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android / platform / hardware / intel / common / libmix / 049b61c / . / videodecoder / VideoDecoderAVC.cpp
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/* INTEL CONFIDENTIAL
* Copyright (c) 2009 Intel Corporation. All rights reserved.
*
* The source code contained or described herein and all documents
* related to the source code ("Material") are owned by Intel
* Corporation or its suppliers or licensors. Title to the
* Material remains with Intel Corporation or its suppliers and
* licensors. The Material contains trade secrets and proprietary
* and confidential information of Intel or its suppliers and
* licensors. The Material is protected by worldwide copyright and
* trade secret laws and treaty provisions. No part of the Material
* may be used, copied, reproduced, modified, published, uploaded,
* posted, transmitted, distributed, or disclosed in any way without
* Intel's prior express written permission.
*
* No license under any patent, copyright, trade secret or other
* intellectual property right is granted to or conferred upon you
* by disclosure or delivery of the Materials, either expressly, by
* implication, inducement, estoppel or otherwise. Any license
* under such intellectual property rights must be express and
* approved by Intel in writing.
*
*/
#include "VideoDecoderAVC.h"
#include "VideoDecoderTrace.h"
#include <string.h>
#include <cutils/properties.h>
// Macros for actual buffer needed calculation
#define WIDI_CONSUMED 6
#define HDMI_CONSUMED 2
#define NW_CONSUMED 2
VideoDecoderAVC::VideoDecoderAVC(const char *mimeType)
: VideoDecoderBase(mimeType, VBP_H264),
mToggleDPB(0),
mErrorConcealment(false){
invalidateDPB(0);
invalidateDPB(1);
mLastPictureFlags = VA_PICTURE_H264_INVALID;
}
VideoDecoderAVC::~VideoDecoderAVC() {
stop();
}
Decode_Status VideoDecoderAVC::start(VideoConfigBuffer *buffer) {
Decode_Status status;
status = VideoDecoderBase::start(buffer);
CHECK_STATUS("VideoDecoderBase::start");
// We don't want base class to manage reference.
VideoDecoderBase::ManageReference(false);
// output by picture order count
VideoDecoderBase::setOutputMethod(OUTPUT_BY_POC);
mErrorConcealment = buffer->flag & WANT_ERROR_CONCEALMENT;
if (buffer->data == NULL || buffer->size == 0) {
WTRACE("No config data to start VA.");
if ((buffer->flag & HAS_SURFACE_NUMBER) && (buffer->flag & HAS_VA_PROFILE)) {
ITRACE("Used client supplied profile and surface to start VA.");
return VideoDecoderBase::setupVA(buffer->surfaceNumber, buffer->profile);
}
return DECODE_SUCCESS;
}
vbp_data_h264 *data = NULL;
status = VideoDecoderBase::parseBuffer(buffer->data, buffer->size, true, (void**)&data);
CHECK_STATUS("VideoDecoderBase::parseBuffer");
status = startVA(data);
return status;
}
void VideoDecoderAVC::stop(void) {
// drop the last frame and ignore return value
endDecodingFrame(true);
VideoDecoderBase::stop();
invalidateDPB(0);
invalidateDPB(1);
mToggleDPB = 0;
mErrorConcealment = false;
mLastPictureFlags = VA_PICTURE_H264_INVALID;
}
void VideoDecoderAVC::flush(void) {
// drop the frame and ignore return value
VideoDecoderBase::flush();
invalidateDPB(0);
invalidateDPB(1);
mToggleDPB = 0;
mLastPictureFlags = VA_PICTURE_H264_INVALID;
}
Decode_Status VideoDecoderAVC::decode(VideoDecodeBuffer *buffer) {
Decode_Status status;
vbp_data_h264 *data = NULL;
if (buffer == NULL) {
return DECODE_INVALID_DATA;
}
status = VideoDecoderBase::parseBuffer(
buffer->data,
buffer->size,
false,
(void**)&data);
CHECK_STATUS("VideoDecoderBase::parseBuffer");
if (!mVAStarted) {
if (data->has_sps && data->has_pps) {
status = startVA(data);
CHECK_STATUS("startVA");
} else {
WTRACE("Can't start VA as either SPS or PPS is still not available.");
return DECODE_SUCCESS;
}
}
VideoDecoderBase::setRotationDegrees(buffer->rotationDegrees);
status = decodeFrame(buffer, data);
if (status == DECODE_MULTIPLE_FRAME) {
buffer->ext = &mExtensionBuffer;
mExtensionBuffer.extType = PACKED_FRAME_TYPE;
mExtensionBuffer.extSize = sizeof(mPackedFrame);
mExtensionBuffer.extData = (uint8_t*)&mPackedFrame;
}
return status;
}
Decode_Status VideoDecoderAVC::decodeFrame(VideoDecodeBuffer *buffer, vbp_data_h264 *data) {
Decode_Status status;
if (data->has_sps == 0 || data->has_pps == 0) {
return DECODE_NO_CONFIG;
}
mVideoFormatInfo.flags = 0;
uint32_t fieldFlags = 0;
for (unsigned int i = 0; i < data->num_pictures; i++) {
VAPictureH264 &pic = data->pic_data[i].pic_parms->CurrPic;
fieldFlags |= pic.flags;
// Don't remove the following codes, it can be enabled for debugging DPB.
