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Merge "Add command buffer support for AidlComposer"

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Ady Abraham 2021-10-20 20:53:41 +00:00 committed by Android (Google) Code Review
commit 6dde1bca6f
2 changed files with 914 additions and 0 deletions
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19
graphics/composer/aidl/Android.bp
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@ -67,3 +67,22 @@ cc_library {
], ],
export_include_dirs: ["include"], export_include_dirs: ["include"],
} }
cc_library_headers {
name: "android.hardware.graphics.composer3-command-buffer",
vendor_available: true,
shared_libs: [
"android.hardware.graphics.composer3-V1-ndk",
"libbase",
"libfmq",
"libsync",
],
static_libs: [
"libaidlcommonsupport",
],
export_shared_lib_headers: [
"libfmq",
"libsync",
],
export_include_dirs: ["include"],
}

895
graphics/composer/aidl/include/android/hardware/graphics/composer3/command-buffer.h Normal file
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@ -0,0 +1,895 @@
/*
* Copyright 2021 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.
*/
#pragma once
#include <algorithm>
#include <limits>
#include <memory>
#include <vector>
#include <inttypes.h>
#include <string.h>
#include <aidl/android/hardware/graphics/composer3/BlendMode.h>
#include <aidl/android/hardware/graphics/composer3/ClientTargetProperty.h>
#include <aidl/android/hardware/graphics/composer3/Color.h>
#include <aidl/android/hardware/graphics/composer3/Command.h>
#include <aidl/android/hardware/graphics/composer3/Composition.h>
#include <aidl/android/hardware/graphics/composer3/FloatColor.h>
#include <aidl/android/hardware/graphics/composer3/HandleIndex.h>
#include <aidl/android/hardware/graphics/composer3/IComposer.h>
#include <aidl/android/hardware/graphics/composer3/IComposerClient.h>
#include <aidl/android/hardware/graphics/composer3/PerFrameMetadata.h>
#include <aidl/android/hardware/graphics/composer3/PerFrameMetadataBlob.h>
#include <aidl/android/hardware/graphics/common/ColorTransform.h>
#include <aidl/android/hardware/graphics/common/FRect.h>
#include <aidl/android/hardware/graphics/common/Rect.h>
#include <aidl/android/hardware/graphics/common/Transform.h>
#include <fmq/AidlMessageQueue.h>
#include <log/log.h>
#include <sync/sync.h>
#include <aidlcommonsupport/NativeHandle.h>
using aidl::android::hardware::graphics::common::ColorTransform;
using aidl::android::hardware::graphics::common::Dataspace;
using aidl::android::hardware::graphics::common::FRect;
using aidl::android::hardware::graphics::common::Rect;
using aidl::android::hardware::graphics::common::Transform;
using aidl::android::hardware::graphics::composer3::BlendMode;
using aidl::android::hardware::graphics::composer3::ClientTargetProperty;
using aidl::android::hardware::graphics::composer3::Color;
using aidl::android::hardware::graphics::composer3::Command;
using aidl::android::hardware::graphics::composer3::Composition;
using aidl::android::hardware::graphics::composer3::FloatColor;
using aidl::android::hardware::graphics::composer3::HandleIndex;
using aidl::android::hardware::graphics::composer3::PerFrameMetadata;
using aidl::android::hardware::graphics::composer3::PerFrameMetadataBlob;
using aidl::android::hardware::common::NativeHandle;
using aidl::android::hardware::common::fmq::SynchronizedReadWrite;
using android::AidlMessageQueue;
using CommandQueueType = AidlMessageQueue<int32_t, SynchronizedReadWrite>;
using aidl::android::hardware::common::fmq::MQDescriptor;
using DescriptorType = MQDescriptor<int32_t, SynchronizedReadWrite>;
namespace aidl::android::hardware::graphics::composer3 {
// This class helps build a command queue. Note that all sizes/lengths are in
// units of uint32_t's.
