ui/base/x/x11_display_util.cc - chromium/src - Git at Google

 // Copyright 2018 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/base/x/x11_display_util.h"

 #include <dlfcn.h>

 #include <bitset>

 #include "base/bits.h"
 #include "base/compiler_specific.h"
 #include "base/logging.h"
 #include "ui/base/x/x11_util.h"
 #include "ui/display/util/display_util.h"
 #include "ui/display/util/edid_parser.h"
 #include "ui/gfx/color_space.h"
 #include "ui/gfx/geometry/matrix3_f.h"
 #include "ui/gfx/geometry/rect.h"
 #include "ui/gfx/geometry/vector3d_f.h"
 #include "ui/gfx/x/x11.h"
 #include "ui/gfx/x/x11_atom_cache.h"

 namespace ui {

 namespace {

 constexpr int kMinVersionXrandr = 103;  // Need at least xrandr version 1.3.

 typedef XRRMonitorInfo* (*XRRGetMonitors)(::Display*, Window, bool, int*);
 typedef void (*XRRFreeMonitors)(XRRMonitorInfo*);

 NO_SANITIZE("cfi-icall")
 std::map<RROutput, int> GetMonitors(int version,
                                     XDisplay* xdisplay,
                                     GLXWindow window) {
   std::map<RROutput, int> output_to_monitor;
   if (version >= 105) {
     void* xrandr_lib = dlopen(nullptr, RTLD_NOW);
     if (xrandr_lib) {
       static XRRGetMonitors XRRGetMonitors_ptr =
           reinterpret_cast<XRRGetMonitors>(dlsym(xrandr_lib, "XRRGetMonitors"));
       static XRRFreeMonitors XRRFreeMonitors_ptr =
           reinterpret_cast<XRRFreeMonitors>(
               dlsym(xrandr_lib, "XRRFreeMonitors"));
       if (XRRGetMonitors_ptr && XRRFreeMonitors_ptr) {
         int nmonitors = 0;
         XRRMonitorInfo* monitors =
             XRRGetMonitors_ptr(xdisplay, window, false, &nmonitors);
         for (int monitor = 0; monitor < nmonitors; monitor++) {
           for (int j = 0; j < monitors[monitor].noutput; j++) {
             output_to_monitor[monitors[monitor].outputs[j]] = monitor;
           }
         }
         XRRFreeMonitors_ptr(monitors);
       }
     }
   }
   return output_to_monitor;
 }

 // Sets the work area on a list of displays.  The work area for each display
 // must already be initialized to the display bounds.  At most one display out
 // of |displays| will be affected.
 void ClipWorkArea(std::vector<display::Display>* displays,
                   int64_t primary_display_index,
                   float scale) {
   XDisplay* xdisplay = gfx::GetXDisplay();
   GLXWindow x_root_window = DefaultRootWindow(xdisplay);

   std::vector<int> value;
   if (!ui::GetIntArrayProperty(x_root_window, "_NET_WORKAREA", &value) ||
       value.size() < 4) {
     return;
   }
   gfx::Rect work_area = gfx::ScaleToEnclosingRect(
       gfx::Rect(value[0], value[1], value[2], value[3]), 1.0f / scale);

   // If the work area entirely contains exactly one display, assume it's meant
   // for that display (and so do nothing).
   if (std::count_if(displays->begin(), displays->end(),
                     [&](const display::Display& display) {
                       return work_area.Contains(display.bounds());
                     }) == 1) {
     return;
   }

   // If the work area is entirely contained within exactly one display, assume
   // it's meant for that display and intersect the work area with only that
   // display.
   auto found = std::find_if(displays->begin(), displays->end(),
                             [&](const display::Display& display) {
                               return display.bounds().Contains(work_area);
                             });

   // If the work area spans multiple displays, intersect the work area with the
   // primary display, like GTK does.
   display::Display& primary =
       found == displays->end() ? (*displays)[primary_display_index] : *found;

   work_area.Intersect(primary.work_area());
   if (!work_area.IsEmpty())
     primary.set_work_area(work_area);
 }

 float GetRefreshRateFromXRRModeInfo(XRRModeInfo* modes,
                                     int num_of_mode,
                                     RRMode current_mode_id) {
   for (int i = 0; i < num_of_mode; i++) {
     XRRModeInfo mode_info = modes[i];
     if (mode_info.id != current_mode_id)
       continue;
     if (!mode_info.hTotal || !mode_info.vTotal)
       return 0;

