#pragma once #include "gemm_base.cuh" namespace nunchaku::kernels { template class GEMM_W4A4; #ifndef __INTELLISENSE__ template class GEMM_W4A4 : public GEMMBase { #else template<> class GEMM_W4A4 : public GEMMBase { using Config = GEMMConfig_W4A4_FP16; #endif public: IMPORT_GEMM_BASE(Config); public: template __device__ __forceinline__ static packed_psum_t mma(packed_act_t act, packed_wgt_t wgt) { packed_psum_t psum; if constexpr (!ACT_UNSIGNED) { asm volatile( "mma.sync.aligned.m16n8k64.row.col.s32.s4.s4.s32 " "{%0, %1, %2, %3}," "{%4, %5, %6, %7}," "{%8, %9}," "{%10, %11, %12, %13};\n" : "=r"(psum.data[0]), "=r"(psum.data[1]), "=r"(psum.data[2]), "=r"(psum.data[3]) : "r"(act.x), "r"(act.y), "r"(act.z), "r"(act.w), "r"(wgt.x), "r"(wgt.y), "r"(0), "r"(0), "r"(0), "r"(0) // "r"(psum.data[0]), "r"(psum.data[1]), "r"(psum.data[2]), "r"(psum.data[3]) ); asm volatile( "mma.sync.aligned.m16n8k64.row.col.s32.s4.s4.s32 " "{%0, %1, %2, %3}," "{%4, %5, %6, %7}," "{%8, %9}," "{%10, %11, %12, %13};\n" : "=r"(psum.data[4]), "=r"(psum.data[5]), "=r"(psum.data[6]), "=r"(psum.data[7]) : "r"(act.x), "r"(act.y), "r"(act.z), "r"(act.w), "r"(wgt.z), "r"(wgt.w), "r"(0), "r"(0), "r"(0), "r"(0) // "r"(psum.data[4]), "r"(psum.data[5]), "r"(psum.data[6]), "r"(psum.data[7]) ); } if constexpr (ACT_UNSIGNED) { asm volatile( "mma.sync.aligned.m16n8k64.row.col.s32.u4.s4.s32 " "{%0, %1, %2, %3}," "{%4, %5, %6, %7}," "{%8, %9}," "{%10, %11, %12, %13};\n" : "=r"(psum.data[0]), "=r"(psum.data[1]), "=r"(psum.data[2]), "=r"(psum.data[3]) : "r"(act.x), "r"(act.y), "r"(act.z), "r"(act.w), "r"(wgt.x), "r"(wgt.y), "r"(0), "r"(0), "r"(0), "r"(0) // "r"(psum.data[0]), "r"(psum.data[1]), "r"(psum.data[2]), "r"(psum.data[3]) ); asm volatile( "mma.sync.aligned.m16n8k64.row.col.s32.u4.s4.s32 " "{%0, %1, %2, %3}," "{%4, %5, %6, %7}," "{%8, %9}," "{%10, %11, %12, %13};\n" : "=r"(psum.data[4]), "=r"(psum.data[5]), "=r"(psum.data[6]), "=r"(psum.data[7]) : "r"(act.x), "r"(act.y), "r"(act.z), "r"(act.w), "r"(wgt.z), "r"(wgt.w), "r"(0), "r"(0), "r"(0), "r"(0) // "r"(psum.data[4]), "r"(psum.data[5]), "r"(psum.data[6]), "r"(psum.data[7]) ); } return psum; } // template template __device__ __forceinline__ static void quantize_w4a4_from_fpsum_warp(const packed_fpsum_t (&fpsum)[INSN_K / INSN_N], packed_act_t &output, half_t *output_scale) { const int laneId = threadIdx.x % WARP_SIZE; constexpr float QVALUE_MAX_SIGNED = 7.0f; constexpr float QVALUE_MAX_UNSIGNED = 15.0f; constexpr float RECPI_QVALUE_MAX_SIGNED = 1 / QVALUE_MAX_SIGNED; constexpr float RECPI_QVALUE_MAX_UNSIGNED = 1 / QVALUE_MAX_UNSIGNED; constexpr float QVALUE_MAX = use_unsigned ? QVALUE_MAX_UNSIGNED : QVALUE_MAX_SIGNED; constexpr float RECPI_QVALUE_MAX = use_unsigned ? RECPI_QVALUE_MAX_UNSIGNED : RECPI_QVALUE_MAX_SIGNED; // constexpr int QUANTIZE_BITMASK = 0xf; // 0 for row 0-7; 1 for row 8-15 half2_t input[2][INSN_K / INSN_N * 2]; #pragma unroll for (int i = 0; i < INSN_K / INSN_N; i++) { input[0][i * 2 + 0] = fpsum[i].data[0]; input[0][i * 2 + 1] = fpsum[i].data[2]; input[1][i * 2 + 0] = fpsum[i].data[1]; input[1][i * 2 + 1] = fpsum[i].data[3]; } half_t maxvalue[2]; maxvalue[0] = 0; maxvalue[1] = 0; #pragma unroll for (int i = 0; i < INSN_K / INSN_M * 2; i++) { half2_t abs0 = __habs2(input[0][i]); half2_t abs1 = __habs2(input[1][i]); maxvalue[0] = __hmax(maxvalue[0], __hmax(abs0.x, abs0.y)); maxvalue[1] = __hmax(maxvalue[1], __hmax(abs1.x, abs1.y)); } #pragma unroll for (int mask = 2; mask > 0; mask /= 2) { maxvalue[0] = __hmax(maxvalue[0], __shfl_xor_sync(~0, maxvalue[0], mask)); maxvalue[1] = __hmax(maxvalue[1], __shfl_xor_sync(~0, maxvalue[1], mask)); } maxvalue[0] = __shfl_sync(~0, maxvalue[0], laneId / 4 * 4); maxvalue[1] = __shfl_sync(~0, maxvalue[1], laneId / 4 * 4); float scale[2]; // scale[0] = float(maxvalue[0]) / QVALUE_MAX; // scale[1] = float(maxvalue[1]) / QVALUE_MAX; scale[0] = float(maxvalue[0]) * RECPI_QVALUE_MAX; scale[1] = float(maxvalue[1]) * RECPI_QVALUE_MAX; if (laneId % 4 == 0) { output_scale[laneId / 4] = half_t(scale[0]); output_scale[laneId / 4 + 8] = half_t(scale[1]); } float rscale[2]; // rscale[0] = QVALUE_MAX / float(maxvalue[0]); // rscale[1] = QVALUE_MAX / float(maxvalue[1]); rscale[0] = cuda_frcp(scale[0]); rscale[1] = cuda_frcp(scale[1]); uint32_t qpacks[2][INSN_K / INSN_M * 2]; #pragma unroll for (int i = 0; i < INSN_K / INSN_M * 2; i++) { #pragma unroll for (int j = 0; j < 2; j++) { // half2_t hval = __hmul2(input[j][i], half2_t(rscale[j], rscale[j])); // float2 fval = half22float2(hval); float2 fval = half22float2(input[j][i]) * make_float2(rscale[j], rscale[j]); qpacks[j][i] = quantize_float2<4, use_unsigned>(fval) << (laneId % 4 * 8); } } // 2 * 8 * 2 = 32 instructions => 256 cycles #pragma unroll for (int mask = 1; mask <= 2; mask *= 2) { #pragma unroll for (int i = 0; i < INSN_K / INSN_M * 2; i++) { #pragma unroll for (int j = 0; j < 2; j++) { qpacks[j][i] |= __shfl_xor_sync(~0, qpacks[j][i], mask); } } } // lane 0,1,2,3 / 4,5,6,7 / ... should have identical qpacks now #pragma unroll for (int i = 0; i < 4; i++) { if (laneId % 4 == i) { output.x = qpacks[0][0 + i]; output.y = qpacks[1][0 + i]; output.z = qpacks[0][4 + i]; output.w = qpacks[1][4 + i]; } } } // loads