ui/display/manager/managed_display_info.h - chromium/src - Git at Google

 // Copyright (c) 2013 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef UI_DISPLAY_MANAGER_MANAGED_DISPLAY_INFO_H_
 #define UI_DISPLAY_MANAGER_MANAGED_DISPLAY_INFO_H_

 #include <stdint.h>
 #include <algorithm>
 #include <map>
 #include <string>
 #include <vector>

 #include "base/files/file_path.h"
 #include "ui/display/display.h"
 #include "ui/display/manager/display_manager_export.h"
 #include "ui/display/types/display_constants.h"
 #include "ui/gfx/geometry/insets.h"
 #include "ui/gfx/geometry/rect.h"

 namespace display {

 // A class that represents the display's mode info.
 class DISPLAY_MANAGER_EXPORT ManagedDisplayMode {
  public:
   ManagedDisplayMode();
   explicit ManagedDisplayMode(const gfx::Size& size);

   ManagedDisplayMode(const gfx::Size& size,
                      float refresh_rate,
                      bool is_interlaced,
                      bool native);

   ManagedDisplayMode(const gfx::Size& size,
                      float refresh_rate,
                      bool is_interlaced,
                      bool native,
                      float device_scale_factor);

   ~ManagedDisplayMode();
   ManagedDisplayMode(const ManagedDisplayMode& other);
   ManagedDisplayMode& operator=(const ManagedDisplayMode& other);

   // Returns the size in DIP which is visible to the user.
   gfx::Size GetSizeInDIP(bool is_internal) const;

   // Returns true if |other| has same size and scale factors.
   bool IsEquivalent(const ManagedDisplayMode& other) const;

   const gfx::Size& size() const { return size_; }
   bool is_interlaced() const { return is_interlaced_; }
   float refresh_rate() const { return refresh_rate_; }

   bool native() const { return native_; }

   // Missing from ui::ManagedDisplayMode
   float device_scale_factor() const { return device_scale_factor_; }

  private:
   gfx::Size size_;              // Physical pixel size of the display.
   float refresh_rate_ = 0.0f;   // Refresh rate of the display, in Hz.
   bool is_interlaced_ = false;  // True if mode is interlaced.
   bool native_ = false;         // True if mode is native mode of the display.
   float device_scale_factor_ = 1.0f;  // The device scale factor of the mode.
 };

 // ManagedDisplayInfo contains metadata for each display. This is used to create
 // |Display| as well as to maintain extra infomation to manage displays in ash
 // environment. This class is intentionally made copiable.
 class DISPLAY_MANAGER_EXPORT ManagedDisplayInfo {
  public:
   using ManagedDisplayModeList = std::vector<ManagedDisplayMode>;

   // Creates a ManagedDisplayInfo from string spec. 100+200-1440x800 creates
   // display
   // whose size is 1440x800 at the location (100, 200) in host coordinates.
   // The format is
   //
   // [origin-]widthxheight[*device_scale_factor][#resolutions list]
   //     [/<properties>][@zoom-factor]
   //
   // where [] are optional:
   // - |origin| is given in x+y- format.
   // - |device_scale_factor| is either 2 or 1 (or empty).
   // - properties can combination of 'o', which adds default overscan insets
   //   (5%), and one rotation property where 'r' is 90 degree clock-wise
   //   (to the 'r'ight) 'u' is 180 degrees ('u'pside-down) and 'l' is
   //   270 degrees (to the 'l'eft).
   // - zoom-factor is floating value, e.g. @1.5 or @1.25.
   // - |resolution list| is the list of size that is given in
   //   |width x height [% refresh_rate]| separated by '|'.
   //
   // A couple of examples:
   // "100x100"
   //      100x100 window at 0,0 origin. 1x device scale factor. no overscan.
   //      no rotation. 1.0 zoom factor.
   // "5+5-300x200*2"
   //      300x200 window at 5,5 origin. 2x device scale factor.
   //      no overscan, no rotation. 1.0 zoom factor.
   // "300x200/ol"
   //      300x200 window at 0,0 origin. 1x device scale factor.
   //      with 5% overscan. rotated to left (90 degree counter clockwise).
   //      1.0 zoom factor.
   // "10+20-300x200/u@1.5"
   //      300x200 window at 10,20 origin. 1x device scale factor.
   //      no overscan. flipped upside-down (180 degree) and 1.5 zoom factor.
   // "200x100#300x200|200x100%59.0|100x100%60"
   //      200x100 window at 0,0 origin, with 3 possible resolutions,
   //      300x200, 200x100 at 59 Hz, and 100x100 at 60 Hz.
   static ManagedDisplayInfo CreateFromSpec(const std::string& spec);

