/* * Copyright (C) 2015 Pedro Arthur * * 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 */ #include "libavutil/mem.h" #include "swscale_internal.h" typedef struct VScalerContext { uint16_t *filter[2]; int32_t *filter_pos; int filter_size; int isMMX; union { yuv2planar1_fn yuv2planar1; yuv2planarX_fn yuv2planarX; yuv2interleavedX_fn yuv2interleavedX; yuv2packed1_fn yuv2packed1; yuv2packed2_fn yuv2packed2; yuv2anyX_fn yuv2anyX; } pfn; yuv2packedX_fn yuv2packedX; } VScalerContext; static int lum_planar_vscale(SwsInternal *c, SwsFilterDescriptor *desc, int sliceY, int sliceH) { VScalerContext *inst = desc->instance; int dstW = desc->dst->width; int first = FFMAX(1-inst->filter_size, inst->filter_pos[sliceY]); int sp = first - desc->src->plane[0].sliceY; int dp = sliceY - desc->dst->plane[0].sliceY; uint8_t **src = desc->src->plane[0].line + sp; uint8_t **dst = desc->dst->plane[0].line + dp; uint16_t *filter = inst->filter[0] + (inst->isMMX ? 0 : sliceY * inst->filter_size); if (inst->filter_size == 1) inst->pfn.yuv2planar1((const int16_t*)src[0], dst[0], dstW, c->lumDither8, 0); else inst->pfn.yuv2planarX(filter, inst->filter_size, (const int16_t**)src, dst[0], dstW, c->lumDither8, 0); if (desc->alpha) { int sp = first - desc->src->plane[3].sliceY; int dp = sliceY - desc->dst->plane[3].sliceY; uint8_t **src = desc->src->plane[3].line + sp; uint8_t **dst = desc->dst->plane[3].line + dp; uint16_t *filter = inst->filter[1] + (inst->isMMX ? 0 : sliceY * inst->filter_size); if (inst->filter_size == 1) inst->pfn.yuv2planar1((const int16_t*)src[0], dst[0], dstW, c->lumDither8, 0); else inst->pfn.yuv2planarX(filter, inst->filter_size, (const int16_t**)src, dst[0], dstW, c->lumDither8, 0); } return 1; } static int chr_planar_vscale(SwsInternal *c, SwsFilterDescriptor *desc, int sliceY, int sliceH) { const int chrSkipMask = (1 << desc->dst->v_chr_sub_sample) - 1; if (sliceY & chrSkipMask) return 0; else { VScalerContext *inst = desc->instance; int dstW = AV_CEIL_RSHIFT(desc->dst->width, desc->dst->h_chr_sub_sample); int chrSliceY = sliceY >> desc->dst->v_chr_sub_sample; int first = FFMAX(1-inst->filter_size, inst->filter_pos[chrSliceY]); int sp1 = first - desc->src->plane[1].sliceY; int sp2 = first - desc->src->plane[2].sliceY; int dp1 = chrSliceY - desc->dst->plane[1].sliceY; int dp2 = chrSliceY - desc->dst->plane[2].sliceY; uint8_t **src1 = desc->src->plane[1].line + sp1; uint8_t **src2 = desc->src->plane[2].line + sp2; uint8_t **dst1 = desc->dst->plane[1].line + dp1; uint8_t **dst2 = desc->dst->plane[2].line + dp2; uint16_t *filter = inst->filter[0] + (inst->isMMX ? 0 : chrSliceY * inst->filter_size); if (c->yuv2nv12cX) { inst->pfn.yuv2interleavedX(c->opts.dst_format, c->chrDither8, filter, inst->filter_size, (const int16_t**)src1, (const int16_t**)src2, dst1[0], dstW); } else if (inst->filter_size == 1) { inst->pfn.yuv2planar1((const int16_t*)src1[0], dst1[0], dstW, c->chrDither8, 0); inst->pfn.yuv2planar1((const int16_t*)src2[0], dst2[0], dstW, c->chrDither8, 3); } else { inst->pfn.yuv2planarX(filter, inst->filter_size, (const int16_t**)src1, dst1[0], dstW, c->chrDither8, 0); inst->pfn.yuv2planarX(filter, inst->filter_size, (const int16_t**)src2, dst2[0], dstW, c->chrDither8, inst->isMMX ? (c->uv_offx2 >> 1) : 3); } } return 1; } static int packed_vscale(SwsInternal *c, SwsFilterDescriptor *desc, int sliceY, int sliceH) { VScalerContext *inst = desc->instance; int dstW = desc->dst->width; int chrSliceY = sliceY >> desc->dst->v_chr_sub_sample; int lum_fsize = inst[0].filter_size; int chr_fsize = inst[1].filter_size; uint16_t *lum_filter = inst[0].filter[0]; uint16_t *chr_filter = inst[1].filter[0]; int firstLum = FFMAX(1-lum_fsize, inst[0].filter_pos[ sliceY]); int firstChr = FFMAX(1-chr_fsize, inst[1].filter_pos[chrSliceY]); int sp0 = firstLum - desc->src->plane[0].sliceY; int sp1 = firstChr - desc->src->plane[1].sliceY; int sp2 = firstChr - desc->src->plane[2].sliceY; int sp3 = firstLum - desc->src->plane[3].sliceY; int dp = sliceY - desc->dst->plane[0].sliceY; uint8_t **src0 = desc->src->plane[0].line + sp0; uint8_t **src1 = desc->src->plane[1].line + sp1; uint8_t **src2 = desc->src->plane[2].line + sp2; uint8_t **src3 = desc->alpha ? desc->src->plane[3].line + sp3 : NULL; uint8_t **dst = desc->dst->plane[0].line + dp; if (c->yuv2packed1 && lum_fsize == 1 && chr_fsize == 1) { // unscaled RGB inst->pfn.yuv2packed1(c, (const int16_t*)*src0, (const int16_t**)src1, (const int16_t**)src2, (const int16_t*)(desc->alpha ? *src3 : NULL), *dst, dstW, 0, sliceY); } else if (c->yuv2packed1 && lum_fsize == 1 && chr_fsize == 2 && chr_filter[2 * chrSliceY + 1] + chr_filter[2 * chrSliceY] == 4096 && chr_filter[2 * chrSliceY + 1] <= 4096U) { // unscaled RGB int chrAlpha = chr_filter[2 * chrSliceY + 1]; inst->pfn.yuv2packed1(c, (const int16_t*)*src0, (const int16_t**)src1, (const int16_t**)src2, (const int16_t*)(desc->alpha ? *src3 : NULL), *dst, dstW, chrAlpha, sliceY); } else if (c->yuv2packed2 && lum_fsize == 2 && chr_fsize == 2 && lum_filter[2 * sliceY + 1] + lum_filter[2 * sliceY] == 4096 && lum_filter[2 * sliceY + 1] <= 4096U && chr_filter[2 * chrSliceY + 1] + chr_filter[2 * chrSliceY] == 4096 && chr_filter[2 * chrSliceY + 1] <= 4096U ) { // bilinear upscale RGB int lumAlpha = lum_filter[2 * sliceY + 1]; int chrAlpha = chr_filter[2 * chrSliceY + 1]; c->lumMmxFilter[2] = c->lumMmxFilter[3] = lum_filter[2 * sliceY] * 0x10001; c->chrMmxFilter[2] = c->chrMmxFilter[3] = chr_filter[2 * chrSliceY] * 0x10001; inst->pfn.yuv2packed2(c, (const int16_t**)src0, (const int16_t**)src1, (const int16_t**)src2, (const int16_t**)src3, *dst, dstW, lumAlpha, chrAlpha, sliceY); } else { // general RGB if ((c->yuv2packed1 && lum_fsize == 1 && chr_fsize == 2) || (c->yuv2packed2 && lum_fsize == 2 && chr_fsize == 2)) { if (!c->warned_unuseable_bilinear) av_log(c, AV_LOG_INFO, "Optimized 2 tap filter code cannot be used\n"); c->warned_unuseable_bilinear = 1; } inst->yuv2packedX(c, lum_filter + sliceY * lum_fsize, (const int16_t**)src0, lum_fsize, chr_filter + chrSliceY * chr_fsize, (const int16_t**)src1, (const int16_t**)src2, chr_fsize, (const int16_t**)src3, *dst, dstW, sliceY); } return 1; } static int any_vscale(SwsInternal *c, SwsFilterDescriptor *desc, int sliceY, int sliceH) { VScalerContext *inst = desc->instance; int dstW = desc->dst->width; int chrSliceY = sliceY >> desc->dst->v_chr_sub_sample; int lum_fsize = inst[0].filter_size; int chr_fsize = inst[1].filter_size; uint16_t *lum_filter = inst[0].filter[0]; uint16_t *chr_filter = inst[1].filter[0]; int firstLum = FFMAX(1-lum_fsize, inst[0].filter_pos[ sliceY]); int firstChr = FFMAX(1-chr_fsize, inst[1].filter_pos[chrSliceY]); int sp0 = firstLum - desc->src->plane[0].sliceY; int sp1 = firstChr - desc->src->plane[1].sliceY; int sp2 = firstChr - desc->src->plane[2].sliceY; int sp3 = firstLum - desc->src->plane[3].sliceY; int dp0 = sliceY - desc->dst->plane[0].sliceY; int dp1 = chrSliceY - desc->dst->plane[1].sliceY; int dp2 = chrSliceY - desc->dst->plane[2].sliceY; int dp3 = sliceY - desc->dst->plane[3].sliceY; uint8_t **src0 = desc->src->plane[0].line + sp0; uint8_t **src1 = desc->src->plane[1].line + sp1; uint8_t **src2 = desc->src->plane[2].line + sp2; uint8_t **src3 = desc->alpha ? desc->src->plane[3].line + sp3 : NULL; uint8_t *dst[4] = { desc->dst->plane[0].line[dp0], desc->dst->plane[1].line[dp1], desc->dst->plane[2].line[dp2], desc->alpha ? desc->dst->plane[3].line[dp3] : NULL }; av_assert1(!c->yuv2packed1 && !c->yuv2packed2); inst->pfn.yuv2anyX(c, lum_filter + sliceY * lum_fsize, (const int16_t**)src0, lum_fsize, chr_filter + sliceY * chr_fsize, (const int16_t**)src1, (const int16_t**)src2, chr_fsize, (const int16_t**)src3, dst, dstW, sliceY); return 1; } int ff_init_vscale(SwsInternal *c, SwsFilterDescriptor *desc, SwsSlice *src, SwsSlice *dst) { VScalerContext *lumCtx = NULL; VScalerContext *chrCtx = NULL; if (isPlanarYUV(c->opts.dst_format) || (isGray(c->opts.dst_format) && !isALPHA(c->opts.dst_format))) { lumCtx = av_mallocz(sizeof(VScalerContext)); if (!lumCtx) return AVERROR(ENOMEM); desc[0].process = lum_planar_vscale; desc[0].instance = lumCtx; desc[0].src = src; desc[0].dst = dst; desc[0].alpha = c->needAlpha; if (!isGray(c->opts.dst_format)) { chrCtx = av_mallocz(sizeof(VScalerContext)); if (!chrCtx) return AVERROR(ENOMEM); desc[1].process = chr_planar_vscale; desc[1].instance = chrCtx; desc[1].src = src; desc[1].dst = dst; } } else { lumCtx = av_calloc(2, sizeof(*lumCtx)); if (!lumCtx) return AVERROR(ENOMEM); chrCtx = &lumCtx[1]; desc[0].process = c->yuv2packedX ? packed_vscale : any_vscale; desc[0].instance = lumCtx; desc[0].src = src; desc[0].dst = dst; desc[0].alpha = c->needAlpha; } ff_init_vscale_pfn(c, c->yuv2plane1, c->yuv2planeX, c->yuv2nv12cX, c->yuv2packed1, c->yuv2packed2, c->yuv2packedX, c->yuv2anyX, c->use_mmx_vfilter); return 0; } void ff_init_vscale_pfn(SwsInternal *c, yuv2planar1_fn yuv2plane1, yuv2planarX_fn yuv2planeX, yuv2interleavedX_fn yuv2nv12cX, yuv2packed1_fn yuv2packed1, yuv2packed2_fn yuv2packed2, yuv2packedX_fn yuv2packedX, yuv2anyX_fn yuv2anyX, int use_mmx) { VScalerContext *lumCtx = NULL; VScalerContext *chrCtx = NULL; int idx = c->numDesc - (c->is_internal_gamma ? 2 : 1); //FIXME avoid hardcoding indexes if (isPlanarYUV(c->opts.dst_format) || (isGray(c->opts.dst_format) && !isALPHA(c->opts.dst_format))) { if (!isGray(c->opts.dst_format)) { chrCtx = c->desc[idx].instance; chrCtx->filter[0] = use_mmx ? (int16_t*)c->chrMmxFilter : c->vChrFilter; chrCtx->filter_size = c->vChrFilterSize; chrCtx->filter_pos = c->vChrFilterPos; chrCtx->isMMX = use_mmx; --idx; if (yuv2nv12cX) chrCtx->pfn.yuv2interleavedX = yuv2nv12cX; else if (c->vChrFilterSize == 1) chrCtx->pfn.yuv2planar1 = yuv2plane1; else chrCtx->pfn.yuv2planarX = yuv2planeX; } lumCtx = c->desc[idx].instance; lumCtx->filter[0] = use_mmx ? (int16_t*)c->lumMmxFilter : c->vLumFilter; lumCtx->filter[1] = use_mmx ? (int16_t*)c->alpMmxFilter : c->vLumFilter; lumCtx->filter_size = c->vLumFilterSize; lumCtx->filter_pos = c->vLumFilterPos; lumCtx->isMMX = use_mmx; if (c->vLumFilterSize == 1) lumCtx->pfn.yuv2planar1 = yuv2plane1; else lumCtx->pfn.yuv2planarX = yuv2planeX; } else { lumCtx = c->desc[idx].instance; chrCtx = &lumCtx[1]; lumCtx->filter[0] = c->vLumFilter; lumCtx->filter_size = c->vLumFilterSize; lumCtx->filter_pos = c->vLumFilterPos; chrCtx->filter[0] = c->vChrFilter; chrCtx->filter_size = c->vChrFilterSize; chrCtx->filter_pos = c->vChrFilterPos; lumCtx->isMMX = use_mmx; chrCtx->isMMX = use_mmx; if (yuv2packedX) { if (c->yuv2packed1 && c->vLumFilterSize == 1 && c->vChrFilterSize <= 2) lumCtx->pfn.yuv2packed1 = yuv2packed1; else if (c->yuv2packed2 && c->vLumFilterSize == 2 && c->vChrFilterSize == 2) lumCtx->pfn.yuv2packed2 = yuv2packed2; lumCtx->yuv2packedX = yuv2packedX; } else lumCtx->pfn.yuv2anyX = yuv2anyX; } }