Files
DeepGEMM/csrc/jit_kernels/impls/sm100_fp8_fp4_mega_moe.hpp
Zhean Xu 891d57b4db Add various optimizations and Mega MoE benchmarks (#316)
* Merge with private repo

* Add Mega MoE Benchmark

* Minor fix

* Update

---------

Co-authored-by: Chenggang Zhao <chenggangz@deepseek.com>
2026-04-24 18:41:37 +08:00

221 lines
9.9 KiB
C++

#pragma once
#include <torch/python.h>
#include "../../jit/compiler.hpp"
#include "../../jit/kernel_runtime.hpp"
#include "../../utils/exception.hpp"
#include "../../utils/format.hpp"
#include "runtime_utils.hpp"
#include <deep_gemm/layout/mega_moe.cuh>
#include <deep_gemm/layout/sym_buffer.cuh>
#include "../heuristics/mega_moe.hpp"
namespace deep_gemm {
class SM100FP8FP4MegaMoERuntime final : public LaunchRuntime<SM100FP8FP4MegaMoERuntime> {
public:
struct Args {
// Templated arguments
int num_max_tokens_per_rank;
int hidden, intermediate_hidden;
int num_experts, num_topk;
int num_ranks;
float activation_clamp;
bool fast_math;
MegaMoEConfig config;
// Runtime arguments
void* y;
int* cumulative_local_expert_recv_stats;
int num_tokens;
layout::SymBuffer<> sym_buffer_ptrs;
// Tensormap
CUtensorMap tensor_map_l1_acts;
CUtensorMap tensor_map_l1_acts_sf;
CUtensorMap tensor_map_l1_weights;
CUtensorMap tensor_map_l1_weights_sf;
CUtensorMap tensor_map_l1_output;
CUtensorMap tensor_map_l2_acts;
CUtensorMap tensor_map_l2_acts_sf;
CUtensorMap tensor_map_l2_weights;
CUtensorMap tensor_map_l2_weights_sf;
// Launch configs
LaunchArgs launch_args;
};
static std::string generate_impl(const Args& args) {
return fmt::format(R"(
#include <deep_gemm/impls/sm100_fp8_fp4_mega_moe.cuh>
using namespace deep_gemm;
static void __instantiate_kernel() {{
auto ptr = reinterpret_cast<void*>(&sm100_fp8_fp4_mega_moe_impl<
{},
{}, {},
{}, {},
{},
{}, {}, {},
{},
{}, {},
{},
{},
{},
{}, {}, {},
{}, {},
{},
{}
>);
}};
)", args.num_max_tokens_per_rank,
args.hidden, args.intermediate_hidden,
args.num_experts, args.num_topk,
args.config.num_experts_per_wave,
args.config.block_m, args.config.block_n, args.config.block_k,
args.config.store_block_m,
args.config.sf_block_m, args.config.sf_block_n,
args.config.num_max_pool_tokens,
args.config.num_padded_sf_pool_tokens,
args.config.num_stages,
args.config.num_dispatch_threads, args.config.num_non_epilogue_threads, args.config.num_epilogue_threads,
args.launch_args.grid_dim.first, args.num_ranks,
to_string(args.activation_clamp),
args.fast_math ? "true" : "false");
}
static void launch_impl(const KernelHandle& kernel, const LaunchConfigHandle& config, Args args) {
// TODO: optimize `args` copy
DG_CUDA_UNIFIED_CHECK(launch_kernel(kernel, config,
args.y,
args.cumulative_local_expert_recv_stats,
args.num_tokens,
args.sym_buffer_ptrs,
args.tensor_map_l1_acts,
args.tensor_map_l1_acts_sf,
args.tensor_map_l1_weights,
args.tensor_map_l1_weights_sf,
args.tensor_map_l1_output,
args.tensor_map_l2_acts,
args.tensor_map_l2_acts_sf,
args.tensor_map_l2_weights,
args.tensor_map_l2_weights_sf
));
}
};
static void sm100_fp8_fp4_mega_moe(
const torch::Tensor& y,
const torch::Tensor& l1_acts, const torch::Tensor& l1_acts_sf,
const torch::Tensor& l2_acts, const torch::Tensor& l2_acts_sf,
const torch::Tensor& l1_weights, const torch::Tensor& l2_weights,
const torch::Tensor& l1_weights_sf, const torch::Tensor& l2_weights_sf,
const std::optional<torch::Tensor> cumulative_local_expert_recv_stats,
const std::vector<int64_t>& sym_buffer_ptrs,
const int& rank_idx, const int& num_max_tokens_per_rank,
const int& num_experts_per_rank,
const int& num_tokens, const int& num_topk,
const int& hidden, const int& intermediate_hidden,
const float& activation_clamp,
const bool& fast_math
) {
const auto num_ranks = static_cast<int>(sym_buffer_ptrs.size());
const auto num_experts = num_experts_per_rank * num_ranks;
const auto num_padded_sf_pool_tokens = static_cast<int>(l1_acts_sf.size(0));
