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mutter-performance-source/src/backends/meta-monitor.c
Jonas Ådahl 9dda79b281 monitor-manager: Move gamma LUT manipulation API to MetaCrtc 
In practice, for KMS backend CRTC's, we cache the gamma in the monitor
manager instance, so that anyone asking gets the pending or up to date
value, instead of the potentially not up to date value if one queries
after gamma was scheduled to be updated, and before it was actually
updated.

While this is true, lets still move the API to the MetaCrtc type; the
backend specific implementation can still look up cached values from the
MetaMonitorManager, but for users, it becomes less cumbersome to not
have to go via the monitor manager.

Part-of: <https://gitlab.gnome.org/GNOME/mutter/-/merge_requests/2165>
2022-09-01 17:52:01 +02:00

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/* -*- mode: C; c-file-style: "gnu"; indent-tabs-mode: nil; -*- */
/*
* Copyright (C) 2016 Red Hat
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License as
* published by the Free Software Foundation; either version 2 of the
* License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA
* 02111-1307, USA.
*/
#include "config.h"
#include "backends/meta-monitor.h"
#include "backends/meta-backend-private.h"
#include "backends/meta-crtc.h"
#include "backends/meta-gpu.h"
#include "backends/meta-monitor-manager-private.h"
#include "backends/meta-settings-private.h"
#include "backends/meta-output.h"
#include "core/boxes-private.h"
#define SCALE_FACTORS_PER_INTEGER 4
#define SCALE_FACTORS_STEPS (1.0 / (float) SCALE_FACTORS_PER_INTEGER)
#define MINIMUM_SCALE_FACTOR 1.0f
#define MAXIMUM_SCALE_FACTOR 4.0f
#define MINIMUM_LOGICAL_AREA (800 * 480)
#define MAXIMUM_REFRESH_RATE_DIFF 0.001
typedef struct _MetaMonitorMode
{
MetaMonitor *monitor;
char *id;
MetaMonitorModeSpec spec;
MetaMonitorCrtcMode *crtc_modes;
} MetaMonitorMode;
typedef struct _MetaMonitorModeTiled
{
MetaMonitorMode parent;
gboolean is_tiled;
} MetaMonitorModeTiled;
typedef struct _MetaMonitorPrivate
{
MetaBackend *backend;
GList *outputs;
GList *modes;
GHashTable *mode_ids;
MetaMonitorMode *preferred_mode;
MetaMonitorMode *current_mode;
MetaMonitorSpec *spec;
MetaLogicalMonitor *logical_monitor;
/*
* The primary or first output for this monitor, 0 if we can't figure out.
* It can be matched to a winsys_id of a MetaOutput.
*
* This is used as an opaque token on reconfiguration when switching from
* clone to extended, to decide on what output the windows should go next
* (it's an attempt to keep windows on the same monitor, and preferably on
* the primary one).
*/
uint64_t winsys_id;
char *display_name;
} MetaMonitorPrivate;
G_DEFINE_TYPE_WITH_PRIVATE (MetaMonitor, meta_monitor, G_TYPE_OBJECT)
struct _MetaMonitorNormal
{
MetaMonitor parent;
};
G_DEFINE_TYPE (MetaMonitorNormal, meta_monitor_normal, META_TYPE_MONITOR)
struct _MetaMonitorTiled
{
MetaMonitor parent;
MetaMonitorManager *monitor_manager;
uint32_t tile_group_id;
/* The tile (0, 0) output. */
MetaOutput *origin_output;
/* The output enabled even when a non-tiled mode is used. */
MetaOutput *main_output;
};
G_DEFINE_TYPE (MetaMonitorTiled, meta_monitor_tiled, META_TYPE_MONITOR)
static void
meta_monitor_mode_free (MetaMonitorMode *mode);
MetaMonitorSpec *
meta_monitor_spec_clone (MetaMonitorSpec *monitor_spec)
{
MetaMonitorSpec *new_monitor_spec;
new_monitor_spec = g_new0 (MetaMonitorSpec, 1);
*new_monitor_spec = (MetaMonitorSpec) {
.connector = g_strdup (monitor_spec->connector),
.vendor = g_strdup (monitor_spec->vendor),
.product = g_strdup (monitor_spec->product),
.serial = g_strdup (monitor_spec->serial),
};
return new_monitor_spec;
}
guint
meta_monitor_spec_hash (gconstpointer key)
{
const MetaMonitorSpec *monitor_spec = key;
return (g_str_hash (monitor_spec->connector) +
g_str_hash (monitor_spec->vendor) +
g_str_hash (monitor_spec->product) +
g_str_hash (monitor_spec->serial));
}
gboolean
meta_monitor_spec_equals (MetaMonitorSpec *monitor_spec,
MetaMonitorSpec *other_monitor_spec)
{
return (g_str_equal (monitor_spec->connector, other_monitor_spec->connector) &&
g_str_equal (monitor_spec->vendor, other_monitor_spec->vendor) &&
g_str_equal (monitor_spec->product, other_monitor_spec->product) &&
g_str_equal (monitor_spec->serial, other_monitor_spec->serial));
}
int
meta_monitor_spec_compare (MetaMonitorSpec *monitor_spec_a,
MetaMonitorSpec *monitor_spec_b)
{
int ret;
ret = strcmp (monitor_spec_a->connector, monitor_spec_b->connector);
if (ret != 0)
return ret;
ret = strcmp (monitor_spec_a->vendor, monitor_spec_b->vendor);
if (ret != 0)
return ret;
ret = strcmp (monitor_spec_a->product, monitor_spec_b->product);
if (ret != 0)
return ret;
return strcmp (monitor_spec_a->serial, monitor_spec_b->serial);
}
void
meta_monitor_spec_free (MetaMonitorSpec *monitor_spec)
{
g_free (monitor_spec->connector);
g_free (monitor_spec->vendor);
g_free (monitor_spec->product);
g_free (monitor_spec->serial);
g_free (monitor_spec);
}
static const MetaOutputInfo *
meta_monitor_get_main_output_info (MetaMonitor *monitor)
{
MetaOutput *output = meta_monitor_get_main_output (monitor);
return meta_output_get_info (output);
}
static void
meta_monitor_generate_spec (MetaMonitor *monitor)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
const MetaOutputInfo *output_info =
meta_monitor_get_main_output_info (monitor);
MetaMonitorSpec *monitor_spec;
const char *vendor;
const char *product;
const char *serial;
vendor = output_info->vendor;
product = output_info->product;
serial = output_info->serial;
monitor_spec = g_new0 (MetaMonitorSpec, 1);
*monitor_spec = (MetaMonitorSpec) {
.connector = g_strdup (output_info->name),
.vendor = g_strdup (vendor ? vendor : "unknown"),
.product = g_strdup (product ? product : "unknown"),
.serial = g_strdup (serial ? serial : "unknown"),
};
priv->spec = monitor_spec;
}
static const double known_diagonals[] = {
12.1,
13.3,
15.6
};
static char *
diagonal_to_str (double d)
{
unsigned int i;
for (i = 0; i < G_N_ELEMENTS (known_diagonals); i++)
{
double delta;
delta = fabs(known_diagonals[i] - d);
if (delta < 0.1)
return g_strdup_printf ("%0.1lf\"", known_diagonals[i]);
}
return g_strdup_printf ("%d\"", (int) (d + 0.5));
}
static char *
meta_monitor_make_display_name (MetaMonitor *monitor)
{
MetaBackend *backend = meta_monitor_get_backend (monitor);
