/* * Modified by Neural Magic * Copyright (C) Marlin.2024 Elias Frantar * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ /* * Adapted from https://github.com/IST-DASLab/marlin */ #ifndef MARLIN_NAMESPACE_NAME #define MARLIN_NAMESPACE_NAME marlin_moe_wna16 #endif #include "kernel.h" #include "core/registration.h" #define STATIC_ASSERT_SCALAR_TYPE_VALID(scalar_t) \ static_assert(std::is_same::value || \ std::is_same::value, \ "only float16 and bfloat16 is supported"); namespace MARLIN_NAMESPACE_NAME { __global__ void MarlinDefault(MARLIN_KERNEL_PARAMS){}; using MarlinFuncPtr = void (*)(MARLIN_KERNEL_PARAMS); // For a given "a" of size [M,K] performs a permutation of the K columns based // on the given "perm" indices. template __global__ void permute_cols_kernel( int4 const* __restrict__ a_int4_ptr, int const* __restrict__ perm_int_ptr, int4* __restrict__ out_int4_ptr, const int32_t* __restrict__ sorted_token_ids_ptr, const int32_t* __restrict__ expert_ids_ptr, const int32_t* __restrict__ num_tokens_past_padded_ptr, int size_m, int size_k, int top_k) { int num_tokens_past_padded = num_tokens_past_padded_ptr[0]; int num_moe_blocks = div_ceil(num_tokens_past_padded, moe_block_size); int32_t block_sorted_ids[moe_block_size]; int block_num_valid_tokens = 0; int64_t old_expert_id = 0; int64_t expert_id = 0; int row_stride = size_k * sizeof(half) / 16; auto read_moe_block_data = [&](int block_id) { block_num_valid_tokens = moe_block_size; int4* tmp_block_sorted_ids = reinterpret_cast(block_sorted_ids); for (int i = 0; i < moe_block_size / 4; i++) { tmp_block_sorted_ids[i] = ((int4*)sorted_token_ids_ptr)[block_id * moe_block_size / 4 + i]; } for (int i = 0; i < moe_block_size; i++) { if (block_sorted_ids[i] >= size_m * top_k) { block_num_valid_tokens = i; break; }; } }; auto permute_row = [&](int row) { int iters = size_k / default_threads; int rest = size_k % default_threads; int in_offset = (row / top_k) * row_stride; int out_offset = row * row_stride; half const* a_row_half = reinterpret_cast(a_int4_ptr + in_offset); half* out_half = reinterpret_cast(out_int4_ptr + out_offset); int base_k = 0; for (int i = 0; i < iters; i++) { auto cur_k = base_k + threadIdx.x; int src_pos = perm_int_ptr[cur_k]; out_half[cur_k] = a_row_half[src_pos]; base_k += default_threads; } if (rest) { if (threadIdx.x < rest) { auto cur_k = base_k + threadIdx.x; int src_pos = perm_int_ptr[cur_k]; out_half[cur_k] = a_row_half[src_pos]; } } }; for (int index = blockIdx.x; index < num_moe_blocks; index += gridDim.x) { old_expert_id = expert_id; int tmp_expert_id = expert_ids_ptr[index]; if (tmp_expert_id == -1) continue; expert_id = tmp_expert_id; perm_int_ptr += (expert_id - old_expert_id) * size_k; read_moe_block_data(index); for (int i = 0; i < block_num_valid_tokens; i++) permute_row(block_sorted_ids[i]); } } typedef struct { int thread_k; int thread_n; int num_threads; } thread_config_t; thread_config_t small_batch_thread_configs[] = { // Ordered by priority // thread_k, thread_n, num_threads {128, 128, 256}, {64, 128, 128}}; thread_config_t large_batch_thread_configs[] = { // Ordered by priority // thread_k, thread_n, num_threads {64, 256, 256}, {64, 128, 128}}; typedef struct { int blocks_per_sm; thread_config_t tb_cfg; } exec_config_t; int get_scales_cache_size(thread_config_t const& th_config, int prob_m, int prob_n, int prob_k, int num_bits, int group_size, bool has_act_order, bool is_k_full) { bool cache_scales_chunk = has_act_order && !is_k_full; int tb_n = th_config.thread_n; int tb_k = th_config.thread_k; // Get max scale groups per thread-block int tb_groups; if (group_size == -1) { tb_groups = 1; } else if (group_size == 0) { tb_groups = div_ceil(tb_k, 32); // Worst case is 32 group size } else { tb_groups = div_ceil(tb_k, group_size); } if (cache_scales_chunk) { int load_groups = tb_groups * pipe_stages * 2; // Chunk size is 2x pipeline over dim K load_groups = max(load_groups, 32); // We load at least 32 scale groups return load_groups * tb_n * 2; } else { int tb_scales = tb_groups * tb_n * 2; return tb_scales * pipe_stages; } } int get_kernel_cache_size(thread_config_t const& th_config, bool m_block_size_8, int thread_m_blocks, int prob_m, int prob_n, int prob_k, int num_bits, int group_size, bool has_act_order, bool is_k_full, int has_zp, int is_zp_float, bool is_a_8bit) { int pack_factor = 32 / num_bits; // Get B size int tb_k = th_config.thread_k; int tb_n = th_config.thread_n; int tb_m = thread_m_blocks * 16; // shm size for block_sorted_ids/rd_block_sorted_ids/block_topk_weights // both of them requires tb_m * 4 bytes (tb_m * int32 or tb_m * float32) int sh_block_meta_size = tb_m * 16; int sh_a_size = pipe_stages * (tb_m * tb_k) * (is_a_8bit ? 1 : 2); int sh_b_size = pipe_stages * (tb_k * tb_n / pack_factor) * 4; int sh_red_size = tb_m * (tb_n + 8) * 2; int sh_bias_size = tb_n * 2; int tmp_size = (sh_b_size > sh_red_size ? sh_red_size : sh_b_size) + sh_bias_size; tmp_size = max(max(sh_b_size, sh_red_size), tmp_size); int sh_s_size = get_scales_cache_size(th_config, prob_m, prob_n, prob_k, num_bits, group_size, has_act_order, is_k_full); int sh_g_idx_size = has_act_order && !is_k_full ? pipe_stages * tb_k / 4 : 0; int sh_zp_size = 0; if (has_zp) { if (is_zp_float) sh_zp_size = sh_s_size; else if (num_bits == 4) sh_zp_size = sh_s_size / 4; else if (num_bits == 8) sh_zp_size = sh_s_size / 2; } int total_size = tmp_size + sh_a_size + sh_s_size + sh_zp_size + sh_g_idx_size + sh_block_meta_size; return total_size; } bool is_valid_config(thread_config_t const& th_config, bool m_block_size_8, int thread_m_blocks, int prob_m, int prob_n, int prob_k, int num_bits, int group_size, bool has_act_order, bool is_k_full, int has_zp, int is_zp_float, int max_shared_mem, bool is_a_8bit) { // Sanity if (th_config.thread_k == -1 || th_config.thread_n == -1 || th_config.num_threads == -1) { return false; } // Verify K/N are divisible by thread K/N if (prob_k % th_config.thread_k != 0 || prob_n % th_config.thread_n != 0) { return false; } // Verify min for thread K/N if (th_config.thread_n < min_thread_n || th_config.thread_k < min_thread_k) { return false; } // num_threads must be at least 128 (= 4 warps) if (th_config.num_threads < 128) { return false; } // Check that pipeline fits into cache int cache_size = get_kernel_cache_size(th_config, m_block_size_8, thread_m_blocks, prob_m, prob_n, prob_k, num_bits, group_size, has_act_order, is_k_full, has_zp, is_zp_float, is_a_8bit); return cache_size <= max_shared_mem; } MarlinFuncPtr get_marlin_kernel( const vllm::ScalarType a_type, const vllm::ScalarType b_type, const vllm::ScalarType c_type, const vllm::ScalarType s_type, int thread_m_blocks, int thread_n_blocks, int thread_k_blocks, bool m_block_size_8, bool has_act_order, bool has_zp, int group_blocks, int threads, bool is_zp_float) { int num_bits = b_type.size_bits(); auto kernel = MarlinDefault; #include "kernel_selector.h" return kernel; } exec_config_t determine_exec_config( const vllm::ScalarType& a_type, const vllm::ScalarType& b_type, const vllm::ScalarType& c_type, const