services/surfaceflinger/DisplayDevice.h - third_party/android/platform/frameworks/native - Git at Google

 /*
  * Copyright (C) 2007 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.
  */

 #ifndef ANDROID_DISPLAY_DEVICE_H
 #define ANDROID_DISPLAY_DEVICE_H

 #include "Transform.h"

 #include <stdlib.h>
 #include <unordered_map>

 #include <math/mat4.h>

 #include <binder/IBinder.h>
 #include <gui/ISurfaceComposer.h>
 #include <hardware/hwcomposer_defs.h>
 #include <ui/GraphicTypes.h>
 #include <ui/HdrCapabilities.h>
 #include <ui/Region.h>
 #include <utils/RefBase.h>
 #include <utils/Mutex.h>
 #include <utils/String8.h>
 #include <utils/Timers.h>

 #include "RenderArea.h"
 #include "RenderEngine/Surface.h"

 #include <memory>

 struct ANativeWindow;

 namespace android {

 struct DisplayInfo;
 class DisplaySurface;
 class Fence;
 class IGraphicBufferProducer;
 class Layer;
 class SurfaceFlinger;
 class HWComposer;

 class DisplayDevice : public LightRefBase<DisplayDevice>
 {
 public:
     constexpr static float sDefaultMinLumiance = 0.0;
     constexpr static float sDefaultMaxLumiance = 500.0;

     // region in layer-stack space
     mutable Region dirtyRegion;
     // region in screen space
     Region undefinedRegion;
     bool lastCompositionHadVisibleLayers;

     enum DisplayType {
         DISPLAY_ID_INVALID = -1,
         DISPLAY_PRIMARY     = HWC_DISPLAY_PRIMARY,
         DISPLAY_EXTERNAL    = HWC_DISPLAY_EXTERNAL,
         DISPLAY_VIRTUAL     = HWC_DISPLAY_VIRTUAL,
         NUM_BUILTIN_DISPLAY_TYPES = HWC_NUM_PHYSICAL_DISPLAY_TYPES,
     };

     enum {
         NO_LAYER_STACK = 0xFFFFFFFF,
     };

     // clang-format off
     DisplayDevice(
             const sp<SurfaceFlinger>& flinger,
             DisplayType type,
             int32_t hwcId,
             bool isSecure,
             const wp<IBinder>& displayToken,
             const sp<ANativeWindow>& nativeWindow,
             const sp<DisplaySurface>& displaySurface,
             std::unique_ptr<RE::Surface> renderSurface,
             int displayWidth,
             int displayHeight,
             bool hasWideColorGamut,
             const HdrCapabilities& hdrCapabilities,
             const int32_t supportedPerFrameMetadata,
             const std::unordered_map<ui::ColorMode, std::vector<ui::RenderIntent>>& hwcColorModes,
             int initialPowerMode);
     // clang-format on

     ~DisplayDevice();

     // whether this is a valid object. An invalid DisplayDevice is returned
     // when an non existing id is requested
     bool isValid() const;

     // isSecure indicates whether this display can be trusted to display
     // secure surfaces.
     bool isSecure() const { return mIsSecure; }

     // Flip the front and back buffers if the back buffer is "dirty".  Might
     // be instantaneous, might involve copying the frame buffer around.
     void flip() const;

     int         getWidth() const;
     int         getHeight() const;

     void                    setVisibleLayersSortedByZ(const Vector< sp<Layer> >& layers);
     const Vector< sp<Layer> >& getVisibleLayersSortedByZ() const;
     void                    setLayersNeedingFences(const Vector< sp<Layer> >& layers);
     const Vector< sp<Layer> >& getLayersNeedingFences() const;
     Region                  getDirtyRegion(bool repaintEverything) const;

     void                    setLayerStack(uint32_t stack);
     void                    setDisplaySize(const int newWidth, const int newHeight);
     void                    setProjection(int orientation, const Rect& viewport, const Rect& frame);