g_autofree char *inches = NULL;
g_autofree char *vendor_name = NULL;
const char *vendor = NULL;
const char *product_name = NULL;
int width_mm;
int height_mm;
meta_monitor_get_physical_dimensions (monitor, &width_mm, &height_mm);
if (meta_monitor_is_laptop_panel (monitor))
return g_strdup (_("Built-in display"));
if (width_mm > 0 && height_mm > 0)
{
if (!meta_monitor_has_aspect_as_size (monitor))
{
double d = sqrt (width_mm * width_mm +
height_mm * height_mm);
inches = diagonal_to_str (d / 25.4);
}
else
{
product_name = meta_monitor_get_product (monitor);
}
}
vendor = meta_monitor_get_vendor (monitor);
if (vendor)
{
vendor_name = meta_backend_get_vendor_name (backend, vendor);
if (!vendor_name)
vendor_name = g_strdup (vendor);
}
else
{
if (inches != NULL)
vendor_name = g_strdup (_("Unknown"));
else
vendor_name = g_strdup (_("Unknown Display"));
}
if (inches != NULL)
{
/**/
return g_strdup_printf (C_("This is a monitor vendor name, followed by a "
"size in inches, like 'Dell 15\"'",
"%s %s"),
vendor_name, inches);
}
else if (product_name != NULL)
{
return g_strdup_printf (C_("This is a monitor vendor name followed by "
"product/model name where size in inches "
"could not be calculated, e.g. Dell U2414H",
"%s %s"),
vendor_name, product_name);
}
else
{
return g_strdup (vendor_name);
}
}
MetaBackend *
meta_monitor_get_backend (MetaMonitor *monitor)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
return priv->backend;
}
GList *
meta_monitor_get_outputs (MetaMonitor *monitor)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
return priv->outputs;
}
MetaOutput *
meta_monitor_get_main_output (MetaMonitor *monitor)
{
return META_MONITOR_GET_CLASS (monitor)->get_main_output (monitor);
}
gboolean
meta_monitor_is_active (MetaMonitor *monitor)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
return !!priv->current_mode;
}
gboolean
meta_monitor_is_primary (MetaMonitor *monitor)
{
MetaOutput *output;
output = meta_monitor_get_main_output (monitor);
return meta_output_is_primary (output);
}
gboolean
meta_monitor_supports_underscanning (MetaMonitor *monitor)
{
const MetaOutputInfo *output_info =
meta_monitor_get_main_output_info (monitor);
return output_info->supports_underscanning;
}
gboolean
meta_monitor_supports_color_transform (MetaMonitor *monitor)
{
const MetaOutputInfo *output_info =
meta_monitor_get_main_output_info (monitor);
return output_info->supports_color_transform;
}
gboolean
meta_monitor_is_underscanning (MetaMonitor *monitor)
{
MetaOutput *output;
output = meta_monitor_get_main_output (monitor);
return meta_output_is_underscanning (output);
}
gboolean
meta_monitor_get_max_bpc (MetaMonitor *monitor,
unsigned int *max_bpc)
{
MetaOutput *output;
output = meta_monitor_get_main_output (monitor);
return meta_output_get_max_bpc (output, max_bpc);
}
gboolean
meta_monitor_is_laptop_panel (MetaMonitor *monitor)
{
const MetaOutputInfo *output_info =
meta_monitor_get_main_output_info (monitor);
switch (output_info->connector_type)
{
case META_CONNECTOR_TYPE_eDP:
case META_CONNECTOR_TYPE_LVDS:
case META_CONNECTOR_TYPE_DSI:
return TRUE;
default:
return FALSE;
}
}
gboolean
meta_monitor_is_virtual (MetaMonitor *monitor)
{
const MetaOutputInfo *output_info =
meta_monitor_get_main_output_info (monitor);
return output_info->is_virtual;
}
gboolean
meta_monitor_is_same_as (MetaMonitor *monitor,
MetaMonitor *other_monitor)
{
const MetaMonitorSpec *spec = meta_monitor_get_spec (monitor);
const MetaMonitorSpec *other_spec = meta_monitor_get_spec (other_monitor);
if ((g_strcmp0 (spec->vendor, "unknown") == 0 ||
g_strcmp0 (spec->product, "unknown") == 0 ||
g_strcmp0 (spec->serial, "unknown") == 0) &&
(g_strcmp0 (other_spec->vendor, "unknown") == 0 ||
g_strcmp0 (other_spec->product, "unknown") == 0 ||
g_strcmp0 (other_spec->serial, "unknown") == 0))
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
MetaMonitorPrivate *other_priv =
meta_monitor_get_instance_private (other_monitor);
return priv->winsys_id == other_priv->winsys_id;
}
if (g_strcmp0 (spec->vendor, other_spec->vendor) != 0)
return FALSE;
if (g_strcmp0 (spec->product, other_spec->product) != 0)
return FALSE;
if (g_strcmp0 (spec->serial, other_spec->serial) != 0)
return FALSE;
return TRUE;
}
void
meta_monitor_get_current_resolution (MetaMonitor *monitor,
int *width,
int *height)
{
MetaMonitorMode *mode = meta_monitor_get_current_mode (monitor);
*width = mode->spec.width;
*height = mode->spec.height;
}
void
meta_monitor_derive_layout (MetaMonitor *monitor,
MetaRectangle *layout)
{
META_MONITOR_GET_CLASS (monitor)->derive_layout (monitor, layout);
}
void
meta_monitor_get_physical_dimensions (MetaMonitor *monitor,
int *width_mm,
int *height_mm)
{
const MetaOutputInfo *output_info =
meta_monitor_get_main_output_info (monitor);
*width_mm = output_info->width_mm;
*height_mm = output_info->height_mm;
}
CoglSubpixelOrder
meta_monitor_get_subpixel_order (MetaMonitor *monitor)
{
const MetaOutputInfo *output_info =
meta_monitor_get_main_output_info (monitor);
return output_info->subpixel_order;
}
const char *
meta_monitor_get_connector (MetaMonitor *monitor)
{
const MetaOutputInfo *output_info =
meta_monitor_get_main_output_info (monitor);
return output_info->name;
}
const char *
meta_monitor_get_vendor (MetaMonitor *monitor)
{
const MetaOutputInfo *output_info =
meta_monitor_get_main_output_info (monitor);
return output_info->vendor;
}
const char *
meta_monitor_get_product (MetaMonitor *monitor)
{
const MetaOutputInfo *output_info =
meta_monitor_get_main_output_info (monitor);
return output_info->product;
}
const char *
meta_monitor_get_serial (MetaMonitor *monitor)
{
const MetaOutputInfo *output_info =
meta_monitor_get_main_output_info (monitor);
return output_info->serial;
}
const MetaEdidInfo *
meta_monitor_get_edid_info (MetaMonitor *monitor)
{
const MetaOutputInfo *output_info =
meta_monitor_get_main_output_info (monitor);
return output_info->edid_info;
}
const char *
meta_monitor_get_edid_checksum_md5 (MetaMonitor *monitor)
{
const MetaOutputInfo *output_info =
meta_monitor_get_main_output_info (monitor);
return output_info->edid_checksum_md5;
}
MetaConnectorType
meta_monitor_get_connector_type (MetaMonitor *monitor)
{
const MetaOutputInfo *output_info =
meta_monitor_get_main_output_info (monitor);
return output_info->connector_type;
}
MetaMonitorTransform