class CommandWriterBase {
public:
CommandWriterBase(uint32_t initialMaxSize) : mDataMaxSize(initialMaxSize) {
mData = std::make_unique<int32_t[]>(mDataMaxSize);
reset();
}
virtual ~CommandWriterBase() { reset(); }
void reset() {
mDataWritten = 0;
mCommandEnd = 0;
// handles in mDataHandles are owned by the caller
mDataHandles.clear();
// handles in mTemporaryHandles are owned by the writer
for (auto handle : mTemporaryHandles) {
native_handle_close(handle);
native_handle_delete(handle);
}
mTemporaryHandles.clear();
}
Command getCommand(uint32_t offset) {
uint32_t val = (offset < mDataWritten) ? mData[offset] : 0;
return static_cast<Command>(val & static_cast<uint32_t>(Command::OPCODE_MASK));
}
bool writeQueue(bool* outQueueChanged, int32_t* outCommandLength,
std::vector<NativeHandle>* outCommandHandles) {
if (mDataWritten == 0) {
*outQueueChanged = false;
*outCommandLength = 0;
outCommandHandles->clear();
return true;
}
// After data are written to the queue, it may not be read by the
// remote reader when
//
// - the writer does not send them (because of other errors)
// - the hwbinder transaction fails
// - the reader does not read them (because of other errors)
//
// Discard the stale data here.
size_t staleDataSize = mQueue ? mQueue->availableToRead() : 0;
if (staleDataSize > 0) {
ALOGW("discarding stale data from message queue");
CommandQueueType::MemTransaction tx;
if (mQueue->beginRead(staleDataSize, &tx)) {
mQueue->commitRead(staleDataSize);
}
}
// write data to queue, optionally resizing it
if (mQueue && (mDataMaxSize <= mQueue->getQuantumCount())) {
if (!mQueue->write(mData.get(), mDataWritten)) {
ALOGE("failed to write commands to message queue");
return false;
}
*outQueueChanged = false;
} else {
auto newQueue = std::make_unique<CommandQueueType>(mDataMaxSize);
if (!newQueue->isValid() || !newQueue->write(mData.get(), mDataWritten)) {
ALOGE("failed to prepare a new message queue ");
return false;
}
mQueue = std::move(newQueue);
*outQueueChanged = true;
}
*outCommandLength = mDataWritten;
*outCommandHandles = std::move(mDataHandles);
return true;
}
DescriptorType getMQDescriptor() const {
return (mQueue) ? mQueue->dupeDesc() : DescriptorType{};
}
static constexpr uint16_t kSelectDisplayLength = 2;
void selectDisplay(int64_t display) {
beginCommand(Command::SELECT_DISPLAY, kSelectDisplayLength);
write64(display);
endCommand();
}
static constexpr uint16_t kSelectLayerLength = 2;
void selectLayer(int64_t layer) {
beginCommand(Command::SELECT_LAYER, kSelectLayerLength);
write64(layer);
endCommand();
}
static constexpr uint16_t kSetErrorLength = 2;
void setError(uint32_t location, int32_t error) {
beginCommand(Command::SET_ERROR, kSetErrorLength);
write(location);
writeSigned(error);
endCommand();
}
static constexpr uint32_t kPresentOrValidateDisplayResultLength = 1;
void setPresentOrValidateResult(uint32_t state) {
beginCommand(Command::SET_PRESENT_OR_VALIDATE_DISPLAY_RESULT,
kPresentOrValidateDisplayResultLength);
write(state);
endCommand();
}
void setChangedCompositionTypes(const std::vector<int64_t>& layers,
const std::vector<Composition>& types) {
size_t totalLayers = std::min(layers.size(), types.size());
size_t currentLayer = 0;
while (currentLayer < totalLayers) {
size_t count =
std::min(totalLayers - currentLayer, static_cast<size_t>(kMaxLength) / 3);
beginCommand(Command::SET_CHANGED_COMPOSITION_TYPES, count * 3);
for (size_t i = 0; i < count; i++) {
write64(layers[currentLayer + i]);
writeSigned(static_cast<int32_t>(types[currentLayer + i]));
}
endCommand();
currentLayer += count;
}
}
void setDisplayRequests(uint32_t displayRequestMask, const std::vector<int64_t>& layers,
const std::vector<uint32_t>& layerRequestMasks) {