     int                     getOrientation() const { return mOrientation; }
     uint32_t                getOrientationTransform() const;
     static uint32_t         getPrimaryDisplayOrientationTransform();
     const Transform&        getTransform() const { return mGlobalTransform; }
     const Rect              getViewport() const { return mViewport; }
     const Rect              getFrame() const { return mFrame; }
     const Rect&             getScissor() const { return mScissor; }
     bool                    needsFiltering() const { return mNeedsFiltering; }

     uint32_t                getLayerStack() const { return mLayerStack; }
     int32_t                 getDisplayType() const { return mType; }
     bool                    isPrimary() const { return mType == DISPLAY_PRIMARY; }
     int32_t                 getHwcDisplayId() const { return mHwcDisplayId; }
     const wp<IBinder>&      getDisplayToken() const { return mDisplayToken; }

     int32_t getSupportedPerFrameMetadata() const { return mSupportedPerFrameMetadata; }

     // We pass in mustRecompose so we can keep VirtualDisplaySurface's state
     // machine happy without actually queueing a buffer if nothing has changed
     status_t beginFrame(bool mustRecompose) const;
     status_t prepareFrame(HWComposer& hwc);

     bool hasWideColorGamut() const { return mHasWideColorGamut; }
     // Whether h/w composer has native support for specific HDR type.
     bool hasHDR10Support() const { return mHasHdr10; }
     bool hasHLGSupport() const { return mHasHLG; }
     bool hasDolbyVisionSupport() const { return mHasDolbyVision; }

     // Return true if the HDR dataspace is supported but
     // there is no corresponding color mode.
     bool hasLegacyHdrSupport(ui::Dataspace dataspace) const;

     // The returned HdrCapabilities is the combination of HDR capabilities from
     // hardware composer and RenderEngine. When the DisplayDevice supports wide
     // color gamut, RenderEngine is able to simulate HDR support in Display P3
     // color space for both PQ and HLG HDR contents. The minimum and maximum
     // luminance will be set to sDefaultMinLumiance and sDefaultMaxLumiance
     // respectively if hardware composer doesn't return meaningful values.
     const HdrCapabilities& getHdrCapabilities() const { return mHdrCapabilities; }

     // Return true if intent is supported by the display.
     bool hasRenderIntent(ui::RenderIntent intent) const;

     void getBestColorMode(ui::Dataspace dataspace, ui::RenderIntent intent,
                           ui::Dataspace* outDataspace, ui::ColorMode* outMode,
                           ui::RenderIntent* outIntent) const;

     void swapBuffers(HWComposer& hwc) const;

     // called after h/w composer has completed its set() call
     void onSwapBuffersCompleted() const;

     Rect getBounds() const {
         return Rect(mDisplayWidth, mDisplayHeight);
     }
     inline Rect bounds() const { return getBounds(); }

     void setDisplayName(const String8& displayName);
     const String8& getDisplayName() const { return mDisplayName; }

     bool makeCurrent() const;
     void setViewportAndProjection() const;

     const sp<Fence>& getClientTargetAcquireFence() const;

     /* ------------------------------------------------------------------------
      * Display power mode management.
      */
     int getPowerMode() const;
     void setPowerMode(int mode);
     bool isDisplayOn() const;

     ui::ColorMode getActiveColorMode() const;
     void setActiveColorMode(ui::ColorMode mode);
     ui::RenderIntent getActiveRenderIntent() const;
     void setActiveRenderIntent(ui::RenderIntent renderIntent);
     android_color_transform_t getColorTransform() const;
     void setColorTransform(const mat4& transform);
     void setCompositionDataSpace(ui::Dataspace dataspace);
     ui::Dataspace getCompositionDataSpace() const;

     /* ------------------------------------------------------------------------
      * Display active config management.
      */
     int getActiveConfig() const;
     void setActiveConfig(int mode);

     // release HWC resources (if any) for removable displays
     void disconnect(HWComposer& hwc);

