/* * Copyright (C) 2013 Wei Gao * Copyright (C) 2013 Lenny Wang * * This file is part of FFmpeg. * * FFmpeg is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * FFmpeg is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with FFmpeg; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ #ifndef AVFILTER_UNSHARP_OPENCL_KERNEL_H #define AVFILTER_UNSHARP_OPENCL_KERNEL_H #include "libavutil/opencl.h" const char *ff_kernel_unsharp_opencl = AV_OPENCL_KERNEL( inline unsigned char clip_uint8(int a) { if (a & (~0xFF)) return (-a)>>31; else return a; } kernel void unsharp_luma( global unsigned char *src, global unsigned char *dst, global int *mask_x, global int *mask_y, int amount, int scalebits, int halfscale, int src_stride, int dst_stride, int width, int height) { int2 threadIdx, blockIdx, globalIdx; threadIdx.x = get_local_id(0); threadIdx.y = get_local_id(1); blockIdx.x = get_group_id(0); blockIdx.y = get_group_id(1); globalIdx.x = get_global_id(0); globalIdx.y = get_global_id(1); if (!amount) { if (globalIdx.x < width && globalIdx.y < height) dst[globalIdx.x + globalIdx.y*dst_stride] = src[globalIdx.x + globalIdx.y*src_stride]; return; } local unsigned int l[32][32]; local unsigned int lcx[LU_RADIUS_X]; local unsigned int lcy[LU_RADIUS_Y]; int indexIx, indexIy, i, j; //load up tile: actual workspace + halo of 8 points in x and y \n for(i = 0; i <= 1; i++) { indexIy = -8 + (blockIdx.y + i) * 16 + threadIdx.y; indexIy = indexIy < 0 ? 0 : indexIy; indexIy = indexIy >= height ? height - 1: indexIy; for(j = 0; j <= 1; j++) { indexIx = -8 + (blockIdx.x + j) * 16 + threadIdx.x; indexIx = indexIx < 0 ? 0 : indexIx; indexIx = indexIx >= width ? width - 1: indexIx; l[i*16 + threadIdx.y][j*16 + threadIdx.x] = src[indexIy*src_stride + indexIx]; } } int indexL = threadIdx.y*16 + threadIdx.x; if (indexL < LU_RADIUS_X) lcx[indexL] = mask_x[indexL]; if (indexL < LU_RADIUS_Y) lcy[indexL] = mask_y[indexL]; barrier(CLK_LOCAL_MEM_FENCE); //needed for unsharp mask application in the end \n int orig_value = (int)l[threadIdx.y + 8][threadIdx.x + 8]; int idx, idy, maskIndex; int temp[2] = {0}; int steps_x = (LU_RADIUS_X-1)/2; int steps_y = (LU_RADIUS_Y-1)/2; // compute the actual workspace + left&right halos \n \n#pragma unroll\n for (j = 0; j <=1; j++) { //extra work to cover left and right halos \n idx = 16*j + threadIdx.x; \n#pragma unroll\n for (i = -steps_y; i <= steps_y; i++) { idy = 8 + i + threadIdx.y; maskIndex = (i + steps_y); temp[j] += (int)l[idy][idx] * lcy[maskIndex]; } } barrier(CLK_LOCAL_MEM_FENCE); //save results from the vertical filter in local memory \n idy = 8 + threadIdx.y; \n#pragma unroll\n for (j = 0; j <=1; j++) { idx = 16*j + threadIdx.x; l[idy][idx] = temp[j]; } barrier(CLK_LOCAL_MEM_FENCE); //compute results with the horizontal filter \n int sum = 0; idy = 8 + threadIdx.y; \n#pragma unroll\n for (j = -steps_x; j <= steps_x; j++) { idx = 8 + j + threadIdx.x; maskIndex = j + steps_x; sum += (int)l[idy][idx] * lcx[maskIndex]; } int res = orig_value + (((orig_value - (int)((sum + halfscale) >> scalebits)) * amount) >> 