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train_gpt2.cu
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train_gpt2.cu
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/*
GPT-2 Transformer Neural Net trained in raw CUDA
*/
#include <stdio.h>
#include <stdlib.h>
#include <ctype.h>
#include <math.h>
#include <time.h>
#include <assert.h>
#include <float.h>
#include <string.h>
#include <unistd.h>
#include <assert.h>
#include <cublas_v2.h>
#include <cuda_runtime.h>
#include <cublasLt.h>
#include <cooperative_groups.h>
#include <cooperative_groups/reduce.h>
// ----------------------------------------------------------------------------
// CUDA utils
// convenience macro for calculating grid/block dimensions for kernels
#define CEIL_DIV(M, N) (((M) + (N)-1) / (N))
// CUDA error checking
void cudaCheck(cudaError_t error, const char *file, int line) {
if (error != cudaSuccess) {
printf("[CUDA ERROR] at file %s:%d:\n%s\n", file, line,
cudaGetErrorString(error));
exit(EXIT_FAILURE);
}
};
#define cudaCheck(err) (cudaCheck(err, __FILE__, __LINE__))
// cuBLAS error checking
void cublasCheck(cublasStatus_t status, const char *file, int line)
{
if (status != CUBLAS_STATUS_SUCCESS) {
printf("[cuBLAS ERROR]: %d %s %d\n", status, file, line);
exit(EXIT_FAILURE);
}
}
#define cublasCheck(status) { cublasCheck((status), __FILE__, __LINE__); }
// cuBLAS workspace. Hardcoding to 32MiB but only Hopper needs 32, for others 4 is OK
static size_t cublaslt_workspace_size = 32 * 1024 * 1024;
static void* cublaslt_workspace = NULL;
static cublasComputeType_t cublas_compute_type;
cublasHandle_t cublas_handle;
cublasLtHandle_t cublaslt_handle;
// ----------------------------------------------------------------------------
// fread convenience utils, with nice handling of error checking using macros
// simple replace fopen, fread, fclose with fopenCheck, freadCheck, fcloseCheck
FILE *fopen_check(const char *path, const char *mode, const char *file, int line) {
FILE *fp = fopen(path, mode);
if (fp == NULL) {
fprintf(stderr, "Error: Failed to open file '%s' at %s:%d\n", path, file, line);
fprintf(stderr, "Error details:\n");
fprintf(stderr, " File: %s\n", file);
fprintf(stderr, " Line: %d\n", line);
fprintf(stderr, " Path: %s\n", path);
fprintf(stderr, " Mode: %s\n", mode);
exit(EXIT_FAILURE);
}
return fp;
}
#define fopenCheck(path, mode) fopen_check(path, mode, __FILE__, __LINE__)
void fread_check(void *ptr, size_t size, size_t nmemb, FILE *stream, const char *file, int line) {
size_t result = fread(ptr, size, nmemb, stream);
if (result != nmemb) {
if (feof(stream)) {
fprintf(stderr, "Error: Unexpected end of file at %s:%d\n", file, line);
} else if (ferror(stream)) {
fprintf(stderr, "Error: File read error at %s:%d\n", file, line);
} else {
fprintf(stderr, "Error: Partial read at %s:%d. Expected %zu elements, read %zu\n",
file, line, nmemb, result);
}
fprintf(stderr, "Error details:\n");
fprintf(stderr, " File: %s\n", file);
fprintf(stderr, " Line: %d\n", line);
fprintf(stderr, " Expected elements: %zu\n", nmemb);
fprintf(stderr, " Read elements: %zu\n", result);
exit(EXIT_FAILURE);
}
}
#define freadCheck(ptr, size, nmemb, stream) fread_check(ptr, size, nmemb, stream, __FILE__, __LINE__)
void fclose_check(FILE *fp, const char *file, int line) {
if (fclose(fp) != 0) {
fprintf(stderr, "Error: Failed to close file at %s:%d\n", file, line);
fprintf(stderr, "Error details:\n");
fprintf(stderr, " File: %s\n", file);
fprintf(stderr, " Line: %d\n", line);
exit(EXIT_FAILURE);
}
}
#define fcloseCheck(fp) fclose_check(fp, __FILE__, __LINE__)
// ----------------------------------------------------------------------------
// malloc error-handling wrapper util
void *malloc_check(size_t size, const char *file, int line) {
void *ptr = malloc(size);
if (ptr == NULL) {
fprintf(stderr, "Error: Memory allocation failed at %s:%d\n", file, line);
fprintf(stderr, "Error details:\n");