size_t totalLayers = std::min(layers.size(), layerRequestMasks.size());
size_t currentLayer = 0;
while (currentLayer < totalLayers) {
size_t count =
std::min(totalLayers - currentLayer, static_cast<size_t>(kMaxLength - 1) / 3);
beginCommand(Command::SET_DISPLAY_REQUESTS, 1 + count * 3);
write(displayRequestMask);
for (size_t i = 0; i < count; i++) {
write64(layers[currentLayer + i]);
write(static_cast<int32_t>(layerRequestMasks[currentLayer + i]));
}
endCommand();
currentLayer += count;
}
}
static constexpr uint16_t kSetPresentFenceLength = 1;
void setPresentFence(int presentFence) {
beginCommand(Command::SET_PRESENT_FENCE, kSetPresentFenceLength);
writeFence(presentFence);
endCommand();
}
void setReleaseFences(const std::vector<int64_t>& layers,
const std::vector<int>& releaseFences) {
size_t totalLayers = std::min(layers.size(), releaseFences.size());
size_t currentLayer = 0;
while (currentLayer < totalLayers) {
size_t count =
std::min(totalLayers - currentLayer, static_cast<size_t>(kMaxLength) / 3);
beginCommand(Command::SET_RELEASE_FENCES, count * 3);
for (size_t i = 0; i < count; i++) {
write64(layers[currentLayer + i]);
writeFence(releaseFences[currentLayer + i]);
}
endCommand();
currentLayer += count;
}
}
static constexpr uint16_t kSetColorTransformLength = 17;
void setColorTransform(const float* matrix, ColorTransform hint) {
beginCommand(Command::SET_COLOR_TRANSFORM, kSetColorTransformLength);
for (int i = 0; i < 16; i++) {
writeFloat(matrix[i]);
}
writeSigned(static_cast<int32_t>(hint));
endCommand();
}
void setClientTarget(uint32_t slot, const native_handle_t* target, int acquireFence,
Dataspace dataspace, const std::vector<Rect>& damage) {
setClientTargetInternal(slot, target, acquireFence, static_cast<int32_t>(dataspace),
damage);
}
static constexpr uint16_t kSetOutputBufferLength = 3;
void setOutputBuffer(uint32_t slot, const native_handle_t* buffer, int releaseFence) {
beginCommand(Command::SET_OUTPUT_BUFFER, kSetOutputBufferLength);
write(slot);
writeHandle(buffer, true);
writeFence(releaseFence);
endCommand();
}
static constexpr uint16_t kValidateDisplayLength = 0;
void validateDisplay() {
beginCommand(Command::VALIDATE_DISPLAY, kValidateDisplayLength);
endCommand();
}
static constexpr uint16_t kPresentOrValidateDisplayLength = 0;
void presentOrvalidateDisplay() {
beginCommand(Command::PRESENT_OR_VALIDATE_DISPLAY, kPresentOrValidateDisplayLength);
endCommand();
}
static constexpr uint16_t kAcceptDisplayChangesLength = 0;
void acceptDisplayChanges() {
beginCommand(Command::ACCEPT_DISPLAY_CHANGES, kAcceptDisplayChangesLength);
endCommand();
}
static constexpr uint16_t kPresentDisplayLength = 0;
void presentDisplay() {
beginCommand(Command::PRESENT_DISPLAY, kPresentDisplayLength);
endCommand();
}
static constexpr uint16_t kSetLayerCursorPositionLength = 2;
void setLayerCursorPosition(int32_t x, int32_t y) {
beginCommand(Command::SET_LAYER_CURSOR_POSITION, kSetLayerCursorPositionLength);
writeSigned(x);
writeSigned(y);
endCommand();
}
static constexpr uint16_t kSetLayerBufferLength = 3;
void setLayerBuffer(uint32_t slot, const native_handle_t* buffer, int acquireFence) {
beginCommand(Command::SET_LAYER_BUFFER, kSetLayerBufferLength);
write(slot);
writeHandle(buffer, true);
writeFence(acquireFence);
endCommand();
}
void setLayerSurfaceDamage(const std::vector<Rect>& damage) {
bool doWrite = (damage.size() <= kMaxLength / 4);
size_t length = (doWrite) ? damage.size() * 4 : 0;
beginCommand(Command::SET_LAYER_SURFACE_DAMAGE, length);
// When there are too many rectangles in the damage region and doWrite
// is false, we write no rectangle at all which means the entire
// layer is damaged.
