#include #include #include #include #include template struct TypeConverter { using Type = half2; }; // keep for generality template <> struct TypeConverter { using Type = half; }; template <> struct TypeConverter { using Type = half2; }; template <> struct TypeConverter<__nv_bfloat162> { using Type = __nv_bfloat16; }; template <> struct TypeConverter<__nv_bfloat16> { using Type = __nv_bfloat162; }; #define ELTS_PER_THREAD 8 constexpr int CVT_FP4_ELTS_PER_THREAD = 8; constexpr int CVT_FP4_SF_VEC_SIZE = 16; // Convert 8 float32 values into 8 e2m1 values (represented as one uint32_t). inline __device__ uint32_t fp32_vec_to_e2m1(float (&array)[8]) { #if defined(__CUDA_ARCH__) && (__CUDA_ARCH__ >= 1000) uint32_t val; asm volatile( "{\n" ".reg .b8 byte0;\n" ".reg .b8 byte1;\n" ".reg .b8 byte2;\n" ".reg .b8 byte3;\n" "cvt.rn.satfinite.e2m1x2.f32 byte0, %2, %1;\n" "cvt.rn.satfinite.e2m1x2.f32 byte1, %4, %3;\n" "cvt.rn.satfinite.e2m1x2.f32 byte2, %6, %5;\n" "cvt.rn.satfinite.e2m1x2.f32 byte3, %8, %7;\n" "mov.b32 %0, {byte0, byte1, byte2, byte3};\n" "}" : "=r"(val) : "f"(array[0]), "f"(array[1]), "f"(array[2]), "f"(array[3]), "f"(array[4]), "f"(array[5]), "f"(array[6]), "f"(array[7])); return val; #else return 0; #endif } // Convert 4 float2 values into 8 e2m1 values (represented as one uint32_t). inline __device__ uint32_t fp32_vec_to_e2m1(float2 (&array)[4]) { #if defined(__CUDA_ARCH__) && (__CUDA_ARCH__ >= 1000) uint32_t val; asm volatile( "{\n" ".reg .b8 byte0;\n" ".reg .b8 byte1;\n" ".reg .b8 byte2;\n" ".reg .b8 byte3;\n" "cvt.rn.satfinite.e2m1x2.f32 byte0, %2, %1;\n" "cvt.rn.satfinite.e2m1x2.f32 byte1, %4, %3;\n" "cvt.rn.satfinite.e2m1x2.f32 byte2, %6, %5;\n" "cvt.rn.satfinite.e2m1x2.f32 byte3, %8, %7;\n" "mov.b32 %0, {byte0, byte1, byte2, byte3};\n" "}" : "=r"(val) : "f"(array[0].x), "f"(array[0].y), "f"(array[1].x), "f"(array[1].y), "f"(array[2].x), "f"(array[2].y), "f"(array[3].x), "f"(array[3].y)); return val; #else return 0; #endif } // Fast reciprocal. inline __device__ float reciprocal_approximate_ftz(float a) { float b; asm volatile("rcp.approx.ftz.f32 %0, %1;\n" : "=f"(b) : "f"(a)); return b; } template __device__ uint8_t* cvt_quant_to_fp4_get_sf_out_offset(int rowIdx, int colIdx, int numCols, SFType* SFout) { #if defined(__CUDA_ARCH__) && (__CUDA_ARCH__ >= 1000) static_assert(CVT_FP4_NUM_THREADS_PER_SF == 1 || CVT_FP4_NUM_THREADS_PER_SF == 2); // One pair of threads write one SF to global memory. // TODO: stage through smem for packed STG.32 // is it better than STG.8 from 4 threads ? if (threadIdx.x % CVT_FP4_NUM_THREADS_PER_SF == 0) { // SF vector index (16 elements share one SF in the K dimension). int32_t kIdx = colIdx / CVT_FP4_NUM_THREADS_PER_SF; int32_t mIdx = rowIdx; // SF layout [numMTiles, numKTiles, 32 (mTile), 4 (mTile), 4(kTile)] // --> index [mTileIdx, kTileIdx, outerMIdx, innerMIdx, innerKIdx] int32_t mTileIdx = mIdx / (32 * 4); // SF vector size 16. int factor = CVT_FP4_SF_VEC_SIZE * 4; int32_t numKTiles = (numCols + factor - 1) / factor; int64_t mTileStride = numKTiles * 32 * 