ui/display/manager/display_change_observer.cc - chromium/src.git - Git at Google

 // Copyright 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.

 #include "ui/display/manager/display_change_observer.h"

 #include <algorithm>
 #include <map>
 #include <set>
 #include <string>
 #include <tuple>
 #include <utility>
 #include <vector>

 #include "base/logging.h"
 #include "base/stl_util.h"
 #include "ui/base/l10n/l10n_util.h"
 #include "ui/base/user_activity/user_activity_detector.h"
 #include "ui/display/display.h"
 #include "ui/display/display_features.h"
 #include "ui/display/display_layout.h"
 #include "ui/display/display_switches.h"
 #include "ui/display/manager/display_layout_store.h"
 #include "ui/display/manager/display_manager.h"
 #include "ui/display/manager/display_manager_utilities.h"
 #include "ui/display/manager/touch_device_manager.h"
 #include "ui/display/types/display_mode.h"
 #include "ui/display/types/display_snapshot.h"
 #include "ui/display/util/display_util.h"
 #include "ui/display/util/edid_parser.h"
 #include "ui/events/devices/device_data_manager.h"
 #include "ui/events/devices/touchscreen_device.h"
 #include "ui/strings/grit/ui_strings.h"

 namespace display {
 namespace {

 // The DPI threshold to determine the device scale factor.
 // DPI higher than |dpi| will use |device_scale_factor|.
 struct DeviceScaleFactorDPIThreshold {
   float dpi;
   float device_scale_factor;
 };

 // Update the list of zoom levels whenever a new device scale factor is added
 // here. See zoom level list in /ui/display/manager/display_util.cc
 const DeviceScaleFactorDPIThreshold kThresholdTableForInternal[] = {
     {320.f, 2.66667f}, {270.0f, 2.25f}, {230.0f, 2.0f}, {220.0f, 1.77778f},
     {180.0f, 1.6f},    {150.0f, 1.25f}, {0.0f, 1.0f},
 };

 // Returns a list of display modes for the given |output| that doesn't exclude
 // any mode. The returned list is sorted by size, then by refresh rate, then by
 // is_interlaced.
 ManagedDisplayInfo::ManagedDisplayModeList GetModeListWithAllRefreshRates(
     const DisplaySnapshot& output) {
   ManagedDisplayInfo::ManagedDisplayModeList display_mode_list;
   for (const auto& mode_info : output.modes()) {
     display_mode_list.emplace_back(mode_info->size(), mode_info->refresh_rate(),
                                    mode_info->is_interlaced(),
                                    output.native_mode() == mode_info.get(),
                                    1.0);
   }

   std::sort(
       display_mode_list.begin(), display_mode_list.end(),
       [](const ManagedDisplayMode& lhs, const ManagedDisplayMode& rhs) {
         return std::forward_as_tuple(lhs.size().width(), lhs.size().height(),
                                      lhs.refresh_rate(), lhs.is_interlaced()) <
                std::forward_as_tuple(rhs.size().width(), rhs.size().height(),
                                      rhs.refresh_rate(), rhs.is_interlaced());
       });

   return display_mode_list;
 }

 }  // namespace

 // static
 ManagedDisplayInfo::ManagedDisplayModeList
 DisplayChangeObserver::GetInternalManagedDisplayModeList(
     const ManagedDisplayInfo& display_info,
     const DisplaySnapshot& output) {
   const DisplayMode* ui_native_mode = output.native_mode();
   ManagedDisplayMode native_mode(ui_native_mode->size(),
                                  ui_native_mode->refresh_rate(),
                                  ui_native_mode->is_interlaced(), true,
                                  display_info.device_scale_factor());
   return CreateInternalManagedDisplayModeList(native_mode);
 }

 // static
 ManagedDisplayInfo::ManagedDisplayModeList
 DisplayChangeObserver::GetExternalManagedDisplayModeList(
     const DisplaySnapshot& output) {
   if (display::features::IsListAllDisplayModesEnabled())
     return GetModeListWithAllRefreshRates(output);

   struct SizeComparator {
     constexpr bool operator()(const gfx::Size& lhs,
                               const gfx::Size& rhs) const {
       return std::forward_as_tuple(lhs.width(), lhs.height()) <
              std::forward_as_tuple(rhs.width(), rhs.height());
     }
   };

   using DisplayModeMap =
       std::map<gfx::Size, ManagedDisplayMode, SizeComparator>;
   DisplayModeMap display_mode_map;

