ref: 2b176495d3f8f8c904d8b2bc603427b1f069a181
dir: /codec/common/src/expand_pic.cpp/
/*! * \copy * Copyright (c) 2013, Cisco Systems * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. * */ #include <string.h> #include "expand_pic.h" #include "cpu_core.h" static inline void MBPadTopLeftLuma_c (uint8_t*& pDst, const int32_t& kiStride) { const uint8_t kuiTL = pDst[0]; int32_t i = 0; uint8_t* pTopLeft = pDst; do { pTopLeft -= kiStride; // pad pTop memcpy (pTopLeft, pDst, 16); // confirmed_safe_unsafe_usage memset (pTopLeft - PADDING_LENGTH, kuiTL, PADDING_LENGTH); //pTop left } while (++i < PADDING_LENGTH); } static inline void MBPadTopLuma_c (uint8_t*& pDst, const int32_t& kiStride, const int32_t& kiMbX) { uint8_t* pTopLine = pDst + (kiMbX << 4); int32_t i = 0; uint8_t* pTop = pTopLine; do { pTop -= kiStride; // pad pTop memcpy (pTop, pTopLine, 16); // confirmed_safe_unsafe_usage } while (++i < PADDING_LENGTH); } static inline void MBPadBottomLuma_c (uint8_t*& pDst, const int32_t& kiStride, const int32_t& kiMbX, const int32_t& kiPicH) { uint8_t* pBottomLine = pDst + (kiPicH - 1) * kiStride + (kiMbX << 4); int32_t i = 0; uint8_t* pBottom = pBottomLine; do { pBottom += kiStride; // pad pBottom memcpy (pBottom, pBottomLine, 16); // confirmed_safe_unsafe_usage } while (++i < PADDING_LENGTH); } static inline void MBPadTopRightLuma_c (uint8_t*& pDst, const int32_t& kiStride, const int32_t& kiPicW) { uint8_t* pTopRight = pDst + kiPicW; const uint8_t kuiTR = pTopRight[-1]; int32_t i = 0; uint8_t* pTop = pTopRight; do { pTop -= kiStride; // pad pTop memcpy (pTop - 16, pTopRight - 16, 16); // confirmed_safe_unsafe_usage memset (pTop, kuiTR, PADDING_LENGTH); //pTop Right } while (++i < PADDING_LENGTH); } static inline void MBPadBottomLeftLuma_c (uint8_t*& pDst, const int32_t& kiStride, const int32_t& kiPicH) { uint8_t* pDstLastLine = pDst + (kiPicH - 1) * kiStride; const uint8_t kuiBL = pDstLastLine[0]; int32_t i = 0; uint8_t* pBottom = pDstLastLine; do { pBottom += kiStride; // pad pBottom memcpy (pBottom, pDstLastLine, 16); // confirmed_safe_unsafe_usage memset (pBottom - PADDING_LENGTH, kuiBL, PADDING_LENGTH); //pBottom left } while (++i < PADDING_LENGTH); } static inline void MBPadBottomRightLuma_c (uint8_t*& pDst, const int32_t& kiStride, const int32_t& kiPicW, const int32_t& kiPicH) { uint8_t* pDstLastLine = pDst + (kiPicH - 1) * kiStride + kiPicW; const uint8_t kuiBR = pDstLastLine[-1]; int32_t i = 0; uint8_t* pBottom = pDstLastLine; do { pBottom += kiStride; // pad pBottom memcpy (pBottom - 16, pDstLastLine - 16, 16); // confirmed_safe_unsafe_usage memset (pBottom, kuiBR, PADDING_LENGTH); //pBottom Right } while (++i < PADDING_LENGTH); } static inline void MBPadLeftLuma_c (uint8_t*& pDst, const int32_t& kiStride, const int32_t& kiMbY) { uint8_t* pTmp = pDst + (kiMbY << 4) * kiStride; for (int32_t i = 0; i < 16; ++i) { // pad left memset (pTmp - PADDING_LENGTH, pTmp[0], PADDING_LENGTH); pTmp += kiStride; } } static inline void MBPadRightLuma_c (uint8_t*& pDst, const int32_t& kiStride, const int32_t& kiMbY, const int32_t& kiPicW) { uint8_t* pTmp = pDst + (kiMbY << 4) * kiStride + kiPicW; for (int32_t i = 0; i < 16; ++i) { // pad right memset (pTmp, pTmp[-1], PADDING_LENGTH); pTmp += kiStride; } } static inline void MBPadTopChroma_c (uint8_t*& pDst, const int32_t& kiStride, const