     // Refresh Rate = Pixel Clock / (Horizontal Total * Vertical Total)
     return mode_info.dotClock /
            static_cast<float>(mode_info.hTotal * mode_info.vTotal);
   }
   return 0;
 }

 int DefaultScreenDepth(XDisplay* xdisplay) {
   return DefaultDepth(xdisplay, DefaultScreen(xdisplay));
 }

 int DefaultBitsPerComponent(XDisplay* xdisplay) {
   Visual* visual = DefaultVisual(xdisplay, DefaultScreen(xdisplay));

   // The mask fields are only valid for DirectColor and TrueColor classes.
   if (visual->c_class == DirectColor || visual->c_class == TrueColor) {
     // RGB components are packed into fixed size integers for each visual.  The
     // layout of bits in the packing is given by
     // |visual->{red,green,blue}_mask|.  Count the number of bits to get the
     // number of bits per component.
     auto bits = [](auto mask) {
       return std::bitset<sizeof(mask) * 8>{mask}.count();
     };
     size_t red_bits = bits(visual->red_mask);
     size_t green_bits = bits(visual->green_mask);
     size_t blue_bits = bits(visual->blue_mask);
     if (red_bits == green_bits && red_bits == blue_bits)
       return red_bits;
   }

   // Next, try getting the number of colormap entries per subfield.  If it's a
   // power of 2, log2 is a possible guess for the number of bits per component.
   if (base::bits::IsPowerOfTwo(visual->map_entries))
     return base::bits::Log2Ceiling(visual->map_entries);

   // |bits_per_rgb| can sometimes be unreliable (may be 11 for 30bpp visuals),
   // so only use it as a last resort.
   return visual->bits_per_rgb;
 }

 bool IsRandRAvailable() {
   int randr_version_major = 0;
   int randr_version_minor = 0;
   static bool is_randr_available = XRRQueryVersion(
       gfx::GetXDisplay(), &randr_version_major, &randr_version_minor);
   return is_randr_available;
 }

 // Get the EDID data from the |output| and stores to |edid|.
 void GetEDIDProperty(XID output, std::vector<uint8_t>* edid) {
   if (!IsRandRAvailable())
     return;

   Display* display = gfx::GetXDisplay();

   Atom edid_property = gfx::GetAtom(RR_PROPERTY_RANDR_EDID);

   bool has_edid_property = false;
   int num_properties = 0;
   gfx::XScopedPtr<Atom[]> properties(
       XRRListOutputProperties(display, output, &num_properties));
   for (int i = 0; i < num_properties; ++i) {
     if (properties[i] == edid_property) {
       has_edid_property = true;
       break;
     }
   }
   if (!has_edid_property)
     return;

   Atom actual_type;
   int actual_format;
   unsigned long bytes_after;
   unsigned long nitems = 0;
   unsigned char* prop = nullptr;
   XRRGetOutputProperty(display, output, edid_property,
                        0,                // offset
                        128,              // length
                        false,            // _delete
                        false,            // pending
                        AnyPropertyType,  // req_type
                        &actual_type, &actual_format, &nitems, &bytes_after,
                        &prop);
   DCHECK_EQ(XA_INTEGER, actual_type);
   DCHECK_EQ(8, actual_format);
   edid->assign(prop, prop + nitems);
   XFree(prop);
 }

 }  // namespace

 int GetXrandrVersion(XDisplay* xdisplay) {
   int xrandr_version = 0;
   // We only support 1.3+. There were library changes before this and we should
   // use the new interface instead of the 1.2 one.
   int randr_version_major = 0;
   int randr_version_minor = 0;
   if (XRRQueryVersion(xdisplay, &randr_version_major, &randr_version_minor)) {
     xrandr_version = randr_version_major * 100 + randr_version_minor;
   }
   return xrandr_version;
 }

 std::vector<display::Display> GetFallbackDisplayList(float scale) {
   XDisplay* display = gfx::GetXDisplay();
   ::Screen* screen = DefaultScreenOfDisplay(display);
   gfx::Size physical_size(WidthMMOfScreen(screen), HeightMMOfScreen(screen));

