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review.blissroms.org / platform_hardware_interfaces / 163e9d68e6aec1d77b7a2477c7ebc652c1cab334 / . / graphics / composer / 2.1 / default / Hwc.cpp
blob: 36c6e54b9532c76b0ff6660c072305b99279d964 [file] [log] [blame]
/*
* 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.
*/
#define LOG_TAG "HwcPassthrough"
#include <mutex>
#include <type_traits>
#include <unordered_map>
#include <unordered_set>
#include <utility>
#include <vector>
#include <hardware/gralloc.h>
#include <hardware/gralloc1.h>
#include <hardware/hwcomposer2.h>
#include <log/log.h>
#include "Hwc.h"
namespace android {
namespace hardware {
namespace graphics {
namespace composer {
namespace V2_1 {
namespace implementation {
using android::hardware::graphics::common::V1_0::PixelFormat;
using android::hardware::graphics::common::V1_0::Transform;
using android::hardware::graphics::common::V1_0::Dataspace;
using android::hardware::graphics::common::V1_0::ColorMode;
using android::hardware::graphics::common::V1_0::ColorTransform;
using android::hardware::graphics::common::V1_0::Hdr;
namespace {
class HandleImporter {
public:
HandleImporter() : mInitialized(false) {}
bool initialize()
{
// allow only one client
if (mInitialized) {
return false;
}
if (!openGralloc()) {
return false;
}
mInitialized = true;
return true;
}
void cleanup()
{
if (!mInitialized) {
return;
}
closeGralloc();
mInitialized = false;
}
// In IComposer, any buffer_handle_t is owned by the caller and we need to
// make a clone for hwcomposer2. We also need to translate empty handle
// to nullptr. This function does that, in-place.
bool importBuffer(buffer_handle_t& handle)
{
if (!handle->numFds && !handle->numInts) {
handle = nullptr;
return true;
}
buffer_handle_t clone = cloneBuffer(handle);
if (!clone) {
return false;
}
handle = clone;
return true;
}
void freeBuffer(buffer_handle_t handle)
{
if (!handle) {
return;
}
releaseBuffer(handle);
}
bool importFence(const native_handle_t* handle, int& fd)
{
if (handle->numFds == 0) {
fd = -1;
} else if (handle->numFds == 1) {
fd = dup(handle->data[0]);
if (fd < 0) {
ALOGE("failed to dup fence fd %d", handle->data[0]);
return false;
}
} else {
ALOGE("invalid fence handle with %d file descriptors",
handle->numFds);
return false;
}
return true;
}
void closeFence(int fd)
{
if (fd >= 0) {
close(fd);
}
}
private:
bool mInitialized;
// Some existing gralloc drivers do not support retaining more than once,
// when we are in passthrough mode.
#ifdef BINDERIZED
bool openGralloc()
{
const hw_module_t* module;
int err = hw_get_module(GRALLOC_HARDWARE_MODULE_ID, &module);
if (err) {
ALOGE("failed to get gralloc module");
return false;
}
uint8_t major = (module->module_api_version >> 8) & 0xff;
if (major > 1) {
ALOGE("unknown gralloc module major version %d", major);
return false;
}
if (major == 1) {
err = gralloc1_open(module, &mDevice);
if (err) {
ALOGE("failed to open gralloc1 device");
return false;
}
mRetain = reinterpret_cast<GRALLOC1_PFN_RETAIN>(
mDevice->getFunction(mDevice, GRALLOC1_FUNCTION_RETAIN));
mRelease = reinterpret_cast<GRALLOC1_PFN_RELEASE>(
mDevice->getFunction(mDevice, GRALLOC1_FUNCTION_RELEASE));
if (!mRetain || !mRelease) {
ALOGE("invalid gralloc1 device");
gralloc1_close(mDevice);
return false;
}
} else {
mModule = reinterpret_cast<const gralloc_module_t*>(module);
}
return true;
}
void closeGralloc()
{
if (mDevice) {
gralloc1_close(mDevice);
}
}
buffer_handle_t cloneBuffer(buffer_handle_t handle)
{
native_handle_t* clone = native_handle_clone(handle);
if (!clone) {
ALOGE("failed to clone buffer %p", handle);
return nullptr;
}
bool err;
if (mDevice) {
err = (mRetain(mDevice, clone) != GRALLOC1_ERROR_NONE);
} else {
err = (mModule->registerBuffer(mModule, clone) != 0);
}
if (err) {
ALOGE("failed to retain/register buffer %p", clone);
native_handle_close(clone);
native_handle_delete(clone);
return nullptr;
}
return clone;
}
void releaseBuffer(buffer_handle_t handle)
{
if (mDevice) {
mRelease(mDevice, handle);
} else {
mModule->unregisterBuffer(mModule, handle);
native_handle_close(handle);
native_handle_delete(const_cast<native_handle_t*>(handle));
}
}
// gralloc1
gralloc1_device_t* mDevice;
GRALLOC1_PFN_RETAIN mRetain;
GRALLOC1_PFN_RELEASE mRelease;
// gralloc0
const gralloc_module_t* mModule;
#else
bool openGralloc() { return true; }
void closeGralloc() {}
buffer_handle_t cloneBuffer(buffer_handle_t handle) { return handle; }
void releaseBuffer(buffer_handle_t) {}