#if 0
VTRACE("%d: decoding frame %.2f, poc top = %d, poc bottom = %d, flags = %d, reference = %d",
i,
buffer->timeStamp/1E6,
pic.TopFieldOrderCnt,
pic.BottomFieldOrderCnt,
pic.flags,
(pic.flags & VA_PICTURE_H264_SHORT_TERM_REFERENCE) ||
(pic.flags & VA_PICTURE_H264_LONG_TERM_REFERENCE));
#endif
}
int32_t topField = fieldFlags & VA_PICTURE_H264_TOP_FIELD;
int32_t botField = fieldFlags & VA_PICTURE_H264_BOTTOM_FIELD;
if ((topField == 0 && botField != 0) || (topField != 0 && botField == 0)) {
mVideoFormatInfo.flags |= IS_SINGLE_FIELD;
}
if (data->new_sps || data->new_pps) {
status = handleNewSequence(data);
CHECK_STATUS("handleNewSequence");
}
if (isWiDiStatusChanged()) {
mSizeChanged = false;
flushSurfaceBuffers();
return DECODE_FORMAT_CHANGE;
}
// first pic_data always exists, check if any slice is parsed
if (data->pic_data[0].num_slices == 0) {
ITRACE("No slice available for decoding.");
status = mSizeChanged ? DECODE_FORMAT_CHANGE : DECODE_SUCCESS;
mSizeChanged = false;
return status;
}
uint64_t lastPTS = mCurrentPTS;
mCurrentPTS = buffer->timeStamp;
//if (lastPTS != mCurrentPTS) {
if (isNewFrame(data, lastPTS == mCurrentPTS)) {
if (mLowDelay) {
// start decoding a new frame
status = beginDecodingFrame(data);
if (status != DECODE_SUCCESS) {
Decode_Status st = status;
// finish decoding the last frame if
// encounter error when decode the new frame
status = endDecodingFrame(false);
CHECK_STATUS("endDecodingFrame");
return st;
}
}
// finish decoding the last frame
status = endDecodingFrame(false);
CHECK_STATUS("endDecodingFrame");
if (!mLowDelay) {
// start decoding a new frame
status = beginDecodingFrame(data);
CHECK_STATUS("beginDecodingFrame");
}
} else {
status = continueDecodingFrame(data);
CHECK_STATUS("continueDecodingFrame");
}
// HAS_COMPLETE_FRAME is not reliable as it may indicate end of a field
#if 0
if (buffer->flag & HAS_COMPLETE_FRAME) {
// finish decoding current frame
status = endDecodingFrame(false);
CHECK_STATUS("endDecodingFrame");
}
#endif
return DECODE_SUCCESS;
}
Decode_Status VideoDecoderAVC::beginDecodingFrame(vbp_data_h264 *data) {
Decode_Status status;
status = acquireSurfaceBuffer();
CHECK_STATUS("acquireSurfaceBuffer");
VAPictureH264 *picture = &(data->pic_data[0].pic_parms->CurrPic);
if ((picture->flags & VA_PICTURE_H264_SHORT_TERM_REFERENCE) ||
(picture->flags & VA_PICTURE_H264_LONG_TERM_REFERENCE)) {
mAcquiredBuffer->referenceFrame = true;
} else {
mAcquiredBuffer->referenceFrame = false;
}
// set asReference in updateDPB
if (picture->flags & VA_PICTURE_H264_TOP_FIELD) {
mAcquiredBuffer->renderBuffer.scanFormat = VA_BOTTOM_FIELD | VA_TOP_FIELD;
} else {
mAcquiredBuffer->renderBuffer.scanFormat = VA_FRAME_PICTURE;
}
// TODO: Set the discontinuity flag
mAcquiredBuffer->renderBuffer.flag = 0;
mAcquiredBuffer->renderBuffer.timeStamp = mCurrentPTS;
mAcquiredBuffer->pictureOrder = getPOC(picture);
if (mSizeChanged) {
mAcquiredBuffer->renderBuffer.flag |= IS_RESOLUTION_CHANGE;
mSizeChanged = false;
}
status = continueDecodingFrame(data);
// surface buffer is released if decode fails
return status;
}
Decode_Status VideoDecoderAVC::continueDecodingFrame(vbp_data_h264 *data) {
Decode_Status status;
vbp_picture_data_h264 *picData = data->pic_data;
// TODO: remove these debugging codes
if (mAcquiredBuffer == NULL || mAcquiredBuffer->renderBuffer.surface == VA_INVALID_SURFACE) {
ETRACE("mAcquiredBuffer is NULL. Implementation bug.");
return DECODE_FAIL;
}
for (uint32_t picIndex = 0; picIndex < data->num_pictures; picIndex++, picData++) {
// sanity check
if (picData == NULL || picData->pic_parms == NULL || picData->slc_data == NULL || picData->num_slices == 0) {
return DECODE_PARSER_FAIL;
}
if (picIndex > 0 &&
(picData->pic_parms->CurrPic.flags & (VA_PICTURE_H264_TOP_FIELD | VA_PICTURE_H264_BOTTOM_FIELD)) == 0) {
// it is a packed frame buffer
vbp_picture_data_h264 *lastPic = &data->pic_data[picIndex - 1];
vbp_slice_data_h264 *sliceData = &(lastPic->slc_data[lastPic->num_slices - 1]);
mPackedFrame.offSet = sliceData->slice_size + sliceData->slice_offset;
mPackedFrame.timestamp = mCurrentPTS; // use the current time stamp for the packed frame
ITRACE("slice data offset= %d, size = %d", sliceData->slice_offset, sliceData->slice_size);
return DECODE_MULTIPLE_FRAME;
}
for (uint32_t sliceIndex = 0; sliceIndex < picData->num_slices; sliceIndex++) {
status = decodeSlice(data, picIndex, sliceIndex);
if (status != DECODE_SUCCESS) {
endDecodingFrame(true);
// TODO: this is new code
// remove current frame from DPB as it can't be decoded.