meta_monitor_logical_to_crtc_transform (MetaMonitor *monitor,
MetaMonitorTransform transform)
{
MetaOutput *output = meta_monitor_get_main_output (monitor);
return meta_output_logical_to_crtc_transform (output, transform);
}
MetaMonitorTransform
meta_monitor_crtc_to_logical_transform (MetaMonitor *monitor,
MetaMonitorTransform transform)
{
MetaOutput *output = meta_monitor_get_main_output (monitor);
return meta_output_crtc_to_logical_transform (output, transform);
}
static void
meta_monitor_dispose (GObject *object)
{
MetaMonitor *monitor = META_MONITOR (object);
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
if (priv->outputs)
{
g_list_foreach (priv->outputs, (GFunc) meta_output_unset_monitor, NULL);
g_list_free_full (priv->outputs, g_object_unref);
priv->outputs = NULL;
}
G_OBJECT_CLASS (meta_monitor_parent_class)->dispose (object);
}
static void
meta_monitor_finalize (GObject *object)
{
MetaMonitor *monitor = META_MONITOR (object);
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
g_hash_table_destroy (priv->mode_ids);
g_list_free_full (priv->modes, (GDestroyNotify) meta_monitor_mode_free);
meta_monitor_spec_free (priv->spec);
g_free (priv->display_name);
G_OBJECT_CLASS (meta_monitor_parent_class)->finalize (object);
}
static void
meta_monitor_init (MetaMonitor *monitor)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
priv->mode_ids = g_hash_table_new (g_str_hash, g_str_equal);
}
static void
meta_monitor_class_init (MetaMonitorClass *klass)
{
GObjectClass *object_class = G_OBJECT_CLASS (klass);
object_class->dispose = meta_monitor_dispose;
object_class->finalize = meta_monitor_finalize;
}
static char *
generate_mode_id (MetaMonitorModeSpec *monitor_mode_spec)
{
gboolean is_interlaced;
is_interlaced = !!(monitor_mode_spec->flags & META_CRTC_MODE_FLAG_INTERLACE);
return g_strdup_printf ("%dx%d%s@%.3f",
monitor_mode_spec->width,
monitor_mode_spec->height,
is_interlaced ? "i" : "",
monitor_mode_spec->refresh_rate);
}
static gboolean
meta_monitor_add_mode (MetaMonitor *monitor,
MetaMonitorMode *monitor_mode,
gboolean replace)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
MetaMonitorMode *existing_mode;
existing_mode = g_hash_table_lookup (priv->mode_ids,
meta_monitor_mode_get_id (monitor_mode));
if (existing_mode && !replace)
return FALSE;
if (existing_mode)
priv->modes = g_list_remove (priv->modes, existing_mode);
priv->modes = g_list_append (priv->modes, monitor_mode);
g_hash_table_replace (priv->mode_ids, monitor_mode->id, monitor_mode);
return TRUE;
}
static MetaMonitorModeSpec
meta_monitor_create_spec (MetaMonitor *monitor,
int width,
int height,
MetaCrtcMode *crtc_mode)
{
const MetaOutputInfo *output_info =
meta_monitor_get_main_output_info (monitor);
const MetaCrtcModeInfo *crtc_mode_info =
meta_crtc_mode_get_info (crtc_mode);
if (meta_monitor_transform_is_rotated (output_info->panel_orientation_transform))
{
int temp = width;
width = height;
height = temp;
}
return (MetaMonitorModeSpec) {
.width = width,
.height = height,
.refresh_rate = crtc_mode_info->refresh_rate,
.flags = crtc_mode_info->flags & HANDLED_CRTC_MODE_FLAGS
};
}
/**
* meta_monitor_get_gamma_lut_size:
* @monitor: The MetaMonitor instance to retrieve the size from.
*
* Get the size of the look-up tables (LUTs) for the monitor.
*
* Retrieve the size of the LUT used to implement the encoding or decoding
* transfer functions ("gamma", "degamma") for the CRTC or CRTCs that backs
* this monitor.
*
* Returns: The number of look-up table entries possible for the monitor. It is
* assumed that each CRTC of a monitor has identical gamma LUT sizes.
*/
size_t
meta_monitor_get_gamma_lut_size (MetaMonitor *monitor)
{
MetaOutput *output;
MetaCrtc *crtc;
size_t size;
output = meta_monitor_get_main_output (monitor);
crtc = meta_output_get_assigned_crtc (output);
meta_crtc_get_gamma_lut (crtc, &size, NULL, NULL, NULL);
return size;
}
typedef struct
{
uint16_t *red;
uint16_t *green;
uint16_t *blue;
size_t size;
} LutData;
static gboolean
set_gamma_lut (MetaMonitor *monitor,
MetaMonitorMode *mode,
MetaMonitorCrtcMode *monitor_crtc_mode,
gpointer user_data,
GError **error)
{
LutData *lut_data = user_data;
MetaCrtc *crtc;
crtc = meta_output_get_assigned_crtc (monitor_crtc_mode->output);
meta_crtc_set_gamma_lut (crtc,
lut_data->size,
lut_data->red,
lut_data->green,
lut_data->blue);
return TRUE;
}
/**
* meta_monitor_set_gamma_lut:
*
* Set a new gamma look-up table (LUT) for the given monitor's CRTCs.
*/
void
meta_monitor_set_gamma_lut (MetaMonitor *monitor,
uint16_t *red,
uint16_t *green,
uint16_t *blue,
size_t size)
{
MetaMonitorMode *current_mode;
LutData lut_data;
current_mode = meta_monitor_get_current_mode (monitor);
g_return_if_fail (current_mode);
lut_data = (LutData) {
.red = red,
.green = green,
.blue = blue,
.size = size,
};
meta_monitor_mode_foreach_crtc (monitor,
current_mode,
set_gamma_lut,
&lut_data,
NULL);
}
static void
meta_monitor_normal_generate_modes (MetaMonitorNormal *monitor_normal)
{
MetaMonitor *monitor = META_MONITOR (monitor_normal);
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (monitor);
MetaOutput *output;
const MetaOutputInfo *output_info;
MetaCrtcMode *preferred_mode;
MetaCrtcModeFlag preferred_mode_flags;
unsigned int i;
output = meta_monitor_get_main_output (monitor);
output_info = meta_output_get_info (output);
preferred_mode = output_info->preferred_mode;
preferred_mode_flags = meta_crtc_mode_get_info (preferred_mode)->flags;
for (i = 0; i < output_info->n_modes; i++)
{
MetaCrtcMode *crtc_mode = output_info->modes[i];
const MetaCrtcModeInfo *crtc_mode_info =
meta_crtc_mode_get_info (crtc_mode);
MetaCrtc *crtc;
MetaMonitorMode *mode;
gboolean replace;
mode = g_new0 (MetaMonitorMode, 1);
mode->monitor = monitor;
mode->spec = meta_monitor_create_spec (monitor,
crtc_mode_info->width,
crtc_mode_info->height,
crtc_mode);
mode->id = generate_mode_id (&mode->spec);
mode->crtc_modes = g_new (MetaMonitorCrtcMode, 1);
mode->crtc_modes[0] = (MetaMonitorCrtcMode) {
.output = output,
.crtc_mode = crtc_mode
};
/*
* We don't distinguish between all available mode flags, just the ones
* that are configurable. We still need to pick some mode though, so
* prefer ones that has the same set of flags as the preferred mode;
* otherwise take the first one in the list. This guarantees that the
* preferred mode is always added.