#endif
};
HandleImporter sHandleImporter;
class BufferClone {
public:
BufferClone() : mHandle(nullptr) {}
BufferClone(BufferClone&& other)
{
mHandle = other.mHandle;
other.mHandle = nullptr;
}
BufferClone(const BufferClone& other) = delete;
BufferClone& operator=(const BufferClone& other) = delete;
BufferClone& operator=(buffer_handle_t handle)
{
clear();
mHandle = handle;
return *this;
}
~BufferClone()
{
clear();
}
private:
void clear()
{
if (mHandle) {
sHandleImporter.freeBuffer(mHandle);
}
}
buffer_handle_t mHandle;
};
} // anonymous namespace
class HwcHal : public IComposer {
public:
HwcHal(const hw_module_t* module);
virtual ~HwcHal();
// IComposer interface
Return<void> getCapabilities(getCapabilities_cb hidl_cb) override;
Return<void> dumpDebugInfo(dumpDebugInfo_cb hidl_cb) override;
Return<void> registerCallback(const sp<IComposerCallback>& callback) override;
Return<uint32_t> getMaxVirtualDisplayCount() override;
Return<void> createVirtualDisplay(uint32_t width, uint32_t height,
PixelFormat formatHint, createVirtualDisplay_cb hidl_cb) override;
Return<Error> destroyVirtualDisplay(Display display) override;
Return<Error> acceptDisplayChanges(Display display) override;
Return<void> createLayer(Display display,
createLayer_cb hidl_cb) override;
Return<Error> destroyLayer(Display display, Layer layer) override;
Return<void> getActiveConfig(Display display,
getActiveConfig_cb hidl_cb) override;
Return<void> getChangedCompositionTypes(Display display,
getChangedCompositionTypes_cb hidl_cb) override;
Return<Error> getClientTargetSupport(Display display,
uint32_t width, uint32_t height,
PixelFormat format, Dataspace dataspace) override;
Return<void> getColorModes(Display display,
getColorModes_cb hidl_cb) override;
Return<void> getDisplayAttribute(Display display,
Config config, Attribute attribute,
getDisplayAttribute_cb hidl_cb) override;
Return<void> getDisplayConfigs(Display display,
getDisplayConfigs_cb hidl_cb) override;
Return<void> getDisplayName(Display display,
getDisplayName_cb hidl_cb) override;
Return<void> getDisplayRequests(Display display,
getDisplayRequests_cb hidl_cb) override;
Return<void> getDisplayType(Display display,
getDisplayType_cb hidl_cb) override;
Return<void> getDozeSupport(Display display,
getDozeSupport_cb hidl_cb) override;
Return<void> getHdrCapabilities(Display display,
getHdrCapabilities_cb hidl_cb) override;
Return<void> getReleaseFences(Display display,
getReleaseFences_cb hidl_cb) override;
Return<void> presentDisplay(Display display,
presentDisplay_cb hidl_cb) override;
Return<Error> setActiveConfig(Display display, Config config) override;
Return<Error> setClientTarget(Display display,
const hidl_handle& target,
const hidl_handle& acquireFence,
Dataspace dataspace, const hidl_vec<Rect>& damage) override;
Return<Error> setColorMode(Display display, ColorMode mode) override;
Return<Error> setColorTransform(Display display,
const hidl_vec<float>& matrix, ColorTransform hint) override;
Return<Error> setOutputBuffer(Display display,
const hidl_handle& buffer,
const hidl_handle& releaseFence) override;
Return<Error> setPowerMode(Display display, PowerMode mode) override;
Return<Error> setVsyncEnabled(Display display, Vsync enabled) override;
Return<void> validateDisplay(Display display,
validateDisplay_cb hidl_cb) override;
Return<Error> setCursorPosition(Display display,
Layer layer, int32_t x, int32_t y) override;
Return<Error> setLayerBuffer(Display display,
Layer layer, const hidl_handle& buffer,
const hidl_handle& acquireFence) override;
Return<Error> setLayerSurfaceDamage(Display display,
Layer layer, const hidl_vec<Rect>& damage) override;
Return<Error> setLayerBlendMode(Display display,
Layer layer, BlendMode mode) override;
Return<Error> setLayerColor(Display display,
Layer layer, const Color& color) override;
Return<Error> setLayerCompositionType(Display display,
Layer layer, Composition type) override;
Return<Error> setLayerDataspace(Display display,
Layer layer, Dataspace dataspace) override;
Return<Error> setLayerDisplayFrame(Display display,
Layer layer, const Rect& frame) override;
Return<Error> setLayerPlaneAlpha(Display display,
Layer layer, float alpha) override;
Return<Error> setLayerSidebandStream(Display display,
Layer layer, const hidl_handle& stream) override;
Return<Error> setLayerSourceCrop(Display display,
Layer layer, const FRect& crop) override;
Return<Error> setLayerTransform(Display display,