   int width = WidthOfScreen(screen);
   int height = HeightOfScreen(screen);
   gfx::Rect bounds_in_pixels(0, 0, width, height);
   display::Display gfx_display(0, bounds_in_pixels);

   if (!display::Display::HasForceDeviceScaleFactor() &&
       !display::IsDisplaySizeBlackListed(physical_size)) {
     DCHECK_LE(1.0f, scale);
     gfx_display.SetScaleAndBounds(scale, bounds_in_pixels);
     gfx_display.set_work_area(
         gfx::ScaleToEnclosingRect(bounds_in_pixels, 1.0f / scale));
   } else {
     scale = 1;
   }

   gfx_display.set_color_depth(DefaultScreenDepth(display));
   gfx_display.set_depth_per_component(DefaultBitsPerComponent(display));

   std::vector<display::Display> displays{gfx_display};
   ClipWorkArea(&displays, 0, scale);
   return displays;
 }

 std::vector<display::Display> BuildDisplaysFromXRandRInfo(
     int version,
     float scale,
     int64_t* primary_display_index_out) {
   DCHECK(primary_display_index_out);
   DCHECK_GE(version, kMinVersionXrandr);
   XDisplay* xdisplay = gfx::GetXDisplay();
   GLXWindow x_root_window = DefaultRootWindow(xdisplay);
   std::vector<display::Display> displays;
   gfx::XScopedPtr<
       XRRScreenResources,
       gfx::XObjectDeleter<XRRScreenResources, void, XRRFreeScreenResources>>
       resources(XRRGetScreenResourcesCurrent(xdisplay, x_root_window));
   if (!resources) {
     LOG(ERROR) << "XRandR returned no displays; falling back to root window";
     return GetFallbackDisplayList(scale);
   }

   const int depth = DefaultScreenDepth(xdisplay);
   const int bits_per_component = DefaultBitsPerComponent(xdisplay);

   std::map<RROutput, int> output_to_monitor =
       GetMonitors(version, xdisplay, x_root_window);
   *primary_display_index_out = 0;
   RROutput primary_display_id = XRRGetOutputPrimary(xdisplay, x_root_window);

   int explicit_primary_display_index = -1;
   int monitor_order_primary_display_index = -1;

   // As per-display scale factor is not supported right now,
   // the X11 root window's scale factor is always used.
   for (int i = 0; i < resources->noutput; ++i) {
     RROutput output_id = resources->outputs[i];
     gfx::XScopedPtr<XRROutputInfo,
                     gfx::XObjectDeleter<XRROutputInfo, void, XRRFreeOutputInfo>>
         output_info(XRRGetOutputInfo(xdisplay, resources.get(), output_id));

     // XRRGetOutputInfo returns null in some cases: https://crbug.com/921490
     if (!output_info)
       continue;

     bool is_connected = (output_info->connection == RR_Connected);
     if (!is_connected)
       continue;

     bool is_primary_display = (output_id == primary_display_id);

     if (output_info->crtc) {
       gfx::XScopedPtr<XRRCrtcInfo,
                       gfx::XObjectDeleter<XRRCrtcInfo, void, XRRFreeCrtcInfo>>
           crtc(XRRGetCrtcInfo(xdisplay, resources.get(), output_info->crtc));

       std::vector<uint8_t> edid_bytes;
       GetEDIDProperty(output_id, &edid_bytes);
       display::EdidParser edid_parser(edid_bytes);
       int64_t display_id = edid_parser.GetDisplayId(output_id);
       // It isn't ideal, but if we can't parse the EDID data, fall back on the
       // display number.
       if (!display_id)
         display_id = i;

       gfx::Rect crtc_bounds(crtc->x, crtc->y, crtc->width, crtc->height);
       display::Display display(display_id, crtc_bounds);

       if (!display::Display::HasForceDeviceScaleFactor()) {
         display.SetScaleAndBounds(scale, crtc_bounds);
         display.set_work_area(
             gfx::ScaleToEnclosingRect(crtc_bounds, 1.0f / scale));
       }

