mutter/src/backends/native/meta-output-kms.c

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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-update.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 */
struct _MetaOutputKms
{
MetaOutputNative parent;
MetaKmsConnector *kms_connector;
};
G_DEFINE_TYPE (MetaOutputKms, meta_output_kms, META_TYPE_OUTPUT_NATIVE)
backend/native: Add and use transactional KMS API This commit introduces, and makes use of, a transactional API used for setting up KMS state, later to be applied, potentially atomically. From an API point of view, so is always the case, but in the current implementation, it still uses legacy drmMode* API to apply the state non-atomically. The API consists of various buliding blocks: * MetaKmsUpdate - a set of configuration changes, the higher level handle for handing over configuration to the impl backend. It's used to set mode, assign framebuffers to planes, queue page flips and set connector properties. * MetaKmsPlaneAssignment - the assignment of a framebuffer to a plane. Currently used to map a framebuffer to the primary plane of a CRTC. In the legacy KMS implementation, the plane assignment is used to derive the framebuffer used for mode setting and page flipping. This also means various high level changes: State, excluding configuring the cursor plane and creating/destroying DRM framebuffer handles, are applied in the end of a clutter frame, in one go. From an API point of view, this is done atomically, but as mentioned, only the non-atomic implementation exists so far. From MetaRendererNative's point of view, a page flip now initially always succeeds; the handling of EBUSY errors are done asynchronously in the MetaKmsImpl backend (still by retrying at refresh rate, but postponing flip callbacks instead of manipulating the frame clock). Handling of falling back to mode setting instead of page flipping is notified after the fact by a more precise page flip feedback API. EGLStream based page flipping relies on the impl backend not being atomic, as the page flipping is done in the EGLStream backend (e.g. nvidia driver). It uses a 'custom' page flip queueing method, keeping the EGLStream logic inside meta-renderer-native.c. Page flip handling is moved to meta-kms-impl-device.c from meta-gpu-kms.c. It goes via an extra idle callback before reaching meta-renderer-native.c to make sure callbacks are invoked outside of the impl context. While dummy power save page flipping is kept in meta-renderer-native.c, the EBUSY handling is moved to meta-kms-impl-simple.c. Instead of freezing the frame clock, actual page flip callbacks are postponed until all EBUSY retries have either succeeded or failed due to some other error than EBUSY. This effectively inhibits new frames to be drawn, meaning we won't stall waiting on the file descriptor for pending page flips. https://gitlab.gnome.org/GNOME/mutter/issues/548 https://gitlab.gnome.org/GNOME/mutter/merge_requests/525
2019-04-04 16:36:41 -04:00
MetaKmsConnector *
meta_output_kms_get_kms_connector (MetaOutputKms *output_kms)
backend/native: Add and use transactional KMS API This commit introduces, and makes use of, a transactional API used for setting up KMS state, later to be applied, potentially atomically. From an API point of view, so is always the case, but in the current implementation, it still uses legacy drmMode* API to apply the state non-atomically. The API consists of various buliding blocks: * MetaKmsUpdate - a set of configuration changes, the higher level handle for handing over configuration to the impl backend. It's used to set mode, assign framebuffers to planes, queue page flips and set connector properties. * MetaKmsPlaneAssignment - the assignment of a framebuffer to a plane. Currently used to map a framebuffer to the primary plane of a CRTC. In the legacy KMS implementation, the plane assignment is used to derive the framebuffer used for mode setting and page flipping. This also means various high level changes: State, excluding configuring the cursor plane and creating/destroying DRM framebuffer handles, are applied in the end of a clutter frame, in one go. From an API point of view, this is done atomically, but as mentioned, only the non-atomic implementation exists so far. From MetaRendererNative's point of view, a page flip now initially always succeeds; the handling of EBUSY errors are done asynchronously in the MetaKmsImpl backend (still by retrying at refresh rate, but postponing flip callbacks instead of manipulating the frame clock). Handling of falling back to mode setting instead of page flipping is notified after the fact by a more precise page flip feedback API. EGLStream based page flipping relies on the impl backend not being atomic, as the page flipping is done in the EGLStream backend (e.g. nvidia driver). It uses a 'custom' page flip queueing method, keeping the EGLStream logic inside meta-renderer-native.c. Page flip handling is moved to meta-kms-impl-device.c from meta-gpu-kms.c. It goes via an extra idle callback before reaching meta-renderer-native.c to make sure callbacks are invoked outside of the impl context. While dummy power save page flipping is kept in meta-renderer-native.c, the EBUSY handling is moved to meta-kms-impl-simple.c. Instead of freezing the frame clock, actual page flip callbacks are postponed until all EBUSY retries have either succeeded or failed due to some other error than EBUSY. This effectively inhibits new frames to be drawn, meaning we won't stall waiting on the file descriptor for pending page flips. https://gitlab.gnome.org/GNOME/mutter/issues/548 https://gitlab.gnome.org/GNOME/mutter/merge_requests/525
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{
return output_kms->kms_connector;
}
void
meta_output_kms_set_underscan (MetaOutputKms *output_kms,
