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/*
* Copyright 2016 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.
*/
// TODO(b/129481165): remove the #pragma below and fix conversion issues
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wconversion"
#undef LOG_TAG
#define LOG_TAG "HwcComposer"
#define ATRACE_TAG ATRACE_TAG_GRAPHICS
#include "HidlComposerHal.h"
#include <SurfaceFlingerProperties.h>
#include <aidl/android/hardware/graphics/common/DisplayHotplugEvent.h>
#include <android/binder_manager.h>
#include <composer-command-buffer/2.2/ComposerCommandBuffer.h>
#include <hidl/HidlTransportSupport.h>
#include <hidl/HidlTransportUtils.h>
#include <log/log.h>
#include <utils/Trace.h>
#include "HWC2.h"
#include "Hal.h"
#include <algorithm>
#include <cinttypes>
using aidl::android::hardware::graphics::common::DisplayHotplugEvent;
using aidl::android::hardware::graphics::common::HdrConversionCapability;
using aidl::android::hardware::graphics::common::HdrConversionStrategy;
using aidl::android::hardware::graphics::composer3::Capability;
using aidl::android::hardware::graphics::composer3::ClientTargetPropertyWithBrightness;
using aidl::android::hardware::graphics::composer3::DimmingStage;
using aidl::android::hardware::graphics::composer3::DisplayCapability;
using aidl::android::hardware::graphics::composer3::OverlayProperties;
namespace android {
using hardware::hidl_handle;
using hardware::hidl_vec;
using hardware::Return;
namespace Hwc2 {
namespace {
using android::hardware::Return;
using android::hardware::Void;
using android::HWC2::ComposerCallback;
class ComposerCallbackBridge : public IComposerCallback {
public:
ComposerCallbackBridge(ComposerCallback& callback, bool vsyncSwitchingSupported)
: mCallback(callback), mVsyncSwitchingSupported(vsyncSwitchingSupported) {}
// For code sharing purposes, `ComposerCallback` (implemented by SurfaceFlinger)
// replaced `onComposerHalHotplug` with `onComposerHalHotplugEvent` by converting
// from HIDL's connection into an AIDL DisplayHotplugEvent.
Return<void> onHotplug(Display display, Connection connection) override {
const auto event = connection == Connection::CONNECTED ? DisplayHotplugEvent::CONNECTED
: DisplayHotplugEvent::DISCONNECTED;
mCallback.onComposerHalHotplugEvent(display, event);
return Void();
}
Return<void> onRefresh(Display display) override {
mCallback.onComposerHalRefresh(display);
return Void();
}
Return<void> onVsync(Display display, int64_t timestamp) override {
if (!mVsyncSwitchingSupported) {
mCallback.onComposerHalVsync(display, timestamp, std::nullopt);
} else {
ALOGW("Unexpected onVsync callback on composer >= 2.4, ignoring.");
}
return Void();
}
Return<void> onVsync_2_4(Display display, int64_t timestamp,
VsyncPeriodNanos vsyncPeriodNanos) override {
if (mVsyncSwitchingSupported) {
mCallback.onComposerHalVsync(display, timestamp, vsyncPeriodNanos);
} else {
ALOGW("Unexpected onVsync_2_4 callback on composer <= 2.3, ignoring.");
}
return Void();
}
Return<void> onVsyncPeriodTimingChanged(Display display,
const VsyncPeriodChangeTimeline& timeline) override {
mCallback.onComposerHalVsyncPeriodTimingChanged(display, timeline);
return Void();
}
Return<void> onSeamlessPossible(Display display) override {
mCallback.onComposerHalSeamlessPossible(display);
return Void();
}
private:
ComposerCallback& mCallback;
const bool mVsyncSwitchingSupported;
};
} // namespace
HidlComposer::~HidlComposer() = default;
namespace {
class BufferHandle {
public:
explicit BufferHandle(const native_handle_t* buffer) {
// nullptr is not a valid handle to HIDL
mHandle = (buffer) ? buffer : native_handle_init(mStorage, 0, 0);
}
operator const hidl_handle&() const // NOLINT(google-explicit-constructor)
{
return mHandle;
}
private:
NATIVE_HANDLE_DECLARE_STORAGE(mStorage, 0, 0);
hidl_handle mHandle;
};
class FenceHandle {
public:
FenceHandle(int fd, bool owned) : mOwned(owned) {
native_handle_t* handle;
if (fd >= 0) {
handle = native_handle_init(mStorage, 1, 0);
handle->data[0] = fd;
} else {
// nullptr is not a valid handle to HIDL
handle = native_handle_init(mStorage, 0, 0);
}
mHandle = handle;
}
~FenceHandle() {
if (mOwned) {
native_handle_close(mHandle);
}
}
operator const hidl_handle&() const // NOLINT(google-explicit-constructor)
{
return mHandle;
}
private:
bool mOwned;
NATIVE_HANDLE_DECLARE_STORAGE(mStorage, 1, 0);
hidl_handle mHandle;
};
// assume NO_RESOURCES when Status::isOk returns false
constexpr Error kDefaultError = Error::NO_RESOURCES;
constexpr V2_4::Error kDefaultError_2_4 = static_cast<V2_4::Error>(kDefaultError);
template <typename T, typename U>
T unwrapRet(Return<T>& ret, const U& default_val) {
return (ret.isOk()) ? static_cast<T>(ret) : static_cast<T>(default_val);
}
Error unwrapRet(Return<Error>& ret) {
return unwrapRet(ret, kDefaultError);
}
template <typename To, typename From>
To translate(From x) {
return static_cast<To>(x);
}
template <typename To, typename From>
std::vector<To> translate(const hidl_vec<From>& in) {
std::vector<To> out;
out.reserve(in.size());
std::transform(in.begin(), in.end(), std::back_inserter(out),
[](From x) { return translate<To>(x); });
return out;
}
sp<GraphicBuffer> allocateClearSlotBuffer() {
if (!sysprop::clear_slots_with_set_layer_buffer(false)) {
return nullptr;
}
sp<GraphicBuffer> buffer = sp<GraphicBuffer>::make(1, 1, PIXEL_FORMAT_RGBX_8888,
GraphicBuffer::USAGE_HW_COMPOSER |
GraphicBuffer::USAGE_SW_READ_OFTEN |
GraphicBuffer::USAGE_SW_WRITE_OFTEN,
"HidlComposer");
if (!buffer || buffer->initCheck() != ::android::OK) {
return nullptr;
}
return std::move(buffer);
}
} // anonymous namespace
HidlComposer::HidlComposer(const std::string& serviceName)
: mClearSlotBuffer(allocateClearSlotBuffer()), mWriter(kWriterInitialSize) {