fprintf(stderr, " File: %s\n", file);
fprintf(stderr, " Line: %d\n", line);
fprintf(stderr, " Size: %zu bytes\n", size);
exit(EXIT_FAILURE);
}
return ptr;
}
#define mallocCheck(size) malloc_check(size, __FILE__, __LINE__)
// ----------------------------------------------------------------------------
// all the kernels
// warp-level reduction for finding the maximum value
__device__ float warpReduceMax(float val) {
for (int offset = 16; offset > 0; offset /= 2) {
val = fmaxf(val, __shfl_down_sync(0xFFFFFFFF, val, offset));
}
return val;
}
// warp-level reduction for summing values
__device__ float warpReduceSum(float val) {
for (int offset = 16; offset > 0; offset /= 2) {
val += __shfl_down_sync(0xFFFFFFFF, val, offset);
}
return val;
}
__global__ void encoder_forward_kernel2(float* out,
int* inp, float* wte, float* wpe,
int B, int T, int C) {
int idx = blockIdx.x * blockDim.x + threadIdx.x;
int N = B * T * C;
if (idx < N) {
int bt = idx / C;
int b = bt / T;
int t = bt % T;
int c = idx % C;
int ix = inp[b * T + t];
float* out_btc = out + b * T * C + t * C + c;
float* wte_ix = wte + ix * C + c;
float* wpe_tc = wpe + t * C + c;
*out_btc = *wte_ix + *wpe_tc;
}
}
// really bad naive kernel with atomicAdd
__global__ void encoder_backward_kernel(float* dwte, float* dwpe,
const float* dout, const int* inp,
int B, int T, int C) {
int idx = blockIdx.x * blockDim.x + threadIdx.x;
int N = B * T * C;
if (idx < N) {
int bt = idx / C;
int b = bt / T;
int t = bt % T;
int c = idx % C;
int ix = inp[b * T + t];
const float* dout_btc = dout + b * T * C + t * C + c;
float* dwte_ix = dwte + ix * C + c;
float* dwpe_tc = dwpe + t * C + c;
atomicAdd(dwte_ix, *dout_btc);
atomicAdd(dwpe_tc, *dout_btc);
}
}
__global__ void layernorm_forward_kernel3(float* __restrict__ out, float* __restrict__ mean, float* __restrict__ rstd,
const float* __restrict__ inp, const float* __restrict__ weight,
const float* __restrict__ bias, int N, int C) {
namespace cg = cooperative_groups;
cg::thread_block block = cg::this_thread_block();
cg::thread_block_tile<32> warp = cg::tiled_partition<32>(block);
int idx = blockIdx.x * warp.meta_group_size() + warp.meta_group_rank();
if(idx >= N) {
return;
}
// the row of input that this group of threads is responsible for
const float* x = inp + idx * C;
// mean
float sum = 0.0f;
for (int i = warp.thread_rank(); i < C; i += warp.size()) {
sum += x[i];
}
sum = cg::reduce(warp, sum, cg::plus<float>{});
float m = sum / C;
if(warp.thread_rank() == 0 && mean != nullptr) {
__stcs(mean + idx, m);
}
// rstd
sum = 0.0f;
for (int i = warp.thread_rank(); i < C; i += warp.size()) {
float diff = x[i] - m;
sum += diff * diff;
}
sum = cg::reduce(warp, sum, cg::plus<float>{});
float s = rsqrtf(sum / C + 1e-5f);
if(warp.thread_rank() == 0 && rstd != nullptr) {
__stcs(rstd + idx, s);
}
// final normalization and scaling by weight/bias
float* o = out + idx * C;
for (int c = warp.thread_rank(); c < C; c += warp.size()) {
// load and store using the .cs "streaming" hint to the compiler,
// indicating that this data will not be reused soon, and can be streamed through the caches
// this allows the threads to get more cache-hits for the (shared) weight and bias parameters
float n = s * (__ldcs(x+c) - m);
__stcs(o+c, n * weight[c] + bias[c]);
}
}
__global__ void add_bias(float* out, float* bias, int B, int T, int OC) {
int idx = blockIdx.x * blockDim.x + threadIdx.x;
int stride = blockDim.x * gridDim.x;
for (int i = idx; i < B*T*OC; i += stride) {
int col = i % OC;
out[i] += bias[col];
}
}
__global__ void permute_kernel(float* q, float* k, float* v,
const float* inp,
int B, int N, int NH, int d) {
// okay so now, this kernel wants Q,K,V to all be of shape (B, NH, N, d)
// but instead, we have a single tensor QKV (inp) of shape (B, N, 3, NH, d)
int idx = blockIdx.x * blockDim.x + threadIdx.x;
// Q[b][nh_][n][d_] = inp[b][n][0][nh_][d_]
if (idx < B * NH * N * d) {
int b = idx / (NH * N * d);