     /* ------------------------------------------------------------------------
      * Debugging
      */
     uint32_t getPageFlipCount() const;
     void dump(String8& result) const;

 private:
     /*
      *  Constants, set during initialization
      */
     sp<SurfaceFlinger> mFlinger;
     DisplayType mType;
     int32_t mHwcDisplayId;
     wp<IBinder> mDisplayToken;

     // ANativeWindow this display is rendering into
     sp<ANativeWindow> mNativeWindow;
     sp<DisplaySurface> mDisplaySurface;

     std::unique_ptr<RE::Surface> mSurface;
     int             mDisplayWidth;
     int             mDisplayHeight;
     mutable uint32_t mPageFlipCount;
     String8         mDisplayName;
     bool            mIsSecure;

     /*
      * Can only accessed from the main thread, these members
      * don't need synchronization.
      */

     // list of visible layers on that display
     Vector< sp<Layer> > mVisibleLayersSortedByZ;
     // list of layers needing fences
     Vector< sp<Layer> > mLayersNeedingFences;

     /*
      * Transaction state
      */
     static status_t orientationToTransfrom(int orientation,
             int w, int h, Transform* tr);

     // The identifier of the active layer stack for this display. Several displays
     // can use the same layer stack: A z-ordered group of layers (sometimes called
     // "surfaces"). Any given layer can only be on a single layer stack.
     uint32_t mLayerStack;

     int mOrientation;
     static uint32_t sPrimaryDisplayOrientation;
     // user-provided visible area of the layer stack
     Rect mViewport;
     // user-provided rectangle where mViewport gets mapped to
     Rect mFrame;
     // pre-computed scissor to apply to the display
     Rect mScissor;
     Transform mGlobalTransform;
     bool mNeedsFiltering;
     // Current power mode
     int mPowerMode;
     // Current active config
     int mActiveConfig;
     // current active color mode
     ui::ColorMode mActiveColorMode = ui::ColorMode::NATIVE;
     // Current active render intent.
     ui::RenderIntent mActiveRenderIntent = ui::RenderIntent::COLORIMETRIC;
     ui::Dataspace mCompositionDataSpace = ui::Dataspace::UNKNOWN;
     // Current color transform
     android_color_transform_t mColorTransform;

     // Need to know if display is wide-color capable or not.
     // Initialized by SurfaceFlinger when the DisplayDevice is created.
     // Fed to RenderEngine during composition.
     bool mHasWideColorGamut;
     bool mHasHdr10;
     bool mHasHLG;
     bool mHasDolbyVision;
     HdrCapabilities mHdrCapabilities;
     const int32_t mSupportedPerFrameMetadata;

     // Mappings from desired Dataspace/RenderIntent to the supported
     // Dataspace/ColorMode/RenderIntent.
     using ColorModeKey = uint64_t;
     struct ColorModeValue {
         ui::Dataspace dataspace;
         ui::ColorMode colorMode;
         ui::RenderIntent renderIntent;
     };

     static ColorModeKey getColorModeKey(ui::Dataspace dataspace, ui::RenderIntent intent) {
         return (static_cast<uint64_t>(dataspace) << 32) | static_cast<uint32_t>(intent);
     }
     void populateColorModes(
             const std::unordered_map<ui::ColorMode, std::vector<ui::RenderIntent>>& hwcColorModes);
     void addColorMode(
             const std::unordered_map<ui::ColorMode, std::vector<ui::RenderIntent>>& hwcColorModes,
             const ui::ColorMode mode, const ui::RenderIntent intent);

     std::unordered_map<ColorModeKey, ColorModeValue> mColorModes;
 };

 struct DisplayDeviceState {
     DisplayDeviceState() = default;
     DisplayDeviceState(DisplayDevice::DisplayType type, bool isSecure);