mComposer = V2_1::IComposer::getService(serviceName);
if (mComposer == nullptr) {
LOG_ALWAYS_FATAL("failed to get hwcomposer service");
}
if (sp<IComposer> composer_2_4 = IComposer::castFrom(mComposer)) {
composer_2_4->createClient_2_4([&](const auto& tmpError, const auto& tmpClient) {
if (tmpError == V2_4::Error::NONE) {
mClient = tmpClient;
mClient_2_2 = tmpClient;
mClient_2_3 = tmpClient;
mClient_2_4 = tmpClient;
}
});
} else if (sp<V2_3::IComposer> composer_2_3 = V2_3::IComposer::castFrom(mComposer)) {
composer_2_3->createClient_2_3([&](const auto& tmpError, const auto& tmpClient) {
if (tmpError == Error::NONE) {
mClient = tmpClient;
mClient_2_2 = tmpClient;
mClient_2_3 = tmpClient;
}
});
} else {
mComposer->createClient([&](const auto& tmpError, const auto& tmpClient) {
if (tmpError != Error::NONE) {
return;
}
mClient = tmpClient;
if (sp<V2_2::IComposer> composer_2_2 = V2_2::IComposer::castFrom(mComposer)) {
mClient_2_2 = V2_2::IComposerClient::castFrom(mClient);
LOG_ALWAYS_FATAL_IF(mClient_2_2 == nullptr,
"IComposer 2.2 did not return IComposerClient 2.2");
}
});
}
if (mClient == nullptr) {
LOG_ALWAYS_FATAL("failed to create composer client");
}
if (!mClearSlotBuffer && sysprop::clear_slots_with_set_layer_buffer(false)) {
LOG_ALWAYS_FATAL("Failed to allocate a buffer for clearing layer buffer slots");
return;
}
}
bool HidlComposer::isSupported(OptionalFeature feature) const {
switch (feature) {
case OptionalFeature::RefreshRateSwitching:
return mClient_2_4 != nullptr;
case OptionalFeature::ExpectedPresentTime:
case OptionalFeature::DisplayBrightnessCommand:
case OptionalFeature::KernelIdleTimer:
case OptionalFeature::PhysicalDisplayOrientation:
return false;
}
}
bool HidlComposer::isVrrSupported() const {
// VRR is not supported on the HIDL composer.
return false;
};
std::vector<Capability> HidlComposer::getCapabilities() {
std::vector<Capability> capabilities;
mComposer->getCapabilities([&](const auto& tmpCapabilities) {
capabilities = translate<Capability>(tmpCapabilities);
});
return capabilities;
}
std::string HidlComposer::dumpDebugInfo() {
std::string info;
mComposer->dumpDebugInfo([&](const auto& tmpInfo) { info = tmpInfo.c_str(); });
return info;
}
void HidlComposer::registerCallback(const sp<IComposerCallback>& callback) {
android::hardware::setMinSchedulerPolicy(callback, SCHED_FIFO, 2);
auto ret = [&]() {
if (mClient_2_4) {
return mClient_2_4->registerCallback_2_4(callback);
}
return mClient->registerCallback(callback);
}();
if (!ret.isOk()) {
ALOGE("failed to register IComposerCallback");
}
}
Error HidlComposer::executeCommands(Display) {
return execute();
}
uint32_t HidlComposer::getMaxVirtualDisplayCount() {
auto ret = mClient->getMaxVirtualDisplayCount();
return unwrapRet(ret, 0);
}
Error HidlComposer::createVirtualDisplay(uint32_t width, uint32_t height, PixelFormat* format,
Display* outDisplay) {
const uint32_t bufferSlotCount = 1;
Error error = kDefaultError;
if (mClient_2_2) {
mClient_2_2->createVirtualDisplay_2_2(width, height,
static_cast<types::V1_1::PixelFormat>(*format),
bufferSlotCount,
[&](const auto& tmpError, const auto& tmpDisplay,
const auto& tmpFormat) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outDisplay = tmpDisplay;
*format = static_cast<types::V1_2::PixelFormat>(
tmpFormat);
});
} else {
mClient->createVirtualDisplay(width, height, static_cast<types::V1_0::PixelFormat>(*format),
bufferSlotCount,
[&](const auto& tmpError, const auto& tmpDisplay,
const auto& tmpFormat) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outDisplay = tmpDisplay;
*format = static_cast<PixelFormat>(tmpFormat);
});
}
return error;
}
Error HidlComposer::destroyVirtualDisplay(Display display) {
auto ret = mClient->destroyVirtualDisplay(display);
return unwrapRet(ret);
}
Error HidlComposer::acceptDisplayChanges(Display display) {
mWriter.selectDisplay(display);
mWriter.acceptDisplayChanges();
return Error::NONE;
}
Error HidlComposer::createLayer(Display display, Layer* outLayer) {
Error error = kDefaultError;
mClient->createLayer(display, kMaxLayerBufferCount,
[&](const auto& tmpError, const auto& tmpLayer) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outLayer = tmpLayer;
});
return error;
}
Error HidlComposer::destroyLayer(Display display, Layer layer) {
auto ret = mClient->destroyLayer(display, layer);
return unwrapRet(ret);
}
Error HidlComposer::getActiveConfig(Display display, Config* outConfig) {
Error error = kDefaultError;
mClient->getActiveConfig(display, [&](const auto& tmpError, const auto& tmpConfig) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outConfig = tmpConfig;
});
return error;
}
Error HidlComposer::getChangedCompositionTypes(
Display display, std::vector<Layer>* outLayers,
std::vector<aidl::android::hardware::graphics::composer3::Composition>* outTypes) {
mReader.takeChangedCompositionTypes(display, outLayers, outTypes);
return Error::NONE;
}
Error HidlComposer::getColorModes(Display display, std::vector<ColorMode>* outModes) {
Error error = kDefaultError;
if (mClient_2_3) {
mClient_2_3->getColorModes_2_3(display, [&](const auto& tmpError, const auto& tmpModes) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outModes = tmpModes;
});
} else if (mClient_2_2) {
mClient_2_2->getColorModes_2_2(display, [&](const auto& tmpError, const auto& tmpModes) {
error = tmpError;
if (error != Error::NONE) {
return;
}
for (types::V1_1::ColorMode colorMode : tmpModes) {
outModes->push_back(static_cast<ColorMode>(colorMode));
}
});
} else {
mClient->getColorModes(display, [&](const auto& tmpError, const auto& tmpModes) {
error = tmpError;
if (error != Error::NONE) {
return;
}
for (types::V1_0::ColorMode colorMode : tmpModes) {
outModes->push_back(static_cast<ColorMode>(colorMode));