if (doWrite) {
writeRegion(damage);
}
endCommand();
}
static constexpr uint16_t kSetLayerBlendModeLength = 1;
void setLayerBlendMode(BlendMode mode) {
beginCommand(Command::SET_LAYER_BLEND_MODE, kSetLayerBlendModeLength);
writeSigned(static_cast<int32_t>(mode));
endCommand();
}
static constexpr uint16_t kSetLayerColorLength = 1;
void setLayerColor(Color color) {
beginCommand(Command::SET_LAYER_COLOR, kSetLayerColorLength);
writeColor(color);
endCommand();
}
static constexpr uint16_t kSetLayerCompositionTypeLength = 1;
void setLayerCompositionType(Composition type) {
beginCommand(Command::SET_LAYER_COMPOSITION_TYPE, kSetLayerCompositionTypeLength);
writeSigned(static_cast<int32_t>(type));
endCommand();
}
static constexpr uint16_t kSetLayerDataspaceLength = 1;
void setLayerDataspace(Dataspace dataspace) {
setLayerDataspaceInternal(static_cast<int32_t>(dataspace));
}
static constexpr uint16_t kSetLayerDisplayFrameLength = 4;
void setLayerDisplayFrame(const Rect& frame) {
beginCommand(Command::SET_LAYER_DISPLAY_FRAME, kSetLayerDisplayFrameLength);
writeRect(frame);
endCommand();
}
static constexpr uint16_t kSetLayerPlaneAlphaLength = 1;
void setLayerPlaneAlpha(float alpha) {
beginCommand(Command::SET_LAYER_PLANE_ALPHA, kSetLayerPlaneAlphaLength);
writeFloat(alpha);
endCommand();
}
static constexpr uint16_t kSetLayerSidebandStreamLength = 1;
void setLayerSidebandStream(const native_handle_t* stream) {
beginCommand(Command::SET_LAYER_SIDEBAND_STREAM, kSetLayerSidebandStreamLength);
writeHandle(stream);
endCommand();
}
static constexpr uint16_t kSetLayerSourceCropLength = 4;
void setLayerSourceCrop(const FRect& crop) {
beginCommand(Command::SET_LAYER_SOURCE_CROP, kSetLayerSourceCropLength);
writeFRect(crop);
endCommand();
}
static constexpr uint16_t kSetLayerTransformLength = 1;
void setLayerTransform(Transform transform) {
beginCommand(Command::SET_LAYER_TRANSFORM, kSetLayerTransformLength);
writeSigned(static_cast<int32_t>(transform));
endCommand();
}
void setLayerVisibleRegion(const std::vector<Rect>& visible) {
bool doWrite = (visible.size() <= kMaxLength / 4);
size_t length = (doWrite) ? visible.size() * 4 : 0;
beginCommand(Command::SET_LAYER_VISIBLE_REGION, length);
// When there are too many rectangles in the visible region and
// doWrite is false, we write no rectangle at all which means the
// entire layer is visible.
if (doWrite) {
writeRegion(visible);
}
endCommand();
}
static constexpr uint16_t kSetLayerZOrderLength = 1;
void setLayerZOrder(uint32_t z) {
beginCommand(Command::SET_LAYER_Z_ORDER, kSetLayerZOrderLength);
write(z);
endCommand();
}
void setLayerPerFrameMetadata(const std::vector<PerFrameMetadata>& metadataVec) {
beginCommand(Command::SET_LAYER_PER_FRAME_METADATA, metadataVec.size() * 2);
for (const auto& metadata : metadataVec) {
writeSigned(static_cast<int32_t>(metadata.key));
writeFloat(metadata.value);
}
endCommand();
}
static constexpr uint16_t kSetLayerColorTransformLength = 16;
void setLayerColorTransform(const float* matrix) {
beginCommand(Command::SET_LAYER_COLOR_TRANSFORM, kSetLayerColorTransformLength);
for (int i = 0; i < 16; i++) {
writeFloat(matrix[i]);
}
endCommand();
}
void setLayerPerFrameMetadataBlobs(const std::vector<PerFrameMetadataBlob>& metadata) {
// in units of uint32_t's
size_t commandLength = 0;
if (metadata.size() > std::numeric_limits<uint32_t>::max()) {
LOG_FATAL("too many metadata blobs - dynamic metadata size is too large");
return;
}
// space for numElements