       switch (crtc->rotation) {
         case RR_Rotate_0:
           display.set_rotation(display::Display::ROTATE_0);
           break;
         case RR_Rotate_90:
           display.set_rotation(display::Display::ROTATE_90);
           break;
         case RR_Rotate_180:
           display.set_rotation(display::Display::ROTATE_180);
           break;
         case RR_Rotate_270:
           display.set_rotation(display::Display::ROTATE_270);
           break;
       }

       if (is_primary_display)
         explicit_primary_display_index = displays.size();

       auto monitor_iter = output_to_monitor.find(output_id);
       if (monitor_iter != output_to_monitor.end() && monitor_iter->second == 0)
         monitor_order_primary_display_index = displays.size();

       if (!display::Display::HasForceDisplayColorProfile()) {
         gfx::ICCProfile icc_profile = ui::GetICCProfileForMonitor(
             monitor_iter == output_to_monitor.end() ? 0 : monitor_iter->second);
         icc_profile.HistogramDisplay(display.id());
         gfx::ColorSpace color_space = icc_profile.GetPrimariesOnlyColorSpace();

         // Most folks do not have an ICC profile set up, but we still want to
         // detect if a display has a wide color gamut so that HDR videos can be
         // enabled.  Only do this if |bits_per_component| > 8 or else SDR
         // screens may have washed out colors.
         if (bits_per_component > 8 && !color_space.IsValid())
           color_space = display::GetColorSpaceFromEdid(edid_parser);

         display.set_color_spaces(
             gfx::DisplayColorSpaces(color_space, gfx::BufferFormat::BGRA_8888));
       }

       display.set_color_depth(depth);
       display.set_depth_per_component(bits_per_component);

       // Set monitor refresh rate
       int refresh_rate = static_cast<int>(GetRefreshRateFromXRRModeInfo(
           resources->modes, resources->nmode, crtc->mode));
       display.set_display_frequency(refresh_rate);

       displays.push_back(display);
     }
   }

   if (explicit_primary_display_index != -1) {
     *primary_display_index_out = explicit_primary_display_index;
   } else if (monitor_order_primary_display_index != -1) {
     *primary_display_index_out = monitor_order_primary_display_index;
   }

   if (displays.empty())
     return GetFallbackDisplayList(scale);

   ClipWorkArea(&displays, *primary_display_index_out, scale);
   return displays;
 }

 base::TimeDelta GetPrimaryDisplayRefreshIntervalFromXrandr(Display* display) {
   constexpr base::TimeDelta kDefaultInterval =
       base::TimeDelta::FromSecondsD(1. / 60);
   GLXWindow root = DefaultRootWindow(display);
   gfx::XScopedPtr<
       XRRScreenResources,
       gfx::XObjectDeleter<XRRScreenResources, void, XRRFreeScreenResources>>
       resources(XRRGetScreenResourcesCurrent(display, root));
   if (!resources)
     return kDefaultInterval;
   // TODO(crbug.com/726842): It might make sense here to pick the output that
   // the window is on. On the other hand, if compositing is enabled, all drawing
   // might be synced to the primary output anyway. Needs investigation.
   RROutput primary_output = XRRGetOutputPrimary(display, root);
   bool disconnected_primary = false;
   for (int i = 0; i < resources->noutput; i++) {
     if (!disconnected_primary && resources->outputs[i] != primary_output)
       continue;

     gfx::XScopedPtr<XRROutputInfo,
                     gfx::XObjectDeleter<XRROutputInfo, void, XRRFreeOutputInfo>>
         output_info(XRRGetOutputInfo(display, resources.get(), primary_output));
     if (!output_info)
       continue;

     if (output_info->connection != RR_Connected) {
       // If the primary monitor is disconnected, then start over and choose the
       // first connected monitor instead.
       if (!disconnected_primary) {
         disconnected_primary = true;
         i = -1;
       }
       continue;
     }
     gfx::XScopedPtr<XRRCrtcInfo,
                     gfx::XObjectDeleter<XRRCrtcInfo, void, XRRFreeCrtcInfo>>
         crtc(XRRGetCrtcInfo(display, resources.get(), output_info->crtc));
     if (!crtc)
       continue;
     float refresh_rate = GetRefreshRateFromXRRModeInfo(
         resources->modes, resources->nmode, crtc->mode);
     if (refresh_rate == 0)
       continue;

     return base::TimeDelta::FromSecondsD(1. / refresh_rate);
   }
   return kDefaultInterval;
 }

