#define LOG_TAG "xmetadataretriever" #include "log.h" #include "xmetadataretriever.h" #include "memoryAdapter.h" #include #include #include #include #define SAVE_BITSTREAM 0 #define SAVE_RGB 0 #if SAVE_BITSTREAM const char* bitstreamPath = "/data/camera/out.h264"; static FILE* fph264 = NULL; #endif #define MAX_PACKET_COUNT_TO_GET_A_FRAME 4096 /* process 1024 packets to get a frame at maximum. */ #define MAX_TIME_TO_GET_A_FRAME 5000000 /* use 5 seconds to get a frame at maximum. */ #define MAX_TIME_TO_GET_A_STREAM 10000000 /* use 10 seconds to get a stream at maximum. */ #define MAX_OUTPUT_STREAM_SIZE (1024*1024) typedef struct AwRetriverContext { CdxDataSourceT mSource; CdxMediaInfoT mMediaInfo; CdxParserT* mParser; CdxStreamT* mStream; VideoDecoder* mVideoDecoder; VideoFrame mVideoFrame; int mCancelPrepareFlag; struct ScMemOpsS *memops; }AwRetriverContext; static int64_t GetSysTime(); #if SAVE_RGB //------------------------------------------------------------------- /*   位图文件的组成 结构名称 符 号 位图文件头 (bitmap-file header) BITMAPFILEHEADER bmfh 位图信息头 (bitmap-information header) BITMAPINFOHEADER bmih 彩色表 (color table) RGBQUAD aColors[] 图象数据阵列字节 BYTE aBitmapBits[] */ typedef struct bmp_header { short twobyte ;//两个字节,用来保证下面成员紧凑排列,这两个字符不能写到文件中 //14B char bfType[2] ;//!文件的类型,该值必需是0x4D42,也就是字符'BM' unsigned int bfSize ;//!说明文件的大小,用字节为单位 unsigned int bfReserved1;//保留,必须设置为0 unsigned int bfOffBits ;//!说明从文件头开始到实际的图象数据之间的字节的偏移量,这里为14B+sizeof(BMPINFO) }BMPHEADER; typedef struct bmp_info { //40B unsigned int biSize ;//!BMPINFO结构所需要的字数 int biWidth ;//!图象的宽度,以象素为单位 int biHeight ;//!图象的宽度,以象素为单位,如果该值是正数,说明图像是倒向的,如果该值是负数,则是正向的 unsigned short biPlanes ;//!目标设备说明位面数,其值将总是被设为1 unsigned short biBitCount ;//!比特数/象素,其值为1、4、8、16、24、或32 unsigned int biCompression ;//说明图象数据压缩的类型 #define BI_RGB 0L //没有压缩 #define BI_RLE8 1L //每个象素8比特的RLE压缩编码,压缩格式由2字节组成(重复象素计数和颜色索引); #define BI_RLE4 2L //每个象素4比特的RLE压缩编码,压缩格式由2字节组成 #define BI_BITFIELDS 3L //每个象素的比特由指定的掩码决定。 unsigned int biSizeImage ;//图象的大小,以字节为单位。当用BI_RGB格式时,可设置为0 int biXPelsPerMeter ;//水平分辨率,用象素/米表示 int biYPelsPerMeter ;//垂直分辨率,用象素/米表示 unsigned int biClrUsed ;//位图实际使用的彩色表中的颜色索引数(设为0的话,则说明使用所有调色板项) unsigned int biClrImportant ;//对图象显示有重要影响的颜色索引的数目,如果是0,表示都重要。 }BMPINFO; typedef struct tagRGBQUAD { unsigned char rgbBlue; unsigned char rgbGreen; unsigned char rgbRed; unsigned char rgbReserved; } RGBQUAD; typedef struct tagBITMAPINFO { BMPINFO bmiHeader; //RGBQUAD bmiColors[1]; unsigned int rgb[3]; } BITMAPINFO; static int get_rgb565_header(int w, int h, BMPHEADER * head, BITMAPINFO * info) { int size = 0; if (head && info) { size = w * h * 2; memset(head, 0, sizeof(* head)); memset(info, 0, sizeof(* info)); head->bfType[0] = 'B'; head->bfType[1] = 'M'; head->bfOffBits = 14 + sizeof(* info); head->bfSize = head->bfOffBits + size; head->bfSize = (head->bfSize + 3) & ~3; size = head->bfSize - head->bfOffBits; info->bmiHeader.biSize = sizeof(info->bmiHeader); info->bmiHeader.biWidth = w; info->bmiHeader.biHeight = -h; info->bmiHeader.biPlanes = 1; info->bmiHeader.biBitCount = 16; info->bmiHeader.biCompression = BI_BITFIELDS; info->bmiHeader.biSizeImage = size; info->rgb[0] = 0xF800; info->rgb[1] = 0x07E0; info->rgb[2] = 