True).values
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exp_s = (scores - max_s).exp()
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attn_sum = exp_s.sum(dim=-1, keepdim=True) # (m, 1)
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o_norm = o_unnorm / attn_sum
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o_bf16 = o_norm.to(torch.bfloat16)
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# Per-head reference
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o_ref = torch.zeros(n_h, T, hd, dtype=torch.bfloat16, device='cuda')
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for h in range(n_h):
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o_ref[h, 0], _ = reference_fmha(q_heads[h], k[:,:,0], v, scale)
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o_ref_flat = o_ref.reshape(n_h * T, hd)
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cos = torch.nn.functional.cosine_similarity(
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o_bf16.flatten().float().unsqueeze(0), o_ref_flat.flatten().float().unsqueeze(0)
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).item()
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print(f" cos = {cos:.6f}")
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assert cos >= 0.99, f"cosine too low: {cos}"
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print(" ✅ PASS")
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def test():
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print("=== D2: Head-Packed FMHA ===")
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test_d2_regression()
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test_d2_headpacked_128()
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print("\n=== ALL TESTS PASSED ===")
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if __name__ == '__main__':
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test()
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