nvfp4-megamoe-kernel/tests/unit/test_fmha_hd64_debug.cu

/**
 * Debug HD=64 PV precision — compare register-math PV vs SS MMA PV
 * to isolate where the 0.931 cosine error comes from.
 */

#include <cuda_runtime.h>
#include <cstdio>
#include <cmath>
#include <cstdlib>
#include <cstring>

#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 = 64, SK = 128, BLOCK_MN = 128;
constexpr int NKT_QK = HD / MMA_K_BF16;     // 4
constexpr int NKT_PV = SK / MMA_K_BF16;     // 8
constexpr int TILE_SZ = BLOCK_MN * MMA_K_BF16;  // 2048 BF16
constexpr int V_TILE_SZ = (HD / 8) * 2 * 64;  // 1024 BF16

__global__ void __launch_bounds__(128)
test_fmha_hd64_debug(const bf16_t* q, const bf16_t* k, const bf16_t* v,
                      bf16_t* o_mma, float* o_ref, float* o_regmath,
                      float scale)
{
    const int tid = threadIdx.x, wid = tid / 32, lane = tid % 32;

    extern __shared__ char sbuf[];
    uint32_t* sTmemBase = (uint32_t*)sbuf;
    bf16_t* sQ0 = (bf16_t*)(((uintptr_t)(sbuf + 4) + 15) & ~(uintptr_t)15);
    bf16_t* sK0 = sQ0 + NKT_QK * TILE_SZ;
    bf16_t* sPk = (bf16_t*)(((uintptr_t)(sK0 + NKT_QK * TILE_SZ) + 127) & ~(uintptr_t)127);
    bf16_t* sV = (bf16_t*)(((uintptr_t)(sPk + TILE_SZ) + 127) & ~(uintptr_t)127);
    float* s_p_vals = (float*)(sV + NKT_PV * V_TILE_SZ);

    // Load Q K-tiles
    for (int kt = 0; kt < NKT_QK; kt++) {
        bf16_t* sq = sQ0 + kt * TILE_SZ;
        for (int i = tid; i < TILE_SZ; i += 128) sq[i] = 0;
        for (int d = tid; d < MMA_K_BF16; d += 128) {
            int ck = d / 8, lc = d % 8;
            sq[ck * 16 * 64 + lc] = q[kt * MMA_K_BF16 + d];
        }
    }

    // Load K K-tiles
    for (int kt = 0; kt < NKT_QK; kt++) {
        bf16_t* sk = sK0 + kt * TILE_SZ;
        for (int i = tid; i < TILE_SZ; i += 128) sk[i] = 0;
        for (int r = 0; r < SK; r++) {
            for (int d = tid; d < MMA_K_BF16; d += 128) {
                int ck = d / 8, lc = d % 8;
                int tmn = r / 8, lr = r % 8;
                sk[ck * 16 * 64 + tmn * 64 + lr * 8 + lc] = k[r * HD + kt * MMA_K_BF16 + d];
            }
        }
    }

    // Load V K-tiles
    for (int kt = 0; kt < NKT_PV; kt++) {
        bf16_t* sv = sV + kt * V_TILE_SZ;
        for (int i = tid; i < V_TILE_SZ; i += 128) sv[i] = 0;
        for (int d = tid; d < HD; d += 128) {
            for (int lr = 0; lr < MMA_K_BF16; lr++) {
                int r = kt * MMA_K_BF16 + lr;
                int g_mn = d / 8, g_k = lr / 8;
                int llr = d % 8, lc = lr % 8;
                sv[g_k * 8 * 64 + g_mn * 64 + llr * 8 + lc] = v[d * SK + r];
            }
        }
    }
    __syncthreads();

    // TMEM alloc
    if (wid == 1) tmem_alloc(__cvta_generic_to_shared(sTmemBase), 128);
    __syncthreads();
    uint32_t tb = *sTmemBase;

    // ===== QK GEMM (4 K-tiles) =====
    {
        uint32_t idesc = make_idesc(BLOCK_MN, BLOCK_MN);
        for (int kt = 0; kt < NKT_QK; kt++) {
            bf16_t* sq = sQ0 + kt * TILE_SZ;
            bf16_t* sk = sK0 + kt * TILE_SZ;
            uint64_t dq = make_umma_desc_kmajor_none(__cvta_generic_to_shared(sq), BLOCK_MN);
            uint64_t dk = make_umma_desc_kmajor_none(__cvta_generic_to_shared(sk), BLOCK_MN);
            if (tid == 0) umma_ss_f16(tb, dq, dk, idesc, kt > 0);
            asm volatile("tcgen05.fence::after_thread_sync;" ::: "memory");
            __syncthreads();
        }
    }