0x001F; logd("rgb565:%dbit,%d*%d,%d\n", info->bmiHeader.biBitCount, w, h, head->bfSize); } return size; } static int save_bmp_rgb565(FILE* fp, int width, int height, unsigned char* pData) { int success = 0; int size = 0; BMPHEADER head; BITMAPINFO info; size = get_rgb565_header(width, height, &head, &info); if(size > 0) { fwrite(head.bfType,1,2,fp); fwrite(&head.bfSize,1,4,fp); fwrite(&head.bfReserved1,1,4,fp); fwrite(&head.bfOffBits,1,4,fp); fwrite(&info,1,sizeof(info), fp); fwrite(pData,1,size, fp); success = 1; } logd("*****success=%d\n", success); return success; } #endif // B = 1.164 * (Y - 16) + 2.018 * (U - 128) // G = 1.164 * (Y - 16) - 0.813 * (V - 128) - 0.391 * (U - 128) // R = 1.164 * (Y - 16) + 1.596 * (V - 128) // B = 298/256 * (Y - 16) + 517/256 * (U - 128) // G = .................. - 208/256 * (V - 128) - 100/256 * (U - 128) // R = .................. + 409/256 * (V - 128) // min_B = (298 * (- 16) + 517 * (- 128)) / 256 = -277 // min_G = (298 * (- 16) - 208 * (255 - 128) - 100 * (255 - 128)) / 256 = -172 // min_R = (298 * (- 16) + 409 * (- 128)) / 256 = -223 // max_B = (298 * (255 - 16) + 517 * (255 - 128)) / 256 = 534 // max_G = (298 * (255 - 16) - 208 * (- 128) - 100 * (- 128)) / 256 = 432 // max_R = (298 * (255 - 16) + 409 * (255 - 128)) / 256 = 481 // clip range -278 .. 535 typedef struct { int nPicWidth; int nPicHeight; unsigned char* pData; unsigned int nDataSize; }RgbVideoFrame; static int transformPictureMb32ToRGB(struct ScMemOpsS *memOps, VideoPicture* pPicture, VideoFrame* pVideoFrame) { unsigned char* pClipTable; unsigned char* pClip; static const int nClipMin = -278; static const int nClipMax = 535; unsigned short* pDst = NULL; unsigned char* pSrcY = NULL; unsigned char* pSrcVU = NULL; int x = 0; int y = 0; int nMbWidth = 0; int nMbHeight = 0; int nVMb = 0; int nHMb = 0; int yPos = 0; int pos = 0; int uvPos = 0; // 可以将pClipTable 以参数的形式传入transformPictureMb32ToRGB //* initialize the clip table. pClipTable = (unsigned char*)malloc(nClipMax - nClipMin + 1); if(pClipTable == NULL) { loge("can not allocate memory for the clip table, quit."); return -1; } for(x=nClipMin; x<=nClipMax; x++) { pClipTable[x-nClipMin] = (x<0) ? 0 : (x>255) ? 255 : x; } pClip = &pClipTable[-nClipMin]; //* flush cache. CdcMemFlushCache(memOps, pPicture->pData0, pPicture->nWidth*pPicture->nHeight); CdcMemFlushCache(memOps, pPicture->pData1, pPicture->nHeight*pPicture->nHeight/2); pDst = (unsigned short*)pVideoFrame->mData; pSrcY = (unsigned char*)pPicture->pData0; pSrcVU = (unsigned char*)pPicture->pData1; nMbWidth = pPicture->nWidth/32; nMbHeight = pPicture->nHeight/32; for(nVMb=0; nVMbnWidth*32+nHMb*32; for(y=0; y<32; y++) { yPos = (nVMb*nMbWidth+nHMb)*1024+y*32; uvPos = ((nVMb/2)*nMbWidth*1024)+nHMb*1024+(y/2)*32+ (((nVMb%2)==1) ? 