act of [WARP_M, WARP_N] and stores to fpsum_warp // [WARP_M, WARP_N * 2] when fuse_glu template struct load_act_to_fpsum { using matrix_t = half_t[WARP_M][WARP_N + 8]; static constexpr size_t SHMEM_SIZE = sizeof(matrix_t); __device__ __forceinline__ void operator()(const half_t *input, int stride, int maxRows, int maxCols, fpsum_warp &out, void *shmem) { const int laneId = threadIdx.x % WARP_SIZE; matrix_t &mat = *reinterpret_cast(shmem); constexpr int PACK_SIZE = WARP_N / WARP_SIZE; using packed_input = std::array; using packed_raw_input = std::array; #pragma unroll for (int row = 0; row < WARP_M; row++) { packed_input pack; // TODO: numCols not multiples of PACK_SIZE if constexpr (fuse_glu) { packed_raw_input raw; raw.fill(half2_t(0, 0)); bool pred = row < maxRows && laneId * PACK_SIZE * 2 < maxCols; if (pred) { raw = load(reinterpret_cast(input + row * stride + laneId * PACK_SIZE * 2)); } #pragma unroll for (int j = 0; j < PACK_SIZE; j++) { pack[j] = raw[j].x * silu(raw[j].y); } } else { pack.fill(half_t(0)); bool pred = row < maxRows && laneId * PACK_SIZE < maxCols; if (pred) { pack = load(reinterpret_cast(input + row * stride + laneId * PACK_SIZE)); } } store(reinterpret_cast(&mat[row][laneId * PACK_SIZE]), pack); } __syncwarp(); for (int m = 0; m < WARP_M_TILES; m++) { for (int n = 0; n < WARP_N_TILES; n++) { const int row = m * INSN_M + laneId % 16; const int col = n * INSN_N + laneId / 16 * 8; uint4 tmp; ldmatrix(&mat[row][col], tmp); *reinterpret_cast(&out[m * WARP_N_TILES + n]) = tmp; } } __syncwarp(); } }; /** * each warp quantizes a INSN_M * INSN_K (16 * 64) matrix * input is per-warp (in global memory) * output is per-thread (in regs) * output_scale is per-warp (in shared memory) * shmem must be at least INSN_M * INSN_K * sizeof(element) (16 * 64 * 0.5 = 512 Bytes) * default to quantize activation, if quantize weight, input should be column-majored and output should be transposed ({x, y, z, w} = {x, z, y, w}) */ __device__ __forceinline__ static void quantize_w4a4_warp(const half_t *input, int stride, packed_act_t &output, half_t *output_scale, void *shmem) { const int laneId = threadIdx.x % WARP_SIZE; constexpr int QUANTIZE_BITWIDTH = 4; constexpr int QVALUE_MAX = 7; // 4 bit => [-8, 7] // 1 lane = 1 pack // 1 warp = 32 lanes = 32 packs = 1 packwarp // a pack is {a0, ..., a7} in figure https://docs.nvidia.com/cuda/parallel-thread-execution/index.html?highlight=ex2#mma-16864-a // PACK_SIZE * 4 = INSN_K / 2 constexpr int PACK_SIZE = INSN_K / 8; // = 8 for 4bit constexpr int NUM_PACKS_PER_ROW = INSN_K / PACK_SIZE; constexpr int NUM_ROWS_PER_PACKWARP = PACK_SIZE * WARP_SIZE / INSN_K; constexpr int NUM_PACKWARPS = INSN_M / NUM_ROWS_PER_PACKWARP; using packed_input = std::array; packed_input packs[NUM_PACKWARPS]; // load #pragma unroll for (int i = 0; i < NUM_PACKWARPS; i++) { int rowId = i * NUM_ROWS_PER_PACKWARP + laneId / NUM_PACKS_PER_ROW; int colId = laneId % NUM_PACKS_PER_ROW * PACK_SIZE; packs[i] = load(reinterpret_cast(input + rowId * stride + colId)); } // find max half_t maxvalue[NUM_PACKWARPS]; #pragma unroll for (int i = 0; i < NUM_PACKWARPS; i++) { maxvalue[i] = __habs(packs[i][0]); #pragma unroll for (int j = 1; j < PACK_SIZE; j++) { maxvalue[i] = __hmax(maxvalue[i], __habs(packs[i][j])); } } // warp reduce (max) #pragma unroll for (int mask = NUM_PACKS_PER_ROW / 2; mask > 0; mask /= 2) { #pragma unroll for (int i = 0; i < NUM_PACKWARPS; i++) { maxvalue[i] = __hmax(maxvalue[i], __shfl_xor_sync(~0, maxvalue[i], mask)); } } // broadcast (max) #pragma unroll for (int i = 0; i < NUM_PACKWARPS; i++) { maxvalue[i] = __shfl_sync(~0, maxvalue[i], laneId / NUM_PACKS_PER_ROW * NUM_PACKS_PER_ROW); } // quantize using matrix_t = uint32_t[INSN_M][NUM_PACKS_PER_ROW]; matrix_t &mat = *reinterpret_cast(shmem); #pragma unroll for (int i = 0; i < NUM_PACKWARPS; i++) { half_t scale = maxvalue[i] / half_t(QVALUE_MAX); half_t rscale = half_t(QVALUE_MAX) / maxvalue[i]; if (laneId % NUM_PACKS_PER_ROW == 0) { output_scale[i * NUM_ROWS_PER_PACKWARP + laneId / NUM_PACKS_PER_ROW] = scale; } uint32_t qpack = 0; // #pragma unroll // for (int j = 0; j < PACK_SIZE; j++) { // int intvalue = __half2int_rn(packs[i][j] / scale); // intvalue = clamp(intvalue, -QVALUE_MAX, QVALUE_MAX); // qpack |= (intvalue & QUANTIZE_BITMASK) << (QUANTIZE_BITWIDTH * j); // } #pragma unroll for (int j = 0; j < PACK_SIZE; j += 2) { half2_t hval = __hmul2(half2_t(rscale, rscale), half2_t(packs[i][j], packs[i][j + 1])); qpack |= quantize_float2(half22float2(hval)) << (j * QUANTIZE_BITWIDTH); } mat[i * NUM_ROWS_PER_PACKWARP + laneId / NUM_PACKS_PER_ROW][laneId % NUM_PACKS_PER_ROW] = qpack; } __syncwarp(); // convert to imma format int row = laneId % 16; int col = laneId / 16 * 4; ldmatrix(&mat[row][col], output); __syncwarp(); } // each thread block (1 warp) quantize WARP_M * WARP_K tile (32 * 64) struct quantize_w4a4_act_kernel { __device__ void operator()(const half_t *input, packed_act_t *output, packed_ascale_t *oscales, int K) { const int laneId = threadIdx.x % WARP_SIZE; const int bm = blockIdx.x / (BLOCK_M / WARP_M); const int bk = blockIdx.y; const int warpId = blockIdx.x % (BLOCK_M / WARP_M); const int row = blockIdx.x * WARP_M; const