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on
T4
Running
on
T4
#include <stdio.h> | |
#include <assert.h> | |
#include "ATen/ATen.h" | |
typedef at::BFloat16 bf16; | |
typedef at::Half fp16; | |
typedef float fp32; | |
template <typename F> | |
__global__ void kernel_forward(const int B, const int T, const int C, const int H, float *__restrict__ _state, | |
const F *__restrict__ const _r, const F *__restrict__ const _k, const F *__restrict__ const _v, const float *__restrict__ _w, const F *__restrict__ _u, | |
F *__restrict__ const _y) | |
{ | |
const int b = blockIdx.x / H; | |
const int h = blockIdx.x % H; | |
const int i = threadIdx.x; | |
_w += h*_N_; | |
_u += h*_N_; | |
_state += h*_N_*_N_ + i*_N_; // wrong if B > 1 !!! | |
__shared__ float r[_N_], k[_N_], u[_N_], w[_N_]; | |
float state[_N_]; | |
#pragma unroll | |
for (int j = 0; j < _N_; j++) | |
state[j] = _state[j]; | |
__syncthreads(); | |
u[i] = float(_u[i]); | |
w[i] = _w[i]; | |
__syncthreads(); | |
for (int t = b*T*C + h*_N_ + i; t < (b+1)*T*C + h*_N_ + i; t += C) | |
{ | |
__syncthreads(); | |
r[i] = float(_r[t]); | |
k[i] = float(_k[t]); | |
__syncthreads(); | |
const float v = float(_v[t]); | |
float y = 0; | |
#pragma unroll | |
for (int j = 0; j < _N_; j+=4) | |
{ | |
const float4& r_ = (float4&)(r[j]); | |
const float4& k_ = (float4&)(k[j]); | |
const float4& w_ = (float4&)(w[j]); | |
const float4& u_ = (float4&)(u[j]); | |
float4& s = (float4&)(state[j]); | |
float4 x; | |
x.x = k_.x * v; | |
x.y = k_.y * v; | |
x.z = k_.z * v; | |
x.w = k_.w * v; | |
y += r_.x * (u_.x * x.x + s.x); | |
y += r_.y * (u_.y * x.y + s.y); | |
y += r_.z * (u_.z * x.z + s.z); | |
y += r_.w * (u_.w * x.w + s.w); | |
s.x = s.x * w_.x + x.x; | |
s.y = s.y * w_.y + x.y; | |
s.z = s.z * w_.z + x.z; | |
s.w = s.w * w_.w + x.w; | |
} | |
_y[t] = F(y); | |
} | |
#pragma unroll | |
for (int j = 0; j < _N_; j++) | |
_state[j] = state[j]; | |
} | |
void cuda_forward_bf16(int B, int T, int C, int H, float *state, bf16 *r, bf16 *k, bf16 *v, float *w, bf16 *u, bf16 *y) | |
{ | |
assert(H*_N_ == C); | |
kernel_forward<<<dim3(B * H), dim3(_N_)>>>(B, T, C, H, state, r, k, v, w, u, y); | |
} | |
void cuda_forward_fp16(int B, int T, int C, int H, float *state, fp16 *r, fp16 *k, fp16 *v, float *w, fp16 *u, fp16 *y) | |
{ | |
assert(H*_N_ == C); | |
kernel_forward<<<dim3(B * H), dim3(_N_)>>>(B, T, C, H, state, r, k, v, w, u, y); | |
} | |
void cuda_forward_fp32(int B, int T, int C, int H, float *state, fp32 *r, fp32 *k, fp32 *v, float *w, fp32 *u, fp32 *y) | |
{ | |
assert(H*_N_ == C); | |
kernel_forward<<<dim3(B * H), dim3(_N_)>>>(B, T, C, H, state, r, k, v, w, u, y); | |
} | |