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vllm/csrc/moe/grouped_topk_kernels.cu
Michael Goin 0852527647
[Perf][DeepSeek] Add sigmoid+bias fusion to fused_grouped_topk from TRTLLM (#28124) 
Signed-off-by: mgoin <mgoin64@gmail.com>
Co-authored-by: Robert Shaw <114415538+robertgshaw2-redhat@users.noreply.github.com>
Co-authored-by: Wentao Ye <44945378+yewentao256@users.noreply.github.com>
2025-11-07 18:20:55 -08:00

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/*
* Adapted from
* https://github.com/NVIDIA/TensorRT-LLM/blob/v0.21.0/cpp/tensorrt_llm/kernels/noAuxTcKernels.cu
* Copyright (c) 2025, The vLLM team.
* SPDX-FileCopyrightText: Copyright (c) 1993-2024 NVIDIA CORPORATION &
* AFFILIATES. All rights reserved. SPDX-License-Identifier: Apache-2.0
*
* 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.
*/
#include <c10/cuda/CUDAStream.h>
#include <torch/all.h>
#include <cuda_fp16.h>
#include <cuda_bf16.h>
#include <cuda/std/limits>
#include <cooperative_groups.h>
#include <cooperative_groups/reduce.h>
namespace cg = cooperative_groups;
namespace vllm {
namespace moe {
constexpr unsigned FULL_WARP_MASK = 0xffffffff;
constexpr int32_t WARP_SIZE = 32;
constexpr int32_t BLOCK_SIZE = 512;
constexpr int32_t NUM_WARPS_PER_BLOCK = BLOCK_SIZE / WARP_SIZE;
namespace warp_topk {
template <int size, typename T>
__host__ __device__ constexpr T round_up_to_multiple_of(T len) {
if (len == 0) {
return 0;
}
return ((len - 1) / size + 1) * size;
}
template <typename T>
constexpr __host__ __device__ bool isPowerOf2(T v) {
return (v && !(v & (v - 1)));
}
template <bool greater, typename T>
__forceinline__ __device__ bool is_better_than(T val, T baseline) {
return (val > baseline && greater) || (val < baseline && !greater);
}
template <bool greater, typename T, typename idxT>
__forceinline__ __device__ bool is_better_than(T val, T baseline, idxT index,
idxT baseline_index) {
bool res = (val > baseline && greater) || (val < baseline && !greater);
if (val == baseline) {
res = (index < baseline_index && greater) ||
(index < baseline_index && !greater);
}
return res;
}
template <typename T, typename idxT>
int calc_smem_size_for_block_wide(int num_of_warp, int64_t k) {
int64_t cache_topk = (sizeof(T) + sizeof(idxT)) * num_of_warp * k;
int64_t n = std::max<int>(num_of_warp / 2 * k, num_of_warp * WARP_SIZE);
return max(cache_topk,
round_up_to_multiple_of<256>(n * sizeof(T)) + n * sizeof(idxT));
}
template <int size, bool ascending, bool reverse, typename T, typename idxT,
bool is_stable>
struct BitonicMerge {
// input should be a bitonic sequence, and sort it to be a monotonic sequence
__device__ static void merge(T* __restrict__ val_arr,
idxT* __restrict__ idx_arr) {
static_assert(isPowerOf2(size));
static_assert(size >= 2 * WARP_SIZE);
constexpr int arr_len = size / WARP_SIZE;
constexpr int stride = arr_len / 2;
for (int i = 0; i < stride; ++i) {
int const other_i = i + stride;
T& val = val_arr[i];
T& other_val = val_arr[other_i];
bool is_better;
if constexpr (is_stable) {
is_better = is_better_than<ascending>(val, other_val, idx_arr[i],
idx_arr[other_i]);
} else {
is_better = is_better_than<ascending>(val, other_val);
}
if (is_better) {
T tmp = val;
