AstrAI/csrc/kernels/attn_paged_decode.cu

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#include "attn_paged_decode_split_kv.cuh"
#ifndef ASTRAI_NO_MMA
#include "attn_paged_decode_split_kv_mma.cuh"
#endif
#include <torch/extension.h>
#include <c10/cuda/CUDAGuard.h>
static int paged_decode_num_splits(int base_blocks, int tiles_total) {
int sm_count = 0;
cudaDeviceGetAttribute(&sm_count, cudaDevAttrMultiProcessorCount, 0);
int n = (2 * sm_count + base_blocks - 1) / base_blocks;
return std::max(1, std::min(n, std::min(tiles_total, 32)));
}
static void launch_paged_scalar_decode(PagedAttentionParams<bf16>& p) {
int group_size = p.q_head / p.kv_head;
int chunks_total = (p.kv_len + PDC_CHUNK - 1) / PDC_CHUNK;
p.num_splits = paged_decode_num_splits(p.batch * p.kv_head, chunks_total);
auto fopt = torch::TensorOptions().dtype(torch::kFloat32).device(torch::kCUDA);
auto o_part = torch::empty({p.batch, p.q_head, p.num_splits, p.head_dim}, fopt);
auto ml_part = torch::empty({p.batch, p.q_head, p.num_splits, 2}, fopt);
p.o_part = o_part.data_ptr<float>();
p.ml_part = ml_part.data_ptr<float>();
size_t smem = PDC_CHUNK * p.head_dim * sizeof(bf16);
paged_attn_decode_split_kv_kernel<<<
dim3(p.batch * p.kv_head, 1, p.num_splits),
dim3(32, group_size),
smem>>>(p);
paged_attn_decode_combine_kernel<<<p.batch * p.q_head, p.head_dim>>>(p);
}
#ifndef ASTRAI_NO_MMA
template <int HEAD_DIM, int BC>
static void launch_paged_mma_decode(PagedAttentionParams<bf16>& p) {
int tiles_total = (p.kv_len + BC - 1) / BC;
p.num_splits = paged_decode_num_splits(p.batch * p.kv_head, tiles_total);
auto fopt = torch::TensorOptions().dtype(torch::kFloat32).device(torch::kCUDA);
auto o_part = torch::empty({p.batch, p.q_head, p.num_splits, p.head_dim}, fopt);
auto ml_part = torch::empty({p.batch, p.q_head, p.num_splits, 2}, fopt);
p.o_part = o_part.data_ptr<float>();
p.ml_part = ml_part.data_ptr<float>();
paged_attn_decode_split_kv_mma_kernel<HEAD_DIM, BC>
<<<dim3(p.kv_head, p.batch, p.num_splits), 32>>>(p);
paged_attn_decode_combine_kernel<<<p.batch * p.q_head, p.head_dim>>>(p);
}
#endif
template <int HEAD_DIM>
static void dispatch_paged_decode(PagedAttentionParams<bf16>& p) {
#ifndef ASTRAI_NO_MMA
int G = p.q_head / p.kv_head;
if (!p.use_mask && G >= 1 && G <= 16 && p.page_size >= 32) {
launch_paged_mma_decode<HEAD_DIM, 32>(p);
return;
}
#endif
launch_paged_scalar_decode(p);
}
torch::Tensor attn_paged_decode(
torch::Tensor q,
torch::Tensor page_table,
torch::Tensor k_cache,
torch::Tensor v_cache,
int64_t page_size,
int64_t kv_len,
c10::optional<torch::Tensor> mask,
bool is_causal = false,
int64_t causal_offset = 0,
c10::optional<double> scale = c10::nullopt
) {
const at::cuda::OptionalCUDAGuard device_guard(device_of(q));
int batch = q.size(0);
int q_head = q.size(1);
int head_dim = q.size(3);
int kv_head = k_cache.size(3);
int max_pages = page_table.size(1);
TORCH_CHECK(q.is_cuda() && page_table.is_cuda() && k_cache.is_cuda() && v_cache.is_cuda());
TORCH_CHECK(q.dtype() == torch::kBFloat16, "q must be bf16");
TORCH_CHECK(k_cache.dtype() == torch::kBFloat16, "k_cache must be bf16");
TORCH_CHECK(v_cache.dtype() == torch::kBFloat16, "v_cache must be bf16");
TORCH_CHECK(page_table.dtype() == torch::kLong, "page_table must be int64");
TORCH_CHECK(q.size(2) == 1, "Q seq_len must be 1 (decode)");
TORCH_CHECK(head_dim % 32 == 0, "head_dim must be multiple of 32");
TORCH_CHECK(k_cache.size(1) == page_size,
"k_cache dim 1 must equal page_size, got ",
k_cache.size(1), " vs ", page_size);
TORCH_CHECK(k_cache.size(0) >= 0, "k_cache must have at least 0 pages");
float scale_val = scale.has_value()
? static_cast<float>(scale.value())
: 1.0f / std::sqrt(static_cast<float>(head_dim));
auto O = torch::empty_like(q);
PagedAttentionParams<bf16, float> p;
p.batch = batch;
p.q_head = q_head;
p.kv_head = kv_head;
p.q_len = 1;
p.kv_len = static_cast<int>(kv_len);
p.head_dim = head_dim;
p.use_mask = (mask.has_value() && mask.value().defined()) ? 1 : 0;
p.is_causal = is_causal ? 1 : 0;
p.causal_offset = static_cast<int>(causal_offset);
p.num_splits = 1;
p.scale = scale_val;
p.page_size = static_cast<int>(page_size);
p.max_pages = max_pages;
p.page_table = page_table.data_ptr<int64_t>();
p.k_cache = reinterpret_cast<const bf16*>(k_cache.data_ptr());
p.v_cache = reinterpret_cast<const bf16*>(v_cache.data_ptr());
p.q = reinterpret_cast<const bf16*>(q.data_ptr());
p.mask = p.use_mask ? mask.value().data_ptr<bool>() : nullptr;
p.o = reinterpret_cast<bf16*>(O.data_ptr());
p.o_part = nullptr;
p.ml_part = nullptr;
switch (p.head_dim) {
case 32: dispatch_paged_decode<32>(p); break;
case 64: dispatch_paged_decode<64>(p); break;
case 128: dispatch_paged_decode<128>(p); break;
case 256: dispatch_paged_decode<256>(p); break;
default:
TORCH_CHECK(false, "paged_decode: unsupported head_dim ", p.head_dim,
" (supported: 32, 64, 128, 256)");
}
return O;
}
PYBIND11_MODULE(TORCH_EXTENSION_NAME, m) {
m.def("attn_paged_decode", &attn_paged_decode,
py::arg("q"),
py::arg("page_table"),
py::arg("k_cache"),
py::arg("v_cache"),
py::arg("page_size"),
py::arg("kv_len"),
py::arg("mask") = py::none(),
py::arg("is_causal") = false,
py::arg("causal_offset") = 0,
py::arg("scale") = py::none(),
"Paged GQA decode — split-KV with direct page-table access.");
}