*/
replace = crtc_mode_info->flags == preferred_mode_flags;
if (!meta_monitor_add_mode (monitor, mode, replace))
{
g_assert (crtc_mode != output_info->preferred_mode);
meta_monitor_mode_free (mode);
continue;
}
if (crtc_mode == output_info->preferred_mode)
monitor_priv->preferred_mode = mode;
crtc = meta_output_get_assigned_crtc (output);
if (crtc)
{
const MetaCrtcConfig *crtc_config;
crtc_config = meta_crtc_get_config (crtc);
if (crtc_config && crtc_mode == crtc_config->mode)
monitor_priv->current_mode = mode;
}
}
}
MetaMonitorNormal *
meta_monitor_normal_new (MetaMonitorManager *monitor_manager,
MetaOutput *output)
{
MetaMonitorNormal *monitor_normal;
MetaMonitor *monitor;
MetaMonitorPrivate *monitor_priv;
monitor_normal = g_object_new (META_TYPE_MONITOR_NORMAL, NULL);
monitor = META_MONITOR (monitor_normal);
monitor_priv = meta_monitor_get_instance_private (monitor);
monitor_priv->backend = meta_monitor_manager_get_backend (monitor_manager);
monitor_priv->outputs = g_list_append (NULL, g_object_ref (output));
meta_output_set_monitor (output, monitor);
monitor_priv->winsys_id = meta_output_get_id (output);
meta_monitor_generate_spec (monitor);
meta_monitor_normal_generate_modes (monitor_normal);
monitor_priv->display_name = meta_monitor_make_display_name (monitor);
return monitor_normal;
}
static MetaOutput *
meta_monitor_normal_get_main_output (MetaMonitor *monitor)
{
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (monitor);
return monitor_priv->outputs->data;
}
static void
meta_monitor_normal_derive_layout (MetaMonitor *monitor,
MetaRectangle *layout)
{
MetaOutput *output;
MetaCrtc *crtc;
const MetaCrtcConfig *crtc_config;
output = meta_monitor_get_main_output (monitor);
crtc = meta_output_get_assigned_crtc (output);
crtc_config = meta_crtc_get_config (crtc);
g_return_if_fail (crtc_config);
meta_rectangle_from_graphene_rect (&crtc_config->layout,
META_ROUNDING_STRATEGY_ROUND,
layout);
}
static gboolean
meta_monitor_normal_get_suggested_position (MetaMonitor *monitor,
int *x,
int *y)
{
const MetaOutputInfo *output_info =
meta_monitor_get_main_output_info (monitor);
if (!output_info->hotplug_mode_update)
return FALSE;
if (output_info->suggested_x < 0 && output_info->suggested_y < 0)
return FALSE;
if (x)
*x = output_info->suggested_x;
if (y)
*y = output_info->suggested_y;
return TRUE;
}
static void
meta_monitor_normal_calculate_crtc_pos (MetaMonitor *monitor,
MetaMonitorMode *monitor_mode,
MetaOutput *output,
MetaMonitorTransform crtc_transform,
int *out_x,
int *out_y)
{
*out_x = 0;
*out_y = 0;
}
static void
meta_monitor_normal_init (MetaMonitorNormal *monitor)
{
}
static void
meta_monitor_normal_class_init (MetaMonitorNormalClass *klass)
{
MetaMonitorClass *monitor_class = META_MONITOR_CLASS (klass);
monitor_class->get_main_output = meta_monitor_normal_get_main_output;
monitor_class->derive_layout = meta_monitor_normal_derive_layout;
monitor_class->calculate_crtc_pos = meta_monitor_normal_calculate_crtc_pos;
monitor_class->get_suggested_position = meta_monitor_normal_get_suggested_position;
}
uint32_t
meta_monitor_tiled_get_tile_group_id (MetaMonitorTiled *monitor_tiled)
{
return monitor_tiled->tile_group_id;
}
gboolean
meta_monitor_get_suggested_position (MetaMonitor *monitor,
int *x,
int *y)
{
return META_MONITOR_GET_CLASS (monitor)->get_suggested_position (monitor,
x, y);
}
static void
add_tiled_monitor_outputs (MetaGpu *gpu,
MetaMonitorTiled *monitor_tiled)
{
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (META_MONITOR (monitor_tiled));
GList *outputs;
GList *l;
outputs = meta_gpu_get_outputs (gpu);
for (l = outputs; l; l = l->next)
{
MetaOutput *output = l->data;
const MetaOutputInfo *output_info = meta_output_get_info (output);
const MetaOutputInfo *origin_output_info;
if (output_info->tile_info.group_id != monitor_tiled->tile_group_id)
continue;
origin_output_info = meta_output_get_info (monitor_tiled->origin_output);
g_warn_if_fail (output_info->subpixel_order ==
origin_output_info->subpixel_order);
monitor_priv->outputs = g_list_append (monitor_priv->outputs,
g_object_ref (output));
meta_output_set_monitor (output, META_MONITOR (monitor_tiled));
}
}
static void
calculate_tile_coordinate (MetaMonitor *monitor,
MetaOutput *output,
MetaMonitorTransform crtc_transform,
int *out_x,
int *out_y)
{
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (monitor);
const MetaOutputInfo *output_info = meta_output_get_info (output);
GList *l;
int x = 0;
int y = 0;
for (l = monitor_priv->outputs; l; l = l->next)
{
const MetaOutputInfo *other_output_info = meta_output_get_info (l->data);
switch (crtc_transform)
{
case META_MONITOR_TRANSFORM_NORMAL:
case META_MONITOR_TRANSFORM_FLIPPED:
if ((other_output_info->tile_info.loc_v_tile ==
output_info->tile_info.loc_v_tile) &&
(other_output_info->tile_info.loc_h_tile <
output_info->tile_info.loc_h_tile))
x += other_output_info->tile_info.tile_w;
if ((other_output_info->tile_info.loc_h_tile ==
output_info->tile_info.loc_h_tile) &&
(other_output_info->tile_info.loc_v_tile <
output_info->tile_info.loc_v_tile))
y += other_output_info->tile_info.tile_h;
break;
case META_MONITOR_TRANSFORM_180:
case META_MONITOR_TRANSFORM_FLIPPED_180:
if ((other_output_info->tile_info.loc_v_tile ==
output_info->tile_info.loc_v_tile) &&
(other_output_info->tile_info.loc_h_tile >
output_info->tile_info.loc_h_tile))
x += other_output_info->tile_info.tile_w;
if ((other_output_info->tile_info.loc_h_tile ==
output_info->tile_info.loc_h_tile) &&
(other_output_info->tile_info.loc_v_tile >
output_info->tile_info.loc_v_tile))
y += other_output_info->tile_info.tile_h;
break;
case META_MONITOR_TRANSFORM_270:
case META_MONITOR_TRANSFORM_FLIPPED_270:
if ((other_output_info->tile_info.loc_v_tile ==
output_info->tile_info.loc_v_tile) &&
(other_output_info->tile_info.loc_h_tile >
output_info->tile_info.loc_h_tile))
y += other_output_info->tile_info.tile_w;
if ((other_output_info->tile_info.loc_h_tile ==
output_info->tile_info.loc_h_tile) &&
(other_output_info->tile_info.loc_v_tile >
output_info->tile_info.loc_v_tile))
x += other_output_info->tile_info.tile_h;
break;
case META_MONITOR_TRANSFORM_90:
case META_MONITOR_TRANSFORM_FLIPPED_90:
if ((other_output_info->tile_info.loc_v_tile ==
output_info->tile_info.loc_v_tile) &&
(other_output_info->tile_info.loc_h_tile <
output_info->tile_info.loc_h_tile))
y += other_output_info->tile_info.tile_w;
if ((other_output_info->tile_info.loc_h_tile ==
output_info->tile_info.loc_h_tile) &&
(other_output_info->tile_info.loc_v_tile <
output_info->tile_info.loc_v_tile))
x += other_output_info->tile_info.tile_h;
break;
}
}
*out_x = x;
*out_y = y;
}
static void
meta_monitor_tiled_calculate_tiled_size (MetaMonitor *monitor,
int *out_width,
int *out_height)
{
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (monitor);
GList *l;
int width;
int height;
width = 0;
height = 0;
for (l = monitor_priv->outputs; l; l = l->next)
{
const MetaOutputInfo *output_info = meta_output_get_info (l->data);
if (output_info->tile_info.loc_v_tile == 0)
width += output_info->tile_info.tile_w;
if (output_info->tile_info.loc_h_tile == 0)
height += output_info->tile_info.tile_h;
}
*out_width = width;
*out_height = height;
}
static gboolean
is_monitor_mode_assigned (MetaMonitor *monitor,
MetaMonitorMode *mode)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
GList *l;
int i;
for (l = priv->outputs, i = 0; l; l = l->next, i++)
{
MetaOutput *output = l->data;
MetaMonitorCrtcMode *monitor_crtc_mode = &mode->crtc_modes[i];
MetaCrtc *crtc;
const MetaCrtcConfig *crtc_config;
crtc = meta_output_get_assigned_crtc (output);