     bool isValid() const { return type >= 0; }
     bool isMainDisplay() const { return type == DisplayDevice::DISPLAY_PRIMARY; }
     bool isVirtualDisplay() const { return type >= DisplayDevice::DISPLAY_VIRTUAL; }

     static std::atomic<int32_t> nextDisplayId;
     int32_t displayId = nextDisplayId++;
     DisplayDevice::DisplayType type = DisplayDevice::DISPLAY_ID_INVALID;
     sp<IGraphicBufferProducer> surface;
     uint32_t layerStack = DisplayDevice::NO_LAYER_STACK;
     Rect viewport;
     Rect frame;
     uint8_t orientation = 0;
     uint32_t width = 0;
     uint32_t height = 0;
     String8 displayName;
     bool isSecure = false;
 };

 class DisplayRenderArea : public RenderArea {
 public:
     DisplayRenderArea(const sp<const DisplayDevice> device,
                       ISurfaceComposer::Rotation rotation = ISurfaceComposer::eRotateNone)
           : DisplayRenderArea(device, device->getBounds(), device->getHeight(), device->getWidth(),
                               rotation) {}
     DisplayRenderArea(const sp<const DisplayDevice> device, Rect sourceCrop, uint32_t reqHeight,
                       uint32_t reqWidth, ISurfaceComposer::Rotation rotation)
           : RenderArea(reqHeight, reqWidth, CaptureFill::OPAQUE, rotation), mDevice(device),
                               mSourceCrop(sourceCrop) {}

     const Transform& getTransform() const override { return mDevice->getTransform(); }
     Rect getBounds() const override { return mDevice->getBounds(); }
     int getHeight() const override { return mDevice->getHeight(); }
     int getWidth() const override { return mDevice->getWidth(); }
     bool isSecure() const override { return mDevice->isSecure(); }
     bool needsFiltering() const override { return mDevice->needsFiltering(); }
     Rect getSourceCrop() const override { return mSourceCrop; }

 private:
     const sp<const DisplayDevice> mDevice;
     const Rect mSourceCrop;
 };

 }; // namespace android

 #endif // ANDROID_DISPLAY_DEVICE_H
	/*
	* Copyright (C) 2007 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.
	*/

	#ifndef ANDROID_DISPLAY_DEVICE_H
	#define ANDROID_DISPLAY_DEVICE_H

	#include "Transform.h"

	#include <stdlib.h>
	#include <unordered_map>

	#include <math/mat4.h>

	#include <binder/IBinder.h>
	#include <gui/ISurfaceComposer.h>
	#include <hardware/hwcomposer_defs.h>
	#include <ui/GraphicTypes.h>
	#include <ui/HdrCapabilities.h>
	#include <ui/Region.h>
	#include <utils/RefBase.h>
	#include <utils/Mutex.h>
	#include <utils/String8.h>
	#include <utils/Timers.h>

	#include "RenderArea.h"
	#include "RenderEngine/Surface.h"

	#include <memory>

	struct ANativeWindow;

	namespace android {

	struct DisplayInfo;
	class DisplaySurface;
	class Fence;
	class IGraphicBufferProducer;
	class Layer;
	class SurfaceFlinger;
	class HWComposer;

	class DisplayDevice : public LightRefBase<DisplayDevice>
	{
	public:
	constexpr static float sDefaultMinLumiance = 0.0;
	constexpr static float sDefaultMaxLumiance = 500.0;

	// region in layer-stack space
	mutable Region dirtyRegion;
	// region in screen space
	Region undefinedRegion;
	bool lastCompositionHadVisibleLayers;

	enum DisplayType {
	DISPLAY_ID_INVALID = -1,
	DISPLAY_PRIMARY = HWC_DISPLAY_PRIMARY,
	DISPLAY_EXTERNAL = HWC_DISPLAY_EXTERNAL,
	DISPLAY_VIRTUAL = HWC_DISPLAY_VIRTUAL,
	NUM_BUILTIN_DISPLAY_TYPES = HWC_NUM_PHYSICAL_DISPLAY_TYPES,
	};

	enum {
	NO_LAYER_STACK = 0xFFFFFFFF,
	};