 }  // namespace ui
	// Copyright 2018 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/base/x/x11_display_util.h"

	#include <dlfcn.h>

	#include <bitset>

	#include "base/bits.h"
	#include "base/compiler_specific.h"
	#include "base/logging.h"
	#include "ui/base/x/x11_util.h"
	#include "ui/display/util/display_util.h"
	#include "ui/display/util/edid_parser.h"
	#include "ui/gfx/color_space.h"
	#include "ui/gfx/geometry/matrix3_f.h"
	#include "ui/gfx/geometry/rect.h"
	#include "ui/gfx/geometry/vector3d_f.h"
	#include "ui/gfx/x/x11.h"
	#include "ui/gfx/x/x11_atom_cache.h"

	namespace ui {

	namespace {

	constexpr int kMinVersionXrandr = 103; // Need at least xrandr version 1.3.

	typedef XRRMonitorInfo* (XRRGetMonitors)(::Display, Window, bool, int*);
	typedef void (XRRFreeMonitors)(XRRMonitorInfo);

	NO_SANITIZE("cfi-icall")
	std::map<RROutput, int> GetMonitors(int version,
	XDisplay* xdisplay,
	GLXWindow window) {
	std::map<RROutput, int> output_to_monitor;
	if (version >= 105) {
	void* xrandr_lib = dlopen(nullptr, RTLD_NOW);
	if (xrandr_lib) {
	static XRRGetMonitors XRRGetMonitors_ptr =
	reinterpret_cast<XRRGetMonitors>(dlsym(xrandr_lib, "XRRGetMonitors"));
	static XRRFreeMonitors XRRFreeMonitors_ptr =
	reinterpret_cast<XRRFreeMonitors>(
	dlsym(xrandr_lib, "XRRFreeMonitors"));
	if (XRRGetMonitors_ptr && XRRFreeMonitors_ptr) {
	int nmonitors = 0;
	XRRMonitorInfo* monitors =
	XRRGetMonitors_ptr(xdisplay, window, false, &nmonitors);
	for (int monitor = 0; monitor < nmonitors; monitor++) {
	for (int j = 0; j < monitors[monitor].noutput; j++) {
	output_to_monitor[monitors[monitor].outputs[j]] = monitor;
	}
	}
	XRRFreeMonitors_ptr(monitors);
	}
	}
	}
	return output_to_monitor;
	}

	// Sets the work area on a list of displays. The work area for each display
	// must already be initialized to the display bounds. At most one display out
	// of \|displays\| will be affected.
	void ClipWorkArea(std::vector<display::Display>* displays,
	int64_t primary_display_index,
	float scale) {
	XDisplay* xdisplay = gfx::GetXDisplay();
	GLXWindow x_root_window = DefaultRootWindow(xdisplay);

	std::vector<int> value;
	if (!ui::GetIntArrayProperty(x_root_window, "_NET_WORKAREA", &value) \|\|
	value.size() < 4) {
	return;
	}
	gfx::Rect work_area = gfx::ScaleToEnclosingRect(
	gfx::Rect(value[0], value[1], value[2], value[3]), 1.0f / scale);

	// If the work area entirely contains exactly one display, assume it's meant
	// for that display (and so do nothing).
	if (std::count_if(displays->begin(), displays->end(),
	[&](const display::Display& display) {
	return work_area.Contains(display.bounds());
	}) == 1) {
	return;
	}

	// If the work area is entirely contained within exactly one display, assume
	// it's meant for that display and intersect the work area with only that
	// display.
	auto found = std::find_if(displays->begin(), displays->end(),
	[&](const display::Display& display) {
	return display.bounds().Contains(work_area);
	});

	// If the work area spans multiple displays, intersect the work area with the
	// primary display, like GTK does.
	display::Display& primary =
	found == displays->end() ? (displays)[primary_display_index] : found;

	work_area.Intersect(primary.work_area());
	if (!work_area.IsEmpty())
	primary.set_work_area(work_area);
	}

	float GetRefreshRateFromXRRModeInfo(XRRModeInfo* modes,
	int num_of_mode,
	RRMode current_mode_id) {
	for (int i = 0; i < num_of_mode; i++) {
	XRRModeInfo mode_info = modes[i];
	if (mode_info.id != current_mode_id)
	continue;
	if (!mode_info.hTotal \|\| !mode_info.vTotal)
	return 0;