   // Creates a ManagedDisplayInfo from string spec using given |id|.
   static ManagedDisplayInfo CreateFromSpecWithID(const std::string& spec,
                                                  int64_t id);

   ManagedDisplayInfo();
   ManagedDisplayInfo(int64_t id, const std::string& name, bool has_overscan);
   ManagedDisplayInfo(const ManagedDisplayInfo& other);
   ~ManagedDisplayInfo();

   int64_t id() const { return id_; }

   // The name of the display.
   const std::string& name() const { return name_; }

   // The path to the display device in the sysfs filesystem.
   void set_sys_path(const base::FilePath& sys_path) { sys_path_ = sys_path; }
   const base::FilePath& sys_path() const { return sys_path_; }

   // True if the display EDID has the overscan flag. This does not create the
   // actual overscan automatically, but used in the message.
   bool has_overscan() const { return has_overscan_; }

   void set_touch_support(Display::TouchSupport support) {
     touch_support_ = support;
   }
   Display::TouchSupport touch_support() const { return touch_support_; }

   // Gets/Sets the device scale factor of the display.
   float device_scale_factor() const { return device_scale_factor_; }
   void set_device_scale_factor(float scale) { device_scale_factor_ = scale; }

   float zoom_factor() const { return zoom_factor_; }
   void set_zoom_factor(float zoom_factor) { zoom_factor_ = zoom_factor; }
   void set_is_zoom_factor_from_ui_scale(bool is_zoom_factor_from_ui_scale) {
     is_zoom_factor_from_ui_scale_ = is_zoom_factor_from_ui_scale;
   }
   bool is_zoom_factor_from_ui_scale() const {
     return is_zoom_factor_from_ui_scale_;
   }

   // Gets/Sets the device DPI of the display.
   float device_dpi() const { return device_dpi_; }
   void set_device_dpi(float dpi) { device_dpi_ = dpi; }

   // The native bounds for the display. The size of this can be
   // different from the |size_in_pixel| when overscan insets are set.
   const gfx::Rect& bounds_in_native() const { return bounds_in_native_; }

   // The size for the display in pixels.
   const gfx::Size& size_in_pixel() const { return size_in_pixel_; }

   // The overscan insets for the display in DIP.
   const gfx::Insets& overscan_insets_in_dip() const {
     return overscan_insets_in_dip_;
   }

   // Sets the rotation for the given |source|. Setting a new rotation will also
   // have it become the active rotation.
   void SetRotation(Display::Rotation rotation, Display::RotationSource source);

   // Returns the currently active rotation for this display.
   Display::Rotation GetActiveRotation() const;

   // Returns the source which set the active rotation for this display.
   Display::RotationSource active_rotation_source() const {
     return active_rotation_source_;
   }

   // Returns the rotation set by a given |source|.
   Display::Rotation GetRotation(Display::RotationSource source) const;

   // Returns a measure of density relative to a display with 1.0 DSF. Unlike the
   // effective DSF, this is independent from the UI scale.
   float GetDensityRatio() const;

   // Returns the ui scale and device scale factor actually used to create
   // display that chrome sees. This can be different from one obtained
   // from dispaly or one specified by a user in following situation.
   // 1) DSF is 2.0f and UI scale is 2.0f. (Returns 1.0f and 1.0f respectiely)
   // 2) A user specified 0.8x on the device that has 1.25 DSF. 1.25 DSF device
   //    uses 1.0f DFS unless 0.8x UI scaling is specified.
   float GetEffectiveDeviceScaleFactor() const;

   // Copy the display info except for fields that can be modified by a user
   // (|rotation_|). |rotation_| is copied when the |another_info| isn't native
   // one.
   void Copy(const ManagedDisplayInfo& another_info);

   // Update the |bounds_in_native_| and |size_in_pixel_| using
   // given |bounds_in_native|.
   void SetBounds(const gfx::Rect& bounds_in_native);

   // Update the |bounds_in_native| according to the current overscan
   // and rotation settings.
   void UpdateDisplaySize();

   // Sets/Clears the overscan insets.
   void SetOverscanInsets(const gfx::Insets& insets_in_dip);
   gfx::Insets GetOverscanInsetsInPixel() const;

