#include #include #include #include "utils.h" static constexpr int kWarpSize = 32; static constexpr int DEFAULT_SHARED_MEM_THRESHOLD_KB = 48; // Default shared memory quota in KB // --------------------------------------------------------------------------- // 1. Warp‑local with configurable shared memory // • One warp handles one token. // • Eight tokens per 256‑thread CTA. // • Shared memory usage is configurable via template parameter. // --------------------------------------------------------------------------- template __global__ void per_token_quant_fp8_kernel( const T* __restrict__ input, DST_DTYPE* __restrict__ output_q, float* __restrict__ output_s, const int64_t hidden_dim, const int64_t num_tokens) { const int warp_id = threadIdx.x / kWarpSize; // 0‑7 (8 warps) const int lane_id = threadIdx.x & (kWarpSize - 1); // 0‑31 const int token_id = blockIdx.x * kTokensPerCTA + warp_id; if (token_id >= num_tokens) return; // Global tensors for this token const T* token_input = input + token_id * hidden_dim; DST_DTYPE* token_output = output_q + token_id * hidden_dim; float* token_scale = output_s + token_id; extern __shared__ char smem_buffer[]; const int smem_padding = 32; // Pad to bank boundary (32 banks * 4 bytes = 128 bytes) const int warp_smem_stride = (hidden_dim * sizeof(T) + smem_padding - 1) / smem_padding * smem_padding; const int warp_smem_offset = warp_id * warp_smem_stride; T* shared_input = reinterpret_cast(smem_buffer + warp_smem_offset); // // Pass-1: Load data and compute max_value // float max_value = 0.f; using vec_t = flashinfer::vec_t; const int32_t num_vec_elems = hidden_dim / kVecSize; for (int32_t i = lane_id; i < num_vec_elems; i += kWarpSize) { vec_t input_vec; input_vec.cast_load(token_input + i * kVecSize); // Store to shared memory if USE_SMEM=true if constexpr (USE_SMEM) { #pragma unroll for (uint32_t j = 0; j < kVecSize; ++j) { shared_input[i * kVecSize + j] = input_vec[j]; } } // Compute max value in parallel #pragma unroll for (uint32_t j = 0; j < kVecSize; ++j) { max_value = fmaxf(max_value, fabsf(static_cast(input_vec[j]))); } } // Ensure all threads in the warp have finished writing to shared memory if constexpr (USE_SMEM) { __syncwarp(); } float warp_max = warpReduceMax(max_value); // NOTE: one CTA has multiple warps (each warp handles one token), so `scale` // must be per-warp/per-thread (register) instead of a single shared variable. const float scale = warp_max / FP8_E4M3_MAX; // Broadcast scale if (lane_id == 0) { token_scale[0] = scale; } const float scale_inv = (scale == 0.f) ? 0.f : 1.0f / scale; // // Pass-2: Quantize and write back // for (int i = lane_id; i < num_vec_elems; i += kWarpSize) { vec_t input_vec; if constexpr (USE_SMEM) { // Load from shared memory #pragma unroll for (uint32_t j = 0; j < kVecSize; ++j) { input_vec[j] = shared_input[i * kVecSize + j]; } } else { // Reload from global memory input_vec.cast_load(token_input + i * kVecSize); } DST_DTYPE output_arr[kVecSize]; #pragma unroll for (uint32_t j = 0; j < kVecSize; ++j) { float val = static_cast(input_vec[j]) * scale_inv; val = fmaxf(fminf(val, FP8_E4M3_MAX), -FP8_E4M3_MAX); #if !defined(USE_ROCM) || defined(HIP_FP8_TYPE_E4M3) output_arr[j] = static_cast(val); #else output_arr[j] = c10::Float8_e4m3fnuz( __hip_cvt_float_to_fp8(val, fp8::fp8_type::__default_saturation, fp8::fp8_type::__default_interpret), c10::Float8_e4m3fnuz::from_bits()); #endif } if constexpr (kVecSize == 16) { *(uint4*)(token_output + i * kVecSize) = *(uint4*)output_arr; } else { // Use element-wise copy for vector size 8 to ensure correctness for (int k = 0; k < kVecSize; ++k) { token_output[i * kVecSize + k] = output_arr[k]; } } } } // --------------------------------------------------------------------------- // 2. Baseline kernel (1 token / CTA, CUB block reduce) // --------------------------------------------------------------------------- template __global__ void per_token_quant_fp8_small_batch_kernel( const T* __restrict__ input, DST_DTYPE* __restrict__ output_q, float* __restrict__ output_s, const int64_t hidden_dim, const int64_t num_tokens) { const int token_idx = blockIdx.x; if (token_idx >= num_tokens) return; const int tid = threadIdx.x; const int block_dim = blockDim.x; const T* token_input = input + token_idx * hidden_dim; DST_DTYPE* token_output = output_q + token_idx * hidden_dim; float max_value = 0.0f; // Use template parameter for vector size using vec_t = flashinfer::vec_t; const int32_t num_vec_elems = hidden_dim / kVecSize; // Find max using vectorized loads for (int32_t i = tid; i < num_vec_elems; i += block_dim) { vec_t input_vec; input_vec.cast_load(token_input + i * kVecSize); #pragma unroll for (uint32_t j = 0; j < kVecSize; ++j) { float val = static_cast(input_vec[j]); max_value = fmaxf(max_value, fabsf(val)); } } max_value = blockReduceMax(max_value); __shared__ float scale; if (tid == 0) { scale = max_value / FP8_E4M3_MAX; output_s[token_idx] = scale; } __syncthreads(); const float scale_inv = 1.0f / scale; // Quantize using vectorized loads for (int32_t i = tid; i < num_vec_elems; i += block_dim) { vec_t input_vec; input_vec.cast_load(token_input + i * kVecSize); DST_DTYPE output_arr[kVecSize]; #pragma unroll for (uint32_t j = 0; j < kVecSize; ++j) { float val = fmaxf(fminf(static_cast(input_vec[j]) * scale_inv, FP8_E4M3_MAX), -FP8_E4M3_MAX); #if !defined(USE_ROCM) || defined(HIP_FP8_TYPE_E4M3) output_arr[j] = static_cast(val); #else output_arr[j] = c10::Float8_e4m3fnuz( __hip_cvt_float_to_fp8(val, fp8::fp8_type::__default_saturation, fp8::fp8_type::__default_interpret), c10::Float8_e4m3fnuz::from_bits()); #endif } if constexpr (kVecSize == 16) { *(uint4*)(token_output + i * kVecSize) = *(uint4*)output_arr; } else { // Use element-wise copy for vector size 8 to ensure correctness for (int k = 0; k < kVecSize; ++k) { token_output[i * kVecSize + k] = output_arr[k]; } } } } template static inline void launch_per_token_quant_fp8_warp_kernel( const dim3& grid, const dim3& block, size_t dynamicSmemSz, cudaStream_t stream, bool use_vec16, bool use_vec8, torch::Tensor input, torch::Tensor output_q, torch::Tensor output_s, const int64_t hidden_dim, const int64_t num_tokens) { const size_t smem_size = USE_SMEM ? dynamicSmemSz : 0; if (use_vec16) { per_token_quant_fp8_kernel <<>>( static_cast(input.data_ptr()), static_cast<__nv_fp8_e4m3*>(output_q.data_ptr()), static_cast(output_s.data_ptr()), hidden_dim, num_tokens); } else if (use_vec8) { per_token_quant_fp8_kernel <<>>( static_cast(input.data_ptr()), static_cast<__nv_fp8_e4m3*>(output_q.data_ptr()), static_cast(output_s.data_ptr()), hidden_dim, num_tokens); } else { per_token_quant_fp8_kernel <<>>( static_cast(input.data_ptr()), static_cast<__nv_fp8_e4m3*>(output_q.data_ptr()), static_cast(output_s.data_ptr()), hidden_dim, num_tokens); } } void sgl_per_token_quant_fp8(torch::Tensor input, torch::Tensor output_q, torch::Tensor output_s) { CHECK_INPUT(input); CHECK_INPUT(output_q); CHECK_INPUT(output_s); const auto input_sizes = input.sizes(); const int64_t num_tokens = input_sizes[0]; const int64_t hidden_dim = input_sizes[1]; TORCH_CHECK(hidden_dim % 4 == 0, "Hidden dimension must be divisible by 4, but got ", hidden_dim); cudaStream_t stream = at::cuda::getCurrentCUDAStream(); const int sm_count = at::cuda::getCurrentDeviceProperties()->multiProcessorCount; const int TOKENS_PER_CTA = 8; const bool use_warp_kernel = (num_tokens >= sm_count * 2 * TOKENS_PER_CTA); const bool use_vec16 = (hidden_dim % 16 == 0); const bool use_vec8 = (hidden_dim % 8 == 0); const int sizeof_T = input.scalar_type() == torch::kFloat16 ? 2 : (input.scalar_type() == torch::kBFloat16 ? 2 : 4); const int smem_padding = 32; // Pad to bank boundary to avoid conflicts const int warp_smem_stride = (hidden_dim * sizeof_T + smem_padding - 1) / smem_padding * smem_padding; const size_t dynamicSmemSz = warp_smem_stride * TOKENS_PER_CTA; bool use_smem = (hidden_dim < 2048); if (dynamicSmemSz >= DEFAULT_SHARED_MEM_THRESHOLD_KB) { use_smem = false; // Disable shared memory if >= 48KB to avoid allocation failures } DISPATCH_PYTORCH_DTYPE_TO_CTYPE_FLOAT_FP16(input.scalar_type(), scalar_t, [&] { if (use_warp_kernel) { // -------- warp‑local --------------------------------------------------- constexpr int THREADS = TOKENS_PER_CTA * kWarpSize; dim3 grid((num_tokens + TOKENS_PER_CTA - 1) / TOKENS_PER_CTA); dim3 block(THREADS); if (use_smem) { launch_per_token_quant_fp8_warp_kernel( grid, block, dynamicSmemSz, stream, use_vec16, use_vec8, input, output_q, output_s, hidden_dim, num_tokens); } else { launch_per_token_quant_fp8_warp_kernel( grid, block, dynamicSmemSz, stream, use_vec16, use_vec8, input, output_q, output_s, hidden_dim, num_tokens); } } else { // -------- baseline ----------------------------------------------------- constexpr int THREADS = 256; dim3 grid(num_tokens); dim3 block(THREADS); if (use_vec16) { per_token_quant_fp8_small_batch_kernel<<>>( static_cast(input.data_ptr()), static_cast<__nv_fp8_e4m3*>(output_q.data_ptr()), static_cast(output_s.data_ptr()), hidden_dim, num_tokens); } else if (use_vec8) { per_token_quant_fp8_small_batch_kernel<<>>( static_cast(input.data_ptr()), static_cast<__nv_fp8_e4m3*>(output_q.data_ptr()), static_cast(output_s.data_ptr()), hidden_dim, num_tokens); } else { per_token_quant_fp8_small_batch_kernel<<>>( static_cast(input.data_ptr()), static_cast<__nv_fp8_e4m3*>(output_q.data_ptr()), static_cast(output_s.data_ptr()), hidden_dim, num_tokens); } } return true; }); }