Layer layer, Transform transform) override;
Return<Error> setLayerVisibleRegion(Display display,
Layer layer, const hidl_vec<Rect>& visible) override;
Return<Error> setLayerZOrder(Display display,
Layer layer, uint32_t z) override;
private:
void initCapabilities();
template<typename T>
void initDispatch(T& func, hwc2_function_descriptor_t desc);
void initDispatch();
bool hasCapability(Capability capability) const;
static void hotplugHook(hwc2_callback_data_t callbackData,
hwc2_display_t display, int32_t connected);
static void refreshHook(hwc2_callback_data_t callbackData,
hwc2_display_t display);
static void vsyncHook(hwc2_callback_data_t callbackData,
hwc2_display_t display, int64_t timestamp);
hwc2_device_t* mDevice;
std::unordered_set<Capability> mCapabilities;
struct {
HWC2_PFN_ACCEPT_DISPLAY_CHANGES acceptDisplayChanges;
HWC2_PFN_CREATE_LAYER createLayer;
HWC2_PFN_CREATE_VIRTUAL_DISPLAY createVirtualDisplay;
HWC2_PFN_DESTROY_LAYER destroyLayer;
HWC2_PFN_DESTROY_VIRTUAL_DISPLAY destroyVirtualDisplay;
HWC2_PFN_DUMP dump;
HWC2_PFN_GET_ACTIVE_CONFIG getActiveConfig;
HWC2_PFN_GET_CHANGED_COMPOSITION_TYPES getChangedCompositionTypes;
HWC2_PFN_GET_CLIENT_TARGET_SUPPORT getClientTargetSupport;
HWC2_PFN_GET_COLOR_MODES getColorModes;
HWC2_PFN_GET_DISPLAY_ATTRIBUTE getDisplayAttribute;
HWC2_PFN_GET_DISPLAY_CONFIGS getDisplayConfigs;
HWC2_PFN_GET_DISPLAY_NAME getDisplayName;
HWC2_PFN_GET_DISPLAY_REQUESTS getDisplayRequests;
HWC2_PFN_GET_DISPLAY_TYPE getDisplayType;
HWC2_PFN_GET_DOZE_SUPPORT getDozeSupport;
HWC2_PFN_GET_HDR_CAPABILITIES getHdrCapabilities;
HWC2_PFN_GET_MAX_VIRTUAL_DISPLAY_COUNT getMaxVirtualDisplayCount;
HWC2_PFN_GET_RELEASE_FENCES getReleaseFences;
HWC2_PFN_PRESENT_DISPLAY presentDisplay;
HWC2_PFN_REGISTER_CALLBACK registerCallback;
HWC2_PFN_SET_ACTIVE_CONFIG setActiveConfig;
HWC2_PFN_SET_CLIENT_TARGET setClientTarget;
HWC2_PFN_SET_COLOR_MODE setColorMode;
HWC2_PFN_SET_COLOR_TRANSFORM setColorTransform;
HWC2_PFN_SET_CURSOR_POSITION setCursorPosition;
HWC2_PFN_SET_LAYER_BLEND_MODE setLayerBlendMode;
HWC2_PFN_SET_LAYER_BUFFER setLayerBuffer;
HWC2_PFN_SET_LAYER_COLOR setLayerColor;
HWC2_PFN_SET_LAYER_COMPOSITION_TYPE setLayerCompositionType;
HWC2_PFN_SET_LAYER_DATASPACE setLayerDataspace;
HWC2_PFN_SET_LAYER_DISPLAY_FRAME setLayerDisplayFrame;
HWC2_PFN_SET_LAYER_PLANE_ALPHA setLayerPlaneAlpha;
HWC2_PFN_SET_LAYER_SIDEBAND_STREAM setLayerSidebandStream;
HWC2_PFN_SET_LAYER_SOURCE_CROP setLayerSourceCrop;
HWC2_PFN_SET_LAYER_SURFACE_DAMAGE setLayerSurfaceDamage;
HWC2_PFN_SET_LAYER_TRANSFORM setLayerTransform;
HWC2_PFN_SET_LAYER_VISIBLE_REGION setLayerVisibleRegion;
HWC2_PFN_SET_LAYER_Z_ORDER setLayerZOrder;
HWC2_PFN_SET_OUTPUT_BUFFER setOutputBuffer;
HWC2_PFN_SET_POWER_MODE setPowerMode;
HWC2_PFN_SET_VSYNC_ENABLED setVsyncEnabled;
HWC2_PFN_VALIDATE_DISPLAY validateDisplay;
} mDispatch;
// cloned buffers for a display
struct DisplayBuffers {
BufferClone ClientTarget;
BufferClone OutputBuffer;
std::unordered_map<Layer, BufferClone> LayerBuffers;
std::unordered_map<Layer, BufferClone> LayerSidebandStreams;
};
std::mutex mCallbackMutex;
sp<IComposerCallback> mCallback;
std::mutex mDisplayMutex;
std::unordered_map<Display, DisplayBuffers> mDisplays;
};
HwcHal::HwcHal(const hw_module_t* module)
: mDevice(nullptr), mDispatch()
{
if (!sHandleImporter.initialize()) {
LOG_ALWAYS_FATAL("failed to initialize handle importer");
}
int status = hwc2_open(module, &mDevice);
if (status) {
LOG_ALWAYS_FATAL("failed to open hwcomposer2 device: %s",
strerror(-status));
}
initCapabilities();
initDispatch();
}
HwcHal::~HwcHal()
{
hwc2_close(mDevice);
mDisplays.clear();
sHandleImporter.cleanup();
}
void HwcHal::initCapabilities()
{
uint32_t count = 0;
mDevice->getCapabilities(mDevice, &count, nullptr);
std::vector<Capability> caps(count);
mDevice->getCapabilities(mDevice, &count, reinterpret_cast<
std::underlying_type<Capability>::type*>(caps.data()));
caps.resize(count);
mCapabilities.insert(caps.cbegin(), caps.cend());
}
template<typename T>
void HwcHal::initDispatch(T& func, hwc2_function_descriptor_t desc)
{
auto pfn = mDevice->getFunction(mDevice, desc);
if (!pfn) {
LOG_ALWAYS_FATAL("failed to get hwcomposer2 function %d", desc);
}
func = reinterpret_cast<T>(pfn);
}
void HwcHal::initDispatch()
{
initDispatch(mDispatch.acceptDisplayChanges,
HWC2_FUNCTION_ACCEPT_DISPLAY_CHANGES);
initDispatch(mDispatch.createLayer, HWC2_FUNCTION_CREATE_LAYER);
initDispatch(mDispatch.createVirtualDisplay,