   ManagedDisplayMode native_mode;
   for (const auto& mode_info : output.modes()) {
     const gfx::Size size = mode_info->size();

     ManagedDisplayMode display_mode(
         mode_info->size(), mode_info->refresh_rate(),
         mode_info->is_interlaced(), output.native_mode() == mode_info.get(),
         1.0);
     if (display_mode.native())
       native_mode = display_mode;

     // Add the display mode if it isn't already present and override interlaced
     // display modes with non-interlaced ones. We prioritize having non
     // interlaced mode over refresh rate. A mode having lower refresh rate
     // but is not interlaced will be picked over a mode having high refresh
     // rate but is interlaced.
     auto display_mode_it = display_mode_map.find(size);
     if (display_mode_it == display_mode_map.end()) {
       display_mode_map.emplace(size, display_mode);
     } else if (display_mode_it->second.is_interlaced() &&
                !display_mode.is_interlaced()) {
       display_mode_it->second = std::move(display_mode);
     } else if (!display_mode.is_interlaced() &&
                display_mode_it->second.refresh_rate() <
                    display_mode.refresh_rate()) {
       display_mode_it->second = std::move(display_mode);
     }
   }

   if (output.native_mode()) {
     const gfx::Size size = native_mode.size();

     auto it = display_mode_map.find(size);
     DCHECK(it != display_mode_map.end())
         << "Native mode must be part of the mode list.";

     // If the native mode was replaced (e.g. by a mode with similar size but
     // higher refresh rate), we overwrite that mode with the native mode. The
     // native mode will always be chosen as the best mode for this size (see
     // DisplayConfigurator::FindDisplayModeMatchingSize()).
     if (!it->second.native())
       it->second = native_mode;
   }

   ManagedDisplayInfo::ManagedDisplayModeList display_mode_list;
   for (const auto& display_mode_pair : display_mode_map)
     display_mode_list.push_back(std::move(display_mode_pair.second));

   return display_mode_list;
 }

 DisplayChangeObserver::DisplayChangeObserver(DisplayManager* display_manager)
     : display_manager_(display_manager) {
   ui::DeviceDataManager::GetInstance()->AddObserver(this);
 }

 DisplayChangeObserver::~DisplayChangeObserver() {
   ui::DeviceDataManager::GetInstance()->RemoveObserver(this);
 }

 MultipleDisplayState DisplayChangeObserver::GetStateForDisplayIds(
     const DisplayConfigurator::DisplayStateList& display_states) {
   UpdateInternalDisplay(display_states);
   if (display_states.size() == 1)
     return MULTIPLE_DISPLAY_STATE_SINGLE;
   DisplayIdList list =
       GenerateDisplayIdList(display_states.begin(), display_states.end(),
                             [](const DisplaySnapshot* display_state) {
                               return display_state->display_id();
                             });
   return display_manager_->ShouldSetMirrorModeOn(list)
              ? MULTIPLE_DISPLAY_STATE_MULTI_MIRROR
              : MULTIPLE_DISPLAY_STATE_MULTI_EXTENDED;
 }

 bool DisplayChangeObserver::GetSelectedModeForDisplayId(
     int64_t display_id,
     ManagedDisplayMode* out_mode) const {
   return display_manager_->GetSelectedModeForDisplayId(display_id, out_mode);
 }

 void DisplayChangeObserver::OnDisplayModeChanged(
     const DisplayConfigurator::DisplayStateList& display_states) {
   UpdateInternalDisplay(display_states);

   std::vector<ManagedDisplayInfo> displays;
   for (const DisplaySnapshot* state : display_states) {
     const DisplayMode* mode_info = state->current_mode();
     if (!mode_info)
       continue;

     displays.emplace_back(CreateManagedDisplayInfo(state, mode_info));
   }

   display_manager_->touch_device_manager()->AssociateTouchscreens(
       &displays, ui::DeviceDataManager::GetInstance()->GetTouchscreenDevices());
   display_manager_->OnNativeDisplaysChanged(displays);