}
});
}
return error;
}
Error HidlComposer::getDisplayAttribute(Display display, Config config,
IComposerClient::Attribute attribute, int32_t* outValue) {
Error error = kDefaultError;
if (mClient_2_4) {
mClient_2_4->getDisplayAttribute_2_4(display, config, attribute,
[&](const auto& tmpError, const auto& tmpValue) {
error = static_cast<Error>(tmpError);
if (error != Error::NONE) {
return;
}
*outValue = tmpValue;
});
} else {
mClient->getDisplayAttribute(display, config,
static_cast<V2_1::IComposerClient::Attribute>(attribute),
[&](const auto& tmpError, const auto& tmpValue) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outValue = tmpValue;
});
}
return error;
}
Error HidlComposer::getDisplayConfigs(Display display, std::vector<Config>* outConfigs) {
Error error = kDefaultError;
mClient->getDisplayConfigs(display, [&](const auto& tmpError, const auto& tmpConfigs) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outConfigs = tmpConfigs;
});
return error;
}
Error HidlComposer::getDisplayConfigurations(Display, int32_t /*maxFrameIntervalNs*/,
std::vector<DisplayConfiguration>*) {
LOG_ALWAYS_FATAL("getDisplayConfigurations should not have been called on this, as "
"it's a HWC3 interface version 3 feature");
}
Error HidlComposer::getDisplayName(Display display, std::string* outName) {
Error error = kDefaultError;
mClient->getDisplayName(display, [&](const auto& tmpError, const auto& tmpName) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outName = tmpName.c_str();
});
return error;
}
Error HidlComposer::getDisplayRequests(Display display, uint32_t* outDisplayRequestMask,
std::vector<Layer>* outLayers,
std::vector<uint32_t>* outLayerRequestMasks) {
mReader.takeDisplayRequests(display, outDisplayRequestMask, outLayers, outLayerRequestMasks);
return Error::NONE;
}
Error HidlComposer::getDozeSupport(Display display, bool* outSupport) {
Error error = kDefaultError;
mClient->getDozeSupport(display, [&](const auto& tmpError, const auto& tmpSupport) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outSupport = tmpSupport;
});
return error;
}
Error HidlComposer::hasDisplayIdleTimerCapability(Display, bool*) {
LOG_ALWAYS_FATAL("hasDisplayIdleTimerCapability should have never been called on this as "
"OptionalFeature::KernelIdleTimer is not supported on HIDL");
}
Error HidlComposer::getHdrCapabilities(Display display, std::vector<Hdr>* outHdrTypes,
float* outMaxLuminance, float* outMaxAverageLuminance,
float* outMinLuminance) {
Error error = kDefaultError;
if (mClient_2_3) {
mClient_2_3->getHdrCapabilities_2_3(display,
[&](const auto& tmpError, const auto& tmpHdrTypes,
const auto& tmpMaxLuminance,
const auto& tmpMaxAverageLuminance,
const auto& tmpMinLuminance) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outHdrTypes = translate<ui::Hdr>(tmpHdrTypes);
*outMaxLuminance = tmpMaxLuminance;
*outMaxAverageLuminance = tmpMaxAverageLuminance;
*outMinLuminance = tmpMinLuminance;
});
} else {
mClient->getHdrCapabilities(display,
[&](const auto& tmpError, const auto& tmpHdrTypes,
const auto& tmpMaxLuminance,
const auto& tmpMaxAverageLuminance,
const auto& tmpMinLuminance) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outHdrTypes = translate<ui::Hdr>(tmpHdrTypes);
*outMaxLuminance = tmpMaxLuminance;
*outMaxAverageLuminance = tmpMaxAverageLuminance;
*outMinLuminance = tmpMinLuminance;
});
}
return error;
}
Error HidlComposer::getOverlaySupport(OverlayProperties* /*outProperties*/) {
return Error::NONE;
}
Error HidlComposer::getReleaseFences(Display display, std::vector<Layer>* outLayers,
std::vector<int>* outReleaseFences) {
mReader.takeReleaseFences(display, outLayers, outReleaseFences);
return Error::NONE;
}
Error HidlComposer::presentDisplay(Display display, int* outPresentFence) {
ATRACE_NAME("HwcPresentDisplay");
mWriter.selectDisplay(display);
mWriter.presentDisplay();
Error error = execute();
if (error != Error::NONE) {
return error;
}
mReader.takePresentFence(display, outPresentFence);
return Error::NONE;
}
Error HidlComposer::setActiveConfig(Display display, Config config) {
auto ret = mClient->setActiveConfig(display, config);
return unwrapRet(ret);
}
Error HidlComposer::setClientTarget(Display display, uint32_t slot, const sp<GraphicBuffer>& target,
int acquireFence, Dataspace dataspace,
const std::vector<IComposerClient::Rect>& damage,
float /*hdrSdrRatio*/) {
mWriter.selectDisplay(display);
const native_handle_t* handle = nullptr;
if (target.get()) {
handle = target->getNativeBuffer()->handle;
}
mWriter.setClientTarget(slot, handle, acquireFence, dataspace, damage);
return Error::NONE;
}
Error HidlComposer::setColorMode(Display display, ColorMode mode, RenderIntent renderIntent) {
hardware::Return<Error> ret(kDefaultError);
if (mClient_2_3) {
ret = mClient_2_3->setColorMode_2_3(display, mode, renderIntent);
} else if (mClient_2_2) {
ret = mClient_2_2->setColorMode_2_2(display, static_cast<types::V1_1::ColorMode>(mode),
renderIntent);
} else {
ret = mClient->setColorMode(display, static_cast<types::V1_0::ColorMode>(mode));
}
return unwrapRet(ret);
}
Error HidlComposer::setColorTransform(Display display, const float* matrix) {
mWriter.selectDisplay(display);
const bool isIdentity = (mat4(matrix) == mat4());
mWriter.setColorTransform(matrix,
isIdentity ? ColorTransform::IDENTITY
: ColorTransform::ARBITRARY_MATRIX);
return Error::NONE;
}
Error HidlComposer::setOutputBuffer(Display display, const native_handle_t* buffer,
int releaseFence) {
mWriter.selectDisplay(display);
mWriter.setOutputBuffer(0, buffer, dup(releaseFence));
return Error::NONE;
}
Error HidlComposer::setPowerMode(Display display, IComposerClient::PowerMode mode) {
Return<Error> ret(Error::UNSUPPORTED);
if (mClient_2_2) {
ret = mClient_2_2->setPowerMode_2_2(display, mode);