backend/native: Add and use transactional KMS API This commit introduces, and makes use of, a transactional API used for setting up KMS state, later to be applied, potentially atomically. From an API point of view, so is always the case, but in the current implementation, it still uses legacy drmMode* API to apply the state non-atomically. The API consists of various buliding blocks: * MetaKmsUpdate - a set of configuration changes, the higher level handle for handing over configuration to the impl backend. It's used to set mode, assign framebuffers to planes, queue page flips and set connector properties. * MetaKmsPlaneAssignment - the assignment of a framebuffer to a plane. Currently used to map a framebuffer to the primary plane of a CRTC. In the legacy KMS implementation, the plane assignment is used to derive the framebuffer used for mode setting and page flipping. This also means various high level changes: State, excluding configuring the cursor plane and creating/destroying DRM framebuffer handles, are applied in the end of a clutter frame, in one go. From an API point of view, this is done atomically, but as mentioned, only the non-atomic implementation exists so far. From MetaRendererNative's point of view, a page flip now initially always succeeds; the handling of EBUSY errors are done asynchronously in the MetaKmsImpl backend (still by retrying at refresh rate, but postponing flip callbacks instead of manipulating the frame clock). Handling of falling back to mode setting instead of page flipping is notified after the fact by a more precise page flip feedback API. EGLStream based page flipping relies on the impl backend not being atomic, as the page flipping is done in the EGLStream backend (e.g. nvidia driver). It uses a 'custom' page flip queueing method, keeping the EGLStream logic inside meta-renderer-native.c. Page flip handling is moved to meta-kms-impl-device.c from meta-gpu-kms.c. It goes via an extra idle callback before reaching meta-renderer-native.c to make sure callbacks are invoked outside of the impl context. While dummy power save page flipping is kept in meta-renderer-native.c, the EBUSY handling is moved to meta-kms-impl-simple.c. Instead of freezing the frame clock, actual page flip callbacks are postponed until all EBUSY retries have either succeeded or failed due to some other error than EBUSY. This effectively inhibits new frames to be drawn, meaning we won't stall waiting on the file descriptor for pending page flips. https://gitlab.gnome.org/GNOME/mutter/issues/548 https://gitlab.gnome.org/GNOME/mutter/merge_requests/525
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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))
{
backend/native: Add and use transactional KMS API This commit introduces, and makes use of, a transactional API used for setting up KMS state, later to be applied, potentially atomically. From an API point of view, so is always the case, but in the current implementation, it still uses legacy drmMode* API to apply the state non-atomically. The API consists of various buliding blocks: * MetaKmsUpdate - a set of configuration changes, the higher level handle for handing over configuration to the impl backend. It's used to set mode, assign framebuffers to planes, queue page flips and set connector properties. * MetaKmsPlaneAssignment - the assignment of a framebuffer to a plane. Currently used to map a framebuffer to the primary plane of a CRTC. In the legacy KMS implementation, the plane assignment is used to derive the framebuffer used for mode setting and page flipping. This also means various high level changes: State, excluding configuring the cursor plane and creating/destroying DRM framebuffer handles, are applied in the end of a clutter frame, in one go. From an API point of view, this is done atomically, but as mentioned, only the non-atomic implementation exists so far. From MetaRendererNative's point of view, a page flip now initially always succeeds; the handling of EBUSY errors are done asynchronously in the MetaKmsImpl backend (still by retrying at refresh rate, but postponing flip callbacks instead of manipulating the frame clock). Handling of falling back to mode setting instead of page flipping is notified after the fact by a more precise page flip feedback API. EGLStream based page flipping relies on the impl backend not being atomic, as the page flipping is done in the EGLStream backend (e.g. nvidia driver). It uses a 'custom' page flip queueing method, keeping the EGLStream logic inside meta-renderer-native.c. Page flip handling is moved to meta-kms-impl-device.c from meta-gpu-kms.c. It goes via an extra idle callback before reaching meta-renderer-native.c to make sure callbacks are invoked outside of the impl context. While dummy power save page flipping is kept in meta-renderer-native.c, the EBUSY handling is moved to meta-kms-impl-simple.c. Instead of freezing the frame clock, actual page flip callbacks are postponed until all EBUSY retries have either succeeded or failed due to some other error than EBUSY. This effectively inhibits new frames to be drawn, meaning we won't stall waiting on the file descriptor for pending page flips. https://gitlab.gnome.org/GNOME/mutter/issues/548 https://gitlab.gnome.org/GNOME/mutter/merge_requests/525
2019-04-04 16:36:41 -04:00
MetaCrtc *crtc;
const MetaCrtcConfig *crtc_config;
const MetaCrtcModeInfo *crtc_mode_info;