    // ===== Softmax (warp 0, row 0 only for T=1 decode) =====
    if (wid == 0) {
        float s_vals[SK], row_max = -INFINITY;
        for (int n = 0; n < SK / 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++) {
                s_vals[n*8+c] = tmp[c] * scale;
                row_max = fmaxf(row_max, tmp[c] * scale);
            }
        }
        row_max = wmax(row_max);
        float row_sum = 0.0f;
        if (lane == 0) for (int j=0;j<SK;j++) {
            s_vals[j] = expf(s_vals[j] - row_max);
            row_sum += s_vals[j];
        }
        row_sum = wsum(row_sum);
        if (lane == 0) for (int j=0;j<SK;j++) s_vals[j] /= row_sum;
        if (lane == 0) for (int j=0;j<SK;j++) s_p_vals[j] = s_vals[j];
    }
    __syncthreads();

    // ===== PV Method 1: Register math (FP32, proven correct) =====
    if (tid == 0) {
        for (int d = 0; d < HD; d++) {
            float ov = 0.0f;
            for (int j = 0; j < SK; j++) ov += s_p_vals[j] * bf16_to_f32(v[d * SK + j]);
            o_regmath[d] = ov;
        }
    }

    // ===== PV Method 2: SS MMA with BLOCK_MN_B=64 =====
    {
        uint32_t idesc_pv = make_idesc(BLOCK_MN, HD);  // (128, 64)
        for (int kt = 0; kt < NKT_PV; kt++) {
            // Fill sPk from s_p_vals
            for (int i = tid; i < TILE_SZ; i += 128) sPk[i] = 0;
            if (tid < 16) {
                int c = tid;
                int ck = c / 8, lc = c % 8;
                sPk[ck * 16 * 64 + 0 * 64 + 0 * 8 + lc] = f32_to_bf16(s_p_vals[kt * MMA_K_BF16 + c]);
            }
            __syncthreads();

            bf16_t* sv = sV + kt * V_TILE_SZ;
            uint64_t dp = make_umma_desc_kmajor_none(__cvta_generic_to_shared(sPk), BLOCK_MN);
            uint64_t dv = make_umma_desc_kmajor_none(__cvta_generic_to_shared(sv), HD);
            if (tid == 0) umma_ss_f16(tb, dp, dv, idesc_pv, kt > 0);
            asm volatile("tcgen05.fence::after_thread_sync;" ::: "memory");
            __syncthreads();
        }
    }

    // Read MMA output 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];
        }
        if (lane == 0) for (int d=0;d<HD;d++) o_mma[d] = f32_to_bf16(o_vals[d]);
    }
    __syncthreads();

    // Scalar reference
    if (tid == 0) {
        float s[SK];
        for (int j=0;j<SK;j++) {
            float dot = 0.0f;
            for (int d=0;d<HD;d++) dot += bf16_to_f32(q[d]) * bf16_to_f32(k[j*HD+d]);
            s[j] = dot * scale;
        }
        float mx = -INFINITY;
        for (int j=0;j<SK;j++) mx = fmaxf(mx, s[j]);
        float sm = 0.0f;
        for (int j=0;j<SK;j++) { s[j] = expf(s[j]-mx); sm += s[j]; }
        for (int j=0;j<SK;j++) s[j] /= sm;
        for (int d=0;d<HD;d++) {
            float ov = 0.0f;
            for (int j=0;j<SK;j++) ov += s[j] * bf16_to_f32(v[d*SK+j]);
            o_ref[d] = ov;
        }
    }

    if (wid == 0) tmem_dealloc(tb, 128);
}

int main() {
    printf("=== Debug HD=64 PV: register-math vs SS MMA ===\n");
    const float SCALE = 1.0f / sqrtf((float)HD);

    bf16_t* h_q = (bf16_t*)malloc(HD*sizeof(bf16_t));
    bf16_t* h_k = (bf16_t*)malloc(SK*HD*sizeof(bf16_t));
    bf16_t* h_v = (bf16_t*)malloc(HD*SK*sizeof(bf16_t));
    bf16_t* h_o_mma = (bf16_t*)calloc(HD, sizeof(bf16_t));
    float* h_o_ref = (float*)calloc(HD, sizeof(float));
    float* h_o_regmath = (float*)calloc(HD, sizeof(float));

    srand(42);
    for (int d=0;d<HD;d++) h_q[d] = f32_to_bf16_host((float)(rand()%100)/100.0f-0.5f);
    for (int i=0;i<SK*HD;i++) h_k[i] = f32_to_bf16_host((float)(rand()%100)/100.0f-0.5f);
    for (int i=0;i<HD*SK;i++) h_v[i] = f32_to_bf16_host((float)(rand()%100)/100.0f-0.5f);