} else if (mode != IComposerClient::PowerMode::ON_SUSPEND) {
ret = mClient->setPowerMode(display, static_cast<V2_1::IComposerClient::PowerMode>(mode));
}
return unwrapRet(ret);
}
Error HidlComposer::setVsyncEnabled(Display display, IComposerClient::Vsync enabled) {
auto ret = mClient->setVsyncEnabled(display, enabled);
return unwrapRet(ret);
}
Error HidlComposer::setClientTargetSlotCount(Display display) {
const uint32_t bufferSlotCount = BufferQueue::NUM_BUFFER_SLOTS;
auto ret = mClient->setClientTargetSlotCount(display, bufferSlotCount);
return unwrapRet(ret);
}
Error HidlComposer::validateDisplay(Display display, nsecs_t /*expectedPresentTime*/,
int32_t /*frameIntervalNs*/, uint32_t* outNumTypes,
uint32_t* outNumRequests) {
ATRACE_NAME("HwcValidateDisplay");
mWriter.selectDisplay(display);
mWriter.validateDisplay();
Error error = execute();
if (error != Error::NONE) {
return error;
}
mReader.hasChanges(display, outNumTypes, outNumRequests);
return Error::NONE;
}
Error HidlComposer::presentOrValidateDisplay(Display display, nsecs_t /*expectedPresentTime*/,
int32_t /*frameIntervalNs*/, uint32_t* outNumTypes,
uint32_t* outNumRequests, int* outPresentFence,
uint32_t* state) {
ATRACE_NAME("HwcPresentOrValidateDisplay");
mWriter.selectDisplay(display);
mWriter.presentOrvalidateDisplay();
Error error = execute();
if (error != Error::NONE) {
return error;
}
mReader.takePresentOrValidateStage(display, state);
if (*state == 1) { // Present succeeded
mReader.takePresentFence(display, outPresentFence);
}
if (*state == 0) { // Validate succeeded.
mReader.hasChanges(display, outNumTypes, outNumRequests);
}
return Error::NONE;
}
Error HidlComposer::setCursorPosition(Display display, Layer layer, int32_t x, int32_t y) {
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerCursorPosition(x, y);
return Error::NONE;
}
Error HidlComposer::setLayerBuffer(Display display, Layer layer, uint32_t slot,
const sp<GraphicBuffer>& buffer, int acquireFence) {
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
const native_handle_t* handle = nullptr;
if (buffer.get()) {
handle = buffer->getNativeBuffer()->handle;
}
mWriter.setLayerBuffer(slot, handle, acquireFence);
return Error::NONE;
}
Error HidlComposer::setLayerBufferSlotsToClear(Display display, Layer layer,
const std::vector<uint32_t>& slotsToClear,
uint32_t activeBufferSlot) {
if (slotsToClear.empty()) {
return Error::NONE;
}
// This can be null when the HAL hasn't explicitly enabled this feature.
if (mClearSlotBuffer == nullptr) {
return Error::NONE;
}
// Backwards compatible way of clearing buffer is to set the layer buffer with a placeholder
// buffer, using the slot that needs to cleared... tricky.
for (uint32_t slot : slotsToClear) {
// Don't clear the active buffer slot because we need to restore the active buffer after
// setting the requested buffer slots with a placeholder buffer.
if (slot != activeBufferSlot) {
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerBuffer(slot, mClearSlotBuffer->handle, /*fence*/ -1);
}
}
// Since we clear buffers by setting them to a placeholder buffer, we want to make sure that the
// last setLayerBuffer command is sent with the currently active buffer, not the placeholder
// buffer, so that there is no perceptual change.
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerBuffer(activeBufferSlot, /*buffer*/ nullptr, /*fence*/ -1);
return Error::NONE;
}
Error HidlComposer::setLayerSurfaceDamage(Display display, Layer layer,
const std::vector<IComposerClient::Rect>& damage) {
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerSurfaceDamage(damage);
return Error::NONE;
}
Error HidlComposer::setLayerBlendMode(Display display, Layer layer,
IComposerClient::BlendMode mode) {
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerBlendMode(mode);
return Error::NONE;
}
static IComposerClient::Color to_hidl_type(
aidl::android::hardware::graphics::composer3::Color color) {
const auto floatColorToUint8Clamped = [](float val) -> uint8_t {
const auto intVal = static_cast<uint64_t>(std::round(255.0f * val));
const auto minVal = static_cast<uint64_t>(0);
const auto maxVal = static_cast<uint64_t>(255);
return std::clamp(intVal, minVal, maxVal);
};
return IComposerClient::Color{
floatColorToUint8Clamped(color.r),
floatColorToUint8Clamped(color.g),
floatColorToUint8Clamped(color.b),
floatColorToUint8Clamped(color.a),
};
}
Error HidlComposer::setLayerColor(
Display display, Layer layer,
const aidl::android::hardware::graphics::composer3::Color& color) {
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerColor(to_hidl_type(color));
return Error::NONE;
}
static IComposerClient::Composition to_hidl_type(
aidl::android::hardware::graphics::composer3::Composition type) {
LOG_ALWAYS_FATAL_IF(static_cast<int32_t>(type) >
static_cast<int32_t>(IComposerClient::Composition::SIDEBAND),
"Trying to use %s, which is not supported by HidlComposer!",
android::to_string(type).c_str());
return static_cast<IComposerClient::Composition>(type);
}
Error HidlComposer::setLayerCompositionType(
Display display, Layer layer,
aidl::android::hardware::graphics::composer3::Composition type) {
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerCompositionType(to_hidl_type(type));
return Error::NONE;
}
Error HidlComposer::setLayerDataspace(Display display, Layer layer, Dataspace dataspace) {
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerDataspace(dataspace);
return Error::NONE;
}
Error HidlComposer::setLayerDisplayFrame(Display display, Layer layer,
const IComposerClient::Rect& frame) {
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerDisplayFrame(frame);
return Error::NONE;
}
Error HidlComposer::setLayerPlaneAlpha(Display display, Layer layer, float alpha) {
