/* * Copyright (C) 2018 The Android Open Source Project * * 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. */ //#define LOG_NDEBUG 0 #define LOG_TAG "C2SoftAomDec" #include #include #include #include #include #include #include "C2SoftAomDec.h" namespace android { constexpr size_t kMinInputBufferSize = 2 * 1024 * 1024; // codecname set and passed in as a compile flag from Android.bp constexpr char COMPONENT_NAME[] = CODECNAME; class C2SoftAomDec::IntfImpl : public SimpleInterface::BaseParams { public: explicit IntfImpl(const std::shared_ptr& helper) : SimpleInterface::BaseParams( helper, COMPONENT_NAME, C2Component::KIND_DECODER, C2Component::DOMAIN_VIDEO, MEDIA_MIMETYPE_VIDEO_AV1) { noPrivateBuffers(); // TODO: account for our buffers here noInputReferences(); noOutputReferences(); noInputLatency(); noTimeStretch(); addParameter(DefineParam(mAttrib, C2_PARAMKEY_COMPONENT_ATTRIBUTES) .withConstValue(new C2ComponentAttributesSetting( C2Component::ATTRIB_IS_TEMPORAL)) .build()); addParameter( DefineParam(mSize, C2_PARAMKEY_PICTURE_SIZE) .withDefault(new C2StreamPictureSizeInfo::output(0u, 320, 240)) .withFields({ C2F(mSize, width).inRange(2, 2048, 2), C2F(mSize, height).inRange(2, 2048, 2), }) .withSetter(SizeSetter) .build()); addParameter( DefineParam(mProfileLevel, C2_PARAMKEY_PROFILE_LEVEL) .withDefault(new C2StreamProfileLevelInfo::input(0u, C2Config::PROFILE_AV1_0, C2Config::LEVEL_AV1_2_1)) .withFields({ C2F(mProfileLevel, profile).oneOf({ C2Config::PROFILE_AV1_0, C2Config::PROFILE_AV1_1}), C2F(mProfileLevel, level).oneOf({ C2Config::LEVEL_AV1_2, C2Config::LEVEL_AV1_2_1, C2Config::LEVEL_AV1_2_2, C2Config::LEVEL_AV1_3, C2Config::LEVEL_AV1_3_1, C2Config::LEVEL_AV1_3_2, }) }) .withSetter(ProfileLevelSetter, mSize) .build()); mHdr10PlusInfoInput = C2StreamHdr10PlusInfo::input::AllocShared(0); addParameter( DefineParam(mHdr10PlusInfoInput, C2_PARAMKEY_INPUT_HDR10_PLUS_INFO) .withDefault(mHdr10PlusInfoInput) .withFields({ C2F(mHdr10PlusInfoInput, m.value).any(), }) .withSetter(Hdr10PlusInfoInputSetter) .build()); mHdr10PlusInfoOutput = C2StreamHdr10PlusInfo::output::AllocShared(0); addParameter( DefineParam(mHdr10PlusInfoOutput, C2_PARAMKEY_OUTPUT_HDR10_PLUS_INFO) .withDefault(mHdr10PlusInfoOutput) .withFields({ C2F(mHdr10PlusInfoOutput, m.value).any(), }) .withSetter(Hdr10PlusInfoOutputSetter) .build()); addParameter(DefineParam(mMaxSize, C2_PARAMKEY_MAX_PICTURE_SIZE) .withDefault(new C2StreamMaxPictureSizeTuning::output( 0u, 320, 240)) .withFields({ C2F(mSize, width).inRange(2, 2048, 2), C2F(mSize, height).inRange(2, 2048, 2), }) .withSetter(MaxPictureSizeSetter, mSize) .build()); addParameter( DefineParam(mMaxInputSize, C2_PARAMKEY_INPUT_MAX_BUFFER_SIZE) .withDefault( new C2StreamMaxBufferSizeInfo::input(0u, kMinInputBufferSize)) .withFields({ C2F(mMaxInputSize, value).any(), }) .calculatedAs(MaxInputSizeSetter, mMaxSize) .build()); C2ChromaOffsetStruct locations[1] = { C2ChromaOffsetStruct::ITU_YUV_420_0()}; std::shared_ptr defaultColorInfo = C2StreamColorInfo::output::AllocShared(1u, 0u, 