val = other_val;
other_val = tmp;
idxT tmp2 = idx_arr[i];
idx_arr[i] = idx_arr[other_i];
idx_arr[other_i] = tmp2;
}
}
BitonicMerge<size / 2, ascending, reverse, T, idxT, is_stable>::merge(
val_arr, idx_arr);
BitonicMerge<size / 2, ascending, reverse, T, idxT, is_stable>::merge(
val_arr + arr_len / 2, idx_arr + arr_len / 2);
}
};
template <int size, bool ascending, typename T, typename idxT, bool is_stable>
struct BitonicSort {
__device__ static void sort(T* __restrict__ val_arr,
idxT* __restrict__ idx_arr) {
static_assert(isPowerOf2(size));
static_assert(size >= 2 * WARP_SIZE);
constexpr int arr_len = size / WARP_SIZE;
BitonicSort<size / 2, true, T, idxT, is_stable>::sort(val_arr, idx_arr);
BitonicSort<size / 2, false, T, idxT, is_stable>::sort(
val_arr + arr_len / 2, idx_arr + arr_len / 2);
BitonicMerge<size, ascending, ascending, T, idxT, is_stable>::merge(
val_arr, idx_arr);
}
};
template <bool ascending, typename T, typename idxT, bool is_stable>
struct BitonicSort<32, ascending, T, idxT, is_stable> {
__device__ static void sort(T* __restrict__ val_arr,
idxT* __restrict__ idx_arr) {
int const lane = threadIdx.x % WARP_SIZE;
// ascending doesn't matter before merging since all we need is a bitonic
// sequence
for (int stage = 0; stage < 4; ++stage) {
for (int stride = (1 << stage); stride > 0; stride /= 2) {
bool reverse = (lane >> stage) & 2;
bool is_second = lane & stride;
T other = __shfl_xor_sync(FULL_WARP_MASK, *val_arr, stride);
idxT other_idx = __shfl_xor_sync(FULL_WARP_MASK, *idx_arr, stride);
bool is_better;
if constexpr (is_stable) {
if constexpr (ascending) {
is_better = ((*val_arr > other) ||
((*val_arr == other) && (*idx_arr < other_idx))) !=
(reverse != is_second);
} else {
is_better = ((*val_arr > other) ||
((*val_arr == other) && (*idx_arr > other_idx))) !=
(reverse != is_second);
}
} else {
is_better = (*val_arr != other &&
(*val_arr > other) != (reverse != is_second));
}
if (is_better) {
*val_arr = other;
*idx_arr = other_idx;
}
}
}
BitonicMerge<32, ascending, ascending, T, idxT, is_stable>::merge(val_arr,
idx_arr);
}
};
template <bool ascending, bool reverse, typename T, typename idxT,
bool is_stable>
struct BitonicMerge<32, ascending, reverse, T, idxT, is_stable> {
__device__ static void merge(T* __restrict__ val_arr,
idxT* __restrict__ idx_arr) {
int const lane = threadIdx.x % WARP_SIZE;
for (int stride = WARP_SIZE / 2; stride > 0; stride /= 2) {
bool is_second = lane & stride;
T& val = *val_arr;
T other = __shfl_xor_sync(FULL_WARP_MASK, val, stride);
idxT& idx = *idx_arr;
idxT other_idx = __shfl_xor_sync(FULL_WARP_MASK, idx, stride);
bool is_better;
if constexpr (is_stable) {
if constexpr (ascending) {
is_better = ((*val_arr > other) ||
((*val_arr == other) && (*idx_arr < other_idx))) ==
(reverse != is_second); // for min
} else {
is_better = ((*val_arr > other) ||
((*val_arr == other) && (*idx_arr > other_idx))) ==
(reverse != is_second); // for max
}
} else {
is_better =
(val != other && ((val > other) == (ascending != is_second)));
}
if (is_better) {
val = other;
idx = other_idx;
}
}
}
};
template <int capacity, bool greater, typename T, typename idxT, bool is_stable>
class WarpSort {
public:
__device__ WarpSort(idxT k, T dummy)
: lane_(threadIdx.x % WARP_SIZE), k_(k), dummy_(dummy) {
static_assert(capacity >= WARP_SIZE && isPowerOf2(capacity));
for (int i = 0; i < max_arr_len_; ++i) {
val_arr_[i] = dummy_;
idx_arr_[i] = 0;
}
}
// load and merge k sorted values
__device__ void load_sorted(T const* __restrict__ in,
idxT const* __restrict__ in_idx, idxT start) {
idxT idx = start + WARP_SIZE - 1 - lane_;
for (int i = max_arr_len_ - 1; i >= 0; --i, idx += WARP_SIZE) {
if (idx < start + k_) {
T t = in[idx];
bool is_better;
if constexpr (is_stable) {
is_better =
is_better_than<greater>(t, val_arr_[i], in_idx[idx], idx_arr_[i]);
} else {
is_better = is_better_than<greater>(t, val_arr_[i]);
}
if (is_better) {
val_arr_[i] = t;
idx_arr_[i] = in_idx[idx];
}
}
}
BitonicMerge<capacity, greater, !greater, T, idxT, is_stable>::merge(
val_arr_, idx_arr_);
}
__device__ void dump(T* __restrict__ out, idxT* __restrict__ out_idx) const {
for (int i = 0; i < max_arr_len_; ++i) {
idxT out_i = i * WARP_SIZE + lane_;
if (out_i < k_) {
out[out_i] = val_arr_[i];
out_idx[out_i] = idx_arr_[i];
}
}
}
__device__ void dumpIdx(idxT* __restrict__ out_idx) const {
for (int i = 0; i < max_arr_len_; ++i) {
idxT out_i = i * WARP_SIZE + lane_;
if (out_i < k_) {
out_idx[out_i] = idx_arr_[i];
}
}
}
protected:
static constexpr int max_arr_len_ = capacity / WARP_SIZE;
T val_arr_[max_arr_len_];
idxT idx_arr_[max_arr_len_];
int const lane_;
idxT const k_;
T const dummy_;
}; // end class WarpSort
template <int capacity, bool greater, typename T, typename idxT, bool is_stable>
class WarpSelect : public WarpSort<capacity, greater, T, idxT, is_stable> {
public:
__device__ WarpSelect(idxT k, T dummy)
: WarpSort<capacity, greater, T, idxT, is_stable>(k, dummy),
k_th_(dummy),
k_th_lane_((k - 1) % WARP_SIZE) {
extern __shared__ char smem_buf[]; // extern __shared__ T smem_buf[];
int const num_of_warp = blockDim.x / WARP_SIZE;
int const warp_id = threadIdx.x / WARP_SIZE;
val_smem_ = reinterpret_cast<T*>(smem_buf);
val_smem_ += warp_id * WARP_SIZE;
idx_smem_ = reinterpret_cast<idxT*>(
smem_buf +
round_up_to_multiple_of<256>(num_of_warp * sizeof(T) * WARP_SIZE));
idx_smem_ += warp_id * WARP_SIZE;
}
__device__ void add(T const* in, idxT start, idxT end) {
idxT const end_for_fullwarp =
round_up_to_multiple_of<WARP_SIZE>(end - start) + start;
for (idxT i = start + lane_; i < end_for_fullwarp; i += WARP_SIZE) {
T val = (i < end) ? in[i] : dummy_;
add(val, i);
}
}
__device__ void add(T val, idxT idx) {
bool do_add;
if constexpr (is_stable) {
do_add = is_better_than<greater>(val, k_th_, idx, k_th_idx_);
} else {
do_add = is_better_than<greater>(val, k_th_);
}
uint32_t mask = __ballot_sync(FULL_WARP_MASK, do_add);
if (mask == 0) {
return;
}
int pos = smem_buf_len_ + __popc(mask & ((0x1u << lane_) - 1));
if (do_add && pos < WARP_SIZE) {
val_smem_[pos] = val;
idx_smem_[pos] = idx;
do_add = false;
}
smem_buf_len_ += __popc(mask);
if (smem_buf_len_ >= WARP_SIZE) {
__syncwarp();
merge_buf_(val_smem_[lane_], idx_smem_[lane_]);
smem_buf_len_ -= WARP_SIZE;
}
if (do_add) {
pos -= WARP_SIZE;
val_smem_[pos] = val;
idx_smem_[pos] = idx;
}
__syncwarp();
}
__device__ void done() {
if (smem_buf_len_) {
T val = (lane_ < smem_buf_len_) ? val_smem_[lane_] : dummy_;