commandLength += 1;
for (auto metadataBlob : metadata) {
commandLength += 1; // key of metadata blob
commandLength += 1; // size information of metadata blob
// metadata content size
size_t metadataSize = metadataBlob.blob.size() / sizeof(uint32_t);
commandLength += metadataSize;
commandLength +=
(metadataBlob.blob.size() - (metadataSize * sizeof(uint32_t)) > 0) ? 1 : 0;
}
if (commandLength > std::numeric_limits<uint16_t>::max()) {
LOG_FATAL("dynamic metadata size is too large");
return;
}
// Blobs are written as:
// {numElements, key1, size1, blob1, key2, size2, blob2, key3, size3...}
uint16_t length = static_cast<uint16_t>(commandLength);
beginCommand(Command::SET_LAYER_PER_FRAME_METADATA_BLOBS, length);
write(static_cast<uint32_t>(metadata.size()));
for (auto metadataBlob : metadata) {
writeSigned(static_cast<int32_t>(metadataBlob.key));
write(static_cast<uint32_t>(metadataBlob.blob.size()));
writeBlob(static_cast<uint32_t>(metadataBlob.blob.size()), metadataBlob.blob.data());
}
endCommand();
}
static constexpr uint16_t kSetLayerFloatColorLength = 4;
void setLayerFloatColor(FloatColor color) {
beginCommand(Command::SET_LAYER_FLOAT_COLOR, kSetLayerFloatColorLength);
writeFloatColor(color);
endCommand();
}
static constexpr uint16_t kSetClientTargetPropertyLength = 2;
void setClientTargetProperty(const ClientTargetProperty& clientTargetProperty) {
beginCommand(Command::SET_CLIENT_TARGET_PROPERTY, kSetClientTargetPropertyLength);
writeSigned(static_cast<int32_t>(clientTargetProperty.pixelFormat));
writeSigned(static_cast<int32_t>(clientTargetProperty.dataspace));
endCommand();
}
void setLayerGenericMetadata(const std::string& key, const bool mandatory,
const std::vector<uint8_t>& value) {
const size_t commandSize = 3 + sizeToElements(key.size()) + sizeToElements(value.size());
if (commandSize > std::numeric_limits<uint16_t>::max()) {
LOG_FATAL("Too much generic metadata (%zu elements)", commandSize);
return;
}
beginCommand(Command::SET_LAYER_GENERIC_METADATA, static_cast<uint16_t>(commandSize));
write(key.size());
writeBlob(key.size(), reinterpret_cast<const unsigned char*>(key.c_str()));
write(mandatory);
write(value.size());
writeBlob(value.size(), value.data());
endCommand();
}
protected:
template <typename T>
void beginCommand(T command, uint16_t length) {
beginCommandBase(static_cast<Command>(command), length);
}
void setClientTargetInternal(uint32_t slot, const native_handle_t* target, int acquireFence,
int32_t dataspace, const std::vector<Rect>& damage) {
bool doWrite = (damage.size() <= (kMaxLength - 4) / 4);
size_t length = 4 + ((doWrite) ? damage.size() * 4 : 0);
beginCommand(Command::SET_CLIENT_TARGET, length);
write(slot);
writeHandle(target, true);
writeFence(acquireFence);
writeSigned(dataspace);
// When there are too many rectangles in the damage region and doWrite
// is false, we write no rectangle at all which means the entire
// client target is damaged.
if (doWrite) {
writeRegion(damage);
}
endCommand();
}
void setLayerDataspaceInternal(int32_t dataspace) {
beginCommand(Command::SET_LAYER_DATASPACE, kSetLayerDataspaceLength);
writeSigned(dataspace);
endCommand();
}
void beginCommandBase(Command command, uint16_t length) {
if (mCommandEnd) {
LOG_FATAL("endCommand was not called before command 0x%x", command);
}
growData(1 + length);
write(static_cast<uint32_t>(command) | length);
mCommandEnd = mDataWritten + length;
}
void endCommand() {
if (!mCommandEnd) {
LOG_FATAL("beginCommand was not called");
