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mutter-performance-source/src/backends/native/meta-output-kms.c
Jonas Ådahl d3abaf46a1 output-kms: Hand over fallback mode management to MetaKms 
Eventually we need MetaKmsMode for more than carrying the
drmModeModeInfo, so prepare for that by having the KMS layer create
MetaKmsMode for those as well.

Part-of: <https://gitlab.gnome.org/GNOME/mutter/-/merge_requests/1488>
2021-01-22 16:47:08 +00:00

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/* -*- mode: C; c-file-style: "gnu"; indent-tabs-mode: nil; -*- */
/*
* Copyright (C) 2013-2017 Red Hat
* Copyright (C) 2018 DisplayLink (UK) Ltd.
*
* 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/native/meta-output-kms.h"
#include <errno.h>
#include <stdlib.h>
#include <string.h>
#include "backends/meta-crtc.h"
#include "backends/native/meta-kms-connector.h"
#include "backends/native/meta-kms-device.h"
#include "backends/native/meta-kms-mode.h"
#include "backends/native/meta-kms-utils.h"
#include "backends/native/meta-crtc-kms.h"
#include "backends/native/meta-crtc-mode-kms.h"
#define SYNC_TOLERANCE 0.01 /* 1 percent */
typedef struct _MetaOutputKms
{
MetaOutput parent;
MetaKmsConnector *kms_connector;
} MetaOutputKms;
G_DEFINE_TYPE (MetaOutputKms, meta_output_kms, META_TYPE_OUTPUT)
MetaKmsConnector *
meta_output_kms_get_kms_connector (MetaOutputKms *output_kms)
{
return output_kms->kms_connector;
}
void
meta_output_kms_set_underscan (MetaOutputKms *output_kms,
MetaKmsUpdate *kms_update)
{
MetaOutput *output = META_OUTPUT (output_kms);
const MetaOutputInfo *output_info = meta_output_get_info (output);
if (!output_info->supports_underscanning)
return;
if (meta_output_is_underscanning (output))
{
MetaCrtc *crtc;
const MetaCrtcConfig *crtc_config;
const MetaCrtcModeInfo *crtc_mode_info;
uint64_t hborder, vborder;
crtc = meta_output_get_assigned_crtc (output);
crtc_config = meta_crtc_get_config (crtc);
crtc_mode_info = meta_crtc_mode_get_info (crtc_config->mode);
hborder = MIN (128, (uint64_t) round (crtc_mode_info->width * 0.05));
vborder = MIN (128, (uint64_t) round (crtc_mode_info->height * 0.05));
g_debug ("Setting underscan of connector %s to %" G_GUINT64_FORMAT " x %" G_GUINT64_FORMAT,
meta_kms_connector_get_name (output_kms->kms_connector),
hborder, vborder);
meta_kms_connector_set_underscanning (output_kms->kms_connector,
kms_update,
hborder,
vborder);
}
else
{
g_debug ("Unsetting underscan of connector %s",
meta_kms_connector_get_name (output_kms->kms_connector));
meta_kms_connector_unset_underscanning (output_kms->kms_connector,
kms_update);
}
}
uint32_t
meta_output_kms_get_connector_id (MetaOutputKms *output_kms)
{
return meta_kms_connector_get_id (output_kms->kms_connector);
}
void
meta_output_kms_set_power_save_mode (MetaOutputKms *output_kms,
uint64_t dpms_state,
MetaKmsUpdate *kms_update)
{
g_debug ("Setting DPMS state of connector %s to %" G_GUINT64_FORMAT,
meta_kms_connector_get_name (output_kms->kms_connector),
dpms_state);
meta_kms_connector_update_set_dpms_state (output_kms->kms_connector,
kms_update,
dpms_state);
}
gboolean
meta_output_kms_can_clone (MetaOutputKms *output_kms,
MetaOutputKms *other_output_kms)
{
return meta_kms_connector_can_clone (output_kms->kms_connector,
other_output_kms->kms_connector);
}
GBytes *
meta_output_kms_read_edid (MetaOutputKms *output_kms)
{
const MetaKmsConnectorState *connector_state;
GBytes *edid_data;
connector_state =
meta_kms_connector_get_current_state (output_kms->kms_connector);
edid_data = connector_state->edid_data;
if (!edid_data)
return NULL;
return g_bytes_new_from_bytes (edid_data, 0, g_bytes_get_size (edid_data));
}
static void
add_common_modes (MetaOutputInfo *output_info,