int col = blockIdx.y * WARP_K; __shared__ alignas(128) half_t oscale_shmem[WARP_M]; __shared__ alignas(128) uint8_t tmp_shmem[INSN_M * INSN_K / 2]; for (int tileId = 0; tileId < WARP_M_TILES; tileId++) { packed_act_t tmpout; quantize_w4a4_warp( input + (row + tileId * INSN_M) * K + col, K, tmpout, oscale_shmem + tileId * INSN_M, tmp_shmem ); store(&output[(((bm * K / WARP_K + bk) * NUM_WARPS + warpId) * WARP_M_TILES + tileId) * WARP_SIZE + laneId], tmpout); } // if (threadIdx.x == 0) { // printf("Block (%d, %d) => offset = %d\n", blockIdx.x, blockIdx.y, (bm * K / WARP_K + bk) * NUM_WARPS + warpId); // } pack_ascales(oscale_shmem, &oscales[((bm * K / WARP_K + bk) * NUM_WARPS + warpId) * ASCALES_NUM_PACKS * ASCALES_VALID_LANES]); } }; // each thread block (1 warp) quantize WARP_N * WARP_K tile (128 * 64) struct quantize_w4a4_wgt_kernel { __device__ void operator()(const half_t *input, packed_wgt_t *output, packed_wscale_t *oscales, int K) { const int laneId = threadIdx.x % WARP_SIZE; const int bn = blockIdx.x / (BLOCK_N / WARP_N); const int bk = blockIdx.y; const int col = blockIdx.x * WARP_N; const int row = blockIdx.y * WARP_K; __shared__ alignas(128) half_t oscale_shmem[WARP_N]; __shared__ alignas(128) uint8_t tmp_shmem[INSN_M * INSN_K / 2]; for (int tileId = 0; tileId < WARP_N_TILES; tileId++) { packed_wgt_t tmpout; quantize_w4a4_warp( input + (col + tileId * INSN_N) * K + row, K, tmpout, oscale_shmem + tileId * INSN_N, tmp_shmem ); std::swap(tmpout.y, tmpout.z); store(&output[((bn * K / WARP_K + bk) * WARP_N_TILES + tileId) * WARP_SIZE + laneId], tmpout); } pack_wscales(oscale_shmem, &oscales[(bn * K / WARP_K + bk) * WSCALES_NUM_PACKS * WSCALES_VALID_LANES]); } }; template __device__ __forceinline__ static void compute(act_warp A, wgt_warp W, ascale_warp ascale, wscale_warp wscale, T &fpsum) { apply_scales([&](int i, int j) { return mma(A[i], W[j]); }, ascale, wscale, fpsum); } __device__ __forceinline__ static void checkNan(fpsum_warp fpsum, const char *info = "") { #if ENABLE_NAN_CHECK const int laneId = threadIdx.x % WARP_SIZE; const int warpId = threadIdx.x / WARP_SIZE; for (int i = 0; i < fpsum.size(); i++) { for (int j = 0; j < 4; j++) { bool abnormal = !isfinite((float)fpsum[i].data[j].x) || !isfinite((float)fpsum[i].data[j].y); if (abnormal) { printf("abnormal value detected at block.x=%d block.y=%d warpId=%d laneId=%d fpsum_warp (%s) i=%d j=%d data.x=%f data.y=%f\n", blockIdx.x, blockIdx.y, warpId, laneId, info, i, j, (float)fpsum[i].data[j].x, (float)fpsum[i].data[j].y ); __trap(); } } } #endif } __device__ __forceinline__ static void checkNan(packed_f32psum_t fpsum, const char *info = "") { #if ENABLE_NAN_CHECK const int laneId = threadIdx.x % WARP_SIZE; const int warpId = threadIdx.x / WARP_SIZE; for (int j = 0; j < 8; j++) { bool abnormal = !isfinite(fpsum.data[j]); if (abnormal) { printf("abnormal value detected at bm=%d bn=%d warpId=%d laneId=%d packed_f32psum_t (%s) j=%d data=%f\n", blockIdx.x, blockIdx.y, warpId, laneId, info, j, fpsum.data[j] ); __trap(); } } #endif } __device__ __forceinline__ static void checkNan(packed_fpsum_t fpsum, const char *info = "") { #if ENABLE_NAN_CHECK const int laneId = threadIdx.x % WARP_SIZE; const int warpId = threadIdx.x / WARP_SIZE; for (int j = 0; j < 4; j++) { bool abnormal = !isfinite((float)fpsum.data[j].x) || !isfinite((float)fpsum.data[j].y); if (abnormal) { printf("abnormal value detected at bm=%d bn=%d warpId=%d laneId=%d packed_fpsum_t (%s) j=%d data.x=%f data.y=%f\n", blockIdx.x, blockIdx.y, warpId, laneId, info, j, (float)fpsum.data[j].x, (float)fpsum.data[j].y ); __trap(); } } #endif } __device__ __forceinline__ static void checkNan(float data, const char *info = "") { #if ENABLE_NAN_CHECK const int laneId = threadIdx.x % WARP_SIZE; const int warpId = threadIdx.x / WARP_SIZE; bool abnormal = !isfinite(data); if (abnormal) { printf("abnormal value detected at bm=%d bn=%d warpId=%d laneId=%d packed_fpsum_t (%s) data=%f\n", blockIdx.x, blockIdx.y, warpId, laneId, info, data ); __trap(); } #endif } // out: [M / BLOCK_M, N / BLOCK_N, NUM_WARPS, 1, NUM_M_TILES, NUM_N_TILES, WARP_SIZE] of fpsum_warp template __device__ __forceinline__ static void gemm_w4a4_block( const BlockInfo binfo, const packed_act_t *act, const packed_wgt_t *wgt, const packed_ascale_t *ascales, const packed_wscale_t *wscales, // const packed_wscale_t *bias_ptr, // half_t *out, int M, int N, int K, Epilogue::Arguments epilogueArgs, bool alwaysfalse) { constexpr int NUM_STAGES = 2; const int laneId = threadIdx.x % WARP_SIZE; const int warpId = threadIdx.x / WARP_SIZE; act_warp A[NUM_STAGES]; // 8 wgt_warp W[NUM_STAGES]; // 32 ascale_warp ascale[NUM_STAGES]; // 1 wscale_warp wscale[NUM_STAGES]; // 2 fpsum_warp fpsum; // 64 // load_wscale(wscales, wscale[0], true); // load_wscale(wscales, wscale[1], true); // load_wscale(wscales, wscale[2], true); for (int k = 0; k < NUM_STAGES - 1; k++) { load_act(act, k, K, A[k], true); load_wgt(wgt, k, K, W[k], true); load_ascale(ascales, k, M, ascale[k], true); load_wscale(wscales, k, N, wscale[k], true); } for (auto &pack : fpsum) { #if 1 for (int i = 0; i < 4; i++) { pack.data[i].x = 0; pack.data[i].y = 0; } #else for (int i = 0; i < 