16); if (globalIdx.x < width && globalIdx.y < height) dst[globalIdx.x + globalIdx.y*dst_stride] = clip_uint8(res); } kernel void unsharp_chroma( global unsigned char *src_y, global unsigned char *dst_y, global int *mask_x, global int *mask_y, int amount, int scalebits, int halfscale, int src_stride_lu, int src_stride_ch, int dst_stride_lu, int dst_stride_ch, int width, int height, int cw, int ch) { global unsigned char *dst_u = dst_y + height * dst_stride_lu; global unsigned char *dst_v = dst_u + ch * dst_stride_ch; global unsigned char *src_u = src_y + height * src_stride_lu; global unsigned char *src_v = src_u + ch * src_stride_ch; int2 threadIdx, blockIdx, globalIdx; threadIdx.x = get_local_id(0); threadIdx.y = get_local_id(1); blockIdx.x = get_group_id(0); blockIdx.y = get_group_id(1); globalIdx.x = get_global_id(0); globalIdx.y = get_global_id(1); int padch = get_global_size(1)/2; global unsigned char *src = globalIdx.y>=padch ? src_v : src_u; global unsigned char *dst = globalIdx.y>=padch ? dst_v : dst_u; blockIdx.y = globalIdx.y>=padch ? blockIdx.y - get_num_groups(1)/2 : blockIdx.y; globalIdx.y = globalIdx.y>=padch ? globalIdx.y - padch : globalIdx.y; if (!amount) { if (globalIdx.x < cw && globalIdx.y < ch) dst[globalIdx.x + globalIdx.y*dst_stride_ch] = src[globalIdx.x + globalIdx.y*src_stride_ch]; return; } local unsigned int l[32][32]; local unsigned int lcx[CH_RADIUS_X]; local unsigned int lcy[CH_RADIUS_Y]; int indexIx, indexIy, i, j; for(i = 0; i <= 1; i++) { indexIy = -8 + (blockIdx.y + i) * 16 + threadIdx.y; indexIy = indexIy < 0 ? 0 : indexIy; indexIy = indexIy >= ch ? ch - 1: indexIy; for(j = 0; j <= 1; j++) { indexIx = -8 + (blockIdx.x + j) * 16 + threadIdx.x; indexIx = indexIx < 0 ? 0 : indexIx; indexIx = indexIx >= cw ? cw - 1: indexIx; l[i*16 + threadIdx.y][j*16 + threadIdx.x] = src[indexIy * src_stride_ch + indexIx]; } } int indexL = threadIdx.y*16 + threadIdx.x; if (indexL < CH_RADIUS_X) lcx[indexL] = mask_x[indexL]; if (indexL < CH_RADIUS_Y) lcy[indexL] = mask_y[indexL]; barrier(CLK_LOCAL_MEM_FENCE); int orig_value = (int)l[threadIdx.y + 8][threadIdx.x + 8]; int idx, idy, maskIndex; int steps_x = CH_RADIUS_X/2; int steps_y = CH_RADIUS_Y/2; int temp[2] = {0,0}; \n#pragma unroll\n for (j = 0; j <= 1; j++) { idx = 16*j + threadIdx.x; \n#pragma unroll\n for (i = -steps_y; i <= steps_y; i++) { idy = 8 + i + threadIdx.y; maskIndex = i + steps_y; temp[j] += (int)l[idy][idx] * lcy[maskIndex]; } } barrier(CLK_LOCAL_MEM_FENCE); idy = 8 + threadIdx.y; \n#pragma unroll\n for (j = 0; j <= 1; j++) { idx = 16*j + threadIdx.x; l[idy][idx] = temp[j]; } barrier(CLK_LOCAL_MEM_FENCE); //compute results with the horizontal filter \n int sum = 0; idy = 8 + threadIdx.y; \n#pragma unroll\n for (j = -steps_x; j <= steps_x; j++) { idx = 8 + j + threadIdx.x; maskIndex = j + steps_x; sum += (int)l[idy][idx] * lcx[maskIndex]; } int res = orig_value + (((orig_value - (int)((sum + halfscale) >> scalebits)) * amount) >> 16); if (globalIdx.x < cw && globalIdx.y < ch) dst[globalIdx.x + globalIdx.y*dst_stride_ch] = clip_uint8(res); } kernel