MetaGpuKms *gpu_kms)
{
const drmModeModeInfo *drm_mode;
MetaCrtcMode *crtc_mode;
GPtrArray *array;
float refresh_rate;
unsigned i;
unsigned max_hdisplay = 0;
unsigned max_vdisplay = 0;
float max_refresh_rate = 0.0;
MetaKmsDevice *kms_device;
MetaKmsModeFlag flag_filter;
GList *l;
for (i = 0; i < output_info->n_modes; i++)
{
MetaCrtcMode *crtc_mode = output_info->modes[i];
MetaCrtcModeKms *crtc_mode_kms = META_CRTC_MODE_KMS (crtc_mode);
drm_mode = meta_crtc_mode_kms_get_drm_mode (crtc_mode_kms);
refresh_rate = meta_calculate_drm_mode_refresh_rate (drm_mode);
max_hdisplay = MAX (max_hdisplay, drm_mode->hdisplay);
max_vdisplay = MAX (max_vdisplay, drm_mode->vdisplay);
max_refresh_rate = MAX (max_refresh_rate, refresh_rate);
}
max_refresh_rate = MAX (max_refresh_rate, 60.0);
max_refresh_rate *= (1 + SYNC_TOLERANCE);
kms_device = meta_gpu_kms_get_kms_device (gpu_kms);
array = g_ptr_array_new ();
if (max_hdisplay > max_vdisplay)
flag_filter = META_KMS_MODE_FLAG_FALLBACK_LANDSCAPE;
else
flag_filter = META_KMS_MODE_FLAG_FALLBACK_PORTRAIT;
for (l = meta_kms_device_get_fallback_modes (kms_device); l; l = l->next)
{
MetaKmsMode *fallback_mode = l->data;
const drmModeModeInfo *drm_mode;
if (!(meta_kms_mode_get_flags (fallback_mode) & flag_filter))
continue;
drm_mode = meta_kms_mode_get_drm_mode (fallback_mode);
refresh_rate = meta_calculate_drm_mode_refresh_rate (drm_mode);
if (drm_mode->hdisplay > max_hdisplay ||
drm_mode->vdisplay > max_vdisplay ||
refresh_rate > max_refresh_rate)
continue;
crtc_mode = meta_gpu_kms_get_mode_from_drm_mode (gpu_kms, drm_mode);
g_ptr_array_add (array, crtc_mode);
}
output_info->modes = g_renew (MetaCrtcMode *, output_info->modes,
output_info->n_modes + array->len);
memcpy (output_info->modes + output_info->n_modes, array->pdata,
array->len * sizeof (MetaCrtcMode *));
output_info->n_modes += array->len;
g_ptr_array_free (array, TRUE);
}
static int
compare_modes (const void *one,
const void *two)
{
MetaCrtcMode *crtc_mode_one = *(MetaCrtcMode **) one;
MetaCrtcMode *crtc_mode_two = *(MetaCrtcMode **) two;
const MetaCrtcModeInfo *crtc_mode_info_one =
meta_crtc_mode_get_info (crtc_mode_one);
const MetaCrtcModeInfo *crtc_mode_info_two =
meta_crtc_mode_get_info (crtc_mode_two);
if (crtc_mode_info_one->width != crtc_mode_info_two->width)
return crtc_mode_info_one->width > crtc_mode_info_two->width ? -1 : 1;
if (crtc_mode_info_one->height != crtc_mode_info_two->height)
return crtc_mode_info_one->height > crtc_mode_info_two->height ? -1 : 1;
if (crtc_mode_info_one->refresh_rate != crtc_mode_info_two->refresh_rate)
return (crtc_mode_info_one->refresh_rate > crtc_mode_info_two->refresh_rate
? -1 : 1);
return g_strcmp0 (meta_crtc_mode_get_name (crtc_mode_one),
meta_crtc_mode_get_name (crtc_mode_two));
}
static gboolean
init_output_modes (MetaOutputInfo *output_info,
MetaGpuKms *gpu_kms,
MetaKmsConnector *kms_connector,
GError **error)
{
const MetaKmsConnectorState *connector_state;
GList *l;
int i;
connector_state = meta_kms_connector_get_current_state (kms_connector);
output_info->preferred_mode = NULL;
output_info->n_modes = g_list_length (connector_state->modes);
output_info->modes = g_new0 (MetaCrtcMode *, output_info->n_modes);
for (l = connector_state->modes, i = 0; l; l = l->next, i++)
{
MetaKmsMode *kms_mode = l->data;
const drmModeModeInfo *drm_mode = meta_kms_mode_get_drm_mode (kms_mode);
MetaCrtcMode *crtc_mode;
crtc_mode = meta_gpu_kms_get_mode_from_drm_mode (gpu_kms, drm_mode);
output_info->modes[i] = crtc_mode;
if (drm_mode->type & DRM_MODE_TYPE_PREFERRED)
output_info->preferred_mode = output_info->modes[i];
}
/* Presume that if the output supports scaling, then we have
* a panel fitter capable of adjusting any mode to suit.