HWC2_FUNCTION_CREATE_VIRTUAL_DISPLAY);
initDispatch(mDispatch.destroyLayer, HWC2_FUNCTION_DESTROY_LAYER);
initDispatch(mDispatch.destroyVirtualDisplay,
HWC2_FUNCTION_DESTROY_VIRTUAL_DISPLAY);
initDispatch(mDispatch.dump, HWC2_FUNCTION_DUMP);
initDispatch(mDispatch.getActiveConfig, HWC2_FUNCTION_GET_ACTIVE_CONFIG);
initDispatch(mDispatch.getChangedCompositionTypes,
HWC2_FUNCTION_GET_CHANGED_COMPOSITION_TYPES);
initDispatch(mDispatch.getClientTargetSupport,
HWC2_FUNCTION_GET_CLIENT_TARGET_SUPPORT);
initDispatch(mDispatch.getColorModes, HWC2_FUNCTION_GET_COLOR_MODES);
initDispatch(mDispatch.getDisplayAttribute,
HWC2_FUNCTION_GET_DISPLAY_ATTRIBUTE);
initDispatch(mDispatch.getDisplayConfigs,
HWC2_FUNCTION_GET_DISPLAY_CONFIGS);
initDispatch(mDispatch.getDisplayName, HWC2_FUNCTION_GET_DISPLAY_NAME);
initDispatch(mDispatch.getDisplayRequests,
HWC2_FUNCTION_GET_DISPLAY_REQUESTS);
initDispatch(mDispatch.getDisplayType, HWC2_FUNCTION_GET_DISPLAY_TYPE);
initDispatch(mDispatch.getDozeSupport, HWC2_FUNCTION_GET_DOZE_SUPPORT);
initDispatch(mDispatch.getHdrCapabilities,
HWC2_FUNCTION_GET_HDR_CAPABILITIES);
initDispatch(mDispatch.getMaxVirtualDisplayCount,
HWC2_FUNCTION_GET_MAX_VIRTUAL_DISPLAY_COUNT);
initDispatch(mDispatch.getReleaseFences,
HWC2_FUNCTION_GET_RELEASE_FENCES);
initDispatch(mDispatch.presentDisplay, HWC2_FUNCTION_PRESENT_DISPLAY);
initDispatch(mDispatch.registerCallback, HWC2_FUNCTION_REGISTER_CALLBACK);
initDispatch(mDispatch.setActiveConfig, HWC2_FUNCTION_SET_ACTIVE_CONFIG);
initDispatch(mDispatch.setClientTarget, HWC2_FUNCTION_SET_CLIENT_TARGET);
initDispatch(mDispatch.setColorMode, HWC2_FUNCTION_SET_COLOR_MODE);
initDispatch(mDispatch.setColorTransform,
HWC2_FUNCTION_SET_COLOR_TRANSFORM);
initDispatch(mDispatch.setCursorPosition,
HWC2_FUNCTION_SET_CURSOR_POSITION);
initDispatch(mDispatch.setLayerBlendMode,
HWC2_FUNCTION_SET_LAYER_BLEND_MODE);
initDispatch(mDispatch.setLayerBuffer, HWC2_FUNCTION_SET_LAYER_BUFFER);
initDispatch(mDispatch.setLayerColor, HWC2_FUNCTION_SET_LAYER_COLOR);
initDispatch(mDispatch.setLayerCompositionType,
HWC2_FUNCTION_SET_LAYER_COMPOSITION_TYPE);
initDispatch(mDispatch.setLayerDataspace,
HWC2_FUNCTION_SET_LAYER_DATASPACE);
initDispatch(mDispatch.setLayerDisplayFrame,
HWC2_FUNCTION_SET_LAYER_DISPLAY_FRAME);
initDispatch(mDispatch.setLayerPlaneAlpha,
HWC2_FUNCTION_SET_LAYER_PLANE_ALPHA);
if (hasCapability(Capability::SIDEBAND_STREAM)) {
initDispatch(mDispatch.setLayerSidebandStream,
HWC2_FUNCTION_SET_LAYER_SIDEBAND_STREAM);
}
initDispatch(mDispatch.setLayerSourceCrop,
HWC2_FUNCTION_SET_LAYER_SOURCE_CROP);
initDispatch(mDispatch.setLayerSurfaceDamage,
HWC2_FUNCTION_SET_LAYER_SURFACE_DAMAGE);
initDispatch(mDispatch.setLayerTransform,
HWC2_FUNCTION_SET_LAYER_TRANSFORM);
initDispatch(mDispatch.setLayerVisibleRegion,
HWC2_FUNCTION_SET_LAYER_VISIBLE_REGION);
initDispatch(mDispatch.setLayerZOrder, HWC2_FUNCTION_SET_LAYER_Z_ORDER);
initDispatch(mDispatch.setOutputBuffer, HWC2_FUNCTION_SET_OUTPUT_BUFFER);
initDispatch(mDispatch.setPowerMode, HWC2_FUNCTION_SET_POWER_MODE);
initDispatch(mDispatch.setVsyncEnabled, HWC2_FUNCTION_SET_VSYNC_ENABLED);
initDispatch(mDispatch.validateDisplay, HWC2_FUNCTION_VALIDATE_DISPLAY);
}
bool HwcHal::hasCapability(Capability capability) const
{
return (mCapabilities.count(capability) > 0);
}
Return<void> HwcHal::getCapabilities(getCapabilities_cb hidl_cb)
{
std::vector<Capability> caps(
mCapabilities.cbegin(), mCapabilities.cend());
hidl_vec<Capability> caps_reply;
caps_reply.setToExternal(caps.data(), caps.size());
hidl_cb(caps_reply);
return Void();
}
Return<void> HwcHal::dumpDebugInfo(dumpDebugInfo_cb hidl_cb)
{
uint32_t len;
mDispatch.dump(mDevice, &len, nullptr);
std::vector<char> buf(len + 1);
mDispatch.dump(mDevice, &len, buf.data());
buf.resize(len + 1);
buf[len] = '\0';
hidl_string buf_reply;
buf_reply.setToExternal(buf.data(), len);
hidl_cb(buf_reply);
return Void();
}
void HwcHal::hotplugHook(hwc2_callback_data_t callbackData,
hwc2_display_t display, int32_t connected)
{
auto hal = reinterpret_cast<HwcHal*>(callbackData);
{
std::lock_guard<std::mutex> lock(hal->mDisplayMutex);
if (connected == HWC2_CONNECTION_CONNECTED) {
hal->mDisplays.emplace(display, DisplayBuffers());
} else if (connected == HWC2_CONNECTION_DISCONNECTED) {
hal->mDisplays.erase(display);
}
}
hal->mCallback->onHotplug(display,
static_cast<IComposerCallback::Connection>(connected));
}
void HwcHal::refreshHook(hwc2_callback_data_t callbackData,
hwc2_display_t display)
