/* Pure-C test: nvcc -I csrc -arch=sm_89 -O3 \ --use_fast_math --ptxas-options=-O3 --extra-device-vectorization \ csrc/tests/attn_decode_test.cu -o test && ./test */ #include "test_utils.cuh" #include "../kernels/attn_decode_split_kv.cuh" #ifndef ASTRAI_NO_MMA #include "../kernels/attn_decode_split_kv_mma.cuh" #endif // Split-K scratch (torch-free): the production launcher allocates these from // torch; here we pass pre-allocated device buffers so the bench loop doesn't // pay a cudaMalloc per iteration. Size for the maximum split count (32). struct DecodeScratch { float* o_part = nullptr; float* ml_part = nullptr; }; // Launch the production decode path (tensor-core head-packing MMA on sm_80+, // scalar fallback otherwise), mirroring dispatch_decode() in attn_decode.cu. #ifndef ASTRAI_NO_MMA static bool decode_use_mma(const AttentionParams& p) { int G = p.q_head / p.kv_head; return !p.use_mask && G > 1 && G <= 16; } template static void launch_mma_decode(AttentionParams& p, DecodeScratch& sc) { int tiles_total = (p.kv_len + BC - 1) / BC; p.num_splits = compute_num_splits(p.batch * p.kv_head, tiles_total); p.o_part = sc.o_part; p.ml_part = sc.ml_part; attn_decode_split_kv_mma_kernel <<>>(p); attn_decode_combine_kernel<<>>(p); } #endif static void launch_scalar_decode(AttentionParams& p, DecodeScratch& sc) { int gs = p.q_head / p.kv_head; int chunks_total = (p.kv_len + DC_CHUNK - 1) / DC_CHUNK; p.num_splits = compute_num_splits(p.batch * p.kv_head, chunks_total); p.o_part = sc.o_part; p.ml_part = sc.ml_part; size_t smem = DC_CHUNK * p.head_dim * sizeof(bf16); attn_decode_split_kv_kernel<<>>(p); attn_decode_combine_kernel<<>>(p); } template static void dispatch_decode_t(AttentionParams& p, DecodeScratch& sc) { #ifndef ASTRAI_NO_MMA if (decode_use_mma(p)) { launch_mma_decode(p, sc); return; } #endif launch_scalar_decode(p, sc); } static void dispatch_decode(AttentionParams& p, DecodeScratch& sc) { dispatch_by_head_dim(p.head_dim, [&]() { dispatch_decode_t(p, sc); }); } // Warmed-up, CUDA-event timed sweep over the production decode MMA path. static void bench() { const int cfgs[][5] = { {1, 32, 4, 512, 128}, // B, Hq, Hk, kv_len, D {1, 32, 4, 1024, 128}, {1, 32, 4, 2048, 128}, {1, 32, 4, 4096, 128}, {16, 32, 4, 2048, 128}, {32, 32, 4, 1024, 128}, }; const int WARMUP = 10, ITERS = 100; printf("\n===== DECODE BENCH (warmup=%d iters=%d) =====\n", WARMUP, ITERS); print_bench_header(); for (int ci = 0; ci < 6; ci++) { int B = cfgs[ci][0], Hq = cfgs[ci][1], Hk = cfgs[ci][2]; int sl = cfgs[ci][3], D = cfgs[ci][4]; size_t nQ = (size_t)B * Hq * D; size_t nKV = (size_t)B * Hk * sl * D; bf16 *dQ, *dK, *dV, *dO; cudaMalloc(&dQ, nQ*2); cudaMalloc(&dK, nKV*2); cudaMalloc(&dV, nKV*2); cudaMalloc(&dO, nQ*2); size_t big = nQ > nKV ? nQ : nKV; bf16* tmp = new bf16[big]; for (size_t i = 0; i < nQ; i++) tmp[i] = f2bf(randf()); cudaMemcpy(dQ, tmp, nQ*2, cudaMemcpyHostToDevice); for (size_t i = 0; i < nKV; i++) tmp[i] = f2bf(randf()); cudaMemcpy(dK, tmp, nKV*2, cudaMemcpyHostToDevice); for (size_t i = 0; i < nKV; i++) tmp[i] = f2bf(randf()); cudaMemcpy(dV, tmp, nKV*2, cudaMemcpyHostToDevice); delete[] tmp; AttentionParams p; p.batch = B; p.q_head = Hq; p.kv_head = Hk; p.q_len = 1; p.kv_len = sl; p.head_dim = D; p.use_mask = 0; p.causal_offset = -1; p.scale = 1.0f / sqrtf((float)D); set_default_strides(p); p.q = dQ; p.k = dK; p.v = dV; p.mask = nullptr; p.o = dO; DecodeScratch sc; cudaMalloc(&sc.o_part, (size_t)B*Hq*32*D*sizeof(float)); cudaMalloc(&sc.ml_part, (size_t)B*Hq*32*2*sizeof(float)); auto launch = [&]() { dispatch_decode(p, sc); }; double flops = 4.0 * B * Hq * (double)sl * D; double bytes = 2.0 * (2.0 * nKV * sizeof(bf16)); BenchResult r = bench_kernel(launch, WARMUP, ITERS, flops, bytes); char cfg[64]; snprintf(cfg, sizeof(cfg), "B=%2d Hq=%2d Hk=%d q=%4d kv=%4d D=%3d causal=%d", B, Hq, Hk, 1, sl, D, 0); print_bench_row(cfg, r); cudaFree(dQ); cudaFree(dK); cudaFree(dV); cudaFree(dO); cudaFree(sc.o_part); cudaFree(sc.ml_part); } } int main() { const int configs[][5] = { {1, 2, 1, 64, 32}, // B,Hq,Hk,seq_len,D {1, 32, 4, 512, 128}, {1, 32, 4, 1024, 128}, }; int n_cfgs = sizeof(configs) / sizeof(configs[0]); for (int ci = 0; ci < n_cfgs; ci++) { int B = configs[ci][0], Hq = configs[ci][1], Hk = configs[ci][2]; int sl = configs[ci][3], D = configs[ci][4], gs = Hq / Hk; printf("=== B=%d Hq=%d Hk=%d seq=%d D=%d gs=%d ===\n", B,Hq,Hk,sl,D,gs); size_t nQ = B*Hq*1*D, nKV = B*Hk*sl*D; float *hQ=new float[nQ], *hK=new float[nKV], *hV=new float[nKV]; for (size_t i=0;i p; p.batch=B; p.q_head=Hq; p.kv_head=Hk; p.q_len=1; p.kv_len=sl; p.head_dim=D; p.use_mask=0; p.causal_offset=-1; p.scale=1.0f/sqrtf((float)D); set_default_strides(p); p.q=dQ; p.k=dK; p.v=dV; p.mask=nullptr; p.o=dO; // Split-K scratch (max 32 splits), sized for the production MMA path. DecodeScratch sc; cudaMalloc(&sc.o_part, (size_t)B*Hq*32*D*sizeof(float)); cudaMalloc(&sc.ml_part, (size_t)B*Hq*32*2*sizeof(float)); double t0=now_ms(); dispatch_decode(p, sc); cudaDeviceSynchronize(); double kms=now_ms()-t0; cudaError_t err=cudaGetLastError(); if (err!=cudaSuccess){printf("CUDA err: %s\n",cudaGetErrorString(err));return 1;} bf16* hOut=new bf16[nQ]; cudaMemcpy(hOut,dO,nQ*2,cudaMemcpyDeviceToHost); float* ref=new float[nQ]; cpu_attention_ref(hQ, hK, hV, hMask, ref, B, Hq, Hk, 1, sl, D, -1); float max_err=0; for (size_t i=0;imax_err) max_err=d; } printf("kernel: %.3f ms max_err: %.6e\n\n",kms,max_err); cudaFree(dQ);cudaFree(dK);cudaFree(dV);cudaFree(dO);cudaFree(dMask); cudaFree(sc.o_part);cudaFree(sc.ml_part); delete[]hQ;delete[]hK;delete[]hV;delete[]hMask;delete[]hOut;delete[]ref;delete[]tmp; } printf("All tests passed!\n"); bench(); return 0; }