4 * 4; int32_t kTileIdx = (kIdx / 4); int64_t kTileStride = 32 * 4 * 4; // M tile layout [32, 4] is column-major. int32_t outerMIdx = (mIdx % 32); int64_t outerMStride = 4 * 4; int32_t innerMIdx = (mIdx % (32 * 4)) / 32; int64_t innerMStride = 4; int32_t innerKIdx = (kIdx % 4); int64_t innerKStride = 1; // Compute the global offset. int64_t SFOffset = mTileIdx * mTileStride + kTileIdx * kTileStride + outerMIdx * outerMStride + innerMIdx * innerMStride + innerKIdx * innerKStride; return reinterpret_cast(SFout) + SFOffset; } #endif return nullptr; } // Define a 16 bytes packed data type. template struct PackedVec { typename TypeConverter::Type elts[4]; }; template <> struct PackedVec<__nv_fp8_e4m3> { __nv_fp8x2_e4m3 elts[8]; }; // Quantizes the provided PackedVec into the uint32_t output template __device__ uint32_t cvt_warp_fp16_to_fp4(PackedVec& vec, float SFScaleVal, uint8_t* SFout) { #if defined(__CUDA_ARCH__) && (__CUDA_ARCH__ >= 1000) // Get absolute maximum values among the local 8 values. auto localMax = __habs2(vec.elts[0]); // Local maximum value. #pragma unroll for (int i = 1; i < CVT_FP4_ELTS_PER_THREAD / 2; i++) { localMax = __hmax2(localMax, __habs2(vec.elts[i])); } // Get the absolute maximum among all 16 values (two threads). localMax = __hmax2(__shfl_xor_sync(uint32_t(-1), localMax, 1), localMax); // Get the final absolute maximum values. float vecMax = float(__hmax(localMax.x, localMax.y)); // Get the SF (max value of the vector / max value of e2m1). // maximum value of e2m1 = 6.0. // TODO: use half as compute data type. float SFValue = SFScaleVal * (vecMax * reciprocal_approximate_ftz(6.0f)); // 8 bits representation of the SF. uint8_t fp8SFVal; // Write the SF to global memory (STG.8). if constexpr (UE8M0_SF) { // Extract the 8 exponent bits from float32. // float 32bits = 1 sign bit + 8 exponent bits + 23 mantissa bits. uint32_t tmp = reinterpret_cast(SFValue) >> 23; fp8SFVal = tmp & 0xff; // Convert back to fp32. reinterpret_cast(SFValue) = tmp << 23; } else { // Here SFValue is always positive, so E4M3 is the same as UE4M3. __nv_fp8_e4m3 tmp = __nv_fp8_e4m3(SFValue); reinterpret_cast<__nv_fp8_e4m3&>(fp8SFVal) = tmp; // Convert back to fp32. SFValue = float(tmp); } // Get the output scale. // Recipe: final_scale = reciprocal(fp32(fp8(SFValue * SFScaleVal))) * // reciprocal(SFScaleVal)) float outputScale = SFValue != 0 ? reciprocal_approximate_ftz( SFValue * reciprocal_approximate_ftz(SFScaleVal)) : 0.0f; if (SFout) { // Write the SF to global memory (STG.8). *SFout = fp8SFVal; } // Convert the input to float. float2 fp2Vals[CVT_FP4_ELTS_PER_THREAD / 2]; #pragma unroll for (int i = 0; i < CVT_FP4_ELTS_PER_THREAD / 2; i++) { if constexpr (std::is_same_v) { fp2Vals[i] = __half22float2(vec.elts[i]); } else { fp2Vals[i] = __bfloat1622float2(vec.elts[i]); } fp2Vals[i].x *= outputScale; fp2Vals[i].y *= outputScale; } // Convert to e2m1 values. uint32_t e2m1Vec = fp32_vec_to_e2m1(fp2Vals); // Write the e2m1 values to global memory. return e2m1Vec; #else return 0; #endif } // Use UE4M3 by