idxT idx = (lane_ < smem_buf_len_) ? idx_smem_[lane_] : 0;
merge_buf_(val, idx);
}
// after done(), smem is used for merging results among warps
__syncthreads();
}
private:
__device__ void set_k_th_() {
k_th_ = __shfl_sync(FULL_WARP_MASK, val_arr_[max_arr_len_ - 1], k_th_lane_);
if constexpr (is_stable) {
k_th_idx_ =
__shfl_sync(FULL_WARP_MASK, idx_arr_[max_arr_len_ - 1], k_th_lane_);
}
}
__device__ void merge_buf_(T val, idxT idx) {
BitonicSort<WARP_SIZE, greater, T, idxT, is_stable>::sort(&val, &idx);
T& old = val_arr_[max_arr_len_ - 1];
bool is_better;
if constexpr (is_stable) {
is_better =
is_better_than<greater>(val, old, idx, idx_arr_[max_arr_len_ - 1]);
} else {
is_better = is_better_than<greater>(val, old);
}
if (is_better) {
old = val;
idx_arr_[max_arr_len_ - 1] = idx;
}
BitonicMerge<capacity, greater, !greater, T, idxT, is_stable>::merge(
val_arr_, idx_arr_);
set_k_th_();
}
using WarpSort<capacity, greater, T, idxT, is_stable>::max_arr_len_;
using WarpSort<capacity, greater, T, idxT, is_stable>::val_arr_;
using WarpSort<capacity, greater, T, idxT, is_stable>::idx_arr_;
using WarpSort<capacity, greater, T, idxT, is_stable>::lane_;
using WarpSort<capacity, greater, T, idxT, is_stable>::k_;
using WarpSort<capacity, greater, T, idxT, is_stable>::dummy_;
T* val_smem_;
idxT* idx_smem_;
int smem_buf_len_ = 0;
T k_th_;
idxT k_th_idx_;
int const k_th_lane_;
}; // end class WarpSelect
} // namespace warp_topk
template <typename T_OUT, typename T_IN>
__device__ inline T_OUT cuda_cast(T_IN val) {
return val;
}
template <>
__device__ inline float cuda_cast<float, __nv_bfloat16>(__nv_bfloat16 val) {
return __bfloat162float(val);
}
template <typename T>
__device__ inline T neg_inf() {
// cuda::std::numeric_limits<T>::infinity() returns `0` for [T=bf16 or fp16]
// so we need to cast from fp32
return cuda_cast<T, float>(-cuda::std::numeric_limits<float>::infinity());
}
template <typename T>
__device__ inline bool is_finite(const T val) {
#if (__CUDACC_VER_MAJOR__ * 10000 + __CUDACC_VER_MINOR__ * 100 >= 120800)
return cuda::std::isfinite(val);
#else
return isfinite(cuda_cast<float, T>(val));
#endif
}
// Scoring function enums
enum ScoringFunc {
SCORING_NONE = 0, // no activation function
SCORING_SIGMOID = 1 // apply sigmoid
};
// Efficient sigmoid approximation from TensorRT-LLM
__device__ inline float sigmoid_accurate(float x) {
return 0.5f * tanhf(0.5f * x) + 0.5f;
}
template <typename T>
__device__ inline T apply_sigmoid(T val) {
float f = cuda_cast<float, T>(val);
return cuda_cast<T, float>(sigmoid_accurate(f));
}
template <typename T>
__device__ void topk_with_k2(T* output, T const* input, T const* bias,
cg::thread_block_tile<32> const& tile,
int32_t const lane_id,
int const num_experts_per_group,
int const scoring_func) {
// Get the top2 per thread
T largest = neg_inf<T>();
T second_largest = neg_inf<T>();
if (num_experts_per_group > WARP_SIZE) {
for (int i = lane_id; i < num_experts_per_group; i += WARP_SIZE) {
T value = input[i];
// Apply scoring function if needed
if (scoring_func == SCORING_SIGMOID) {
value = apply_sigmoid(value);
}
value = value + bias[i];
if (value > largest) {
second_largest = largest;
largest = value;