512 : 0); for(x=0; x<32; x+=2) { signed y1 = (signed)pSrcY[yPos+x+0] - 16; signed y2 = (signed)pSrcY[yPos+x+1] - 16; signed u = (signed)pSrcVU[uvPos+x+0] - 128; signed v = (signed)pSrcVU[uvPos+x+1] - 128; signed u_b = u * 517; signed u_g = -u * 100; signed v_g = -v * 208; signed v_r = v * 409; signed tmp1 = y1 * 298; signed b1 = (tmp1 + u_b) / 256; signed g1 = (tmp1 + v_g + u_g) / 256; signed r1 = (tmp1 + v_r) / 256; signed tmp2 = y2 * 298; signed b2 = (tmp2 + u_b) / 256; signed g2 = (tmp2 + v_g + u_g) / 256; signed r2 = (tmp2 + v_r) / 256; unsigned int rgb1 = ((pClip[r1] >> 3) << 11) | ((pClip[g1] >> 2) << 5) | (pClip[b1] >> 3); unsigned int rgb2 = ((pClip[r2] >> 3) << 11) | ((pClip[g2] >> 2) << 5) | (pClip[b2] >> 3); *(unsigned int *)(&pDst[pos]) = (rgb2 << 16) | rgb1; pos += 2; } pos += (nMbWidth-1)*32; } } } pDst = (unsigned short*)pVideoFrame->mData; for(y=0; ynTopOffset; y++) { memset(pDst+y*pVideoFrame->mWidth, 0, 2*pVideoFrame->mWidth); } for(y=pPicture->nBottomOffset; ymHeight; y++) { memset(pDst+y*pVideoFrame->mWidth, 0, 2*pVideoFrame->mWidth); } for(y=pPicture->nTopOffset; ynBottomOffset; y++) { memset(pDst+y*pVideoFrame->mWidth, 0, 2*pPicture->nLeftOffset); memset(pDst+y*pVideoFrame->mWidth+pPicture->nRightOffset, 0, 2*(pVideoFrame->mWidth-pPicture->nRightOffset)); } free(pClipTable); #if SAVE_RGB FILE* outFp = fopen("/data/UDISK/rgb.bmp", "wb"); if(outFp != NULL) { logd("************save_bmp_rgb565\n"); save_bmp_rgb565(outFp, pVideoFrame->mWidth, pVideoFrame->mHeight, pVideoFrame->mData); fclose(outFp); } #endif return 0; } static int transformPicture(struct ScMemOpsS *memOps, VideoPicture* pPicture, VideoFrame* pVideoFrame); static void clear(AwRetriever* v) { AwRetriverContext* p; p = (AwRetriverContext*)v; if(p->mParser) { CdxParserForceStop(p->mParser); //* to prevend parser from blocking at a network io. CdxParserClose(p->mParser); p->mParser = NULL; p->mStream = NULL; } else if(p->mStream) { CdxStreamForceStop(p->mStream); CdxStreamClose(p->mStream); p->mStream = NULL; } if(p->mVideoDecoder != NULL) { DestroyVideoDecoder(p->mVideoDecoder); p->mVideoDecoder = NULL; } if(p->mSource.uri) { free(p->mSource.uri); } memset(&p->mMediaInfo, 0, sizeof(CdxMediaInfoT)); if(p->mVideoFrame.mData) { free(p->mVideoFrame.mData); p->mVideoFrame.mData = NULL; } memset(&p->mVideoFrame, 0x00, sizeof(VideoFrame)); return; } AwRetriever* AwRetrieverCreate() { AwRetriverContext* p; p = (AwRetriverContext*)malloc(sizeof(AwRetriverContext)); if(!p) { return NULL; } memset(p, 0x00, sizeof(AwRetriverContext)); memset(&p->mSource, 0, sizeof(CdxDataSourceT)); p->memops = MemAdapterGetOpsS(); if(p->memops == NULL) { free(p); return NULL; } CdcMemOpen(p->memops); return (AwRetriever*)p; } int AwRetrieverDestory(AwRetriever* v) { AwRetriverContext* p; p = (AwRetriverContext*)v; clear(v); CdcMemClose(p->memops); free(p); return 0; } int AwRetrieverSetDataSource(AwRetriever* v, const char* pUrl) { AwRetriverContext* p; p = (AwRetriverContext*)v; clear(v); //* 1. set the datasource object. //* check whether ths uri has a scheme. if(strstr(pUrl, "://") != NULL) { p->mSource.uri = strdup(pUrl); if(p->mSource.uri == NULL) { loge("can not dump string of uri."); return -1; } } else { p->mSource.uri = (char*)malloc(strlen(pUrl)+8); if(p->mSource.uri == NULL) { loge("can not dump string of uri."); return -1; } sprintf(p->mSource.uri, "file://%s", pUrl); } logd("uri: %s", p->mSource.uri); //* 2. create a parser. p->mStream = CdxStreamCreate(&p->mSource); if(!p->mStream) { loge("stream creat fail."); return -1; } int ret = CdxStreamConnect(p->mStream); if(ret < 0) { return -1; } p->mParser = CdxParserCreate(p->mStream, MUTIL_AUDIO); if(!p->mParser) { loge("parser creat fail."); return -1; } ret = CdxParserInit(p->mParser); if(ret < 0) { return -1; } //* 3. get media info. memset(&p->mMediaInfo, 0, sizeof(CdxMediaInfoT)); if(CdxParserGetMediaInfo(p->mParser, &p->mMediaInfo) == 0) { if (p->mParser->type == CDX_PARSER_TS || p->mParser->type == CDX_PARSER_BD || p->mParser->type == CDX_PARSER_HLS) { p->mMediaInfo.program[0].video[0].bIsFramePackage = 0; /* stream package */ } else { p->mMediaInfo.program[0].video[0].bIsFramePackage = 1; /* frame package */ } } return 0; } VideoFrame *AwRetrieverGetFrameAtTime(AwRetriever* v, int64_t timeUs) { VideoPicture* pPicture; int bDone; int bSuccess; int bHasVideo; int nHorizonScaleRatio; int nVerticalScaleRatio; VConfig vconfig; CdxPacketT packet; int ret; int nPacketCount; int64_t nStartTime; int64_t nTimePassed; AwRetriverContext* p; p = (AwRetriverContext*)v; //* FIXME: //* if it is a media file with drm protection, we should not return an album art picture. #if MediaScanDedug logd("getFrameAtTime, mFd=%d", mFd); #endif bDone = 0; bSuccess = 0; bHasVideo = 0; memset(&vconfig, 0, sizeof(VConfig)); //* 1. check whether there is a video stream. if(p->mMediaInfo.programIndex >= 0 && p->mMediaInfo.programNum >= p->mMediaInfo.programIndex) { if(p->mMediaInfo.program[p->mMediaInfo.programIndex].videoNum > 0) bHasVideo = 1; } if(!bHasVideo) { logw("media file do not contain a video stream, getFrameAtTime() return fail."); return NULL; } //* 2. create a video decoder. if(p->mVideoDecoder == NULL) { p->mVideoDecoder = CreateVideoDecoder(); //* use decoder to capture thumbnail, decoder use less memory in this mode. vconfig.bThumbnailMode = 1; //* all decoder support YV12 format. #if(CONFIG_CHIP == OPTION_CHIP_C500 ) vconfig.eOutputPixelFormat = PIXEL_FORMAT_YUV_MB32_420; #else vconfig.eOutputPixelFormat = PIXEL_FORMAT_YV12; #endif //* no need to decode two picture when decoding a thumbnail picture. vconfig.bDisable3D = 1; vconfig.nAlignStride = 16;//* set align stride to 16 as defualt #if 1 //* set this flag when the parser can give this info, mov files recorded by iphone or android phone //* conains this info. //* set the rotation int nRotateDegree; int nRotation = atoi((const char*)p->mMediaInfo.rotate); if(nRotation == 0) nRotateDegree = 0; else if(nRotation == 90) nRotateDegree = 1; else if(nRotation == 180) nRotateDegree = 2; else if(nRotation == 270) nRotateDegree = 3; else nRotateDegree = 0; if(nRotateDegree != 0) { vconfig.bRotationEn = 1; vconfig.nRotateDegree = nRotateDegree; } else { vconfig.bRotationEn = 0; vconfig.nRotateDegree = 0; } #endif //* set the picture scale down ratio, we generate a picture with pixel size less than 640x480. nHorizonScaleRatio = 0; nVerticalScaleRatio = 0; if(vconfig.nRotateDegree == 1 || vconfig.nRotateDegree == 3) { if(p->mMediaInfo.program[p->mMediaInfo.programIndex].video[0].nWidth > 960 || p->mMediaInfo.program[p->mMediaInfo.programIndex].video[0].nWidth == 0) /* nWidth=0 treated as nWidth=1920 */ nHorizonScaleRatio = 2; //* scale down to 1/4 the original width; else if(p->mMediaInfo.program[p->mMediaInfo.programIndex].video[0].nWidth > 480) nHorizonScaleRatio = 1; //* scale down to 1/2 the original