default. template __global__ void #if defined(__CUDA_ARCH__) && (__CUDA_ARCH__ >= 1000) __launch_bounds__(512, 4) cvt_fp16_to_fp4( #else cvt_fp16_to_fp4( #endif int32_t numRows, int32_t numCols, Type const* in, float const* SFScale, uint32_t* out, uint32_t* SFout, uint32_t* input_offset_by_experts, uint32_t* output_scale_offset_by_experts, int n_experts, bool low_latency) { #if defined(__CUDA_ARCH__) && (__CUDA_ARCH__ >= 1000) using PackedVec = PackedVec; static constexpr int CVT_FP4_NUM_THREADS_PER_SF = (CVT_FP4_SF_VEC_SIZE / CVT_FP4_ELTS_PER_THREAD); static_assert(sizeof(PackedVec) == sizeof(Type) * CVT_FP4_ELTS_PER_THREAD, "Vec size is not matched."); int tid = blockIdx.x * blockDim.x + threadIdx.x; int colsPerRow = numCols / CVT_FP4_ELTS_PER_THREAD; // Each global thread processes one element for (int globalIdx = tid; globalIdx < numRows * colsPerRow; globalIdx += gridDim.x * blockDim.x) { // Calculate which row and column this global thread should process int rowIdx = globalIdx / colsPerRow; int colIdx = globalIdx % colsPerRow; int64_t inOffset = rowIdx * colsPerRow + colIdx; PackedVec in_vec = reinterpret_cast(in)[inOffset]; // Get the output tensor offset. // Same as inOffset because 8 elements are packed into one uint32_t. int64_t outOffset = inOffset; auto& out_pos = out[outOffset]; // Find index within the experts using different strategies based on expert // count int rowIdx_in_expert = 0; int expert_idx = 0; if constexpr (SMALL_NUM_EXPERTS) { for (int i = 0; i < n_experts; i++) { uint32_t current_offset = __ldca(&input_offset_by_experts[i]); uint32_t next_offset = __ldca(&input_offset_by_experts[i + 1]); if (rowIdx >= current_offset && rowIdx < next_offset) { rowIdx_in_expert = rowIdx - current_offset; expert_idx = i; break; } } } else { // Load input offsets into registers first, then do the computation. // Local array size set to 17 because of register limit. uint32_t local_offsets[17]; for (int chunk_start = 0; chunk_start < n_experts; chunk_start += 16) { *reinterpret_cast(local_offsets) = __ldca(reinterpret_cast( &input_offset_by_experts[chunk_start])); *reinterpret_cast(local_offsets + 4) = __ldca(reinterpret_cast( &input_offset_by_experts[chunk_start + 4])); *reinterpret_cast(local_offsets + 8) = __ldca(reinterpret_cast( &input_offset_by_experts[chunk_start + 8])); *reinterpret_cast(local_offsets + 12) = __ldca(reinterpret_cast( &input_offset_by_experts[chunk_start + 12])); local_offsets[16] = __ldca(&input_offset_by_experts[chunk_start + 16]); // Check against the 16 loaded offsets #pragma unroll for (int i = 0; i < 16; i++) { if (rowIdx >= local_offsets[i] && rowIdx < local_offsets[i + 1]) { rowIdx_in_expert = rowIdx - local_offsets[i]; expert_idx = chunk_start + i; break; } } } } // Get the global scaling factor, which will be applied to the SF. // Note SFScale is the same as next GEMM's alpha, which is // (448.f / (Alpha_A / 6.f)). float const SFScaleVal = SFScale == nullptr ? 