	// Refresh Rate = Pixel Clock / (Horizontal Total * Vertical Total)
	return mode_info.dotClock /
	static_cast<float>(mode_info.hTotal * mode_info.vTotal);
	}
	return 0;
	}

	int DefaultScreenDepth(XDisplay* xdisplay) {
	return DefaultDepth(xdisplay, DefaultScreen(xdisplay));
	}

	int DefaultBitsPerComponent(XDisplay* xdisplay) {
	Visual* visual = DefaultVisual(xdisplay, DefaultScreen(xdisplay));

	// The mask fields are only valid for DirectColor and TrueColor classes.
	if (visual->c_class == DirectColor \|\| visual->c_class == TrueColor) {
	// RGB components are packed into fixed size integers for each visual. The
	// layout of bits in the packing is given by
	// \|visual->{red,green,blue}_mask\|. Count the number of bits to get the
	// number of bits per component.
	auto bits = [](auto mask) {
	return std::bitset<sizeof(mask) * 8>{mask}.count();
	};
	size_t red_bits = bits(visual->red_mask);
	size_t green_bits = bits(visual->green_mask);
	size_t blue_bits = bits(visual->blue_mask);
	if (red_bits == green_bits && red_bits == blue_bits)
	return red_bits;
	}

	// Next, try getting the number of colormap entries per subfield. If it's a
	// power of 2, log2 is a possible guess for the number of bits per component.
	if (base::bits::IsPowerOfTwo(visual->map_entries))
	return base::bits::Log2Ceiling(visual->map_entries);

	// \|bits_per_rgb\| can sometimes be unreliable (may be 11 for 30bpp visuals),
	// so only use it as a last resort.
	return visual->bits_per_rgb;
	}

	bool IsRandRAvailable() {
	int randr_version_major = 0;
	int randr_version_minor = 0;
	static bool is_randr_available = XRRQueryVersion(
	gfx::GetXDisplay(), &randr_version_major, &randr_version_minor);
	return is_randr_available;
	}

	// Get the EDID data from the \|output\| and stores to \|edid\|.
	void GetEDIDProperty(XID output, std::vector<uint8_t>* edid) {
	if (!IsRandRAvailable())
	return;

	Display* display = gfx::GetXDisplay();

	Atom edid_property = gfx::GetAtom(RR_PROPERTY_RANDR_EDID);

	bool has_edid_property = false;
	int num_properties = 0;
	gfx::XScopedPtr<Atom[]> properties(
	XRRListOutputProperties(display, output, &num_properties));
	for (int i = 0; i < num_properties; ++i) {
	if (properties[i] == edid_property) {
	has_edid_property = true;
	break;
	}
	}
	if (!has_edid_property)
	return;

	Atom actual_type;
	int actual_format;
	unsigned long bytes_after;
	unsigned long nitems = 0;
	unsigned char* prop = nullptr;
	XRRGetOutputProperty(display, output, edid_property,
	0, // offset
	128, // length
	false, // _delete
	false, // pending
	AnyPropertyType, // req_type
	&actual_type, &actual_format, &nitems, &bytes_after,
	&prop);
	DCHECK_EQ(XA_INTEGER, actual_type);
	DCHECK_EQ(8, actual_format);
	edid->assign(prop, prop + nitems);
	XFree(prop);
	}

	} // namespace

	int GetXrandrVersion(XDisplay* xdisplay) {
	int xrandr_version = 0;
	// We only support 1.3+. There were library changes before this and we should
	// use the new interface instead of the 1.2 one.
	int randr_version_major = 0;
	int randr_version_minor = 0;
	if (XRRQueryVersion(xdisplay, &randr_version_major, &randr_version_minor)) {
	xrandr_version = randr_version_major * 100 + randr_version_minor;
	}
	return xrandr_version;
	}

	std::vector<display::Display> GetFallbackDisplayList(float scale) {
	XDisplay* display = gfx::GetXDisplay();
	::Screen* screen = DefaultScreenOfDisplay(display);
	gfx::Size physical_size(WidthMMOfScreen(screen), HeightMMOfScreen(screen));

