/* * Copyright (C) 2001-2003 Michael Niedermayer <michaelni@gmx.at> * * This file is part of Libav. * * Libav 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. * * Libav 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 Libav; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ #include <assert.h> #include <inttypes.h> #include <math.h> #include <stdio.h> #include <string.h> #include "libavutil/avutil.h" #include "libavutil/bswap.h" #include "libavutil/cpu.h" #include "libavutil/intreadwrite.h" #include "libavutil/mathematics.h" #include "libavutil/pixdesc.h" #include "config.h" #include "rgb2rgb.h" #include "swscale_internal.h" #include "swscale.h" DECLARE_ALIGNED(8, const uint8_t, ff_dither_8x8_128)[8][8] = { { 36, 68, 60, 92, 34, 66, 58, 90, }, { 100, 4, 124, 28, 98, 2, 122, 26, }, { 52, 84, 44, 76, 50, 82, 42, 74, }, { 116, 20, 108, 12, 114, 18, 106, 10, }, { 32, 64, 56, 88, 38, 70, 62, 94, }, { 96, 0, 120, 24, 102, 6, 126, 30, }, { 48, 80, 40, 72, 54, 86, 46, 78, }, { 112, 16, 104, 8, 118, 22, 110, 14, }, }; DECLARE_ALIGNED(8, static const uint8_t, sws_pb_64)[8] = { 64, 64, 64, 64, 64, 64, 64, 64 }; static av_always_inline void fillPlane(uint8_t *plane, int stride, int width, int height, int y, uint8_t val) { int i; uint8_t *ptr = plane + stride * y; for (i = 0; i < height; i++) { memset(ptr, val, width); ptr += stride; } } static void fill_plane9or10(uint8_t *plane, int stride, int width, int height, int y, uint8_t val, const int dst_depth, const int big_endian) { int i, j; uint16_t *dst = (uint16_t *) (plane + stride * y); #define FILL8TO9_OR_10(wfunc) \ for (i = 0; i < height; i++) { \ for (j = 0; j < width; j++) { \ wfunc(&dst[j], (val << (dst_depth - 8)) | \ (val >> (16 - dst_depth))); \ } \ dst += stride / 2; \ } if (big_endian) { FILL8TO9_OR_10(AV_WB16); } else { FILL8TO9_OR_10(AV_WL16); } } static void hScale16To19_c(SwsContext *c, int16_t *_dst, int dstW, const uint8_t *_src, const int16_t *filter, const int32_t *filterPos, int filterSize) { const AVPixFmtDescriptor *desc = av_pix_fmt_desc_get(c->srcFormat); int i; int32_t *dst = (int32_t *) _dst; const uint16_t *src = (const uint16_t *) _src; int bits = desc->comp[0].depth_minus1; int sh = bits - 4; for (i = 0; i < dstW; i++) { int j; int srcPos = filterPos[i]; int val = 0; for (j = 0; j < filterSize; j++) { val += src[srcPos + j] * filter[filterSize * i + j]; } // filter=14 bit, input=16 bit, output=30 bit, >> 11 makes 19 bit dst[i] = FFMIN(val >> sh, (1 << 19) - 1); } } static void hScale16To15_c(SwsContext *c, int16_t *dst, int dstW, const uint8_t *_src, const int16_t *filter, const int32_t *filterPos, int filterSize) { const AVPixFmtDescriptor *desc = av_pix_fmt_desc_get(c->srcFormat); int i; const uint16_t *src = (const uint16_t *) _src; int sh = desc->comp[0].depth_minus1; for (i = 0; i < dstW; i++) { int j; int srcPos = filterPos[i]; int