8u /* bitDepth */, C2Color::YUV_420); memcpy(defaultColorInfo->m.locations, locations, sizeof(locations)); defaultColorInfo = C2StreamColorInfo::output::AllocShared( {C2ChromaOffsetStruct::ITU_YUV_420_0()}, 0u, 8u /* bitDepth */, C2Color::YUV_420); helper->addStructDescriptors(); addParameter(DefineParam(mColorInfo, C2_PARAMKEY_CODED_COLOR_INFO) .withConstValue(defaultColorInfo) .build()); addParameter( DefineParam(mDefaultColorAspects, C2_PARAMKEY_DEFAULT_COLOR_ASPECTS) .withDefault(new C2StreamColorAspectsTuning::output( 0u, C2Color::RANGE_UNSPECIFIED, C2Color::PRIMARIES_UNSPECIFIED, C2Color::TRANSFER_UNSPECIFIED, C2Color::MATRIX_UNSPECIFIED)) .withFields({ C2F(mDefaultColorAspects, range).inRange( C2Color::RANGE_UNSPECIFIED, C2Color::RANGE_OTHER), C2F(mDefaultColorAspects, primaries).inRange( C2Color::PRIMARIES_UNSPECIFIED, C2Color::PRIMARIES_OTHER), C2F(mDefaultColorAspects, transfer).inRange( C2Color::TRANSFER_UNSPECIFIED, C2Color::TRANSFER_OTHER), C2F(mDefaultColorAspects, matrix).inRange( C2Color::MATRIX_UNSPECIFIED, C2Color::MATRIX_OTHER) }) .withSetter(DefaultColorAspectsSetter) .build()); // TODO: support more formats? addParameter(DefineParam(mPixelFormat, C2_PARAMKEY_PIXEL_FORMAT) .withConstValue(new C2StreamPixelFormatInfo::output( 0u, HAL_PIXEL_FORMAT_YCBCR_420_888)) .build()); } static C2R SizeSetter(bool mayBlock, const C2P& oldMe, C2P& me) { (void)mayBlock; C2R res = C2R::Ok(); if (!me.F(me.v.width).supportsAtAll(me.v.width)) { res = res.plus(C2SettingResultBuilder::BadValue(me.F(me.v.width))); me.set().width = oldMe.v.width; } if (!me.F(me.v.height).supportsAtAll(me.v.height)) { res = res.plus(C2SettingResultBuilder::BadValue(me.F(me.v.height))); me.set().height = oldMe.v.height; } return res; } static C2R MaxPictureSizeSetter( bool mayBlock, C2P& me, const C2P& size) { (void)mayBlock; // TODO: get max width/height from the size's field helpers vs. // hardcoding me.set().width = c2_min(c2_max(me.v.width, size.v.width), 4096u); me.set().height = c2_min(c2_max(me.v.height, size.v.height), 4096u); return C2R::Ok(); } static C2R MaxInputSizeSetter( bool mayBlock, C2P& me, const C2P& maxSize) { (void)mayBlock; // assume compression ratio of 2 me.set().value = c2_max((((maxSize.v.width + 63) / 64) * ((maxSize.v.height + 63) / 64) * 3072), kMinInputBufferSize); return C2R::Ok(); } static C2R DefaultColorAspectsSetter(bool mayBlock, C2P &me) { (void)mayBlock; if (me.v.range > C2Color::RANGE_OTHER) { me.set().range = C2Color::RANGE_OTHER; } if (me.v.primaries > C2Color::PRIMARIES_OTHER) { me.set().primaries = C2Color::PRIMARIES_OTHER; } if (me.v.transfer > C2Color::TRANSFER_OTHER) { me.set().transfer = C2Color::TRANSFER_OTHER; } if (me.v.matrix > C2Color::MATRIX_OTHER) { me.set().matrix = C2Color::MATRIX_OTHER; } return C2R::Ok(); } static C2R ProfileLevelSetter(bool mayBlock, C2P &me, const C2P &size) { (void)mayBlock; (void)size; (void)me; // TODO: validate return C2R::Ok(); } std::shared_ptr getDefaultColorAspects_l() { return mDefaultColorAspects; } static C2R Hdr10PlusInfoInputSetter(bool