} else if (mDataWritten > mCommandEnd) {
LOG_FATAL("too much data written");
mDataWritten = mCommandEnd;
} else if (mDataWritten < mCommandEnd) {
LOG_FATAL("too little data written");
while (mDataWritten < mCommandEnd) {
write(0);
}
}
mCommandEnd = 0;
}
void write(uint32_t val) { mData[mDataWritten++] = val; }
void writeSigned(int32_t val) { memcpy(&mData[mDataWritten++], &val, sizeof(val)); }
void writeFloat(float val) { memcpy(&mData[mDataWritten++], &val, sizeof(val)); }
void write64(uint64_t val) {
uint32_t lo = static_cast<uint32_t>(val & 0xffffffff);
uint32_t hi = static_cast<uint32_t>(val >> 32);
write(lo);
write(hi);
}
void writeRect(const Rect& rect) {
writeSigned(rect.left);
writeSigned(rect.top);
writeSigned(rect.right);
writeSigned(rect.bottom);
}
void writeRegion(const std::vector<Rect>& region) {
for (const auto& rect : region) {
writeRect(rect);
}
}
void writeFRect(const FRect& rect) {
writeFloat(rect.left);
writeFloat(rect.top);
writeFloat(rect.right);
writeFloat(rect.bottom);
}
void writeColor(const Color& color) {
write((color.r << 0) | (color.g << 8) | (color.b << 16) | (color.a << 24));
}
void writeFloatColor(const FloatColor& color) {
writeFloat(color.r);
writeFloat(color.g);
writeFloat(color.b);
writeFloat(color.a);
}
void writeBlob(uint32_t length, const unsigned char* blob) {
memcpy(&mData[mDataWritten], blob, length);
uint32_t numElements = length / 4;
mDataWritten += numElements;
mDataWritten += (length - (numElements * 4) > 0) ? 1 : 0;
}
// ownership of handle is not transferred
void writeHandle(const native_handle_t* handle, bool useCache) {
if (!handle) {
writeSigned(
static_cast<int32_t>((useCache) ? HandleIndex::CACHED : HandleIndex::EMPTY));
return;
}
mDataHandles.push_back(::android::makeToAidl(handle));
writeSigned(mDataHandles.size() - 1);
}
void writeHandle(const native_handle_t* handle) { writeHandle(handle, false); }
// ownership of fence is transferred
void writeFence(int fence) {
native_handle_t* handle = nullptr;
if (fence >= 0) {
handle = getTemporaryHandle(1, 0);
if (handle) {
handle->data[0] = fence;
} else {
ALOGW("failed to get temporary handle for fence %d", fence);
sync_wait(fence, -1);
close(fence);
}
}
writeHandle(handle);
}
native_handle_t* getTemporaryHandle(int numFds, int numInts) {
native_handle_t* handle = native_handle_create(numFds, numInts);
if (handle) {
mTemporaryHandles.push_back(handle);
}
return handle;
}
static constexpr uint16_t kMaxLength = std::numeric_limits<uint16_t>::max();
std::unique_ptr<int32_t[]> mData;
uint32_t mDataWritten;
private:
void growData(uint32_t grow) {
uint32_t newWritten = mDataWritten + grow;
if (newWritten < mDataWritten) {
LOG_ALWAYS_FATAL("buffer overflowed; data written %" PRIu32 ", growing by %" PRIu32,
mDataWritten, grow);
}
if (newWritten <= mDataMaxSize) {
return;
}
uint32_t newMaxSize = mDataMaxSize << 1;
if (newMaxSize < newWritten) {
newMaxSize = newWritten;
}
auto newData = std::make_unique<int32_t[]>(newMaxSize);
std::copy_n(mData.get(), mDataWritten, newData.get());
mDataMaxSize = newMaxSize;
mData = std::move(newData);
}
uint32_t sizeToElements(uint32_t size) { return (size + 3) / 4; }
uint32_t mDataMaxSize;
// end offset of the current command
uint32_t mCommandEnd;
std::vector<NativeHandle> mDataHandles;
std::vector<native_handle_t*> mTemporaryHandles;
std::unique_ptr<CommandQueueType> mQueue;
};
// This class helps parse a command queue. Note that all sizes/lengths are in
// units of uint32_t's.