void unsharp_default(global unsigned char *src, global unsigned char *dst, const global unsigned int *mask_lu, const global unsigned int *mask_ch, int amount_lu, int amount_ch, int step_x_lu, int step_y_lu, int step_x_ch, int step_y_ch, int scalebits_lu, int scalebits_ch, int halfscale_lu, int halfscale_ch, int src_stride_lu, int src_stride_ch, int dst_stride_lu, int dst_stride_ch, int height, int width, int ch, int cw) { global unsigned char *dst_y = dst; global unsigned char *dst_u = dst_y + height * dst_stride_lu; global unsigned char *dst_v = dst_u + ch * dst_stride_ch; global unsigned char *src_y = src; global unsigned char *src_u = src_y + height * src_stride_lu; global unsigned char *src_v = src_u + ch * src_stride_ch; global unsigned char *temp_dst; global unsigned char *temp_src; const global unsigned int *temp_mask; int global_id = get_global_id(0); int i, j, x, y, temp_src_stride, temp_dst_stride, temp_height, temp_width, temp_steps_x, temp_steps_y, temp_amount, temp_scalebits, temp_halfscale, sum, idx_x, idx_y, temp, res; if (global_id < width * height) { y = global_id / width; x = global_id % width; temp_dst = dst_y; temp_src = src_y; temp_src_stride = src_stride_lu; temp_dst_stride = dst_stride_lu; temp_height = height; temp_width = width; temp_steps_x = step_x_lu; temp_steps_y = step_y_lu; temp_mask = mask_lu; temp_amount = amount_lu; temp_scalebits = scalebits_lu; temp_halfscale = halfscale_lu; } else if ((global_id >= width * height) && (global_id < width * height + ch * cw)) { y = (global_id - width * height) / cw; x = (global_id - width * height) % cw; temp_dst = dst_u; temp_src = src_u; temp_src_stride = src_stride_ch; temp_dst_stride = dst_stride_ch; temp_height = ch; temp_width = cw; temp_steps_x = step_x_ch; temp_steps_y = step_y_ch; temp_mask = mask_ch; temp_amount = amount_ch; temp_scalebits = scalebits_ch; temp_halfscale = halfscale_ch; } else { y = (global_id - width * height - ch * cw) / cw; x = (global_id - width * height - ch * cw) % cw; temp_dst = dst_v; temp_src = src_v; temp_src_stride = src_stride_ch; temp_dst_stride = dst_stride_ch; temp_height = ch; temp_width = cw; temp_steps_x = step_x_ch; temp_steps_y = step_y_ch; temp_mask = mask_ch; temp_amount = amount_ch; temp_scalebits = scalebits_ch; temp_halfscale = halfscale_ch; } if (temp_amount) { sum = 0; for (j = 0; j <= 2 * temp_steps_y; j++) { idx_y = (y - temp_steps_y + j) <= 0 ? 0 : (y - temp_steps_y + j) >= temp_height ? temp_height-1 : y - temp_steps_y + j; for (i = 0; i <= 2 * temp_steps_x; i++) { idx_x = (x - temp_steps_x + i) <= 0 ? 0 : (x - temp_steps_x + i) >= temp_width ? temp_width-1 : x - temp_steps_x + i; sum += temp_mask[i + j * (2 * temp_steps_x + 1)] * temp_src[idx_x + idx_y * temp_src_stride]; } } temp = (int)temp_src[x + y * temp_src_stride]; res = temp + (((temp - (int)((sum + temp_halfscale) >> temp_scalebits)) * temp_amount) >> 16); temp_dst[x + y * temp_dst_stride] = clip_uint8(res); } else { temp_dst[x + y * temp_dst_stride] = temp_src[x + y * temp_src_stride]; } } ); #endif /* AVFILTER_UNSHARP_OPENCL_KERNEL_H */