{
auto hal = reinterpret_cast<HwcHal*>(callbackData);
hal->mCallback->onRefresh(display);
}
void HwcHal::vsyncHook(hwc2_callback_data_t callbackData,
hwc2_display_t display, int64_t timestamp)
{
auto hal = reinterpret_cast<HwcHal*>(callbackData);
hal->mCallback->onVsync(display, timestamp);
}
Return<void> HwcHal::registerCallback(const sp<IComposerCallback>& callback)
{
std::lock_guard<std::mutex> lock(mCallbackMutex);
mCallback = callback;
mDispatch.registerCallback(mDevice, HWC2_CALLBACK_HOTPLUG, this,
reinterpret_cast<hwc2_function_pointer_t>(hotplugHook));
mDispatch.registerCallback(mDevice, HWC2_CALLBACK_REFRESH, this,
reinterpret_cast<hwc2_function_pointer_t>(refreshHook));
mDispatch.registerCallback(mDevice, HWC2_CALLBACK_VSYNC, this,
reinterpret_cast<hwc2_function_pointer_t>(vsyncHook));
return Void();
}
Return<uint32_t> HwcHal::getMaxVirtualDisplayCount()
{
return mDispatch.getMaxVirtualDisplayCount(mDevice);
}
Return<void> HwcHal::createVirtualDisplay(uint32_t width, uint32_t height,
PixelFormat formatHint, createVirtualDisplay_cb hidl_cb)
{
int32_t format = static_cast<int32_t>(formatHint);
hwc2_display_t display;
auto error = mDispatch.createVirtualDisplay(mDevice, width, height,
&format, &display);
if (error == HWC2_ERROR_NONE) {
std::lock_guard<std::mutex> lock(mDisplayMutex);
mDisplays.emplace(display, DisplayBuffers());
}
hidl_cb(static_cast<Error>(error), display,
static_cast<PixelFormat>(format));
return Void();
}
Return<Error> HwcHal::destroyVirtualDisplay(Display display)
{
auto error = mDispatch.destroyVirtualDisplay(mDevice, display);
if (error == HWC2_ERROR_NONE) {
std::lock_guard<std::mutex> lock(mDisplayMutex);
mDisplays.erase(display);
}
return static_cast<Error>(error);
}
Return<Error> HwcHal::acceptDisplayChanges(Display display)
{
auto error = mDispatch.acceptDisplayChanges(mDevice, display);
return static_cast<Error>(error);
}
Return<void> HwcHal::createLayer(Display display, createLayer_cb hidl_cb)
{
hwc2_layer_t layer;
auto error = mDispatch.createLayer(mDevice, display, &layer);
hidl_cb(static_cast<Error>(error), layer);
return Void();
}
Return<Error> HwcHal::destroyLayer(Display display, Layer layer)
{
auto error = mDispatch.destroyLayer(mDevice, display, layer);
if (error == HWC2_ERROR_NONE) {
std::lock_guard<std::mutex> lock(mDisplayMutex);
auto dpy = mDisplays.find(display);
dpy->second.LayerBuffers.erase(layer);
dpy->second.LayerSidebandStreams.erase(layer);
}
return static_cast<Error>(error);
}
Return<void> HwcHal::getActiveConfig(Display display,
getActiveConfig_cb hidl_cb)
{
hwc2_config_t config;
auto error = mDispatch.getActiveConfig(mDevice, display, &config);
hidl_cb(static_cast<Error>(error), config);
return Void();
}
Return<void> HwcHal::getChangedCompositionTypes(Display display,
getChangedCompositionTypes_cb hidl_cb)
{
uint32_t count = 0;
auto error = mDispatch.getChangedCompositionTypes(mDevice, display,
&count, nullptr, nullptr);
if (error != HWC2_ERROR_NONE) {
count = 0;
}
std::vector<hwc2_layer_t> layers(count);
std::vector<Composition> types(count);
error = mDispatch.getChangedCompositionTypes(mDevice, display,
&count, layers.data(),
reinterpret_cast<std::underlying_type<Composition>::type*>(
types.data()));
if (error != HWC2_ERROR_NONE) {
count = 0;
}
layers.resize(count);
types.resize(count);
hidl_vec<Layer> layers_reply;
layers_reply.setToExternal(layers.data(), layers.size());
hidl_vec<Composition> types_reply;
types_reply.setToExternal(types.data(), types.size());
hidl_cb(static_cast<Error>(error), layers_reply, types_reply);
return Void();
}
Return<Error> HwcHal::getClientTargetSupport(Display display,
uint32_t width, uint32_t height,
PixelFormat format, Dataspace dataspace)
{
auto error = mDispatch.getClientTargetSupport(mDevice, display,
width, height, static_cast<int32_t>(format),
static_cast<int32_t>(dataspace));
return static_cast<Error>(error);
}
Return<void> HwcHal::getColorModes(Display display, getColorModes_cb hidl_cb)
{
uint32_t count = 0;
auto error = mDispatch.getColorModes(mDevice, display, &count, nullptr);
if (error != HWC2_ERROR_NONE) {
count = 0;
}
std::vector<ColorMode> modes(count);
error = mDispatch.getColorModes(mDevice, display, &count,
reinterpret_cast<std::underlying_type<ColorMode>::type*>(
modes.data()));
if (error != HWC2_ERROR_NONE) {
count = 0;
}
modes.resize(count);
hidl_vec<ColorMode> modes_reply;
modes_reply.setToExternal(modes.data(), modes.size());
hidl_cb(static_cast<Error>(error), modes_reply);