int32_t& kiMbX) { uint8_t* pTopLine = pDst + (kiMbX << 3); int32_t i = 0; uint8_t* pTop = pTopLine; do { pTop -= kiStride; // pad pTop memcpy (pTop, pTopLine, 8); // confirmed_safe_unsafe_usage } while (++i < CHROMA_PADDING_LENGTH); } static inline void MBPadBottomChroma_c (uint8_t*& pDst, const int32_t& kiStride, const int32_t& kiMbX, const int32_t& kiPicH) { uint8_t* pBottomLine = pDst + (kiPicH - 1) * kiStride + (kiMbX << 3); int32_t i = 0; uint8_t* pBottom = pBottomLine; do { pBottom += kiStride; // pad pBottom memcpy (pBottom, pBottomLine, 8); // confirmed_safe_unsafe_usage } while (++i < CHROMA_PADDING_LENGTH); } static inline void MBPadTopLeftChroma_c (uint8_t*& pDst, const int32_t& kiStride) { const uint8_t kuiTL = pDst[0]; int32_t i = 0; uint8_t* pTopLeft = pDst; do { pTopLeft -= kiStride; // pad pTop memcpy (pTopLeft, pDst, 8); // confirmed_safe_unsafe_usage memset (pTopLeft - CHROMA_PADDING_LENGTH, kuiTL, CHROMA_PADDING_LENGTH); //pTop left } while (++i < CHROMA_PADDING_LENGTH); } static inline void MBPadTopRightChroma_c (uint8_t*& pDst, const int32_t& kiStride, const int32_t& kiPicW) { uint8_t* pTopRight = pDst + kiPicW; const uint8_t kuiTR = pTopRight[-1]; int32_t i = 0; uint8_t* pTop = pTopRight; do { pTop -= kiStride; // pad pTop memcpy (pTop - 8, pTopRight - 8, 8); // confirmed_safe_unsafe_usage memset (pTop, kuiTR, CHROMA_PADDING_LENGTH); //pTop Right } while (++i < CHROMA_PADDING_LENGTH); } static inline void MBPadBottomLeftChroma_c (uint8_t*& pDst, const int32_t& kiStride, const int32_t& kiPicH) { uint8_t* pDstLastLine = pDst + (kiPicH - 1) * kiStride; const uint8_t kuiBL = pDstLastLine[0]; int32_t i = 0; uint8_t* pBottom = pDstLastLine; do { pBottom += kiStride; // pad pBottom memcpy (pBottom, pDstLastLine, 8); // confirmed_safe_unsafe_usage memset (pBottom - CHROMA_PADDING_LENGTH, kuiBL, CHROMA_PADDING_LENGTH); //pBottom left } while (++i < CHROMA_PADDING_LENGTH); } static inline void MBPadBottomRightChroma_c (uint8_t*& pDst, const int32_t& kiStride, const int32_t& kiPicW, const int32_t kiPicH) { uint8_t* pDstLastLine = pDst + (kiPicH - 1) * kiStride + kiPicW; const uint8_t kuiBR = pDstLastLine[-1]; int32_t i = 0; uint8_t* pBottom = pDstLastLine; do { pBottom += kiStride; // pad pBottom memcpy (pBottom - 8, pDstLastLine - 8, 8); // confirmed_safe_unsafe_usage memset (pBottom, kuiBR, CHROMA_PADDING_LENGTH); //pBottom Right } while (++i < CHROMA_PADDING_LENGTH); } static inline void MBPadLeftChroma_c (uint8_t*& pDst, const int32_t& kiStride, const int32_t& kiMbY) { uint8_t* pTmp = pDst + (kiMbY << 3) * kiStride; for (int32_t i = 0; i < 8; ++i) { // pad left memset (pTmp - CHROMA_PADDING_LENGTH, pTmp[0], CHROMA_PADDING_LENGTH); pTmp += kiStride; } } static inline void MBPadRightChroma_c (uint8_t*& pDst, const int32_t& kiStride, const int32_t& kiMbY, const int32_t& kiPicW) { uint8_t* pTmp = pDst + (kiMbY << 3) * kiStride + kiPicW; for (int32_t i = 0; i < 8; ++i) { // pad right memset (pTmp, pTmp[-1], CHROMA_PADDING_LENGTH); pTmp += kiStride; } } void PadMBLuma_c (uint8_t*& pDst, const int32_t& kiStride, const int32_t& kiPicW, const int32_t& kiPicH, const int32_t& kiMbX, const int32_t& kiMbY, const int32_t& kiMBWidth, const int32_t& kiMBHeight) { if (kiMbX == 0 && kiMbY == 0) { MBPadTopLeftLuma_c (pDst, kiStride); } else if (kiMbY == 0 && kiMbX == kiMBWidth - 