removeReferenceFromDPB(picData->pic_parms);
return status;
}
}
}
return DECODE_SUCCESS;
}
Decode_Status VideoDecoderAVC::decodeSlice(vbp_data_h264 *data, uint32_t picIndex, uint32_t sliceIndex) {
Decode_Status status;
VAStatus vaStatus;
uint32_t bufferIDCount = 0;
// maximum 4 buffers to render a slice: picture parameter, IQMatrix, slice parameter, slice data
VABufferID bufferIDs[4];
vbp_picture_data_h264 *picData = &(data->pic_data[picIndex]);
vbp_slice_data_h264 *sliceData = &(picData->slc_data[sliceIndex]);
VAPictureParameterBufferH264 *picParam = picData->pic_parms;
VASliceParameterBufferH264 *sliceParam = &(sliceData->slc_parms);
if (sliceParam->first_mb_in_slice == 0 || mDecodingFrame == false) {
// either condition indicates start of a new frame
if (sliceParam->first_mb_in_slice != 0) {
WTRACE("The first slice is lost.");
// TODO: handle the first slice lost
}
if (mDecodingFrame) {
// interlace content, complete decoding the first field
vaStatus = vaEndPicture(mVADisplay, mVAContext);
CHECK_VA_STATUS("vaEndPicture");
// for interlace content, top field may be valid only after the second field is parsed
int32_t poc = getPOC(&(picParam->CurrPic));
if (poc < mAcquiredBuffer->pictureOrder) {
mAcquiredBuffer->pictureOrder = poc;
}
}
// Check there is no reference frame loss before decoding a frame
// Update the reference frames and surface IDs for DPB and current frame
status = updateDPB(picParam);
CHECK_STATUS("updateDPB");
#ifndef USE_AVC_SHORT_FORMAT
//We have to provide a hacked DPB rather than complete DPB for libva as workaround
status = updateReferenceFrames(picData);
CHECK_STATUS("updateReferenceFrames");
#endif
vaStatus = vaBeginPicture(mVADisplay, mVAContext, mAcquiredBuffer->renderBuffer.surface);
CHECK_VA_STATUS("vaBeginPicture");
// start decoding a frame
mDecodingFrame = true;
vaStatus = vaCreateBuffer(
mVADisplay,
mVAContext,
VAPictureParameterBufferType,
sizeof(VAPictureParameterBufferH264),
1,
picParam,
&bufferIDs[bufferIDCount]);
CHECK_VA_STATUS("vaCreatePictureParameterBuffer");
bufferIDCount++;
vaStatus = vaCreateBuffer(
mVADisplay,
mVAContext,
VAIQMatrixBufferType,
sizeof(VAIQMatrixBufferH264),
1,
data->IQ_matrix_buf,
&bufferIDs[bufferIDCount]);
CHECK_VA_STATUS("vaCreateIQMatrixBuffer");
bufferIDCount++;
}
#ifndef USE_AVC_SHORT_FORMAT
status = setReference(sliceParam);
CHECK_STATUS("setReference");
vaStatus = vaCreateBuffer(
mVADisplay,
mVAContext,
VASliceParameterBufferType,
sizeof(VASliceParameterBufferH264),
1,
sliceParam,
&bufferIDs[bufferIDCount]);
#else
vaStatus = vaCreateBuffer(
mVADisplay,
mVAContext,
VASliceParameterBufferType,
sizeof(VASliceParameterBufferH264Base),
1,
sliceParam,
&bufferIDs[bufferIDCount]);
#endif
CHECK_VA_STATUS("vaCreateSliceParameterBuffer");
bufferIDCount++;
vaStatus = vaCreateBuffer(
mVADisplay,
mVAContext,
VASliceDataBufferType,
sliceData->slice_size, //size
1, //num_elements
sliceData->buffer_addr + sliceData->slice_offset,
&bufferIDs[bufferIDCount]);
CHECK_VA_STATUS("vaCreateSliceDataBuffer");
bufferIDCount++;
vaStatus = vaRenderPicture(