	// clang-format off
	DisplayDevice(
	const sp<SurfaceFlinger>& flinger,
	DisplayType type,
	int32_t hwcId,
	bool isSecure,
	const wp<IBinder>& displayToken,
	const sp<ANativeWindow>& nativeWindow,
	const sp<DisplaySurface>& displaySurface,
	std::unique_ptr<RE::Surface> renderSurface,
	int displayWidth,
	int displayHeight,
	bool hasWideColorGamut,
	const HdrCapabilities& hdrCapabilities,
	const int32_t supportedPerFrameMetadata,
	const std::unordered_map<ui::ColorMode, std::vector<ui::RenderIntent>>& hwcColorModes,
	int initialPowerMode);
	// clang-format on

	~DisplayDevice();

	// whether this is a valid object. An invalid DisplayDevice is returned
	// when an non existing id is requested
	bool isValid() const;

	// isSecure indicates whether this display can be trusted to display
	// secure surfaces.
	bool isSecure() const { return mIsSecure; }

	// Flip the front and back buffers if the back buffer is "dirty". Might
	// be instantaneous, might involve copying the frame buffer around.
	void flip() const;

	int getWidth() const;
	int getHeight() const;

	void setVisibleLayersSortedByZ(const Vector< sp<Layer> >& layers);
	const Vector< sp<Layer> >& getVisibleLayersSortedByZ() const;
	void setLayersNeedingFences(const Vector< sp<Layer> >& layers);
	const Vector< sp<Layer> >& getLayersNeedingFences() const;
	Region getDirtyRegion(bool repaintEverything) const;

	void setLayerStack(uint32_t stack);
	void setDisplaySize(const int newWidth, const int newHeight);
	void setProjection(int orientation, const Rect& viewport, const Rect& frame);

	int getOrientation() const { return mOrientation; }
	uint32_t getOrientationTransform() const;
	static uint32_t getPrimaryDisplayOrientationTransform();
	const Transform& getTransform() const { return mGlobalTransform; }
	const Rect getViewport() const { return mViewport; }
	const Rect getFrame() const { return mFrame; }
	const Rect& getScissor() const { return mScissor; }
	bool needsFiltering() const { return mNeedsFiltering; }

	uint32_t getLayerStack() const { return mLayerStack; }
	int32_t getDisplayType() const { return mType; }
	bool isPrimary() const { return mType == DISPLAY_PRIMARY; }
	int32_t getHwcDisplayId() const { return mHwcDisplayId; }
	const wp<IBinder>& getDisplayToken() const { return mDisplayToken; }

	int32_t getSupportedPerFrameMetadata() const { return mSupportedPerFrameMetadata; }

	// We pass in mustRecompose so we can keep VirtualDisplaySurface's state
	// machine happy without actually queueing a buffer if nothing has changed
	status_t beginFrame(bool mustRecompose) const;
	status_t prepareFrame(HWComposer& hwc);

	bool hasWideColorGamut() const { return mHasWideColorGamut; }
	// Whether h/w composer has native support for specific HDR type.
	bool hasHDR10Support() const { return mHasHdr10; }
	bool hasHLGSupport() const { return mHasHLG; }
	bool hasDolbyVisionSupport() const { return mHasDolbyVision; }

	// Return true if the HDR dataspace is supported but
	// there is no corresponding color mode.
	bool hasLegacyHdrSupport(ui::Dataspace dataspace) const;

	// The returned HdrCapabilities is the combination of HDR capabilities from
	// hardware composer and RenderEngine. When the DisplayDevice supports wide
	// color gamut, RenderEngine is able to simulate HDR support in Display P3
	// color space for both PQ and HLG HDR contents. The minimum and maximum
	// luminance will be set to sDefaultMinLumiance and sDefaultMaxLumiance
	// respectively if hardware composer doesn't return meaningful values.
	const HdrCapabilities& getHdrCapabilities() const { return mHdrCapabilities; }

