d9822a3843
Adds a new method, IGBP::detachNextBuffer, that effectively does dequeue + request + detach in a single call, but does not need to know anything about the dequeued buffer, and will not block on dequeue. This is mostly for the upcoming StreamSplitter to use in its onBufferReleased callback. Change-Id: Ie88a69de109003acebaa486a5b44c8a455726550
566 lines
21 KiB
C++
566 lines
21 KiB
C++
/*
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* Copyright 2013 The Android Open Source Project
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*
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* Licensed under the Apache License, Version 2.0 (the "License");
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* you may not use this file except in compliance with the License.
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* You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*/
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// #define LOG_NDEBUG 0
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#include "VirtualDisplaySurface.h"
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#include "HWComposer.h"
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// ---------------------------------------------------------------------------
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namespace android {
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// ---------------------------------------------------------------------------
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#if defined(FORCE_HWC_COPY_FOR_VIRTUAL_DISPLAYS)
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static const bool sForceHwcCopy = true;
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#else
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static const bool sForceHwcCopy = false;
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#endif
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#define VDS_LOGE(msg, ...) ALOGE("[%s] "msg, \
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mDisplayName.string(), ##__VA_ARGS__)
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#define VDS_LOGW_IF(cond, msg, ...) ALOGW_IF(cond, "[%s] "msg, \
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mDisplayName.string(), ##__VA_ARGS__)
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#define VDS_LOGV(msg, ...) ALOGV("[%s] "msg, \
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mDisplayName.string(), ##__VA_ARGS__)
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static const char* dbgCompositionTypeStr(DisplaySurface::CompositionType type) {
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switch (type) {
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case DisplaySurface::COMPOSITION_UNKNOWN: return "UNKNOWN";
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case DisplaySurface::COMPOSITION_GLES: return "GLES";
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case DisplaySurface::COMPOSITION_HWC: return "HWC";
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case DisplaySurface::COMPOSITION_MIXED: return "MIXED";
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default: return "<INVALID>";
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}
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}
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VirtualDisplaySurface::VirtualDisplaySurface(HWComposer& hwc, int32_t dispId,
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const sp<IGraphicBufferProducer>& sink,
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const sp<IGraphicBufferProducer>& bqProducer,
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const sp<IGraphicBufferConsumer>& bqConsumer,
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const String8& name)
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: ConsumerBase(bqConsumer),
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mHwc(hwc),
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mDisplayId(dispId),
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mDisplayName(name),
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mOutputUsage(GRALLOC_USAGE_HW_COMPOSER),
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mProducerSlotSource(0),
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mDbgState(DBG_STATE_IDLE),
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mDbgLastCompositionType(COMPOSITION_UNKNOWN),
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mMustRecompose(false)
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{
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mSource[SOURCE_SINK] = sink;
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mSource[SOURCE_SCRATCH] = bqProducer;
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resetPerFrameState();
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int sinkWidth, sinkHeight;
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sink->query(NATIVE_WINDOW_WIDTH, &sinkWidth);
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sink->query(NATIVE_WINDOW_HEIGHT, &sinkHeight);
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// Pick the buffer format to request from the sink when not rendering to it
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// with GLES. If the consumer needs CPU access, use the default format
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// set by the consumer. Otherwise allow gralloc to decide the format based
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// on usage bits.