width; if(p->mMediaInfo.program[p->mMediaInfo.programIndex].video[0].nHeight > 1280 || p->mMediaInfo.program[p->mMediaInfo.programIndex].video[0].nHeight == 0) /* nHeight=0 treated as nHeight=1080 */ nVerticalScaleRatio = 2; //* scale down to 1/4 the original height; else if(p->mMediaInfo.program[p->mMediaInfo.programIndex].video[0].nHeight > 640) nVerticalScaleRatio = 1; //* scale down to 1/2 the original height; } else { if(p->mMediaInfo.program[p->mMediaInfo.programIndex].video[0].nWidth > 1280 || p->mMediaInfo.program[p->mMediaInfo.programIndex].video[0].nWidth == 0) /* nWidth=0 treated as nWidth=1920 */ nHorizonScaleRatio = 2; //* scale down to 1/4 the original width; else if(p->mMediaInfo.program[p->mMediaInfo.programIndex].video[0].nWidth > 640) nHorizonScaleRatio = 1; //* scale down to 1/2 the original width; if(p->mMediaInfo.program[p->mMediaInfo.programIndex].video[0].nHeight > 960 || p->mMediaInfo.program[p->mMediaInfo.programIndex].video[0].nHeight == 0) /* nHeight=0 treated as nHeight=1080 */ nVerticalScaleRatio = 2; //* scale down to 1/4 the original height; else if(p->mMediaInfo.program[p->mMediaInfo.programIndex].video[0].nHeight > 480) nVerticalScaleRatio = 1; //* scale down to 1/2 the original height; } //* set to the same scale ratio. if(nVerticalScaleRatio > nHorizonScaleRatio) nHorizonScaleRatio = nVerticalScaleRatio; else nVerticalScaleRatio = nHorizonScaleRatio; //* set scale ratio to vconfig. if(nHorizonScaleRatio || nVerticalScaleRatio) { vconfig.bScaleDownEn = 1; vconfig.nHorizonScaleDownRatio = nHorizonScaleRatio; vconfig.nVerticalScaleDownRatio = nVerticalScaleRatio; } //* initialize the decoder. vconfig.nVbvBufferSize = 2*1024*1024; vconfig.nDeInterlaceHoldingFrameBufferNum = NUM_OF_PICTURES_KEEPPED_BY_DEINTERLACE; vconfig.nDisplayHoldingFrameBufferNum = 0; vconfig.nRotateHoldingFrameBufferNum = NUM_OF_PICTURES_KEEPPED_BY_ROTATE; vconfig.nDecodeSmoothFrameBufferNum = NUM_OF_PICTURES_FOR_EXTRA_SMOOTH; vconfig.memops = p->memops; if(InitializeVideoDecoder(p->mVideoDecoder, &p->mMediaInfo.program[p->mMediaInfo.programIndex].video[0], &vconfig) != 0) { loge("initialize video decoder fail."); return NULL; } } if(timeUs < 0) { //The key frame of MKV always at the end of file, need reset to 0, //otherwise will return mix thumbnail if(p->mParser->type == CDX_PARSER_MKV) { timeUs = 0; } else { timeUs = ((int64_t)p->mMediaInfo.program[p->mMediaInfo.programIndex].duration*1000/2); } } if(p->mMediaInfo.program[p->mMediaInfo.programIndex].duration < 30000) { timeUs = 0; } //* 3. seek parser to the specific position. if(p->mMediaInfo.bSeekable && timeUs > 0 && timeUs < ((int64_t)p->mMediaInfo.program[p->mMediaInfo.programIndex].duration*1000)) { //* FIXME. //* we should seek to a position according to the 'option' param. //* option = 0 means seek to the sync frame privious to the timeUs. //* option = 1 means seek to the sync frame next to the timeUs. //* option = 2 means seek to the sync frame closest to the timeUs. //* option = 3 means seek to the closest frame to the timeUs. //* here we process all case as option = 0. if(CdxParserSeekTo(p->mParser, timeUs) != 0) { loge("can not seek media file to the specific time %lld us.", timeUs); return