*/
if (connector_state->has_scaling)
add_common_modes (output_info, gpu_kms);
if (!output_info->modes)
{
g_set_error (error, G_IO_ERROR, G_IO_ERROR_FAILED,
"No modes available");
return FALSE;
}
qsort (output_info->modes, output_info->n_modes,
sizeof (MetaCrtcMode *), compare_modes);
if (!output_info->preferred_mode)
output_info->preferred_mode = output_info->modes[0];
return TRUE;
}
MetaOutputKms *
meta_output_kms_new (MetaGpuKms *gpu_kms,
MetaKmsConnector *kms_connector,
MetaOutput *old_output,
GError **error)
{
MetaGpu *gpu = META_GPU (gpu_kms);
uint32_t connector_id;
uint32_t gpu_id;
g_autoptr (MetaOutputInfo) output_info = NULL;
MetaOutput *output;
MetaOutputKms *output_kms;
const MetaKmsConnectorState *connector_state;
GArray *crtcs;
GList *l;
gpu_id = meta_gpu_kms_get_id (gpu_kms);
connector_id = meta_kms_connector_get_id (kms_connector);
output_info = meta_output_info_new ();
output_info->name = g_strdup (meta_kms_connector_get_name (kms_connector));
connector_state = meta_kms_connector_get_current_state (kms_connector);
output_info->panel_orientation_transform =
connector_state->panel_orientation_transform;
if (meta_monitor_transform_is_rotated (output_info->panel_orientation_transform))
{
output_info->width_mm = connector_state->height_mm;
output_info->height_mm = connector_state->width_mm;
}
else
{
output_info->width_mm = connector_state->width_mm;
output_info->height_mm = connector_state->height_mm;
}
if (!init_output_modes (output_info, gpu_kms, kms_connector, error))
return NULL;
crtcs = g_array_new (FALSE, FALSE, sizeof (MetaCrtc *));
for (l = meta_gpu_get_crtcs (gpu); l; l = l->next)
{
MetaCrtcKms *crtc_kms = META_CRTC_KMS (l->data);
MetaKmsCrtc *kms_crtc = meta_crtc_kms_get_kms_crtc (crtc_kms);
uint32_t crtc_idx;
crtc_idx = meta_kms_crtc_get_idx (kms_crtc);
if (connector_state->common_possible_crtcs & (1 << crtc_idx))
g_array_append_val (crtcs, crtc_kms);
}
output_info->n_possible_crtcs = crtcs->len;
output_info->possible_crtcs = (MetaCrtc **) g_array_free (crtcs, FALSE);
output_info->suggested_x = connector_state->suggested_x;
output_info->suggested_y = connector_state->suggested_y;
output_info->hotplug_mode_update = connector_state->hotplug_mode_update;
output_info->supports_underscanning =
meta_kms_connector_is_underscanning_supported (kms_connector);
meta_output_info_parse_edid (output_info, connector_state->edid_data);
output_info->connector_type = meta_kms_connector_get_connector_type (kms_connector);
output_info->tile_info = connector_state->tile_info;
output = g_object_new (META_TYPE_OUTPUT_KMS,
"id", ((uint64_t) gpu_id << 32) | connector_id,
"gpu", gpu,
"info", output_info,
NULL);
output_kms = META_OUTPUT_KMS (output);
output_kms->kms_connector = kms_connector;
if (connector_state->current_crtc_id)
{
for (l = meta_gpu_get_crtcs (gpu); l; l = l->next)
{
MetaCrtc *crtc = l->data;
if (meta_crtc_get_id (crtc) == connector_state->current_crtc_id)
{
MetaOutputAssignment output_assignment;
if (old_output)
{
output_assignment = (MetaOutputAssignment) {
.is_primary = meta_output_is_primary (old_output),
.is_presentation = meta_output_is_presentation (old_output),
};
}
else
{
output_assignment = (MetaOutputAssignment) {
.is_primary = FALSE,
.is_presentation = FALSE,
};
}
meta_output_assign_crtc (output, crtc, &output_assignment);
break;
}
}
}
else
{
meta_output_unassign_crtc (output);
}
return output_kms;
}
static void
meta_output_kms_init (MetaOutputKms *output_kms)
{
}
static void
meta_output_kms_class_init (MetaOutputKmsClass *klass)
{
}
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