int rest = idx % (NH * N * d);
int nh_ = rest / (N * d);
rest = rest % (N * d);
int n = rest / d;
int d_ = rest % d;
int inp_idx = \
(b * N * 3 * NH * d)
+ (n * 3 * NH * d)
+ (0 * NH * d)
+ (nh_ * d)
+ d_;
q[idx] = __ldcs(&inp[inp_idx]);
k[idx] = __ldcs(&inp[inp_idx + NH * d]);
v[idx] = __ldcs(&inp[inp_idx + 2 * (NH * d)]);
}
}
__global__ void permute_kernel_backward(float* dinp,
const float* dq, const float* dk, const float* dv,
int B, int N, int NH, int d) {
int idx = blockIdx.x * blockDim.x + threadIdx.x;
if (idx < B * NH * N * d) {
int b = idx / (NH * N * d);
int rest = idx % (NH * N * d);
int nh_ = rest / (N * d);
rest = rest % (N * d);
int n = rest / d;
int d_ = rest % d;
int inp_idx = (b * N * 3 * NH * d) + (n * 3 * NH * d) + (0 * NH * d) + (nh_ * d) + d_;
dinp[inp_idx] += dq[idx];
dinp[inp_idx + NH * d] += dk[idx];
dinp[inp_idx + 2 * (NH * d)] += dv[idx];
}
}
__global__ void unpermute_kernel(float* inp, float *out, int B, int N, int NH, int d) {
// out has shape (B, nh, N, d) but we need to unpermute it to (B, N, nh, d)
int idx = blockIdx.x * blockDim.x + threadIdx.x;
// out[b][n][nh_][d_] <- inp[b][nh_][n][d_]
if (idx < B * NH * N * d) {
int b = idx / (NH * N * d);
int rest = idx % (NH * N * d);
int nh_ = rest / (N * d);
rest = rest % (N * d);
int n = rest / d;
int d_ = rest % d;
int other_idx = (b * NH * N * d) + (n * NH * d) + (nh_ * d) + d_;
out[other_idx] = __ldcs(&inp[idx]);
}
}
__global__ void unpermute_kernel_backward(float* dinp, const float *dout, int B, int N, int NH, int d) {
int idx = blockIdx.x * blockDim.x + threadIdx.x;
if (idx < B * NH * N * d) {
int b = idx / (NH * N * d);
int rest = idx % (NH * N * d);
int nh_ = rest / (N * d);
rest = rest % (N * d);
int n = rest / d;
int d_ = rest % d;
int other_idx = (b * NH * N * d) + (n * NH * d) + (nh_ * d) + d_;
dinp[idx] += dout[other_idx];
}
}
__device__ float& vec_at(float4& vec, int index) {
return reinterpret_cast<float*>(&vec)[index];
}
__device__ float vec_at(const float4& vec, int index) {
return reinterpret_cast<const float*>(&vec)[index];
}
__global__ void softmax_forward_kernel5(float* out, float inv_temperature, const float* inp, int N, int T) {
// inp, out shape: (N, T, T), where N = B * NH
// fuses the multiplication by scale inside attention
// directly autoregressive, so we only compute the lower triangular part
// uses the online softmax algorithm
assert(T % 4 == 0);
namespace cg = cooperative_groups;
cg::thread_block block = cg::this_thread_block();
cg::thread_block_tile<32> warp = cg::tiled_partition<32>(block);
int idx = blockIdx.x * warp.meta_group_size() + warp.meta_group_rank();
if(idx >= N * T) {
return;
}
int own_pos = idx % T;
int pos_by_4 = own_pos / 4;
// one row of inp, i.e. inp[idx, :] of shape (T,)
const float* x = inp + idx * T;
// not INF, so we don't get NaNs accidentally when subtracting two values.
float maxval = -FLT_MAX;
float sumval = 0.0f;
const float4* x_vec = reinterpret_cast<const float4*>(x);
for (int i = warp.thread_rank(); i < pos_by_4; i += warp.size()) {
float4 v = x_vec[i];
float old_maxval = maxval;
for(int k = 0; k < 4; ++k) {
maxval = fmaxf(maxval, vec_at(v, k));
}
sumval *= expf(inv_temperature * (old_maxval - maxval));
for(int k = 0; k < 4; ++k) {
sumval += expf(inv_temperature * (vec_at(v, k) - maxval));
}
}
if(4*pos_by_4 + warp.thread_rank() <= own_pos) {
float old_maxval = maxval;
maxval = fmaxf(maxval, x[4*pos_by_4 + warp.thread_rank()]);
sumval *= expf(inv_temperature * (old_maxval - maxval));
sumval += expf(inv_temperature * (x[4*pos_by_4 + warp.thread_rank()] - maxval));
}
float global_maxval = cg::reduce(warp, maxval, cg::greater<float>{});
sumval *= expf(inv_temperature * (maxval - global_maxval));
float sum = cg::reduce(warp, sumval, cg::plus<float>{});
float norm = 1.f / sum;
// divide the whole row by the sum
for (int i = warp.thread_rank(); i <= own_pos; i += warp.size()) {
// recalculation is faster than doing the round-trip through memory.