} else if (value > second_largest) {
second_largest = value;
}
}
} else {
for (int i = lane_id; i < num_experts_per_group; i += WARP_SIZE) {
T value = input[i];
// Apply scoring function if needed
if (scoring_func == SCORING_SIGMOID) {
value = apply_sigmoid(value);
}
value = value + bias[i];
largest = value;
}
}
__syncwarp(); // Ensure all threads have valid data before reduction
// Get the top2 warpwise
T max1 = cg::reduce(tile, largest, cg::greater<T>());
T max2 = max1;
bool equal_to_max1 = (max1 == largest);
int count_max1 = __popc(__ballot_sync(FULL_WARP_MASK, equal_to_max1));
if (count_max1 == 1) {
largest = (largest == max1) ? second_largest : largest;
max2 = cg::reduce(tile, largest, cg::greater<T>());
}
if (lane_id == 0) {
*output = max1 + max2;
}
}
template <typename T>
__global__ void topk_with_k2_kernel(T* output, T* input, T const* bias,
int64_t const num_tokens,
int64_t const num_cases,
int64_t const n_group,
int64_t const num_experts_per_group,
int const scoring_func) {
int32_t warp_id = threadIdx.x / WARP_SIZE;
int32_t lane_id = threadIdx.x % WARP_SIZE;
int32_t case_id = blockIdx.x * NUM_WARPS_PER_BLOCK + warp_id;
if (case_id < num_cases) {
input += case_id * num_experts_per_group;
// bias is per expert group, offset to current group
int32_t group_id = case_id % n_group;
T const* group_bias = bias + group_id * num_experts_per_group;
output += case_id;
cg::thread_block block = cg::this_thread_block();
cg::thread_block_tile<32> tile = cg::tiled_partition<32>(block);
#if (defined(__CUDA_ARCH__) && (__CUDA_ARCH__ >= 900))
asm volatile("griddepcontrol.wait;");
#endif
topk_with_k2(output, input, group_bias, tile, lane_id,
num_experts_per_group, scoring_func);
}
#if (defined(__CUDA_ARCH__) && (__CUDA_ARCH__ >= 900))
asm volatile("griddepcontrol.launch_dependents;");
#endif
}
template <typename T, typename IdxT>
__global__ void group_idx_and_topk_idx_kernel(
T* scores, T const* group_scores, float* topk_values, IdxT* topk_indices,
T const* bias, int64_t const num_tokens, int64_t const n_group,
int64_t const topk_group, int64_t const topk, int64_t const num_experts,
int64_t const num_experts_per_group, bool renormalize,
double routed_scaling_factor, int scoring_func) {
int32_t warp_id = threadIdx.x / WARP_SIZE;
int32_t lane_id = threadIdx.x % WARP_SIZE;
int32_t case_id =
blockIdx.x * NUM_WARPS_PER_BLOCK + warp_id; // one per token
scores += case_id * num_experts;
group_scores += case_id * n_group;
topk_values += case_id * topk;
topk_indices += case_id * topk;
int32_t align_num_experts_per_group =
warp_topk::round_up_to_multiple_of<WARP_SIZE>(num_experts_per_group);
cg::thread_block block = cg::this_thread_block();
cg::thread_block_tile<32> tile = cg::tiled_partition<32>(block);
extern __shared__ char smem_buf[]; // NOTE: reuse the shared memory here to
// store the target topk idx
int32_t* s_topk_idx = reinterpret_cast<int32_t*>(smem_buf);
T* s_topk_value =
reinterpret_cast<T*>(s_topk_idx + NUM_WARPS_PER_BLOCK * topk) +
warp_id * topk;
s_topk_idx += warp_id * topk;
T value = neg_inf<T>();
T topk_group_value = neg_inf<T>();
int32_t num_equalto_topkth_group;
#if (defined(__CUDA_ARCH__) && (__CUDA_ARCH__ >= 900))
asm volatile("griddepcontrol.wait;"); // I think all prolog can be put before