NULL; } } else { logw("media file do not support seek operation, get frame from the begin."); } //* 4. loop to decode a picture. nPacketCount = 0; nStartTime = GetSysTime(); do { //* 4.1 prefetch packet type and packet data size. packet.flags = 0; if(CdxParserPrefetch(p->mParser, &packet) != 0) { //* prefetch fail, may be file end reached. bDone = 1; bSuccess = 0; break; } //* 4.2 feed data to the video decoder. if(packet.type == CDX_MEDIA_VIDEO && (packet.flags&MINOR_STREAM)==0) { ret = RequestVideoStreamBuffer(p->mVideoDecoder, packet.length, (char**)&packet.buf, &packet.buflen, (char**)&packet.ringBuf, &packet.ringBufLen, 0); if(ret==0 && (packet.buflen+packet.ringBufLen)>=packet.length) { nPacketCount++; if(CdxParserRead(p->mParser, &packet) == 0) { VideoStreamDataInfo dataInfo; dataInfo.pData = (char*)packet.buf; dataInfo.nLength = packet.length; dataInfo.nPts = packet.pts; dataInfo.nPcr = -1; dataInfo.bIsFirstPart = 1; dataInfo.bIsLastPart = 1; dataInfo.nStreamIndex = 0; SubmitVideoStreamData(p->mVideoDecoder, &dataInfo, 0); } else { //* read data fail, may be data error. loge("read packet from parser fail."); bDone = 1; bSuccess = 0; break; } } else { //* no buffer, may be the decoder is full of stream. logw("waiting for stream buffer."); } } else { //* only process the major video stream. //* allocate a buffer to read uncare media data and skip it. packet.buf = malloc(packet.length); if(packet.buf != NULL) { nPacketCount++; packet.buflen = packet.length; packet.ringBuf = NULL; packet.ringBufLen = 0; if(CdxParserRead(p->mParser, &packet) == 0) { free(packet.buf); continue; } else { free(packet.buf); //* read data fail, may be data error. loge("read packet from parser fail."); bDone = 1; bSuccess = 0; break; } } else { loge("can not allocate buffer for none video packet."); bDone = 1; bSuccess = 0; break; } } //* 4.3 decode stream. ret = DecodeVideoStream(p->mVideoDecoder, 0 /*eos*/, 1/*key frame only*/, 0/*drop b frame*/, 0/*current time*/); if(ret < 0) { loge("decode stream return fail."); bDone = 1; bSuccess = 0; break; } else if(ret == VDECODE_RESULT_RESOLUTION_CHANGE) { logi("video resolution changed."); ReopenVideoEngine(p->mVideoDecoder, &vconfig, &p->mMediaInfo.program[p->mMediaInfo.programIndex].video[0]); continue; } //* 4.4 try to get a picture from the decoder. if(ret == VDECODE_RESULT_FRAME_DECODED || ret == VDECODE_RESULT_KEYFRAME_DECODED) { pPicture = RequestPicture(p->mVideoDecoder, 0/*the major stream*/); if(pPicture != NULL) { bDone = 1; bSuccess = 1; break; } } //* check whether cost too long time or process too much packets. nTimePassed = GetSysTime() - nStartTime; if(nTimePassed > MAX_TIME_TO_GET_A_FRAME || nTimePassed < 0) { logw("cost more than %d us but can not get a picture, quit.", MAX_TIME_TO_GET_A_FRAME); bDone = 1; bSuccess = 0; break; } if(nPacketCount > MAX_PACKET_COUNT_TO_GET_A_FRAME) { logw("process more than %d packets but can not get a picture, quit.", MAX_PACKET_COUNT_TO_GET_A_FRAME); bDone = 1; bSuccess = 0; break; } }while(!bDone); //* 5. transform the picture if suceess to get a picture. if(bSuccess) { //* let the width and height is multiple of 2, for convinient of yuv to rgb565 converting. if(pPicture->nLeftOffset & 1) pPicture->nLeftOffset += 1; if(pPicture->nRightOffset & 1) pPicture->nRightOffset -= 1; if(pPicture->nTopOffset & 1) pPicture->nTopOffset += 1; if(pPicture->nBottomOffset & 1) pPicture->nBottomOffset -= 1; //* I find that the mpeg2 decoder output the original picture's crop params, //* it is bigger than the scaledown picture's size. if((pPicture->nBottomOffset != 0 || pPicture->nRightOffset != 0) && pPicture->nRightOffset <= pPicture->nLineStride) { p->mVideoFrame.mDisplayWidth = pPicture->nRightOffset - pPicture->nLeftOffset; p->mVideoFrame.mDisplayHeight = pPicture->nBottomOffset - pPicture->nTopOffset; p->mVideoFrame.mWidth = p->mVideoFrame.mDisplayWidth; p->mVideoFrame.mHeight = p->mVideoFrame.mDisplayHeight; } else { p->mVideoFrame.mDisplayWidth = pPicture->nWidth; p->mVideoFrame.mDisplayHeight = pPicture->nHeight; p->mVideoFrame.mWidth = pPicture->nWidth; p->mVideoFrame.mHeight = pPicture->nHeight; } if(pPicture->ePixelFormat == PIXEL_FORMAT_YUV_MB32_420) { // for 1663, mb32 p->mVideoFrame.mDisplayWidth = pPicture->nWidth; p->mVideoFrame.mDisplayHeight = pPicture->nHeight; p->mVideoFrame.mWidth = pPicture->nWidth; p->mVideoFrame.mHeight = pPicture->nHeight; p->mVideoFrame.mSize = p->mVideoFrame.mWidth * p->mVideoFrame.mHeight * 2; p->mVideoFrame.mData = (unsigned char*)malloc(p->mVideoFrame.mSize); if(p->mVideoFrame.mData == NULL) { loge("can not allocate memory for video frame."); return NULL; } } else { p->mVideoFrame.mSize = p->mVideoFrame.mWidth * p->mVideoFrame.mHeight * 2; //* for RGB565 pixel format. p->mVideoFrame.mData = (unsigned char*)malloc(p->mVideoFrame.mSize); if(p->mVideoFrame.mData == NULL) { loge("can not allocate memory for video frame."); return NULL; } } p->mVideoFrame.mRotationAngle = 0; if(pPicture->ePixelFormat == PIXEL_FORMAT_YUV_MB32_420) { //* convert pixel format. if(transformPictureMb32ToRGB(p->memops, pPicture, &p->mVideoFrame) < 0) { return NULL; } } else { if(transformPicture(p->memops, pPicture, &p->mVideoFrame) < 0) { return NULL; } } return &p->mVideoFrame; } else { loge("cannot decode a picture."); return NULL; } } int AwRetrieverGetMetaData(AwRetriever* v, int type, void* pVal) { AwRetriverContext* p; p = (AwRetriverContext*)v; switch(type) { case METADATA_VIDEO_WIDTH: { int *w = (int*)pVal; logd("w: %d", p->mMediaInfo.program[0].video[0].nWidth); *w = p->mMediaInfo.program[0].video[0].nWidth; break; } case METADATA_VIDEO_HEIGHT: { int *h = (int*)pVal; logd("h: %d", p->mMediaInfo.program[0].video[0].nHeight); *h = p->mMediaInfo.program[0].video[0].nHeight; break; } case METADATA_DURATION: { int *duration = (int*)pVal; *duration = p->mMediaInfo.program[0].duration; break; } default: break; } return -1; } static int64_t GetSysTime() { int64_t time; struct timeval t; gettimeofday(&t, NULL); time = (int64_t)t.tv_sec * 1000000; time += t.tv_usec; return time; } static int transformPicture(struct ScMemOpsS *memOps, VideoPicture* pPicture, VideoFrame* pVideoFrame) { unsigned short* pDst; unsigned char* pSrcY; unsigned char* pSrcU; unsigned char* pSrcV; int y; int x; unsigned char* pClipTable; unsigned char* pClip; static const int nClipMin = -278; static const int nClipMax = 535; if((pPicture->ePixelFormat!