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int sinkUsage;
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sink->query(NATIVE_WINDOW_CONSUMER_USAGE_BITS, &sinkUsage);
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if (sinkUsage & (GRALLOC_USAGE_SW_READ_MASK | GRALLOC_USAGE_SW_WRITE_MASK)) {
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int sinkFormat;
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sink->query(NATIVE_WINDOW_FORMAT, &sinkFormat);
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mDefaultOutputFormat = sinkFormat;
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} else {
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mDefaultOutputFormat = HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED;
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}
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mOutputFormat = mDefaultOutputFormat;
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ConsumerBase::mName = String8::format("VDS: %s", mDisplayName.string());
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mConsumer->setConsumerName(ConsumerBase::mName);
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mConsumer->setConsumerUsageBits(GRALLOC_USAGE_HW_COMPOSER);
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mConsumer->setDefaultBufferSize(sinkWidth, sinkHeight);
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mConsumer->setDefaultMaxBufferCount(2);
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}
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VirtualDisplaySurface::~VirtualDisplaySurface() {
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}
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status_t VirtualDisplaySurface::beginFrame(bool mustRecompose) {
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if (mDisplayId < 0)
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return NO_ERROR;
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mMustRecompose = mustRecompose;
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VDS_LOGW_IF(mDbgState != DBG_STATE_IDLE,
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"Unexpected beginFrame() in %s state", dbgStateStr());
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mDbgState = DBG_STATE_BEGUN;
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uint32_t transformHint, numPendingBuffers;
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mQueueBufferOutput.deflate(&mSinkBufferWidth, &mSinkBufferHeight,
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&transformHint, &numPendingBuffers);
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return refreshOutputBuffer();
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}
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status_t VirtualDisplaySurface::prepareFrame(CompositionType compositionType) {
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if (mDisplayId < 0)
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return NO_ERROR;
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VDS_LOGW_IF(mDbgState != DBG_STATE_BEGUN,
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"Unexpected prepareFrame() in %s state", dbgStateStr());
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mDbgState = DBG_STATE_PREPARED;
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mCompositionType = compositionType;
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if (sForceHwcCopy && mCompositionType == COMPOSITION_GLES) {
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// Some hardware can do RGB->YUV conversion more efficiently in hardware
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// controlled by HWC than in hardware controlled by the video encoder.
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// Forcing GLES-composed frames to go through an extra copy by the HWC
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// allows the format conversion to happen there, rather than passing RGB
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// directly to the consumer.
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//
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// On the other hand, when the consumer prefers RGB or can consume RGB
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// inexpensively, this forces an unnecessary copy.
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mCompositionType = COMPOSITION_MIXED;
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}
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if (mCompositionType != mDbgLastCompositionType) {
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VDS_LOGV("prepareFrame: composition type changed to %s",
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dbgCompositionTypeStr(mCompositionType));
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mDbgLastCompositionType = mCompositionType;
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}
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if (mCompositionType != COMPOSITION_GLES &&
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(mOutputFormat != mDefaultOutputFormat ||
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mOutputUsage != GRALLOC_USAGE_HW_COMPOSER)) {
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// We must have just switched from GLES-only to MIXED or HWC
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// composition. Stop using the format and usage requested by the GLES
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// driver; they may be suboptimal when HWC is writing to the output
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// buffer. For example, if the output is going to a video encoder, and
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// HWC can write directly to YUV, some hardware can skip a
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// memory-to-memory RGB-to-YUV conversion step.
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//
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// If we just switched *to* GLES-only mode, we'll change the
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// format/usage and get a new buffer when the GLES driver calls
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// dequeueBuffer().
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mOutputFormat = mDefaultOutputFormat;
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mOutputUsage = GRALLOC_USAGE_HW_COMPOSER;
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refreshOutputBuffer();
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}
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return NO_ERROR;
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}
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status_t VirtualDisplaySurface::compositionComplete() {
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return NO_ERROR;
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}
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status_t VirtualDisplaySurface::advanceFrame() {
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if (mDisplayId < 0)
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return NO_ERROR;
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if (mCompositionType == COMPOSITION_HWC) {
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VDS_LOGW_IF(mDbgState != DBG_STATE_PREPARED,
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"Unexpected advanceFrame() in %s state on HWC frame",
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dbgStateStr());
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} else {
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VDS_LOGW_IF(mDbgState != DBG_STATE_GLES_DONE,
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"Unexpected advanceFrame() in %s state on GLES/MIXED frame",
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dbgStateStr());
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}
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mDbgState = DBG_STATE_HWC;
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if (mOutputProducerSlot < 0 ||
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(mCompositionType != COMPOSITION_HWC && mFbProducerSlot < 0)) {
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// Last chance bailout if something bad happened earlier. For example,
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// in a GLES configuration, if the sink disappears then dequeueBuffer
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// will fail, the GLES driver won't queue a buffer, but SurfaceFlinger
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// will soldier on. So we end up here without a buffer. There should
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// be lots of scary messages in the log just before this.
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VDS_LOGE("advanceFrame: no buffer, bailing out");
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return NO_MEMORY;
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}
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sp<GraphicBuffer> fbBuffer = mFbProducerSlot >= 0 ?