mVADisplay,
mVAContext,
bufferIDs,
bufferIDCount);
CHECK_VA_STATUS("vaRenderPicture");
return DECODE_SUCCESS;
}
Decode_Status VideoDecoderAVC::setReference(VASliceParameterBufferH264 *sliceParam) {
int32_t numList = 1;
// TODO: set numList to 0 if it is I slice
if (sliceParam->slice_type == 1 || sliceParam->slice_type == 6) {
// B slice
numList = 2;
}
int32_t activeMinus1 = sliceParam->num_ref_idx_l0_active_minus1;
VAPictureH264 *ref = sliceParam->RefPicList0;
for (int32_t i = 0; i < numList; i++) {
if (activeMinus1 >= REF_LIST_SIZE) {
ETRACE("Invalid activeMinus1 (%d)", activeMinus1);
return DECODE_PARSER_FAIL;
}
for (int32_t j = 0; j <= activeMinus1; j++, ref++) {
if (!(ref->flags & VA_PICTURE_H264_INVALID)) {
ref->picture_id = findSurface(ref);
if (ref->picture_id == VA_INVALID_SURFACE) {
// Error DecodeRefMissing is counted once even there're multiple
mAcquiredBuffer->renderBuffer.errBuf.errorNumber = 1;
mAcquiredBuffer->renderBuffer.errBuf.errorArray[0].type = DecodeRefMissing;
if (mLastReference) {
WTRACE("Reference frame %d is missing. Use last reference", getPOC(ref));
ref->picture_id = mLastReference->renderBuffer.surface;
} else {
ETRACE("Reference frame %d is missing. Stop decoding.", getPOC(ref));
return DECODE_NO_REFERENCE;
}
}
}
}
activeMinus1 = sliceParam->num_ref_idx_l1_active_minus1;
ref = sliceParam->RefPicList1;
}
return DECODE_SUCCESS;
}
Decode_Status VideoDecoderAVC::updateDPB(VAPictureParameterBufferH264 *picParam) {
clearAsReference(mToggleDPB);
// pointer to toggled DPB (new)
DecodedPictureBuffer *dpb = mDPBs[!mToggleDPB];
VAPictureH264 *ref = picParam->ReferenceFrames;
// update current picture ID
picParam->CurrPic.picture_id = mAcquiredBuffer->renderBuffer.surface;
// build new DPB
for (int32_t i = 0; i < MAX_REF_NUMBER; i++, ref++) {
if (ref->flags & VA_PICTURE_H264_INVALID) {
continue;
}
#ifdef USE_AVC_SHORT_FORMAT
ref->picture_id = findSurface(ref);
#endif
dpb->poc = getPOC(ref);
// looking for the latest ref frame in the DPB with specified POC, in case frames have same POC
dpb->surfaceBuffer = findRefSurfaceBuffer(ref);
if (dpb->surfaceBuffer == NULL) {
ETRACE("Reference frame %d is missing for current frame %d", dpb->poc, getPOC(&(picParam->CurrPic)));
// Error DecodeRefMissing is counted once even there're multiple
mAcquiredBuffer->renderBuffer.errBuf.errorNumber = 1;
mAcquiredBuffer->renderBuffer.errBuf.errorArray[0].type = DecodeRefMissing;
if (dpb->poc == getPOC(&(picParam->CurrPic))) {
WTRACE("updateDPB: Using the current picture for missing reference.");
dpb->surfaceBuffer = mAcquiredBuffer;
} else if (mLastReference) {
WTRACE("updateDPB: Use last reference frame %d for missing reference.", mLastReference->pictureOrder);
// TODO: this is new code for error resilience
dpb->surfaceBuffer = mLastReference;
} else {
WTRACE("updateDPB: Unable to recover the missing reference frame.");
// continue buillding DPB without updating dpb pointer.
continue;
// continue building DPB as this reference may not be actually used.
// especially happen after seeking to a non-IDR I frame.
