/** * Minimal test: PV via SS MMA with just 1 K-tile. * P(128,16) × V(16,16) → O(128,16) * A = P K-tile (128, 16) from SMEM, B = V K-tile (16, 16) from SMEM * Both in canonical K-major layout. * Tests if SS MMA can handle BLOCK_MN_A=128, BLOCK_MN_B=16. */ #include #include #include #include #include "dsv4/kernels/attention/fmha_common.cuh" #include "dsv4/kernels/attention/fmha_umma_desc.cuh" using namespace dsv4::kernels::attention; static bf16_t f32_to_bf16_host(float f) { uint32_t u; memcpy(&u,&f,4); return (uint16_t)(u>>16); } static float bf16_to_f32_host(bf16_t h) { uint32_t u=(uint32_t)h<<16; float f; memcpy(&f,&u,4); return f; } constexpr int HD = 16, BLOCK_MN = 128; __global__ void __launch_bounds__(128) test_pv_ss() { const int tid = threadIdx.x, wid = tid / 32, lane = tid % 32; extern __shared__ char sbuf[]; uint32_t* sTmemBase = (uint32_t*)sbuf; // A = P (128, 16) canonical — all 1.0 for row 0, 0 elsewhere bf16_t* sP = (bf16_t*)(((uintptr_t)(sbuf + 4) + 15) & ~(uintptr_t)15); // B = V (16, 16) canonical — all 2.0 bf16_t* sV = (bf16_t*)(((uintptr_t)(sP + 128 * 16) + 127) & ~(uintptr_t)127); // Fill P: (128, 16) canonical, row 0 = all 1.0 constexpr int CORES_MN = 128 / 8; // 16 constexpr int CORES_K = 16 / 8; // 2 for (int i = tid; i < 128 * 16; i += 128) sP[i] = 0; __syncthreads(); // Row 0: core_mn=0, local_r=0 for (int c = tid; c < 16; c += 128) { int ck = c / 8, lc = c % 8; int dst_idx = ck * CORES_MN * 64 + 0 * 64 + 0 * 8 + lc; sP[dst_idx] = f32_to_bf16(1.0f); } // Fill V: (16, 16) canonical, all 2.0 for (int i = tid; i < 16 * 16; i += 128) sV[i] = 0; __syncthreads(); for (int i = tid; i < 16 * 16; i += 128) { int r = i / 16, c = i % 16; int ck = c / 8, lc = c % 8; int tmn = r / 8, lr = r % 8; sV[ck * 2 * 64 + tmn * 64 + lr * 8 + lc] = f32_to_bf16(2.0f); } __syncthreads(); // TMEM alloc: 128 columns if (wid == 1) tmem_alloc(__cvta_generic_to_shared(sTmemBase), 128); __syncthreads(); uint32_t tb = *sTmemBase; // PV SS MMA: A=(128,16) BLOCK_MN=128, B=(16,16) BLOCK_MN=16 // C = A × B^T = (128, 16) → TMEM // Expected: C[0, 0..15] = 16.0 (1.0 * 2.0 * 8 core values... actually sum of 16 ones * 2.0 = 32.0, MMA scale 0.5 → 16.0) printf("Before PV: tid=%d\n", tid); uint64_t dp = make_umma_desc_kmajor_none(__cvta_generic_to_shared(sP), BLOCK_MN); uint64_t dv = make_umma_desc_kmajor_none(__cvta_generic_to_shared(sV), 16); uint32_t idesc = make_idesc(BLOCK_MN, HD); // MMA_M=8, MMA_N=1 if (tid == 0) umma_ss_f16(tb, dp, dv, idesc, false); asm volatile("tcgen05.fence::after_thread_sync;" ::: "memory"); __syncthreads(); printf("After PV: tid=%d\n", tid); // Read O from TMEM if (wid == 0) { float o_vals[HD]; for (int n = 0; n < HD / 8; n++) { float tmp[8]; asm volatile("tcgen05.ld.sync.aligned.32x32b.x8.b32 {%0,%1,%2,%3,%4,%5,%6,%7},[%8];" : "=f"(tmp[0]),"=f"(tmp[1]),"=f"(tmp[2]),"=f"(tmp[3]), "=f"(tmp[4]),"=f"(tmp[5]),"=f"(tmp[6]),"=f"(tmp[7]) : "r"(tb + n*8)); asm volatile("tcgen05.wait::ld.sync.aligned;"); if (lane == 0) for (int c=0;c<8;c++) o_vals[n*8+c] = tmp[c]; // Don't apply scale correction yet } if (lane == 0) { printf("O[0,0..15]: "); for (int d=0;d>>(); cudaError_t err = cudaDeviceSynchronize(); if (err != cudaSuccess) { printf("CUDA ERROR: %s\n", cudaGetErrorString(err)); return 1; } printf("PASS\n"); return 0; }