#include "cuda_runtime.h" #include "curand.h" #include "cublas_v2.h" #include extern "C" { #include "blas.h" #include "cuda.h" #include "utils.h" } __global__ void scale_bias_kernel(float *output, float *biases, int n, int size) { int offset = blockIdx.x * blockDim.x + threadIdx.x; int filter = blockIdx.y; int batch = blockIdx.z; if(offset < size) output[(batch*n+filter)*size + offset] *= biases[filter]; } void scale_bias_gpu(float *output, float *biases, int batch, int n, int size) { dim3 dimGrid((size-1)/BLOCK + 1, n, batch); dim3 dimBlock(BLOCK, 1, 1); scale_bias_kernel<<>>(output, biases, n, size); check_error(cudaPeekAtLastError()); } __global__ void backward_scale_kernel(float *x_norm, float *delta, int batch, int n, int size, float *scale_updates) { __shared__ float part[BLOCK]; int i,b; int filter = blockIdx.x; int p = threadIdx.x; float sum = 0; for(b = 0; b < batch; ++b){ for(i = 0; i < size; i += BLOCK){ int index = p + i + size*(filter + n*b); sum += (p+i < size) ? delta[index]*x_norm[index] : 0; } } part[p] = sum; __syncthreads(); if (p == 0) { for(i = 0; i < BLOCK; ++i) scale_updates[filter] += part[i]; } } void backward_scale_gpu(float *x_norm, float *delta, int batch, int n, int size, float *scale_updates) { backward_scale_kernel<<>>(x_norm, delta, batch, n, size, scale_updates); check_error(cudaPeekAtLastError()); } __global__ void add_bias_kernel(float *output, float *biases, int batch, int n, int size) { int index = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if (index >= n*size*batch) return; int i = index % size; index /= size; int j = index % n; index /= n; int k = index; output[(k*n+j)*size + i] += biases[j]; } void add_bias_gpu(float *output, float *biases, int batch, int n, int size) { int num = n*size*batch; add_bias_kernel<<>>(output, biases, batch, n, size); check_error(cudaPeekAtLastError()); } __global__ void backward_bias_conn_kernel(float *bias_updates, float *delta, int batch, int n) { int index = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if (index >= n) return; int b; float sum = 0; for(b = 0; b < batch; ++b){ int i = b*n + index; sum += delta[i]; } bias_updates[index] += sum; } __global__ void backward_bias_kernel(float *bias_updates, float *delta, int batch, int n, int size) { __shared__ float part[BLOCK]; int i,b; int filter = blockIdx.x; int p = threadIdx.x; float sum = 0; for(b = 0; b < batch; ++b){ for(i = 0; i < size; i += BLOCK){ int index = p + i + size*(filter + n*b); sum += (p+i < size) ? delta[index] : 0; } } part[p] = sum; __syncthreads(); if (p == 0) { for(i = 0; i < BLOCK; ++i) bias_updates[filter] += part[i]; } } void backward_bias_gpu(float *bias_updates, float *delta, int batch, int n, int size) { if(size == 1){ backward_bias_conn_kernel<<>>(bias_updates, delta, batch, n); }else{ backward_bias_kernel<<>>(bias_updates, delta, batch, n, size); } check_error(cudaPeekAtLastError()); } /* __global__ void dot_kernel(float *output, float scale, int batch, int n, int size, float *delta) { int index = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; int f1 = index / n; int f2 = index % n; if (f2 <= f1) return; float sum = 0; float norm1 = 0; float norm2 = 0; int b, i; for(b = 0; b < batch; ++b){ for(i = 0; i < size; ++i){ int i1 = b * size * n + f1 * size + i; int i2 = b * size * n + f2 * size + i; sum += output[i1] * output[i2]; norm1 += output[i1] * output[i1]; norm2 += output[i2] * output[i2]; } } norm1 = sqrt(norm1); norm2 = sqrt(norm2); float norm = norm1 * norm2; sum = sum / norm; for(b = 