8; i++) { pack.data[i] = 0; } #endif } int dummy = 0; for (int k1 = 0; k1 < K / WARP_K; k1 += NUM_STAGES) { #pragma unroll for (int k2 = 0; k2 < NUM_STAGES; k2++) { int nextk = k1 + k2 + NUM_STAGES - 1; int idx = (k2 + NUM_STAGES - 1) % NUM_STAGES; bool pred = nextk < K / WARP_K; load_act(act, nextk, K, A[idx], pred); load_wgt(wgt, nextk, K, W[idx], pred); load_ascale(ascales, nextk, M, ascale[idx], pred); load_wscale(wscales, nextk, N, wscale[idx], pred); // load_wscale(wscales, wscale[idx], pred); // __syncthreads(); // if (alwaysfalse) { // dummy = clock(); // } compute(A[k2], W[k2], ascale[k2], wscale[k2], fpsum); if (alwaysfalse) { dummy = clock(); } // asm volatile ("membar.cta;"); } } unused_var(dummy, alwaysfalse); #if 0 auto f16psum = packed_fp32_to_fp16(fpsum); #else auto f16psum = fpsum; #endif CHECK_NAN(f16psum, "f16psum"); Epilogue()(binfo, f16psum, M, N, K, epilogueArgs); } template struct EpilogueQuantize { struct Arguments { packed_act_t *qout; packed_ascale_t *oscales; half_t shift_value; const packed_wscale_t *smooth_factor; }; static constexpr int NUM_PACKS = INSN_K / INSN_N; static constexpr int NUM_GROUPS = WARP_N_TILES / NUM_PACKS; __device__ __forceinline__ void apply_quantize(fpsum_warp fpsum, int M, int N, int K, packed_act_t *qout, packed_ascale_t *oscales, half_t shift_value, const packed_wscale_t *smooth_factor) { const int laneId = threadIdx.x % WARP_SIZE; const int warpId = threadIdx.x / WARP_SIZE; __shared__ half_t oscale_shmem[NUM_WARPS][WARP_M]; wscale_warp smooth; load_wscale(smooth_factor, 0, N, smooth, true); #pragma unroll for (int group = 0; group < NUM_GROUPS; group++) { #pragma unroll for (int i = 0; i < WARP_M_TILES; i++) { packed_fpsum_t tmp[NUM_PACKS]; #pragma unroll for (int j = 0; j < NUM_PACKS; j++) { half2_t ws1 = broadcast_wscale(smooth, (group * NUM_PACKS + j) * 4, laneId); half2_t ws2 = broadcast_wscale(smooth, (group * NUM_PACKS + j) * 4 + 2, laneId); #pragma unroll for (int k = 0; k < 4; k++) { half2_t src = fpsum[i * WARP_N_TILES + group * NUM_PACKS + j].data[k]; half2_t &dst = tmp[j].data[k]; // dst.x = gelu(src.x); // dst.y = gelu(src.y); if constexpr (FUSE_GELU) { dst = gelu_half2(src); } else { dst = src; } dst += half2_t(shift_value, shift_value); // dst = src; } // auto h2div = [](half2_t a, half2_t b) ALWAYSINLINE { // float2 af = half22float2(a); // float2 bf = half22float2(b); // float2 of; // of.x = __fdividef(af.x, bf.x); // of.y = __fdividef(af.y, bf.y); // return float22half2(of); // }; tmp[j].data[0] = h2div(tmp[j].data[0], ws1); tmp[j].data[1] = h2div(tmp[j].data[1], ws1); tmp[j].data[2] = h2div(tmp[j].data[2], ws2); tmp[j].data[3] = h2div(tmp[j].data[3], ws2); } packed_act_t qresult; quantize_w4a4_from_fpsum_warp(tmp, qresult, &oscale_shmem[warpId][i * INSN_M]); store(&qout[((group * NUM_WARPS + warpId) * WARP_M_TILES + i) * WARP_SIZE + laneId], qresult); } __syncwarp(); pack_ascales(&oscale_shmem[warpId][0], &oscales[(group * NUM_WARPS + warpId) * ASCALES_NUM_PACKS * ASCALES_VALID_LANES]); __syncwarp(); } } __device__ __forceinline__ void operator()(const BlockInfo binfo, fpsum_warp fpsum, int M, int N, int K, Arguments args) { const int bm = binfo.bm; const int bn = binfo.bn; apply_quantize( fpsum, M, N, K, args.qout + (bm * N / WARP_K + bn * NUM_GROUPS) * NUM_WARPS * WARP_M_TILES * WARP_SIZE, args.oscales + (bm * N / WARP_K + bn * NUM_GROUPS) * NUM_WARPS * ASCALES_NUM_PACKS * ASCALES_VALID_LANES, args.shift_value, args.smooth_factor + bn * WSCALES_NUM_PACKS * WSCALES_VALID_LANES ); } }; // using EpilogueQuantizeFuseGelu = EpilogueQuantize; template struct Lora { static_assert(rank % 16 == 0); static constexpr int LORA_RANK = rank; static constexpr int LORA_M_TILES = WARP_M / 16; static constexpr int LORA_R_TILES = LORA_RANK / 16; static constexpr int LORA_N_TILES = WARP_N / 16; static_assert(LORA_M_TILES == WARP_M_TILES); static_assert(LORA_N_TILES == WARP_N_TILES); // lora_down: [WARP_M, WARP_N] x [WARP_N, R] (row-wise) = [WARP_M, R] // lora up: [WARP_M, R] x [WARP_N, R] (col-wise) = [WARP_M, WARP_N] // we use fp32 for lora activation since there's no bf16 reduction in sm_89 :( using lora_act_warp = std::array; using lora_act16_warp = std::array; using lora_wgt_warp = std::array; using scale_t = std::array; // lora_wgt: [N / 16, LORA_R_TILES, WARP_SIZE] of packed_fpsum_t __device__ __forceinline__ static lora_wgt_warp load_lora_wgt(const packed_fpsum_t *ptr) { const int laneId = threadIdx.x % WARP_SIZE; const packed_fpsum_t *ptr_lane = ptr + laneId; lora_wgt_warp result; #if 0 #pragma unroll for (int n = 0; n < LORA_N_TILES; n++) { #pragma unroll for (int r = 0; r < LORA_R_TILES; r++) { result[n * LORA_R_TILES + r] = load(ptr_lane + (n * LORA_R_TILES + r) * WARP_SIZE); } } #else unrolled_loop([&]() { unrolled_loop([&]() { constexpr int offset = (n * LORA_R_TILES + r) * WARP_SIZE; result[n * LORA_R_TILES + r] = load(ptr_lane + offset); }); }); #endif return result; } // lora_act: [M / BLOCK_M, NUM_WARPS, LORA_M_TILES, LORA_R_TILES, 8, WARP_SIZE] of float __device__ __forceinline__ static lora_act16_warp load_lora_act(const float *ptr, scale_t scales) { const int laneId = threadIdx.x % WARP_SIZE; const float *ptrlane = ptr + laneId; lora_act16_warp