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mProducerBuffers[mFbProducerSlot] : sp<GraphicBuffer>(NULL);
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sp<GraphicBuffer> outBuffer = mProducerBuffers[mOutputProducerSlot];
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VDS_LOGV("advanceFrame: fb=%d(%p) out=%d(%p)",
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mFbProducerSlot, fbBuffer.get(),
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mOutputProducerSlot, outBuffer.get());
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// At this point we know the output buffer acquire fence,
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// so update HWC state with it.
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mHwc.setOutputBuffer(mDisplayId, mOutputFence, outBuffer);
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status_t result = NO_ERROR;
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if (fbBuffer != NULL) {
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result = mHwc.fbPost(mDisplayId, mFbFence, fbBuffer);
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}
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return result;
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}
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void VirtualDisplaySurface::onFrameCommitted() {
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if (mDisplayId < 0)
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return;
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VDS_LOGW_IF(mDbgState != DBG_STATE_HWC,
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"Unexpected onFrameCommitted() in %s state", dbgStateStr());
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mDbgState = DBG_STATE_IDLE;
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sp<Fence> fbFence = mHwc.getAndResetReleaseFence(mDisplayId);
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if (mCompositionType == COMPOSITION_MIXED && mFbProducerSlot >= 0) {
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// release the scratch buffer back to the pool
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Mutex::Autolock lock(mMutex);
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int sslot = mapProducer2SourceSlot(SOURCE_SCRATCH, mFbProducerSlot);
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VDS_LOGV("onFrameCommitted: release scratch sslot=%d", sslot);
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addReleaseFenceLocked(sslot, mProducerBuffers[mFbProducerSlot], fbFence);
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releaseBufferLocked(sslot, mProducerBuffers[mFbProducerSlot],
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EGL_NO_DISPLAY, EGL_NO_SYNC_KHR);
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}
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if (mOutputProducerSlot >= 0) {
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int sslot = mapProducer2SourceSlot(SOURCE_SINK, mOutputProducerSlot);
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QueueBufferOutput qbo;
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sp<Fence> outFence = mHwc.getLastRetireFence(mDisplayId);
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VDS_LOGV("onFrameCommitted: queue sink sslot=%d", sslot);
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if (mMustRecompose) {
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status_t result = mSource[SOURCE_SINK]->queueBuffer(sslot,
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QueueBufferInput(
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systemTime(), false /* isAutoTimestamp */,
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Rect(mSinkBufferWidth, mSinkBufferHeight),
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NATIVE_WINDOW_SCALING_MODE_FREEZE, 0 /* transform */,
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true /* async*/,
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outFence),
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&qbo);
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if (result == NO_ERROR) {
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updateQueueBufferOutput(qbo);
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}
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} else {
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// If the surface hadn't actually been updated, then we only went
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// through the motions of updating the display to keep our state
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// machine happy. We cancel the buffer to avoid triggering another
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// re-composition and causing an infinite loop.
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mSource[SOURCE_SINK]->cancelBuffer(sslot, outFence);
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}
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}
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resetPerFrameState();
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}
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void VirtualDisplaySurface::dump(String8& result) const {
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}
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status_t VirtualDisplaySurface::requestBuffer(int pslot,
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sp<GraphicBuffer>* outBuf) {
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VDS_LOGW_IF(mDbgState != DBG_STATE_GLES,
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"Unexpected requestBuffer pslot=%d in %s state",
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pslot, dbgStateStr());
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*outBuf = mProducerBuffers[pslot];
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return NO_ERROR;
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}
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status_t VirtualDisplaySurface::setBufferCount(int bufferCount) {
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return mSource[SOURCE_SINK]->setBufferCount(bufferCount);
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}
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status_t VirtualDisplaySurface::dequeueBuffer(Source source,
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uint32_t format, uint32_t usage, int* sslot, sp<Fence>* fence) {
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// Don't let a slow consumer block us
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bool async = (source == SOURCE_SINK);
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status_t result = mSource[source]->dequeueBuffer(sslot, fence, async,
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mSinkBufferWidth, mSinkBufferHeight, format, usage);
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if (result < 0)
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return result;
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int pslot = mapSource2ProducerSlot(source, *sslot);
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VDS_LOGV("dequeueBuffer(%s): sslot=%d pslot=%d result=%d",
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dbgSourceStr(source), *sslot, pslot, result);
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uint32_t sourceBit = static_cast<uint32_t>(source) << pslot;
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if ((mProducerSlotSource & (1u << pslot)) != sourceBit) {
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// This slot was previously dequeued from the other source; must
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// re-request the buffer.