//return DECODE_NO_REFERENCE;
}
}
if (dpb->surfaceBuffer) {
// this surface is used as reference
dpb->surfaceBuffer->asReferernce = true;
}
dpb++;
}
// add current frame to DPB if it is a reference frame
if ((picParam->CurrPic.flags & VA_PICTURE_H264_SHORT_TERM_REFERENCE) ||
(picParam->CurrPic.flags & VA_PICTURE_H264_LONG_TERM_REFERENCE)) {
dpb->poc = getPOC(&(picParam->CurrPic));
dpb->surfaceBuffer = mAcquiredBuffer;
dpb->surfaceBuffer->asReferernce = true;
}
// invalidate the current used DPB
invalidateDPB(mToggleDPB);
mToggleDPB = !mToggleDPB;
return DECODE_SUCCESS;
}
Decode_Status VideoDecoderAVC::updateReferenceFrames(vbp_picture_data_h264 *picData) {
bool found = false;
uint32_t flags = 0;
VAPictureParameterBufferH264 *picParam = picData->pic_parms;
VASliceParameterBufferH264 *sliceParam = NULL;
uint8_t activeMinus1 = 0;
VAPictureH264 *refList = NULL;
VAPictureH264 *dpb = picParam->ReferenceFrames;
VAPictureH264 *refFrame = NULL;
// invalidate DPB in the picture buffer
memset(picParam->ReferenceFrames, 0xFF, sizeof(picParam->ReferenceFrames));
picParam->num_ref_frames = 0;
// update DPB from the reference list in each slice.
for (uint32_t slice = 0; slice < picData->num_slices; slice++) {
sliceParam = &(picData->slc_data[slice].slc_parms);
for (int32_t list = 0; list < 2; list++) {
refList = (list == 0) ? sliceParam->RefPicList0 :
sliceParam->RefPicList1;
activeMinus1 = (list == 0) ? sliceParam->num_ref_idx_l0_active_minus1 :
sliceParam->num_ref_idx_l1_active_minus1;
if (activeMinus1 >= REF_LIST_SIZE) {
return DECODE_PARSER_FAIL;
}
for (uint8_t item = 0; item < (uint8_t)(activeMinus1 + 1); item++, refList++) {
if (refList->flags & VA_PICTURE_H264_INVALID) {
break;
}
found = false;
refFrame = picParam->ReferenceFrames;
for (uint8_t frame = 0; frame < picParam->num_ref_frames; frame++, refFrame++) {
if (refFrame->TopFieldOrderCnt == refList->TopFieldOrderCnt) {
///check for complementary field
flags = refFrame->flags | refList->flags;
//If both TOP and BOTTOM are set, we'll clear those flags
if ((flags & VA_PICTURE_H264_TOP_FIELD) &&
(flags & VA_PICTURE_H264_BOTTOM_FIELD)) {
refFrame->flags = VA_PICTURE_H264_SHORT_TERM_REFERENCE;
}
found = true; //already in the DPB; will not add this one
break;
}
}
if (found == false) {
// add a new reference to the DPB
dpb->picture_id = findSurface(refList);
if (dpb->picture_id == VA_INVALID_SURFACE) {
if (mLastReference != NULL) {
dpb->picture_id = mLastReference->renderBuffer.surface;
} else {
ETRACE("Reference frame %d is missing. Stop updating references frames.", getPOC(refList));
return DECODE_NO_REFERENCE;
}
}
dpb->flags = refList->flags;
dpb->frame_idx = refList->frame_idx;
dpb->TopFieldOrderCnt = refList->TopFieldOrderCnt;
dpb->BottomFieldOrderCnt = refList->BottomFieldOrderCnt;
dpb++;
picParam->num_ref_frames++;
}
}
}
}
return DECODE_SUCCESS;
}
void VideoDecoderAVC::removeReferenceFromDPB(VAPictureParameterBufferH264 *picParam) {
// remove the current frame from DPB as it can't be decoded.
if ((picParam->CurrPic.flags & VA_PICTURE_H264_SHORT_TERM_REFERENCE) ||
(picParam->CurrPic.flags & VA_PICTURE_H264_LONG_TERM_REFERENCE)) {
DecodedPictureBuffer *dpb = mDPBs[mToggleDPB];
uint32_t poc = getPOC(&(picParam->CurrPic));
for (int32_t i = 0; i < DPB_SIZE; i++, dpb++) {
if (poc == dpb->poc) {
dpb->poc = (uint32_t)-1;
if (dpb->surfaceBuffer) {
dpb->surfaceBuffer->asReferernce = false;
}
dpb->surfaceBuffer = NULL;
break;
}
}
}
}
uint32_t VideoDecoderAVC::getPOC(VAPictureH264 *pic) {
if (pic->flags & VA_PICTURE_H264_BOTTOM_FIELD) {
return pic->BottomFieldOrderCnt;
}
return pic->TopFieldOrderCnt;
}
VASurfaceID VideoDecoderAVC::findSurface(VAPictureH264 *pic) {
VideoSurfaceBuffer *p = findSurfaceBuffer(pic);
if (p == NULL) {
ETRACE("Could not find surface for poc %d", getPOC(pic));
return VA_INVALID_SURFACE;
}
return p->renderBuffer.surface;
}
VideoSurfaceBuffer* VideoDecoderAVC::findSurfaceBuffer(VAPictureH264 *pic) {
DecodedPictureBuffer *dpb = mDPBs[mToggleDPB];