result; #if 0 #pragma unroll for (int i = 0; i < LORA_M_TILES * LORA_R_TILES; i++) { packed_f32psum_t tmp; #pragma unroll for (int j = 0; j < 8; j++) { const int offset = i * 8 * WARP_SIZE + j * WARP_SIZE; tmp.data[j] = ptrlane[offset]; // tmp.data[j] = ptr[i * 8 * WARP_SIZE + j * WARP_SIZE + laneId]; } CHECK_NAN(tmp, "load_lora_act.tmp"); result[i] = packed_fp32_to_fp16(tmp); } #else unrolled_loop([&]() { unrolled_loop([&]{ constexpr int i = m * LORA_R_TILES + r; packed_f32psum_t tmp; unrolled_loop<8>([&]() { constexpr int offset = i * 8 * WARP_SIZE + j * WARP_SIZE; tmp.data[j] = ptrlane[offset] * scales[r]; }); CHECK_NAN(tmp, "load_lora_act.tmp"); result[i] = packed_fp32_to_fp16(tmp); }); }); #endif return result; } // no vector reduction in sm_89 :( __device__ __forceinline__ static void reduce_lora_act(float *ptr, lora_act_warp val) { const int laneId = threadIdx.x % WARP_SIZE; float *ptrlane = ptr + laneId; // #pragma unroll // for (int i = 0; i < LORA_M_TILES * LORA_R_TILES; i++) { // #pragma unroll // for (int j = 0; j < 8; j++) { // int offset = i * 8 * WARP_SIZE + j * WARP_SIZE; // reduce_add(&ptrlane[offset], val[i].data[j]); // } // } unrolled_loop([&]() { unrolled_loop<8>([&]() { constexpr int offset = i * 8 * WARP_SIZE + j * WARP_SIZE; reduce_add(&ptrlane[offset], val[i].data[j]); }); }); } // __device__ __forceinline__ // static void reduce_lora_act(float *ptr, lora_act_warp val, int m) { // const int laneId = threadIdx.x % WARP_SIZE; // float *ptrlane = ptr + laneId + m * LORA_R_TILES * 8 * WARP_SIZE; // unrolled_loop([&]() { // unrolled_loop<8>([&]() { // constexpr int offset = r * 8 * WARP_SIZE + j * WARP_SIZE; // reduce_add(&ptrlane[offset], val[m * LORA_R_TILES + r].data[j]); // }); // }); // } struct EpilogueLoraUp { struct Arguments { const float *lora_act; const packed_fpsum_t *lora_wgt_up; scale_t scales; }; __device__ __forceinline__ static void apply_lora_up(fpsum_warp &fpsum, int M, int N, int K, const float *act, const packed_fpsum_t *wgt, const scale_t scales, const BlockInfo binfo) { const int laneId = threadIdx.x % WARP_SIZE; const int warpId = threadIdx.x / WARP_SIZE; if constexpr (rank > 0) { lora_act16_warp lora_act = load_lora_act(act + warpId * (LORA_M_TILES * LORA_R_TILES * 8 * WARP_SIZE), scales); lora_wgt_warp lora_wgt = load_lora_wgt(wgt); for (int m = 0; m < LORA_M_TILES; m++) { for (int n = 0; n < LORA_N_TILES; n++) { packed_f32psum_t psum = packed_fp16_to_fp32(fpsum[m * WARP_N_TILES + n]); for (int r = 0; r < LORA_R_TILES; r++) { CHECK_NAN(lora_act[m * LORA_R_TILES + r], "lora_act"); CHECK_NAN(lora_wgt[n * LORA_R_TILES + r], "lora_wgt"); psum = mma_f16xf16_f32(lora_act[m * LORA_R_TILES + r], lora_wgt[n * LORA_R_TILES + r], psum); } fpsum[m * WARP_N_TILES + n] = packed_fp32_to_fp16(psum); } } } } __device__ __forceinline__ void operator()(const BlockInfo binfo, fpsum_warp &fpsum, int M, int N, int K, Arguments args) { const int bm = binfo.bm; const int bn = binfo.bn; CHECK_NAN(fpsum, "fpsum"); if constexpr (rank == 0) { return; } apply_lora_up( fpsum, M, N, K, args.lora_act + bm * (NUM_WARPS * LORA_M_TILES * LORA_R_TILES * 8 * WARP_SIZE), args.lora_wgt_up + bn * (BLOCK_N / 16) * LORA_R_TILES * WARP_SIZE, args.scales, binfo // for debug ); CHECK_NAN(fpsum, "fpsum"); } }; struct EpilogueLoraDown { struct Arguments { const packed_fpsum_t *lora_wgt_down; float *lora_act; }; __device__ __forceinline__ static void apply_lora_down(fpsum_warp &fpsum, int M, int N, int K, float *act, const packed_fpsum_t *wgt) { const int laneId = threadIdx.x % WARP_SIZE; const int warpId = threadIdx.x / WARP_SIZE; if constexpr (rank > 0) { lora_act_warp lora_act; lora_act.fill(packed_f32psum_t::zeros()); lora_wgt_warp lora_wgt = load_lora_wgt(wgt); // clock_t dummy = 0; #pragma unroll for (int m = 0; m < LORA_M_TILES; m++) { #pragma unroll for (int n = 0; n < LORA_N_TILES; n++) { #pragma unroll for (int r = 0; r < LORA_R_TILES; r++) { auto &psum = lora_act[m * LORA_R_TILES + r]; CHECK_NAN(fpsum[m * WARP_N_TILES + n], "apply_lora_down.fpsum"); CHECK_NAN(lora_wgt[n * LORA_R_TILES + r], "apply_lora_down.lora_wgt"); psum = mma_f16xf16_f32(fpsum[m * WARP_N_TILES + n], lora_wgt[n * LORA_R_TILES + r], psum); CHECK_NAN(psum, "apply_lora_down.psum"); } } // reduce_lora_act(act + warpId * (LORA_M_TILES * LORA_R_TILES * 8 * WARP_SIZE), lora_act, m); // if (alwaysfalse) { // dummy = clock(); // } } reduce_lora_act(act + warpId * (LORA_M_TILES * LORA_R_TILES * 8 * WARP_SIZE), lora_act); // unused_var(dummy, alwaysfalse); } } __device__ __forceinline__ void operator()(const BlockInfo binfo, fpsum_warp &fpsum, int M, int N, int K, Arguments args) { const int bm = binfo.bm; const int bn = binfo.bn; if constexpr (rank == 0) { return; } apply_lora_down( fpsum, M, N, K, args.lora_act + bm * (NUM_WARPS * LORA_M_TILES * LORA_R_TILES * 8 * WARP_SIZE), args.lora_wgt_down + bn * (BLOCK_N / 16) * LORA_R_TILES * WARP_SIZE ); } }; template struct quantize_w4a4_fuse_lora_kernel { static constexpr size_t SHMEM_PER_WARP = ceilDiv(load_act_to_fpsum::SHMEM_SIZE, 128) * 128; static constexpr size_t SHMEM_SIZE = SHMEM_PER_WARP * NUM_WARPS; struct Arguments { const half_t *input; const packed_wscale_t *smooth_factor; packed_act_t *output; packed_ascale_t *oscales; const packed_fpsum_t *lora_wgt_down; float *lora_act; // aligned to BLOCK_M and BLOCK_N int M, N; // N should be the actual K in the next GEMM (needs /2 if fuse_glu) // the actual M and N (no need to /2 if fuse_glu) int actualM, actualN; }; __device__ __forceinline__ void operator()(Arguments args) { const BlockInfo binfo = { .bm = (int)blockIdx.x, .bn = (int)blockIdx.y, .numBlocksM = (int)gridDim.x, .numBlocksN = (int)gridDim.y, }; const int bm = binfo.bm; const int bn = binfo.bn; const int warpId = threadIdx.x / WARP_SIZE; const int m_offset = bm * BLOCK_M + warpId * WARP_M; const int n_offset = bn * BLOCK_N * (fuse_glu ? 