return Void();
}
Return<void> HwcHal::getDisplayAttribute(Display display,
Config config, Attribute attribute,
getDisplayAttribute_cb hidl_cb)
{
int32_t value;
auto error = mDispatch.getDisplayAttribute(mDevice, display, config,
static_cast<int32_t>(attribute), &value);
hidl_cb(static_cast<Error>(error), value);
return Void();
}
Return<void> HwcHal::getDisplayConfigs(Display display,
getDisplayConfigs_cb hidl_cb)
{
uint32_t count = 0;
auto error = mDispatch.getDisplayConfigs(mDevice, display,
&count, nullptr);
if (error != HWC2_ERROR_NONE) {
count = 0;
}
std::vector<hwc2_config_t> configs(count);
error = mDispatch.getDisplayConfigs(mDevice, display,
&count, configs.data());
if (error != HWC2_ERROR_NONE) {
count = 0;
}
configs.resize(count);
hidl_vec<Config> configs_reply;
configs_reply.setToExternal(configs.data(), configs.size());
hidl_cb(static_cast<Error>(error), configs_reply);
return Void();
}
Return<void> HwcHal::getDisplayName(Display display,
getDisplayName_cb hidl_cb)
{
uint32_t count = 0;
auto error = mDispatch.getDisplayName(mDevice, display, &count, nullptr);
if (error != HWC2_ERROR_NONE) {
count = 0;
}
std::vector<char> name(count + 1);
error = mDispatch.getDisplayName(mDevice, display, &count, name.data());
if (error != HWC2_ERROR_NONE) {
count = 0;
}
name.resize(count + 1);
name[count] = '\0';
hidl_string name_reply;
name_reply.setToExternal(name.data(), count);
hidl_cb(static_cast<Error>(error), name_reply);
return Void();
}
Return<void> HwcHal::getDisplayRequests(Display display,
getDisplayRequests_cb hidl_cb)
{
int32_t display_reqs;
uint32_t count = 0;
auto error = mDispatch.getDisplayRequests(mDevice, display,
&display_reqs, &count, nullptr, nullptr);
if (error != HWC2_ERROR_NONE) {
count = 0;
}
std::vector<hwc2_layer_t> layers(count);
std::vector<int32_t> layer_reqs(count);
error = mDispatch.getDisplayRequests(mDevice, display,
&display_reqs, &count, layers.data(), layer_reqs.data());
if (error != HWC2_ERROR_NONE) {
count = 0;
}
layers.resize(count);
layer_reqs.resize(count);
hidl_vec<Layer> layers_reply;
layers_reply.setToExternal(layers.data(), layers.size());
hidl_vec<uint32_t> layer_reqs_reply;
layer_reqs_reply.setToExternal(
reinterpret_cast<uint32_t*>(layer_reqs.data()),
layer_reqs.size());
hidl_cb(static_cast<Error>(error), display_reqs,
layers_reply, layer_reqs_reply);
return Void();
}
Return<void> HwcHal::getDisplayType(Display display,
getDisplayType_cb hidl_cb)
{
int32_t type;
auto error = mDispatch.getDisplayType(mDevice, display, &type);
hidl_cb(static_cast<Error>(error), static_cast<DisplayType>(type));
return Void();
}
Return<void> HwcHal::getDozeSupport(Display display,
getDozeSupport_cb hidl_cb)
{
int32_t support;
auto error = mDispatch.getDozeSupport(mDevice, display, &support);
hidl_cb(static_cast<Error>(error), support);
return Void();
}
Return<void> HwcHal::getHdrCapabilities(Display display,
getHdrCapabilities_cb hidl_cb)
{
float max_lumi, max_avg_lumi, min_lumi;
uint32_t count = 0;
auto error = mDispatch.getHdrCapabilities(mDevice, display,
&count, nullptr, &max_lumi, &max_avg_lumi, &min_lumi);
if (error != HWC2_ERROR_NONE) {
count = 0;
}
std::vector<Hdr> types(count);
error = mDispatch.getHdrCapabilities(mDevice, display, &count,
reinterpret_cast<std::underlying_type<Hdr>::type*>(types.data()),
&max_lumi, &max_avg_lumi, &min_lumi);
if (error != HWC2_ERROR_NONE) {
count = 0;
}
types.resize(count);
hidl_vec<Hdr> types_reply;
types_reply.setToExternal(types.data(), types.size());
hidl_cb(static_cast<Error>(error), types_reply,
max_lumi, max_avg_lumi, min_lumi);
return Void();
}
Return<void> HwcHal::getReleaseFences(Display display,
getReleaseFences_cb hidl_cb)
{
uint32_t count = 0;
auto error = mDispatch.getReleaseFences(mDevice, display,
&count, nullptr, nullptr);
if (error != HWC2_ERROR_NONE) {
count = 0;
}
std::vector<hwc2_layer_t> layers(count);
std::vector<int32_t> fences(count);
error = mDispatch.getReleaseFences(mDevice, display,
&count, layers.data(), fences.data());
if (error != HWC2_ERROR_NONE) {
count = 0;
}
layers.resize(count);
fences.resize(count);
// filter out layers with release fence -1
std::vector<hwc2_layer_t> filtered_layers;
std::vector<int> filtered_fences;
for (size_t i = 0; i < layers.size(); i++) {
if (fences[i] >= 0) {
filtered_layers.push_back(layers[i]);
filtered_fences.push_back(fences[i]);
}
}
hidl_vec<Layer> layers_reply;
native_handle_t* fences_reply =
native_handle_create(filtered_fences.size(), 0);