   // Sets/Gets the flag to clear overscan insets.
   bool clear_overscan_insets() const { return clear_overscan_insets_; }
   void set_clear_overscan_insets(bool clear) { clear_overscan_insets_ = clear; }

   void set_native(bool native) { native_ = native; }
   bool native() const { return native_; }

   const ManagedDisplayModeList& display_modes() const { return display_modes_; }
   // Sets the display mode list. The mode list will be sorted for the
   // display.
   void SetManagedDisplayModes(const ManagedDisplayModeList& display_modes);

   // Returns the native mode size. If a native mode is not present, return an
   // empty size.
   gfx::Size GetNativeModeSize() const;

   const gfx::ColorSpace& color_space() const { return color_space_; }
   void set_color_space(const gfx::ColorSpace& color_space) {
     color_space_ = color_space;
   }

   bool is_aspect_preserving_scaling() const {
     return is_aspect_preserving_scaling_;
   }

   void set_is_aspect_preserving_scaling(bool value) {
     is_aspect_preserving_scaling_ = value;
   }

   // Maximum cursor size in native pixels.
   const gfx::Size& maximum_cursor_size() const { return maximum_cursor_size_; }
   void set_maximum_cursor_size(const gfx::Size& size) {
     maximum_cursor_size_ = size;
   }

   const std::string& manufacturer_id() const { return manufacturer_id_; }
   void set_manufacturer_id(const std::string& id) { manufacturer_id_ = id; }

   const std::string& product_id() const { return product_id_; }
   void set_product_id(const std::string& id) { product_id_ = id; }

   int32_t year_of_manufacture() const { return year_of_manufacture_; }
   void set_year_of_manufacture(int32_t year) { year_of_manufacture_ = year; }

   // Returns a string representation of the ManagedDisplayInfo, excluding
   // display modes.
   std::string ToString() const;

   // Returns a string representation of the ManagedDisplayInfo, including
   // display modes.
   std::string ToFullString() const;

  private:
   int64_t id_;
   std::string name_;
   std::string manufacturer_id_;
   std::string product_id_;
   int32_t year_of_manufacture_;
   base::FilePath sys_path_;
   bool has_overscan_;
   std::map<Display::RotationSource, Display::Rotation> rotations_;
   Display::RotationSource active_rotation_source_;
   Display::TouchSupport touch_support_;

   // This specifies the device's pixel density. (For example, a display whose
   // DPI is higher than the threshold is considered to have device_scale_factor
   // = 2.0 on Chrome OS).  This is used by the graphics layer to choose and draw
   // appropriate images and scale layers properly.
   float device_scale_factor_;
   gfx::Rect bounds_in_native_;

   // This specifies the device's DPI.
   float device_dpi_;

   // The size of the display in use. The size can be different from the size
   // of |bounds_in_native_| if the display has overscan insets and/or rotation.
   gfx::Size size_in_pixel_;
   gfx::Insets overscan_insets_in_dip_;

   // The zoom level currently applied to the display. This value is appended
   // multiplicatively to the device scale factor to get the effecting scaling
   // for a display.
   float zoom_factor_;

   // True if the |zoom_factor_| currently set is a port of the ui-scale. This is
   // needed to correctly compute zoom values and effective device scale factor
   // for FHD devices with 1.25 device scale factor.
   bool is_zoom_factor_from_ui_scale_;

   // True if this comes from native platform (DisplayChangeObserver).
   bool native_;

   // True if the display is configured to preserve the aspect ratio. When the
   // display is configured in a non-native mode, only parts of the display will
   // be used such that the aspect ratio is preserved.
   bool is_aspect_preserving_scaling_;

   // True if the displays' overscan inset should be cleared. This is
   // to distinguish the empty overscan insets from native display info.
   bool clear_overscan_insets_;

   // The list of modes supported by this display.
   ManagedDisplayModeList display_modes_;

   // Maximum cursor size.
   gfx::Size maximum_cursor_size_;

   // Colorimetry information of the Display (if IsValid()), including e.g.
   // transfer and primaries information, retrieved from its EDID.
   gfx::ColorSpace color_space_;

   // If you add a new member, you need to update Copy().
 };

 // Resets the synthesized display id for testing. This
 // is necessary to avoid overflowing the output index.
 void DISPLAY_MANAGER_EXPORT ResetDisplayIdForTest();