float ev = expf(inv_temperature * (__ldcs(x + i) - global_maxval));
__stcs(out + idx * T + i, ev * norm);
}
}
__global__ void residual_forward_kernel(float* out, float* inp1, float* inp2, int N) {
int idx = blockIdx.x * blockDim.x + threadIdx.x;
if (idx < N) {
out[idx] = __ldcs(&inp1[idx]) + __ldcs(&inp2[idx]);
}
}
__global__ void residual_backward_kernel(float* dinp1, float* dinp2, float* dout, int N) {
int idx = blockIdx.x * blockDim.x + threadIdx.x;
if (idx < N) {
dinp1[idx] += __ldcs(&dout[idx]);
dinp2[idx] += __ldcs(&dout[idx]);
}
}
#define GELU_SCALING_FACTOR sqrtf(2.0f / M_PI)
__global__ void gelu_forward_kernel(float* out, const float* inp, int N) {
int i = blockIdx.x * blockDim.x + threadIdx.x;
if (i < N) {
float xi = inp[i];
float cube = 0.044715f * xi * xi * xi;
out[i] = 0.5f * xi * (1.0f + tanhf(GELU_SCALING_FACTOR * (xi + cube)));
}
}
__global__ void gelu_backward_kernel(float* dinp, const float* inp, const float* dout, const int N) {
int i = blockIdx.x * blockDim.x + threadIdx.x;
if (i < N) {
float x = inp[i];
float cube = 0.044715f * x * x * x;
float tanh_arg = GELU_SCALING_FACTOR * (x + cube);
float tanh_out = tanhf(tanh_arg);
float coshf_out = coshf(tanh_arg);
float sech_out = 1.0f / (coshf_out * coshf_out);
float local_grad = 0.5f * (1.0f + tanh_out) + x * 0.5f * sech_out * GELU_SCALING_FACTOR * (1.0f + 3.0f * 0.044715f * x * x);
dinp[i] += local_grad * dout[i];
}
}
__global__ void crossentropy_forward_kernel1(float* losses,
float* probs, int* targets,
int B, int T, int V) {
int i = blockIdx.x * blockDim.x + threadIdx.x;
if (i < B * T) {
int b = i / T;
int t = i % T;
float* probs_bt = probs + b * T * V + t * V;
int ix = targets[b * T + t];
losses[b * T + t] = -logf(probs_bt[ix]);
}
}
__global__ void softmax_forward_kernel7(float* out, const float* inp, int N, int C) {
// out is (N, C) just like inp. Each row of inp will get softmaxed.
// same as kernel4, but optimised for very large Cs with advanced unrolling
// The trick is to read into a register array (all indices known at compile time)
// and always read UNROLL_FACTOR values to maximise memory level parallelism
// even if we would be out of bounds, we set the index to min(C-1, idx)
// so we just do some unnecessary reads (obviously bad for small C)
// the writes are in a separate loop with a conditional check for out of bounds
// making it separate is necessary to convince the compiler to do the right thing
const int UNROLL_FACTOR = 8;
const int warpsPerBlock = blockDim.x / 32;
extern __shared__ float shared[];
int idx = blockIdx.x;
int tid = threadIdx.x;
int warpId = threadIdx.x / 32; // warp index within a block
int laneId = threadIdx.x % 32; // thread index within a warp
// shared[] must be allocated to have 2 * warpsPerBlock elements
// first half for max values, the second half for sum values
float* maxvals = shared;
float* sumvals = &shared[warpsPerBlock];
if (tid >= C) {
maxvals[warpId] = -INFINITY;
sumvals[warpId] = 0.0f;
return;
}
const float* x = inp + idx * C; // input
float* y = out + idx * C; // output
// first, thread coarsening by directly accessing global memory in series
float maxval = -INFINITY;
for (int i = tid; i < C; i += blockDim.x * UNROLL_FACTOR) {
#pragma unroll
for (int u = 0; u < UNROLL_FACTOR; u++) {
maxval = fmaxf(maxval, x[min(C - 1, i + u*blockDim.x)]);
}
}
// now within-warp reductions for maxval
maxval = warpReduceMax(maxval);
// the 0th thread of each warp writes the maxval of that warp to shared memory
if (laneId == 0) maxvals[warpId] = maxval;
__syncthreads();
// now the 0th thread reduces the maxvals in shared memory, i.e. across warps
if (tid == 0) {
float val = maxvals[tid];
#pragma unroll
for (int i = 1; i < warpsPerBlock; i++) {
val = fmaxf(val, maxvals[i]);
}
// store the final max in the first position
maxvals[0] = val;
}
__syncthreads();
// broadcast the max to all threads
float offset = maxvals[0];
// compute expf and write the result to global memory
// + thread coarsening for sum
float sumval = 0.0f;
for (int i = tid; i < C; i += blockDim.x * UNROLL_FACTOR) {
float reg_array[UNROLL_FACTOR];
#pragma unroll
for (int u = 0; u < UNROLL_FACTOR; u++) {
reg_array[u] = __ldcs(&x[min(C - 1, i + u*blockDim.x)]);
}
#pragma unroll
for (int u = 0; u < UNROLL_FACTOR; u++) {
if (i + u*blockDim.x < C) {
float output = expf(reg_array[u] - offset);
y[min(C - 1, i + u*blockDim.x)] = output; // compiler likes redundant min()?!