= PIXEL_FORMAT_YV12) && (pPicture->ePixelFormat!= PIXEL_FORMAT_YUV_PLANER_420)) { loge("source pixel format is not YV12, quit."); return -1; } //* initialize the clip table. pClipTable = (unsigned char*)malloc(nClipMax - nClipMin + 1); if(pClipTable == NULL) { loge("can not allocate memory for the clip table, quit."); return -1; } for(x=nClipMin; x<=nClipMax; x++) { pClipTable[x-nClipMin] = (x<0) ? 0 : (x>255) ? 255 : x; } pClip = &pClipTable[-nClipMin]; //* flush cache. CdcMemFlushCache(memOps, pPicture->pData0, pPicture->nLineStride*pPicture->nHeight); CdcMemFlushCache(memOps, pPicture->pData1, pPicture->nLineStride*pPicture->nHeight/4); CdcMemFlushCache(memOps, pPicture->pData2, pPicture->nLineStride*pPicture->nHeight/4); //* set pointers. pDst = (unsigned short*)pVideoFrame->mData; pSrcY = (unsigned char*)pPicture->pData0 + pPicture->nTopOffset * pPicture->nLineStride + pPicture->nLeftOffset; if(pPicture->ePixelFormat== PIXEL_FORMAT_YV12) { pSrcV = (unsigned char*)pPicture->pData1 + (pPicture->nTopOffset/2) * (pPicture->nLineStride/2) + pPicture->nLeftOffset/2; pSrcU = (unsigned char*)pPicture->pData2 + (pPicture->nTopOffset/2) * (pPicture->nLineStride/2) + pPicture->nLeftOffset/2; } else { pSrcU = (unsigned char*)pPicture->pData1 + (pPicture->nTopOffset/2) * (pPicture->nLineStride/2) + pPicture->nLeftOffset/2; pSrcV = (unsigned char*)pPicture->pData2 + (pPicture->nTopOffset/2) * (pPicture->nLineStride/2) + pPicture->nLeftOffset/2; } for(y = 0; y < (int)pVideoFrame->mHeight; ++y) { for(x = 0; x < (int)pVideoFrame->mWidth; x += 2) { // B = 1.164 * (Y - 16) + 2.018 * (U - 128) // G = 1.164 * (Y - 16) - 0.813 * (V - 128) - 0.391 * (U - 128) // R = 1.164 * (Y - 16) + 1.596 * (V - 128) // B = 298/256 * (Y - 16) + 517/256 * (U - 128) // G = .................. - 208/256 * (V - 128) - 100/256 * (U - 128) // R = .................. + 409/256 * (V - 128) // min_B = (298 * (- 16) + 517 * (- 128)) / 256 = -277 // min_G = (298 * (- 16) - 208 * (255 - 128) - 100 * (255 - 128)) / 256 = -172 // min_R = (298 * (- 16) + 409 * (- 128)) / 256 = -223 // max_B = (298 * (255 - 16) + 517 * (255 - 128)) / 256 = 534 // max_G = (298 * (255 - 16) - 208 * (- 128) - 100 * (- 128)) / 256 = 432 // max_R = (298 * (255 - 16) + 409 * (255 - 128)) / 256 = 481 // clip range -278 .. 535 signed y1 = (signed)pSrcY[x] - 16; signed y2 = (signed)pSrcY[x + 1] - 16; signed u = (signed)pSrcU[x / 2] - 128; signed v = (signed)pSrcV[x / 2] - 128; signed u_b = u * 517; signed u_g = -u * 100; signed v_g = -v * 208; signed v_r = v * 409; signed tmp1 = y1 * 298; signed b1 = (tmp1 + u_b) / 256; signed g1 = (tmp1 + v_g + u_g) / 256; signed r1 = (tmp1 + v_r) / 256; signed tmp2 = y2 * 298; signed b2 = (tmp2 + u_b) / 256; signed g2 = (tmp2 + v_g + u_g) / 256; signed r2 = (tmp2 + v_r) / 256; unsigned int rgb1 = ((pClip[r1] >> 3) << 11) | ((pClip[g1] >> 2) << 5) | (pClip[b1] >> 3); unsigned int rgb2 = ((pClip[r2] >> 3) << 11) | ((pClip[g2] >> 2) << 5) | (pClip[b2] >> 3); *(unsigned int *)(&pDst[x]) = (rgb2 << 16) | rgb1; } pSrcY += pPicture->nLineStride; if(y & 1) { pSrcU += pPicture->nLineStride / 2; pSrcV += pPicture->nLineStride / 2; } pDst += pVideoFrame->mWidth; } free(pClipTable); return 0; }