ref: 73e0ce9f876fc6ea042072addeb21cd9cbac443b
dir: /src/h264bsd_conceal.c/
/* * Copyright (C) 2009 The Android Open Source Project * Modified for use by h264bsd standalone library * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ /*------------------------------------------------------------------------------ Table of contents 1. Include headers 2. External compiler flags 3. Module defines 4. Local function prototypes 5. Functions h264bsdConceal ConcealMb Transform ------------------------------------------------------------------------------*/ /*------------------------------------------------------------------------------ 1. Include headers ------------------------------------------------------------------------------*/ #include "h264bsd_conceal.h" #include "h264bsd_util.h" #include "h264bsd_reconstruct.h" #include "h264bsd_dpb.h" /*------------------------------------------------------------------------------ 2. External compiler flags -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- 3. Module defines ------------------------------------------------------------------------------*/ /*lint -e702 disable lint warning on right shift of signed quantity */ /*------------------------------------------------------------------------------ 4. Local function prototypes ------------------------------------------------------------------------------*/ static u32 ConcealMb(mbStorage_t *pMb, image_t *currImage, u32 row, u32 col, u32 sliceType, u8 *data); static void Transform(i32 *data); /*------------------------------------------------------------------------------ Function name: h264bsdConceal Functional description: Perform error concealment for a picture. Two types of concealment is performed based on sliceType: 1) copy from previous picture for P-slices. 2) concealment from neighbour pixels for I-slices I-type concealment is based on ideas presented by Jarno Tulkki. The concealment algorithm determines frequency domain coefficients from the neighbour pixels, applies integer transform (the same transform used in the residual processing) and uses the results as pixel values for concealed macroblocks. Transform produces 4x4 array and one pixel value has to be used for 4x4 luma blocks and 2x2 chroma blocks. Similar concealment is performed for whole picture (the choise of the type is based on last successfully decoded slice header of the picture but it is handled by the calling function). It is acknowledged that this may result in wrong type of concealment when a picture contains both types of slices. However, determination of slice type macroblock-by-macroblock cannot be done due to the fact that it is impossible to know to which slice each corrupted (not successfully decoded) macroblock belongs. The error concealment is started by searching the first propoerly decoded macroblock and concealing the row containing the macroblock in question. After that all macroblocks above the row in question are concealed. Finally concealment of rows below is performed. The order of concealment for 4x4 picture where macroblock 9 is the first properly decoded one is as follows (properly decoded macroblocks marked with 'x', numbers indicating the order of concealment): 4 6 8 10 3 5 7 9 1 x x 2 11 12 13 14 If all macroblocks of the picture are lost, the concealment is copy of previous picture for P-type and setting the image to constant gray (pixel value 128) for I-type. Concealment sets quantization parameter of the concealed macroblocks to value 40 and macroblock type to intra to enable deblocking filter to smooth the edges of the concealed areas. Inputs: pStorage pointer to storage structure currImage pointer to current image structure sliceType type of the slice Outputs: currImage concealed macroblocks will