crtc_config = crtc ? meta_crtc_get_config (crtc) : NULL;
if (monitor_crtc_mode->crtc_mode &&
(!crtc || !crtc_config ||
crtc_config->mode != monitor_crtc_mode->crtc_mode))
return FALSE;
else if (!monitor_crtc_mode->crtc_mode && crtc)
return FALSE;
}
return TRUE;
}
static gboolean
is_crtc_mode_tiled (MetaOutput *output,
MetaCrtcMode *crtc_mode)
{
const MetaOutputInfo *output_info = meta_output_get_info (output);
const MetaCrtcModeInfo *crtc_mode_info = meta_crtc_mode_get_info (crtc_mode);
return (crtc_mode_info->width == (int) output_info->tile_info.tile_w &&
crtc_mode_info->height == (int) output_info->tile_info.tile_h);
}
static MetaCrtcMode *
find_tiled_crtc_mode (MetaOutput *output,
MetaCrtcMode *reference_crtc_mode)
{
const MetaOutputInfo *output_info = meta_output_get_info (output);
const MetaCrtcModeInfo *reference_crtc_mode_info =
meta_crtc_mode_get_info (reference_crtc_mode);
MetaCrtcMode *crtc_mode;
unsigned int i;
crtc_mode = output_info->preferred_mode;
if (is_crtc_mode_tiled (output, crtc_mode))
return crtc_mode;
for (i = 0; i < output_info->n_modes; i++)
{
const MetaCrtcModeInfo *crtc_mode_info;
crtc_mode = output_info->modes[i];
crtc_mode_info = meta_crtc_mode_get_info (crtc_mode);
if (!is_crtc_mode_tiled (output, crtc_mode))
continue;
if (crtc_mode_info->refresh_rate != reference_crtc_mode_info->refresh_rate)
continue;
if (crtc_mode_info->flags != reference_crtc_mode_info->flags)
continue;
return crtc_mode;
}
return NULL;
}
static MetaMonitorMode *
create_tiled_monitor_mode (MetaMonitorTiled *monitor_tiled,
MetaCrtcMode *reference_crtc_mode,
gboolean *out_is_preferred)
{
MetaMonitor *monitor = META_MONITOR (monitor_tiled);
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (monitor);
MetaMonitorModeTiled *mode;
int width, height;
GList *l;
unsigned int i;
gboolean is_preferred = TRUE;
mode = g_new0 (MetaMonitorModeTiled, 1);
mode->is_tiled = TRUE;
meta_monitor_tiled_calculate_tiled_size (monitor, &width, &height);
mode->parent.monitor = monitor;
mode->parent.spec =
meta_monitor_create_spec (monitor, width, height, reference_crtc_mode);
mode->parent.id = generate_mode_id (&mode->parent.spec);
mode->parent.crtc_modes = g_new0 (MetaMonitorCrtcMode,
g_list_length (monitor_priv->outputs));
for (l = monitor_priv->outputs, i = 0; l; l = l->next, i++)
{
MetaOutput *output = l->data;
const MetaOutputInfo *output_info = meta_output_get_info (output);
MetaCrtcMode *tiled_crtc_mode;
tiled_crtc_mode = find_tiled_crtc_mode (output, reference_crtc_mode);
if (!tiled_crtc_mode)
{
g_warning ("No tiled mode found on %s", meta_output_get_name (output));
meta_monitor_mode_free ((MetaMonitorMode *) mode);
return NULL;
}
mode->parent.crtc_modes[i] = (MetaMonitorCrtcMode) {
.output = output,
.crtc_mode = tiled_crtc_mode
};
is_preferred = (is_preferred &&
tiled_crtc_mode == output_info->preferred_mode);
}
*out_is_preferred = is_preferred;
return (MetaMonitorMode *) mode;
}
static void
generate_tiled_monitor_modes (MetaMonitorTiled *monitor_tiled)
{
MetaMonitor *monitor = META_MONITOR (monitor_tiled);
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (monitor);
MetaOutput *main_output;
const MetaOutputInfo *main_output_info;
GList *tiled_modes = NULL;
unsigned int i;
MetaMonitorMode *best_mode = NULL;
GList *l;
main_output = meta_monitor_get_main_output (META_MONITOR (monitor_tiled));
main_output_info = meta_output_get_info (main_output);
for (i = 0; i < main_output_info->n_modes; i++)
{
MetaCrtcMode *reference_crtc_mode = main_output_info->modes[i];
MetaMonitorMode *mode;
gboolean is_preferred;
if (!is_crtc_mode_tiled (main_output, reference_crtc_mode))
continue;
mode = create_tiled_monitor_mode (monitor_tiled, reference_crtc_mode,
&is_preferred);
if (!mode)
continue;
tiled_modes = g_list_append (tiled_modes, mode);
if (is_monitor_mode_assigned (monitor, mode))
monitor_priv->current_mode = mode;
if (is_preferred)
monitor_priv->preferred_mode = mode;
}
while ((l = tiled_modes))
{
MetaMonitorMode *mode = l->data;
tiled_modes = g_list_remove_link (tiled_modes, l);
if (!meta_monitor_add_mode (monitor, mode, FALSE))
{
meta_monitor_mode_free (mode);
continue;
}
if (!monitor_priv->preferred_mode)
{
if (!best_mode ||
mode->spec.refresh_rate > best_mode->spec.refresh_rate)
best_mode = mode;
}
}
if (best_mode)
monitor_priv->preferred_mode = best_mode;
}
static MetaMonitorMode *
create_untiled_monitor_mode (MetaMonitorTiled *monitor_tiled,
MetaOutput *main_output,
MetaCrtcMode *crtc_mode)
{
MetaMonitor *monitor = META_MONITOR (monitor_tiled);
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (monitor);
MetaMonitorModeTiled *mode;
const MetaCrtcModeInfo *crtc_mode_info;
GList *l;
int i;
if (is_crtc_mode_tiled (main_output, crtc_mode))
return NULL;
mode = g_new0 (MetaMonitorModeTiled, 1);
mode->is_tiled = FALSE;
mode->parent.monitor = monitor;
crtc_mode_info = meta_crtc_mode_get_info (crtc_mode);
mode->parent.spec = meta_monitor_create_spec (monitor,
crtc_mode_info->width,
crtc_mode_info->height,
crtc_mode);
mode->parent.id = generate_mode_id (&mode->parent.spec);
mode->parent.crtc_modes = g_new0 (MetaMonitorCrtcMode,
g_list_length (monitor_priv->outputs));
for (l = monitor_priv->outputs, i = 0; l; l = l->next, i++)
{
MetaOutput *output = l->data;
if (output == main_output)
{
mode->parent.crtc_modes[i] = (MetaMonitorCrtcMode) {
.output = output,
.crtc_mode = crtc_mode
};
}
else
{
mode->parent.crtc_modes[i] = (MetaMonitorCrtcMode) {
.output = output,
.crtc_mode = NULL
};
}
}
return &mode->parent;
}
static int
count_untiled_crtc_modes (MetaOutput *output)
{
const MetaOutputInfo *output_info = meta_output_get_info (output);
int count;
unsigned int i;
count = 0;
for (i = 0; i < output_info->n_modes; i++)
{
MetaCrtcMode *crtc_mode = output_info->modes[i];
if (!is_crtc_mode_tiled (output, crtc_mode))
count++;
}
return count;
}
static MetaOutput *
find_untiled_output (MetaMonitorTiled *monitor_tiled)
{
MetaMonitor *monitor = META_MONITOR (monitor_tiled);
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (monitor);
MetaOutput *best_output;
int best_untiled_crtc_mode_count;
GList *l;
best_output = monitor_tiled->origin_output;
best_untiled_crtc_mode_count =
count_untiled_crtc_modes (monitor_tiled->origin_output);
for (l = monitor_priv->outputs; l; l = l->next)
{
MetaOutput *output = l->data;
int untiled_crtc_mode_count;
if (output == monitor_tiled->origin_output)
continue;
untiled_crtc_mode_count = count_untiled_crtc_modes (output);
if (untiled_crtc_mode_count > best_untiled_crtc_mode_count)
{
best_untiled_crtc_mode_count = untiled_crtc_mode_count;
best_output = output;
}
}
return best_output;
}
static void
generate_untiled_monitor_modes (MetaMonitorTiled *monitor_tiled)
{
MetaMonitor *monitor = META_MONITOR (monitor_tiled);
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (monitor);
MetaOutput *main_output;
const MetaOutputInfo *main_output_info;
unsigned int i;
main_output = meta_monitor_get_main_output (monitor);
main_output_info = meta_output_get_info (main_output);
for (i = 0; i < main_output_info->n_modes; i++)
{
MetaCrtcMode *crtc_mode = main_output_info->modes[i];
MetaMonitorMode *mode;
mode = create_untiled_monitor_mode (monitor_tiled,
main_output,
crtc_mode);
if (!mode)
continue;
if (!meta_monitor_add_mode (monitor, mode, FALSE))
{
meta_monitor_mode_free (mode);
continue;
}
if (is_monitor_mode_assigned (monitor, mode))
{
g_assert (!monitor_priv->current_mode);
monitor_priv->current_mode = mode;
}
if (!monitor_priv->preferred_mode &&
crtc_mode == main_output_info->preferred_mode)
monitor_priv->preferred_mode = mode;