mayBlock, C2P &me) { (void)mayBlock; (void)me; // TODO: validate return C2R::Ok(); } static C2R Hdr10PlusInfoOutputSetter(bool mayBlock, C2P &me) { (void)mayBlock; (void)me; // TODO: validate return C2R::Ok(); } private: std::shared_ptr mProfileLevel; std::shared_ptr mSize; std::shared_ptr mMaxSize; std::shared_ptr mMaxInputSize; std::shared_ptr mColorInfo; std::shared_ptr mPixelFormat; std::shared_ptr mDefaultColorAspects; std::shared_ptr mHdr10PlusInfoInput; std::shared_ptr mHdr10PlusInfoOutput; }; C2SoftAomDec::C2SoftAomDec(const char* name, c2_node_id_t id, const std::shared_ptr& intfImpl) : SimpleC2Component( std::make_shared>(name, id, intfImpl)), mIntf(intfImpl), mCodecCtx(nullptr){ GENERATE_FILE_NAMES(); CREATE_DUMP_FILE(mInFile); CREATE_DUMP_FILE(mOutFile); gettimeofday(&mTimeStart, nullptr); gettimeofday(&mTimeEnd, nullptr); } C2SoftAomDec::~C2SoftAomDec() { onRelease(); } c2_status_t C2SoftAomDec::onInit() { status_t err = initDecoder(); return err == OK ? C2_OK : C2_CORRUPTED; } c2_status_t C2SoftAomDec::onStop() { mSignalledError = false; mSignalledOutputEos = false; return C2_OK; } void C2SoftAomDec::onReset() { (void)onStop(); c2_status_t err = onFlush_sm(); if (err != C2_OK) { ALOGW("Failed to flush decoder. Try to hard reset decoder."); destroyDecoder(); (void)initDecoder(); } } void C2SoftAomDec::onRelease() { destroyDecoder(); } c2_status_t C2SoftAomDec::onFlush_sm() { if (aom_codec_decode(mCodecCtx, nullptr, 0, nullptr)) { ALOGE("Failed to flush av1 decoder."); return C2_CORRUPTED; } aom_codec_iter_t iter = nullptr; while (aom_codec_get_frame(mCodecCtx, &iter)) { } mSignalledError = false; mSignalledOutputEos = false; return C2_OK; } static int GetCPUCoreCount() { int cpuCoreCount = 1; #if defined(_SC_NPROCESSORS_ONLN) cpuCoreCount = sysconf(_SC_NPROCESSORS_ONLN); #else // _SC_NPROC_ONLN must be defined... cpuCoreCount = sysconf(_SC_NPROC_ONLN); #endif CHECK(cpuCoreCount >= 1); ALOGV("Number of CPU cores: %d", cpuCoreCount); return cpuCoreCount; } status_t C2SoftAomDec::initDecoder() { mSignalledError = false; mSignalledOutputEos = false; if (!mCodecCtx) { mCodecCtx = new aom_codec_ctx_t; } if (!mCodecCtx) { ALOGE("mCodecCtx is null"); return NO_MEMORY; } aom_codec_dec_cfg_t cfg; memset(&cfg, 0, sizeof(aom_codec_dec_cfg_t)); cfg.threads = GetCPUCoreCount(); cfg.allow_lowbitdepth = 1; aom_codec_flags_t flags; memset(&flags, 0, sizeof(aom_codec_flags_t)); ALOGV("Using libaom AV1 software decoder."); aom_codec_err_t err; if ((err = aom_codec_dec_init(mCodecCtx, aom_codec_av1_dx(), &cfg, 0))) { ALOGE("av1 decoder failed to initialize. (%d)", err); return UNKNOWN_ERROR; } return OK; } status_t C2SoftAomDec::destroyDecoder() { if (mCodecCtx) { aom_codec_destroy(mCodecCtx); delete mCodecCtx; mCodecCtx = nullptr; } return OK; } void fillEmptyWork(const std::unique_ptr& work) { uint32_t flags = 0; if (work->input.flags & C2FrameData::FLAG_END_OF_STREAM) { flags |= C2FrameData::FLAG_END_OF_STREAM; ALOGV("signalling eos"); } work->worklets.front()->output.flags = (C2FrameData::flags_t)flags; work->worklets.front()->output.buffers.clear(); work->worklets.front()->output.ordinal = work->input.ordinal; work->workletsProcessed = 1u; } void C2SoftAomDec::finishWork(uint64_t index, const std::unique_ptr& work, const std::shared_ptr& block) { std::shared_ptr buffer = createGraphicBuffer(block, C2Rect(mWidth, mHeight)); auto fillWork = [buffer, index, intf = this->mIntf]( const std::unique_ptr& work) { uint32_t flags = 0; if ((work->input.flags & C2FrameData::FLAG_END_OF_STREAM) && (c2_cntr64_t(index) == work->input.ordinal.frameIndex)) { flags |= C2FrameData::FLAG_END_OF_STREAM; ALOGV("signalling eos"); } work->worklets.front()->output.flags = (C2FrameData::flags_t)flags; work->worklets.front()->output.buffers.clear(); work->worklets.front()->output.buffers.push_back(buffer); work->worklets.front()->output.ordinal = work->input.ordinal; work->workletsProcessed = 1u; for (const std::unique_ptr ¶m: work->input.configUpdate) { if (param) { C2StreamHdr10PlusInfo::input *hdr10PlusInfo = C2StreamHdr10PlusInfo::input::From(param.get()); if (hdr10PlusInfo != nullptr) { std::vector> failures; std::unique_ptr outParam = C2Param::CopyAsStream( *param.get(), true /*output*/, param->stream()); c2_status_t err = intf->config( { outParam.get() }, C2_MAY_BLOCK, &failures); if (err == C2_OK) { work->worklets.front()->output.configUpdate.push_back( C2Param::Copy(*outParam.get())); } else { ALOGE("finishWork: Config update size failed"); } break; } } } }; if (work && c2_cntr64_t(index) == work->input.ordinal.frameIndex) { fillWork(work); } else { finish(index, fillWork); } } void C2SoftAomDec::process(const std::unique_ptr& work, const std::shared_ptr& pool) { work->result = C2_OK; work->workletsProcessed = 0u; work->worklets.front()->output.configUpdate.clear(); work->worklets.front()->output.flags = work->input.flags; if (mSignalledError || mSignalledOutputEos) { work->result = C2_BAD_VALUE; return; } size_t inOffset = 0u; size_t inSize = 0u; C2ReadView rView = mDummyReadView; if (!work->input.buffers.empty()) { rView = work->input.buffers[0]->data().linearBlocks().front().map().get(); inSize = rView.capacity(); if (inSize && rView.error()) { ALOGE("read view map failed %d", rView.error()); work->result = C2_CORRUPTED; return; } } bool codecConfig = ((work->input.flags & C2FrameData::FLAG_CODEC_CONFIG) != 0); bool eos = ((work->input.flags & C2FrameData::FLAG_END_OF_STREAM) != 0); ALOGV("in buffer attr. size %zu timestamp %d frameindex %d, flags %x", inSize, (int)work->input.ordinal.timestamp.peeku(), (int)work->input.ordinal.frameIndex.peeku(), work->input.flags); if (codecConfig) { fillEmptyWork(work); return; } int64_t frameIndex = work->input.ordinal.frameIndex.peekll(); if (inSize) { uint8_t* bitstream = const_cast(rView.data() + inOffset); int32_t decodeTime = 0; int32_t delay = 0; DUMP_TO_FILE(mOutFile, bitstream, inSize); GETTIME(&mTimeStart, nullptr); TIME_DIFF(mTimeEnd, mTimeStart, delay); aom_codec_err_t err = aom_codec_decode(mCodecCtx, bitstream, inSize, &frameIndex); GETTIME(&mTimeEnd, nullptr); TIME_DIFF(mTimeStart, mTimeEnd, decodeTime); ALOGV("decodeTime=%4d delay=%4d\n", decodeTime, delay); if (err != AOM_CODEC_OK) { ALOGE("av1 decoder failed to decode frame err: %d", err); work->result = C2_CORRUPTED; work->workletsProcessed = 1u; mSignalledError = true; return; } } else { if (aom_codec_decode(mCodecCtx, nullptr, 0, nullptr)) { ALOGE("Failed to flush av1 decoder."); work->result = C2_CORRUPTED; work->workletsProcessed = 1u; mSignalledError = true; return; } } (void)outputBuffer(pool, work); if (eos) { drainInternal(DRAIN_COMPONENT_WITH_EOS, pool, work); mSignalledOutputEos = true; } else if (!inSize) { fillEmptyWork(work); } } static void copyOutputBufferToYuvPlanarFrame( uint8_t *dstY, uint8_t *dstU, uint8_t *dstV, const uint8_t *srcY, const uint8_t *srcU, const uint8_t *srcV, size_t srcYStride, size_t srcUStride, size_t srcVStride, size_t dstYStride, size_t dstUVStride, uint32_t width, uint32_t height) { for (size_t i = 0; i < height; ++i) { memcpy(dstY, srcY, width); srcY += srcYStride; dstY += dstYStride; } for (size_t i = 0; i < height / 2; ++i) { memcpy(dstV, srcV, width / 2); srcV += srcVStride; dstV += dstUVStride; } for (size_t i = 0; i < height / 2; ++i) { memcpy(dstU, srcU, width / 2); srcU += srcUStride; dstU += dstUVStride; } } static void convertYUV420Planar16ToY410(uint32_t *dst, const uint16_t *srcY, const uint16_t *srcU, const uint16_t *srcV, size_t srcYStride, size_t srcUStride, size_t srcVStride, size_t dstStride, size_t width, size_t height) { // Converting two lines at a time, slightly faster for (size_t y = 0; y < height; y += 2) { uint32_t *dstTop = (uint32_t *) dst; uint32_t *dstBot = (uint32_t *) (dst + dstStride); uint16_t *ySrcTop = (uint16_t*) srcY; uint16_t *ySrcBot = (uint16_t*) (srcY + srcYStride); uint16_t *uSrc = (uint16_t*) srcU; uint16_t *vSrc = (uint16_t*) srcV; uint32_t u01, v01, y01, y23, y45, y67, uv0, uv1; size_t x = 0; for (; x < width - 3; x += 4) { u01 = *((uint32_t*)uSrc); uSrc += 2; v01 = *((uint32_t*)vSrc); vSrc += 2; y01 = *((uint32_t*)ySrcTop); ySrcTop += 2; y23 = *((uint32_t*)ySrcTop); ySrcTop += 2; y45 = *((uint32_t*)ySrcBot); ySrcBot += 2; y67 = *((uint32_t*)ySrcBot); ySrcBot += 2; uv0 = (u01 & 0x3FF) | ((v01 & 0x3FF) << 20); uv1 = (u01 >> 16) | ((v01 >> 16) << 20); *dstTop++ = 3 << 30 | ((y01 & 0x3FF) << 10) | uv0; *dstTop++ = 3 << 30 | ((y01 >> 16) << 10) | uv0; *dstTop++ = 3 << 30 | ((y23 & 0x3FF) << 10) | uv1; *dstTop++ = 3 << 30 | ((y23 >> 16) << 10) | uv1; *dstBot++ = 3 << 30 | ((y45 & 0x3FF) << 10) | uv0; *dstBot++ = 3 << 30 | ((y45 >> 16) << 10) | uv0; *dstBot++ = 3 << 30 | ((y67 & 0x3FF) << 10) | uv1; *dstBot++ = 3 << 30 | ((y67 >> 16) << 10) | uv1; } // There should be at most 2 more pixels to process. Note that we don't // need to consider odd case as the buffer is always aligned to even. if (x < width) { u01 = *uSrc; v01 = *vSrc; y01 = *((uint32_t*)ySrcTop); y45 = *((uint32_t*)ySrcBot); uv0 = (u01 & 0x3FF) | ((v01 & 0x3FF) << 20); *dstTop++ = ((y01 & 0x3FF) << 10) | uv0; *dstTop++ = ((y01 >> 16) << 