backend/native: Add and use transactional KMS API This commit introduces, and makes use of, a transactional API used for setting up KMS state, later to be applied, potentially atomically. From an API point of view, so is always the case, but in the current implementation, it still uses legacy drmMode* API to apply the state non-atomically. The API consists of various buliding blocks: * MetaKmsUpdate - a set of configuration changes, the higher level handle for handing over configuration to the impl backend. It's used to set mode, assign framebuffers to planes, queue page flips and set connector properties. * MetaKmsPlaneAssignment - the assignment of a framebuffer to a plane. Currently used to map a framebuffer to the primary plane of a CRTC. In the legacy KMS implementation, the plane assignment is used to derive the framebuffer used for mode setting and page flipping. This also means various high level changes: State, excluding configuring the cursor plane and creating/destroying DRM framebuffer handles, are applied in the end of a clutter frame, in one go. From an API point of view, this is done atomically, but as mentioned, only the non-atomic implementation exists so far. From MetaRendererNative's point of view, a page flip now initially always succeeds; the handling of EBUSY errors are done asynchronously in the MetaKmsImpl backend (still by retrying at refresh rate, but postponing flip callbacks instead of manipulating the frame clock). Handling of falling back to mode setting instead of page flipping is notified after the fact by a more precise page flip feedback API. EGLStream based page flipping relies on the impl backend not being atomic, as the page flipping is done in the EGLStream backend (e.g. nvidia driver). It uses a 'custom' page flip queueing method, keeping the EGLStream logic inside meta-renderer-native.c. Page flip handling is moved to meta-kms-impl-device.c from meta-gpu-kms.c. It goes via an extra idle callback before reaching meta-renderer-native.c to make sure callbacks are invoked outside of the impl context. While dummy power save page flipping is kept in meta-renderer-native.c, the EBUSY handling is moved to meta-kms-impl-simple.c. Instead of freezing the frame clock, actual page flip callbacks are postponed until all EBUSY retries have either succeeded or failed due to some other error than EBUSY. This effectively inhibits new frames to be drawn, meaning we won't stall waiting on the file descriptor for pending page flips. https://gitlab.gnome.org/GNOME/mutter/issues/548 https://gitlab.gnome.org/GNOME/mutter/merge_requests/525
2019-04-04 16:36:41 -04:00
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_update_set_underscanning (kms_update,
output_kms->kms_connector,
hborder, vborder);
}
else
{
g_debug ("Unsetting underscan of connector %s",
meta_kms_connector_get_name (output_kms->kms_connector));
meta_kms_update_unset_underscanning (kms_update,
output_kms->kms_connector);
}
}
uint32_t
meta_output_kms_get_connector_id (MetaOutputKms *output_kms)
{
return meta_kms_connector_get_id (output_kms->kms_connector);
}
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);
}
static GBytes *
meta_output_kms_read_edid (MetaOutputNative *output_native)
{
MetaOutputKms *output_kms = META_OUTPUT_KMS (output_native);
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)
{
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);
MetaKmsMode *kms_mode = meta_crtc_mode_kms_get_kms_mode (crtc_mode_kms);
const drmModeModeInfo *drm_mode = meta_kms_mode_get_drm_mode (kms_mode);
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_kms_mode (gpu_kms, fallback_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_kms_mode (gpu_kms, kms_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;
}
static MetaConnectorType
meta_kms_connector_type_from_drm (uint32_t drm_connector_type)
{
Introduce virtual monitors Virtual monitors are monitors that isn't backed by any monitor like hardware. It would typically be backed by e.g. a remote desktop service, or a network display. It is currently only supported by the native backend, and whether the X11 backend will ever see virtual monitors is an open question. This rest of this commit message describes how it works under the native backend. Each virutal monitor consists of virtualized mode setting components: * A virtual CRTC mode (MetaCrtcModeVirtual) * A virtual CRTC (MetaCrtcVirtual) * A virtual connector (MetaOutputVirtual) In difference to the corresponding mode setting objects that represents KMS objects, the virtual ones isn't directly tied to a MetaGpu, other than the CoglFramebuffer being part of the GPU context of the primary GPU, which is the case for all monitors no matter what GPU they are connected to. Part of the reason for this is that a MetaGpu in practice represents a mode setting device, and its CRTCs and outputs, are all backed by real mode setting objects, while a virtual monitor is only backed by a framebuffer that is tied to the primary GPU. Maybe this will be reevaluated in the future, but since a virtual monitor is not tied to any GPU currently, so is the case for the virtual mode setting objects. The native rendering backend, including the cursor renderer, is adapted to handle the situation where a CRTC does not have a GPU associated with it; this in practice means that it e.g. will not try to upload HW cursor buffers when the cursor is only on a virtual monitor. The same applies to the native renderer, which is made to avoid creating MetaOnscreenNative for views that are backed by virtual CRTCs, as well as to avoid trying to mode set on such views. Part-of: <https://gitlab.gnome.org/GNOME/mutter/-/merge_requests/1698>
2021-01-26 10:49:28 -05:00
g_warn_if_fail (drm_connector_type < META_CONNECTOR_TYPE_META);
return (MetaConnectorType) drm_connector_type;
}
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;
uint32_t drm_connector_type;
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);
drm_connector_type = meta_kms_connector_get_connector_type (kms_connector);
output_info->connector_type =
meta_kms_connector_type_from_drm (drm_connector_type);
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)
{
MetaOutputNativeClass *output_native_class = META_OUTPUT_NATIVE_CLASS (klass);
output_native_class->read_edid = meta_output_kms_read_edid;
}