   // For the purposes of user activity detection, ignore synthetic mouse events
   // that are triggered by screen resizes: http://crbug.com/360634
   ui::UserActivityDetector* user_activity_detector =
       ui::UserActivityDetector::Get();
   if (user_activity_detector)
     user_activity_detector->OnDisplayPowerChanging();
 }

 void DisplayChangeObserver::OnDisplayModeChangeFailed(
     const DisplayConfigurator::DisplayStateList& displays,
     MultipleDisplayState failed_new_state) {
   // If display configuration failed during startup, simply update the display
   // manager with detected displays. If no display is detected, it will
   // create a pseudo display.
   if (display_manager_->GetNumDisplays() == 0)
     OnDisplayModeChanged(displays);
 }

 void DisplayChangeObserver::OnInputDeviceConfigurationChanged(
     uint8_t input_device_types) {
   if (input_device_types & ui::InputDeviceEventObserver::kTouchscreen) {
     // If there are no cached display snapshots, either there are no attached
     // displays or the cached snapshots have been invalidated. For the first
     // case there aren't any touchscreens to associate. For the second case,
     // the displays and touch input-devices will get associated when display
     // configuration finishes.
     const auto& cached_displays =
         display_manager_->configurator()->cached_displays();
     if (!cached_displays.empty())
       OnDisplayModeChanged(cached_displays);
   }
 }

 void DisplayChangeObserver::UpdateInternalDisplay(
     const DisplayConfigurator::DisplayStateList& display_states) {
   bool force_first_display_internal = ForceFirstDisplayInternal();

   for (auto* state : display_states) {
     if (state->type() == DISPLAY_CONNECTION_TYPE_INTERNAL ||
         (force_first_display_internal &&
          (!Display::HasInternalDisplay() ||
           state->display_id() == Display::InternalDisplayId()))) {
       if (Display::HasInternalDisplay())
         DCHECK_EQ(Display::InternalDisplayId(), state->display_id());
       Display::SetInternalDisplayId(state->display_id());

       if (state->native_mode() &&
           (!display_manager_->IsDisplayIdValid(state->display_id()) ||
            !state->current_mode())) {
         // Register the internal display info if
         // 1) If it's not already registered. It'll be treated as
         // new display in |UpdateDisplaysWith()|.
         // 2) If it's not connected, because the display info will not
         // be updated in |UpdateDisplaysWith()|, which will skips the
         // disconnected displays.
         ManagedDisplayInfo new_info =
             CreateManagedDisplayInfo(state, state->native_mode());
         display_manager_->UpdateInternalDisplay(new_info);
       }
       return;
     }
   }
 }

 ManagedDisplayInfo DisplayChangeObserver::CreateManagedDisplayInfo(
     const DisplaySnapshot* snapshot,
     const DisplayMode* mode_info) {
   std::string name = (snapshot->type() == DISPLAY_CONNECTION_TYPE_INTERNAL)
                          ? l10n_util::GetStringUTF8(IDS_DISPLAY_NAME_INTERNAL)
                          : snapshot->display_name();

   if (name.empty())
     name = l10n_util::GetStringUTF8(IDS_DISPLAY_NAME_UNKNOWN);

   const bool has_overscan = snapshot->has_overscan();
   const int64_t id = snapshot->display_id();

   ManagedDisplayInfo new_info = ManagedDisplayInfo(id, name, has_overscan);

   if (snapshot->product_code() != DisplaySnapshot::kInvalidProductCode) {
     uint16_t manufacturer_id = 0;
     uint16_t product_id = 0;
     EdidParser::SplitProductCodeInManufacturerIdAndProductId(
         snapshot->product_code(), &manufacturer_id, &product_id);
     new_info.set_manufacturer_id(
         EdidParser::ManufacturerIdToString(manufacturer_id));
     new_info.set_product_id(EdidParser::ProductIdToString(product_id));
   }
   new_info.set_year_of_manufacture(snapshot->year_of_manufacture());

   new_info.set_panel_orientation(snapshot->panel_orientation());
   new_info.set_sys_path(snapshot->sys_path());
   new_info.set_native(true);

   float device_scale_factor = 1.0f;
   // Sets dpi only if the screen size is not blacklisted.
   const float dpi = IsDisplaySizeBlackListed(snapshot->physical_size())
                         ? 0
                         : kInchInMm * mode_info->size().width() /
                               snapshot->physical_size().width();
   constexpr gfx::Size k225DisplaySizeHack(3000, 2000);