10) | uv0; *dstBot++ = ((y45 & 0x3FF) << 10) | uv0; *dstBot++ = ((y45 >> 16) << 10) | uv0; } srcY += srcYStride * 2; srcU += srcUStride; srcV += srcVStride; dst += dstStride * 2; } return; } static void convertYUV420Planar16ToYUV420Planar( uint8_t *dstY, uint8_t *dstU, uint8_t *dstV, const uint16_t *srcY, const uint16_t *srcU, const uint16_t *srcV, size_t srcYStride, size_t srcUStride, size_t srcVStride, size_t dstYStride, size_t dstUVStride, size_t width, size_t height) { for (size_t y = 0; y < height; ++y) { for (size_t x = 0; x < width; ++x) { dstY[x] = (uint8_t)(srcY[x] >> 2); } srcY += srcYStride; dstY += dstYStride; } for (size_t y = 0; y < (height + 1) / 2; ++y) { for (size_t x = 0; x < (width + 1) / 2; ++x) { dstU[x] = (uint8_t)(srcU[x] >> 2); dstV[x] = (uint8_t)(srcV[x] >> 2); } srcU += srcUStride; srcV += srcVStride; dstU += dstUVStride; dstV += dstUVStride; } return; } bool C2SoftAomDec::outputBuffer( const std::shared_ptr &pool, const std::unique_ptr &work) { if (!(work && pool)) return false; aom_codec_iter_t iter = nullptr; aom_image_t* img = aom_codec_get_frame(mCodecCtx, &iter); if (!img) return false; if (img->d_w != mWidth || img->d_h != mHeight) { mWidth = img->d_w; mHeight = img->d_h; C2StreamPictureSizeInfo::output size(0u, mWidth, mHeight); std::vector> failures; c2_status_t err = mIntf->config({&size}, C2_MAY_BLOCK, &failures); if (err == C2_OK) { work->worklets.front()->output.configUpdate.push_back( C2Param::Copy(size)); } else { ALOGE("Config update size failed"); mSignalledError = true; work->result = C2_CORRUPTED; work->workletsProcessed = 1u; return false; } } CHECK(img->fmt == AOM_IMG_FMT_I420 || img->fmt == AOM_IMG_FMT_I42016); std::shared_ptr block; uint32_t format = HAL_PIXEL_FORMAT_YV12; if (img->fmt == AOM_IMG_FMT_I42016) { IntfImpl::Lock lock = mIntf->lock(); std::shared_ptr defaultColorAspects = mIntf->getDefaultColorAspects_l(); if (defaultColorAspects->primaries == C2Color::PRIMARIES_BT2020 && defaultColorAspects->matrix == C2Color::MATRIX_BT2020 && defaultColorAspects->transfer == C2Color::TRANSFER_ST2084) { format = HAL_PIXEL_FORMAT_RGBA_1010102; } } C2MemoryUsage usage = {C2MemoryUsage::CPU_READ, C2MemoryUsage::CPU_WRITE}; c2_status_t err = pool->fetchGraphicBlock(align(mWidth, 16), mHeight, format, usage, &block); if (err != C2_OK) { ALOGE("fetchGraphicBlock for Output failed with status %d", err); work->result = err; return false; } C2GraphicView wView = block->map().get(); if (wView.error()) { ALOGE("graphic view map failed %d", wView.error()); work->result = C2_CORRUPTED; return false; } ALOGV("provided (%dx%d) required (%dx%d), out frameindex %d", block->width(), block->height(), mWidth, mHeight, (int)*(int64_t*)img->user_priv); uint8_t* dstY = const_cast(wView.data()[C2PlanarLayout::PLANE_Y]); uint8_t* dstU = const_cast(wView.data()[C2PlanarLayout::PLANE_U]); uint8_t* dstV = const_cast(wView.data()[C2PlanarLayout::PLANE_V]); size_t srcYStride = img->stride[AOM_PLANE_Y]; size_t srcUStride = img->stride[AOM_PLANE_U]; size_t srcVStride = img->stride[AOM_PLANE_V]; C2PlanarLayout