	int width = WidthOfScreen(screen);
	int height = HeightOfScreen(screen);
	gfx::Rect bounds_in_pixels(0, 0, width, height);
	display::Display gfx_display(0, bounds_in_pixels);

	if (!display::Display::HasForceDeviceScaleFactor() &&
	!display::IsDisplaySizeBlackListed(physical_size)) {
	DCHECK_LE(1.0f, scale);
	gfx_display.SetScaleAndBounds(scale, bounds_in_pixels);
	gfx_display.set_work_area(
	gfx::ScaleToEnclosingRect(bounds_in_pixels, 1.0f / scale));
	} else {
	scale = 1;
	}

	gfx_display.set_color_depth(DefaultScreenDepth(display));
	gfx_display.set_depth_per_component(DefaultBitsPerComponent(display));

	std::vector<display::Display> displays{gfx_display};
	ClipWorkArea(&displays, 0, scale);
	return displays;
	}

	std::vector<display::Display> BuildDisplaysFromXRandRInfo(
	int version,
	float scale,
	int64_t* primary_display_index_out) {
	DCHECK(primary_display_index_out);
	DCHECK_GE(version, kMinVersionXrandr);
	XDisplay* xdisplay = gfx::GetXDisplay();
	GLXWindow x_root_window = DefaultRootWindow(xdisplay);
	std::vector<display::Display> displays;
	gfx::XScopedPtr<
	XRRScreenResources,
	gfx::XObjectDeleter<XRRScreenResources, void, XRRFreeScreenResources>>
	resources(XRRGetScreenResourcesCurrent(xdisplay, x_root_window));
	if (!resources) {
	LOG(ERROR) << "XRandR returned no displays; falling back to root window";
	return GetFallbackDisplayList(scale);
	}

	const int depth = DefaultScreenDepth(xdisplay);
	const int bits_per_component = DefaultBitsPerComponent(xdisplay);

	std::map<RROutput, int> output_to_monitor =
	GetMonitors(version, xdisplay, x_root_window);
	*primary_display_index_out = 0;
	RROutput primary_display_id = XRRGetOutputPrimary(xdisplay, x_root_window);

	int explicit_primary_display_index = -1;
	int monitor_order_primary_display_index = -1;

	// As per-display scale factor is not supported right now,
	// the X11 root window's scale factor is always used.
	for (int i = 0; i < resources->noutput; ++i) {
	RROutput output_id = resources->outputs[i];
	gfx::XScopedPtr<XRROutputInfo,
	gfx::XObjectDeleter<XRROutputInfo, void, XRRFreeOutputInfo>>
	output_info(XRRGetOutputInfo(xdisplay, resources.get(), output_id));

	// XRRGetOutputInfo returns null in some cases: https://crbug.com/921490
	if (!output_info)
	continue;

	bool is_connected = (output_info->connection == RR_Connected);
	if (!is_connected)
	continue;

	bool is_primary_display = (output_id == primary_display_id);

	if (output_info->crtc) {
	gfx::XScopedPtr<XRRCrtcInfo,
	gfx::XObjectDeleter<XRRCrtcInfo, void, XRRFreeCrtcInfo>>
	crtc(XRRGetCrtcInfo(xdisplay, resources.get(), output_info->crtc));

	std::vector<uint8_t> edid_bytes;
	GetEDIDProperty(output_id, &edid_bytes);
	display::EdidParser edid_parser(edid_bytes);
	int64_t display_id = edid_parser.GetDisplayId(output_id);
	// It isn't ideal, but if we can't parse the EDID data, fall back on the
	// display number.
	if (!display_id)
	display_id = i;

	gfx::Rect crtc_bounds(crtc->x, crtc->y, crtc->width, crtc->height);
	display::Display display(display_id, crtc_bounds);

	if (!display::Display::HasForceDeviceScaleFactor()) {
	display.SetScaleAndBounds(scale, crtc_bounds);
	display.set_work_area(
	gfx::ScaleToEnclosingRect(crtc_bounds, 1.0f / scale));
	}

	switch (crtc->rotation) {
	case RR_Rotate_0:
	display.set_rotation(display::Display::ROTATE_0);
	break;
	case RR_Rotate_90:
	display.set_rotation(display::Display::ROTATE_90);
	break;
	case RR_Rotate_180:
	display.set_rotation(display::Display::ROTATE_180);
	break;
	case RR_Rotate_270:
	display.set_rotation(display::Display::ROTATE_270);
	break;
	}