   if (snapshot->type() == DISPLAY_CONNECTION_TYPE_INTERNAL) {
     // TODO(oshima): This is a stopgap hack to deal with b/74845106.
     // Remove this hack when it's resolved.
     if (mode_info->size() == k225DisplaySizeHack)
       device_scale_factor = 2.25f;
     else if (dpi)
       device_scale_factor = FindDeviceScaleFactor(dpi);
   } else {
     ManagedDisplayMode mode;
     if (display_manager_->GetSelectedModeForDisplayId(snapshot->display_id(),
                                                       &mode)) {
       device_scale_factor = mode.device_scale_factor();
       new_info.set_native(mode.native());
     }
   }
   new_info.set_device_scale_factor(device_scale_factor);

   const gfx::Rect display_bounds(snapshot->origin(), mode_info->size());
   new_info.SetBounds(display_bounds);
   new_info.set_is_aspect_preserving_scaling(
       snapshot->is_aspect_preserving_scaling());
   if (dpi)
     new_info.set_device_dpi(dpi);
   new_info.set_color_space(snapshot->color_space());
   new_info.set_bits_per_channel(snapshot->bits_per_channel());

   new_info.set_refresh_rate(mode_info->refresh_rate());
   new_info.set_is_interlaced(mode_info->is_interlaced());

   ManagedDisplayInfo::ManagedDisplayModeList display_modes =
       (snapshot->type() == DISPLAY_CONNECTION_TYPE_INTERNAL)
           ? GetInternalManagedDisplayModeList(new_info, *snapshot)
           : GetExternalManagedDisplayModeList(*snapshot);
   new_info.SetManagedDisplayModes(display_modes);

   new_info.set_maximum_cursor_size(snapshot->maximum_cursor_size());
   return new_info;
 }

 // static
 float DisplayChangeObserver::FindDeviceScaleFactor(float dpi) {
   for (size_t i = 0; i < base::size(kThresholdTableForInternal); ++i) {
     if (dpi > kThresholdTableForInternal[i].dpi)
       return kThresholdTableForInternal[i].device_scale_factor;
   }
   return 1.0f;
 }

 }  // namespace display
	// Copyright 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.

	#include "ui/display/manager/display_change_observer.h"

	#include <algorithm>
	#include <map>
	#include <set>
	#include <string>
	#include <tuple>
	#include <utility>
	#include <vector>

	#include "base/logging.h"
	#include "base/stl_util.h"
	#include "ui/base/l10n/l10n_util.h"
	#include "ui/base/user_activity/user_activity_detector.h"
	#include "ui/display/display.h"
	#include "ui/display/display_features.h"
	#include "ui/display/display_layout.h"
	#include "ui/display/display_switches.h"
	#include "ui/display/manager/display_layout_store.h"
	#include "ui/display/manager/display_manager.h"
	#include "ui/display/manager/display_manager_utilities.h"
	#include "ui/display/manager/touch_device_manager.h"
	#include "ui/display/types/display_mode.h"
	#include "ui/display/types/display_snapshot.h"
	#include "ui/display/util/display_util.h"
	#include "ui/display/util/edid_parser.h"
	#include "ui/events/devices/device_data_manager.h"
	#include "ui/events/devices/touchscreen_device.h"
	#include "ui/strings/grit/ui_strings.h"

	namespace display {
	namespace {

	// The DPI threshold to determine the device scale factor.
	// DPI higher than \|dpi\| will use \|device_scale_factor\|.
	struct DeviceScaleFactorDPIThreshold {
	float dpi;
	float device_scale_factor;
	};

	// Update the list of zoom levels whenever a new device scale factor is added
	// here. See zoom level list in /ui/display/manager/display_util.cc
	const DeviceScaleFactorDPIThreshold kThresholdTableForInternal[] = {
	{320.f, 2.66667f}, {270.0f, 2.25f}, {230.0f, 2.0f}, {220.0f, 1.77778f},
	{180.0f, 1.6f}, {150.0f, 1.25f}, {0.0f, 1.0f},
	};