val = 0; for (j = 0; j < filterSize; j++) { val += src[srcPos + j] * filter[filterSize * i + j]; } // filter=14 bit, input=16 bit, output=30 bit, >> 15 makes 15 bit dst[i] = FFMIN(val >> sh, (1 << 15) - 1); } } // bilinear / bicubic scaling static void hScale8To15_c(SwsContext *c, int16_t *dst, int dstW, const uint8_t *src, const int16_t *filter, const int32_t *filterPos, int filterSize) { int i; for (i = 0; i < dstW; i++) { int j; int srcPos = filterPos[i]; int val = 0; for (j = 0; j < filterSize; j++) { val += ((int)src[srcPos + j]) * filter[filterSize * i + j]; } dst[i] = FFMIN(val >> 7, (1 << 15) - 1); // the cubic equation does overflow ... } } static void hScale8To19_c(SwsContext *c, int16_t *_dst, int dstW, const uint8_t *src, const int16_t *filter, const int32_t *filterPos, int filterSize) { int i; int32_t *dst = (int32_t *) _dst; for (i = 0; i < dstW; i++) { int j; int srcPos = filterPos[i]; int val = 0; for (j = 0; j < filterSize; j++) { val += ((int)src[srcPos + j]) * filter[filterSize * i + j]; } dst[i] = FFMIN(val >> 3, (1 << 19) - 1); // the cubic equation does overflow ... } } // FIXME all pal and rgb srcFormats could do this conversion as well // FIXME all scalers more complex than bilinear could do half of this transform static void chrRangeToJpeg_c(int16_t *dstU, int16_t *dstV, int width) { int i; for (i = 0; i < width; i++) { dstU[i] = (FFMIN(dstU[i], 30775) * 4663 - 9289992) >> 12; // -264 dstV[i] = (FFMIN(dstV[i], 30775) * 4663 - 9289992) >> 12; // -264 } } static void chrRangeFromJpeg_c(int16_t *dstU, int16_t *dstV, int width) { int i; for (i = 0; i < width; i++) { dstU[i] = (dstU[i] * 1799 + 4081085) >> 11; // 1469 dstV[i] = (dstV[i] * 1799 + 4081085) >> 11; // 1469 } } static void lumRangeToJpeg_c(int16_t *dst, int width) { int i; for (i = 0; i < width; i++) dst[i] = (FFMIN(dst[i], 30189) * 19077 - 39057361) >> 14; } static void lumRangeFromJpeg_c(int16_t *dst, int width) { int i; for (i = 0; i < width; i++) dst[i] = (dst[i] * 14071 + 33561947) >> 14; } static void chrRangeToJpeg16_c(int16_t *_dstU, int16_t *_dstV, int width) { int i; int32_t *dstU = (int32_t *) _dstU; int32_t *dstV = (int32_t *) _dstV; for (i = 0; i < width; i++) { dstU[i] = (FFMIN(dstU[i], 30775 << 4) * 4663 - (9289992 << 4)) >> 12; // -264 dstV[i] = (FFMIN(dstV[i], 30775 << 4) * 4663 - (9289992 << 4)) >> 12; // -264 } } static void chrRangeFromJpeg16_c(int16_t *_dstU, int16_t *_dstV, int width) { int i; int32_t *dstU = (int32_t *) _dstU; int32_t *dstV = (int32_t *) _dstV; for (i = 0; i < width; i++) { dstU[i] = (dstU[i] * 1799 + (4081085 << 4)) >> 11; // 1469 dstV[i] = (dstV[i] * 1799 + (4081085 << 4)) >> 11; // 1469 } } static void lumRangeToJpeg16_c(int16_t *_dst, int width) { int i; int32_t *dst = (int32_t *) _dst; for (i = 0; i < width; i++) dst[i] = (FFMIN(dst[i], 30189 << 4) * 4769 - (39057361 << 2)) >> 12; } static void