	if (is_primary_display)
	explicit_primary_display_index = displays.size();

	auto monitor_iter = output_to_monitor.find(output_id);
	if (monitor_iter != output_to_monitor.end() && monitor_iter->second == 0)
	monitor_order_primary_display_index = displays.size();

	if (!display::Display::HasForceDisplayColorProfile()) {
	gfx::ICCProfile icc_profile = ui::GetICCProfileForMonitor(
	monitor_iter == output_to_monitor.end() ? 0 : monitor_iter->second);
	icc_profile.HistogramDisplay(display.id());
	gfx::ColorSpace color_space = icc_profile.GetPrimariesOnlyColorSpace();

	// Most folks do not have an ICC profile set up, but we still want to
	// detect if a display has a wide color gamut so that HDR videos can be
	// enabled. Only do this if \|bits_per_component\| > 8 or else SDR
	// screens may have washed out colors.
	if (bits_per_component > 8 && !color_space.IsValid())
	color_space = display::GetColorSpaceFromEdid(edid_parser);

	display.set_color_spaces(
	gfx::DisplayColorSpaces(color_space, gfx::BufferFormat::BGRA_8888));
	}

	display.set_color_depth(depth);
	display.set_depth_per_component(bits_per_component);

	// Set monitor refresh rate
	int refresh_rate = static_cast<int>(GetRefreshRateFromXRRModeInfo(
	resources->modes, resources->nmode, crtc->mode));
	display.set_display_frequency(refresh_rate);

	displays.push_back(display);
	}
	}

	if (explicit_primary_display_index != -1) {
	*primary_display_index_out = explicit_primary_display_index;
	} else if (monitor_order_primary_display_index != -1) {
	*primary_display_index_out = monitor_order_primary_display_index;
	}

	if (displays.empty())
	return GetFallbackDisplayList(scale);

	ClipWorkArea(&displays, *primary_display_index_out, scale);
	return displays;
	}

	base::TimeDelta GetPrimaryDisplayRefreshIntervalFromXrandr(Display* display) {
	constexpr base::TimeDelta kDefaultInterval =
	base::TimeDelta::FromSecondsD(1. / 60);
	GLXWindow root = DefaultRootWindow(display);
	gfx::XScopedPtr<
	XRRScreenResources,
	gfx::XObjectDeleter<XRRScreenResources, void, XRRFreeScreenResources>>
	resources(XRRGetScreenResourcesCurrent(display, root));
	if (!resources)
	return kDefaultInterval;
	// TODO(crbug.com/726842): It might make sense here to pick the output that
	// the window is on. On the other hand, if compositing is enabled, all drawing
	// might be synced to the primary output anyway. Needs investigation.
	RROutput primary_output = XRRGetOutputPrimary(display, root);
	bool disconnected_primary = false;
	for (int i = 0; i < resources->noutput; i++) {
	if (!disconnected_primary && resources->outputs[i] != primary_output)
	continue;

	gfx::XScopedPtr<XRROutputInfo,
	gfx::XObjectDeleter<XRROutputInfo, void, XRRFreeOutputInfo>>
	output_info(XRRGetOutputInfo(display, resources.get(), primary_output));
	if (!output_info)
	continue;

	if (output_info->connection != RR_Connected) {
	// If the primary monitor is disconnected, then start over and choose the
	// first connected monitor instead.
	if (!disconnected_primary) {
	disconnected_primary = true;
	i = -1;
	}
	continue;
	}
	gfx::XScopedPtr<XRRCrtcInfo,
	gfx::XObjectDeleter<XRRCrtcInfo, void, XRRFreeCrtcInfo>>
	crtc(XRRGetCrtcInfo(display, resources.get(), output_info->crtc));
	if (!crtc)
	continue;
	float refresh_rate = GetRefreshRateFromXRRModeInfo(
	resources->modes, resources->nmode, crtc->mode);
	if (refresh_rate == 0)
	continue;

	return base::TimeDelta::FromSecondsD(1. / refresh_rate);
	}
	return kDefaultInterval;
	}

	} // namespace ui