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result |= BUFFER_NEEDS_REALLOCATION;
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mProducerSlotSource &= ~(1u << pslot);
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mProducerSlotSource |= sourceBit;
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}
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if (result & RELEASE_ALL_BUFFERS) {
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for (uint32_t i = 0; i < BufferQueue::NUM_BUFFER_SLOTS; i++) {
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if ((mProducerSlotSource & (1u << i)) == sourceBit)
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mProducerBuffers[i].clear();
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}
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}
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if (result & BUFFER_NEEDS_REALLOCATION) {
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mSource[source]->requestBuffer(*sslot, &mProducerBuffers[pslot]);
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VDS_LOGV("dequeueBuffer(%s): buffers[%d]=%p fmt=%d usage=%#x",
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dbgSourceStr(source), pslot, mProducerBuffers[pslot].get(),
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mProducerBuffers[pslot]->getPixelFormat(),
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mProducerBuffers[pslot]->getUsage());
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}
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return result;
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}
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status_t VirtualDisplaySurface::dequeueBuffer(int* pslot, sp<Fence>* fence, bool async,
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uint32_t w, uint32_t h, uint32_t format, uint32_t usage) {
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VDS_LOGW_IF(mDbgState != DBG_STATE_PREPARED,
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"Unexpected dequeueBuffer() in %s state", dbgStateStr());
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mDbgState = DBG_STATE_GLES;
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VDS_LOGW_IF(!async, "EGL called dequeueBuffer with !async despite eglSwapInterval(0)");
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VDS_LOGV("dequeueBuffer %dx%d fmt=%d usage=%#x", w, h, format, usage);
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status_t result = NO_ERROR;
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Source source = fbSourceForCompositionType(mCompositionType);
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if (source == SOURCE_SINK) {
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if (mOutputProducerSlot < 0) {
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// Last chance bailout if something bad happened earlier. For example,
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// in a GLES configuration, if the sink disappears then dequeueBuffer
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// will fail, the GLES driver won't queue a buffer, but SurfaceFlinger
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// will soldier on. So we end up here without a buffer. There should
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// be lots of scary messages in the log just before this.
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VDS_LOGE("dequeueBuffer: no buffer, bailing out");
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return NO_MEMORY;
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}
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// We already dequeued the output buffer. If the GLES driver wants
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// something incompatible, we have to cancel and get a new one. This
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// will mean that HWC will see a different output buffer between
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// prepare and set, but since we're in GLES-only mode already it
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// shouldn't matter.
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usage |= GRALLOC_USAGE_HW_COMPOSER;
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const sp<GraphicBuffer>& buf = mProducerBuffers[mOutputProducerSlot];
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if ((usage & ~buf->getUsage()) != 0 ||
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(format != 0 && format != (uint32_t)buf->getPixelFormat()) ||
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(w != 0 && w != mSinkBufferWidth) ||
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(h != 0 && h != mSinkBufferHeight)) {
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VDS_LOGV("dequeueBuffer: dequeueing new output buffer: "
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"want %dx%d fmt=%d use=%#x, "
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"have %dx%d fmt=%d use=%#x",
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w, h, format, usage,
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mSinkBufferWidth, mSinkBufferHeight,
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buf->getPixelFormat(), buf->getUsage());
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mOutputFormat = format;
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mOutputUsage = usage;
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result = refreshOutputBuffer();