be written here Returns: HANTRO_OK ------------------------------------------------------------------------------*/ u32 h264bsdConceal(storage_t *pStorage, image_t *currImage, u32 sliceType) { /* Variables */ u32 i, j; u32 row, col; u32 width, height; u8 *refData; mbStorage_t *mb; /* Code */ ASSERT(pStorage); ASSERT(currImage); DEBUG(("Concealing %s slice\n", IS_I_SLICE(sliceType) ? "intra" : "inter")); width = currImage->width; height = currImage->height; refData = NULL; /* use reference picture with smallest available index */ if (IS_P_SLICE(sliceType) || (pStorage->intraConcealmentFlag != 0)) { i = 0; do { refData = h264bsdGetRefPicData(pStorage->dpb, i); i++; if (i >= 16) break; } while (refData == NULL); } i = row = col = 0; /* find first properly decoded macroblock -> start point for concealment */ while (i < pStorage->picSizeInMbs && !pStorage->mb[i].decoded) { i++; col++; if (col == width) { row++; col = 0; } } /* whole picture lost -> copy previous or set grey */ if (i == pStorage->picSizeInMbs) { if ( (IS_I_SLICE(sliceType) && (pStorage->intraConcealmentFlag == 0)) || refData == NULL) { memset(currImage->data, 128, width*height*384); } else { #ifndef FLASCC memcpy(currImage->data, refData, width*height*384); #else int ii = 0; int size = width*height*384; u8* curr_data = currImage->data; for (ii = 0; ii < size;ii++) curr_data[i] = refData[i]; #endif } pStorage->numConcealedMbs = pStorage->picSizeInMbs; /* no filtering if whole picture concealed */ for (i = 0; i < pStorage->picSizeInMbs; i++) pStorage->mb[i].disableDeblockingFilterIdc = 1; return(HANTRO_OK); } /* start from the row containing the first correct macroblock, conceal the * row in question, all rows above that row and then continue downwards */ mb = pStorage->mb + row * width; for (j = col; j--;) { ConcealMb(mb+j, currImage, row, j, sliceType, refData); mb[j].decoded = 1; pStorage->numConcealedMbs++; } for (j = col + 1; j < width; j++) { if (!mb[j].decoded) { ConcealMb(mb+j, currImage, row, j, sliceType, refData); mb[j].decoded = 1; pStorage->numConcealedMbs++; } } /* if previous row(s) could not be concealed -> conceal them now */ if (row) { for (j = 0; j < width; j++) { i = row - 1; mb = pStorage->mb + i*width + j; do { ConcealMb(mb, currImage, i, j, sliceType, refData); mb->decoded = 1; pStorage->numConcealedMbs++; mb -= width; } while(i--); } } /* process rows below the one containing the first correct macroblock */ for (i = row + 1; i < height; i++) { mb = pStorage->mb + i * width; for (j = 0; j < width; j++) { if (!mb[j].decoded) { ConcealMb(mb+j, currImage, i, j, sliceType, refData); mb[j].decoded = 1; pStorage->numConcealedMbs++; } } } return(HANTRO_OK); } /*------------------------------------------------------------------------------ Function name: ConcealMb Functional description: Perform error concealment for one macroblock, location of the macroblock in the picture indicated by row and col ------------------------------------------------------------------------------*/ static u32 ConcealMb(mbStorage_t *pMb, image_t *currImage, u32 row, u32 col, u32 sliceType, u8 *refData) { /* Variables */ u32 i, j, comp; u32 hor, ver; u32 mbNum; u32 width, height; u8 *mbPos; u8 data[384]; u8 *pData; i32 tmp; i32 firstPhase[16]; i32 *pTmp; /* neighbours above, below, left and right */ i32 a[4] = { 0,0,0,0 }, b[4], l[4] = { 0,0,0,0 }, r[4]; u32 A, B, L, R; #ifdef H264DEC_OMXDL u8 fillBuff[32*21 + 15 + 32]; u8 *pFill; #endif /* Code */ ASSERT(pMb); ASSERT(!pMb->decoded); ASSERT(currImage); ASSERT(col < currImage->width); ASSERT(row < currImage->height); #ifdef H264DEC_OMXDL pFill = ALIGN(fillBuff, 16); #endif width = currImage->width; height = currImage->height; mbNum = row * width + col; h264bsdSetCurrImageMbPointers(currImage, mbNum); mbPos = currImage->data + row * 16 * width * 16 + col * 16; A = B = L = R = HANTRO_FALSE; /* set qpY to 40 to enable some filtering in deblocking (stetson value) */ pMb->qpY = 40; pMb->disableDeblockingFilterIdc = 0; /* mbType set to intra to perform filtering despite the values of other * boundary strength determination fields */ pMb->mbType = I_4x4; pMb->filterOffsetA = 0; pMb->filterOffsetB = 0; pMb->chromaQpIndexOffset = 0; if (IS_I_SLICE(sliceType)) memset(data, 0, sizeof(data)); else { mv_t mv = {0,0}; image_t refImage; refImage.width = width; refImage.height = height; refImage.data = refData; if (refImage.data) { #ifndef H264DEC_OMXDL h264bsdPredictSamples(data, &mv, &refImage, col*16, row*16, 0, 0, 16, 16); #else h264bsdPredictSamples(data, &mv, &refImage, ((row*16) + ((col*16)<<16)), 0x00001010, pFill); #endif h264bsdWriteMacroblock(currImage, data); return(HANTRO_OK); } else memset(data, 0, sizeof(data)); } memset(firstPhase, 0, sizeof(firstPhase)); /* counter for number of neighbours used */ j = 0; hor = ver = 0; if (row && (pMb-width)->decoded) { A = HANTRO_TRUE; pData = mbPos - width*16; a[0] = *pData++; a[0] += *pData++; a[0] += *pData++; a[0] += *pData++; a[1] = *pData++; a[1] += *pData++; a[1] += *pData++; a[1] += *pData++; a[2] = *pData++; a[2] += *pData++; a[2] += *pData++; a[2] += *pData++; a[3] = *pData++; a[3] += *pData++; a[3] += *pData++; a[3] += *pData++; USED(pData); j++; hor++; firstPhase[0] += a[0] + a[1] + a[2] + a[3]; firstPhase[1] += a[0] + a[1] - a[2] - a[3]; } if ((row != height - 1) && (pMb+width)->decoded) { B = HANTRO_TRUE; pData = mbPos + 16*width*16; b[0] = *pData++; b[0] += *pData++; b[0] += *pData++; b[0] += *pData++; b[1] = *pData++; b[1] += *pData++; b[1] += *pData++; b[1] += *pData++; b[2] = *pData++; b[2] += *pData++; b[2] += *pData++; b[2] += *pData++; b[3] = *pData++; b[3] += *pData++; b[3] += *pData++; b[3] += *pData++; USED(pData); j++; hor++; firstPhase[0] += b[0] + b[1] + b[2] + b[3]; firstPhase[1] += b[0] + b[1] - b[2] - b[3]; } if (col && (pMb-1)->decoded) { L = HANTRO_TRUE; pData = mbPos - 1; l[0] = pData[0]; l[0] += pData[16*width]; l[0] += pData[32*width]; l[0] += pData[48*width]; pData += 64*width; l[1] = pData[0]; l[1] += pData[16*width]; l[1] += pData[32*width]; l[1] += pData[48*width]; pData += 64*width; l[2] = pData[0]; l[2] += pData[16*width]; l[2] += pData[32*width]; l[2] += pData[48*width]; pData += 64*width; l[3] = pData[0]; l[3] += pData[16*width]; l[3] += pData[32*width]; l[3] += pData[48*width]; j++; ver++; firstPhase[0] += l[0] + l[1] + l[2] + l[3]; firstPhase[4] += l[0] + l[1] - l[2] - l[3]; } if ((col != width - 1) && (pMb+1)->decoded) { R = HANTRO_TRUE; pData = mbPos + 16; r[0] = pData[0]; r[0] += pData[16*width]; r[0] += pData[32*width]; r[0] += pData[48*width]; pData += 64*width; r[1] = pData[0]; r[1] += pData[16*width]; r[1] += pData[32*width]; r[1] += pData[48*width]; pData += 64*width; r[2] = pData[0]; r[2] += pData[16*width]; r[2] += pData[32*width]; r[2] += pData[48*width]; pData += 64*width; r[3] = pData[0]; r[3] += pData[16*width]; r[3] += pData[32*width]; r[3] += pData[48*width]; j++; ver++; firstPhase[0] += r[0] + r[1] + r[2] + r[3]; firstPhase[4] += r[0] + r[1] - r[2] - r[3]; } /* at least one properly decoded neighbour available */ ASSERT(j); /*lint -esym(644,l,r,a,b) variable initialized above */ if (!hor && L && R) firstPhase[1] = (l[0]+l[1]+l[2]+l[3]-r[0]-r[1]-r[2]-r[3]) >> 5; else if (hor) firstPhase[1] >>= (3+hor); if (!ver && A && B) firstPhase[4] = (a[0]+a[1]+a[2]+a[3]-b[0]-b[1]-b[2]-b[3]) >> 5; else if (ver) firstPhase[4] >>= (3+ver); switch (j) { case 1: firstPhase[0] >>= 4; break; case 2: firstPhase[0] >>= 5; break; case 3: /* approximate (firstPhase[0]*4/3)>>6 */ firstPhase[0] = (21 * firstPhase[0]) >> 10; break; default: /* 4 */ firstPhase[0] >>= 6; break; } Transform(firstPhase); for (i = 0, pData = data, pTmp = firstPhase; i < 256;) { tmp = pTmp[(i & 0xF)>>2]; /*lint -e734 CLIP1 macro results in value that fits into 8 bits */ *pData++ = CLIP1(tmp); /*lint +e734 */ i++; if (!