0; b < batch; ++b){ for(i = 0; i < size; ++i){ int i1 = b * size * n + f1 * size + i; int i2 = b * size * n + f2 * size + i; delta[i1] += - scale * sum * output[i2] / norm; delta[i2] += - scale * sum * output[i1] / norm; } } } void dot_error_gpu(layer l) { dot_kernel<<>>(l.output_gpu, l.dot, l.batch, l.n, l.out_w * l.out_h, l.delta_gpu); check_error(cudaPeekAtLastError()); } */ __global__ void adam_kernel(int N, float *x, float *m, float *v, float B1, float B2, float rate, float eps, int t) { int index = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if (index >= N) return; float mhat = m[index] / (1.f - powf(B1, t)); float vhat = v[index] / (1.f - powf(B2, t)); x[index] = x[index] + rate * mhat / (sqrtf(vhat) + eps); } extern "C" void adam_gpu(int n, float *x, float *m, float *v, float B1, float B2, float rate, float eps, int t) { adam_kernel<<>>(n, x, m, v, B1, B2, rate, eps, t); check_error(cudaPeekAtLastError()); } extern "C" void adam_update_gpu(float *w, float *d, float *m, float *v, float B1, float B2, float eps, float decay, float rate, int n, int batch, int t) { scal_gpu(n, B1, m, 1); scal_gpu(n, B2, v, 1); axpy_gpu(n, -decay*batch, w, 1, d, 1); axpy_gpu(n, (1-B1), d, 1, m, 1); mul_gpu(n, d, 1, d, 1); axpy_gpu(n, (1-B2), d, 1, v, 1); adam_gpu(n, w, m, v, B1, B2, rate, eps, t); fill_gpu(n, 0, d, 1); } __global__ void normalize_kernel(int N, float *x, float *mean, float *variance, int batch, int filters, int spatial) { int index = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if (index >= N) return; int f = (index/spatial)%filters; x[index] = (x[index] - mean[f])/(sqrtf(variance[f] + .00001f)); } __global__ void normalize_delta_kernel(int N, float *x, float *mean, float *variance, float *mean_delta, float *variance_delta, int batch, int filters, int spatial, float *delta) { int index = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if (index >= N) return; int f = (index/spatial)%filters; delta[index] = delta[index] * 1.f/(sqrtf(variance[f] + .00001f)) + variance_delta[f] * 2.f * (x[index] - mean[f]) / (spatial * batch) + mean_delta[f]/(spatial*batch); } extern "C" void normalize_delta_gpu(float *x, float *mean, float *variance, float *mean_delta, float *variance_delta, int batch, int filters, int spatial, float *delta) { size_t N = batch*filters*spatial; normalize_delta_kernel<<>>(N, x, mean, variance, mean_delta, variance_delta, batch, filters, spatial, delta); check_error(cudaPeekAtLastError()); } __global__ void variance_delta_kernel(float *x, float *delta, float *mean, float *variance, int batch, int filters, int spatial, float *variance_delta) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if (i >= filters) return; int j,k; variance_delta[i] = 0; for(j = 0; j < batch; ++j){ for(k = 0; k < spatial; ++k){ int index = j*filters*spatial + i*spatial + k; variance_delta[i] += delta[index]*(x[index] - mean[i]); } } variance_delta[i] *= -.5f * powf(variance[i] + .00001f, (float)(-3.f/2.f)); } __global__ void accumulate_kernel(float *x, int n, int groups, float *sum) { int k; int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if (i >= groups) return; sum[i] = 0; for(k = 0; k < n; ++k){ sum[i] += x[k*groups + i]; } } __global__ void fast_mean_delta_kernel(float *delta, float *variance, int batch, int filters, int spatial, float *mean_delta) { const int threads = BLOCK; __shared__ float local[threads]; int id = threadIdx.x; local[id] = 0; int filter = blockIdx.x; int i, j; for(j = 0; j < batch; ++j){ for(i = 0; i < spatial; i += threads){ int index = j*spatial*filters + filter*spatial + i + id; local[id] += (i+id < spatial) ? delta[index] : 0; } } __syncthreads(); if(id == 0){ mean_delta[filter] = 0; for(i = 0; i < threads; ++i){ mean_delta[filter] += local[i]; } mean_delta[filter] *= (-1.f/sqrtf(variance[filter] + .00001f)); } } __global__ void fast_variance_delta_kernel(float *x, float *delta, float *mean, float *variance, int batch, int filters, int spatial, float *variance_delta) { const int threads = BLOCK; __shared__ float local[threads]; int id = threadIdx.x; local[id] = 0; int filter = blockIdx.x; int i, j; for(j = 0; j < batch; ++j){ for(i = 0; i < spatial; i += threads){ int index = j*spatial*filters + filter*spatial + i + id; local[id] += (i+id < spatial) ? delta[index]*(x[index] - mean[filter]) : 0; } } __syncthreads(); if(id == 0){ variance_delta[filter] = 0; for(i = 0; i < threads; ++i){ variance_delta[filter] += local[i]; } variance_delta[filter] *= -.5f * powf(variance[filter] + .00001f, (float)(-3.f/2.f)); } } __global__ void mean_delta_kernel(float *delta, float *variance, int batch, int filters, int spatial, float *mean_delta) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if (i >= filters) return; int j,k; mean_delta[i] = 0; for (j = 0; j < batch; ++j) { for (k = 0; k < spatial; ++k) { int index = j*filters*spatial + i*spatial + k; mean_delta[i] += delta[index]; } } mean_delta[i] *= (-1.f/sqrtf(variance[i] + .00001f)); } extern "C" void mean_delta_gpu(float *delta, float *variance, int batch, int filters, int spatial, float *mean_delta) { mean_delta_kernel<<>>(delta, variance, batch, filters, spatial, mean_delta); check_error(cudaPeekAtLastError()); } extern "C" void fast_mean_delta_gpu(float *delta, float *variance, int batch, int filters, int spatial, float *mean_delta) { fast_mean_delta_kernel<<>>(delta, variance, batch, filters, spatial, mean_delta); check_error(cudaPeekAtLastError()); } extern "C" void fast_variance_delta_gpu(float *x, float *delta, float *mean, float *variance, int batch, int filters, int spatial, float *variance_delta) { fast_variance_delta_kernel<<>>(x, delta, mean, variance, batch, filters, spatial, variance_delta); check_error(cudaPeekAtLastError()); } __global__ void mean_kernel(float *x, int batch, int filters, int spatial, float *mean) { float scale = 1.f/(batch * spatial); int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if (i >= filters) return; int j,k; mean[i] = 0; for(j = 0; j < batch; ++j){ for(k = 0; k < spatial; ++k){ int index = j*filters*spatial + i*spatial + k; mean[i] += x[index]; } } mean[i] *= scale; } __global__ void variance_kernel(float *x, float *mean, int batch, int filters, int spatial, float *variance) { float scale = 1.f/(batch * spatial - 1); int j,k; int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if (i >= filters) return; variance[i] = 0; for(j = 0; j < batch; ++j){ for(k = 0; k < spatial; ++k){ int index = j*filters*spatial + i*spatial + k; variance[i] += powf((x[index] - mean[i]), 2); } } variance[i] *= scale; } __global__ void reorg_kernel(int N, float *x, int w, int h, int c, int batch, int stride, int forward, float *out) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i >= N) return; int in_index = i; int in_w = i%w; i = i/w; int in_h = i%h; i = i/h; int in_c = i%c; i = i/c; int b = i%batch; int out_c = c/(stride*stride); int c2 = in_c % out_c; int offset = in_c / out_c; int w2 = in_w*stride + offset % stride; int h2 = in_h*stride + offset / stride; //printf("%d\n", offset); int