// acqbulk because it's ptr arithmetic
#endif
if (case_id < num_tokens) {
// calculate group_idx
int32_t target_num_min = WARP_SIZE - n_group + topk_group;
// The check is necessary to avoid abnormal input
if (lane_id < n_group && is_finite(group_scores[lane_id])) {
value = group_scores[lane_id];
}
int count_equal_to_top_value = WARP_SIZE - n_group;
int pre_count_equal_to_top_value = 0;
// Use loop to find the largset top_group
while (count_equal_to_top_value < target_num_min) {
__syncwarp(); // Ensure all threads have valid data before reduction
topk_group_value = cg::reduce(tile, value, cg::greater<T>());
if (value == topk_group_value) {
value = neg_inf<T>();
}
pre_count_equal_to_top_value = count_equal_to_top_value;
count_equal_to_top_value =
__popc(__ballot_sync(FULL_WARP_MASK, (value == neg_inf<T>())));
}
num_equalto_topkth_group = target_num_min - pre_count_equal_to_top_value;
}
__syncthreads();
warp_topk::WarpSelect</*capability*/ WARP_SIZE, /*greater*/ true, T, int32_t,
/* is_stable */ true>
queue((int32_t)topk, neg_inf<T>());
int count_equalto_topkth_group = 0;
bool if_proceed_next_topk = topk_group_value != neg_inf<T>();
if (case_id < num_tokens && if_proceed_next_topk) {
for (int i_group = 0; i_group < n_group; i_group++) {
if ((group_scores[i_group] > topk_group_value) ||
((group_scores[i_group] == topk_group_value) &&
(count_equalto_topkth_group < num_equalto_topkth_group))) {
int32_t offset = i_group * num_experts_per_group;
for (int32_t i = lane_id; i < align_num_experts_per_group;
i += WARP_SIZE) {
T candidates = neg_inf<T>();
if (i < num_experts_per_group) {
// Apply scoring function (if any) and add bias
T input = scores[offset + i];
if (is_finite(input)) {
T score = (scoring_func == SCORING_SIGMOID) ? apply_sigmoid(input)
: input;
candidates = score + bias[offset + i];
}
}
queue.add(candidates, offset + i);
}
if (group_scores[i_group] == topk_group_value) {
count_equalto_topkth_group++;
}
}
}
queue.done();
__syncwarp();
// Get the topk_idx
queue.dumpIdx(s_topk_idx);
__syncwarp();
}
// Load the valid score value
// Calculate the summation
float topk_sum = 1e-20;
if (case_id < num_tokens && if_proceed_next_topk) {
for (int i = lane_id;
i < warp_topk::round_up_to_multiple_of<WARP_SIZE>(topk);
i += WARP_SIZE) {
T value = cuda_cast<T, float>(0.0f);
if (i < topk) {
// Load the score value (without bias) for normalization
T input = scores[s_topk_idx[i]];
value =
(scoring_func == SCORING_SIGMOID) ? apply_sigmoid(input) : input;
s_topk_value[i] = value;
}
topk_sum +=
cg::reduce(tile, cuda_cast<float, T>(value), cg::plus<float>());
}
}
__syncthreads();
if (case_id < num_tokens) {
if (if_proceed_next_topk) {
for (int i = lane_id; i < topk; i += WARP_SIZE) {
float value;
if (renormalize) {
value = cuda_cast<float, T>(s_topk_value[i]) / topk_sum *
routed_scaling_factor;
} else {
value = cuda_cast<float, T>(s_topk_value[i]) * routed_scaling_factor;
}
topk_indices[i] = s_topk_idx[i];
topk_values[i] = value;
}
} else {
for (int i = lane_id; i < topk; i += WARP_SIZE) {
topk_indices[i] = i;
topk_values[i] = 1.0f / topk;
}
}
// Note: when if_proceed_next_topk==false, choose the first 8 experts as the
// default result.