}
}
static MetaMonitorMode *
find_best_mode (MetaMonitor *monitor)
{
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (monitor);
MetaMonitorMode *best_mode = NULL;
GList *l;
for (l = monitor_priv->modes; l; l = l->next)
{
MetaMonitorMode *mode = l->data;
int area, best_area;
if (!best_mode)
{
best_mode = mode;
continue;
}
area = mode->spec.width * mode->spec.height;
best_area = best_mode->spec.width * best_mode->spec.height;
if (area > best_area)
{
best_mode = mode;
continue;
}
if (mode->spec.refresh_rate > best_mode->spec.refresh_rate)
{
best_mode = mode;
continue;
}
}
return best_mode;
}
static void
meta_monitor_tiled_generate_modes (MetaMonitorTiled *monitor_tiled)
{
MetaMonitor *monitor = META_MONITOR (monitor_tiled);
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (monitor);
/*
* Tiled monitors may look a bit different from each other, depending on the
* monitor itself, the driver, etc.
*
* On some, the tiled modes will be the preferred CRTC modes, and running
* untiled is done by only enabling (0, 0) tile. In this case, things are
* pretty straight forward.
*
* Other times a monitor may have some bogus mode preferred on the main tile,
* and an untiled mode preferred on the non-main tile, and there seems to be
* no guarantee that the (0, 0) tile is the one that should drive the
* non-tiled mode.
*
* To handle both these cases, the following hueristics are implemented:
*
* 1) Find all the tiled CRTC modes of the (0, 0) tile, and create tiled
* monitor modes for all tiles based on these.
* 2) If there is any tiled monitor mode combination where all CRTC modes
* are the preferred ones, that one is marked as preferred.
* 3) If there is no preferred mode determined so far, assume the tiled
* monitor mode with the highest refresh rate is preferred.
* 4) Find the tile with highest number of untiled CRTC modes available,
* assume this is the one driving the monitor in untiled mode, and
* create monitor modes for all untiled CRTC modes of that tile. If
* there is still no preferred mode, set any untiled mode as preferred
* if the CRTC mode is marked as such.
* 5) If at this point there is still no preferred mode, just pick the one
* with the highest number of pixels and highest refresh rate.
*
* Note that this ignores the preference if the preference is a non-tiled
* mode. This seems to be the case on some systems, where the user tends to
* manually set up the tiled mode anyway.
*/
generate_tiled_monitor_modes (monitor_tiled);
if (!monitor_priv->preferred_mode)
g_warning ("Tiled monitor on %s didn't have any tiled modes",
monitor_priv->spec->connector);
generate_untiled_monitor_modes (monitor_tiled);
if (!monitor_priv->preferred_mode)
{
g_warning ("Tiled monitor on %s didn't have a valid preferred mode",
monitor_priv->spec->connector);
monitor_priv->preferred_mode = find_best_mode (monitor);
}
}
MetaMonitorTiled *
meta_monitor_tiled_new (MetaMonitorManager *monitor_manager,
MetaOutput *output)
{
const MetaOutputInfo *output_info = meta_output_get_info (output);
MetaMonitorTiled *monitor_tiled;
MetaMonitor *monitor;
MetaMonitorPrivate *monitor_priv;
monitor_tiled = g_object_new (META_TYPE_MONITOR_TILED, NULL);
monitor = META_MONITOR (monitor_tiled);
monitor_priv = meta_monitor_get_instance_private (monitor);
monitor_priv->backend = meta_monitor_manager_get_backend (monitor_manager);
monitor_tiled->tile_group_id = output_info->tile_info.group_id;
monitor_priv->winsys_id = meta_output_get_id (output);
monitor_tiled->origin_output = output;
add_tiled_monitor_outputs (meta_output_get_gpu (output), monitor_tiled);
monitor_tiled->main_output = find_untiled_output (monitor_tiled);
meta_monitor_generate_spec (monitor);
monitor_tiled->monitor_manager = monitor_manager;
meta_monitor_manager_tiled_monitor_added (monitor_manager,
META_MONITOR (monitor_tiled));
meta_monitor_tiled_generate_modes (monitor_tiled);
monitor_priv->display_name = meta_monitor_make_display_name (monitor);
return monitor_tiled;
}
static MetaOutput *
meta_monitor_tiled_get_main_output (MetaMonitor *monitor)
{
MetaMonitorTiled *monitor_tiled = META_MONITOR_TILED (monitor);
return monitor_tiled->main_output;
}
static void
meta_monitor_tiled_derive_layout (MetaMonitor *monitor,
MetaRectangle *layout)
{
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (monitor);
GList *l;
float min_x, min_y, max_x, max_y;
min_x = FLT_MAX;
min_y = FLT_MAX;
max_x = 0.0;
max_y = 0.0;
for (l = monitor_priv->outputs; l; l = l->next)
{
MetaOutput *output = l->data;
MetaCrtc *crtc;
const MetaCrtcConfig *crtc_config;
const graphene_rect_t *crtc_layout;
crtc = meta_output_get_assigned_crtc (output);
if (!crtc)
continue;
crtc_config = meta_crtc_get_config (crtc);
g_return_if_fail (crtc_config);
crtc_layout = &crtc_config->layout;
min_x = MIN (crtc_layout->origin.x, min_x);
min_y = MIN (crtc_layout->origin.y, min_y);
max_x = MAX (crtc_layout->origin.x + crtc_layout->size.width, max_x);
max_y = MAX (crtc_layout->origin.y + crtc_layout->size.height, max_y);
}
*layout = (MetaRectangle) {
.x = roundf (min_x),
.y = roundf (min_y),
.width = roundf (max_x - min_x),
.height = roundf (max_y - min_y)
};
}
static gboolean
meta_monitor_tiled_get_suggested_position (MetaMonitor *monitor,
int *x,
int *y)
{
return FALSE;
}
static void
meta_monitor_tiled_calculate_crtc_pos (MetaMonitor *monitor,
MetaMonitorMode *monitor_mode,
MetaOutput *output,
MetaMonitorTransform crtc_transform,
int *out_x,
int *out_y)
{
MetaMonitorModeTiled *mode_tiled = (MetaMonitorModeTiled *) monitor_mode;
if (mode_tiled->is_tiled)
{
calculate_tile_coordinate (monitor, output, crtc_transform,
out_x, out_y);
}
else
{
*out_x = 0;
*out_y = 0;
}
}
static void
meta_monitor_tiled_finalize (GObject *object)
{
MetaMonitorTiled *monitor_tiled = META_MONITOR_TILED (object);
meta_monitor_manager_tiled_monitor_removed (monitor_tiled->monitor_manager,
META_MONITOR (monitor_tiled));
G_OBJECT_CLASS (meta_monitor_tiled_parent_class)->finalize (object);
}
static void
meta_monitor_tiled_init (MetaMonitorTiled *monitor)
{
}
static void
meta_monitor_tiled_class_init (MetaMonitorTiledClass *klass)
{
GObjectClass *object_class = G_OBJECT_CLASS (klass);
MetaMonitorClass *monitor_class = META_MONITOR_CLASS (klass);
object_class->finalize = meta_monitor_tiled_finalize;
monitor_class->get_main_output = meta_monitor_tiled_get_main_output;
monitor_class->derive_layout = meta_monitor_tiled_derive_layout;
monitor_class->calculate_crtc_pos = meta_monitor_tiled_calculate_crtc_pos;
monitor_class->get_suggested_position = meta_monitor_tiled_get_suggested_position;
}
static void
meta_monitor_mode_free (MetaMonitorMode *monitor_mode)
{
g_free (monitor_mode->id);
g_free (monitor_mode->crtc_modes);
g_free (monitor_mode);
}
MetaMonitorSpec *
meta_monitor_get_spec (MetaMonitor *monitor)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
return priv->spec;
}
MetaLogicalMonitor *
meta_monitor_get_logical_monitor (MetaMonitor *monitor)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
return priv->logical_monitor;
}
MetaMonitorMode *
meta_monitor_get_mode_from_id (MetaMonitor *monitor,
const char *monitor_mode_id)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
return g_hash_table_lookup (priv->mode_ids, monitor_mode_id);
}
gboolean
meta_monitor_mode_spec_has_similar_size (MetaMonitorModeSpec *monitor_mode_spec,
MetaMonitorModeSpec *other_monitor_mode_spec)
{
const float target_ratio = 1.0;
/* The a size difference of 15% means e.g. 4K modes matches other 4K modes,
* FHD (2K) modes other FHD modes, and HD modes other HD modes, but not each
* other.