sumval += output; // combined into the same loop unlike kernel3
}
}
}
// okay now we calculated exp(x - max(x))
// step 2: sum all the values and divide by the sum
// within-warp reduction for sumval
sumval = warpReduceSum(sumval);
// write sumval to shared memory
if (laneId == 0) sumvals[warpId] = sumval;
__syncthreads();
// inter-thread reduction of sum
if (tid == 0) {
float val = sumvals[tid];
#pragma unroll
for (int i = 1; i < warpsPerBlock; ++i) {
val += sumvals[i];
}
sumvals[0] = val;
}
__syncthreads();
// broadcast the sum to all threads
float sum = sumvals[0];
// divide the whole row by the sum
for (int i = tid; i < C; i += blockDim.x * UNROLL_FACTOR) {
float reg_array[UNROLL_FACTOR];
#pragma unroll
for (int u = 0; u < UNROLL_FACTOR; u++) {
reg_array[u] = y[min(C - 1, i + u*blockDim.x)];
}
#pragma unroll
for (int u = 0; u < UNROLL_FACTOR; u++) {
if (i + u*blockDim.x < C) {
y[i + u*blockDim.x] = reg_array[u] / sum;
}
}
}
}
__global__ void crossentropy_softmax_backward_kernel1(float* dlogits,
const float* dlosses, const float* probs, const int* targets,
int B, int T, int V) {
int i = blockIdx.x * blockDim.x + threadIdx.x;
if (i < B * T * V) {
int b = i / (T * V);
int t = (i / V) % T;
int v = i % V;
float* dlogits_bt = dlogits + b * T * V + t * V;
const float* probs_bt = probs + b * T * V + t * V;
float dloss = dlosses[b * T + t];
int ix = targets[b * T + t];
float p = probs_bt[v];
float indicator = v == ix ? 1.0f : 0.0f;
dlogits_bt[v] += (p - indicator) * dloss;
}
}
__global__ void matmul_backward_bias_kernel_faster(float* dbias, const float* dout, int B, int T, int OC) {
extern __shared__ float shared[];
int o = blockIdx.x; // range [0, OC)
int tid = threadIdx.x; // range [0, block_size)
int block_size = blockDim.x;
const float* x = dout + o;
// thread coarsening
double sum = 0.0f;
for (int i = tid; i < B * T; i += block_size) {
sum += x[i * OC];
}
shared[tid] = (float) sum;
__syncthreads();
// reductions
for (int stride = block_size / 2; stride >= 1; stride /= 2) {
__syncthreads();
if (tid < stride) {
shared[tid] += shared[tid + stride];
}
}
// write the final result (at thread 0) to global memory
if (tid == 0) {
dbias[o] = shared[0];
}
}
__global__ void layernorm_backward_kernel(float* dinp, float* dweight, float* dbias,
float* dout, float* inp, const float* weight, const float* mean, const float* rstd,
int B, int T, int C) {
namespace cg = cooperative_groups;
cg::thread_block block = cg::this_thread_block();
cg::thread_block_tile<32> warp = cg::tiled_partition<32>(block);
int idx = blockIdx.x * warp.meta_group_size() + warp.meta_group_rank();
int N = B * T;
if(idx >= N) {
return;
}
int b = idx / T;
int t = idx % T;
float* dout_bt = dout + b * T * C + t * C;
float* inp_bt = inp + b * T * C + t * C;
float* dinp_bt = dinp + b * T * C + t * C;
float mean_bt = mean[b * T + t];
float rstd_bt = rstd[b * T + t];
// first: two reduce operations
float dnorm_mean = 0.0f;
float dnorm_norm_mean = 0.0f;
for (int i = warp.thread_rank(); i < C; i += warp.size()) {
float norm_bti = (inp_bt[i] - mean_bt) * rstd_bt;
float dnorm_i = weight[i] * dout_bt[i];
dnorm_mean += dnorm_i;
dnorm_norm_mean += dnorm_i * norm_bti;
}
dnorm_mean = cg::reduce(warp, dnorm_mean, cg::plus<float>{});
dnorm_norm_mean = cg::reduce(warp, dnorm_norm_mean, cg::plus<float>{});
dnorm_mean = dnorm_mean / C;
dnorm_norm_mean = dnorm_norm_mean / C;
// now iterate again and accumulate all the gradients
for (int i = warp.thread_rank(); i < C; i += warp.size()) {
float norm_bti = (inp_bt[i] - mean_bt) * rstd_bt;
float dnorm_i = weight[i] * dout_bt[i];
// gradient contribution to bias
atomicAdd(&dbias[i], dout_bt[i]);
// gradient contribution to weight
atomicAdd(&dweight[i], norm_bti * dout_bt[i]);
// gradient contribution to input
float dval = 0.0f;
dval += dnorm_i; // term 1
dval -= dnorm_mean; // term 2
dval -= norm_bti * dnorm_norm_mean; // term 3
dval *= rstd_bt; // final scale
dinp_bt[i] += dval;
}
}
__global__ void setConstant(float* vec, float constant, int N) {
int idx = blockIdx.x * blockDim.x + threadIdx.x;
if (idx < N) {
vec[idx] = constant;
}
}
// naive kernel to backward through an autoregressive softmax, just to get correctness
__global__ void softmax_autoregressive_backward_kernel(float* dpreatt, const float* datt, const float* att,
int B, int T, int C, int NH) {
int t3 = blockIdx.x * blockDim.x + threadIdx.x;
if (t3 >= T) {
return;
}
int hs = C / NH; // head size
float scale = 1.0f / sqrtf(hs);
int idx = blockIdx.y * T * T;
for (int t = t3; t < T; t++) {
float result = 0.0;
const float* att_bth = att + idx + t*T;
const float* datt_bth = datt + idx + t*T;
float* dpreatt_bth = dpreatt + idx + t*T;
for (int t2 = 0; t2 <= t; t2++) {
float indicator = t2 == t3 ? 1.0f : 0.0f;
float local_derivative = att_bth[t2] * (indicator - att_bth[t3]);
result += scale * local_derivative * datt_bth[t2];
}
dpreatt_bth[t3] += result;
}
}
// Implements linear interpolation using only two floating-point operations (as opposed to three in a naive implementation).