1.0f : SFScale[expert_idx]; int factor = CVT_FP4_SF_VEC_SIZE * 4; // The actual output_scales dim is computed from the padded numCols. int32_t numCols_padded = (numCols + factor - 1) / factor * factor; int numCols_SFout = numCols_padded / CVT_FP4_SF_VEC_SIZE / 4; uint32_t* SFout_in_expert = SFout + output_scale_offset_by_experts[expert_idx] * numCols_SFout; auto sf_out = cvt_quant_to_fp4_get_sf_out_offset( rowIdx_in_expert, colIdx, numCols, SFout_in_expert); out_pos = cvt_warp_fp16_to_fp4(in_vec, SFScaleVal, sf_out); } #endif } // Kernel for LARGE_M_TOPK = true (large m_topk optimized version) template __global__ void #if defined(__CUDA_ARCH__) && (__CUDA_ARCH__ >= 1000) __launch_bounds__(1024, 4) cvt_fp16_to_fp4( #else cvt_fp16_to_fp4( #endif int32_t numRows, int32_t numCols, Type const* in, float const* SFScale, uint32_t* out, uint32_t* SFout, uint32_t* input_offset_by_experts, uint32_t* output_scale_offset_by_experts, int n_experts) { #if defined(__CUDA_ARCH__) && (__CUDA_ARCH__ >= 1000) using PackedVec = PackedVec; static constexpr int CVT_FP4_NUM_THREADS_PER_SF = (CVT_FP4_SF_VEC_SIZE / CVT_FP4_ELTS_PER_THREAD); static_assert(sizeof(PackedVec) == sizeof(Type) * CVT_FP4_ELTS_PER_THREAD, "Vec size is not matched."); extern __shared__ uint32_t shared_input_offsets[]; // Load input offsets into shared memory. // If n_experts is larger than 4, use vectorized int4 to save instructions. // If n_experts is smaller than 4, read directly. if constexpr (SMALL_NUM_EXPERTS) { for (int i = threadIdx.x; i < n_experts + 1; i += blockDim.x) { shared_input_offsets[i] = input_offset_by_experts[i]; } } else { for (int i = threadIdx.x * 4; i < n_experts; i += blockDim.x * 4) { *reinterpret_cast(&shared_input_offsets[i]) = *reinterpret_cast(&input_offset_by_experts[i]); } if (threadIdx.x == 0) { shared_input_offsets[n_experts] = input_offset_by_experts[n_experts]; } } __syncthreads(); int tid = blockIdx.x * blockDim.x + threadIdx.x; int colsPerRow = numCols / CVT_FP4_ELTS_PER_THREAD; // Each global thread processes one element for (int globalIdx = tid; globalIdx < numRows * colsPerRow; globalIdx += gridDim.x * blockDim.x) { // Calculate which row and column this global thread should process int rowIdx = globalIdx / colsPerRow; int colIdx = globalIdx % colsPerRow; int64_t inOffset = rowIdx * colsPerRow + colIdx; PackedVec in_vec = reinterpret_cast(in)[inOffset]; int64_t outOffset = inOffset; auto& out_pos = out[outOffset]; // Find expert using binary search for better performance with large m_topk int rowIdx_in_expert = 0; int expert_idx = 0; // Binary search through experts using shared memory int left = 0, right = n_experts - 1; while (left <= right) { int mid = (left + right) / 2; // Get offsets: shared_input_offsets[i] corresponds to // input_offset_by_experts[i] uint32_t mid_offset = shared_input_offsets[mid]; uint32_t next_offset = shared_input_offsets[mid + 1]; if (rowIdx >= mid_offset && rowIdx < next_offset) { rowIdx_in_expert = rowIdx - mid_offset; expert_idx = mid; break; } else if (rowIdx < mid_offset) { right = mid - 1; } else { left = mid + 1; } } float const SFScaleVal = SFScale == nullptr ? 