*/
const float epsilon = 0.15;
return G_APPROX_VALUE (((float) monitor_mode_spec->width /
other_monitor_mode_spec->width) *
((float) monitor_mode_spec->height /
other_monitor_mode_spec->height),
target_ratio, epsilon);
}
static gboolean
meta_monitor_mode_spec_equals (MetaMonitorModeSpec *monitor_mode_spec,
MetaMonitorModeSpec *other_monitor_mode_spec)
{
return (monitor_mode_spec->width == other_monitor_mode_spec->width &&
monitor_mode_spec->height == other_monitor_mode_spec->height &&
ABS (monitor_mode_spec->refresh_rate -
other_monitor_mode_spec->refresh_rate) < MAXIMUM_REFRESH_RATE_DIFF &&
monitor_mode_spec->flags == other_monitor_mode_spec->flags);
}
MetaMonitorMode *
meta_monitor_get_mode_from_spec (MetaMonitor *monitor,
MetaMonitorModeSpec *monitor_mode_spec)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
GList *l;
for (l = priv->modes; l; l = l->next)
{
MetaMonitorMode *monitor_mode = l->data;
if (meta_monitor_mode_spec_equals (monitor_mode_spec,
&monitor_mode->spec))
return monitor_mode;
}
return NULL;
}
MetaMonitorMode *
meta_monitor_get_preferred_mode (MetaMonitor *monitor)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
return priv->preferred_mode;
}
MetaMonitorMode *
meta_monitor_get_current_mode (MetaMonitor *monitor)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
return priv->current_mode;
}
static gboolean
is_current_mode_known (MetaMonitor *monitor)
{
MetaOutput *output;
MetaCrtc *crtc;
output = meta_monitor_get_main_output (monitor);
crtc = meta_output_get_assigned_crtc (output);
return (meta_monitor_is_active (monitor) ==
(crtc && meta_crtc_get_config (crtc)));
}
void
meta_monitor_derive_current_mode (MetaMonitor *monitor)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
MetaMonitorMode *current_mode = NULL;
GList *l;
for (l = priv->modes; l; l = l->next)
{
MetaMonitorMode *mode = l->data;
if (is_monitor_mode_assigned (monitor, mode))
{
current_mode = mode;
break;
}
}
priv->current_mode = current_mode;
g_warn_if_fail (is_current_mode_known (monitor));
}
void
meta_monitor_set_current_mode (MetaMonitor *monitor,
MetaMonitorMode *mode)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
priv->current_mode = mode;
}
GList *
meta_monitor_get_modes (MetaMonitor *monitor)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
return priv->modes;
}
void
meta_monitor_calculate_crtc_pos (MetaMonitor *monitor,
MetaMonitorMode *monitor_mode,
MetaOutput *output,
MetaMonitorTransform crtc_transform,
int *out_x,
int *out_y)
{
META_MONITOR_GET_CLASS (monitor)->calculate_crtc_pos (monitor,
monitor_mode,
output,
crtc_transform,
out_x,
out_y);
}
/* The minimum resolution at which we turn on a window-scale of 2 */
#define HIDPI_LIMIT 192
/*
* The minimum screen height at which we turn on a window-scale of 2;
* below this there just isn't enough vertical real estate for GNOME
* apps to work, and it's better to just be tiny
*/
#define HIDPI_MIN_HEIGHT 1200
/* From http://en.wikipedia.org/wiki/4K_resolution#Resolutions_of_common_formats */
#define SMALLEST_4K_WIDTH 3656
static float
calculate_scale (MetaMonitor *monitor,
MetaMonitorMode *monitor_mode,
MetaMonitorScalesConstraint constraints)
{
int resolution_width, resolution_height;
int width_mm, height_mm;
int scale;
scale = 1.0;
meta_monitor_mode_get_resolution (monitor_mode,
&resolution_width,
&resolution_height);
if (resolution_height < HIDPI_MIN_HEIGHT)
return scale;
/* 4K TV */
switch (meta_monitor_get_connector_type (monitor))
{
case META_CONNECTOR_TYPE_HDMIA:
case META_CONNECTOR_TYPE_HDMIB:
if (resolution_width < SMALLEST_4K_WIDTH)
return scale;
break;
default:
break;
}
meta_monitor_get_physical_dimensions (monitor, &width_mm, &height_mm);
/*
* Somebody encoded the aspect ratio (16/9 or 16/10) instead of the physical
* size.
*/
if (meta_monitor_has_aspect_as_size (monitor))
return scale;
if (width_mm > 0 && height_mm > 0)
{
double dpi_x, dpi_y;
dpi_x = (double) resolution_width / (width_mm / 25.4);
dpi_y = (double) resolution_height / (height_mm / 25.4);
/*
* We don't completely trust these values so both must be high, and never
* pick higher ratio than 2 automatically.