vllm::ScalarType& s_type, int prob_m, int prob_n, int prob_k, int num_experts, int top_k, int thread_m_blocks, bool m_block_size_8, int num_bits, int group_size, bool has_act_order, bool is_k_full, bool has_zp, bool is_zp_float, int max_shared_mem, int sms, bool is_a_8bit) { exec_config_t exec_cfg = exec_config_t{1, thread_config_t{-1, -1, -1}}; thread_config_t* thread_configs = thread_m_blocks > 1 ? large_batch_thread_configs : small_batch_thread_configs; int thread_configs_size = thread_m_blocks > 1 ? sizeof(large_batch_thread_configs) / sizeof(thread_config_t) : sizeof(small_batch_thread_configs) / sizeof(thread_config_t); int count = 0; constexpr int device_max_reg_size = 255 * 1024; for (int i = 0; i < thread_configs_size; i++) { thread_config_t th_config = thread_configs[i]; if (!is_valid_config(th_config, m_block_size_8, thread_m_blocks, prob_m, prob_n, prob_k, num_bits, group_size, has_act_order, is_k_full, has_zp, is_zp_float, max_shared_mem - 512, is_a_8bit)) { continue; } int cache_size = get_kernel_cache_size( th_config, m_block_size_8, thread_m_blocks, prob_m, prob_n, prob_k, num_bits, group_size, has_act_order, is_k_full, has_zp, is_zp_float, is_a_8bit); int group_blocks = 0; if (!has_act_order) { group_blocks = group_size == -1 ? -1 : (group_size / 16); } auto kernel = get_marlin_kernel(a_type, b_type, c_type, s_type, thread_m_blocks, th_config.thread_n / 16, th_config.thread_k / 16, m_block_size_8, has_act_order, has_zp, group_blocks, th_config.num_threads, is_zp_float); if (kernel == MarlinDefault) continue; cudaFuncAttributes attr; cudaFuncGetAttributes(&attr, kernel); int reg_size = max(attr.numRegs, 1) * th_config.num_threads * 4; int allow_count = min(device_max_reg_size / reg_size, max_shared_mem / (cache_size + 1536)); if (thread_m_blocks == 1) allow_count = max(min(allow_count, 4), 1); else allow_count = max(min(allow_count, 2), 1); if (prob_n / th_config.thread_n * prob_m * top_k * 4 < sms * allow_count) { allow_count = max(prob_n / th_config.thread_n * prob_m * top_k * 4 / sms, 1); } if (allow_count > count) { count = allow_count; exec_cfg = {count, th_config}; }; } return exec_cfg; } void marlin_mm(const void* A, const void* B, void* C, void* C_tmp, void* b_bias, void* a_s, void* b_s, void* g_s, void* zp, void* g_idx, void* perm, void* a_tmp, void* sorted_token_ids, void* expert_ids, void* num_tokens_past_padded, void* topk_weights, int moe_block_size, int num_experts, int top_k, bool mul_topk_weights, bool is_ep, int prob_m, int prob_n, int prob_k, void* workspace, vllm::ScalarType const& a_type, vllm::ScalarType const& b_type, vllm::ScalarType const& c_type, vllm::ScalarType const& s_type, bool has_bias, bool has_act_order, bool is_k_full, bool has_zp, int num_groups, int group_size, int dev, cudaStream_t stream, int thread_k, int thread_n, int sms, int blocks_per_sm, bool use_atomic_add, bool use_fp32_reduce, bool is_zp_float) { int thread_m_blocks = div_ceil(moe_block_size, 16); bool m_block_size_8 = moe_block_size == 8; bool is_a_8bit = a_type.size_bits() == 8; TORCH_CHECK(prob_m > 0 && prob_n > 0 && prob_k > 0, "Invalid MNK = [", prob_m, ", ", prob_n, ", ", prob_k, "]"); int group_blocks = 0; if (has_act_order) { if (is_k_full) { TORCH_CHECK(group_size != -1); group_blocks = group_size / 16; TORCH_CHECK(prob_k % group_blocks == 0, "prob_k = ", prob_k, " is not divisible by group_blocks = ", group_blocks); } else { TORCH_CHECK(group_size == 0); group_blocks = 0; } } else { if (group_size == -1) { group_blocks = -1; } else { group_blocks = group_size / 16; TORCH_CHECK(prob_k % group_blocks == 0, "prob_k = ", prob_k, " is not divisible by group_blocks = ", group_blocks); } } int num_bits = b_type.size_bits(); const int4* A_ptr = (const int4*)A; const int4* B_ptr = (const int4*)B; int4* C_ptr = (int4*)C; int4* C_tmp_ptr = (int4*)C_tmp; const int4* bias_ptr = (const int4*)b_bias; const float* a_s_ptr = (const float*)a_s; const int4* b_s_ptr = (const int4*)b_s; const uint16_t* g_s_ptr = (const uint16_t*)g_s; const int4* zp_ptr = (const int4*)zp; const int* g_idx_ptr = (const int*)g_idx; const int* perm_ptr = (const int*)perm; int4* a_tmp_ptr = (int4*)a_tmp; const int32_t* sorted_token_ids_ptr = (const int32_t*)sorted_token_ids; const int32_t* expert_ids_ptr = (const int32_t*)expert_ids; const int32_t* num_tokens_past_padded_ptr = (const int32_t*)num_tokens_past_padded; const float* topk_weights_ptr = (const float*)topk_weights; int* locks = (int*)workspace; if (has_act_order) { // Permute A columns auto kernel = permute_cols_kernel<8>; if (moe_block_size == 8) { } else if (moe_block_size == 16) kernel = permute_cols_kernel<16>; else if (moe_block_size == 32) kernel = permute_cols_kernel<32>; else if (moe_block_size == 48) kernel = permute_cols_kernel<48>; else if (moe_block_size == 64) kernel = permute_cols_kernel<64>; else TORCH_CHECK(false, "unsupported moe_block_size ", moe_block_size); // avoid ">>>" being formatted to "> > >" // clang-format off kernel<<>>( A_ptr, perm_ptr, a_tmp_ptr, sorted_token_ids_ptr, expert_ids_ptr, num_tokens_past_padded_ptr, prob_m, prob_k, top_k); // clang-format on A_ptr = a_tmp_ptr; prob_m = prob_m * top_k; top_k = 1; // If we have a full K, then we can run the non-act-order version of Marlin // (since the weight rows are reordered by increasing group ids, and by // having a full K, we have full original groups) if (is_k_full) has_act_order = false; } int max_shared_mem = 0; cudaDeviceGetAttribute(&max_shared_mem, cudaDevAttrMaxSharedMemoryPerBlockOptin, dev); TORCH_CHECK(max_shared_mem > 0); int major_capability, minor_capability; cudaDeviceGetAttribute(&major_capability, cudaDevAttrComputeCapabilityMajor, dev); cudaDeviceGetAttribute(&minor_capability, cudaDevAttrComputeCapabilityMinor, dev); TORCH_CHECK(major_capability * 10 + minor_capability >= 80, "marlin kernel only support Ampere or newer GPUs."); if (a_type == vllm::kFE4M3fn) { TORCH_CHECK(major_capability * 10 + minor_capability >= 89, "FP8 only support Ada Lovelace or newer GPUs."); TORCH_CHECK( major_capability * 10 + minor_capability == 89 || major_capability * 10 + minor_capability == 120, "Marlin W4A8-FP8 only support SM89 or SM120 device (It is slower than " "Marlin W4A16 on other devices)."); } // Set thread config exec_config_t exec_cfg; thread_config_t thread_tfg; if (thread_k != -1 && thread_n != -1) { thread_tfg = thread_config_t{thread_k, thread_n, thread_k * thread_n / 64}; if (blocks_per_sm == -1) blocks_per_sm = 1; exec_cfg = exec_config_t{blocks_per_sm, thread_tfg}; TORCH_CHECK(prob_n % thread_n == 0, "prob_n = ", prob_n, " is not divisible by thread_n = ", thread_n); TORCH_CHECK(prob_k % thread_k == 0, "prob_k = ", prob_k, " is not divisible by thread_k = ", thread_k); } else { // Auto config exec_cfg = determine_exec_config( a_type, b_type, c_type, s_type, prob_m, prob_n, prob_k, num_experts, top_k, thread_m_blocks, m_block_size_8, num_bits, group_size, has_act_order, is_k_full, has_zp, is_zp_float, max_shared_mem, sms, is_a_8bit); thread_tfg = exec_cfg.tb_cfg; } int num_threads = thread_tfg.num_threads; thread_k = thread_tfg.thread_k; thread_n = thread_tfg.thread_n; int blocks = sms * exec_cfg.blocks_per_sm; if (exec_cfg.blocks_per_sm > 1) max_shared_mem = max_shared_mem / exec_cfg.blocks_per_sm - 1024; int thread_k_blocks = thread_k / 16; int thread_n_blocks = thread_n / 16; TORCH_CHECK(is_valid_config(thread_tfg, m_block_size_8, thread_m_blocks, prob_m, prob_n, prob_k, num_bits, group_size, has_act_order, is_k_full, has_zp, is_zp_float, max_shared_mem, is_a_8bit), "Invalid thread config: thread_m_blocks = ", thread_m_blocks, ", thread_k = ", thread_tfg.thread_k, ", thread_n = ", thread_tfg.thread_n, ", num_threads = ", thread_tfg.num_threads, " for MKN = [", prob_m, ", ", prob_k, ", ", prob_n, "] and num_bits = ", num_bits, ", group_size = ", group_size, ", has_act_order = ", has_act_order, ", is_k_full = ", is_k_full, ", has_zp = ", has_zp, ", is_zp_float = ", is_zp_float, ", max_shared_mem = ", max_shared_mem); int sh_cache_size = get_kernel_cache_size(thread_tfg, m_block_size_8, thread_m_blocks, prob_m, prob_n, prob_k, num_bits, group_size, has_act_order, is_k_full, has_zp, is_zp_float, is_a_8bit); auto kernel = get_marlin_kernel( a_type, b_type, c_type, s_type, thread_m_blocks, thread_n_blocks, thread_k_blocks, m_block_size_8, has_act_order, has_zp, group_blocks, num_threads, is_zp_float); if (kernel == MarlinDefault) { TORCH_CHECK(false, "Unsupported shapes: MNK = [", prob_m, ", ", prob_n, ", ", prob_k, "]", ", has_act_order = ", has_act_order, ", num_groups = ", num_groups, ", group_size = ", group_size, ", thread_m_blocks = ", thread_m_blocks, ", thread_n_blocks = ", thread_n_blocks, ", thread_k_blocks = ", thread_k_blocks, ", num_bits = ", num_bits); } cudaFuncSetAttribute(kernel, cudaFuncAttributeMaxDynamicSharedMemorySize, max_shared_mem); // avoid ">>>" being formatted to "> > >" // clang-format off kernel<<>>( A_ptr, B_ptr, C_ptr, C_tmp_ptr, bias_ptr, a_s_ptr, b_s_ptr, g_s_ptr, zp_ptr, g_idx_ptr, sorted_token_ids_ptr, expert_ids_ptr, num_tokens_past_padded_ptr, topk_weights_ptr, top_k, mul_topk_weights, is_ep, num_groups, prob_m, prob_n, prob_k, locks, has_bias, use_atomic_add, use_fp32_reduce); // clang-format on } } // namespace MARLIN_NAMESPACE_NAME torch::Tensor moe_wna16_marlin_gemm( torch::Tensor& a, std::optional c_or_none, torch::Tensor& b_q_weight, std::optional const& b_bias_or_none, torch::Tensor& b_scales, std::optional const& a_scales_or_none, std::optional const& global_scale_or_none, std::optional const& b_zeros_or_none, std::optional const& g_idx_or_none, std::optional const& perm_or_none, torch::Tensor& workspace, torch::Tensor& sorted_token_ids, torch::Tensor& expert_ids, torch::Tensor& num_tokens_past_padded, torch::Tensor& topk_weights, int64_t moe_block_size, int64_t top_k, bool mul_topk_weights, bool is_ep, vllm::ScalarTypeId const& b_type_id, int64_t size_m, int64_t size_n, int64_t size_k, bool is_k_full, bool use_atomic_add, bool use_fp32_reduce, bool is_zp_float, int64_t thread_k, int64_t thread_n, int64_t blocks_per_sm) { vllm::ScalarTypeId a_type_id, c_type_id, s_type_id; auto c_dtype = a.dtype(); if (a.scalar_type() == at::ScalarType::Half) { a_type_id = vllm::kFloat16.id(); c_type_id = vllm::kFloat16.id(); } else if (a.scalar_type() == at::ScalarType::BFloat16) { a_type_id = vllm::kBFloat16.id(); c_type_id = vllm::kBFloat16.id(); } else { c_dtype = b_scales.dtype(); if (b_scales.scalar_type() == at::ScalarType::Half) { c_type_id = vllm::kFloat16.id(); } else if (b_scales.scalar_type() == at::ScalarType::BFloat16) { c_type_id = vllm::kBFloat16.id(); } else { c_type_id = vllm::kBFloat16.id(); TORCH_CHECK(c_or_none.has_value(), "c must be passed for W4A8-FP4"); torch::Tensor c = c_or_none.value(); c_dtype = c.dtype(); if (c.scalar_type() == at::ScalarType::Half) { c_type_id = vllm::kFloat16.id(); } else if (c.scalar_type() == at::ScalarType::BFloat16) { c_type_id = vllm::kBFloat16.id(); } else { TORCH_CHECK(false, "unsupported c dtype"); } } if (a.scalar_type() == at::ScalarType::Float8_e4m3fn) { a_type_id = vllm::kFE4M3fn.id(); } else if (a.scalar_type() == at::ScalarType::Char) { a_type_id = vllm::kS8.id(); } else { TORCH_CHECK(false, "unsupported `a` scalar_type"); } } s_type_id = c_type_id; if (b_type_id == vllm::kFE2M1f.id()) { if (b_scales.scalar_type() == at::ScalarType::Float8_e4m3fn) { s_type_id = vllm::kFE4M3fn.id(); } else if (b_scales.scalar_type() == at::ScalarType::Float8_e8m0fnu) { s_type_id = vllm::kFE8M0fnu.id(); } else { TORCH_CHECK(false, "When b_type = float4_e2m1f, b_scale scalar type must be", "float8_e4m3fn (for NVFP4) or float8_e8m0fnu (for MXFP4)."); } } vllm::ScalarType a_type = vllm::ScalarType::from_id(a_type_id); vllm::ScalarType b_type = vllm::ScalarType::from_id(b_type_id); vllm::ScalarType c_type = vllm::ScalarType::from_id(c_type_id); vllm::ScalarType s_type = vllm::ScalarType::from_id(s_type_id); int pack_factor = 32 / b_type.size_bits(); int num_experts = b_q_weight.size(0); if (moe_block_size != 8) { TORCH_CHECK(moe_block_size % 16 == 0, "unsupported moe_block_size=", moe_block_size); TORCH_CHECK(moe_block_size >= 16 && moe_block_size <= 64, "unsupported moe_block_size=", moe_block_size); } // Verify A TORCH_CHECK(a.size(0) == size_m, "Shape mismatch: a.size(0) = ", a.size(0), ", size_m = ", size_m); TORCH_CHECK(a.size(1) == size_k, "Shape mismatch: a.size(1) = ", a.size(1), ", size_k = ", size_k); // Verify B TORCH_CHECK( size_k % MARLIN_NAMESPACE_NAME::tile_size == 0, "size_k = ", size_k, " is not divisible by tile_size = ", MARLIN_NAMESPACE_NAME::tile_size); TORCH_CHECK((size_k / MARLIN_NAMESPACE_NAME::tile_size) == b_q_weight.size(1), "Shape mismatch: b_q_weight.size(1) = ", b_q_weight.size(1), ", size_k = ", size_k, ", tile_size = ", MARLIN_NAMESPACE_NAME::tile_size); TORCH_CHECK( b_q_weight.size(2) % MARLIN_NAMESPACE_NAME::tile_size == 0, "b_q_weight.size(2) = ", b_q_weight.size(2), " is not divisible by tile_size = ", MARLIN_NAMESPACE_NAME::tile_size); int actual_size_n = (b_q_weight.size(2) / MARLIN_NAMESPACE_NAME::tile_size) * pack_factor; TORCH_CHECK(size_n == actual_size_n, "size_n = ", size_n, ", actual_size_n = ", actual_size_n); // Verify device and strides TORCH_CHECK(a.device().is_cuda(), "A is not on GPU"); TORCH_CHECK(a.is_contiguous(), "A is not contiguous"); TORCH_CHECK(b_q_weight.device().is_cuda(), "b_q_weight is not on GPU"); TORCH_CHECK(b_q_weight.is_contiguous(), "b_q_weight is not contiguous"); TORCH_CHECK(b_scales.device().is_cuda(), "b_scales is not on GPU"); TORCH_CHECK(b_scales.is_contiguous(), "b_scales is not contiguous"); torch::Tensor a_scales; auto options = torch::TensorOptions().dtype(c_dtype).device(a.device()); auto options_fp32 = torch::TensorOptions().dtype(at::kFloat).device(a.device()); if (a_scales_or_none.has_value()) { a_scales = a_scales_or_none.value(); TORCH_CHECK(a_type.size_bits() == 8, "a_scales can only be used for 8bit activation."); } else { a_scales = torch::empty({0}, options_fp32); TORCH_CHECK(a_type.size_bits() != 8, "the a_scales parameter must be passed for 8bit activation."); } // sms: number of SMs to use for the kernel int sms = -1; cudaDeviceGetAttribute(&sms, cudaDevAttrMultiProcessorCount, a.get_device()); // Alloc buffers const at::cuda::OptionalCUDAGuard device_guard(device_of(a)); torch::Tensor c; if (c_or_none.has_value()) { c = c_or_none.value(); TORCH_CHECK(c.device().is_cuda(), "c is not on GPU"); TORCH_CHECK(c.is_contiguous(), "c is not contiguous"); TORCH_CHECK(c.size(0) == size_m * top_k, "Shape mismatch: c.size(0) = ", c.size(0), ", size_m * topk = ", size_m * top_k); TORCH_CHECK(c.size(1) == size_n, "Shape mismatch: c.size(1) = ", c.size(1), ", size_n = ", size_n); } else { c = torch::empty({size_m * top_k, size_n}, options); } // Alloc C tmp buffer that is going to be used for the global reduce torch::Tensor c_tmp; if (use_fp32_reduce && !use_atomic_add) { // max num of threadblocks is sms * 4 long max_c_tmp_size = min( (long)size_n * sorted_token_ids.size(0), (long)sms * 4 * moe_block_size * MARLIN_NAMESPACE_NAME::max_thread_n); if (moe_block_size == 8) max_c_tmp_size *= 2; c_tmp = torch::empty({max_c_tmp_size}, options_fp32); } else { c_tmp = torch::empty({0}, options_fp32); } // Detect groupsize and act_order int num_groups = -1; int group_size = -1; int rank = b_scales.sizes().size(); TORCH_CHECK(rank == 3, "b_scales rank = ", rank, " is not 3"); TORCH_CHECK(b_scales.size(2) == size_n, "b_scales dim 2 = ", b_scales.size(2), " is not size_n = ", size_n); num_groups = b_scales.size(1); torch::Tensor g_idx, perm, a_tmp; if (g_idx_or_none.has_value() && perm_or_none.has_value()) { g_idx = g_idx_or_none.value(); perm = perm_or_none.value(); TORCH_CHECK(g_idx.device().is_cuda(), "g_idx is not on GPU"); TORCH_CHECK(g_idx.is_contiguous(), "g_idx is not contiguous"); TORCH_CHECK(perm.device().is_cuda(), "perm is not on GPU"); TORCH_CHECK(perm.is_contiguous(), "perm is not contiguous"); // Verify g_idx and perm TORCH_CHECK((g_idx.size(-1) == 0 && perm.size(-1) == 0) || (g_idx.size(-1) == size_k && perm.size(-1) == size_k), "Unexpected g_idx.size(-1) = ", g_idx.size(-1), " and perm.size(-1) = ", perm.size(-1), ", where size_k = ", size_k); } else { g_idx = torch::empty({0}, options); perm = torch::empty({0}, options); a_tmp = torch::empty({0}, options); } bool has_act_order = g_idx.size(-1) > 0 && perm.size(-1) > 0; if (has_act_order) { a_tmp = torch::empty({size_m * top_k, size_k}, options); if (is_k_full) { TORCH_CHECK(num_groups > 1, "For act_order, num_groups must be > 1"); TORCH_CHECK(size_k % num_groups == 0, "size_k = ", size_k, ", is not divisible by num_groups = ", num_groups); group_size = size_k / num_groups; } else { group_size = 0; } } else { a_tmp = torch::empty({0}, options); if (num_groups > 1) { TORCH_CHECK( size_k % num_groups == 0, "size_k = ", size_k, ", is not divisible by b_scales.size(1) = ", b_scales.size(1)); group_size = size_k / num_groups; } else { group_size = -1; } } torch::Tensor global_scale; if (global_scale_or_none.has_value()) { global_scale = global_scale_or_none.value(); TORCH_CHECK(b_type == vllm::kFE2M1f && s_type == vllm::kFE4M3fn, "global_scale can only be used for nvfp4 format."); } else { global_scale = torch::empty({0}, options); TORCH_CHECK(!