if (fences_reply) {
layers_reply.setToExternal(filtered_layers.data(),
filtered_layers.size());
memcpy(fences_reply->data, filtered_fences.data(),
sizeof(int) * filtered_fences.size());
hidl_cb(static_cast<Error>(error), layers_reply, fences_reply);
native_handle_close(fences_reply);
native_handle_delete(fences_reply);
} else {
NATIVE_HANDLE_DECLARE_STORAGE(fences_storage, 0, 0);
fences_reply = native_handle_init(fences_storage, 0, 0);
hidl_cb(Error::NO_RESOURCES, layers_reply, fences_reply);
for (auto fence : filtered_fences) {
close(fence);
}
}
return Void();
}
Return<void> HwcHal::presentDisplay(Display display,
presentDisplay_cb hidl_cb)
{
int32_t fence = -1;
auto error = mDispatch.presentDisplay(mDevice, display, &fence);
NATIVE_HANDLE_DECLARE_STORAGE(fence_storage, 1, 0);
native_handle_t* fence_reply;
if (fence >= 0) {
fence_reply = native_handle_init(fence_storage, 1, 0);
fence_reply->data[0] = fence;
} else {
fence_reply = native_handle_init(fence_storage, 0, 0);
}
hidl_cb(static_cast<Error>(error), fence_reply);
if (fence >= 0) {
close(fence);
}
return Void();
}
Return<Error> HwcHal::setActiveConfig(Display display, Config config)
{
auto error = mDispatch.setActiveConfig(mDevice, display, config);
return static_cast<Error>(error);
}
Return<Error> HwcHal::setClientTarget(Display display,
const hidl_handle& target,
const hidl_handle& acquireFence,
Dataspace dataspace, const hidl_vec<Rect>& damage)
{
const native_handle_t* targetHandle = target.getNativeHandle();
if (!sHandleImporter.importBuffer(targetHandle)) {
return Error::NO_RESOURCES;
}
int32_t fence;
if (!sHandleImporter.importFence(acquireFence, fence)) {
sHandleImporter.freeBuffer(targetHandle);
return Error::NO_RESOURCES;
}
hwc_region_t damage_region = { damage.size(),
reinterpret_cast<const hwc_rect_t*>(&damage[0]) };
int32_t error = mDispatch.setClientTarget(mDevice, display,
targetHandle, fence, static_cast<int32_t>(dataspace),
damage_region);
if (error == HWC2_ERROR_NONE) {
std::lock_guard<std::mutex> lock(mDisplayMutex);
auto dpy = mDisplays.find(display);
dpy->second.ClientTarget = targetHandle;
} else {
sHandleImporter.freeBuffer(target);
sHandleImporter.closeFence(fence);
}
return static_cast<Error>(error);
}
Return<Error> HwcHal::setColorMode(Display display, ColorMode mode)
{
auto error = mDispatch.setColorMode(mDevice, display,
static_cast<int32_t>(mode));
return static_cast<Error>(error);
}
Return<Error> HwcHal::setColorTransform(Display display,
const hidl_vec<float>& matrix, ColorTransform hint)
{
auto error = mDispatch.setColorTransform(mDevice, display,
&matrix[0], static_cast<int32_t>(hint));
return static_cast<Error>(error);
}
Return<Error> HwcHal::setOutputBuffer(Display display,
const hidl_handle& buffer,
const hidl_handle& releaseFence)
{
const native_handle_t* bufferHandle = buffer.getNativeHandle();
if (!sHandleImporter.importBuffer(bufferHandle)) {
return Error::NO_RESOURCES;
}
int32_t fence;
if (!sHandleImporter.importFence(releaseFence, fence)) {
sHandleImporter.freeBuffer(bufferHandle);
return Error::NO_RESOURCES;
}
int32_t error = mDispatch.setOutputBuffer(mDevice,
display, bufferHandle, fence);
if (error == HWC2_ERROR_NONE) {
std::lock_guard<std::mutex> lock(mDisplayMutex);
auto dpy = mDisplays.find(display);
dpy->second.OutputBuffer = bufferHandle;
} else {
sHandleImporter.freeBuffer(bufferHandle);
}
// unlike in setClientTarget, fence is owned by us and is always closed
sHandleImporter.closeFence(fence);
return static_cast<Error>(error);
}
Return<Error> HwcHal::setPowerMode(Display display, PowerMode mode)
{
auto error = mDispatch.setPowerMode(mDevice, display,
static_cast<int32_t>(mode));
return static_cast<Error>(error);
}
Return<Error> HwcHal::setVsyncEnabled(Display display,
Vsync enabled)
{
auto error = mDispatch.setVsyncEnabled(mDevice, display,
static_cast<int32_t>(enabled));
return static_cast<Error>(error);
}
Return<void> HwcHal::validateDisplay(Display display,
validateDisplay_cb hidl_cb)
{
uint32_t types_count = 0;
uint32_t reqs_count = 0;
auto error = mDispatch.validateDisplay(mDevice, display,
&types_count, &reqs_count);
hidl_cb(static_cast<Error>(error), types_count, reqs_count);
return Void();
}
Return<Error> HwcHal::setCursorPosition(Display display,
Layer layer, int32_t x, int32_t y)
{
auto error = mDispatch.setCursorPosition(mDevice, display, layer, x, y);
return static_cast<Error>(error);
}
Return<Error> HwcHal::setLayerBuffer(Display display,
