import torch import torch.nn.functional as F import tilelang from tilelang.autotuner import * import tilelang.language as T from tilelang.carver.arch import driver from einops import rearrange, einsum import argparse @tilelang.jit( out_idx=[6], pass_configs={ tilelang.PassConfigKey.TL_ENABLE_FAST_MATH: True, }) def flashattn(batch, heads, kv_head_num, seqlen_kv, dim, pe_dim, block_N, block_H, num_split): scale = (1.0 / (dim + pe_dim))**0.5 * 1.44269504 # log2(e) dtype = "float16" accum_dtype = "float" kv_group_num = heads // kv_head_num VALID_BLOCK_H = min(block_H, kv_group_num) assert kv_head_num == 1, "kv_head_num must be 1" sm_num = driver.get_num_sms() @T.prim_func def main_split_persistent( Q: T.Tensor([batch, heads, dim], dtype), Q_pe: T.Tensor([batch, heads, pe_dim], dtype), KV: T.Tensor([batch, seqlen_kv, kv_head_num, dim], dtype), K_pe: T.Tensor([batch, seqlen_kv, kv_head_num, pe_dim], dtype), glse: T.Tensor([batch, heads, num_split], dtype), Output_partial: T.Tensor([batch, heads, num_split, dim], dtype), Output: T.Tensor([batch, heads, dim], dtype), ): with T.Kernel(sm_num, threads=256) as (block_id): Q_shared = T.alloc_shared([block_H, dim], dtype) S_shared = T.alloc_shared([block_H, block_N], dtype) Q_pe_shared = T.alloc_shared([block_H, pe_dim], dtype) KV_shared = T.alloc_shared([block_N, dim], dtype) K_pe_shared = T.alloc_shared([block_N, pe_dim], dtype) # O_shared = T.alloc_shared([block_H, dim], dtype) acc_s = T.alloc_fragment([block_H, block_N], accum_dtype) acc_s_cast = T.alloc_fragment([block_H, block_N], dtype) acc_o = T.alloc_fragment([block_H, dim], accum_dtype) scores_max = T.alloc_fragment([block_H], accum_dtype) scores_max_prev = T.alloc_fragment([block_H], accum_dtype) scores_scale = T.alloc_fragment([block_H], accum_dtype) scores_sum = T.alloc_fragment([block_H], accum_dtype) logsum = T.alloc_fragment([block_H], accum_dtype) po_local = T.alloc_fragment([dim], dtype) o_accum_local = T.alloc_fragment([dim], accum_dtype) lse_local_split = T.alloc_local([1], accum_dtype) lse_logsum_local = T.alloc_local([1], accum_dtype) lse_max_local = T.alloc_local([1], accum_dtype) scale_local = T.alloc_local([1], accum_dtype) T.annotate_layout({ # O_shared: tilelang.layout.make_swizzled_layout(O_shared), S_shared: tilelang.layout.make_swizzled_layout(S_shared), lse_logsum_local: T.Fragment(lse_logsum_local.shape, forward_thread_fn=lambda i: i), }) T.use_swizzle(10) total_tiles = batch * (heads // min(block_H, kv_group_num)) * num_split waves = T.ceildiv(total_tiles, sm_num) for w in T.serial(waves): tile_id = sm_num * w + block_id bid = tile_id // ((heads // min(block_H, kv_group_num)) * num_split) hid = tile_id // num_split % (heads // min(block_H, kv_group_num)) sid = tile_id % num_split cur_kv_head = hid // (kv_group_num // block_H) if bid < batch and hid * VALID_BLOCK_H < heads and sid < num_split: T.copy(Q[bid, hid * VALID_BLOCK_H:(hid + 1) * VALID_BLOCK_H, :], Q_shared) T.copy(Q_pe[bid, hid * VALID_BLOCK_H:(hid + 1) * VALID_BLOCK_H, :], Q_pe_shared) T.fill(acc_o, 0) T.fill(logsum, 0) T.fill(scores_max, -T.infinity(accum_dtype)) loop_range = T.ceildiv((seqlen_kv // num_split), block_N) for k in T.Pipelined(loop_range, num_stages=2): kv_start = (seqlen_kv // num_split) * sid + k * block_N kv_end = (seqlen_kv // num_split) * sid + (k + 1) * block_N T.copy(KV[bid, kv_start:kv_end, cur_kv_head, :], KV_shared) T.copy(K_pe[bid, kv_start:kv_end, cur_kv_head, :], K_pe_shared) T.clear(acc_s) T.gemm( Q_shared, KV_shared, acc_s, transpose_B=True, policy=T.GemmWarpPolicy.FullCol) T.gemm( Q_pe_shared, K_pe_shared, acc_s, transpose_B=True, policy=T.GemmWarpPolicy.FullCol) T.copy(scores_max, scores_max_prev) T.fill(scores_max, -T.infinity(accum_dtype)) T.reduce_max(acc_s, scores_max, dim=1, clear=False) for i in T.Parallel(block_H): scores_scale[i] = T.exp2(scores_max_prev[i] * scale - scores_max[i] * scale) for i, j in T.Parallel(block_H, block_N): acc_s[i, j] = T.exp2(acc_s[i, j] * scale - scores_max[i] * scale) T.reduce_sum(acc_s, scores_sum, dim=1) T.copy(acc_s, S_shared) T.copy(S_shared, acc_s_cast) for i in T.Parallel(block_H): logsum[i] = logsum[i] * scores_scale[i] + scores_sum[i] for