1) { MBPadTopRightLuma_c (pDst, kiStride, kiPicW); } else if (kiMbY == kiMBHeight - 1 && kiMbX == 0) { MBPadBottomLeftLuma_c (pDst, kiStride, kiPicH); } else if (kiMbY == kiMBHeight - 1 && kiMbX == kiMBWidth - 1) { MBPadBottomRightLuma_c (pDst, kiStride, kiPicW, kiPicH); } if (kiMbX == 0) { MBPadLeftLuma_c (pDst, kiStride, kiMbY); } else if (kiMbX == kiMBWidth - 1) { MBPadRightLuma_c (pDst, kiStride, kiMbY, kiPicW); } if (kiMbY == 0 && kiMbX > 0 && kiMbX < kiMBWidth - 1) { MBPadTopLuma_c (pDst, kiStride, kiMbX); } else if (kiMbY == kiMBHeight - 1 && kiMbX > 0 && kiMbX < kiMBWidth - 1) { MBPadBottomLuma_c (pDst, kiStride, kiMbX, kiPicH); } } void PadMBChroma_c (uint8_t*& pDst, const int32_t& kiStride, const int32_t& kiPicW, const int32_t& kiPicH, const int32_t& kiMbX, const int32_t& kiMbY, const int32_t& kiMBWidth, const int32_t& kiMBHeight) { if (kiMbX == 0 && kiMbY == 0) { MBPadTopLeftChroma_c (pDst, kiStride); } else if (kiMbY == 0 && kiMbX == kiMBWidth - 1) { MBPadTopRightChroma_c (pDst, kiStride, kiPicW); } else if (kiMbY == kiMBHeight - 1 && kiMbX == 0) { MBPadBottomLeftChroma_c (pDst, kiStride, kiPicH); } else if (kiMbY == kiMBHeight - 1 && kiMbX == kiMBWidth - 1) { MBPadBottomRightChroma_c (pDst, kiStride, kiPicW, kiPicH); } if (kiMbX == 0) { MBPadLeftChroma_c (pDst, kiStride, kiMbY); } else if (kiMbX == kiMBWidth - 1) { MBPadRightChroma_c (pDst, kiStride, kiMbY, kiPicW); } if (kiMbY == 0 && kiMbX > 0 && kiMbX < kiMBWidth - 1) { MBPadTopChroma_c (pDst, kiStride, kiMbX); } else if (kiMbY == kiMBHeight - 1 && kiMbX > 0 && kiMbX < kiMBWidth - 1) { MBPadBottomChroma_c (pDst, kiStride, kiMbX, kiPicH); } } // rewrite it (split into luma & chroma) that is helpful for mmx/sse2 optimization perform, 9/27/2009 static inline void ExpandPictureLuma_c (uint8_t* pDst, const int32_t kiStride, const int32_t kiPicW, const int32_t kiPicH) { uint8_t* pTmp = pDst; uint8_t* pDstLastLine = pTmp + (kiPicH - 1) * kiStride; const int32_t kiPaddingLen = PADDING_LENGTH; const uint8_t kuiTL = pTmp[0]; const uint8_t kuiTR = pTmp[kiPicW - 1]; const uint8_t kuiBL = pDstLastLine[0]; const uint8_t kuiBR = pDstLastLine[kiPicW - 1]; int32_t i = 0; do { const int32_t kiStrides = (1 + i) * kiStride; uint8_t* pTop = pTmp - kiStrides; uint8_t* pBottom = pDstLastLine + kiStrides; // pad pTop and pBottom memcpy (pTop, pTmp, kiPicW); // confirmed_safe_unsafe_usage memcpy (pBottom, pDstLastLine, kiPicW); // confirmed_safe_unsafe_usage // pad corners memset (pTop - kiPaddingLen, kuiTL, kiPaddingLen); //pTop left memset (pTop + kiPicW, kuiTR, kiPaddingLen); //pTop right memset (pBottom - kiPaddingLen, kuiBL, kiPaddingLen); //pBottom left memset (pBottom + kiPicW, kuiBR, kiPaddingLen); //pBottom right ++ i; } while (i < kiPaddingLen); // pad left and right i = 0; do { memset (pTmp - kiPaddingLen, pTmp[0], kiPaddingLen); memset (pTmp + kiPicW, pTmp[kiPicW - 1], kiPaddingLen); pTmp += kiStride; ++ i; } while (i < kiPicH); } static inline void ExpandPictureChroma_c (uint8_t* pDst, const int32_t kiStride, const int32_t kiPicW, const int32_t kiPicH) { uint8_t* pTmp = pDst; uint8_t* pDstLastLine = pTmp + (kiPicH - 1) * kiStride; const int32_t kiPaddingLen = (PADDING_LENGTH >> 1); const uint8_t kuiTL = pTmp[0]; const uint8_t kuiTR = pTmp[kiPicW - 1]; const uint8_t kuiBL = pDstLastLine[0]; const uint8_t kuiBR = pDstLastLine[kiPicW - 