// Reference: https://developer.nvidia.com/blog/lerp-faster-cuda
__device__ inline float lerp(float start, float end, float weight) {
return fma(weight, end, fma(-weight, start, start));
}
__global__ void adamw_kernel2(float* params_memory, float* grads_memory, float* m_memory, float* v_memory, long num_parameters,
float learning_rate, float beta1, float beta2, float beta1_correction, float beta2_correction, float eps, float weight_decay) {
int i = blockIdx.x * blockDim.x + threadIdx.x;
if (i >= num_parameters) return; // guard
float grad = grads_memory[i];
float m = m_memory[i];
float v = v_memory[i];
// update the first moment (momentum)
m = lerp(grad, m, beta1);
m_memory[i] = m;
// update the second moment (RMSprop)
v = lerp(grad * grad, v, beta2);
v_memory[i] = v;
m /= beta1_correction; // m_hat
v /= beta2_correction; // v_hat
params_memory[i] -= learning_rate * (m / (sqrtf(v) + eps) + weight_decay * params_memory[i]);
}
// ----------------------------------------------------------------------------
// kernel launchers
void encoder_forward(float* out,
int* inp, float* wte, float* wpe,
int B, int T, int C) {
const int N = B * T * C;
const int block_size = 256;
const int grid_size = CEIL_DIV(N, block_size);
encoder_forward_kernel2<<<grid_size, block_size>>>(out, inp, wte, wpe, B, T, C);
cudaCheck(cudaGetLastError());
}
void encoder_backward(float* dwte, float* dwpe,
const float* dout, const int* inp,
int B, int T, int C) {
const int N = B * T * C;
const int block_size = 256;
const int grid_size = CEIL_DIV(N, block_size);
encoder_backward_kernel<<<grid_size, block_size>>>(dwte, dwpe, dout, inp, B, T, C);
cudaCheck(cudaGetLastError());
}
void layernorm_forward(float* out, float* mean, float* rstd,
float* inp, float* weight, float* bias,
int B, int T, int C) {
const int block_size = 512;
const int N = B * T;
const int grid_size = CEIL_DIV(N * 32, block_size);
layernorm_forward_kernel3<<<grid_size, block_size>>>(out, mean, rstd, inp, weight, bias, N, C);
cudaCheck(cudaGetLastError());
}
// uses cuBLAS
void matmul_forward_cublas(float* out,
float* inp, float* weight, float* bias,
int B, int T, int C, int OC) {
const int sqrt_block_size = 32;
const float alpha = 1.0f;
const float beta = 0.0f;
cublasCheck(cublasSgemm(cublas_handle, CUBLAS_OP_T, CUBLAS_OP_N, OC, B*T, C, &alpha, weight, C, inp, C, &beta, out, OC));
// and now we still have to add the bias... (ew)
if (bias != NULL) {
int block_size = sqrt_block_size * sqrt_block_size;
int grid_size = CEIL_DIV(OC * B * T, block_size);
add_bias<<<grid_size, block_size>>>(out, bias, B, T, OC);
cudaCheck(cudaGetLastError());
}
}
// uses cuBLASLt to fuse the bias and gelu. does not work with OC = 50257 (last layer)
// https://docs.nvidia.com/cuda/cublas/#cublasltmatmul
// https://github.com/NVIDIA/CUDALibrarySamples/blob/master/cuBLASLt/LtSgemm/sample_cublasLt_LtSgemm.cu
void matmul_forward_cublaslt(float* out,
float* inp, float* weight, float* bias,
int B, int T, int C, int OC) {
int has_bias = (bias != NULL);
// check bias alignment
if(((uintptr_t)bias % 16) != 0) {
printf("Bias pointer is not aligned (cuBLASLt requirement)!\n");
exit(EXIT_FAILURE);
}
int returnedResults = 0;
cublasLtMatmulDesc_t operationDesc;
cublasLtMatmulPreference_t preference;
cublasLtMatrixLayout_t weightLayout;
cublasLtMatrixLayout_t inputLayout;
cublasLtMatrixLayout_t outputLayout;
cublasLtMatrixLayout_t biasLayout;
cublasLtMatmulHeuristicResult_t heuristic;
// create the operation descriptor
cublasOperation_t opNoTranspose = CUBLAS_OP_N;
cublasOperation_t opTranspose = CUBLAS_OP_T;
cublasLtEpilogue_t epilogueBias = CUBLASLT_EPILOGUE_BIAS;
cublasCheck(cublasLtMatmulDescCreate(&operationDesc, cublas_compute_type, CUDA_R_32F));
cublasCheck(cublasLtMatmulDescSetAttribute(operationDesc, CUBLASLT_MATMUL_DESC_TRANSA, &opTranspose, sizeof(opTranspose)));