// Heuristics
const auto config = get_mega_moe_config(
num_ranks, num_experts, num_experts_per_rank,
num_max_tokens_per_rank, num_tokens, num_topk, hidden, intermediate_hidden, num_padded_sf_pool_tokens);
// Make tensormap
constexpr int kGranK = 32;
const auto tensor_map_l1_acts = make_tma_2d_desc(l1_acts,
hidden, config.num_max_pool_tokens,
config.block_k, config.load_block_m,
static_cast<int>(l1_acts.stride(-2)),
config.swizzle_acts_mode);
const auto tensor_map_l1_acts_sf = make_tma_sf_desc(cute::UMMA::Major::MN, l1_acts_sf,
config.num_padded_sf_pool_tokens, hidden,
config.sf_block_m, kGranK,
1, 0);
const auto tensor_map_l1_weights = make_tma_2d_desc(l1_weights,
hidden, num_experts_per_rank * intermediate_hidden * 2,
config.block_k, config.load_block_n,
static_cast<int>(l1_weights.stride(-2)),
config.swizzle_weights_mode);
const auto tensor_map_l1_weights_sf = make_tma_sf_desc(cute::UMMA::Major::MN, l1_weights_sf,
intermediate_hidden * 2, hidden,
config.block_n, kGranK,
num_experts_per_rank, 0);
// NOTES: L1 output and L2 activations are essentially the same tensor.
// Post-SwiGLU output has half the N width (`BLOCK_N / 2` per input tile),
// so the swizzle mode is also halved (128 -> 64).
const auto tensor_map_l1_output = make_tma_2d_desc(l2_acts,
intermediate_hidden, config.num_max_pool_tokens,
config.block_n / 2, config.store_block_m,
static_cast<int>(l2_acts.stride(-2)),
config.swizzle_acts_mode / 2);
const auto tensor_map_l2_acts = make_tma_2d_desc(l2_acts,
intermediate_hidden, config.num_max_pool_tokens,
config.block_k, config.load_block_m,
static_cast<int>(l2_acts.stride(-2)),
config.swizzle_acts_mode);
const auto tensor_map_l2_acts_sf = make_tma_sf_desc(cute::UMMA::Major::MN, l2_acts_sf,
config.num_padded_sf_pool_tokens, intermediate_hidden,
config.sf_block_m, kGranK,
1, 0);
const auto tensor_map_l2_weights = make_tma_2d_desc(l2_weights,
intermediate_hidden, num_experts_per_rank * hidden,
config.block_k, config.load_block_n,
static_cast<int>(l2_weights.stride(-2)),
config.swizzle_weights_mode);
const auto tensor_map_l2_weights_sf = make_tma_sf_desc(cute::UMMA::Major::MN, l2_weights_sf,
hidden, intermediate_hidden,
config.block_n, kGranK,
num_experts_per_rank, 0);
// Stats can be optional
int* cumulative_local_expert_recv_stats_ptr = nullptr;
if (cumulative_local_expert_recv_stats.has_value())
cumulative_local_expert_recv_stats_ptr = cumulative_local_expert_recv_stats->data_ptr<int>();
// Launch
const auto num_sms = device_runtime->get_num_sms();
const SM100FP8FP4MegaMoERuntime::Args args = {
.num_max_tokens_per_rank = num_max_tokens_per_rank,
.hidden = hidden, .intermediate_hidden = intermediate_hidden,
.num_experts = num_experts, .num_topk = num_topk,
.num_ranks = num_ranks,
.activation_clamp = activation_clamp,
.fast_math = fast_math,
.config = config,
.y = y.data_ptr(),
.cumulative_local_expert_recv_stats = cumulative_local_expert_recv_stats_ptr,
.num_tokens = num_tokens,
.sym_buffer_ptrs = layout::SymBuffer<>(sym_buffer_ptrs, rank_idx),
.tensor_map_l1_acts = tensor_map_l1_acts,
.tensor_map_l1_acts_sf = tensor_map_l1_acts_sf,
.tensor_map_l1_weights = tensor_map_l1_weights,
.tensor_map_l1_weights_sf = tensor_map_l1_weights_sf,
.tensor_map_l1_output = tensor_map_l1_output,
.tensor_map_l2_acts = tensor_map_l2_acts,
.tensor_map_l2_acts_sf = tensor_map_l2_acts_sf,
.tensor_map_l2_weights = tensor_map_l2_weights,
.tensor_map_l2_weights_sf = tensor_map_l2_weights_sf,
.launch_args = LaunchArgs(num_sms,
config.num_dispatch_threads + config.num_non_epilogue_threads + config.num_epilogue_threads,
config.smem_size, 2)
};
const auto code = SM100FP8FP4MegaMoERuntime::generate(args);
const auto runtime = compiler->build("sm100_fp8_fp4_mega_moe", code);
SM100FP8FP4MegaMoERuntime::launch(runtime, args);
}
} // namespace deep_gemm