	// Return true if intent is supported by the display.
	bool hasRenderIntent(ui::RenderIntent intent) const;

	void getBestColorMode(ui::Dataspace dataspace, ui::RenderIntent intent,
	ui::Dataspace* outDataspace, ui::ColorMode* outMode,
	ui::RenderIntent* outIntent) const;

	void swapBuffers(HWComposer& hwc) const;

	// called after h/w composer has completed its set() call
	void onSwapBuffersCompleted() const;

	Rect getBounds() const {
	return Rect(mDisplayWidth, mDisplayHeight);
	}
	inline Rect bounds() const { return getBounds(); }

	void setDisplayName(const String8& displayName);
	const String8& getDisplayName() const { return mDisplayName; }

	bool makeCurrent() const;
	void setViewportAndProjection() const;

	const sp<Fence>& getClientTargetAcquireFence() const;

	/* ------------------------------------------------------------------------
	* Display power mode management.
	*/
	int getPowerMode() const;
	void setPowerMode(int mode);
	bool isDisplayOn() const;

	ui::ColorMode getActiveColorMode() const;
	void setActiveColorMode(ui::ColorMode mode);
	ui::RenderIntent getActiveRenderIntent() const;
	void setActiveRenderIntent(ui::RenderIntent renderIntent);
	android_color_transform_t getColorTransform() const;
	void setColorTransform(const mat4& transform);
	void setCompositionDataSpace(ui::Dataspace dataspace);
	ui::Dataspace getCompositionDataSpace() const;

	/* ------------------------------------------------------------------------
	* Display active config management.
	*/
	int getActiveConfig() const;
	void setActiveConfig(int mode);

	// release HWC resources (if any) for removable displays
	void disconnect(HWComposer& hwc);

	/* ------------------------------------------------------------------------
	* Debugging
	*/
	uint32_t getPageFlipCount() const;
	void dump(String8& result) const;

	private:
	/*
	* Constants, set during initialization
	*/
	sp<SurfaceFlinger> mFlinger;
	DisplayType mType;
	int32_t mHwcDisplayId;
	wp<IBinder> mDisplayToken;

	// ANativeWindow this display is rendering into
	sp<ANativeWindow> mNativeWindow;
	sp<DisplaySurface> mDisplaySurface;

	std::unique_ptr<RE::Surface> mSurface;
	int mDisplayWidth;
	int mDisplayHeight;
	mutable uint32_t mPageFlipCount;
	String8 mDisplayName;
	bool mIsSecure;

	/*
	* Can only accessed from the main thread, these members
	* don't need synchronization.
	*/

	// list of visible layers on that display
	Vector< sp<Layer> > mVisibleLayersSortedByZ;
	// list of layers needing fences
	Vector< sp<Layer> > mLayersNeedingFences;

	/*
	* Transaction state
	*/
	static status_t orientationToTransfrom(int orientation,
	int w, int h, Transform* tr);

	// The identifier of the active layer stack for this display. Several displays
	// can use the same layer stack: A z-ordered group of layers (sometimes called
	// "surfaces"). Any given layer can only be on a single layer stack.
	uint32_t mLayerStack;

	int mOrientation;
	static uint32_t sPrimaryDisplayOrientation;
	// user-provided visible area of the layer stack
	Rect mViewport;
	// user-provided rectangle where mViewport gets mapped to
	Rect mFrame;
	// pre-computed scissor to apply to the display
	Rect mScissor;
	Transform mGlobalTransform;
	bool mNeedsFiltering;
	// Current power mode
	int mPowerMode;
	// Current active config
	int mActiveConfig;
	// current active color mode
	ui::ColorMode mActiveColorMode = ui::ColorMode::NATIVE;
	// Current active render intent.
	ui::RenderIntent mActiveRenderIntent = ui::RenderIntent::COLORIMETRIC;
	ui::Dataspace mCompositionDataSpace = ui::Dataspace::UNKNOWN;
	// Current color transform
	android_color_transform_t mColorTransform;