lumRangeFromJpeg16_c(int16_t *_dst, int width) { int i; int32_t *dst = (int32_t *) _dst; for (i = 0; i < width; i++) dst[i] = (dst[i] * 14071 + (33561947 << 4)) >> 14; } static void hyscale_fast_c(SwsContext *c, int16_t *dst, int dstWidth, const uint8_t *src, int srcW, int xInc) { int i; unsigned int xpos = 0; for (i = 0; i < dstWidth; i++) { register unsigned int xx = xpos >> 16; register unsigned int xalpha = (xpos & 0xFFFF) >> 9; dst[i] = (src[xx] << 7) + (src[xx + 1] - src[xx]) * xalpha; xpos += xInc; } } // *** horizontal scale Y line to temp buffer static av_always_inline void hyscale(SwsContext *c, int16_t *dst, int dstWidth, const uint8_t *src_in[4], int srcW, int xInc, const int16_t *hLumFilter, const int32_t *hLumFilterPos, int hLumFilterSize, uint8_t *formatConvBuffer, uint32_t *pal, int isAlpha) { void (*toYV12)(uint8_t *, const uint8_t *, int, uint32_t *) = isAlpha ? c->alpToYV12 : c->lumToYV12; void (*convertRange)(int16_t *, int) = isAlpha ? NULL : c->lumConvertRange; const uint8_t *src = src_in[isAlpha ? 3 : 0]; if (toYV12) { toYV12(formatConvBuffer, src, srcW, pal); src = formatConvBuffer; } else if (c->readLumPlanar && !isAlpha) { c->readLumPlanar(formatConvBuffer, src_in, srcW); src = formatConvBuffer; } if (!c->hyscale_fast) { c->hyScale(c, dst, dstWidth, src, hLumFilter, hLumFilterPos, hLumFilterSize); } else { // fast bilinear upscale / crap downscale c->hyscale_fast(c, dst, dstWidth, src, srcW, xInc); } if (convertRange) convertRange(dst, dstWidth); } static void hcscale_fast_c(SwsContext *c, int16_t *dst1, int16_t *dst2, int dstWidth, const uint8_t *src1, const uint8_t *src2, int srcW, int xInc) { int i; unsigned int xpos = 0; for (i = 0; i < dstWidth; i++) { register unsigned int xx = xpos >> 16; register unsigned int xalpha = (xpos & 0xFFFF) >> 9; dst1[i] = (src1[xx] * (xalpha ^ 127) + src1[xx + 1] * xalpha); dst2[i] = (src2[xx] * (xalpha ^ 127) + src2[xx + 1] * xalpha); xpos += xInc; } } static av_always_inline void hcscale(SwsContext *c, int16_t *dst1, int16_t *dst2, int dstWidth, const uint8_t *src_in[4], int srcW, int xInc, const int16_t *hChrFilter, const int32_t *hChrFilterPos, int hChrFilterSize, uint8_t *formatConvBuffer, uint32_t *pal) { const uint8_t *src1 = src_in[1], *src2 = src_in[2]; if (c->chrToYV12) { uint8_t *buf2 = formatConvBuffer + FFALIGN(srcW * FFALIGN(c->srcBpc, 8) >> 3, 16); c->chrToYV12(formatConvBuffer, buf2, src1, src2, srcW, pal); src1 = formatConvBuffer; src2 = buf2; } else if (c->readChrPlanar) { uint8_t *buf2 = formatConvBuffer + FFALIGN(srcW * FFALIGN(c->srcBpc, 8) >> 3, 16); c->readChrPlanar(formatConvBuffer, buf2, src_in, srcW); src1 = formatConvBuffer; src2 = buf2; } if (!c->hcscale_fast) { c->hcScale(c, dst1, dstWidth, src1, hChrFilter, hChrFilterPos, hChrFilterSize); c->hcScale(c, dst2, dstWidth, src2, hChrFilter, hChrFilterPos, hChrFilterSize); } else { // fast bilinear upscale / crap downscale c->hcscale_fast(c, dst1, dst2, dstWidth, src1, src2, srcW, xInc); } if (c->chrConvertRange) c->chrConvertRange(dst1, dst2, dstWidth); } #define DEBUG_SWSCALE_BUFFERS 0 #define DEBUG_BUFFERS(...) \ if (DEBUG_SWSCALE_BUFFERS) \ av_log(c, AV_LOG_DEBUG, __VA_ARGS__) static int swscale(SwsContext *c, const uint8_t *src[], int srcStride[], int srcSliceY, int srcSliceH, uint8_t *dst[], int dstStride[]) { /* load a few things into local vars to make the code more readable? * and faster */ const int srcW = c->srcW; const int dstW = c->dstW; const int dstH = c->dstH; const int chrDstW = c->chrDstW; const int chrSrcW = c->chrSrcW; const int lumXInc = c->lumXInc; const int chrXInc = c->chrXInc; const enum AVPixelFormat dstFormat = c->dstFormat; const int flags = c->flags; int32_t *vLumFilterPos = c->vLumFilterPos; int32_t *vChrFilterPos = c->vChrFilterPos; int32_t *hLumFilterPos = c->hLumFilterPos; int32_t *hChrFilterPos = c->hChrFilterPos; int16_t *vLumFilter = c->vLumFilter; int16_t *vChrFilter = c->vChrFilter; int16_t *hLumFilter = c->hLumFilter; int16_t *hChrFilter = c->hChrFilter; int32_t *lumMmxFilter = c->lumMmxFilter; int32_t *chrMmxFilter = c->chrMmxFilter; const int vLumFilterSize = c->vLumFilterSize; const int vChrFilterSize = c->vChrFilterSize; const int hLumFilterSize = c->hLumFilterSize; const int hChrFilterSize = c->hChrFilterSize; int16_t **lumPixBuf = c->lumPixBuf; int16_t **chrUPixBuf = c->chrUPixBuf; int16_t **chrVPixBuf = c->chrVPixBuf; int16_t **alpPixBuf = c->alpPixBuf; const int vLumBufSize = c->vLumBufSize; const int vChrBufSize = c->vChrBufSize; uint8_t *formatConvBuffer = c->formatConvBuffer; uint32_t *pal = c->pal_yuv; yuv2planar1_fn yuv2plane1 = c->yuv2plane1; yuv2planarX_fn yuv2planeX = c->yuv2planeX; yuv2interleavedX_fn yuv2nv12cX = c->yuv2nv12cX; yuv2packed1_fn yuv2packed1 = c->yuv2packed1; yuv2packed2_fn yuv2packed2 = c->yuv2packed2; yuv2packedX_fn yuv2packedX = c->yuv2packedX; yuv2anyX_fn yuv2anyX = c->yuv2anyX; const int chrSrcSliceY = srcSliceY >> c->chrSrcVSubSample; const int chrSrcSliceH = -((-srcSliceH) >> c->chrSrcVSubSample); int should_dither = is9_OR_10BPS(c->srcFormat) || is16BPS(c->srcFormat); int lastDstY; /* vars which will change and which we need to store back in the context */ int dstY = c->dstY; int lumBufIndex = c->lumBufIndex; int chrBufIndex = c->chrBufIndex; int lastInLumBuf = c->lastInLumBuf; int lastInChrBuf = c->lastInChrBuf; if (isPacked(c->srcFormat)) { src[0] = src[1] = src[2] = src[3] = src[0]; srcStride[0] = srcStride[1] = srcStride[2] = srcStride[3] = srcStride[0]; } srcStride[1] <<= c->vChrDrop; srcStride[2] <<= c->vChrDrop; DEBUG_BUFFERS("swscale() %p[%d] %p[%d] %p[%d] %p[%d] -> %p[%d] %p[%d] %p[%d] %p[%d]\n", src[0], srcStride[0], src[1], srcStride[1], src[2], srcStride[2], src[3], srcStride[3], dst[0], dstStride[0], dst[1], dstStride[1], dst[2], dstStride[2], dst[3], dstStride[3]); DEBUG_BUFFERS("srcSliceY: %d srcSliceH: %d dstY: %d dstH: %d\n", srcSliceY, srcSliceH, dstY, dstH); DEBUG_BUFFERS("vLumFilterSize: %d vLumBufSize: %d vChrFilterSize: %d vChrBufSize: %d\n", vLumFilterSize, vLumBufSize, vChrFilterSize, vChrBufSize); if (dstStride[0] % 8 != 0 || dstStride[1] % 8 != 0 || dstStride[2] % 8 != 0 || dstStride[3] % 8 != 0) { static int warnedAlready = 0; // FIXME maybe move this into the context if (flags & SWS_PRINT_INFO && !warnedAlready) { av_log(c, AV_LOG_WARNING, "Warning: dstStride is not aligned!\n" " ->cannot do aligned memory accesses anymore\n"); warnedAlready = 1; } } /* Note the user might start scaling the picture in the middle so this * will not get executed. This is not really intended but works * currently, so people might do it. */ if (srcSliceY == 0) { lumBufIndex = -1; chrBufIndex = -1; dstY = 0; lastInLumBuf = -1; lastInChrBuf = -1; } if (!should_dither) { c->chrDither8 = c->lumDither8 = sws_pb_64; } lastDstY = dstY; for (; dstY < dstH; dstY++) { const int chrDstY = dstY >> c->chrDstVSubSample; uint8_t *dest[4] = { dst[0] + dstStride[0] * dstY, dst[1] + dstStride[1] * chrDstY, dst[2] + dstStride[2] * chrDstY, (CONFIG_SWSCALE_ALPHA && alpPixBuf) ? dst[3] + dstStride[3] * dstY : NULL, }; // First line needed as input const int firstLumSrcY = FFMAX(1 - vLumFilterSize, vLumFilterPos[dstY]); const int firstLumSrcY2 = FFMAX(1 - vLumFilterSize, vLumFilterPos[FFMIN(dstY | ((1 << c->chrDstVSubSample) - 1), dstH - 1)]); // First line needed as input const int firstChrSrcY = FFMAX(1 - vChrFilterSize, vChrFilterPos[chrDstY]); // Last line needed as input int lastLumSrcY = FFMIN(c->srcH, firstLumSrcY + vLumFilterSize) - 1; int lastLumSrcY2 = FFMIN(c->srcH, firstLumSrcY2 + vLumFilterSize) - 1; int lastChrSrcY = FFMIN(c->chrSrcH, firstChrSrcY + vChrFilterSize) - 1; int enough_lines; // handle holes (FAST_BILINEAR & weird filters) if (firstLumSrcY > lastInLumBuf) lastInLumBuf = firstLumSrcY - 1; if (firstChrSrcY > lastInChrBuf) lastInChrBuf = firstChrSrcY - 1; assert(firstLumSrcY >= lastInLumBuf - vLumBufSize + 1); assert(firstChrSrcY >= lastInChrBuf - vChrBufSize + 1); DEBUG_BUFFERS("dstY: %d\n", dstY); DEBUG_BUFFERS("\tfirstLumSrcY: %d lastLumSrcY: %d lastInLumBuf: %d\n", firstLumSrcY, lastLumSrcY, lastInLumBuf); DEBUG_BUFFERS("\tfirstChrSrcY: %d lastChrSrcY: %d lastInChrBuf: %d\n", firstChrSrcY, lastChrSrcY, lastInChrBuf); // Do we have enough lines in this slice to output the dstY line enough_lines = lastLumSrcY2 < srcSliceY + srcSliceH && lastChrSrcY < -((-srcSliceY - srcSliceH) >> c->chrSrcVSubSample); if (!enough_lines) { lastLumSrcY = srcSliceY + srcSliceH - 1; lastChrSrcY = chrSrcSliceY + chrSrcSliceH - 1; DEBUG_BUFFERS("buffering slice: lastLumSrcY %d lastChrSrcY %d\n", lastLumSrcY, lastChrSrcY); } // Do horizontal scaling