class CommandReaderBase {
public:
CommandReaderBase() : mDataMaxSize(0) { reset(); }
bool setMQDescriptor(const DescriptorType& descriptor) {
mQueue = std::make_unique<CommandQueueType>(descriptor, false);
if (mQueue->isValid()) {
return true;
} else {
mQueue = nullptr;
return false;
}
}
bool readQueue(int32_t commandLength, std::vector<NativeHandle> commandHandles) {
if (!mQueue) {
return false;
}
auto quantumCount = mQueue->getQuantumCount();
if (mDataMaxSize < quantumCount) {
mDataMaxSize = quantumCount;
mData = std::make_unique<int32_t[]>(mDataMaxSize);
}
if (commandLength > mDataMaxSize || !mQueue->read(mData.get(), commandLength)) {
ALOGE("failed to read commands from message queue");
return false;
}
mDataSize = commandLength;
mDataRead = 0;
mCommandBegin = 0;
mCommandEnd = 0;
mDataHandles = std::move(commandHandles);
return true;
}
void reset() {
mDataSize = 0;
mDataRead = 0;
mCommandBegin = 0;
mCommandEnd = 0;
mDataHandles.clear();
}
protected:
template <typename T>
bool beginCommand(T* outCommand, uint16_t* outLength) {
return beginCommandBase(reinterpret_cast<Command*>(outCommand), outLength);
}
bool isEmpty() const { return (mDataRead >= mDataSize); }
bool beginCommandBase(Command* outCommand, uint16_t* outLength) {
if (mCommandEnd) {
LOG_FATAL("endCommand was not called for last command");
}
constexpr uint32_t opcode_mask = static_cast<uint32_t>(Command::OPCODE_MASK);
constexpr uint32_t length_mask = static_cast<uint32_t>(Command::LENGTH_MASK);
uint32_t val = read();
*outCommand = static_cast<Command>(val & opcode_mask);
*outLength = static_cast<uint16_t>(val & length_mask);
if (mDataRead + *outLength > mDataSize) {
ALOGE("command 0x%x has invalid command length %" PRIu16, *outCommand, *outLength);
// undo the read() above
mDataRead--;
return false;
}
mCommandEnd = mDataRead + *outLength;
return true;
}
void endCommand() {
if (!mCommandEnd) {
LOG_FATAL("beginCommand was not called");
} else if (mDataRead > mCommandEnd) {
LOG_FATAL("too much data read");
mDataRead = mCommandEnd;
} else if (mDataRead < mCommandEnd) {
LOG_FATAL("too little data read");
mDataRead = mCommandEnd;
}
mCommandBegin = mCommandEnd;
mCommandEnd = 0;
}
uint32_t getCommandLoc() const { return mCommandBegin; }
uint32_t read() { return mData[mDataRead++]; }
int32_t readSigned() {
int32_t val;
memcpy(&val, &mData[mDataRead++], sizeof(val));
return val;
}
float readFloat() {
float val;
memcpy(&val, &mData[mDataRead++], sizeof(val));
return val;
}
uint64_t read64() {
uint32_t lo = read();
uint32_t hi = read();
return (static_cast<uint64_t>(hi) << 32) | lo;
}
Color readColor() {
uint32_t val = read();
return Color{
static_cast<int8_t>((val >> 0) & 0xff),
static_cast<int8_t>((val >> 8) & 0xff),
static_cast<int8_t>((val >> 16) & 0xff),
static_cast<int8_t>((val >> 24) & 0xff),
};
}
// ownership of handle is not transferred
const native_handle_t* readHandle(bool* outUseCache) {
const native_handle_t* handle = nullptr;
int32_t index = readSigned();
switch (index) {
case static_cast<int32_t>(HandleIndex::EMPTY):
*outUseCache = false;
break;
case static_cast<int32_t>(HandleIndex::CACHED):
*outUseCache = true;
break;
default:
if (static_cast<size_t>(index) < mDataHandles.size()) {
handle = ::android::makeFromAidl(mDataHandles[index]);
} else {
ALOGE("invalid handle index %zu", static_cast<size_t>(index));
}
*outUseCache = false;
break;
}
return handle;
}
const native_handle_t* readHandle() {
bool useCache;
return readHandle(&useCache);
}
// ownership of fence is transferred
int readFence() {
auto handle = readHandle();
if (!handle || handle->numFds == 0) {
return -1;
}
if (handle->numFds != 1) {
ALOGE("invalid fence handle with %d fds", handle->numFds);
return -1;
}
int fd = dup(handle->data[0]);
if (fd < 0) {
ALOGW("failed to dup fence %d", handle->data[0]);
sync_wait(handle->data[0], -1);
fd = -1;
}
return fd;
}
std::unique_ptr<int32_t[]> mData;
uint32_t mDataRead;
private:
std::unique_ptr<CommandQueueType> mQueue;
uint32_t mDataMaxSize;
uint32_t mDataSize;
// begin/end offsets of the current command
uint32_t mCommandBegin;
uint32_t mCommandEnd;
std::vector<NativeHandle> mDataHandles;
};
} // namespace aidl::android::hardware::graphics::composer3