out_index = w2 + w*stride*(h2 + h*stride*(c2 + out_c*b)); // printf("%d %d %d\n", w2, h2, c2); //printf("%d %d\n", in_index, out_index); //if(out_index >= N || out_index < 0) printf("bad bad bad \n"); if(forward) out[out_index] = x[in_index]; else out[in_index] = x[out_index]; //if(forward) out[1] = x[1]; //else out[0] = x[0]; } __global__ void axpy_kernel(int N, float ALPHA, float *X, int OFFX, int INCX, float *Y, int OFFY, int INCY) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < N) Y[OFFY+i*INCY] += ALPHA*X[OFFX+i*INCX]; } __global__ void pow_kernel(int N, float ALPHA, float *X, int INCX, float *Y, int INCY) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < N) Y[i*INCY] = pow(X[i*INCX], ALPHA); } __global__ void const_kernel(int N, float ALPHA, float *X, int INCX) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < N) X[i*INCX] = ALPHA; } __global__ void constrain_kernel(int N, float ALPHA, float *X, int INCX) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < N) X[i*INCX] = fminf(ALPHA, fmaxf(-ALPHA, X[i*INCX])); } __global__ void supp_kernel(int N, float ALPHA, float *X, int INCX) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < N) { if((X[i*INCX] * X[i*INCX]) < (ALPHA * ALPHA)) X[i*INCX] = 0; } } __global__ void add_kernel(int N, float ALPHA, float *X, int INCX) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < N) X[i*INCX] += ALPHA; } __global__ void scal_kernel(int N, float ALPHA, float *X, int INCX) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < N) X[i*INCX] *= ALPHA; } __global__ void fill_kernel(int N, float ALPHA, float *X, int INCX) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < N) X[i*INCX] = ALPHA; } __global__ void copy_kernel(int N, float *X, int OFFX, int INCX, float *Y, int OFFY, int INCY) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < N) Y[i*INCY + OFFY] = X[i*INCX + OFFX]; } __global__ void mul_kernel(int N, float *X, int INCX, float *Y, int INCY) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < N) Y[i*INCY] *= X[i*INCX]; } extern "C" void normalize_gpu(float *x, float *mean, float *variance, int batch, int filters, int spatial) { size_t N = batch*filters*spatial; normalize_kernel<<>>(N, x, mean, variance, batch, filters, spatial); check_error(cudaPeekAtLastError()); } __global__ void l2norm_kernel(int N, float *x, float *dx, int batch, int filters, int spatial) { int index = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if (index >= N) return; int b = index / spatial; int i = index % spatial; int f; float sum = 0; for(f = 0; f < filters; ++f){ int index = b*filters*spatial + f*spatial + i; sum += powf(x[index], 2); } sum = sqrtf(sum); if(sum == 0) sum = 1; //printf("%f\n", sum); for(f = 0; f < filters; ++f){ int index = b*filters*spatial + f*spatial + i; x[index] /= sum; dx[index] = (1 - x[index]) / sum; } } extern "C" void l2normalize_gpu(float *x, float *dx, int batch, int filters, int spatial) { size_t N = batch*spatial; l2norm_kernel<<>>(N, x, dx, batch, filters, spatial); check_error(cudaPeekAtLastError()); } __global__ void fast_mean_kernel(float *x, int batch, int filters, int spatial, float *mean) { const int threads = BLOCK; __shared__ float local[threads]; int id = threadIdx.x; local[id] = 0; int filter = blockIdx.x; int i, j; for(j = 0; j < batch; ++j){ for(i = 0; i < spatial; i += threads){ int index = j*spatial*filters + filter*spatial + i + id; local[id] += (i+id < spatial) ? x[index] : 0; } } __syncthreads(); if(id == 0){ mean[filter] = 0; for(i = 0; i < threads; ++i){ mean[filter] += local[i]; } mean[filter] /= spatial * batch; } } __global__ void fast_variance_kernel(float *x, float *mean, int batch, int filters, int spatial, float *variance) { const int threads = BLOCK; __shared__ float local[threads]; int id = threadIdx.x; local[id] = 0; int filter = blockIdx.x; int i, j; for(j = 0; j < batch; ++j){ for(i = 0; i < spatial; i += threads){ int index = j*spatial*filters + filter*spatial + i + id; local[id] += (i+id < spatial) ? powf((x[index] - mean[filter]), 2) : 0; } } __syncthreads(); if(id == 0){ variance[filter] = 0; for(i = 0; i < threads; ++i){ variance[filter] += local[i]; } variance[filter] /= (spatial * batch - 1); } } extern "C" void fast_mean_gpu(float *x, int batch, int filters, int spatial, float *mean) { fast_mean_kernel<<>>(x, batch, filters, spatial, mean); check_error(cudaPeekAtLastError()); } extern "C" void fast_variance_gpu(float *x, float *mean, int batch, int filters, int spatial, float *variance) { fast_variance_kernel<<>>(x, mean, batch, filters, spatial, variance); check_error(cudaPeekAtLastError()); } extern "C" void mean_gpu(float *x, int batch, int filters, int spatial, float *mean) { mean_kernel<<>>(x, batch, filters, spatial, mean); check_error(cudaPeekAtLastError()); } extern "C" void variance_gpu(float *x, float *mean, int batch, int filters, int spatial, float *variance) { variance_kernel<<>>(x, mean, batch, filters, spatial, variance); check_error(cudaPeekAtLastError()); } extern "C" void axpy_gpu(int N, float ALPHA, float * X, int INCX, float * Y, int INCY) { axpy_gpu_offset(N, ALPHA, X, 0, INCX, Y, 0, INCY); } extern "C" void pow_gpu(int N, float ALPHA, float * X, int INCX, float * Y, int INCY) { pow_kernel<<>>(N, ALPHA, X, INCX, Y, INCY); check_error(cudaPeekAtLastError()); } extern "C" void axpy_gpu_offset(int N, float ALPHA, float * X, int OFFX, int INCX, float * Y, int OFFY, int INCY) { axpy_kernel<<>>(N, ALPHA, X, OFFX, INCX, Y, OFFY, INCY); check_error(cudaPeekAtLastError()); } extern "C" void copy_gpu(int N, float * X, int INCX, float * Y, int INCY) { copy_gpu_offset(N, X, 0, INCX, Y, 0, INCY); } extern "C" void mul_gpu(int N, float * X, int INCX, float * Y, int INCY) { mul_kernel<<>>(N, X, INCX, Y, INCY); check_error(cudaPeekAtLastError()); } extern "C" void copy_gpu_offset(int N, float * X, int OFFX, int INCX, float * Y, int OFFY, int INCY) { copy_kernel<<>>(N, X, OFFX, INCX, Y, OFFY, INCY); check_error(cudaPeekAtLastError()); } __global__ void flatten_kernel(int N, float *x, int spatial, int layers, int batch, int forward, float *out) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i >= N) return; int in_s = i%spatial; i = i/spatial; int in_c = i%layers; i = i/layers; int b = i; int i1 = b*layers*spatial + in_c*spatial + in_s; int i2 = b*layers*spatial + in_s*layers + in_c; if (forward) out[i2] = x[i1]; else out[i1] = x[i2]; } extern "C" void flatten_gpu(float *x, int spatial, int layers, int batch, int forward, float *out) { int size = spatial*batch*layers; flatten_kernel<<>>(size, x, spatial, layers, batch, forward, out); check_error(cudaPeekAtLastError()); } extern "C" void reorg_gpu(float *x, int w, int h, int c, int batch, int stride, int forward, float *out) { int size = w*h*c*batch; reorg_kernel<<>>(size, x, w, h, c, batch, stride, forward, out); check_error(cudaPeekAtLastError()); } __global__ void mask_kernel(int n, float *x, float mask_num, float *mask, float val) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < n && mask[i] == mask_num) x[i] = val; } extern "C" void mask_gpu(int N, float * X, float mask_num, float * mask, float val) { mask_kernel<<>>(N, X, mask_num, mask, val); check_error(cudaPeekAtLastError()); } __global__ void scale_mask_kernel(int n, float *x, float mask_num, float *mask, float scale) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < n && mask[i] == mask_num) x[i] *= scale; } extern "C" void scale_mask_gpu(int N, float * X, float mask_num, float * mask, float scale) { scale_mask_kernel<<>>(N, X, mask_num, mask, scale); check_error(cudaPeekAtLastError()); } extern "C" void const_gpu(int N, float ALPHA, float * X, int INCX) { const_kernel<<>>(N, ALPHA, X, INCX); check_error(cudaPeekAtLastError()); } extern "C" void constrain_gpu(int N, float ALPHA, float * X, int INCX) { constrain_kernel<<>>(N, ALPHA, X, INCX); check_error(cudaPeekAtLastError()); } extern "C" void add_gpu(int N, float ALPHA, float * X, int INCX) { add_kernel<<>>(N, ALPHA, X, INCX); check_error(cudaPeekAtLastError()); } extern "C" void scal_gpu(int N, float ALPHA, float * X, int INCX) { scal_kernel<<>>(N, ALPHA, X, INCX); check_error(cudaPeekAtLastError()); } extern "C" void supp_gpu(int N, float ALPHA, float * X, int INCX) { supp_kernel<<>>(N, ALPHA, X, INCX); check_error(cudaPeekAtLastError()); } extern "C" void fill_gpu(int N, float ALPHA, float * X, int INCX) { fill_kernel<<>>(N, ALPHA, X, INCX); check_error(cudaPeekAtLastError()); } __global__ void shortcut_kernel(int size, int minw, int minh, int minc, int stride, int sample, int batch, int w1, int h1, int c1, float *add, int w2, int h2, int c2, float s1, float s2, float *out) { int id = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if (id >= size) return; int i = id % minw; id /= minw; int j = id % minh; id /= minh; int k = id % minc; id /= minc; int b = id % batch; int out_index = i*sample + w2*(j*sample + h2*(k + c2*b)); int add_index = i*stride + w1*(j*stride + h1*(k + c1*b)); out[out_index] = s1*out[out_index] + s2*add[add_index]; //out[out_index] += add[add_index]; } extern "C" void shortcut_gpu(int batch, int w1, int h1, int c1, float *add, int w2, int h2, int c2, float s1, float s2, float *out) { int minw = (w1 < w2) ? w1 : w2; int minh = (h1 < h2) ? h1 : h2; int minc = (c1 < c2) ? c1 : c2; int stride = w1/w2; int sample = w2/w1; assert(stride == h1/h2); assert(sample == h2/h1); if(stride < 1) stride = 1; if(sample < 1) sample = 1; int size = batch * minw * minh * minc; shortcut_kernel<<>>(size, minw, minh, minc, stride, sample, batch, w1, h1, c1, add, w2, h2, c2, s1, s2, out); check_error(cudaPeekAtLastError()); } __global__ void smooth_l1_kernel(int n, float *pred, float *truth, float *delta, float *error) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < n){ float diff = truth[i] - pred[i]; float abs_val = fabsf(diff); if(abs_val < 1) { error[i] = diff * diff; delta[i] = diff; } else { error[i] = 2*abs_val - 1; delta[i] = (diff > 0) ? 1 : -1; } } } extern "C" void smooth_l1_gpu(int n, float *pred, float *truth, float *delta, float *error) { smooth_l1_kernel<<>>(n, pred, truth, delta, error); check_error(cudaPeekAtLastError()); } __global__ void softmax_x_ent_kernel(int n, float *pred, float *truth, float *delta, float *error) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < n){ float t = truth[i]; float p = pred[i]; error[i] = (t) ? -log(p) : 0; delta[i] = t-p; } } extern "C" void softmax_x_ent_gpu(int n, float *pred, float *truth, float *delta, float *error) { softmax_x_ent_kernel<<>>(n, pred, truth, delta, error); check_error(cudaPeekAtLastError()); } __global__ void logistic_x_ent_kernel(int n, float *pred, float *truth, float *delta, float *error) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < n){ float t = truth[i]; float p = pred[i]; error[i] = -t*log(p+.0000001) - (1-t)*log(1-p+.0000001); delta[i] = t-p; } } extern "C" void logistic_x_ent_gpu(int n, float *pred, float *truth, float *delta, float *error) { logistic_x_ent_kernel<<>>(n, pred, truth, delta, error); check_error(cudaPeekAtLastError()); } __global__ void l2_kernel(int n, float *pred, float *truth, float *delta, float *error) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < n){ float diff = truth[i] - pred[i]; error[i] = diff * diff; //I know this is technically wrong, deal with it. delta[i] = diff; } } extern "C" void l2_gpu(int n, float *pred, float *truth, float *delta, float *error) { l2_kernel<<>>(n, pred, truth, delta, error); check_error(cudaPeekAtLastError()); } __global__ void l1_kernel(int n, float *pred, float *truth, float *delta, float *error) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < n){ float diff = truth[i] - pred[i]; error[i] = abs(diff); delta[i] = (diff > 0) ? 1 : -1; } } extern "C" void l1_gpu(int n, float *pred, float *truth, float *delta, float *error) { l1_kernel<<>>(n, pred, truth, delta, error); check_error(cudaPeekAtLastError()); } __global__ void wgan_kernel(int n, float *pred, float *truth, float *delta, float *error) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < n){ error[i] = truth[i] ? -pred[i] : pred[i]; delta[i] = (truth[i] > 0) ? 1 : -1; } } extern "C" void wgan_gpu(int n, float *pred, float *truth, float *delta, float *error) { wgan_kernel<<>>(n, pred, truth, delta, error); check_error(cudaPeekAtLastError()); } __global__ void weighted_sum_kernel(int n, float *a, float *b, float *s, float *c) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < n){ c[i] = s[i]*a[i] + (1-s[i])*(b ? b[i] : 0); } } __global__ void deinter_kernel(int NX, float *X, int NY, float *Y, int B, float *OUT) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < (NX+NY)*B){ int b = i / (NX+NY); int j = i % (NX+NY); if (j < NX){ if(X) X[b*NX + j] += OUT[i]; } else { if(Y) Y[b*NY + j - NX] += OUT[i]; } } } extern "C" void deinter_gpu(int NX, float *X, int NY, float *Y, int B, float *OUT) { deinter_kernel<<>>(NX, X, NY, Y, B, OUT); check_error(cudaPeekAtLastError()); } __global__ void inter_kernel(int NX, float *X, int NY, float *Y, int B, float *OUT) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < (NX+NY)*B){ int b = i / (NX+NY); int j = i % (NX+NY); if (j < NX){ OUT[i] = X[b*NX + j]; } else { OUT[i] = Y[b*NY + j - NX]; } } } extern "C" void inter_gpu(int NX, float *X, int NY, float *Y, int B, float *OUT) { inter_kernel<<>>(NX, X, NY, Y, B, OUT); check_error(cudaPeekAtLastError()); } extern "C" void weighted_sum_gpu(float *a, float *b, float *s, int num, float *c) { weighted_sum_kernel<<>>(num, a, b, s, c); check_error(cudaPeekAtLastError()); } __global__ void weighted_delta_kernel(int n, float *a, float *b, float *s, float *da, float *db, float *ds, float *dc) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < n){ if(da) da[i] += dc[i] * s[i]; if(db) db[i] += dc[i] * (1-s[i]); ds[i] += dc[i] * (a[i] - b[i]); } } extern "C" void weighted_delta_gpu(float *a, float *b, float *s, float *da, float *db, float *ds, int num, float *dc) { weighted_delta_kernel<<>>(num, a, b, s, da, db, ds, dc); check_error(cudaPeekAtLastError()); } __global__ void mult_add_into_kernel(int n, float *a, float *b, float *c) { int i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i < n){ c[i] += a[i]*b[i]; } } extern "C" void mult_add_into_gpu(int num, float *a, float *b, float *c) { mult_add_into_kernel<<>>(num, a, b, c); check_error(cudaPeekAtLastError()); } __device__ void softmax_device(float *input, int n, float temp, int stride, float *output) { int i; float sum = 0; float largest = -INFINITY; for(i = 0; i < n; ++i){ int val = input[i*stride]; largest = (val>largest) ? val : largest; } for(i = 0; i < n; ++i){ float e = expf(input[i*stride]/temp - largest/temp); sum += e; output[i*stride] = e; } for(i = 0; i < n; ++i){ output[i*stride] /= sum; } } __global__ void softmax_tree_kernel(float *input, int spatial, int batch, int stride, float temp, float *output, int groups, int *group_size, int *group_offset) { int id = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if (id >= spatial*batch*groups) return; int s = id % spatial; id = id / spatial; int g = id % groups; int b = id / groups; int goff = group_offset[g]*spatial; int boff = b*stride; softmax_device(input + goff + boff + s, group_size[g], temp, spatial, output + goff + boff + s); } extern "C" void softmax_tree(float *input, int spatial, int batch, int stride, float temp, float *output, tree hier) { int *tree_groups_size = cuda_make_int_array(hier.group_size, hier.groups); int *tree_groups_offset = cuda_make_int_array(hier.group_offset, hier.groups); /* static int *tree_groups_size = 0; static int *tree_groups_offset = 0; if(!tree_groups_size){ tree_groups_size = cuda_make_int_array(hier.group_size, hier.groups); tree_groups_offset = cuda_make_int_array(hier.group_offset, hier.groups); } */ int num = spatial*batch*hier.groups; softmax_tree_kernel<<>>(input, spatial, batch, stride, temp, output, hier.groups, tree_groups_size, tree_groups_offset); check_error(cudaPeekAtLastError()); cuda_free((float *)tree_groups_size); cuda_free((float *)tree_groups_offset); } __global__ void softmax_kernel(float *input, int n, int batch, int batch_offset, int groups, int group_offset, int stride, float temp, float *output) { int id = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if (id >= batch*groups) return; int b = id / groups; int g = id % groups; softmax_device(input + b*batch_offset + g*group_offset, n, temp, stride, output + b*batch_offset + g*group_offset); } extern "C" void softmax_gpu(float *input, int n, int batch, int batch_offset, int groups, int group_offset, int stride, float temp, float *output) { softmax_kernel<<>>(input, n, batch, batch_offset, groups, group_offset, stride, temp, output); check_error(cudaPeekAtLastError()); } __global__ void upsample_kernel(size_t N, float *x, int w, int h, int c, int batch, int stride, int forward, float scale, float *out) { size_t i = (blockIdx.x + blockIdx.y*gridDim.x) * blockDim.x + threadIdx.x; if(i >= N) return; int out_index = i; int out_w = i%(w*stride); i = i/(w*stride); int out_h = i%(h*stride); i = i/(h*stride); int out_c = i%c; i = i/c; int b = i%batch; int in_w = out_w / stride; int in_h = out_h / stride; int in_c = out_c; int in_index = b*w*h*c + in_c*w*h + in_h*w + in_w; if(forward) out[out_index] += scale * x[in_index]; else atomicAdd(x+in_index, scale * out[out_index]); } extern "C" void upsample_gpu(float *in, int w, int h, int c, int batch, int stride, int forward, float scale, float *out) { size_t size = w*h*c*batch*stride*stride; upsample_kernel<<>>(size, in, w, h, c, batch, stride, forward, scale, out); check_error(cudaPeekAtLastError()); }