VisualRWKV-Gradio-1 / cuda /operators.cu
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#include <stdio.h>
#include <assert.h>
#include "ATen/ATen.h"
#include <cuda_fp16.h>
#define MIN_VALUE (-1e38)
typedef at::Half fp16;
__half *cast(fp16 *ptr) {
return reinterpret_cast<__half *>(ptr);
}
template <typename F>
__global__ void kernel_wkv_forward(const int B, const int T, const int C,
const float *__restrict__ const _w, const float *__restrict__ const _u, const F *__restrict__ const _k, const F *__restrict__ const _v,
F *__restrict__ const _y, float *__restrict__ const _aa, float *__restrict__ const _bb, float *__restrict__ const _pp) {
const int idx = blockIdx.x * blockDim.x + threadIdx.x;
const int _b = idx / C;
const int _c = idx % C;
const int _offset = _b * T * C + _c;
const int _state_offset = _b * C + _c;
float u = _u[_c];
float w = _w[_c];
const F *__restrict__ const k = _k + _offset;
const F *__restrict__ const v = _v + _offset;
F *__restrict__ const y = _y + _offset;
float aa = _aa[_state_offset];
float bb = _bb[_state_offset];
float pp = _pp[_state_offset];
for (int i = 0; i < T; i++) {
const int ii = i * C;
const float kk = float(k[ii]);
const float vv = float(v[ii]);
float ww = u + kk;
float p = max(pp, ww);
float e1 = exp(pp - p);
float e2 = exp(ww - p);
y[ii] = F((e1 * aa + e2 * vv) / (e1 * bb + e2));
ww = w + pp;
p = max(ww, kk);
e1 = exp(ww - p);
e2 = exp(kk - p);
aa = e1 * aa + e2 * vv;
bb = e1 * bb + e2;
pp = p;
}
_aa[_state_offset] = aa;
_bb[_state_offset] = bb;
_pp[_state_offset] = pp;
}
template <typename F>
void cuda_wkv_forward(int B, int T, int C, float *w, float *u, F *k, F *v, F *y, float *aa, float *bb, float *pp) {
dim3 threadsPerBlock( min(C, 32) );
assert(B * C % threadsPerBlock.x == 0);
dim3 numBlocks(B * C / threadsPerBlock.x);
kernel_wkv_forward<<<numBlocks, threadsPerBlock>>>(B, T, C, w, u, k, v, y, aa, bb, pp);
}
template void cuda_wkv_forward<fp16>(
int B, int T, int C,
float *w, float *u, fp16 *k, fp16 *v, fp16 *y,
float *aa, float *bb, float *pp);
template void cuda_wkv_forward<float>(
int B, int T, int C,
float *w, float *u, float *k, float *v, float *y,
float *aa, float *bb, float *pp);
__global__ void kernel_mm_seq_fp32i8(
const int B, const int N, const int M,
const float *__restrict__ const x, const int x_stride,
const uint8_t *__restrict__ const w, const int w_stride,
const float *__restrict__ const mx,
const float *__restrict__ const rx,
const float *__restrict__ const my,
const float *__restrict__ const ry,
float *__restrict__ const y, const int y_stride) {
const int i = blockIdx.x * blockDim.x + threadIdx.x;
const int k = blockIdx.y * blockDim.y + threadIdx.y;
if (i < B && k < M) {
float y_local = 0;
for (int j = 0; j < N; ++j) {
y_local += x[i * x_stride + j] * (
(float(w[j * w_stride + k]) + 0.5f)
* rx[k] * ry[j] + mx[k] + my[j]
);
}
y[i * y_stride + k] = y_local;
}
}
template <typename F>
void cuda_mm8_seq(int B, int N, int M,
F *x, int x_stride,
uint8_t *w, int w_stride,
F *mx, F *rx,
F *my, F *ry,
F *y, int y_stride);
template <>
void cuda_mm8_seq<float>(int B, int N, int M,
float *x, int x_stride,
uint8_t *w, int w_stride,
float *mx, float *rx,
float *my, float *ry,
float *y, int y_stride) {
dim3 blockSize(1, 128);
dim3 gridSize((B + blockSize.x - 1) / blockSize.x, (M + blockSize.y - 1) / blockSize.y);
kernel_mm_seq_fp32i8<<<gridSize, blockSize>>>(
B, N, M, x, x_stride, w, w_stride,
mx, rx, my, ry, y, y_stride);
}
__global__ void kernel_mm_seq_fp16i8(
const int B, const int N, const int M,
const __half *__restrict__ const x, const int x_stride,