}
#if (defined(__CUDA_ARCH__) && (__CUDA_ARCH__ >= 900))
asm volatile("griddepcontrol.launch_dependents;");
#endif
}
template <typename T, typename IdxT>
void invokeNoAuxTc(T* scores, T* group_scores, float* topk_values,
IdxT* topk_indices, T const* bias, int64_t const num_tokens,
int64_t const num_experts, int64_t const n_group,
int64_t const topk_group, int64_t const topk,
bool const renormalize, double const routed_scaling_factor,
int const scoring_func, bool enable_pdl = false,
cudaStream_t const stream = 0) {
int64_t num_cases = num_tokens * n_group;
int64_t topk_with_k2_num_blocks = (num_cases - 1) / NUM_WARPS_PER_BLOCK + 1;
auto* kernel_instance1 = &topk_with_k2_kernel<T>;
cudaLaunchConfig_t config;
config.gridDim = topk_with_k2_num_blocks;
config.blockDim = BLOCK_SIZE;
config.dynamicSmemBytes = 0;
config.stream = stream;
cudaLaunchAttribute attrs[1];
attrs[0].id = cudaLaunchAttributeProgrammaticStreamSerialization;
attrs[0].val.programmaticStreamSerializationAllowed = enable_pdl;
config.numAttrs = 1;
config.attrs = attrs;
cudaLaunchKernelEx(&config, kernel_instance1, group_scores, scores, bias,
num_tokens, num_cases, n_group, num_experts / n_group,
scoring_func);
int64_t topk_with_k_group_num_blocks =
(num_tokens - 1) / NUM_WARPS_PER_BLOCK + 1;
size_t dynamic_smem_in_bytes =
warp_topk::calc_smem_size_for_block_wide<T, int32_t>(NUM_WARPS_PER_BLOCK,
topk);
auto* kernel_instance2 = &group_idx_and_topk_idx_kernel<T, IdxT>;
config.gridDim = topk_with_k_group_num_blocks;
config.blockDim = BLOCK_SIZE;
config.dynamicSmemBytes = dynamic_smem_in_bytes;
config.stream = stream;
attrs[0].id = cudaLaunchAttributeProgrammaticStreamSerialization;
attrs[0].val.programmaticStreamSerializationAllowed = enable_pdl;
config.numAttrs = 1;
config.attrs = attrs;
cudaLaunchKernelEx(&config, kernel_instance2, scores, group_scores,
topk_values, topk_indices, bias, num_tokens, n_group,
topk_group, topk, num_experts, num_experts / n_group,
renormalize, routed_scaling_factor, scoring_func);
}
#define INSTANTIATE_NOAUX_TC(T, IdxT) \
template void invokeNoAuxTc<T, IdxT>( \
T * scores, T * group_scores, float* topk_values, IdxT* topk_indices, \
T const* bias, int64_t const num_tokens, int64_t const num_experts, \
int64_t const n_group, int64_t const topk_group, int64_t const topk, \
bool const renormalize, double const routed_scaling_factor, \
int const scoring_func, bool enable_pdl, cudaStream_t const stream);
INSTANTIATE_NOAUX_TC(float, int32_t);
INSTANTIATE_NOAUX_TC(half, int32_t);
INSTANTIATE_NOAUX_TC(__nv_bfloat16, int32_t);
} // end namespace moe
} // namespace vllm
std::tuple<torch::Tensor, torch::Tensor> grouped_topk(
torch::Tensor const& scores, int64_t n_group, int64_t topk_group,
int64_t topk, bool renormalize, double routed_scaling_factor,
torch::Tensor const& bias, int64_t scoring_func = 0) {
auto data_type = scores.scalar_type();