	// Need to know if display is wide-color capable or not.
	// Initialized by SurfaceFlinger when the DisplayDevice is created.
	// Fed to RenderEngine during composition.
	bool mHasWideColorGamut;
	bool mHasHdr10;
	bool mHasHLG;
	bool mHasDolbyVision;
	HdrCapabilities mHdrCapabilities;
	const int32_t mSupportedPerFrameMetadata;

	// Mappings from desired Dataspace/RenderIntent to the supported
	// Dataspace/ColorMode/RenderIntent.
	using ColorModeKey = uint64_t;
	struct ColorModeValue {
	ui::Dataspace dataspace;
	ui::ColorMode colorMode;
	ui::RenderIntent renderIntent;
	};

	static ColorModeKey getColorModeKey(ui::Dataspace dataspace, ui::RenderIntent intent) {
	return (static_cast<uint64_t>(dataspace) << 32) \| static_cast<uint32_t>(intent);
	}
	void populateColorModes(
	const std::unordered_map<ui::ColorMode, std::vector<ui::RenderIntent>>& hwcColorModes);
	void addColorMode(
	const std::unordered_map<ui::ColorMode, std::vector<ui::RenderIntent>>& hwcColorModes,
	const ui::ColorMode mode, const ui::RenderIntent intent);

	std::unordered_map<ColorModeKey, ColorModeValue> mColorModes;
	};

	struct DisplayDeviceState {
	DisplayDeviceState() = default;
	DisplayDeviceState(DisplayDevice::DisplayType type, bool isSecure);

	bool isValid() const { return type >= 0; }
	bool isMainDisplay() const { return type == DisplayDevice::DISPLAY_PRIMARY; }
	bool isVirtualDisplay() const { return type >= DisplayDevice::DISPLAY_VIRTUAL; }

	static std::atomic<int32_t> nextDisplayId;
	int32_t displayId = nextDisplayId++;
	DisplayDevice::DisplayType type = DisplayDevice::DISPLAY_ID_INVALID;
	sp<IGraphicBufferProducer> surface;
	uint32_t layerStack = DisplayDevice::NO_LAYER_STACK;
	Rect viewport;
	Rect frame;
	uint8_t orientation = 0;
	uint32_t width = 0;
	uint32_t height = 0;
	String8 displayName;
	bool isSecure = false;
	};

	class DisplayRenderArea : public RenderArea {
	public:
	DisplayRenderArea(const sp<const DisplayDevice> device,
	ISurfaceComposer::Rotation rotation = ISurfaceComposer::eRotateNone)
	: DisplayRenderArea(device, device->getBounds(), device->getHeight(), device->getWidth(),
	rotation) {}
	DisplayRenderArea(const sp<const DisplayDevice> device, Rect sourceCrop, uint32_t reqHeight,
	uint32_t reqWidth, ISurfaceComposer::Rotation rotation)
	: RenderArea(reqHeight, reqWidth, CaptureFill::OPAQUE, rotation), mDevice(device),
	mSourceCrop(sourceCrop) {}

	const Transform& getTransform() const override { return mDevice->getTransform(); }
	Rect getBounds() const override { return mDevice->getBounds(); }
	int getHeight() const override { return mDevice->getHeight(); }
	int getWidth() const override { return mDevice->getWidth(); }
	bool isSecure() const override { return mDevice->isSecure(); }
	bool needsFiltering() const override { return mDevice->needsFiltering(); }
	Rect getSourceCrop() const override { return mSourceCrop; }

	private:
	const sp<const DisplayDevice> mDevice;
	const Rect mSourceCrop;
	};

	}; // namespace android

	#endif // ANDROID_DISPLAY_DEVICE_H