1.0f : SFScale[expert_idx]; int factor = CVT_FP4_SF_VEC_SIZE * 4; int32_t numCols_padded = (numCols + factor - 1) / factor * factor; int numCols_SFout = numCols_padded / CVT_FP4_SF_VEC_SIZE / 4; uint32_t* SFout_in_expert = SFout + output_scale_offset_by_experts[expert_idx] * numCols_SFout; auto sf_out = cvt_quant_to_fp4_get_sf_out_offset( rowIdx_in_expert, colIdx, numCols, SFout_in_expert); out_pos = cvt_warp_fp16_to_fp4(in_vec, SFScaleVal, sf_out); } #endif } template void quant_impl(void* output, void* output_scale, void* input, void* input_global_scale, void* input_offset_by_experts, void* output_scale_offset_by_experts, int m_topk, int k, int n_experts, cudaStream_t stream) { // TODO: this multiProcessorCount should be cached. int device; cudaGetDevice(&device); int multiProcessorCount; cudaDeviceGetAttribute(&multiProcessorCount, cudaDevAttrMultiProcessorCount, device); // Grid, Block size. // Each thread converts 8 values. int const workSizePerRow = k / ELTS_PER_THREAD; int const totalWorkSize = m_topk * workSizePerRow; dim3 block(std::min(workSizePerRow, 512)); // Get number of blocks per SM (assume we can fully utilize the SM). int const numBlocksPerSM = 2048 / block.x; dim3 grid(std::min(static_cast((totalWorkSize + block.x - 1) / block.x), multiProcessorCount * numBlocksPerSM)); while (grid.x <= multiProcessorCount && block.x > 64) { grid.x *= 2; block.x = (block.x + 1) / 2; } int const blockRepeat = (totalWorkSize + block.x * grid.x - 1) / (block.x * grid.x); if (blockRepeat > 1) { size_t shared_mem_size = (n_experts + 1) * sizeof(uint32_t); if (n_experts >= 4) { cvt_fp16_to_fp4 <<>>( m_topk, k, reinterpret_cast(input), reinterpret_cast(input_global_scale), reinterpret_cast(output), reinterpret_cast(output_scale), reinterpret_cast(input_offset_by_experts), reinterpret_cast(output_scale_offset_by_experts), n_experts); } else { cvt_fp16_to_fp4<<>>( m_topk, k, reinterpret_cast(input), reinterpret_cast(input_global_scale), reinterpret_cast(output), reinterpret_cast(output_scale), reinterpret_cast(input_offset_by_experts), reinterpret_cast(output_scale_offset_by_experts), n_experts); } } else { if (n_experts >= 16) { cvt_fp16_to_fp4<<>>( m_topk, k, reinterpret_cast(input), reinterpret_cast(input_global_scale), reinterpret_cast(output), reinterpret_cast(output_scale), reinterpret_cast(input_offset_by_experts), reinterpret_cast(output_scale_offset_by_experts), n_experts, /* bool low_latency */ true); } else { cvt_fp16_to_fp4<<>>( m_topk, k, reinterpret_cast(input), reinterpret_cast(input_global_scale), reinterpret_cast(output), reinterpret_cast(output_scale), reinterpret_cast(input_offset_by_experts), reinterpret_cast(output_scale_offset_by_experts), n_experts, /* bool low_latency */ true); } } } /*Quantization entry for fp4 experts quantization*/ #define CHECK_TH_CUDA(x, m) TORCH_CHECK(x.is_cuda(), m, "must be a CUDA tensor") #define CHECK_CONTIGUOUS(x, m) \ TORCH_CHECK(x.is_contiguous(), m, "must be contiguous") #define CHECK_INPUT(x, m) \ CHECK_TH_CUDA(x, m); \ CHECK_CONTIGUOUS(x, m); constexpr auto