i, j in T.Parallel(block_H, dim): acc_o[i, j] *= scores_scale[i] T.gemm(acc_s_cast, KV_shared, acc_o, policy=T.GemmWarpPolicy.FullCol) for i, j in T.Parallel(block_H, dim): acc_o[i, j] /= logsum[i] for i in T.Parallel(block_H): logsum[i] = T.log2(logsum[i]) + scores_max[i] * scale T.copy(logsum, glse[bid, hid * VALID_BLOCK_H:(hid + 1) * VALID_BLOCK_H, sid]) # T.copy(acc_o, O_shared) T.copy( acc_o, Output_partial[bid, hid * VALID_BLOCK_H:(hid + 1) * VALID_BLOCK_H, sid, :]) T.sync_grid() waves = T.ceildiv(heads * batch, sm_num) for w in T.serial(waves): tile_id = sm_num * w + block_id hid = tile_id // batch bid = tile_id % batch if bid < batch and hid < heads: T.clear(lse_logsum_local) T.clear(o_accum_local) lse_max_local[0] = -T.infinity(accum_dtype) for k in T.serial(num_split): lse_max_local[0] = T.max(lse_max_local[0], glse[bid, hid, k]) for k in T.Pipelined(num_split, num_stages=1): lse_local_split[0] = glse[bid, hid, k] lse_logsum_local[0] += T.exp2(lse_local_split[0] - lse_max_local[0]) lse_logsum_local[0] = T.log2(lse_logsum_local[0]) + lse_max_local[0] for k in T.serial(num_split): for i in T.Parallel(dim): po_local[i] = Output_partial[bid, hid, k, i] lse_local_split[0] = glse[bid, hid, k] scale_local[0] = T.exp2(lse_local_split[0] - lse_logsum_local[0]) for i in T.Parallel(dim): o_accum_local[i] += po_local[i] * scale_local[0] for i in T.Parallel(dim): Output[bid, hid, i] = o_accum_local[i] return main_split_persistent def ref_program(q, q_pe, kv, k_pe, glse, Output_partial): # """ # Inputs: # - q (Tensor): [batch, heads, dim] # - q_pe (Tensor): [batch, heads, pe_dim] # - kv (Tensor): [batch, seqlen_kv, kv_head_num, dim] # - k_pe (Tensor): [batch, seqlen_kv, kv_head_num, pe_dim] # - glse (Tensor): [batch, heads, num_split] # - Output_partial (Tensor): [batch, heads, num_split, dim] # Outputs: # - output (Tensor): [batch, heads, dim] # """ dim = q.shape[-1] pe_dim = q_pe.shape[-1] num_head_groups = q.shape[1] // kv.shape[2] scale = (dim + pe_dim)**0.5 q = rearrange( q, 'b (h g) d -> b g h d', g=num_head_groups) # [batch_size, num_head_groups, groups, dim] q_pe = rearrange( q_pe, 'b (h g) d -> b g h d', g=num_head_groups) # [batch_size, num_head_groups, groups, pe_dim] kv = rearrange(kv, 'b n h d -> b h n d') # [batch_size, groups, seqlen_kv, dim] k_pe = rearrange(k_pe, 'b n h d -> b h n d') # [batch_size, num_head_groups, groups, pe_dim] query = torch.concat([q, q_pe], dim=-1) key = torch.concat([kv, k_pe], dim=-1) scores = einsum( query, key, 'b g h d, b h s d -> b g h s') # [batch_size, num_head_groups, groups, seqlen_kv] attention = F.softmax( scores / scale, dim=-1) # [batch_size, num_head_groups, groups, seqlen_kv] out = einsum(attention, kv, 'b g h s, b h s d -> b g h d') # [batch_size, num_head_groups, groups, dim] out = rearrange(out, 'b g h d -> b (h g) d') # [batch_size, heads, dim] return out def main(): parser = argparse.ArgumentParser() parser.add_argument('--batch', type=int, default=128, help='batch size') parser.add_argument('--heads', type=int, default=128, help='q heads number') parser.add_argument('--kv_heads', type=int, default=1, help='kv heads number') parser.add_argument('--kv_ctx', type=int, default=8192, help='kv context length') parser.add_argument('--dim', type=int, default=512, help='head dim') parser.add_argument('--pe_dim', type=int, default=64, help='pe head dim') args = parser.parse_args() batch, heads, kv_heads, kv_ctx, dim, pe_dim = args.batch, args.heads, args.kv_heads, args.kv_ctx, args.dim, args.pe_dim qk_flops = 2 * batch * heads * kv_ctx * (dim + pe_dim) pv_flops = 2 * batch * heads * kv_ctx * dim total_flops = qk_flops + pv_flops BLOCK_N = 64 BLOCK_H = 64 num_split = 2 kernel = flashattn(batch, heads, kv_heads, kv_ctx, dim, pe_dim, BLOCK_N, BLOCK_H, num_split) print(kernel.get_kernel_source()) profiler = kernel.get_profiler(tensor_supply_type=tilelang.TensorSupplyType.Randn) profiler.assert_allclose(ref_program, rtol=0.01, atol=0.01) latency = profiler.do_bench(warmup=500) print(f"Latency: {latency} ms") print(f"TFlops: {total_flops / latency * 1e-9} TFlops") if __name__ == "__main__": main()