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerPlaneAlpha(alpha);
return Error::NONE;
}
Error HidlComposer::setLayerSidebandStream(Display display, Layer layer,
const native_handle_t* stream) {
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerSidebandStream(stream);
return Error::NONE;
}
Error HidlComposer::setLayerSourceCrop(Display display, Layer layer,
const IComposerClient::FRect& crop) {
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerSourceCrop(crop);
return Error::NONE;
}
Error HidlComposer::setLayerTransform(Display display, Layer layer, Transform transform) {
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerTransform(transform);
return Error::NONE;
}
Error HidlComposer::setLayerVisibleRegion(Display display, Layer layer,
const std::vector<IComposerClient::Rect>& visible) {
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerVisibleRegion(visible);
return Error::NONE;
}
Error HidlComposer::setLayerZOrder(Display display, Layer layer, uint32_t z) {
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerZOrder(z);
return Error::NONE;
}
Error HidlComposer::execute() {
// prepare input command queue
bool queueChanged = false;
uint32_t commandLength = 0;
hidl_vec<hidl_handle> commandHandles;
if (!mWriter.writeQueue(&queueChanged, &commandLength, &commandHandles)) {
mWriter.reset();
return Error::NO_RESOURCES;
}
// set up new input command queue if necessary
if (queueChanged) {
auto ret = mClient->setInputCommandQueue(*mWriter.getMQDescriptor());
auto error = unwrapRet(ret);
if (error != Error::NONE) {
mWriter.reset();
return error;
}
}
if (commandLength == 0) {
mWriter.reset();
return Error::NONE;
}
Error error = kDefaultError;
hardware::Return<void> ret;
auto hidl_callback = [&](const auto& tmpError, const auto& tmpOutChanged,
const auto& tmpOutLength, const auto& tmpOutHandles) {
error = tmpError;
// set up new output command queue if necessary
if (error == Error::NONE && tmpOutChanged) {
error = kDefaultError;
mClient->getOutputCommandQueue([&](const auto& tmpError, const auto& tmpDescriptor) {
error = tmpError;
if (error != Error::NONE) {
return;
}
mReader.setMQDescriptor(tmpDescriptor);
});
}
if (error != Error::NONE) {
return;
}
if (mReader.readQueue(tmpOutLength, tmpOutHandles)) {
error = mReader.parse();
mReader.reset();
} else {
error = Error::NO_RESOURCES;
}
};
if (mClient_2_2) {
ret = mClient_2_2->executeCommands_2_2(commandLength, commandHandles, hidl_callback);
} else {
ret = mClient->executeCommands(commandLength, commandHandles, hidl_callback);
}
// executeCommands can fail because of out-of-fd and we do not want to
// abort() in that case
if (!ret.isOk()) {
ALOGE("executeCommands failed because of %s", ret.description().c_str());
}
if (error == Error::NONE) {
std::vector<CommandReader::CommandError> commandErrors = mReader.takeErrors();
for (const auto& cmdErr : commandErrors) {
auto command =
static_cast<IComposerClient::Command>(mWriter.getCommand(cmdErr.location));
if (command == IComposerClient::Command::VALIDATE_DISPLAY ||
command == IComposerClient::Command::PRESENT_DISPLAY ||
command == IComposerClient::Command::PRESENT_OR_VALIDATE_DISPLAY) {
error = cmdErr.error;
} else {
ALOGW("command 0x%x generated error %d", command, cmdErr.error);
}
}
}
mWriter.reset();
return error;
}
// Composer HAL 2.2
Error HidlComposer::setLayerPerFrameMetadata(
Display display, Layer layer,
const std::vector<IComposerClient::PerFrameMetadata>& perFrameMetadatas) {
if (!mClient_2_2) {
return Error::UNSUPPORTED;
}
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerPerFrameMetadata(perFrameMetadatas);
return Error::NONE;
}
std::vector<IComposerClient::PerFrameMetadataKey> HidlComposer::getPerFrameMetadataKeys(
Display display) {
std::vector<IComposerClient::PerFrameMetadataKey> keys;
if (!mClient_2_2) {
return keys;
}
Error error = kDefaultError;
if (mClient_2_3) {
mClient_2_3->getPerFrameMetadataKeys_2_3(display,
[&](const auto& tmpError, const auto& tmpKeys) {
error = tmpError;
if (error != Error::NONE) {
ALOGW("getPerFrameMetadataKeys failed "
"with %d",
tmpError);
return;
}
keys = tmpKeys;
});
} else {
mClient_2_2
->getPerFrameMetadataKeys(display, [&](const auto& tmpError, const auto& tmpKeys) {
error = tmpError;
if (error != Error::NONE) {
ALOGW("getPerFrameMetadataKeys failed with %d", tmpError);
return;
}
keys.clear();
for (auto key : tmpKeys) {
keys.push_back(static_cast<IComposerClient::PerFrameMetadataKey>(key));
}
});
}
return keys;
}
Error HidlComposer::getRenderIntents(Display display, ColorMode colorMode,
std::vector<RenderIntent>* outRenderIntents) {
if (!mClient_2_2) {
outRenderIntents->push_back(RenderIntent::COLORIMETRIC);
return Error::NONE;
}
Error error = kDefaultError;
auto getRenderIntentsLambda = [&](const auto& tmpError, const auto& tmpKeys) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outRenderIntents = tmpKeys;
};
if (mClient_2_3) {
mClient_2_3->getRenderIntents_2_3(display, colorMode, getRenderIntentsLambda);
} else {
mClient_2_2->getRenderIntents(display, static_cast<types::V1_1::ColorMode>(colorMode),
getRenderIntentsLambda);
}
return error;
}
Error HidlComposer::getDataspaceSaturationMatrix(Dataspace dataspace, mat4* outMatrix) {
if (!mClient_2_2) {
*outMatrix = mat4();
return Error::NONE;
}
Error error = kDefaultError;
mClient_2_2->getDataspaceSaturationMatrix(static_cast<types::V1_1::Dataspace>(dataspace),
[&](const auto& tmpError, const auto& tmpMatrix) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outMatrix = mat4(tmpMatrix.data());
});
return error;
}
// Composer HAL 2.3
Error HidlComposer::getDisplayIdentificationData(Display display, uint8_t* outPort,
std::vector<uint8_t>* outData) {
if (!mClient_2_3) {
return Error::UNSUPPORTED;
}