*/
if (dpi_x > HIDPI_LIMIT && dpi_y > HIDPI_LIMIT)
scale = 2.0;
}
return scale;
}
float
meta_monitor_calculate_mode_scale (MetaMonitor *monitor,
MetaMonitorMode *monitor_mode,
MetaMonitorScalesConstraint constraints)
{
MetaBackend *backend = meta_get_backend ();
MetaSettings *settings = meta_backend_get_settings (backend);
int global_scaling_factor;
if (meta_settings_get_global_scaling_factor (settings,
&global_scaling_factor))
return global_scaling_factor;
return calculate_scale (monitor, monitor_mode, constraints);
}
static gboolean
is_logical_size_large_enough (int width,
int height)
{
return width * height >= MINIMUM_LOGICAL_AREA;
}
static gboolean
is_scale_valid_for_size (float width,
float height,
float scale)
{
if (scale < MINIMUM_SCALE_FACTOR || scale > MAXIMUM_SCALE_FACTOR)
return FALSE;
return is_logical_size_large_enough (floorf (width / scale),
floorf (height / scale));
}
gboolean
meta_monitor_mode_should_be_advertised (MetaMonitorMode *monitor_mode)
{
MetaMonitorMode *preferred_mode;
g_return_val_if_fail (monitor_mode != NULL, FALSE);
preferred_mode = meta_monitor_get_preferred_mode (monitor_mode->monitor);
if (monitor_mode->spec.width == preferred_mode->spec.width &&
monitor_mode->spec.height == preferred_mode->spec.height)
return TRUE;
return is_logical_size_large_enough (monitor_mode->spec.width,
monitor_mode->spec.height);
}
static float
get_closest_scale_factor_for_resolution (float width,
float height,
float scale,
float threshold)
{
unsigned int i, j;
float scaled_h;
float scaled_w;
float best_scale;
int base_scaled_w;
gboolean found_one;
best_scale = 0;
if (!is_scale_valid_for_size (width, height, scale))
return best_scale;
if (fmodf (width, scale) == 0.0 && fmodf (height, scale) == 0.0)
return scale;
i = 0;
found_one = FALSE;
base_scaled_w = floorf (width / scale);
do
{
for (j = 0; j < 2; j++)
{
float current_scale;
int offset = i * (j ? 1 : -1);
scaled_w = base_scaled_w + offset;
current_scale = width / scaled_w;
scaled_h = height / current_scale;
if (current_scale >= scale + threshold ||
current_scale <= scale - threshold ||
current_scale < MINIMUM_SCALE_FACTOR ||
current_scale > MAXIMUM_SCALE_FACTOR)
{
return best_scale;
}
if (floorf (scaled_h) == scaled_h)
{
found_one = TRUE;
if (fabsf (current_scale - scale) < fabsf (best_scale - scale))
best_scale = current_scale;
}
}
i++;
}
while (!found_one);
return best_scale;
}
float *
meta_monitor_calculate_supported_scales (MetaMonitor *monitor,
MetaMonitorMode *monitor_mode,
MetaMonitorScalesConstraint constraints,
int *n_supported_scales)
{
unsigned int i, j;
int width, height;
GArray *supported_scales;
supported_scales = g_array_new (FALSE, FALSE, sizeof (float));
meta_monitor_mode_get_resolution (monitor_mode, &width, &height);
for (i = floorf (MINIMUM_SCALE_FACTOR);
i <= ceilf (MAXIMUM_SCALE_FACTOR);
i++)
{
if (constraints & META_MONITOR_SCALES_CONSTRAINT_NO_FRAC)
{
if (is_scale_valid_for_size (width, height, i))
{
float scale = i;
g_array_append_val (supported_scales, scale);
}
}
else
{
float max_bound;
if (i == floorf (MINIMUM_SCALE_FACTOR) ||
i == ceilf (MAXIMUM_SCALE_FACTOR))
max_bound = SCALE_FACTORS_STEPS;
else
max_bound = SCALE_FACTORS_STEPS / 2.0;
for (j = 0; j < SCALE_FACTORS_PER_INTEGER; j++)
{
float scale;
float scale_value = i + j * SCALE_FACTORS_STEPS;
scale = get_closest_scale_factor_for_resolution (width, height,
scale_value,
max_bound);
if (scale > 0.0)
g_array_append_val (supported_scales, scale);
}
}
}
if (supported_scales->len == 0)
{
float fallback_scale;
fallback_scale = 1.0;
g_array_append_val (supported_scales, fallback_scale);
}
*n_supported_scales = supported_scales->len;
return (float *) g_array_free (supported_scales, FALSE);
}
MetaMonitorModeSpec *
meta_monitor_mode_get_spec (MetaMonitorMode *monitor_mode)
{
return &monitor_mode->spec;
}
const char *
meta_monitor_mode_get_id (MetaMonitorMode *monitor_mode)
{
return monitor_mode->id;
}
void
meta_monitor_mode_get_resolution (MetaMonitorMode *monitor_mode,
int *width,
int *height)
{
*width = monitor_mode->spec.width;
*height = monitor_mode->spec.height;
}
float
meta_monitor_mode_get_refresh_rate (MetaMonitorMode *monitor_mode)
{
return monitor_mode->spec.refresh_rate;
}
MetaCrtcModeFlag
meta_monitor_mode_get_flags (MetaMonitorMode *monitor_mode)
{
return monitor_mode->spec.flags;
}
gboolean
meta_monitor_mode_foreach_crtc (MetaMonitor *monitor,
MetaMonitorMode *mode,
MetaMonitorModeFunc func,
gpointer user_data,
GError **error)
{
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (monitor);
GList *l;
int i;
for (l = monitor_priv->outputs, i = 0; l; l = l->next, i++)
{
MetaMonitorCrtcMode *monitor_crtc_mode = &mode->crtc_modes[i];
if (!monitor_crtc_mode->crtc_mode)
continue;
if (!func (monitor, mode, monitor_crtc_mode, user_data, error))
return FALSE;
}
return TRUE;
}
gboolean
meta_monitor_mode_foreach_output (MetaMonitor *monitor,
MetaMonitorMode *mode,
MetaMonitorModeFunc func,
gpointer user_data,
GError **error)
{
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (monitor);
GList *l;
int i;
for (l = monitor_priv->outputs, i = 0; l; l = l->next, i++)
{
MetaMonitorCrtcMode *monitor_crtc_mode = &mode->crtc_modes[i];
if (!func (monitor, mode, monitor_crtc_mode, user_data, error))
return FALSE;
}
return TRUE;
}
MetaMonitorCrtcMode *
meta_monitor_get_crtc_mode_for_output (MetaMonitor *monitor,
MetaMonitorMode *mode,
MetaOutput *output)
{
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (monitor);
GList *l;
int i;
for (l = monitor_priv->outputs, i = 0; l; l = l->next, i++)
{
MetaMonitorCrtcMode *monitor_crtc_mode = &mode->crtc_modes[i];
if (monitor_crtc_mode->output == output)
return monitor_crtc_mode;
}
g_warn_if_reached ();
return NULL;
}
const char *
meta_monitor_get_display_name (MetaMonitor *monitor)
{
MetaMonitorPrivate *monitor_priv =
meta_monitor_get_instance_private (monitor);
return monitor_priv->display_name;
}
void
meta_monitor_set_logical_monitor (MetaMonitor *monitor,
MetaLogicalMonitor *logical_monitor)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
priv->logical_monitor = logical_monitor;
}
static MetaOutput *
maybe_get_privacy_screen_output (MetaMonitor *monitor)
{
MetaMonitorPrivate *priv = meta_monitor_get_instance_private (monitor);
if (priv->outputs && priv->outputs->next)
return NULL;
return meta_monitor_get_main_output (monitor);
}
MetaPrivacyScreenState
meta_monitor_get_privacy_screen_state (MetaMonitor *monitor)
{
MetaOutput *output;
output = maybe_get_privacy_screen_output (monitor);
if (!output)
return META_PRIVACY_SCREEN_UNAVAILABLE;
return meta_output_get_privacy_screen_state (output);
}
gboolean
meta_monitor_set_privacy_screen_enabled (MetaMonitor *monitor,
gboolean enabled,
GError **error)
{
MetaOutput *output;
output = maybe_get_privacy_screen_output (monitor);
if (!output)
{
g_set_error_literal (error, G_IO_ERROR, G_IO_ERROR_NOT_SUPPORTED,
"The privacy screen is not supported by this output");
return FALSE;
}
return meta_output_set_privacy_screen_enabled (output, enabled, error);
}
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