cublasCheck(cublasLtMatmulDescSetAttribute(operationDesc, CUBLASLT_MATMUL_DESC_TRANSB, &opNoTranspose, sizeof(opNoTranspose)));
cublasCheck(cublasLtMatmulDescSetAttribute(operationDesc, CUBLASLT_MATMUL_DESC_EPILOGUE, &epilogueBias, sizeof(epilogueBias)));
cublasCheck(cublasLtMatmulDescSetAttribute(operationDesc, CUBLASLT_MATMUL_DESC_BIAS_POINTER, &bias, sizeof(bias)));
// define matrix layouts
cublasCheck(cublasLtMatrixLayoutCreate(&weightLayout, CUDA_R_32F, C, OC, C));
cublasCheck(cublasLtMatrixLayoutCreate(&inputLayout, CUDA_R_32F, C, B*T, C));
cublasCheck(cublasLtMatrixLayoutCreate(&outputLayout, CUDA_R_32F, OC, B*T, OC));
cublasCheck(cublasLtMatrixLayoutCreate(&biasLayout, CUDA_R_32F, OC, 1, OC));
// create a preference handle with specified max workspace
cublasCheck(cublasLtMatmulPreferenceCreate(&preference));
cublasCheck(cublasLtMatmulPreferenceSetAttribute(preference,
CUBLASLT_MATMUL_PREF_MAX_WORKSPACE_BYTES,
&cublaslt_workspace_size, sizeof(cublaslt_workspace_size)));
// find a suitable algorithm
cublasCheck(cublasLtMatmulAlgoGetHeuristic(cublaslt_handle, operationDesc,
weightLayout, inputLayout, outputLayout, outputLayout,
preference, 1, &heuristic, &returnedResults));
if (returnedResults == 0) {
printf("No cuBLASLt algorithm: B: %d, T: %d, C: %d, OC: %d, bias: %d\n", B, T, C, OC, has_bias);
exit(EXIT_FAILURE);
}
// call the matmul
const float alpha = 1.0f, beta = 0.0f;
cublasCheck(cublasLtMatmul(cublaslt_handle, operationDesc,
&alpha, weight, weightLayout, inp, inputLayout, &beta,
out, outputLayout, out, outputLayout, &heuristic.algo,
cublaslt_workspace, cublaslt_workspace_size, 0));
// cleanups
cublasCheck(cublasLtMatmulPreferenceDestroy(preference));
cublasCheck(cublasLtMatmulDescDestroy(operationDesc));
cublasCheck(cublasLtMatrixLayoutDestroy(weightLayout));
cublasCheck(cublasLtMatrixLayoutDestroy(inputLayout));
cublasCheck(cublasLtMatrixLayoutDestroy(outputLayout));
cublasCheck(cublasLtMatrixLayoutDestroy(biasLayout));
}
void attention_forward(float* out, float* vaccum, float* qkvr, float* preatt, float* att,
float* inp,
int B, int T, int C, int NH) {
const int block_size = 256;
const int softmax_block_size = 256;
// inp is (B, T, 3C) QKV
// preatt, att are (B, NH, T, T)
// output is (B, T, C)
int HS = C / NH; // head size
// permute and separate inp from (B, T, 3, NH, HS) to 3X (B, NH, T, HS)
float *q, *k, *v;
q = qkvr + 0 * B * T * C;
k = qkvr + 1 * B * T * C;
v = qkvr + 2 * B * T * C;
int total_threads = B * NH * T * HS;
int num_blocks = CEIL_DIV(total_threads, block_size);
permute_kernel<<<num_blocks, block_size>>>(q, k, v, inp, B, T, NH, HS);
cudaCheck(cudaGetLastError());
// batched matrix multiply with cuBLAS
const float alpha = 1.0f;
const float beta = 0.0f;
cublasCheck(cublasSgemmStridedBatched(cublas_handle,
CUBLAS_OP_T, CUBLAS_OP_N,
T, T, HS,
&alpha,
k, HS, T * HS,
q, HS, T * HS,
&beta,
preatt, T, T * T,
B * NH));
// multiply all elements of preatt elementwise by scale
float scale = 1.0 / sqrtf(HS);
int grid_size = CEIL_DIV(B * NH * T * 32, softmax_block_size);
softmax_forward_kernel5<<<grid_size, softmax_block_size>>>(att, scale, preatt, B * NH, T);
cudaCheck(cudaGetLastError());
// new approach: first cuBLAS another batched matmul
// y = att @ v # (B, nh, T, T) @ (B, nh, T, hs) -> (B, nh, T, hs)
cublasCheck(cublasSgemmStridedBatched(cublas_handle,
CUBLAS_OP_N, CUBLAS_OP_N,
HS, T, T,
&alpha,
v, HS, T * HS,
att, T, T * T,
&beta,
vaccum, HS, T * HS,
B * NH));
// now unpermute
// y = y.transpose(1, 2).contiguous().view(B, T, C) # re-assemble all head outputs side by side
num_blocks = CEIL_DIV(B * T * C, block_size);
unpermute_kernel<<<num_blocks, block_size>>>(vaccum, out, B, T, NH, HS);
cudaCheck(cudaGetLastError());
}
void residual_forward(float* out, float* inp1, float* inp2, int N) {