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if (result < 0)
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return result;
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}
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}
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if (source == SOURCE_SINK) {
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*pslot = mOutputProducerSlot;
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*fence = mOutputFence;
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} else {
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int sslot;
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result = dequeueBuffer(source, format, usage, &sslot, fence);
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if (result >= 0) {
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*pslot = mapSource2ProducerSlot(source, sslot);
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}
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}
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return result;
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}
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status_t VirtualDisplaySurface::detachBuffer(int /* slot */) {
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VDS_LOGE("detachBuffer is not available for VirtualDisplaySurface");
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return INVALID_OPERATION;
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}
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status_t VirtualDisplaySurface::detachNextBuffer(
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sp<GraphicBuffer>* /* outBuffer */, sp<Fence>* /* outFence */) {
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VDS_LOGE("detachNextBuffer is not available for VirtualDisplaySurface");
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return INVALID_OPERATION;
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}
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status_t VirtualDisplaySurface::attachBuffer(int* /* outSlot */,
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const sp<GraphicBuffer>& /* buffer */) {
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VDS_LOGE("attachBuffer is not available for VirtualDisplaySurface");
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return INVALID_OPERATION;
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}
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status_t VirtualDisplaySurface::queueBuffer(int pslot,
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const QueueBufferInput& input, QueueBufferOutput* output) {
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VDS_LOGW_IF(mDbgState != DBG_STATE_GLES,
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"Unexpected queueBuffer(pslot=%d) in %s state", pslot,
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dbgStateStr());
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mDbgState = DBG_STATE_GLES_DONE;
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VDS_LOGV("queueBuffer pslot=%d", pslot);
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status_t result;
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if (mCompositionType == COMPOSITION_MIXED) {
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// Queue the buffer back into the scratch pool
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QueueBufferOutput scratchQBO;
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int sslot = mapProducer2SourceSlot(SOURCE_SCRATCH, pslot);
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result = mSource[SOURCE_SCRATCH]->queueBuffer(sslot, input, &scratchQBO);
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if (result != NO_ERROR)
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return result;
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// Now acquire the buffer from the scratch pool -- should be the same
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// slot and fence as we just queued.
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Mutex::Autolock lock(mMutex);
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BufferQueue::BufferItem item;
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result = acquireBufferLocked(&item, 0);
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if (result != NO_ERROR)
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return result;
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VDS_LOGW_IF(item.mBuf != sslot,
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"queueBuffer: acquired sslot %d from SCRATCH after queueing sslot %d",
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item.mBuf, sslot);
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mFbProducerSlot = mapSource2ProducerSlot(SOURCE_SCRATCH, item.mBuf);
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mFbFence = mSlots[item.mBuf].mFence;
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} else {
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LOG_FATAL_IF(mCompositionType != COMPOSITION_GLES,
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"Unexpected queueBuffer in state %s for compositionType %s",
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dbgStateStr(), dbgCompositionTypeStr(mCompositionType));
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// Extract the GLES release fence for HWC to acquire