for (int32_t i = 0; i < DPB_SIZE; i++, dpb++) {
if (dpb->poc == pic->BottomFieldOrderCnt ||
dpb->poc == pic->TopFieldOrderCnt) {
// TODO: remove these debugging codes
if (dpb->surfaceBuffer == NULL) {
ETRACE("Invalid surface buffer in the DPB for poc %d.", getPOC(pic));
}
return dpb->surfaceBuffer;
}
}
// ETRACE("Unable to find surface for poc %d", getPOC(pic));
return NULL;
}
VideoSurfaceBuffer* VideoDecoderAVC::findRefSurfaceBuffer(VAPictureH264 *pic) {
DecodedPictureBuffer *dpb = mDPBs[mToggleDPB];
// always looking for the latest one in the DPB, in case ref frames have same POC
dpb += (DPB_SIZE - 1);
for (int32_t i = DPB_SIZE; i > 0; i--, dpb--) {
if (dpb->poc == pic->BottomFieldOrderCnt ||
dpb->poc == pic->TopFieldOrderCnt) {
// TODO: remove these debugging codes
if (dpb->surfaceBuffer == NULL) {
ETRACE("Invalid surface buffer in the DPB for poc %d.", getPOC(pic));
}
return dpb->surfaceBuffer;
}
}
ETRACE("Unable to find surface for poc %d", getPOC(pic));
return NULL;
}
void VideoDecoderAVC::invalidateDPB(int toggle) {
DecodedPictureBuffer* p = mDPBs[toggle];
for (int i = 0; i < DPB_SIZE; i++) {
p->poc = (uint32_t) -1;
p->surfaceBuffer = NULL;
p++;
}
}
void VideoDecoderAVC::clearAsReference(int toggle) {
DecodedPictureBuffer* p = mDPBs[toggle];
for (int i = 0; i < DPB_SIZE; i++) {
if (p->surfaceBuffer) {
p->surfaceBuffer->asReferernce = false;
}
p++;
}
}
Decode_Status VideoDecoderAVC::startVA(vbp_data_h264 *data) {
int32_t DPBSize = getDPBSize(data);
//Use high profile for all kinds of H.264 profiles (baseline, main and high) except for constrained baseline
VAProfile vaProfile = VAProfileH264High;
// TODO: determine when to use VAProfileH264ConstrainedBaseline, set only if we are told to do so
if ((data->codec_data->profile_idc == 66 || data->codec_data->constraint_set0_flag == 1) &&
data->codec_data->constraint_set1_flag == 1) {
if (mErrorConcealment) {
vaProfile = VAProfileH264ConstrainedBaseline;
}
}
VideoDecoderBase::setOutputWindowSize(mConfigBuffer.flag & WANT_ADAPTIVE_PLAYBACK ? OUTPUT_WINDOW_SIZE : DPBSize);
updateFormatInfo(data);
// for 1080p, limit the total surface to 19, according the hardware limitation
// change the max surface number from 19->10 to workaround memory shortage
// remove the workaround
if(mVideoFormatInfo.height == 1088 && DPBSize + AVC_EXTRA_SURFACE_NUMBER > 19) {
DPBSize = 19 - AVC_EXTRA_SURFACE_NUMBER;
}
if (mConfigBuffer.flag & WANT_ADAPTIVE_PLAYBACK) {
// When Adaptive playback is enabled, turn off low delay mode.
// Otherwise there may be a 240ms stuttering if the output mode is changed from LowDelay to Delay.
enableLowDelayMode(false);
} else {
// for baseline profile, enable low delay mode automatically
enableLowDelayMode(data->codec_data->profile_idc == 66);
}
return VideoDecoderBase::setupVA(DPBSize + AVC_EXTRA_SURFACE_NUMBER, vaProfile);
}
void VideoDecoderAVC::updateFormatInfo(vbp_data_h264 *data) {
// new video size
int width = (data->pic_data[0].pic_parms->picture_width_in_mbs_minus1 + 1) * 16;
int height = (data->pic_data[0].pic_parms->picture_height_in_mbs_minus1 + 1) * 16;
ITRACE("updateFormatInfo: current size: %d x %d, new size: %d x %d",
mVideoFormatInfo.width, mVideoFormatInfo.height, width, height);
if ((mVideoFormatInfo.width != width ||
mVideoFormatInfo.height != height) &&
width && height) {
if (VideoDecoderBase::alignMB(mVideoFormatInfo.width) != width ||
VideoDecoderBase::alignMB(mVideoFormatInfo.height) != height) {
mSizeChanged = true;
ITRACE("Video size is changed.");
}
mVideoFormatInfo.width = width;
mVideoFormatInfo.height = height;
}
// video_range has default value of 0.
mVideoFormatInfo.videoRange = data->codec_data->video_full_range_flag;
switch (data->codec_data->matrix_coefficients) {
case 1:
mVideoFormatInfo.colorMatrix = VA_SRC_BT709;
break;
// ITU-R Recommendation BT.470-6 System B, G (MP4), same as
// SMPTE 170M/BT601
case 5:
case 6:
mVideoFormatInfo.colorMatrix = VA_SRC_BT601;
break;
default:
// unknown color matrix, set to 0 so color space flag will not be set.