Error error = kDefaultError;
mClient_2_3->getDisplayIdentificationData(display,
[&](const auto& tmpError, const auto& tmpPort,
const auto& tmpData) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outPort = tmpPort;
*outData = tmpData;
});
return error;
}
Error HidlComposer::setLayerColorTransform(Display display, Layer layer, const float* matrix) {
if (!mClient_2_3) {
return Error::UNSUPPORTED;
}
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerColorTransform(matrix);
return Error::NONE;
}
Error HidlComposer::getDisplayedContentSamplingAttributes(Display display, PixelFormat* outFormat,
Dataspace* outDataspace,
uint8_t* outComponentMask) {
if (!outFormat || !outDataspace || !outComponentMask) {
return Error::BAD_PARAMETER;
}
if (!mClient_2_3) {
return Error::UNSUPPORTED;
}
Error error = kDefaultError;
mClient_2_3->getDisplayedContentSamplingAttributes(display,
[&](const auto tmpError,
const auto& tmpFormat,
const auto& tmpDataspace,
const auto& tmpComponentMask) {
error = tmpError;
if (error == Error::NONE) {
*outFormat = tmpFormat;
*outDataspace = tmpDataspace;
*outComponentMask =
static_cast<uint8_t>(
tmpComponentMask);
}
});
return error;
}
Error HidlComposer::setDisplayContentSamplingEnabled(Display display, bool enabled,
uint8_t componentMask, uint64_t maxFrames) {
if (!mClient_2_3) {
return Error::UNSUPPORTED;
}
auto enable = enabled ? V2_3::IComposerClient::DisplayedContentSampling::ENABLE
: V2_3::IComposerClient::DisplayedContentSampling::DISABLE;
return mClient_2_3->setDisplayedContentSamplingEnabled(display, enable, componentMask,
maxFrames);
}
Error HidlComposer::getDisplayedContentSample(Display display, uint64_t maxFrames,
uint64_t timestamp, DisplayedFrameStats* outStats) {
if (!outStats) {
return Error::BAD_PARAMETER;
}
if (!mClient_2_3) {
return Error::UNSUPPORTED;
}
Error error = kDefaultError;
mClient_2_3->getDisplayedContentSample(display, maxFrames, timestamp,
[&](const auto tmpError, auto tmpNumFrames,
const auto& tmpSamples0, const auto& tmpSamples1,
const auto& tmpSamples2, const auto& tmpSamples3) {
error = tmpError;
if (error == Error::NONE) {
outStats->numFrames = tmpNumFrames;
outStats->component_0_sample = tmpSamples0;
outStats->component_1_sample = tmpSamples1;
outStats->component_2_sample = tmpSamples2;
outStats->component_3_sample = tmpSamples3;
}
});
return error;
}
Error HidlComposer::setLayerPerFrameMetadataBlobs(
Display display, Layer layer,
const std::vector<IComposerClient::PerFrameMetadataBlob>& metadata) {
if (!mClient_2_3) {
return Error::UNSUPPORTED;
}
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerPerFrameMetadataBlobs(metadata);
return Error::NONE;
}
Error HidlComposer::setDisplayBrightness(Display display, float brightness, float,
const DisplayBrightnessOptions&) {
if (!mClient_2_3) {
return Error::UNSUPPORTED;
}
return mClient_2_3->setDisplayBrightness(display, brightness);
}
// Composer HAL 2.4
Error HidlComposer::getDisplayCapabilities(Display display,
std::vector<DisplayCapability>* outCapabilities) {
if (!mClient_2_3) {
return Error::UNSUPPORTED;
}
V2_4::Error error = kDefaultError_2_4;
if (mClient_2_4) {
mClient_2_4->getDisplayCapabilities_2_4(display,
[&](const auto& tmpError, const auto& tmpCaps) {
error = tmpError;
if (error != V2_4::Error::NONE) {
return;
}
*outCapabilities =
translate<DisplayCapability>(tmpCaps);
});
} else {
mClient_2_3
->getDisplayCapabilities(display, [&](const auto& tmpError, const auto& tmpCaps) {
error = static_cast<V2_4::Error>(tmpError);
if (error != V2_4::Error::NONE) {
return;
}
*outCapabilities = translate<DisplayCapability>(tmpCaps);
});
}
return static_cast<Error>(error);
}
V2_4::Error HidlComposer::getDisplayConnectionType(
Display display, IComposerClient::DisplayConnectionType* outType) {
using Error = V2_4::Error;
if (!mClient_2_4) {
return Error::UNSUPPORTED;
}
Error error = kDefaultError_2_4;
mClient_2_4->getDisplayConnectionType(display, [&](const auto& tmpError, const auto& tmpType) {
error = tmpError;
if (error != V2_4::Error::NONE) {
return;
}
*outType = tmpType;
});
return error;
}
V2_4::Error HidlComposer::getDisplayVsyncPeriod(Display display, VsyncPeriodNanos* outVsyncPeriod) {
using Error = V2_4::Error;
if (!mClient_2_4) {
return Error::UNSUPPORTED;
}
Error error = kDefaultError_2_4;
mClient_2_4->getDisplayVsyncPeriod(display,
[&](const auto& tmpError, const auto& tmpVsyncPeriod) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outVsyncPeriod = tmpVsyncPeriod;
});
return error;
}
V2_4::Error HidlComposer::setActiveConfigWithConstraints(
Display display, Config config,
const IComposerClient::VsyncPeriodChangeConstraints& vsyncPeriodChangeConstraints,
VsyncPeriodChangeTimeline* outTimeline) {
using Error = V2_4::Error;
if (!mClient_2_4) {
return Error::UNSUPPORTED;
}
Error error = kDefaultError_2_4;
mClient_2_4->setActiveConfigWithConstraints(display, config, vsyncPeriodChangeConstraints,
[&](const auto& tmpError, const auto& tmpTimeline) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outTimeline = tmpTimeline;
});
return error;
}
V2_4::Error HidlComposer::setAutoLowLatencyMode(Display display, bool on) {
using Error = V2_4::Error;
if (!mClient_2_4) {
return Error::UNSUPPORTED;
}
return mClient_2_4->setAutoLowLatencyMode(display, on);
}
V2_4::Error HidlComposer::getSupportedContentTypes(
Display displayId, std::vector<IComposerClient::ContentType>* outSupportedContentTypes) {
using Error = V2_4::Error;
if (!mClient_2_4) {
return Error::UNSUPPORTED;
}
Error error = kDefaultError_2_4;
mClient_2_4->getSupportedContentTypes(displayId,
[&](const auto& tmpError,
const auto& tmpSupportedContentTypes) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outSupportedContentTypes = tmpSupportedContentTypes;
});
return error;