const uint8_t *__restrict__ const w, const int w_stride,
const __half *__restrict__ const mx,
const __half *__restrict__ const rx,
const __half *__restrict__ const my,
const __half *__restrict__ const ry,
__half *__restrict__ const y, const int y_stride) {
const int i = blockIdx.x * blockDim.x + threadIdx.x;
const int k = blockIdx.y * blockDim.y + threadIdx.y;
if (i < B && k < M) {
float y_local = 0;
for (int j = 0; j < N; ++j) {
y_local += __half2float(x[i * x_stride + j]) * (
(float(w[j * w_stride + k]) + 0.5f)
* __half2float(rx[k]) * __half2float(ry[j])
+ __half2float(mx[k]) + __half2float(my[j])
);
}
y[i * y_stride + k] = __float2half(y_local);
}
}
template <>
void cuda_mm8_seq<fp16>(int B, int N, int M,
fp16 *x, int x_stride,
uint8_t *w, int w_stride,
fp16 *mx, fp16 *rx,
fp16 *my, fp16 *ry,
fp16 *y, int y_stride) {
dim3 blockSize(1, 128);
dim3 gridSize((B + blockSize.x - 1) / blockSize.x, (M + blockSize.y - 1) / blockSize.y);
kernel_mm_seq_fp16i8<<<gridSize, blockSize>>>(
B, N, M, cast(x), x_stride, w, w_stride,
cast(mx), cast(rx), cast(my), cast(ry), cast(y), y_stride);
}
#define MM8_ONE_JSPLIT 24
#define MM8_ONE_TILE 1024
__global__ void kernel_mm_one_fp32i8(
const int N, const int M,
const float *__restrict__ const x,
const uint8_t *__restrict__ const w, const int w_stride,
const float *__restrict__ const mx,
const float *__restrict__ const rx,
const float *__restrict__ const my,
const float *__restrict__ const ry,
float *__restrict__ const y) {
const int k = blockIdx.y * blockDim.y + threadIdx.y;
const int j0 = min(N, blockIdx.x * ((N + MM8_ONE_JSPLIT - 1) / MM8_ONE_JSPLIT));
const int j1 = min(N, (blockIdx.x + 1) * ((N + MM8_ONE_JSPLIT - 1) / MM8_ONE_JSPLIT));
if (k < M) {
float y_local = 0;
for (int j = j0; j < j1; ++j) {
y_local += x[j] * (
(float(w[j * w_stride + k]) + 0.5f)
* rx[k] * ry[j] + mx[k] + my[j]
);
}
atomicAdd(&y[k], y_local);
}
}
template <typename F>
void cuda_mm8_one(int N, int M,
F *x,
uint8_t *w, int w_stride,
F *mx, F *rx,
F *my, F *ry,
float *y);
template <>
void cuda_mm8_one<float>(int N, int M,
float *x,
uint8_t *w, int w_stride,
float *mx, float *rx,
float *my, float *ry,
float *y) {
dim3 blockSize(1, MM8_ONE_TILE);
dim3 gridSize(MM8_ONE_JSPLIT, (M + blockSize.y - 1) / blockSize.y);
kernel_mm_one_fp32i8<<<gridSize, blockSize>>>(
N, M, x, w, w_stride,
mx, rx, my, ry, y);
}
__global__ void kernel_mm_one_fp16i8(
const int N, const int M,
const __half *__restrict__ const x,
const uint8_t *__restrict__ const w, const int w_stride,
const __half *__restrict__ const mx,
const __half *__restrict__ const rx,
const __half *__restrict__ const my,
const __half *__restrict__ const ry,
float *__restrict__ const y) {
const int k = blockIdx.y * blockDim.y + threadIdx.y;
const int j0 = min(N, blockIdx.x * ((N + MM8_ONE_JSPLIT - 1) / MM8_ONE_JSPLIT));
const int j1 = min(N, (blockIdx.x + 1) * ((N + MM8_ONE_JSPLIT - 1) / MM8_ONE_JSPLIT));
if (k < M) {
float y_local = 0;
for (int j = j0; j < j1; ++j) {
y_local += __half2float(x[j]) * (
(float(w[j * w_stride + k]) + 0.5f)
* __half2float(rx[k]) * __half2float(ry[j])
+ __half2float(mx[k]) + __half2float(my[j])
);
}
atomicAdd(&y[k], y_local);
}
}
template <>
void cuda_mm8_one<fp16>(int N, int M,
fp16 *x,
uint8_t *w, int w_stride,
fp16 *mx, fp16 *rx,
fp16 *my, fp16 *ry,
float *y) {
dim3 blockSize(1, MM8_ONE_TILE);
dim3 gridSize(MM8_ONE_JSPLIT, (M + blockSize.y - 1) / blockSize.y);
kernel_mm_one_fp16i8<<<gridSize, blockSize>>>(
N, M, cast(x), w, w_stride,
cast(mx), cast(rx), cast(my), cast(ry), y);
}