mVideoFormatInfo.colorMatrix = 0;
break;
}
mVideoFormatInfo.aspectX = data->codec_data->sar_width;
mVideoFormatInfo.aspectY = data->codec_data->sar_height;
mVideoFormatInfo.bitrate = data->codec_data->bit_rate;
mVideoFormatInfo.cropLeft = data->codec_data->crop_left;
mVideoFormatInfo.cropRight = data->codec_data->crop_right;
mVideoFormatInfo.cropTop = data->codec_data->crop_top;
mVideoFormatInfo.cropBottom = data->codec_data->crop_bottom;
ITRACE("Cropping: left = %d, top = %d, right = %d, bottom = %d",
data->codec_data->crop_left,
data->codec_data->crop_top,
data->codec_data->crop_right,
data->codec_data->crop_bottom);
if (mConfigBuffer.flag & WANT_SURFACE_PROTECTION) {
mVideoFormatInfo.actualBufferNeeded = mConfigBuffer.surfaceNumber;
} else {
// The number of actual buffer needed is
// outputQueue + nativewindow_owned + num_ref_frames + widi_need_max + 1(available buffer)
// while outputQueue = DPB < 8? DPB :8
mVideoFormatInfo.actualBufferNeeded = mOutputWindowSize + NW_CONSUMED /* Owned by native window */
+ data->codec_data->num_ref_frames
#ifndef USE_GEN_HW
+ HDMI_CONSUMED /* Two extra buffers are needed for native window buffer cycling */
+ (mWiDiOn ? WIDI_CONSUMED : 0) /* WiDi maximum needs */
#endif
+ 1;
}
ITRACE("actualBufferNeeded =%d", mVideoFormatInfo.actualBufferNeeded);
mVideoFormatInfo.valid = true;
setRenderRect();
}
bool VideoDecoderAVC::isWiDiStatusChanged() {
#ifndef USE_GEN_HW
if (mWiDiOn)
return false;
if (mConfigBuffer.flag & WANT_SURFACE_PROTECTION)
return false;
if (!(mConfigBuffer.flag & USE_NATIVE_GRAPHIC_BUFFER))
return false;
char prop[PROPERTY_VALUE_MAX];
bool widi_on = (property_get("media.widi.enabled", prop, NULL) > 0) &&
(!strcmp(prop, "1") || !strcasecmp(prop, "true"));
if (widi_on) {
mVideoFormatInfo.actualBufferNeeded += WIDI_CONSUMED;
mWiDiOn = true;
ITRACE("WiDi is enabled, actual buffer needed is %d", mVideoFormatInfo.actualBufferNeeded);
return true;
}
return false;
#else
return false;
#endif
}
Decode_Status VideoDecoderAVC::handleNewSequence(vbp_data_h264 *data) {
updateFormatInfo(data);
bool needFlush = false;
bool rawDataMode = !(mConfigBuffer.flag & USE_NATIVE_GRAPHIC_BUFFER);
if (!rawDataMode) {
needFlush = (mVideoFormatInfo.width > mVideoFormatInfo.surfaceWidth)
|| (mVideoFormatInfo.height > mVideoFormatInfo.surfaceHeight)
|| isWiDiStatusChanged()
|| (mVideoFormatInfo.actualBufferNeeded > mConfigBuffer.surfaceNumber);
}
if (needFlush || (rawDataMode && mSizeChanged)) {
mSizeChanged = false;
flushSurfaceBuffers();
return DECODE_FORMAT_CHANGE;
} else
return DECODE_SUCCESS;
}
bool VideoDecoderAVC::isNewFrame(vbp_data_h264 *data, bool equalPTS) {
if (data->num_pictures == 0) {
ETRACE("num_pictures == 0");
return true;
}
vbp_picture_data_h264* picData = data->pic_data;
if (picData->num_slices == 0) {
ETRACE("num_slices == 0");
return true;
}
bool newFrame = false;
uint32_t fieldFlags = VA_PICTURE_H264_TOP_FIELD | VA_PICTURE_H264_BOTTOM_FIELD;
if (picData->slc_data[0].slc_parms.first_mb_in_slice != 0) {
// not the first slice, assume it is continuation of a partial frame
// TODO: check if it is new frame boundary as the first slice may get lost in streaming case.