(b_type == vllm::kFE2M1f && s_type == vllm::kFE4M3fn), "the global_scale parameter must be passed for nvfp4 format."); } bool has_bias = b_bias_or_none.has_value(); torch::Tensor b_bias; if (has_bias) { b_bias = b_bias_or_none.value(); TORCH_CHECK(b_bias.device().is_cuda(), "b_bias is not on GPU"); TORCH_CHECK(b_bias.is_contiguous(), "b_bias is not contiguous"); TORCH_CHECK(b_bias.size(1) == size_n, "b_bias.size(0) != size_n"); TORCH_CHECK(b_bias.stride(1) == 1, "b_bias.stride(1) != 1"); } else { b_bias = torch::empty({0}, options); } torch::Tensor b_zeros; if (b_zeros_or_none.has_value()) { b_zeros = b_zeros_or_none.value(); TORCH_CHECK(b_zeros.device().is_cuda(), "b_zeros is not on GPU"); TORCH_CHECK(b_zeros.is_contiguous(), "b_zeros is not contiguous"); } else { b_zeros = torch::empty({0}, options); } bool has_zp = b_zeros.size(-1) > 0; if (has_zp) { TORCH_CHECK( b_type == vllm::kU4 || b_type == vllm::kU8, "b_type must be u4 or u8 when has_zp = True. Got = ", b_type.str()); } else { TORCH_CHECK(b_type == vllm::kU4B8 || b_type == vllm::kU8B128 || b_type == vllm::kS4 || b_type == vllm::kS8 || b_type == vllm::kFE4M3fn || b_type == vllm::kFE2M1f, "b_type must be uint4b8, uint8b128, int4, int8, " "float8_e4m3fn or float4_e2m1f when has_zp = False. Got = ", b_type.str()); } if (has_zp && is_zp_float) { TORCH_CHECK(a.scalar_type() == at::ScalarType::Half, "Computation type must be float16 (half) when using float zero " "points."); } // Verify b_zeros if (has_zp) { int rank = b_zeros.sizes().size(); TORCH_CHECK(rank == 3, "b_zeros rank = ", rank, " is not 3"); if (is_zp_float) { TORCH_CHECK(b_zeros.size(2) == size_n, "b_zeros dim 2 = ", b_zeros.size(2), " is not size_n = ", size_n); TORCH_CHECK(num_groups == b_zeros.size(1), "b_zeros dim 1 = ", b_zeros.size(1), " is not num_groups = ", num_groups); TORCH_CHECK(num_groups != -1, "num_groups must be != -1"); } else { TORCH_CHECK(b_zeros.size(1) == num_groups, "b_zeros dim 1 = ", b_zeros.size(1), " is not num_groups = ", num_groups); TORCH_CHECK(b_zeros.size(2) == size_n / pack_factor, "b_zeros dim 2 = ", b_zeros.size(2), " is not size_n / pack_factor = ", size_n / pack_factor); } } // Verify workspace size TORCH_CHECK(size_n % MARLIN_NAMESPACE_NAME::min_thread_n == 0, "size_n = ", size_n, ", is not divisible by min_thread_n = ", MARLIN_NAMESPACE_NAME::min_thread_n); int max_n_tiles = size_n / MARLIN_NAMESPACE_NAME::min_thread_n; int min_workspace_size = min( max_n_tiles * (int)(sorted_token_ids.size(0) / moe_block_size), sms * 4); TORCH_CHECK(workspace.numel() >= min_workspace_size, "workspace.numel = ", workspace.numel(), " is below min_workspace_size = ", min_workspace_size); int dev = a.get_device(); TORCH_CHECK(a_scales.scalar_type() == at::ScalarType::Float, "scalar type of a_scales must be float"); TORCH_CHECK(global_scale.scalar_type() == c.scalar_type(), "scalar type of global_scale must be the same with c"); if (a_type.size_bits() == 16) { TORCH_CHECK( a.scalar_type() == c.scalar_type(), "scalar type of a must be the same with c for 16 bit activation"); } MARLIN_NAMESPACE_NAME::marlin_mm( a.data_ptr(), b_q_weight.data_ptr(), c.data_ptr(), c_tmp.data_ptr(), b_bias.data_ptr(), a_scales.data_ptr(), b_scales.data_ptr(), global_scale.data_ptr(), b_zeros.data_ptr(), g_idx.data_ptr(), perm.data_ptr(), a_tmp.data_ptr(), sorted_token_ids.data_ptr(), expert_ids.data_ptr(), num_tokens_past_padded.data_ptr(), topk_weights.data_ptr(), moe_block_size, num_experts, top_k, mul_topk_weights, is_ep, size_m, size_n, size_k, workspace.data_ptr(), a_type, b_type, c_type, s_type, has_bias, has_act_order, is_k_full, has_zp, num_groups, group_size, dev, at::cuda::getCurrentCUDAStream(dev), thread_k, thread_n, sms, blocks_per_sm, use_atomic_add, use_fp32_reduce, is_zp_float); return c; } TORCH_LIBRARY_IMPL_EXPAND(TORCH_EXTENSION_NAME, CUDA, m) { m.impl("moe_wna16_marlin_gemm", &moe_wna16_marlin_gemm); }