HALF = at::ScalarType::Half; constexpr auto BF16 = at::ScalarType::BFloat16; constexpr auto FLOAT = at::ScalarType::Float; constexpr auto INT = at::ScalarType::Int; constexpr auto UINT8 = at::ScalarType::Byte; void scaled_fp4_experts_quant_sm100a( torch::Tensor& output, torch::Tensor& output_scale, torch::Tensor const& input, torch::Tensor const& input_global_scale, torch::Tensor const& input_offset_by_experts, torch::Tensor const& output_scale_offset_by_experts) { CHECK_INPUT(output, "output must be a CUDA tensor"); CHECK_INPUT(output_scale, "output_scale must be a CUDA tensor"); CHECK_INPUT(input, "input must be a CUDA tensor"); CHECK_INPUT(input_global_scale, "input_global_scale must be a CUDA tensor"); CHECK_INPUT(input_offset_by_experts, "input_offset_by_experts must be a CUDA tensor"); CHECK_INPUT(output_scale_offset_by_experts, "output_scale_offset_by_experts must be a CUDA tensor"); TORCH_CHECK(output.dim() == 2); TORCH_CHECK(output_scale.dim() == 2); TORCH_CHECK(input.dim() == 2); TORCH_CHECK(input_global_scale.dim() == 1); TORCH_CHECK(input_offset_by_experts.dim() == 1); TORCH_CHECK(output_scale_offset_by_experts.dim() == 1); TORCH_CHECK(input.scalar_type() == HALF || input.scalar_type() == BF16); TORCH_CHECK(input_global_scale.scalar_type() == FLOAT); TORCH_CHECK(input_offset_by_experts.scalar_type() == INT); TORCH_CHECK(output_scale_offset_by_experts.scalar_type() == INT); // output is uint8 (two nvfp4 values are packed into one uint8) // output_scale is int32 (four fp8 values are packed into one int32) TORCH_CHECK(output.scalar_type() == UINT8); TORCH_CHECK(output_scale.scalar_type() == INT); const int BLOCK_SIZE = 16; auto m_topk = input.size(0); auto k = input.size(1); TORCH_CHECK(k % BLOCK_SIZE == 0, "k must be a multiple of 16"); auto n_experts = input_global_scale.size(0); TORCH_CHECK(input_offset_by_experts.size(0) == n_experts + 1); TORCH_CHECK(output_scale_offset_by_experts.size(0) == n_experts + 1); TORCH_CHECK(output.size(0) == m_topk); TORCH_CHECK(output.size(1) == k / 2); int scales_k = k / BLOCK_SIZE; // 4 means the swizzle requirement by nvidia nvfp4. int padded_k = (scales_k + (4 - 1)) / 4 * 4; // 4 means 4 fp8 values are packed into one int32 TORCH_CHECK(output_scale.size(1) * 4 == padded_k); auto in_dtype = input.dtype(); const at::cuda::OptionalCUDAGuard device_guard(device_of(input)); const cudaStream_t stream = at::cuda::getCurrentCUDAStream(input.get_device()); if (in_dtype == at::ScalarType::Half) { quant_impl(output.data_ptr(), output_scale.data_ptr(), input.data_ptr(), input_global_scale.data_ptr(), input_offset_by_experts.data_ptr(), output_scale_offset_by_experts.data_ptr(), m_topk, k, n_experts, stream); } else if (in_dtype == at::ScalarType::BFloat16) { quant_impl<__nv_bfloat16>(output.data_ptr(), output_scale.data_ptr(), input.data_ptr(), input_global_scale.data_ptr(), input_offset_by_experts.data_ptr(), output_scale_offset_by_experts.data_ptr(), m_topk, k, n_experts, stream); } else { TORCH_CHECK(false, "Expected input data type to be half or bfloat16"); } }