 }  // namespace display

 #endif  //  UI_DISPLAY_MANAGER_MANAGED_DISPLAY_INFO_H_
	// Copyright (c) 2013 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef UI_DISPLAY_MANAGER_MANAGED_DISPLAY_INFO_H_
	#define UI_DISPLAY_MANAGER_MANAGED_DISPLAY_INFO_H_

	#include <stdint.h>
	#include <algorithm>
	#include <map>
	#include <string>
	#include <vector>

	#include "base/files/file_path.h"
	#include "ui/display/display.h"
	#include "ui/display/manager/display_manager_export.h"
	#include "ui/display/types/display_constants.h"
	#include "ui/gfx/geometry/insets.h"
	#include "ui/gfx/geometry/rect.h"

	namespace display {

	// A class that represents the display's mode info.
	class DISPLAY_MANAGER_EXPORT ManagedDisplayMode {
	public:
	ManagedDisplayMode();
	explicit ManagedDisplayMode(const gfx::Size& size);

	ManagedDisplayMode(const gfx::Size& size,
	float refresh_rate,
	bool is_interlaced,
	bool native);

	ManagedDisplayMode(const gfx::Size& size,
	float refresh_rate,
	bool is_interlaced,
	bool native,
	float device_scale_factor);

	~ManagedDisplayMode();
	ManagedDisplayMode(const ManagedDisplayMode& other);
	ManagedDisplayMode& operator=(const ManagedDisplayMode& other);

	// Returns the size in DIP which is visible to the user.
	gfx::Size GetSizeInDIP(bool is_internal) const;

	// Returns true if \|other\| has same size and scale factors.
	bool IsEquivalent(const ManagedDisplayMode& other) const;

	const gfx::Size& size() const { return size_; }
	bool is_interlaced() const { return is_interlaced_; }
	float refresh_rate() const { return refresh_rate_; }

	bool native() const { return native_; }

	// Missing from ui::ManagedDisplayMode
	float device_scale_factor() const { return device_scale_factor_; }

	private:
	gfx::Size size_; // Physical pixel size of the display.
	float refresh_rate_ = 0.0f; // Refresh rate of the display, in Hz.
	bool is_interlaced_ = false; // True if mode is interlaced.
	bool native_ = false; // True if mode is native mode of the display.
	float device_scale_factor_ = 1.0f; // The device scale factor of the mode.
	};

	// ManagedDisplayInfo contains metadata for each display. This is used to create
	// \|Display\| as well as to maintain extra infomation to manage displays in ash
	// environment. This class is intentionally made copiable.
	class DISPLAY_MANAGER_EXPORT ManagedDisplayInfo {
	public:
	using ManagedDisplayModeList = std::vector<ManagedDisplayMode>;

	// Creates a ManagedDisplayInfo from string spec. 100+200-1440x800 creates
	// display
	// whose size is 1440x800 at the location (100, 200) in host coordinates.
	// The format is
	//
	// [origin-]widthxheight[*device_scale_factor][#resolutions list]
	// [/<properties>][@zoom-factor]
	//
	// where [] are optional:
	// - \|origin\| is given in x+y- format.
	// - \|device_scale_factor\| is either 2 or 1 (or empty).
	// - properties can combination of 'o', which adds default overscan insets
	// (5%), and one rotation property where 'r' is 90 degree clock-wise
	// (to the 'r'ight) 'u' is 180 degrees ('u'pside-down) and 'l' is
	// 270 degrees (to the 'l'eft).
	// - zoom-factor is floating value, e.g. @1.5 or @1.25.
	// - \|resolution list\| is the list of size that is given in
	// \|width x height [% refresh_rate]\| separated by '\|'.
	//
	// A couple of examples:
	// "100x100"
	// 100x100 window at 0,0 origin. 1x device scale factor. no overscan.
	// no rotation. 1.0 zoom factor.
	// "5+5-300x200*2"
	// 300x200 window at 5,5 origin. 2x device scale factor.
	// no overscan, no rotation. 1.0 zoom factor.
	// "300x200/ol"
	// 300x200 window at 0,0 origin. 1x device scale factor.
	// with 5% overscan. rotated to left (90 degree counter clockwise).
	// 1.0 zoom factor.
	// "10+20-300x200/u@1.5"
	// 300x200 window at 10,20 origin. 1x device scale factor.
	// no overscan. flipped upside-down (180 degree) and 1.5 zoom factor.
	// "200x100#300x200\|200x100%59.0\|100x100%60"
	// 200x100 window at 0,0 origin, with 3 possible resolutions,
	// 300x200, 200x100 at 59 Hz, and 100x100 at 60 Hz.
	static ManagedDisplayInfo CreateFromSpec(const std::string& spec);