}
V2_4::Error HidlComposer::setContentType(Display display,
IComposerClient::ContentType contentType) {
using Error = V2_4::Error;
if (!mClient_2_4) {
return Error::UNSUPPORTED;
}
return mClient_2_4->setContentType(display, contentType);
}
V2_4::Error HidlComposer::setLayerGenericMetadata(Display display, Layer layer,
const std::string& key, bool mandatory,
const std::vector<uint8_t>& value) {
using Error = V2_4::Error;
if (!mClient_2_4) {
return Error::UNSUPPORTED;
}
mWriter.selectDisplay(display);
mWriter.selectLayer(layer);
mWriter.setLayerGenericMetadata(key, mandatory, value);
return Error::NONE;
}
V2_4::Error HidlComposer::getLayerGenericMetadataKeys(
std::vector<IComposerClient::LayerGenericMetadataKey>* outKeys) {
using Error = V2_4::Error;
if (!mClient_2_4) {
return Error::UNSUPPORTED;
}
Error error = kDefaultError_2_4;
mClient_2_4->getLayerGenericMetadataKeys([&](const auto& tmpError, const auto& tmpKeys) {
error = tmpError;
if (error != Error::NONE) {
return;
}
*outKeys = tmpKeys;
});
return error;
}
Error HidlComposer::setBootDisplayConfig(Display /*displayId*/, Config) {
return Error::UNSUPPORTED;
}
Error HidlComposer::clearBootDisplayConfig(Display /*displayId*/) {
return Error::UNSUPPORTED;
}
Error HidlComposer::getPreferredBootDisplayConfig(Display /*displayId*/, Config*) {
return Error::UNSUPPORTED;
}
Error HidlComposer::getHdrConversionCapabilities(std::vector<HdrConversionCapability>*) {
return Error::UNSUPPORTED;
}
Error HidlComposer::setHdrConversionStrategy(HdrConversionStrategy, Hdr*) {
return Error::UNSUPPORTED;
}
Error HidlComposer::setRefreshRateChangedCallbackDebugEnabled(Display, bool) {
return Error::UNSUPPORTED;
}
Error HidlComposer::notifyExpectedPresent(Display, nsecs_t, int32_t) {
return Error::UNSUPPORTED;
}
Error HidlComposer::getClientTargetProperty(
Display display, ClientTargetPropertyWithBrightness* outClientTargetProperty) {
IComposerClient::ClientTargetProperty property;
mReader.takeClientTargetProperty(display, &property);
outClientTargetProperty->display = display;
outClientTargetProperty->clientTargetProperty.dataspace =
static_cast<::aidl::android::hardware::graphics::common::Dataspace>(property.dataspace);
outClientTargetProperty->clientTargetProperty.pixelFormat =
static_cast<::aidl::android::hardware::graphics::common::PixelFormat>(
property.pixelFormat);
outClientTargetProperty->brightness = 1.f;
outClientTargetProperty->dimmingStage = DimmingStage::NONE;
return Error::NONE;
}
Error HidlComposer::setLayerBrightness(Display, Layer, float) {
return Error::NONE;
}
Error HidlComposer::setLayerBlockingRegion(Display, Layer,
const std::vector<IComposerClient::Rect>&) {
return Error::NONE;
}
Error HidlComposer::getDisplayDecorationSupport(
Display,
std::optional<aidl::android::hardware::graphics::common::DisplayDecorationSupport>*
support) {
support->reset();
return Error::UNSUPPORTED;
}
Error HidlComposer::setIdleTimerEnabled(Display, std::chrono::milliseconds) {
LOG_ALWAYS_FATAL("setIdleTimerEnabled should have never been called on this as "
"OptionalFeature::KernelIdleTimer is not supported on HIDL");
}
Error HidlComposer::getPhysicalDisplayOrientation(Display, AidlTransform*) {
LOG_ALWAYS_FATAL("getPhysicalDisplayOrientation should have never been called on this as "
"OptionalFeature::PhysicalDisplayOrientation is not supported on HIDL");
}
void HidlComposer::registerCallback(ComposerCallback& callback) {
const bool vsyncSwitchingSupported =
isSupported(Hwc2::Composer::OptionalFeature::RefreshRateSwitching);
registerCallback(sp<ComposerCallbackBridge>::make(callback, vsyncSwitchingSupported));
}
void HidlComposer::onHotplugConnect(Display) {}
void HidlComposer::onHotplugDisconnect(Display) {}
CommandReader::~CommandReader() {
resetData();
}
Error CommandReader::parse() {
resetData();
IComposerClient::Command command;
uint16_t length = 0;
while (!isEmpty()) {
if (!beginCommand(&command, &length)) {
break;
}
bool parsed = false;
switch (command) {
case IComposerClient::Command::SELECT_DISPLAY:
parsed = parseSelectDisplay(length);
break;
case IComposerClient::Command::SET_ERROR:
parsed = parseSetError(length);
break;
case IComposerClient::Command::SET_CHANGED_COMPOSITION_TYPES:
parsed = parseSetChangedCompositionTypes(length);
break;
case IComposerClient::Command::SET_DISPLAY_REQUESTS:
parsed = parseSetDisplayRequests(length);
break;
case IComposerClient::Command::SET_PRESENT_FENCE:
parsed = parseSetPresentFence(length);
break;
case IComposerClient::Command::SET_RELEASE_FENCES:
parsed = parseSetReleaseFences(length);
break;
case IComposerClient::Command ::SET_PRESENT_OR_VALIDATE_DISPLAY_RESULT:
parsed = parseSetPresentOrValidateDisplayResult(length);
break;
case IComposerClient::Command::SET_CLIENT_TARGET_PROPERTY:
parsed = parseSetClientTargetProperty(length);
break;
default:
parsed = false;
break;
}
endCommand();
if (!parsed) {
ALOGE("failed to parse command 0x%x length %" PRIu16, command, length);
break;
}
}
return isEmpty() ? Error::NONE : Error::NO_RESOURCES;
}
bool CommandReader::parseSelectDisplay(uint16_t length) {
if (length != CommandWriterBase::kSelectDisplayLength) {
return false;
}
mCurrentReturnData = &mReturnData[read64()];
return true;
}
bool CommandReader::parseSetError(uint16_t length) {
if (length != CommandWriterBase::kSetErrorLength) {
return false;
}
auto location = read();
auto error = static_cast<Error>(readSigned());
mErrors.emplace_back(CommandError{location, error});
return true;
}
bool CommandReader::parseSetChangedCompositionTypes(uint16_t length) {
// (layer id, composition type) pairs
if (length % 3 != 0 || !mCurrentReturnData) {
return false;
}
uint32_t count = length / 3;
mCurrentReturnData->changedLayers.reserve(count);
mCurrentReturnData->compositionTypes.reserve(count);