auto input_size = scores.sizes();
int64_t num_tokens = input_size[0];
int64_t num_experts = input_size[1];
TORCH_CHECK(input_size.size() == 2, "scores must be a 2D Tensor");
TORCH_CHECK(num_experts % n_group == 0,
"num_experts should be divisible by n_group");
TORCH_CHECK(n_group <= 32,
"n_group should be smaller than or equal to 32 for now");
TORCH_CHECK(topk <= 32, "topk should be smaller than or equal to 32 for now");
TORCH_CHECK(scoring_func == vllm::moe::SCORING_NONE ||
scoring_func == vllm::moe::SCORING_SIGMOID,
"scoring_func must be SCORING_NONE (0) or SCORING_SIGMOID (1)");
torch::Tensor group_scores = torch::empty(
{num_tokens, n_group}, torch::dtype(data_type).device(torch::kCUDA));
// Always output float32 for topk_values (eliminates Python-side conversion)
torch::Tensor topk_values = torch::empty(
{num_tokens, topk}, torch::dtype(torch::kFloat32).device(torch::kCUDA));
torch::Tensor topk_indices = torch::empty(
{num_tokens, topk}, torch::dtype(torch::kInt32).device(torch::kCUDA));
auto stream = c10::cuda::getCurrentCUDAStream(scores.get_device());
switch (data_type) {
case torch::kFloat16:
// Handle Float16
vllm::moe::invokeNoAuxTc<half, int32_t>(
reinterpret_cast<half*>(scores.mutable_data_ptr()),
reinterpret_cast<half*>(group_scores.mutable_data_ptr()),
reinterpret_cast<float*>(topk_values.mutable_data_ptr()),
reinterpret_cast<int32_t*>(topk_indices.mutable_data_ptr()),
reinterpret_cast<half const*>(bias.data_ptr()), num_tokens,
num_experts, n_group, topk_group, topk, renormalize,
routed_scaling_factor, static_cast<int>(scoring_func), false, stream);
break;
case torch::kFloat32:
// Handle Float32
vllm::moe::invokeNoAuxTc<float, int32_t>(
reinterpret_cast<float*>(scores.mutable_data_ptr()),
reinterpret_cast<float*>(group_scores.mutable_data_ptr()),
reinterpret_cast<float*>(topk_values.mutable_data_ptr()),
reinterpret_cast<int32_t*>(topk_indices.mutable_data_ptr()),
reinterpret_cast<float const*>(bias.data_ptr()), num_tokens,
num_experts, n_group, topk_group, topk, renormalize,
routed_scaling_factor, static_cast<int>(scoring_func), false, stream);
break;
case torch::kBFloat16:
// Handle BFloat16
vllm::moe::invokeNoAuxTc<__nv_bfloat16, int32_t>(
reinterpret_cast<__nv_bfloat16*>(scores.mutable_data_ptr()),
reinterpret_cast<__nv_bfloat16*>(group_scores.mutable_data_ptr()),
reinterpret_cast<float*>(topk_values.mutable_data_ptr()),
reinterpret_cast<int32_t*>(topk_indices.mutable_data_ptr()),
reinterpret_cast<__nv_bfloat16 const*>(bias.data_ptr()), num_tokens,
num_experts, n_group, topk_group, topk, renormalize,
routed_scaling_factor, static_cast<int>(scoring_func), false, stream);
break;
default:
// Handle other data types
throw std::invalid_argument(
"Invalid dtype, only supports float16, float32, and bfloat16");
break;
}
return {topk_values, topk_indices};
}
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