	// Creates a ManagedDisplayInfo from string spec using given \|id\|.
	static ManagedDisplayInfo CreateFromSpecWithID(const std::string& spec,
	int64_t id);

	ManagedDisplayInfo();
	ManagedDisplayInfo(int64_t id, const std::string& name, bool has_overscan);
	ManagedDisplayInfo(const ManagedDisplayInfo& other);
	~ManagedDisplayInfo();

	int64_t id() const { return id_; }

	// The name of the display.
	const std::string& name() const { return name_; }

	// The path to the display device in the sysfs filesystem.
	void set_sys_path(const base::FilePath& sys_path) { sys_path_ = sys_path; }
	const base::FilePath& sys_path() const { return sys_path_; }

	// True if the display EDID has the overscan flag. This does not create the
	// actual overscan automatically, but used in the message.
	bool has_overscan() const { return has_overscan_; }

	void set_touch_support(Display::TouchSupport support) {
	touch_support_ = support;
	}
	Display::TouchSupport touch_support() const { return touch_support_; }

	// Gets/Sets the device scale factor of the display.
	float device_scale_factor() const { return device_scale_factor_; }
	void set_device_scale_factor(float scale) { device_scale_factor_ = scale; }

	float zoom_factor() const { return zoom_factor_; }
	void set_zoom_factor(float zoom_factor) { zoom_factor_ = zoom_factor; }
	void set_is_zoom_factor_from_ui_scale(bool is_zoom_factor_from_ui_scale) {
	is_zoom_factor_from_ui_scale_ = is_zoom_factor_from_ui_scale;
	}
	bool is_zoom_factor_from_ui_scale() const {
	return is_zoom_factor_from_ui_scale_;
	}

	// Gets/Sets the device DPI of the display.
	float device_dpi() const { return device_dpi_; }
	void set_device_dpi(float dpi) { device_dpi_ = dpi; }

	// The native bounds for the display. The size of this can be
	// different from the \|size_in_pixel\| when overscan insets are set.
	const gfx::Rect& bounds_in_native() const { return bounds_in_native_; }

	// The size for the display in pixels.
	const gfx::Size& size_in_pixel() const { return size_in_pixel_; }

	// The overscan insets for the display in DIP.
	const gfx::Insets& overscan_insets_in_dip() const {
	return overscan_insets_in_dip_;
	}

	// Sets the rotation for the given \|source\|. Setting a new rotation will also
	// have it become the active rotation.
	void SetRotation(Display::Rotation rotation, Display::RotationSource source);

	// Returns the currently active rotation for this display.
	Display::Rotation GetActiveRotation() const;

	// Returns the source which set the active rotation for this display.
	Display::RotationSource active_rotation_source() const {
	return active_rotation_source_;
	}

	// Returns the rotation set by a given \|source\|.
	Display::Rotation GetRotation(Display::RotationSource source) const;

	// Returns a measure of density relative to a display with 1.0 DSF. Unlike the
	// effective DSF, this is independent from the UI scale.
	float GetDensityRatio() const;

	// Returns the ui scale and device scale factor actually used to create
	// display that chrome sees. This can be different from one obtained
	// from dispaly or one specified by a user in following situation.
	// 1) DSF is 2.0f and UI scale is 2.0f. (Returns 1.0f and 1.0f respectiely)
	// 2) A user specified 0.8x on the device that has 1.25 DSF. 1.25 DSF device
	// uses 1.0f DFS unless 0.8x UI scaling is specified.
	float GetEffectiveDeviceScaleFactor() const;

	// Copy the display info except for fields that can be modified by a user
	// (\|rotation_\|). \|rotation_\| is copied when the \|another_info\| isn't native
	// one.
	void Copy(const ManagedDisplayInfo& another_info);

	// Update the \|bounds_in_native_\| and \|size_in_pixel_\| using
	// given \|bounds_in_native\|.
	void SetBounds(const gfx::Rect& bounds_in_native);

	// Update the \|bounds_in_native\| according to the current overscan
	// and rotation settings.
	void UpdateDisplaySize();

	// Sets/Clears the overscan insets.
	void SetOverscanInsets(const gfx::Insets& insets_in_dip);
	gfx::Insets GetOverscanInsetsInPixel() const;