(i & 0x3F)) pTmp += 4; } /* chroma components */ mbPos = currImage->data + width * height * 256 + row * 8 * width * 8 + col * 8; for (comp = 0; comp < 2; comp++) { memset(firstPhase, 0, sizeof(firstPhase)); /* counter for number of neighbours used */ j = 0; hor = ver = 0; if (A) { pData = mbPos - width*8; a[0] = *pData++; a[0] += *pData++; a[1] = *pData++; a[1] += *pData++; a[2] = *pData++; a[2] += *pData++; a[3] = *pData++; a[3] += *pData++; USED(pData); j++; hor++; firstPhase[0] += a[0] + a[1] + a[2] + a[3]; firstPhase[1] += a[0] + a[1] - a[2] - a[3]; } if (B) { pData = mbPos + 8*width*8; b[0] = *pData++; b[0] += *pData++; b[1] = *pData++; b[1] += *pData++; b[2] = *pData++; b[2] += *pData++; b[3] = *pData++; b[3] += *pData++; USED(pData); j++; hor++; firstPhase[0] += b[0] + b[1] + b[2] + b[3]; firstPhase[1] += b[0] + b[1] - b[2] - b[3]; } if (L) { pData = mbPos - 1; l[0] = pData[0]; l[0] += pData[8*width]; pData += 16*width; l[1] = pData[0]; l[1] += pData[8*width]; pData += 16*width; l[2] = pData[0]; l[2] += pData[8*width]; pData += 16*width; l[3] = pData[0]; l[3] += pData[8*width]; j++; ver++; firstPhase[0] += l[0] + l[1] + l[2] + l[3]; firstPhase[4] += l[0] + l[1] - l[2] - l[3]; } if (R) { pData = mbPos + 8; r[0] = pData[0]; r[0] += pData[8*width]; pData += 16*width; r[1] = pData[0]; r[1] += pData[8*width]; pData += 16*width; r[2] = pData[0]; r[2] += pData[8*width]; pData += 16*width; r[3] = pData[0]; r[3] += pData[8*width]; j++; ver++; firstPhase[0] += r[0] + r[1] + r[2] + r[3]; firstPhase[4] += r[0] + r[1] - r[2] - r[3]; } if (!hor && L && R) firstPhase[1] = (l[0]+l[1]+l[2]+l[3]-r[0]-r[1]-r[2]-r[3]) >> 4; else if (hor) firstPhase[1] >>= (2+hor); if (!ver && A && B) firstPhase[4] = (a[0]+a[1]+a[2]+a[3]-b[0]-b[1]-b[2]-b[3]) >> 4; else if (ver) firstPhase[4] >>= (2+ver); switch (j) { case 1: firstPhase[0] >>= 3; break; case 2: firstPhase[0] >>= 4; break; case 3: /* approximate (firstPhase[0]*4/3)>>5 */ firstPhase[0] = (21 * firstPhase[0]) >> 9; break; default: /* 4 */ firstPhase[0] >>= 5; break; } Transform(firstPhase); pData = data + 256 + comp*64; for (i = 0, pTmp = firstPhase; i < 64;) { tmp = pTmp[(i & 0x7)>>1]; /*lint -e734 CLIP1 macro results in value that fits into 8 bits */ *pData++ = CLIP1(tmp); /*lint +e734 */ i++; if (!(i & 0xF)) pTmp += 4; } /* increment pointers for cr */ mbPos += width * height * 64; } h264bsdWriteMacroblock(currImage, data); return(HANTRO_OK); } /*------------------------------------------------------------------------------ Function name: Transform Functional description: Simplified transform, assuming that only dc component and lowest horizontal and lowest vertical component may be non-zero ------------------------------------------------------------------------------*/ static void Transform(i32 *data) { u32 col; i32 tmp0, tmp1; if (!data[1] && !data[4]) { data[1] = data[2] = data[3] = data[4] = data[5] = data[6] = data[7] = data[8] = data[9] = data[10] = data[11] = data[12] = data[13] = data[14] = data[15] = data[0]; return; } /* first horizontal transform for rows 0 and 1 */ tmp0 = data[0]; tmp1 = data[1]; data[0] = tmp0 + tmp1; data[1] = tmp0 + (tmp1>>1); data[2] = tmp0 - (tmp1>>1); data[3] = tmp0 - tmp1; tmp0 = data[4]; data[5] = tmp0; data[6] = tmp0; data[7] = tmp0; /* then vertical transform */ for (col = 4; col--; data++) { tmp0 = data[0]; tmp1 = data[4]; data[0] = tmp0 + tmp1; data[4] = tmp0 + (tmp1>>1); data[8] = tmp0 - (tmp1>>1); data[12] = tmp0 - tmp1; } } /*lint +e702 */