WTRACE("first_mb_in_slice != 0");
if (!equalPTS) {
// return true if different timestamp, it is a workaround here for a streaming case
WTRACE("different PTS, treat it as a new frame");
return true;
}
} else {
if ((picData->pic_parms->CurrPic.flags & fieldFlags) == fieldFlags) {
ETRACE("Current picture has both odd field and even field.");
}
// current picture is a field or a frame, and buffer conains the first slice, check if the current picture and
// the last picture form an opposite field pair
if (((mLastPictureFlags | picData->pic_parms->CurrPic.flags) & fieldFlags) == fieldFlags) {
// opposite field
newFrame = false;
WTRACE("current picture is not at frame boundary.");
mLastPictureFlags = 0;
} else {
newFrame = true;
mLastPictureFlags = 0;
for (uint32_t i = 0; i < data->num_pictures; i++) {
mLastPictureFlags |= data->pic_data[i].pic_parms->CurrPic.flags;
}
if ((mLastPictureFlags & fieldFlags) == fieldFlags) {
// current buffer contains both odd field and even field.
mLastPictureFlags = 0;
}
}
}
return newFrame;
}
int32_t VideoDecoderAVC::getDPBSize(vbp_data_h264 *data) {
// 1024 * MaxDPB / ( PicWidthInMbs * FrameHeightInMbs * 384 ), 16
struct DPBTable {
int32_t level;
float maxDPB;
} dpbTable[] = {
{9, 148.5},
{10, 148.5},
{11, 337.5},
{12, 891.0},
{13, 891.0},
{20, 891.0},
{21, 1782.0},
{22, 3037.5},
{30, 3037.5},
{31, 6750.0},
{32, 7680.0},
{40, 12288.0},
{41, 12288.0},
{42, 13056.0},
{50, 41400.0},
{51, 69120.0}
};
int32_t count = sizeof(dpbTable)/sizeof(DPBTable);
float maxDPB = 0;
for (int32_t i = 0; i < count; i++)
{
if (dpbTable[i].level == data->codec_data->level_idc) {
maxDPB = dpbTable[i].maxDPB;
break;
}
}
int32_t maxDPBSize = maxDPB * 1024 / (
(data->pic_data[0].pic_parms->picture_width_in_mbs_minus1 + 1) *
(data->pic_data[0].pic_parms->picture_height_in_mbs_minus1 + 1) *
384);
if (maxDPBSize > 16) {
maxDPBSize = 16;
} else if (maxDPBSize == 0) {
maxDPBSize = 3;
}
if(maxDPBSize < data->codec_data->num_ref_frames) {
maxDPBSize = data->codec_data->num_ref_frames;
}
// add one extra frame for current frame.
maxDPBSize += 1;
ITRACE("maxDPBSize = %d, num_ref_frame = %d", maxDPBSize, data->codec_data->num_ref_frames);
return maxDPBSize;
}
Decode_Status VideoDecoderAVC::checkHardwareCapability(VAProfile profile) {
#ifndef USE_GEN_HW
VAStatus vaStatus;
VAConfigAttrib cfgAttribs[2];
cfgAttribs[0].type = VAConfigAttribMaxPictureWidth;
cfgAttribs[1].type = VAConfigAttribMaxPictureHeight;
vaStatus = vaGetConfigAttributes(mVADisplay, VAProfileH264High,
VAEntrypointVLD, cfgAttribs, 2);
CHECK_VA_STATUS("vaGetConfigAttributes");
if (cfgAttribs[0].value * cfgAttribs[1].value < (uint32_t)mVideoFormatInfo.width * (uint32_t)mVideoFormatInfo.height) {
ETRACE("hardware supports resolution %d * %d smaller than the clip resolution %d * %d",
cfgAttribs[0].value, cfgAttribs[1].value, mVideoFormatInfo.width, mVideoFormatInfo.height);
return DECODE_DRIVER_FAIL;
}
#endif
return DECODE_SUCCESS;
}
#ifdef USE_AVC_SHORT_FORMAT
Decode_Status VideoDecoderAVC::getCodecSpecificConfigs(
VAProfile profile, VAConfigID *config)
{
VAStatus vaStatus;
VAConfigAttrib attrib[2];
if (config == NULL) {
ETRACE("Invalid parameter!");
return DECODE_FAIL;
}
attrib[0].type = VAConfigAttribRTFormat;
attrib[0].value = VA_RT_FORMAT_YUV420;
attrib[1].type = VAConfigAttribDecSliceMode;
attrib[1].value = VA_DEC_SLICE_MODE_NORMAL;
vaStatus = vaGetConfigAttributes(mVADisplay,profile,VAEntrypointVLD, &attrib[1], 1);
if (attrib[1].value & VA_DEC_SLICE_MODE_BASE) {
ITRACE("AVC short format used");
attrib[1].value = VA_DEC_SLICE_MODE_BASE;
} else if (attrib[1].value & VA_DEC_SLICE_MODE_NORMAL) {
ITRACE("AVC long format ssed");
attrib[1].value = VA_DEC_SLICE_MODE_NORMAL;
} else {
ETRACE("Unsupported Decode Slice Mode!");
return DECODE_FAIL;
}
vaStatus = vaCreateConfig(
mVADisplay,
profile,
VAEntrypointVLD,
&attrib[0],
2,
config);
CHECK_VA_STATUS("vaCreateConfig");
return DECODE_SUCCESS;
}
#endif