1]; int32_t i = 0; do { const int32_t kiStrides = (1 + i) * kiStride; uint8_t* pTop = pTmp - kiStrides; uint8_t* pBottom = pDstLastLine + kiStrides; // pad pTop and pBottom memcpy (pTop, pTmp, kiPicW); // confirmed_safe_unsafe_usage memcpy (pBottom, pDstLastLine, kiPicW); // confirmed_safe_unsafe_usage // pad corners memset (pTop - kiPaddingLen, kuiTL, kiPaddingLen); //pTop left memset (pTop + kiPicW, kuiTR, kiPaddingLen); //pTop right memset (pBottom - kiPaddingLen, kuiBL, kiPaddingLen); //pBottom left memset (pBottom + kiPicW, kuiBR, kiPaddingLen); //pBottom right ++ i; } while (i < kiPaddingLen); // pad left and right i = 0; do { memset (pTmp - kiPaddingLen, pTmp[0], kiPaddingLen); memset (pTmp + kiPicW, pTmp[kiPicW - 1], kiPaddingLen); pTmp += kiStride; ++ i; } while (i < kiPicH); } void InitExpandPictureFunc (SExpandPicFunc* pExpandPicFunc, const uint32_t kuiCPUFlag) { pExpandPicFunc->pfExpandLumaPicture = ExpandPictureLuma_c; pExpandPicFunc->pfExpandChromaPicture[0] = ExpandPictureChroma_c; pExpandPicFunc->pfExpandChromaPicture[1] = ExpandPictureChroma_c; #if defined(X86_ASM) if ((kuiCPUFlag & WELS_CPU_SSE2) == WELS_CPU_SSE2) { pExpandPicFunc->pfExpandLumaPicture = ExpandPictureLuma_sse2; pExpandPicFunc->pfExpandChromaPicture[0] = ExpandPictureChromaUnalign_sse2; pExpandPicFunc->pfExpandChromaPicture[1] = ExpandPictureChromaAlign_sse2; } #endif//X86_ASM #if defined(HAVE_NEON) if (kuiCPUFlag & WELS_CPU_NEON) { pExpandPicFunc->pfExpandLumaPicture = ExpandPictureLuma_neon; pExpandPicFunc->pfExpandChromaPicture[0] = ExpandPictureChroma_neon; pExpandPicFunc->pfExpandChromaPicture[1] = ExpandPictureChroma_neon; } #endif//HAVE_NEON #if defined(HAVE_NEON_AARCH64) if (kuiCPUFlag & WELS_CPU_NEON) { pExpandPicFunc->pfExpandLumaPicture = ExpandPictureLuma_AArch64_neon; pExpandPicFunc->pfExpandChromaPicture[0] = ExpandPictureChroma_AArch64_neon; pExpandPicFunc->pfExpandChromaPicture[1] = ExpandPictureChroma_AArch64_neon; } #endif//HAVE_NEON_AARCH64 #if defined(HAVE_MMI) if (kuiCPUFlag & WELS_CPU_MMI) { pExpandPicFunc->pfExpandLumaPicture = ExpandPictureLuma_mmi; pExpandPicFunc->pfExpandChromaPicture[0] = ExpandPictureChromaUnalign_mmi; pExpandPicFunc->pfExpandChromaPicture[1] = ExpandPictureChromaAlign_mmi; } #endif//HAVE_MMI } //void ExpandReferencingPicture (SPicture* pPic, PExpandPictureFunc pExpLuma, PExpandPictureFunc pExpChrom[2]) { void ExpandReferencingPicture (uint8_t* pData[3], int32_t iWidth, int32_t iHeight, int32_t iStride[3], PExpandPictureFunc pExpLuma, PExpandPictureFunc pExpChrom[2]) { /*local variable*/ uint8_t* pPicY = pData[0]; uint8_t* pPicCb = pData[1]; uint8_t* pPicCr = pData[2]; const int32_t kiWidthY = iWidth; const int32_t kiHeightY = iHeight; const int32_t kiWidthUV = kiWidthY >> 1; const int32_t kiHeightUV = kiHeightY >> 1; pExpLuma (pPicY, iStride[0], kiWidthY, kiHeightY); if (kiWidthUV >= 16) { // fix coding picture size as 16x16 const bool kbChrAligned = /*(iWidthUV >= 16) && */ ((kiWidthUV & 0x0F) == 0); // chroma planes: (16+iWidthUV) & 15 pExpChrom[kbChrAligned] (pPicCb, iStride[1], kiWidthUV, kiHeightUV); pExpChrom[kbChrAligned] (pPicCr, iStride[2], kiWidthUV, kiHeightUV); } else { // fix coding picture size as 16x16 ExpandPictureChroma_c (pPicCb, iStride[1], kiWidthUV, kiHeightUV); ExpandPictureChroma_c (pPicCr, iStride[2], kiWidthUV, kiHeightUV); } }