	// Sets/Gets the flag to clear overscan insets.
	bool clear_overscan_insets() const { return clear_overscan_insets_; }
	void set_clear_overscan_insets(bool clear) { clear_overscan_insets_ = clear; }

	void set_native(bool native) { native_ = native; }
	bool native() const { return native_; }

	const ManagedDisplayModeList& display_modes() const { return display_modes_; }
	// Sets the display mode list. The mode list will be sorted for the
	// display.
	void SetManagedDisplayModes(const ManagedDisplayModeList& display_modes);

	// Returns the native mode size. If a native mode is not present, return an
	// empty size.
	gfx::Size GetNativeModeSize() const;

	const gfx::ColorSpace& color_space() const { return color_space_; }
	void set_color_space(const gfx::ColorSpace& color_space) {
	color_space_ = color_space;
	}

	bool is_aspect_preserving_scaling() const {
	return is_aspect_preserving_scaling_;
	}

	void set_is_aspect_preserving_scaling(bool value) {
	is_aspect_preserving_scaling_ = value;
	}

	// Maximum cursor size in native pixels.
	const gfx::Size& maximum_cursor_size() const { return maximum_cursor_size_; }
	void set_maximum_cursor_size(const gfx::Size& size) {
	maximum_cursor_size_ = size;
	}

	const std::string& manufacturer_id() const { return manufacturer_id_; }
	void set_manufacturer_id(const std::string& id) { manufacturer_id_ = id; }

	const std::string& product_id() const { return product_id_; }
	void set_product_id(const std::string& id) { product_id_ = id; }

	int32_t year_of_manufacture() const { return year_of_manufacture_; }
	void set_year_of_manufacture(int32_t year) { year_of_manufacture_ = year; }

	// Returns a string representation of the ManagedDisplayInfo, excluding
	// display modes.
	std::string ToString() const;

	// Returns a string representation of the ManagedDisplayInfo, including
	// display modes.
	std::string ToFullString() const;

	private:
	int64_t id_;
	std::string name_;
	std::string manufacturer_id_;
	std::string product_id_;
	int32_t year_of_manufacture_;
	base::FilePath sys_path_;
	bool has_overscan_;
	std::map<Display::RotationSource, Display::Rotation> rotations_;
	Display::RotationSource active_rotation_source_;
	Display::TouchSupport touch_support_;

	// This specifies the device's pixel density. (For example, a display whose
	// DPI is higher than the threshold is considered to have device_scale_factor
	// = 2.0 on Chrome OS). This is used by the graphics layer to choose and draw
	// appropriate images and scale layers properly.
	float device_scale_factor_;
	gfx::Rect bounds_in_native_;

	// This specifies the device's DPI.
	float device_dpi_;

	// The size of the display in use. The size can be different from the size
	// of \|bounds_in_native_\| if the display has overscan insets and/or rotation.
	gfx::Size size_in_pixel_;
	gfx::Insets overscan_insets_in_dip_;

	// The zoom level currently applied to the display. This value is appended
	// multiplicatively to the device scale factor to get the effecting scaling
	// for a display.
	float zoom_factor_;

	// True if the \|zoom_factor_\| currently set is a port of the ui-scale. This is
	// needed to correctly compute zoom values and effective device scale factor
	// for FHD devices with 1.25 device scale factor.
	bool is_zoom_factor_from_ui_scale_;

	// True if this comes from native platform (DisplayChangeObserver).
	bool native_;

	// True if the display is configured to preserve the aspect ratio. When the
	// display is configured in a non-native mode, only parts of the display will
	// be used such that the aspect ratio is preserved.
	bool is_aspect_preserving_scaling_;

	// True if the displays' overscan inset should be cleared. This is
	// to distinguish the empty overscan insets from native display info.
	bool clear_overscan_insets_;

	// The list of modes supported by this display.
	ManagedDisplayModeList display_modes_;

	// Maximum cursor size.
	gfx::Size maximum_cursor_size_;

	// Colorimetry information of the Display (if IsValid()), including e.g.
	// transfer and primaries information, retrieved from its EDID.
	gfx::ColorSpace color_space_;

	// If you add a new member, you need to update Copy().
	};

	// Resets the synthesized display id for testing. This
	// is necessary to avoid overflowing the output index.
	void DISPLAY_MANAGER_EXPORT ResetDisplayIdForTest();

	} // namespace display

	#endif // UI_DISPLAY_MANAGER_MANAGED_DISPLAY_INFO_H_