    bf16_t *d_q,*d_k,*d_v,*d_o_mma; float *d_o_ref, *d_o_regmath;
    cudaMalloc(&d_q, HD*sizeof(bf16_t));
    cudaMalloc(&d_k, SK*HD*sizeof(bf16_t));
    cudaMalloc(&d_v, HD*SK*sizeof(bf16_t));
    cudaMalloc(&d_o_mma, HD*sizeof(bf16_t));
    cudaMalloc(&d_o_ref, HD*sizeof(float));
    cudaMalloc(&d_o_regmath, HD*sizeof(float));
    cudaMemcpy(d_q, h_q, HD*sizeof(bf16_t), cudaMemcpyHostToDevice);
    cudaMemcpy(d_k, h_k, SK*HD*sizeof(bf16_t), cudaMemcpyHostToDevice);
    cudaMemcpy(d_v, h_v, HD*SK*sizeof(bf16_t), cudaMemcpyHostToDevice);

    int smem = (4+16 + NKT_QK*TILE_SZ*2 + NKT_QK*TILE_SZ*2 + TILE_SZ*2 + NKT_PV*V_TILE_SZ*2 + SK*4 + 256 + 127) & ~127;
    printf("SMEM: %d bytes (%.1f KB)\n", smem, smem/1024.0f);
    cudaFuncSetAttribute(test_fmha_hd64_debug, cudaFuncAttributeMaxDynamicSharedMemorySize, smem);
    test_fmha_hd64_debug<<<1, 128, smem>>>(d_q, d_k, d_v, d_o_mma, d_o_ref, d_o_regmath, SCALE);

    cudaError_t err = cudaDeviceSynchronize();
    if (err != cudaSuccess) { printf("CUDA ERROR: %s\n", cudaGetErrorString(err)); return 1; }

    cudaMemcpy(h_o_mma, d_o_mma, HD*sizeof(bf16_t), cudaMemcpyDeviceToHost);
    cudaMemcpy(h_o_ref, d_o_ref, HD*sizeof(float), cudaMemcpyDeviceToHost);
    cudaMemcpy(h_o_regmath, d_o_regmath, HD*sizeof(float), cudaMemcpyDeviceToHost);

    // Compare register-math PV vs reference
    printf("\n--- Register-math PV vs FP32 reference ---\n");
    float cs_reg = 0, na_reg = 0, nb_reg = 0;
    for (int d=0;d<HD;d++) {
        float a = h_o_regmath[d], b = h_o_ref[d];
        cs_reg += a*b; na_reg += a*a; nb_reg += b*b;
    }
    cs_reg /= (sqrtf(na_reg)*sqrtf(nb_reg)+1e-10f);
    printf("Cosine: %.8f\n", cs_reg);

    // Compare MMA PV vs reference
    printf("\n--- MMA PV vs FP32 reference (all 64 elements) ---\n");
    for (int d=0;d<HD;d++) printf("  MMA[%2d]=%10.6f  ref[%2d]=%10.6f  ratio=%.4f\n",
        d, bf16_to_f32_host(h_o_mma[d]), d, h_o_ref[d],
        fabsf(h_o_ref[d])>1e-6f ? bf16_to_f32_host(h_o_mma[d])/h_o_ref[d] : 0);
    float cs_mma = 0, na_mma = 0, nb_mma = 0;
    for (int d=0;d<HD;d++) {
        float a = bf16_to_f32_host(h_o_mma[d]), b = h_o_ref[d];
        if (fabsf(b)>1e-4f) { cs_mma += a*b; na_mma += a*a; nb_mma += b*b; }
    }
    cs_mma /= (sqrtf(na_mma)*sqrtf(nb_mma)+1e-10f);
    printf("Filtered cosine: %.8f\n", cs_mma);

    // Compare MMA PV vs register-math PV
    printf("\n--- MMA PV vs register-math PV ---\n");
    float cs_cmp = 0, na_cmp = 0, nb_cmp = 0;
    for (int d=0;d<HD;d++) {
        float a = bf16_to_f32_host(h_o_mma[d]), b = h_o_regmath[d];
        cs_cmp += a*b; na_cmp += a*a; nb_cmp += b*b;
    }
    cs_cmp /= (sqrtf(na_cmp)*sqrtf(nb_cmp)+1e-10f);
    printf("Cosine: %.8f\n", cs_cmp);

    // Check if MMA output is proportional to reference (scale factor issue)
    float ratio_sum = 0; int rc = 0;
    for (int d=0;d<HD;d++) {
        float a = bf16_to_f32_host(h_o_mma[d]), b = h_o_ref[d];
        if (fabsf(b)>1e-6f) { ratio_sum += a/b; rc++; }
    }
    float avg_ratio = rc>0 ? ratio_sum/rc : 0;
    printf("Average MMA/ref ratio: %.6f\n", avg_ratio);

    printf("\nTest %s\n", cs_cmp > 0.999f ? "PASSED" : "FAILED");

    cudaFree(d_q); cudaFree(d_k); cudaFree(d_v);
    cudaFree(d_o_mma); cudaFree(d_o_ref); cudaFree(d_o_regmath);
    free(h_q); free(h_k); free(h_v); free(h_o_mma); free(h_o_ref); free(h_o_regmath);
    return cs_cmp > 0.999f ? 0 : 1;
}