while (count > 0) {
auto layer = read64();
auto type = static_cast<aidl::android::hardware::graphics::composer3::Composition>(
readSigned());
mCurrentReturnData->changedLayers.push_back(layer);
mCurrentReturnData->compositionTypes.push_back(type);
count--;
}
return true;
}
bool CommandReader::parseSetDisplayRequests(uint16_t length) {
// display requests followed by (layer id, layer requests) pairs
if (length % 3 != 1 || !mCurrentReturnData) {
return false;
}
mCurrentReturnData->displayRequests = read();
uint32_t count = (length - 1) / 3;
mCurrentReturnData->requestedLayers.reserve(count);
mCurrentReturnData->requestMasks.reserve(count);
while (count > 0) {
auto layer = read64();
auto layerRequestMask = read();
mCurrentReturnData->requestedLayers.push_back(layer);
mCurrentReturnData->requestMasks.push_back(layerRequestMask);
count--;
}
return true;
}
bool CommandReader::parseSetPresentFence(uint16_t length) {
if (length != CommandWriterBase::kSetPresentFenceLength || !mCurrentReturnData) {
return false;
}
if (mCurrentReturnData->presentFence >= 0) {
close(mCurrentReturnData->presentFence);
}
mCurrentReturnData->presentFence = readFence();
return true;
}
bool CommandReader::parseSetReleaseFences(uint16_t length) {
// (layer id, release fence index) pairs
if (length % 3 != 0 || !mCurrentReturnData) {
return false;
}
uint32_t count = length / 3;
mCurrentReturnData->releasedLayers.reserve(count);
mCurrentReturnData->releaseFences.reserve(count);
while (count > 0) {
auto layer = read64();
auto fence = readFence();
mCurrentReturnData->releasedLayers.push_back(layer);
mCurrentReturnData->releaseFences.push_back(fence);
count--;
}
return true;
}
bool CommandReader::parseSetPresentOrValidateDisplayResult(uint16_t length) {
if (length != CommandWriterBase::kPresentOrValidateDisplayResultLength || !mCurrentReturnData) {
return false;
}
mCurrentReturnData->presentOrValidateState = read();
return true;
}
bool CommandReader::parseSetClientTargetProperty(uint16_t length) {
if (length != CommandWriterBase::kSetClientTargetPropertyLength || !mCurrentReturnData) {
return false;
}
mCurrentReturnData->clientTargetProperty.pixelFormat = static_cast<PixelFormat>(readSigned());
mCurrentReturnData->clientTargetProperty.dataspace = static_cast<Dataspace>(readSigned());
return true;
}
void CommandReader::resetData() {
mErrors.clear();
for (auto& data : mReturnData) {
if (data.second.presentFence >= 0) {
close(data.second.presentFence);
}
for (auto fence : data.second.releaseFences) {
if (fence >= 0) {
close(fence);
}
}
}
mReturnData.clear();
mCurrentReturnData = nullptr;
}
std::vector<CommandReader::CommandError> CommandReader::takeErrors() {
return std::move(mErrors);
}
bool CommandReader::hasChanges(Display display, uint32_t* outNumChangedCompositionTypes,
uint32_t* outNumLayerRequestMasks) const {
auto found = mReturnData.find(display);
if (found == mReturnData.end()) {
*outNumChangedCompositionTypes = 0;
*outNumLayerRequestMasks = 0;
return false;
}
const ReturnData& data = found->second;
*outNumChangedCompositionTypes = data.compositionTypes.size();
*outNumLayerRequestMasks = data.requestMasks.size();
return !(data.compositionTypes.empty() && data.requestMasks.empty());
}
void CommandReader::takeChangedCompositionTypes(
Display display, std::vector<Layer>* outLayers,
std::vector<aidl::android::hardware::graphics::composer3::Composition>* outTypes) {
auto found = mReturnData.find(display);
if (found == mReturnData.end()) {
outLayers->clear();
outTypes->clear();
return;
}
ReturnData& data = found->second;
*outLayers = std::move(data.changedLayers);
*outTypes = std::move(data.compositionTypes);
}
void CommandReader::takeDisplayRequests(Display display, uint32_t* outDisplayRequestMask,
std::vector<Layer>* outLayers,
std::vector<uint32_t>* outLayerRequestMasks) {
auto found = mReturnData.find(display);
if (found == mReturnData.end()) {
*outDisplayRequestMask = 0;
outLayers->clear();
outLayerRequestMasks->clear();
return;
}
ReturnData& data = found->second;
*outDisplayRequestMask = data.displayRequests;
*outLayers = std::move(data.requestedLayers);
*outLayerRequestMasks = std::move(data.requestMasks);
}
void CommandReader::takeReleaseFences(Display display, std::vector<Layer>* outLayers,
std::vector<int>* outReleaseFences) {
auto found = mReturnData.find(display);
if (found == mReturnData.end()) {
outLayers->clear();
outReleaseFences->clear();
return;
}
ReturnData& data = found->second;
*outLayers = std::move(data.releasedLayers);
*outReleaseFences = std::move(data.releaseFences);
}
void CommandReader::takePresentFence(Display display, int* outPresentFence) {
auto found = mReturnData.find(display);
if (found == mReturnData.end()) {
*outPresentFence = -1;
return;
}
ReturnData& data = found->second;
*outPresentFence = data.presentFence;
data.presentFence = -1;
}
void CommandReader::takePresentOrValidateStage(Display display, uint32_t* state) {
auto found = mReturnData.find(display);
if (found == mReturnData.end()) {
*state = -1;
return;
}
ReturnData& data = found->second;
*state = data.presentOrValidateState;
}
void CommandReader::takeClientTargetProperty(
Display display, IComposerClient::ClientTargetProperty* outClientTargetProperty) {
auto found = mReturnData.find(display);
// If not found, return the default values.
if (found == mReturnData.end()) {
outClientTargetProperty->pixelFormat = PixelFormat::RGBA_8888;
outClientTargetProperty->dataspace = Dataspace::UNKNOWN;
return;
}
ReturnData& data = found->second;
*outClientTargetProperty = data.clientTargetProperty;
}
} // namespace Hwc2
} // namespace android
// TODO(b/129481165): remove the #pragma below and fix conversion issues
#pragma clang diagnostic pop // ignored "-Wconversion"