	// Returns a list of display modes for the given \|output\| that doesn't exclude
	// any mode. The returned list is sorted by size, then by refresh rate, then by
	// is_interlaced.
	ManagedDisplayInfo::ManagedDisplayModeList GetModeListWithAllRefreshRates(
	const DisplaySnapshot& output) {
	ManagedDisplayInfo::ManagedDisplayModeList display_mode_list;
	for (const auto& mode_info : output.modes()) {
	display_mode_list.emplace_back(mode_info->size(), mode_info->refresh_rate(),
	mode_info->is_interlaced(),
	output.native_mode() == mode_info.get(),
	1.0);
	}

	std::sort(
	display_mode_list.begin(), display_mode_list.end(),
	[](const ManagedDisplayMode& lhs, const ManagedDisplayMode& rhs) {
	return std::forward_as_tuple(lhs.size().width(), lhs.size().height(),
	lhs.refresh_rate(), lhs.is_interlaced()) <
	std::forward_as_tuple(rhs.size().width(), rhs.size().height(),
	rhs.refresh_rate(), rhs.is_interlaced());
	});

	return display_mode_list;
	}

	} // namespace

	// static
	ManagedDisplayInfo::ManagedDisplayModeList
	DisplayChangeObserver::GetInternalManagedDisplayModeList(
	const ManagedDisplayInfo& display_info,
	const DisplaySnapshot& output) {
	const DisplayMode* ui_native_mode = output.native_mode();
	ManagedDisplayMode native_mode(ui_native_mode->size(),
	ui_native_mode->refresh_rate(),
	ui_native_mode->is_interlaced(), true,
	display_info.device_scale_factor());
	return CreateInternalManagedDisplayModeList(native_mode);
	}

	// static
	ManagedDisplayInfo::ManagedDisplayModeList
	DisplayChangeObserver::GetExternalManagedDisplayModeList(
	const DisplaySnapshot& output) {
	if (display::features::IsListAllDisplayModesEnabled())
	return GetModeListWithAllRefreshRates(output);

	struct SizeComparator {
	constexpr bool operator()(const gfx::Size& lhs,
	const gfx::Size& rhs) const {
	return std::forward_as_tuple(lhs.width(), lhs.height()) <
	std::forward_as_tuple(rhs.width(), rhs.height());
	}
	};

	using DisplayModeMap =
	std::map<gfx::Size, ManagedDisplayMode, SizeComparator>;
	DisplayModeMap display_mode_map;

	ManagedDisplayMode native_mode;
	for (const auto& mode_info : output.modes()) {
	const gfx::Size size = mode_info->size();

	ManagedDisplayMode display_mode(
	mode_info->size(), mode_info->refresh_rate(),
	mode_info->is_interlaced(), output.native_mode() == mode_info.get(),
	1.0);
	if (display_mode.native())
	native_mode = display_mode;

	// Add the display mode if it isn't already present and override interlaced
	// display modes with non-interlaced ones. We prioritize having non
	// interlaced mode over refresh rate. A mode having lower refresh rate
	// but is not interlaced will be picked over a mode having high refresh
	// rate but is interlaced.
	auto display_mode_it = display_mode_map.find(size);
	if (display_mode_it == display_mode_map.end()) {
	display_mode_map.emplace(size, display_mode);
	} else if (display_mode_it->second.is_interlaced() &&
	!display_mode.is_interlaced()) {
	display_mode_it->second = std::move(display_mode);
	} else if (!display_mode.is_interlaced() &&
	display_mode_it->second.refresh_rate() <
	display_mode.refresh_rate()) {
	display_mode_it->second = std::move(display_mode);
	}
	}

	if (output.native_mode()) {
	const gfx::Size size = native_mode.size();

	auto it = display_mode_map.find(size);
	DCHECK(it != display_mode_map.end())
	<< "Native mode must be part of the mode list.";

	// If the native mode was replaced (e.g. by a mode with similar size but
	// higher refresh rate), we overwrite that mode with the native mode. The
	// native mode will always be chosen as the best mode for this size (see
	// DisplayConfigurator::FindDisplayModeMatchingSize()).
	if (!it->second.native())
	it->second = native_mode;
	}

	ManagedDisplayInfo::ManagedDisplayModeList display_mode_list;
	for (const auto& display_mode_pair : display_mode_map)
	display_mode_list.push_back(std::move(display_mode_pair.second));

	return display_mode_list;
	}

	DisplayChangeObserver::DisplayChangeObserver(DisplayManager* display_manager)
	: display_manager_(display_manager) {
	ui::DeviceDataManager::GetInstance()->AddObserver(this);
	}