while (lastInLumBuf < lastLumSrcY) { const uint8_t *src1[4] = { src[0] + (lastInLumBuf + 1 - srcSliceY) * srcStride[0], src[1] + (lastInLumBuf + 1 - srcSliceY) * srcStride[1], src[2] + (lastInLumBuf + 1 - srcSliceY) * srcStride[2], src[3] + (lastInLumBuf + 1 - srcSliceY) * srcStride[3], }; lumBufIndex++; assert(lumBufIndex < 2 * vLumBufSize); assert(lastInLumBuf + 1 - srcSliceY < srcSliceH); assert(lastInLumBuf + 1 - srcSliceY >= 0); hyscale(c, lumPixBuf[lumBufIndex], dstW, src1, srcW, lumXInc, hLumFilter, hLumFilterPos, hLumFilterSize, formatConvBuffer, pal, 0); if (CONFIG_SWSCALE_ALPHA && alpPixBuf) hyscale(c, alpPixBuf[lumBufIndex], dstW, src1, srcW, lumXInc, hLumFilter, hLumFilterPos, hLumFilterSize, formatConvBuffer, pal, 1); lastInLumBuf++; DEBUG_BUFFERS("\t\tlumBufIndex %d: lastInLumBuf: %d\n", lumBufIndex, lastInLumBuf); } while (lastInChrBuf < lastChrSrcY) { const uint8_t *src1[4] = { src[0] + (lastInChrBuf + 1 - chrSrcSliceY) * srcStride[0], src[1] + (lastInChrBuf + 1 - chrSrcSliceY) * srcStride[1], src[2] + (lastInChrBuf + 1 - chrSrcSliceY) * srcStride[2], src[3] + (lastInChrBuf + 1 - chrSrcSliceY) * srcStride[3], }; chrBufIndex++; assert(chrBufIndex < 2 * vChrBufSize); assert(lastInChrBuf + 1 - chrSrcSliceY < (chrSrcSliceH)); assert(lastInChrBuf + 1 - chrSrcSliceY >= 0); // FIXME replace parameters through context struct (some at least) if (c->needs_hcscale) hcscale(c, chrUPixBuf[chrBufIndex], chrVPixBuf[chrBufIndex], chrDstW, src1, chrSrcW, chrXInc, hChrFilter, hChrFilterPos, hChrFilterSize, formatConvBuffer, pal); lastInChrBuf++; DEBUG_BUFFERS("\t\tchrBufIndex %d: lastInChrBuf: %d\n", chrBufIndex, lastInChrBuf); } // wrap buf index around to stay inside the ring buffer if (lumBufIndex >= vLumBufSize) lumBufIndex -= vLumBufSize; if (chrBufIndex >= vChrBufSize) chrBufIndex -= vChrBufSize; if (!enough_lines) break; // we can't output a dstY line so let's try with the next slice #if HAVE_MMX_INLINE updateMMXDitherTables(c, dstY, lumBufIndex, chrBufIndex, lastInLumBuf, lastInChrBuf); #endif if (should_dither) { c->chrDither8 = ff_dither_8x8_128[chrDstY & 7]; c->lumDither8 = ff_dither_8x8_128[dstY & 7]; } if (dstY >= dstH - 2) { /* hmm looks like we can't use MMX here without overwriting * this array's tail */ ff_sws_init_output_funcs(c, &yuv2plane1, &yuv2planeX, &yuv2nv12cX, &yuv2packed1, &yuv2packed2, &yuv2packedX, &yuv2anyX); } { const int16_t **lumSrcPtr = (const int16_t **)lumPixBuf + lumBufIndex + firstLumSrcY - lastInLumBuf + vLumBufSize; const int16_t **chrUSrcPtr = (const int16_t **)chrUPixBuf + chrBufIndex + firstChrSrcY - lastInChrBuf + vChrBufSize; const int16_t **chrVSrcPtr = (const int16_t **)chrVPixBuf + chrBufIndex + firstChrSrcY - lastInChrBuf + vChrBufSize; const int16_t **alpSrcPtr = (CONFIG_SWSCALE_ALPHA && alpPixBuf) ? (const int16_t **)alpPixBuf + lumBufIndex + firstLumSrcY - lastInLumBuf + vLumBufSize : NULL; if (firstLumSrcY < 0 || firstLumSrcY + vLumFilterSize > c->srcH) { const int16_t **tmpY = (const int16_t **)lumPixBuf + 2 * vLumBufSize; int neg = -firstLumSrcY, i; int end = FFMIN(c->srcH - firstLumSrcY, vLumFilterSize); for (i = 0; i < neg; i++) tmpY[i] = lumSrcPtr[neg]; for (; i < end; i++) tmpY[i] = lumSrcPtr[i]; for (; i < vLumFilterSize; i++) tmpY[i] = tmpY[i - 1]; lumSrcPtr = tmpY; if (alpSrcPtr) { const int16_t **tmpA = (const int16_t **)alpPixBuf + 2 * vLumBufSize; for (i = 0; i < neg; i++) tmpA[i] = alpSrcPtr[neg]; for (; i < end; i++) tmpA[i] = alpSrcPtr[i]; for (; i < vLumFilterSize; i++) tmpA[i] = tmpA[i - 1]; alpSrcPtr = tmpA; } } if (firstChrSrcY < 0 || firstChrSrcY + vChrFilterSize > c->chrSrcH) { const int16_t **tmpU = (const int16_t **)chrUPixBuf + 2 * vChrBufSize, **tmpV = (const int16_t **)chrVPixBuf + 2 * vChrBufSize; int neg = -firstChrSrcY, i; int end = FFMIN(c->chrSrcH - firstChrSrcY, vChrFilterSize); for (i = 0; i < neg; i++) { tmpU[i] = chrUSrcPtr[neg]; tmpV[i] = chrVSrcPtr[neg]; } for (; i < end; i++) { tmpU[i] = chrUSrcPtr[i]; tmpV[i] = chrVSrcPtr[i]; } for (; i < vChrFilterSize; i++) { tmpU[i] = tmpU[i - 1]; tmpV[i] = tmpV[i - 1]; } chrUSrcPtr = tmpU; chrVSrcPtr = tmpV; } if (isPlanarYUV(dstFormat) || (isGray(dstFormat) && !isALPHA(dstFormat))) { // YV12 like const int chrSkipMask = (1 << c->chrDstVSubSample) - 1; if (vLumFilterSize == 1) { yuv2plane1(lumSrcPtr[0], dest[0], dstW, c->lumDither8, 0); } else { yuv2planeX(vLumFilter + dstY * vLumFilterSize, vLumFilterSize, lumSrcPtr, dest[0], dstW, c->lumDither8, 0); } if (!((dstY & chrSkipMask) || isGray(dstFormat))) { if (yuv2nv12cX) { yuv2nv12cX(c, vChrFilter + chrDstY * vChrFilterSize, vChrFilterSize, chrUSrcPtr, chrVSrcPtr, dest[1], chrDstW); } else if (vChrFilterSize == 1) { yuv2plane1(chrUSrcPtr[0], dest[1], chrDstW, c->chrDither8, 0); yuv2plane1(chrVSrcPtr[0], dest[2], chrDstW, c->chrDither8, 3); } else { yuv2planeX(vChrFilter + chrDstY * vChrFilterSize, vChrFilterSize, chrUSrcPtr, dest[1], chrDstW, c->chrDither8, 0); yuv2planeX(vChrFilter + chrDstY * vChrFilterSize, vChrFilterSize, chrVSrcPtr, dest[2], chrDstW, c->chrDither8, 3); } } if (CONFIG_SWSCALE_ALPHA && alpPixBuf) { if (vLumFilterSize == 1) { yuv2plane1(alpSrcPtr[0], dest[3], dstW, c->lumDither8, 0); } else { yuv2planeX(vLumFilter + dstY * vLumFilterSize, vLumFilterSize, alpSrcPtr, dest[3], dstW, c->lumDither8, 0); } } } else if (yuv2packedX) { if (c->yuv2packed1 && vLumFilterSize == 1 && vChrFilterSize <= 2) { // unscaled RGB int chrAlpha = vChrFilterSize == 1 ? 