layout = wView.layout(); size_t dstYStride = layout.planes[C2PlanarLayout::PLANE_Y].rowInc; size_t dstUVStride = layout.planes[C2PlanarLayout::PLANE_U].rowInc; if (img->fmt == AOM_IMG_FMT_I42016) { const uint16_t *srcY = (const uint16_t *)img->planes[AOM_PLANE_Y]; const uint16_t *srcU = (const uint16_t *)img->planes[AOM_PLANE_U]; const uint16_t *srcV = (const uint16_t *)img->planes[AOM_PLANE_V]; if (format == HAL_PIXEL_FORMAT_RGBA_1010102) { convertYUV420Planar16ToY410((uint32_t *)dstY, srcY, srcU, srcV, srcYStride / 2, srcUStride / 2, srcVStride / 2, dstYStride / sizeof(uint32_t), mWidth, mHeight); } else { convertYUV420Planar16ToYUV420Planar(dstY, dstU, dstV, srcY, srcU, srcV, srcYStride / 2, srcUStride / 2, srcVStride / 2, dstYStride, dstUVStride, mWidth, mHeight); } } else { const uint8_t *srcY = (const uint8_t *)img->planes[AOM_PLANE_Y]; const uint8_t *srcU = (const uint8_t *)img->planes[AOM_PLANE_U]; const uint8_t *srcV = (const uint8_t *)img->planes[AOM_PLANE_V]; copyOutputBufferToYuvPlanarFrame( dstY, dstU, dstV, srcY, srcU, srcV, srcYStride, srcUStride, srcVStride, dstYStride, dstUVStride, mWidth, mHeight); } finishWork(*(int64_t*)img->user_priv, work, std::move(block)); block = nullptr; return true; } c2_status_t C2SoftAomDec::drainInternal( uint32_t drainMode, const std::shared_ptr& pool, const std::unique_ptr& work) { if (drainMode == NO_DRAIN) { ALOGW("drain with NO_DRAIN: no-op"); return C2_OK; } if (drainMode == DRAIN_CHAIN) { ALOGW("DRAIN_CHAIN not supported"); return C2_OMITTED; } if (aom_codec_decode(mCodecCtx, nullptr, 0, nullptr)) { ALOGE("Failed to flush av1 decoder."); return C2_CORRUPTED; } while ((outputBuffer(pool, work))) { } if (drainMode == DRAIN_COMPONENT_WITH_EOS && work && work->workletsProcessed == 0u) { fillEmptyWork(work); } return C2_OK; } c2_status_t C2SoftAomDec::drain(uint32_t drainMode, const std::shared_ptr& pool) { return drainInternal(drainMode, pool, nullptr); } class C2SoftAomFactory : public C2ComponentFactory { public: C2SoftAomFactory() : mHelper(std::static_pointer_cast( GetCodec2PlatformComponentStore()->getParamReflector())) {} virtual c2_status_t createComponent( c2_node_id_t id, std::shared_ptr* const component, std::function deleter) override { *component = std::shared_ptr( new C2SoftAomDec(COMPONENT_NAME, id, std::make_shared(mHelper)), deleter); return C2_OK; } virtual c2_status_t createInterface( c2_node_id_t id, std::shared_ptr* const interface, std::function deleter) override { *interface = std::shared_ptr( new SimpleInterface( COMPONENT_NAME, id, std::make_shared(mHelper)), deleter); return C2_OK; } virtual ~C2SoftAomFactory() override = default; private: std::shared_ptr mHelper; }; } // namespace android __attribute__((cfi_canonical_jump_table)) extern "C" ::C2ComponentFactory* CreateCodec2Factory() { ALOGV("in %s", __func__); return new ::android::C2SoftAomFactory(); } __attribute__((cfi_canonical_jump_table)) extern "C" void DestroyCodec2Factory(::C2ComponentFactory* factory) { ALOGV("in %s", __func__); delete factory; }