const int block_size = 256;
const int grid_size = CEIL_DIV(N, block_size);
residual_forward_kernel<<<grid_size, block_size>>>(out, inp1, inp2, N);
cudaCheck(cudaGetLastError());
}
void residual_backward(float* dinp1, float* dinp2, float* dout, int N) {
const int block_size = 256;
const int grid_size = CEIL_DIV(N, block_size);
residual_backward_kernel<<<grid_size, block_size>>>(dinp1, dinp2, dout, N);
cudaCheck(cudaGetLastError());
}
void gelu_forward(float* out, const float* inp, int N) {
const int block_size = 128;
const int grid_size = CEIL_DIV(N, block_size);
gelu_forward_kernel<<<grid_size, block_size>>>(out, inp, N);
cudaCheck(cudaGetLastError());
}
void gelu_backward(float* dinp, const float* inp, const float* dout, const int N) {
const int block_size = 128;
const int grid_size = CEIL_DIV(N, block_size);
gelu_backward_kernel<<<grid_size, block_size>>>(dinp, inp, dout, N);
cudaCheck(cudaGetLastError());
}
void softmax_forward(float* out, float* inp, int N, int C) {
int grid_size = N;
const int block_size = 512;
size_t shared_mem_size = 2 * block_size / 32 * sizeof(float);
softmax_forward_kernel7<<<grid_size, block_size, shared_mem_size>>>(out, inp, N, C);
cudaCheck(cudaGetLastError());
}
void crossentropy_forward(float* losses,
float* probs, int* targets,
int B, int T, int V) {
const int block_size = 128;
const int N = B * T;
const int grid_size = CEIL_DIV(N, block_size);
crossentropy_forward_kernel1<<<grid_size, block_size>>>(losses, probs, targets, B, T, V);
cudaCheck(cudaGetLastError());
}
void crossentropy_softmax_backward(float* dlogits,
const float* dlosses, const float* probs, const int* targets,
int B, int T, int V) {
const int block_size = 256;
const int N = B * T * V;
const int grid_size = CEIL_DIV(N, block_size);
crossentropy_softmax_backward_kernel1<<<grid_size, block_size>>>(dlogits, dlosses, probs, targets, B, T, V);
cudaCheck(cudaGetLastError());
}
void matmul_backward(float* dinp, float* dweight, float* dbias,
float* dout, float* inp, float* weight,
int B, int T, int C, int OC) {
float alpha = 1.0f;
float beta = 1.0f; // note we must use beta = 1.0 so that we do a +=, as we should, because gradients add
// backward to input
cublasCheck(cublasSgemm(cublas_handle, CUBLAS_OP_N, CUBLAS_OP_N, C, B*T, OC, &alpha, weight, C, dout, OC, &beta, dinp, C));
// backward to weight
cublasCheck(cublasSgemm(cublas_handle, CUBLAS_OP_N, CUBLAS_OP_T, C, OC, B*T, &alpha, inp, C, dout, OC, &beta, dweight, C));
// backward to bias, if given
if (dbias != NULL) {
const int block_size=512;
dim3 block_dim(block_size);
dim3 grid_dim(OC);
size_t shared_mem_size = block_size * sizeof(float);
matmul_backward_bias_kernel_faster<<<grid_dim, block_dim, shared_mem_size>>>(dbias, dout, B, T, OC);
cudaCheck(cudaGetLastError());
}
}
void layernorm_backward(float* dinp, float* dweight, float* dbias,
float* dout, float* inp, float* weight, float* mean, float* rstd,
int B, int T, int C) {
const int block_size = 256;
const int N = B * T;
// one warp per token, so we need to divide by 32 here.
const int grid_size = CEIL_DIV(N, block_size / 32);
layernorm_backward_kernel<<<grid_size, block_size>>>(dinp, dweight, dbias, dout, inp, weight, mean, rstd, B, T, C);
cudaCheck(cudaGetLastError());
}
// the sequence of transformations in this compound op is:
// inp (B,T,3C) -> qkvr (B,T,3C) -> preatt (B,NH,T,T) -> att (B,NH,T,T) -> vaccum (B,T,C) -> out (B,T,C)
void attention_backward(float* dinp, float* dqkvr, float* dpreatt, float* datt, float* dvaccum,
const float* dout,
const float* inp, const float* qkvr, const float* preatt, const float* att, const float* vaccum,
int B, int T, int C, int NH) {
const int block_size = 256;
int HS = C / NH; // head size
const float alpha = 1.0f;
const float beta = 1.0f; // note beta = 1.0f so that we accumulate gradients (+=)