ref: 05bf57a2af593ff8d946b8619262ece147ab5fa9
dir: /codec/processing/src/complexityanalysis/ComplexityAnalysis.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 "ComplexityAnalysis.h" #include "../common/cpu.h" WELSVP_NAMESPACE_BEGIN /////////////////////////////////////////////////////////////////////////////////////////////////////////////// CComplexityAnalysis::CComplexityAnalysis (int32_t iCpuFlag) { m_eMethod = METHOD_COMPLEXITY_ANALYSIS; m_pfGomSad = NULL; WelsMemset (&m_sComplexityAnalysisParam, 0, sizeof (m_sComplexityAnalysisParam)); } CComplexityAnalysis::~CComplexityAnalysis() { } EResult CComplexityAnalysis::Process (int32_t iType, SPixMap* pSrcPixMap, SPixMap* pRefPixMap) { EResult eReturn = RET_SUCCESS; switch (m_sComplexityAnalysisParam.iComplexityAnalysisMode) { case FRAME_SAD: AnalyzeFrameComplexityViaSad (pSrcPixMap, pRefPixMap); break; case GOM_SAD: AnalyzeGomComplexityViaSad (pSrcPixMap, pRefPixMap); break; case GOM_VAR: AnalyzeGomComplexityViaVar (pSrcPixMap, pRefPixMap); break; default: eReturn = RET_INVALIDPARAM; break; } return eReturn; } EResult CComplexityAnalysis::Set (int32_t iType, void* pParam) { if (pParam == NULL) { return RET_INVALIDPARAM; } m_sComplexityAnalysisParam = * (SComplexityAnalysisParam*)pParam; return RET_SUCCESS; } EResult CComplexityAnalysis::Get (int32_t iType, void* pParam) { if (pParam == NULL) { return RET_INVALIDPARAM; } SComplexityAnalysisParam* sComplexityAnalysisParam = (SComplexityAnalysisParam*)pParam; sComplexityAnalysisParam->iFrameComplexity = m_sComplexityAnalysisParam.iFrameComplexity; return RET_SUCCESS; } /////////////////////////////////////////////////////////////////////////////////////////////// void CComplexityAnalysis::AnalyzeFrameComplexityViaSad (SPixMap* pSrcPixMap, SPixMap* pRefPixMap) { SVAACalcResult* pVaaCalcResults = NULL; pVaaCalcResults = m_sComplexityAnalysisParam.pCalcResult; m_sComplexityAnalysisParam.iFrameComplexity = pVaaCalcResults->iFrameSad; if (m_sComplexityAnalysisParam.iCalcBgd) { //BGD control m_sComplexityAnalysisParam.iFrameComplexity = (int32_t)GetFrameSadExcludeBackground (pSrcPixMap, pRefPixMap); } } int32_t CComplexityAnalysis::GetFrameSadExcludeBackground (SPixMap* pSrcPixMap, SPixMap* pRefPixMap) { int32_t iWidth = pSrcPixMap->sRect.iRectWidth; int32_t iHeight = pSrcPixMap->sRect.iRectHeight; int32_t iMbWidth = iWidth >> 4; int32_t iMbHeight = iHeight >> 4; int32_t iMbNum = iMbWidth * iMbHeight; int32_t iMbNumInGom = m_sComplexityAnalysisParam.iMbNumInGom; int32_t iGomMbNum = (iMbNum + iMbNumInGom - 1) / iMbNumInGom; int32_t iGomMbStartIndex = 0, iGomMbEndIndex = 0; uint8_t* pBackgroundMbFlag = (uint8_t*)m_sComplexityAnalysisParam.pBackgroundMbFlag; uint32_t* uiRefMbType = (uint32_t*)m_sComplexityAnalysisParam.uiRefMbType; SVAACalcResult* pVaaCalcResults = m_sComplexityAnalysisParam.pCalcResult; int32_t* pGomForegroundBlockNum = m_sComplexityAnalysisParam.pGomForegroundBlockNum; uint32_t uiFrameSad = 0; for (int32_t j = 0; j < iGomMbNum; j ++) { iGomMbStartIndex = j * iMbNumInGom; iGomMbEndIndex = WELS_MIN ((j + 1) * iMbNumInGom, iMbNum); for (int32_t i = iGomMbStartIndex; i < iGomMbEndIndex; i ++) { if (pBackgroundMbFlag[i] == 0 || IS_INTRA (uiRefMbType[i])) { pGomForegroundBlockNum[j]++; uiFrameSad += pVaaCalcResults->pSad8x8[i][0]; uiFrameSad += pVaaCalcResults->pSad8x8[i][1]; uiFrameSad += pVaaCalcResults->pSad8x8[i][2]; uiFrameSad += pVaaCalcResults->pSad8x8[i][3]; } } } return (uiFrameSad); } void InitGomSadFunc (PGOMSadFunc& pfGomSad, uint8_t iCalcBgd) { pfGomSad = GomSampleSad; if (iCalcBgd) { pfGomSad = GomSampleSadExceptBackground; } } void GomSampleSad (uint32_t* pGomSad, int32_t* pGomForegroundBlockNum, int32_t* pSad8x8, uint8_t pBackgroundMbFlag) { (*pGomForegroundBlockNum) ++; *pGomSad += pSad8x8[0]; *pGomSad += pSad8x8[1]; *pGomSad += pSad8x8[2]; *pGomSad += pSad8x8[3]; } void GomSampleSadExceptBackground (uint32_t* pGomSad, int32_t* pGomForegroundBlockNum, int32_t* pSad8x8, uint8_t pBackgroundMbFlag) { if (pBackgroundMbFlag == 0) { (*pGomForegroundBlockNum) ++; *pGomSad += pSad8x8[0]; *pGomSad += pSad8x8[1]; *pGomSad += pSad8x8[2]; *pGomSad += pSad8x8[3]; } } void CComplexityAnalysis::AnalyzeGomComplexityViaSad (SPixMap* pSrcPixMap, SPixMap* pRefPixMap) { int32_t iWidth = pSrcPixMap->sRect.iRectWidth; int32_t iHeight = pSrcPixMap->sRect.iRectHeight; int32_t iMbWidth = iWidth >> 4; int32_t iMbHeight = iHeight >> 4; int32_t iMbNum = iMbWidth * iMbHeight; int32_t iMbNumInGom = m_sComplexityAnalysisParam.iMbNumInGom; int32_t iGomMbNum = (iMbNum + iMbNumInGom - 1) / iMbNumInGom; int32_t iGomMbStartIndex = 0, iGomMbEndIndex = 0, iGomMbRowNum = 0; int32_t iMbStartIndex = 0, iMbEndIndex = 0; int32_t iStartSampleIndex = 0; uint8_t* pBackgroundMbFlag = (uint8_t*)m_sComplexityAnalysisParam.pBackgroundMbFlag; uint32_t* uiRefMbType = (uint32_t*)m_sComplexityAnalysisParam.uiRefMbType; SVAACalcResult* pVaaCalcResults = m_sComplexityAnalysisParam.pCalcResult; int32_t* pGomForegroundBlockNum = (int32_t*)m_sComplexityAnalysisParam.pGomForegroundBlockNum; int32_t* pGomComplexity = (int32_t*)m_sComplexityAnalysisParam.pGomComplexity; uint8_t* pRefY = NULL, *pSrcY = NULL; int32_t iRefStride = 0, iCurStride = 0; uint8_t* pRefTmp = NULL, *pCurTmp = NULL; uint32_t uiGomSad = 0, uiFrameSad = 0; pRefY = (uint8_t*)pRefPixMap->pPixel[0]; pSrcY = (uint8_t*)pSrcPixMap->pPixel[0]; iRefStride = pRefPixMap->iStride[0]; iCurStride = pSrcPixMap->iStride[0]; InitGomSadFunc (m_pfGomSad, m_sComplexityAnalysisParam.iCalcBgd); for (int32_t j = 0; j < iGomMbNum; j ++) { uiGomSad = 0; iGomMbStartIndex = j * iMbNumInGom; iGomMbEndIndex = WELS_MIN ((j + 1) * iMbNumInGom, iMbNum); iGomMbRowNum = (iGomMbEndIndex + iMbWidth - 1) / iMbWidth - iGomMbStartIndex / iMbWidth; iMbStartIndex = iGomMbStartIndex; iMbEndIndex = WELS_MIN ((iMbStartIndex / iMbWidth + 1) * iMbWidth, iGomMbEndIndex); iStartSampleIndex = (iMbStartIndex / iMbWidth) * MB_WIDTH_LUMA * iRefStride + (iMbStartIndex % iMbWidth) * MB_WIDTH_LUMA; do { pRefTmp = pRefY + iStartSampleIndex; pCurTmp = pSrcY + iStartSampleIndex; for (int32_t i = iMbStartIndex; i < iMbEndIndex; i ++) { m_pfGomSad (&uiGomSad, pGomForegroundBlockNum + j, pVaaCalcResults->pSad8x8[i], pBackgroundMbFlag[i] && !IS_INTRA (uiRefMbType[i])); } iMbStartIndex = iMbEndIndex; iMbEndIndex = WELS_MIN (iMbEndIndex + iMbWidth , iGomMbEndIndex); iStartSampleIndex = (iMbStartIndex / iMbWidth) * MB_WIDTH_LUMA * iRefStride + (iMbStartIndex % iMbWidth) * MB_WIDTH_LUMA; } while (--iGomMbRowNum); pGomComplexity[j] = uiGomSad; uiFrameSad += pGomComplexity[j]; } m_sComplexityAnalysisParam.iFrameComplexity = uiFrameSad; } void CComplexityAnalysis::AnalyzeGomComplexityViaVar (SPixMap* pSrcPixMap, SPixMap* pRefPixMap) { int32_t iWidth = pSrcPixMap->sRect.iRectWidth; int32_t iHeight = pSrcPixMap->sRect.iRectHeight; int32_t iMbWidth = iWidth >> 4; int32_t iMbHeight = iHeight >> 4; int32_t iMbNum = iMbWidth * iMbHeight; int32_t iMbNumInGom = m_sComplexityAnalysisParam.iMbNumInGom; int32_t iGomMbNum = (iMbNum + iMbNumInGom - 1) / iMbNumInGom; int32_t iGomSampleNum = 0; int32_t iGomMbStartIndex = 0, iGomMbEndIndex = 0, iGomMbRowNum = 0; int32_t iMbStartIndex = 0, iMbEndIndex = 0; int32_t iStartSampleIndex = 0; SVAACalcResult* pVaaCalcResults = m_sComplexityAnalysisParam.pCalcResult; int32_t* pGomComplexity = (int32_t*)m_sComplexityAnalysisParam.pGomComplexity; uint8_t* pSrcY = NULL; int32_t iCurStride = 0; uint8_t* pCurTmp = NULL; uint32_t uiSampleSum = 0, uiSquareSum = 0; pSrcY = (uint8_t*)pSrcPixMap->pPixel[0]; iCurStride = pSrcPixMap->iStride[0]; for (int32_t j = 0; j < iGomMbNum; j ++) { uiSampleSum = 0; uiSquareSum = 0; iGomMbStartIndex = j * iMbNumInGom; iGomMbEndIndex = WELS_MIN ((j + 1) * iMbNumInGom, iMbNum); iGomMbRowNum = (iGomMbEndIndex + iMbWidth - 1) / iMbWidth - iGomMbStartIndex / iMbWidth; iMbStartIndex = iGomMbStartIndex; iMbEndIndex = WELS_MIN ((iMbStartIndex / iMbWidth + 1) * iMbWidth, iGomMbEndIndex); iStartSampleIndex = (iMbStartIndex / iMbWidth) * MB_WIDTH_LUMA * iCurStride + (iMbStartIndex % iMbWidth) * MB_WIDTH_LUMA; iGomSampleNum = (iMbEndIndex - iMbStartIndex) * MB_WIDTH_LUMA * MB_WIDTH_LUMA; do { pCurTmp = pSrcY + iStartSampleIndex; for (int32_t i = iMbStartIndex; i < iMbEndIndex; i ++) { uiSampleSum += pVaaCalcResults->pSum16x16[i]; uiSquareSum += pVaaCalcResults->pSumOfSquare16x16[i]; } iMbStartIndex = iMbEndIndex; iMbEndIndex = WELS_MIN (iMbEndIndex + iMbWidth, iGomMbEndIndex); iStartSampleIndex = (iMbStartIndex / iMbWidth) * MB_WIDTH_LUMA * iCurStride + (iMbStartIndex % iMbWidth) * MB_WIDTH_LUMA; } while (--iGomMbRowNum); pGomComplexity[j] = uiSquareSum - (uiSampleSum * uiSampleSum / iGomSampleNum); } } WELSVP_NAMESPACE_END