/* Kernels for crossentropy forward pass. Compile example: nvcc -O3 --use_fast_math -lcublas -lcublasLt crossentropy_forward.cu -o crossentropy_forward version 1 is a straight-forward port from CPU code to kernel, parallel over B,T ./crossentropy_forward 1 */ #include #include #include #include "common.h" // ---------------------------------------------------------------------------- // CPU code reference void crossentropy_forward_cpu(float* losses, const float* probs, const int* targets, int B, int T, int V) { // output: losses is (B,T) of the individual losses at each position // input: probs are (B,T,V) of the probabilities // input: targets is (B,T) of integers giving the correct index in logits for (int b = 0; b < B; b++) { for (int t = 0; t < T; t++) { // loss = -log(probs[target]) const float* probs_bt = probs + b * T * V + t * V; int ix = targets[b * T + t]; losses[b * T + t] = -logf(probs_bt[ix]); } } } // ---------------------------------------------------------------------------- // GPU kernels __global__ void crossentropy_forward_kernel1(float* losses, const float* probs, const 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; const float* probs_bt = probs + b * T * V + t * V; int ix = targets[b * T + t]; losses[b * T + t] = -logf(probs_bt[ix]); } } // ---------------------------------------------------------------------------- // kernel launcher void crossentropy_forward1(float* losses, const float* probs, const int* targets, int B, int T, int V, const int block_size) { const int N = B * T; const int grid_size = ceil_div(N, block_size); crossentropy_forward_kernel1<<>>(losses, probs, targets, B, T, V); cudaCheck(cudaGetLastError()); } // kernel version dispatch void crossentropy_forward(int kernel_num, float* losses, const float* probs, const int* targets, int B, int T, int V, const int block_size) { switch (kernel_num) { case 1: crossentropy_forward1(losses, probs, targets, B, T, V, block_size); break; default: printf("Invalid kernel number\n"); exit(1); } } // ---------------------------------------------------------------------------- int main(int argc, char **argv) { srand(0); int B = 8; int T = 1024; int V = 50257; int deviceIdx = 0; cudaCheck(cudaSetDevice(deviceIdx)); // create host memory of random numbers float* out = (float*)malloc(B * T * sizeof(float)); float* probs = make_random_float_01(B * T * V); int* targets = make_random_int(B * T, V); // move to GPU float* d_out; float* d_probs; int* d_targets; cudaCheck(cudaMalloc(&d_out, B * T * sizeof(float))); cudaCheck(cudaMalloc(&d_probs, B * T * V * sizeof(float))); cudaCheck(cudaMalloc(&d_targets, B * T * sizeof(int))); cudaCheck(cudaMemcpy(d_probs, probs, B * T * V * sizeof(float), cudaMemcpyHostToDevice)); cudaCheck(cudaMemcpy(d_targets, targets, B * T * sizeof(int), cudaMemcpyHostToDevice)); // read kernel_num from command line int kernel_num = 1; if (argc > 1) { kernel_num = atoi(argv[1]); } printf("Using kernel %d\n", kernel_num); // first check the correctness of the kernel crossentropy_forward_cpu(out, probs, targets, B, T, V); // time the kernel at different block sizes int block_sizes[] = {32, 64, 128, 256, 512, 1024}; for (int j = 0; j < sizeof(block_sizes) / sizeof(int); j++) { int block_size = block_sizes[j]; printf("Checking block size %d.\n", block_size); crossentropy_forward(kernel_num, d_out, d_probs, d_targets, B, T, V, block_size); validate_result(d_out, out, "out", B * T, 1e-5f); } printf("All results match. Starting benchmarks.\n\n"); for (int j = 0; j < sizeof(block_sizes) / sizeof(int); j++) { int block_size = block_sizes[j]; int repeat_times = 1000; float elapsed_time = benchmark_kernel(repeat_times, crossentropy_forward, kernel_num, d_out, d_probs, d_targets, B, T, V, block_size); printf("block_size %4d | time %.4f ms | per token %.2f ns\n", block_size, elapsed_time, elapsed_time * 1'000'000 / (B*T)); } // free memory free(out); free(probs); free(targets); cudaCheck(cudaFree(d_out)); cudaCheck(cudaFree(d_probs)); cudaCheck(cudaFree(d_targets)); return 0; }