	DisplayChangeObserver::~DisplayChangeObserver() {
	ui::DeviceDataManager::GetInstance()->RemoveObserver(this);
	}

	MultipleDisplayState DisplayChangeObserver::GetStateForDisplayIds(
	const DisplayConfigurator::DisplayStateList& display_states) {
	UpdateInternalDisplay(display_states);
	if (display_states.size() == 1)
	return MULTIPLE_DISPLAY_STATE_SINGLE;
	DisplayIdList list =
	GenerateDisplayIdList(display_states.begin(), display_states.end(),
	[](const DisplaySnapshot* display_state) {
	return display_state->display_id();
	});
	return display_manager_->ShouldSetMirrorModeOn(list)
	? MULTIPLE_DISPLAY_STATE_MULTI_MIRROR
	: MULTIPLE_DISPLAY_STATE_MULTI_EXTENDED;
	}

	bool DisplayChangeObserver::GetSelectedModeForDisplayId(
	int64_t display_id,
	ManagedDisplayMode* out_mode) const {
	return display_manager_->GetSelectedModeForDisplayId(display_id, out_mode);
	}

	void DisplayChangeObserver::OnDisplayModeChanged(
	const DisplayConfigurator::DisplayStateList& display_states) {
	UpdateInternalDisplay(display_states);

	std::vector<ManagedDisplayInfo> displays;
	for (const DisplaySnapshot* state : display_states) {
	const DisplayMode* mode_info = state->current_mode();
	if (!mode_info)
	continue;

	displays.emplace_back(CreateManagedDisplayInfo(state, mode_info));
	}

	display_manager_->touch_device_manager()->AssociateTouchscreens(
	&displays, ui::DeviceDataManager::GetInstance()->GetTouchscreenDevices());
	display_manager_->OnNativeDisplaysChanged(displays);

	// For the purposes of user activity detection, ignore synthetic mouse events
	// that are triggered by screen resizes: http://crbug.com/360634
	ui::UserActivityDetector* user_activity_detector =
	ui::UserActivityDetector::Get();
	if (user_activity_detector)
	user_activity_detector->OnDisplayPowerChanging();
	}

	void DisplayChangeObserver::OnDisplayModeChangeFailed(
	const DisplayConfigurator::DisplayStateList& displays,
	MultipleDisplayState failed_new_state) {
	// If display configuration failed during startup, simply update the display
	// manager with detected displays. If no display is detected, it will
	// create a pseudo display.
	if (display_manager_->GetNumDisplays() == 0)
	OnDisplayModeChanged(displays);
	}

	void DisplayChangeObserver::OnInputDeviceConfigurationChanged(
	uint8_t input_device_types) {
	if (input_device_types & ui::InputDeviceEventObserver::kTouchscreen) {
	// If there are no cached display snapshots, either there are no attached
	// displays or the cached snapshots have been invalidated. For the first
	// case there aren't any touchscreens to associate. For the second case,
	// the displays and touch input-devices will get associated when display
	// configuration finishes.
	const auto& cached_displays =
	display_manager_->configurator()->cached_displays();
	if (!cached_displays.empty())
	OnDisplayModeChanged(cached_displays);
	}
	}

	void DisplayChangeObserver::UpdateInternalDisplay(
	const DisplayConfigurator::DisplayStateList& display_states) {
	bool force_first_display_internal = ForceFirstDisplayInternal();

	for (auto* state : display_states) {
	if (state->type() == DISPLAY_CONNECTION_TYPE_INTERNAL \|\|
	(force_first_display_internal &&
	(!Display::HasInternalDisplay() \|\|
	state->display_id() == Display::InternalDisplayId()))) {
	if (Display::HasInternalDisplay())
	DCHECK_EQ(Display::InternalDisplayId(), state->display_id());
	Display::SetInternalDisplayId(state->display_id());

	if (state->native_mode() &&
	(!display_manager_->IsDisplayIdValid(state->display_id()) \|\|
	!state->current_mode())) {
	// Register the internal display info if
	// 1) If it's not already registered. It'll be treated as
	// new display in \|UpdateDisplaysWith()\|.
	// 2) If it's not connected, because the display info will not
	// be updated in \|UpdateDisplaysWith()\|, which will skips the
	// disconnected displays.
	ManagedDisplayInfo new_info =
	CreateManagedDisplayInfo(state, state->native_mode());
	display_manager_->UpdateInternalDisplay(new_info);
	}
	return;
	}
	}
	}