0 : vChrFilter[2 * dstY + 1]; yuv2packed1(c, *lumSrcPtr, chrUSrcPtr, chrVSrcPtr, alpPixBuf ? *alpSrcPtr : NULL, dest[0], dstW, chrAlpha, dstY); } else if (c->yuv2packed2 && vLumFilterSize == 2 && vChrFilterSize == 2) { // bilinear upscale RGB int lumAlpha = vLumFilter[2 * dstY + 1]; int chrAlpha = vChrFilter[2 * dstY + 1]; lumMmxFilter[2] = lumMmxFilter[3] = vLumFilter[2 * dstY] * 0x10001; chrMmxFilter[2] = chrMmxFilter[3] = vChrFilter[2 * chrDstY] * 0x10001; yuv2packed2(c, lumSrcPtr, chrUSrcPtr, chrVSrcPtr, alpPixBuf ? alpSrcPtr : NULL, dest[0], dstW, lumAlpha, chrAlpha, dstY); } else { // general RGB yuv2packedX(c, vLumFilter + dstY * vLumFilterSize, lumSrcPtr, vLumFilterSize, vChrFilter + dstY * vChrFilterSize, chrUSrcPtr, chrVSrcPtr, vChrFilterSize, alpSrcPtr, dest[0], dstW, dstY); } } else { yuv2anyX(c, vLumFilter + dstY * vLumFilterSize, lumSrcPtr, vLumFilterSize, vChrFilter + dstY * vChrFilterSize, chrUSrcPtr, chrVSrcPtr, vChrFilterSize, alpSrcPtr, dest, dstW, dstY); } } } if (isPlanar(dstFormat) && isALPHA(dstFormat) && !alpPixBuf) { int length = dstW; int height = dstY - lastDstY; if (is16BPS(c->dstFormat)) length *= 2; if (is9_OR_10BPS(dstFormat)) { const AVPixFmtDescriptor *desc = av_pix_fmt_desc_get(dstFormat); fill_plane9or10(dst[3], dstStride[3], length, height, lastDstY, 255, desc->comp[3].depth_minus1 + 1, isBE(dstFormat)); } else fillPlane(dst[3], dstStride[3], length, height, lastDstY, 255); } #if HAVE_MMXEXT_INLINE if (av_get_cpu_flags() & AV_CPU_FLAG_MMXEXT) __asm__ volatile ("sfence" ::: "memory"); #endif emms_c(); /* store changed local vars back in the context */ c->dstY = dstY; c->lumBufIndex = lumBufIndex; c->chrBufIndex = chrBufIndex; c->lastInLumBuf = lastInLumBuf; c->lastInChrBuf = lastInChrBuf; return dstY - lastDstY; } static av_cold void sws_init_swscale(SwsContext *c) { enum AVPixelFormat srcFormat = c->srcFormat; ff_sws_init_output_funcs(c, &c->yuv2plane1, &c->yuv2planeX, &c->yuv2nv12cX, &c->yuv2packed1, &c->yuv2packed2, &c->yuv2packedX, &c->yuv2anyX); ff_sws_init_input_funcs(c); if (c->srcBpc == 8) { if (c->dstBpc <= 10) { c->hyScale = c->hcScale = hScale8To15_c; if (c->flags & SWS_FAST_BILINEAR) { c->hyscale_fast = hyscale_fast_c; c->hcscale_fast = hcscale_fast_c; } } else { c->hyScale = c->hcScale = hScale8To19_c; } } else { c->hyScale = c->hcScale = c->dstBpc > 10 ? hScale16To19_c : hScale16To15_c; } if (c->srcRange != c->dstRange && !isAnyRGB(c->dstFormat)) { if (c->dstBpc <= 10) { if (c->srcRange) { c->lumConvertRange = lumRangeFromJpeg_c; c->chrConvertRange = chrRangeFromJpeg_c; } else { c->lumConvertRange = lumRangeToJpeg_c; c->chrConvertRange = chrRangeToJpeg_c; } } else { if (c->srcRange) { c->lumConvertRange = lumRangeFromJpeg16_c; c->chrConvertRange = chrRangeFromJpeg16_c; } else { c->lumConvertRange = lumRangeToJpeg16_c; c->chrConvertRange = chrRangeToJpeg16_c; } } } if (!(isGray(srcFormat) || isGray(c->dstFormat) || srcFormat == AV_PIX_FMT_MONOBLACK || srcFormat == AV_PIX_FMT_MONOWHITE)) c->needs_hcscale = 1; } SwsFunc ff_getSwsFunc(SwsContext *c) { sws_init_swscale(c); if (ARCH_PPC) ff_sws_init_swscale_ppc(c); if (ARCH_X86) ff_sws_init_swscale_x86(c); return swscale; }