2 : 1); extern __shared__ uint8_t shmem[]; fpsum_warp fpsum; load_act_to_fpsum()( args.input + m_offset * args.actualN + n_offset, args.actualN, args.actualM - m_offset, args.actualN - n_offset, fpsum, shmem + warpId * SHMEM_PER_WARP // args.smooth_factor ? args.smooth_factor + n_offset : nullptr ); CHECK_NAN(fpsum, "fpsum"); // for (int i = 0; i < 16; i++) { // printf("bm=%d bn=%d warp=%d lane=%d fpsum[%d][0:1]=%f %f\n", // bm, bn, warpId, threadIdx.x % WARP_SIZE, i, // (float)fpsum[i].data[0].x, (float)fpsum[i].data[0].y); // } EpilogueLoraDown()(binfo, fpsum, args.M, args.N, 0, typename EpilogueLoraDown::Arguments{ .lora_wgt_down = args.lora_wgt_down, .lora_act = args.lora_act, }); EpilogueQuantize()(binfo, fpsum, args.M, args.N, 0, typename EpilogueQuantize::Arguments{ .qout = args.output, .oscales = args.oscales, .shift_value = 0, .smooth_factor = args.smooth_factor }); } }; }; struct EpilogueGelu { struct Arguments { size_t unused; }; // static constexpr float SHIFT_VALUE = 0.171875f; __device__ __forceinline__ void operator()(const BlockInfo binfo, fpsum_warp &fpsum, int M, int N, int K, Arguments args) { #pragma unroll for (int i = 0; i < WARP_M_TILES; i++) { #pragma unroll for (int j = 0; j < WARP_N_TILES; j++) { #pragma unroll for (int k = 0; k < 4; k++) { half2_t &data = fpsum[i * WARP_N_TILES + j].data[k]; data = gelu_half2(data); // data = __hadd2(data, half2_t(SHIFT_VALUE, SHIFT_VALUE)); } } } } }; // template struct EpilogueQKVProj { struct Arguments { half_t *out; int actualM, actualN; half_t *pool_out; // [M / PoolSize, N] const float *rotary_emb; // [M, HEAD_DIM / 2, ROTARY_EMB_NUM_ELEMENTS] const half_t *rmsnorm_weight_q; // [HEAD_DIM] const half_t *rmsnorm_weight_k; // [HEAD_DIM] float epsilon; }; static constexpr int HEAD_DIM = 128; static constexpr int NUM_HEADS_PER_WARP = WARP_N / HEAD_DIM; static constexpr int PoolSize = 128; static constexpr int NUM_WARPS_PER_POOL = PoolSize / WARP_M; static constexpr int NUM_POOLS_PER_BLOCK = BLOCK_M / PoolSize; static constexpr int ROTARY_EMB_NUM_ELEMENTS = 2; // 1 for theta, 2 for {sin, cos} pair __device__ __forceinline__ static void apply(fpsum_warp fpsum, half_t *out, int M, int N, int K, half_t *pool_out, const float *rotary_emb, const half_t *rmsnorm_weight, float epsilon) { const int laneId = threadIdx.x % WARP_SIZE; const int warpId = threadIdx.x / WARP_SIZE; __shared__ alignas(128) uint8_t shmem[NUM_WARPS][ceilDiv(unpack_fpsum::SHMEM_SIZE, 128) * 128]; constexpr int PACK_SIZE = unpack_fpsum::PACK_SIZE; using pack_t = unpack_fpsum::pack_t; using pack_rope_t = std::array; constexpr int LANES_PER_HEAD = HEAD_DIM / PACK_SIZE; pack_t reduce_tmp; __shared__ alignas(128) pack_t pool[NUM_WARPS]; // load rmsnorm scales pack_t rms; if (laneId < LANES_PER_HEAD) { rms = load(reinterpret_cast(&rmsnorm_weight[laneId * PACK_SIZE])); } if constexpr (LANES_PER_HEAD < WARP_SIZE) { for (int i = 0; i < PACK_SIZE; i++) { rms[i] = __shfl_sync(~0, rms[i], laneId % LANES_PER_HEAD); } } const float *rotary_emb_base_addr = &rotary_emb[(warpId * WARP_M) * HEAD_DIM / 2 * ROTARY_EMB_NUM_ELEMENTS + laneId * PACK_SIZE / 2 * ROTARY_EMB_NUM_ELEMENTS]; CHECK_NAN(fpsum, "fpsum"); unpack_fpsum()(fpsum, out + warpId * WARP_M * N, N, INT_MAX, INT_MAX, shmem[warpId], [&](int rowId, pack_t &pack) ALWAYSINLINE { // load rope pack_rope_t rope; if (laneId < LANES_PER_HEAD) { // freq = load(reinterpret_cast(&freqs_cis[(warpId * WARP_M + rowId) * HEAD_DIM * 2 + laneId * PACK_SIZE * 2])); rope = load(reinterpret_cast(&rotary_emb_base_addr[rowId * HEAD_DIM / 2 * ROTARY_EMB_NUM_ELEMENTS])); } if constexpr (LANES_PER_HEAD < WARP_SIZE) { for (int i = 0; i < rope.size(); i++) { rope[i] = __shfl_sync(~0, rope[i], laneId % LANES_PER_HEAD); } } // rmsnorm float sqrsum = 0.0f; for (int i = 0; i < PACK_SIZE; i++) { sqrsum += float(pack[i]) * float(pack[i]); CHECK_NAN(sqrsum, "sqrsum"); } #pragma unroll for (int mask = LANES_PER_HEAD / 2; mask > 0; mask /= 2) { sqrsum += __shfl_xor_sync(~0, sqrsum, mask); } sqrsum /= HEAD_DIM; float coef = cuda_frsqrt(sqrsum + epsilon); CHECK_NAN(coef, "coef"); for (int i = 0; i < PACK_SIZE; i++) { pack[i] *= coef * float(rms[i]); CHECK_NAN(rms[i], "rms.wgt"); CHECK_NAN(pack[i], "rms.out"); } #if 1 // rope for (int i = 0; i < PACK_SIZE; i += 2) { float2 pack2 = half22float2(half2_t(pack[i], pack[i+1])); CHECK_NAN(freq[i].x, "rope.freq"); CHECK_NAN(freq[i].y, "rope.freq"); CHECK_NAN(freq[i+1].x, "rope.freq"); CHECK_NAN(freq[i+1].y, "rope.freq"); // half2_t tmp = __hmul2(freq[i], pack2); // tmp = __hfma2(freq[i+1], pack2, tmp); // pack[i] = tmp.x; // pack[i+1] = tmp.y; // printf("block.x=%d block.y=%d warpId=%d rowId=%d (%d) freqs = %f %f %f %f\n", // blockIdx.x, blockIdx.y, warpId, rowId, // blockIdx.x * BLOCK_M + warpId * WARP_M + rowId, // (float)freq[i].x, (float)freq[i].y, (float)freq[i+1].x, (float)freq[i+1].y // ); // __trap(); // half2_t tmp = __hmul2(half2_t(pack2.x, pack2.x), freq[i]); // tmp = __hfma2(half2_t(pack2.y, pack2.y), freq[i+1], tmp); // pack[i] = tmp.x; // pack[i+1] = tmp.y; float sin, cos; if constexpr (ROTARY_EMB_NUM_ELEMENTS == 1) { sin = cuda_sin(rope[i / 2]); cos = cuda_cos(rope[i / 2]); } if constexpr (ROTARY_EMB_NUM_ELEMENTS == 2) { sin = rope[i]; cos = rope[i+1]; } // pack[i] = pack2.x * freq[i].x + pack2.y * freq[i].y; // pack[i+1] = pack2.x * freq[i+1].x + pack2.y * freq[i+1].y; pack[i] = half_t(pack2.x * cos - pack2.y * sin); pack[i+1] = half_t(pack2.x * sin + pack2.y * cos); CHECK_NAN(pack[i], "rope.out"); CHECK_NAN(pack[i+1], "rope.out"); } #endif // mean pool for (int i = 0; i < PACK_SIZE; i++) { reduce_tmp[i] += pack[i]; } }); if (!pool_out) { return; } store(&pool[warpId], reduce_tmp); __syncthreads(); if (warpId < NUM_POOLS_PER_BLOCK) { const int row = warpId * NUM_WARPS_PER_POOL; reduce_tmp = load(&pool[row]); for (int i = 1; i < NUM_WARPS_PER_POOL; i++) { pack_t pack = load(&pool[row + i]); for (int j = 0; j < PACK_SIZE; j++) { reduce_tmp[j] += pack[j]; } } for (int j = 0; j < PACK_SIZE; j++) { reduce_tmp[j] /= PoolSize; } store(reinterpret_cast(pool_out + warpId * N), reduce_tmp); } __syncthreads(); } __device__ __forceinline__ void operator()(const BlockInfo binfo, fpsum_warp fpsum, int M, int N, int K, Arguments args) { const int bm = binfo.bm; const int bn = binfo.bn; assert(binfo.numBlocksN % 3 == 0); const bool is_q = bn < binfo.numBlocksN / 3; const bool is_k = !is_q && bn < binfo.numBlocksN / 3 * 2; assert(!args.pool_out || args.actualM == M); assert(args.actualN == N); if (is_q || is_k) { apply( fpsum, args.out + bm * BLOCK_M * args.actualN + bn * BLOCK_N, M, N, K, args.pool_out ? args.pool_out + bm * BLOCK_M / PoolSize * N : nullptr, args.rotary_emb + bm * BLOCK_M * (HEAD_DIM / 2 * ROTARY_EMB_NUM_ELEMENTS), is_q ? args.rmsnorm_weight_q : args.rmsnorm_weight_k, args.epsilon ); } else { EpilogueDefault()(binfo, fpsum, M, N, K, typename EpilogueDefault::Arguments{ .out = args.out, .actualM = args.actualM, .actualN = args.actualN, }); } } }; struct EpilogueLiteLA { __device__ __forceinline__ static half2_t movmatrix(half2_t x) { asm volatile ("movmatrix.sync.aligned.m8n8.trans.b16 %0, %1;" : "=r"(*reinterpret_cast(&x)) : "r"(*reinterpret_cast(&x))); return x; } __device__ __forceinline__ static packed_f32psum_t mma_litela(packed_fpsum_t k, packed_fpsum_t v, packed_f32psum_t psum) { for (int i = 0; i < 4; i++) { k.data[i] = movmatrix(k.data[i]); v.data[i] = movmatrix(v.data[i]); } std::swap(v.data[1], v.data[2]); return mma_f16xf16_f32(v, k, psum); } static constexpr int LITELA_HEAD_DIM = 32; static constexpr int LITELA_K_TILES = LITELA_HEAD_DIM / 16; static constexpr int LITELA_V_TILES = LITELA_HEAD_DIM / 16; static constexpr int SHMEM_SIZE = NUM_WARPS * (LITELA_HEAD_DIM + 1) * (LITELA_HEAD_DIM + 8) * sizeof(float); // out_vk: [batch_size, num_heads, head_dim + 1, head_dim] __device__ __forceinline__ static void apply_litela(const BlockInfo binfo, fpsum_warp fpsum, float *out_vk, int num_blocks_per_batch) { const int laneId = threadIdx.x % WARP_SIZE; const int warpId = threadIdx.x / WARP_SIZE; using vk_t = float[NUM_WARPS][LITELA_HEAD_DIM + 1][LITELA_HEAD_DIM + 8]; extern __shared__ uint8_t shmem[]; vk_t &shmem_vk = *reinterpret_cast(shmem); static_assert(sizeof(vk_t) == SHMEM_SIZE); static_assert(WARP_N == BLOCK_N); assert(binfo.numBlocksN % 3 == 0); const int num_heads = binfo.numBlocksN / 3 * 2 * (WARP_N / (LITELA_HEAD_DIM * 2)); const int batch_id = binfo.bm / num_blocks_per_batch; for (int head_id = 0; head_id < WARP_N / (LITELA_HEAD_DIM * 2); head_id++) { const int global_head_id = (binfo.bn - binfo.numBlocksN / 3) * (WARP_N / (LITELA_HEAD_DIM * 2)) + head_id; float *out_vk_current_head = out_vk + (batch_id * num_heads + global_head_id) * (LITELA_HEAD_DIM + 1) * LITELA_HEAD_DIM; for (int i = laneId; i < sizeof(shmem_vk) / sizeof(float) / NUM_WARPS; i += WARP_SIZE) { *((&shmem_vk[warpId][0][0]) + i) = 0; } __syncwarp(); for (int tile_v = 0; tile_v < LITELA_V_TILES; tile_v++) { for (int tile_k = 0; tile_k < LITELA_K_TILES; tile_k++) { packed_f32psum_t attn_sum = { 0 }; for (int i = 0; i < WARP_M_TILES; i++) { packed_fpsum_t k = fpsum[i * WARP_N_TILES + head_id * (LITELA_HEAD_DIM * 2) / 16 + tile_k]; packed_fpsum_t v = fpsum[i * WARP_N_TILES + head_id * (LITELA_HEAD_DIM * 2) / 16 + LITELA_HEAD_DIM / 16 + tile_v]; for (int j = 0; j < 4; j++) { k.data[j] = __hmax2(k.data[j], half2_t(0, 0)); // relu } attn_sum = mma_litela(k, v, attn_sum); } const int row = tile_v * 16 + laneId / 4; const int col = tile_k * 16 + laneId % 4 * 2; shmem_vk[warpId][row + 0][col + 0] = attn_sum.data[0]; shmem_vk[warpId][row + 0][col + 1] = attn_sum.data[1]; shmem_vk[warpId][row + 8][col + 0] = attn_sum.data[2]; shmem_vk[warpId][row + 8][col + 1] = attn_sum.data[3]; shmem_vk[warpId][row + 0][col + 8] = attn_sum.data[4]; shmem_vk[warpId][row + 0][col + 9] = attn_sum.data[5]; shmem_vk[warpId][row + 8][col + 8] = attn_sum.data[6]; shmem_vk[warpId][row + 8][col + 9] = attn_sum.data[7]; } } for (int tile_k = 0; tile_k < LITELA_K_TILES; tile_k++) { packed_f32psum_t attn_sum = { 0 }; for (int i = 0; i < WARP_M_TILES; i++) { packed_fpsum_t k = fpsum[i * WARP_N_TILES + head_id * (LITELA_HEAD_DIM * 2) / 16 + tile_k]; packed_fpsum_t v = {}; for (int j = 0; j < 4; j++) { k.data[j] = __hmax2(k.data[j], half2_t(0, 0)); // relu } #pragma unroll for (int i = 0; i < 4; i++) { v.data[i] = half2_t(1, 1); } // if (laneId < 4) { // v.data[0] = half2_t(1, 1); // v.data[2] = half2_t(1, 1); // } // if (laneId % 4 == 0) { // v.data[0] = half2_t(1, 0); // v.data[1] = half2_t(1, 0); // } attn_sum = mma_litela(k, v, attn_sum); } const int row = LITELA_HEAD_DIM + laneId / 4; const int col = tile_k * 16 + laneId % 4 * 2; if (laneId < 4) { shmem_vk[warpId][row + 0][col + 0] = attn_sum.data[0]; shmem_vk[warpId][row + 0][col + 1] = attn_sum.data[1]; shmem_vk[warpId][row + 0][col + 8] = attn_sum.data[4]; shmem_vk[warpId][row + 0][col + 9] = attn_sum.data[5]; } } __syncthreads(); for (int i = warpId; i < LITELA_HEAD_DIM + 1; i += NUM_WARPS) { for (int j = laneId; j < LITELA_HEAD_DIM; j += WARP_SIZE) { float sum = 0; for (int k = 0; k < NUM_WARPS; k++) { sum += shmem_vk[k][i][j]; } reduce_add(&out_vk_current_head[i * LITELA_HEAD_DIM + j], sum); } } __syncthreads(); } } struct Arguments { half_t *out_q; float *out_vk; int num_blocks_per_batch; int actualM; }; __device__ __forceinline__ void operator()(const BlockInfo binfo, fpsum_warp fpsum, int M, int N, int K, Arguments args) { const int bm = binfo.bm; const int bn = binfo.bn; if (bn < binfo.numBlocksN / 3) { fpsum = apply_act(fpsum, [](half_t x) { return __hmax(x, 0); }); // relu return EpilogueDefault()( binfo, fpsum, M, N / 3, K, typename EpilogueDefault::Arguments{ .out = args.out_q, .actualM = args.actualM, .actualN = N / 3, }); } return apply_litela(binfo, fpsum, args.out_vk, args.num_blocks_per_batch); } // each thread block mults BlockSize*HEAD_DIM q and (HEAD_DIM+1)*HEAD_DIM vk, in-place writes back to q // q: [batch_size, #blocks, block_size, #heads, HEAD_DIM] // vk: [batch_size, #heads, HEAD_DIM+1, HEAD_DIM] struct vk_mul_q_kernel { // FIXME FIXME FIXME __device__ void operator()(half_t *q, const float *vk, float eps, int num_tokens) { const int block_id = blockIdx.x; const int head_id = blockIdx.y; const int batch_id = blockIdx.z; const int num_blocks = gridDim.x; const int num_heads = gridDim.y; const int block_size = blockDim.x; bool pred = block_id * block_size + threadIdx.x < num_tokens; half_t *localq = &q[(((batch_id * num_blocks + block_id) * block_size + threadIdx.x) * num_heads + head_id) * LITELA_HEAD_DIM]; const float *localvk = &vk[(batch_id * num_heads + head_id) * (LITELA_HEAD_DIM + 1) * LITELA_HEAD_DIM]; // half_t *localout = &out[(((batch_id * num_blocks + block_id) * block_size + threadIdx.x) * num_heads + head_id) * LITELA_HEAD_DIM]; using packed_q = std::array; using packed_vk = std::array; half_t qblock[LITELA_HEAD_DIM]; for (int i = 0; i < LITELA_HEAD_DIM; i += sizeof(packed_q) / sizeof(half_t)) { if (pred) { *reinterpret_cast(&qblock[i]) = load(reinterpret_cast(&localq[i])); } } float outblock[LITELA_HEAD_DIM + 1]; #pragma unroll for (int j = 0; j < LITELA_HEAD_DIM + 1; j++) { outblock[j] = 0; #pragma unroll for (int i = 0; i < LITELA_HEAD_DIM; i += sizeof(packed_vk) / sizeof(float)) { packed_vk vkpack = load(reinterpret_cast(&localvk[j * LITELA_HEAD_DIM + i])); #pragma unroll for (int k = 0; k < vkpack.size(); k++) { outblock[j] += (float)qblock[i + k] * vkpack[k]; } } } for (int i = 0; i < LITELA_HEAD_DIM; i += sizeof(packed_q) / sizeof(half_t)) { packed_q opack; for (int k = 0; k < opack.size(); k++) { opack[k] = __fdividef(outblock[i + k], outblock[LITELA_HEAD_DIM] + eps); } if (pred) { store(reinterpret_cast(&localq[i]), opack); } } } }; }; template struct gemm_w4a4_kernel { __device__ void operator()( const packed_act_t *act, const packed_wgt_t *wgt, const packed_ascale_t *ascales, const packed_wscale_t *wscales, int M, int N, int K, Epilogue::Arguments epilogueArgs, bool swapBlockXY, bool alwaysfalse) { // printf("Device sizeof(args) = %d", (int)sizeof(epilogueArgs)); BlockInfo binfo = { .bm = (int)blockIdx.x, .bn = (int)blockIdx.y, .numBlocksM = (int)gridDim.x, .numBlocksN = (int)gridDim.y, }; if (swapBlockXY) { std::swap(binfo.bm, binfo.bn); std::swap(binfo.numBlocksM, binfo.numBlocksN); } const int bm = binfo.bm; const int bn = binfo.bn; // bool fusequant = !out; gemm_w4a4_block( binfo, act + bm * (K / WARP_K) * NUM_WARPS * WARP_M_TILES * WARP_SIZE, wgt + bn * (K / WARP_K) * WARP_N_TILES * WARP_SIZE, ascales + bm * (K / WARP_K) * NUM_WARPS * ASCALES_NUM_PACKS * ASCALES_VALID_LANES, wscales + bn * (K / WARP_K) * WSCALES_NUM_PACKS * WSCALES_VALID_LANES, // bias ? bias + bn * WSCALES_NUM_PACKS * WSCALES_VALID_LANES : nullptr, // out + (bm * BLOCK_M * N) + bn * BLOCK_N, // out + (bm * N / BLOCK_N + bn) * NUM_WARPS * WARP_M_TILES * WARP_N_TILES * WARP_SIZE, M, N, K, epilogueArgs, alwaysfalse ); } }; }; }; // namespace nunchaku::kernels