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int64_t timestamp;
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bool isAutoTimestamp;
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Rect crop;
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int scalingMode;
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uint32_t transform;
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bool async;
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input.deflate(×tamp, &isAutoTimestamp, &crop, &scalingMode,
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&transform, &async, &mFbFence);
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mFbProducerSlot = pslot;
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mOutputFence = mFbFence;
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}
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*output = mQueueBufferOutput;
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return NO_ERROR;
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}
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void VirtualDisplaySurface::cancelBuffer(int pslot, const sp<Fence>& fence) {
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VDS_LOGW_IF(mDbgState != DBG_STATE_GLES,
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"Unexpected cancelBuffer(pslot=%d) in %s state", pslot,
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dbgStateStr());
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VDS_LOGV("cancelBuffer pslot=%d", pslot);
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Source source = fbSourceForCompositionType(mCompositionType);
|
|
return mSource[source]->cancelBuffer(
|
|
mapProducer2SourceSlot(source, pslot), fence);
|
|
}
|
|
|
|
int VirtualDisplaySurface::query(int what, int* value) {
|
|
return mSource[SOURCE_SINK]->query(what, value);
|
|
}
|
|
|
|
status_t VirtualDisplaySurface::connect(const sp<IProducerListener>& listener,
|
|
int api, bool producerControlledByApp,
|
|
QueueBufferOutput* output) {
|
|
QueueBufferOutput qbo;
|
|
status_t result = mSource[SOURCE_SINK]->connect(listener, api,
|
|
producerControlledByApp, &qbo);
|
|
if (result == NO_ERROR) {
|
|
updateQueueBufferOutput(qbo);
|
|
*output = mQueueBufferOutput;
|
|
}
|
|
return result;
|
|
}
|
|
|
|
status_t VirtualDisplaySurface::disconnect(int api) {
|
|
return mSource[SOURCE_SINK]->disconnect(api);
|
|
}
|
|
|
|
status_t VirtualDisplaySurface::setSidebandStream(const sp<NativeHandle>& /*stream*/) {
|
|
return INVALID_OPERATION;
|
|
}
|
|
|
|
void VirtualDisplaySurface::updateQueueBufferOutput(
|
|
const QueueBufferOutput& qbo) {
|
|
uint32_t w, h, transformHint, numPendingBuffers;
|
|
qbo.deflate(&w, &h, &transformHint, &numPendingBuffers);
|
|
mQueueBufferOutput.inflate(w, h, 0, numPendingBuffers);
|
|
}
|
|
|
|
void VirtualDisplaySurface::resetPerFrameState() {
|
|
mCompositionType = COMPOSITION_UNKNOWN;
|
|
mSinkBufferWidth = 0;
|
|
mSinkBufferHeight = 0;
|
|
mFbFence = Fence::NO_FENCE;
|
|
mOutputFence = Fence::NO_FENCE;
|
|
mOutputProducerSlot = -1;
|
|
mFbProducerSlot = -1;
|
|
}
|
|
|
|
status_t VirtualDisplaySurface::refreshOutputBuffer() {
|
|
if (mOutputProducerSlot >= 0) {
|
|
mSource[SOURCE_SINK]->cancelBuffer(
|
|
mapProducer2SourceSlot(SOURCE_SINK, mOutputProducerSlot),
|
|
mOutputFence);
|
|
}
|
|
|
|
int sslot;
|
|
status_t result = dequeueBuffer(SOURCE_SINK, mOutputFormat, mOutputUsage,
|
|
&sslot, &mOutputFence);
|
|
if (result < 0)
|
|
return result;
|
|
mOutputProducerSlot = mapSource2ProducerSlot(SOURCE_SINK, sslot);
|
|
|
|
// On GLES-only frames, we don't have the right output buffer acquire fence
|
|
// until after GLES calls queueBuffer(). So here we just set the buffer
|
|
// (for use in HWC prepare) but not the fence; we'll call this again with
|
|
// the proper fence once we have it.
|
|
result = mHwc.setOutputBuffer(mDisplayId, Fence::NO_FENCE,
|
|
mProducerBuffers[mOutputProducerSlot]);
|
|
|
|
return result;
|
|
}
|
|
|
|
// This slot mapping function is its own inverse, so two copies are unnecessary.
|
|
// Both are kept to make the intent clear where the function is called, and for
|
|
// the (unlikely) chance that we switch to a different mapping function.
|
|
int VirtualDisplaySurface::mapSource2ProducerSlot(Source source, int sslot) {
|
|
if (source == SOURCE_SCRATCH) {
|
|
return BufferQueue::NUM_BUFFER_SLOTS - sslot - 1;
|
|
} else {
|
|
return sslot;
|
|
}
|
|
}
|
|
int VirtualDisplaySurface::mapProducer2SourceSlot(Source source, int pslot) {
|
|
return mapSource2ProducerSlot(source, pslot);
|
|
}
|
|
|
|
VirtualDisplaySurface::Source
|
|
VirtualDisplaySurface::fbSourceForCompositionType(CompositionType type) {
|
|
return type == COMPOSITION_MIXED ? SOURCE_SCRATCH : SOURCE_SINK;
|
|
}
|
|
|
|
const char* VirtualDisplaySurface::dbgStateStr() const {
|
|
switch (mDbgState) {
|
|
case DBG_STATE_IDLE: return "IDLE";
|
|
case DBG_STATE_PREPARED: return "PREPARED";
|
|
case DBG_STATE_GLES: return "GLES";
|
|
case DBG_STATE_GLES_DONE: return "GLES_DONE";
|
|
case DBG_STATE_HWC: return "HWC";
|
|
default: return "INVALID";
|
|
}
|
|
}
|
|
|
|
const char* VirtualDisplaySurface::dbgSourceStr(Source s) {
|
|
switch (s) {
|
|
case SOURCE_SINK: return "SINK";
|
|
case SOURCE_SCRATCH: return "SCRATCH";
|
|
default: return "INVALID";
|
|
}
|
|
}
|
|
|
|
// ---------------------------------------------------------------------------
|
|
} // namespace android
|
|
// ---------------------------------------------------------------------------
|