Layer layer, const hidl_handle& buffer,
const hidl_handle& acquireFence)
{
const native_handle_t* bufferHandle = buffer.getNativeHandle();
if (!sHandleImporter.importBuffer(bufferHandle)) {
return Error::NO_RESOURCES;
}
int32_t fence;
if (!sHandleImporter.importFence(acquireFence, fence)) {
sHandleImporter.freeBuffer(bufferHandle);
return Error::NO_RESOURCES;
}
int32_t error = mDispatch.setLayerBuffer(mDevice,
display, layer, bufferHandle, fence);
if (error == HWC2_ERROR_NONE) {
std::lock_guard<std::mutex> lock(mDisplayMutex);
auto dpy = mDisplays.find(display);
dpy->second.LayerBuffers[layer] = bufferHandle;
} else {
sHandleImporter.freeBuffer(bufferHandle);
sHandleImporter.closeFence(fence);
}
return static_cast<Error>(error);
}
Return<Error> HwcHal::setLayerSurfaceDamage(Display display,
Layer layer, const hidl_vec<Rect>& damage)
{
hwc_region_t damage_region = { damage.size(),
reinterpret_cast<const hwc_rect_t*>(&damage[0]) };
auto error = mDispatch.setLayerSurfaceDamage(mDevice, display, layer,
damage_region);
return static_cast<Error>(error);
}
Return<Error> HwcHal::setLayerBlendMode(Display display,
Layer layer, BlendMode mode)
{
auto error = mDispatch.setLayerBlendMode(mDevice, display, layer,
static_cast<int32_t>(mode));
return static_cast<Error>(error);
}
Return<Error> HwcHal::setLayerColor(Display display,
Layer layer, const Color& color)
{
hwc_color_t hwc_color{color.r, color.g, color.b, color.a};
auto error = mDispatch.setLayerColor(mDevice, display, layer, hwc_color);
return static_cast<Error>(error);
}
Return<Error> HwcHal::setLayerCompositionType(Display display,
Layer layer, Composition type)
{
auto error = mDispatch.setLayerCompositionType(mDevice, display, layer,
static_cast<int32_t>(type));
return static_cast<Error>(error);
}
Return<Error> HwcHal::setLayerDataspace(Display display,
Layer layer, Dataspace dataspace)
{
auto error = mDispatch.setLayerDataspace(mDevice, display, layer,
static_cast<int32_t>(dataspace));
return static_cast<Error>(error);
}
Return<Error> HwcHal::setLayerDisplayFrame(Display display,
Layer layer, const Rect& frame)
{
hwc_rect_t hwc_frame{frame.left, frame.top, frame.right, frame.bottom};
auto error = mDispatch.setLayerDisplayFrame(mDevice, display, layer,
hwc_frame);
return static_cast<Error>(error);
}
Return<Error> HwcHal::setLayerPlaneAlpha(Display display,
Layer layer, float alpha)
{
auto error = mDispatch.setLayerPlaneAlpha(mDevice, display, layer, alpha);
return static_cast<Error>(error);
}
Return<Error> HwcHal::setLayerSidebandStream(Display display,
Layer layer, const hidl_handle& stream)
{
const native_handle_t* streamHandle = stream.getNativeHandle();
if (!sHandleImporter.importBuffer(streamHandle)) {
return Error::NO_RESOURCES;
}
int32_t error = mDispatch.setLayerSidebandStream(mDevice,
display, layer, streamHandle);
if (error == HWC2_ERROR_NONE) {
std::lock_guard<std::mutex> lock(mDisplayMutex);
auto dpy = mDisplays.find(display);
dpy->second.LayerSidebandStreams[layer] = streamHandle;
} else {
sHandleImporter.freeBuffer(streamHandle);
}
return static_cast<Error>(error);
}
Return<Error> HwcHal::setLayerSourceCrop(Display display,
Layer layer, const FRect& crop)
{
hwc_frect_t hwc_crop{crop.left, crop.top, crop.right, crop.bottom};
auto error = mDispatch.setLayerSourceCrop(mDevice, display, layer,
hwc_crop);
return static_cast<Error>(error);
}
Return<Error> HwcHal::setLayerTransform(Display display,
Layer layer, Transform transform)
{
auto error = mDispatch.setLayerTransform(mDevice, display, layer,
static_cast<int32_t>(transform));
return static_cast<Error>(error);
}
Return<Error> HwcHal::setLayerVisibleRegion(Display display,
Layer layer, const hidl_vec<Rect>& visible)
{
hwc_region_t visible_region = { visible.size(),
reinterpret_cast<const hwc_rect_t*>(&visible[0]) };
auto error = mDispatch.setLayerVisibleRegion(mDevice, display, layer,
visible_region);
return static_cast<Error>(error);
}
Return<Error> HwcHal::setLayerZOrder(Display display,
Layer layer, uint32_t z)
{
auto error = mDispatch.setLayerZOrder(mDevice, display, layer, z);
return static_cast<Error>(error);
}
IComposer* HIDL_FETCH_IComposer(const char*)
{
const hw_module_t* module;
int err = hw_get_module(HWC_HARDWARE_MODULE_ID, &module);
if (err) {
ALOGE("failed to get hwcomposer module");
return nullptr;
}
return new HwcHal(module);
}
} // namespace implementation
} // namespace V2_1
} // namespace composer
} // namespace graphics
} // namespace hardware
} // namespace android