	ManagedDisplayInfo DisplayChangeObserver::CreateManagedDisplayInfo(
	const DisplaySnapshot* snapshot,
	const DisplayMode* mode_info) {
	std::string name = (snapshot->type() == DISPLAY_CONNECTION_TYPE_INTERNAL)
	? l10n_util::GetStringUTF8(IDS_DISPLAY_NAME_INTERNAL)
	: snapshot->display_name();

	if (name.empty())
	name = l10n_util::GetStringUTF8(IDS_DISPLAY_NAME_UNKNOWN);

	const bool has_overscan = snapshot->has_overscan();
	const int64_t id = snapshot->display_id();

	ManagedDisplayInfo new_info = ManagedDisplayInfo(id, name, has_overscan);

	if (snapshot->product_code() != DisplaySnapshot::kInvalidProductCode) {
	uint16_t manufacturer_id = 0;
	uint16_t product_id = 0;
	EdidParser::SplitProductCodeInManufacturerIdAndProductId(
	snapshot->product_code(), &manufacturer_id, &product_id);
	new_info.set_manufacturer_id(
	EdidParser::ManufacturerIdToString(manufacturer_id));
	new_info.set_product_id(EdidParser::ProductIdToString(product_id));
	}
	new_info.set_year_of_manufacture(snapshot->year_of_manufacture());

	new_info.set_panel_orientation(snapshot->panel_orientation());
	new_info.set_sys_path(snapshot->sys_path());
	new_info.set_native(true);

	float device_scale_factor = 1.0f;
	// Sets dpi only if the screen size is not blacklisted.
	const float dpi = IsDisplaySizeBlackListed(snapshot->physical_size())
	? 0
	: kInchInMm * mode_info->size().width() /
	snapshot->physical_size().width();
	constexpr gfx::Size k225DisplaySizeHack(3000, 2000);

	if (snapshot->type() == DISPLAY_CONNECTION_TYPE_INTERNAL) {
	// TODO(oshima): This is a stopgap hack to deal with b/74845106.
	// Remove this hack when it's resolved.
	if (mode_info->size() == k225DisplaySizeHack)
	device_scale_factor = 2.25f;
	else if (dpi)
	device_scale_factor = FindDeviceScaleFactor(dpi);
	} else {
	ManagedDisplayMode mode;
	if (display_manager_->GetSelectedModeForDisplayId(snapshot->display_id(),
	&mode)) {
	device_scale_factor = mode.device_scale_factor();
	new_info.set_native(mode.native());
	}
	}
	new_info.set_device_scale_factor(device_scale_factor);

	const gfx::Rect display_bounds(snapshot->origin(), mode_info->size());
	new_info.SetBounds(display_bounds);
	new_info.set_is_aspect_preserving_scaling(
	snapshot->is_aspect_preserving_scaling());
	if (dpi)
	new_info.set_device_dpi(dpi);
	new_info.set_color_space(snapshot->color_space());
	new_info.set_bits_per_channel(snapshot->bits_per_channel());

	new_info.set_refresh_rate(mode_info->refresh_rate());
	new_info.set_is_interlaced(mode_info->is_interlaced());

	ManagedDisplayInfo::ManagedDisplayModeList display_modes =
	(snapshot->type() == DISPLAY_CONNECTION_TYPE_INTERNAL)
	? GetInternalManagedDisplayModeList(new_info, *snapshot)
	: GetExternalManagedDisplayModeList(*snapshot);
	new_info.SetManagedDisplayModes(display_modes);

	new_info.set_maximum_cursor_size(snapshot->maximum_cursor_size());
	return new_info;
	}

	// static
	float DisplayChangeObserver::FindDeviceScaleFactor(float dpi) {
	for (size_t i = 0; i < base::size(kThresholdTableForInternal); ++i) {
	if (dpi > kThresholdTableForInternal[i].dpi)
	return kThresholdTableForInternal[i].device_scale_factor;
	}
	return 1.0f;
	}

	} // namespace display