/* -*- mode: C; c-file-style: "gnu"; indent-tabs-mode: nil; -*- */ /* * Copyright (C) 2013 Red Hat Inc. * * 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. * * Author: Giovanni Campagna */ #include "config.h" #include "meta-monitor-manager-kms.h" #include "meta-monitor-config.h" #include "meta-monitor-config-manager.h" #include "meta-backend-private.h" #include "meta-renderer-native.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include "meta-default-modes.h" #define ALL_TRANSFORMS (META_MONITOR_TRANSFORM_FLIPPED_270 + 1) #define ALL_TRANSFORMS_MASK ((1 << ALL_TRANSFORMS) - 1) #define SYNC_TOLERANCE 0.01 /* 1 percent */ /* Try each 50 milleseconds up to half a second to get a proper EDID read */ #define EDID_RETRY_TIMEOUT_MS 50 #define EDID_MAX_NUM_RETRIES 10 typedef struct { drmModeConnector *connector; unsigned n_encoders; drmModeEncoderPtr *encoders; drmModeEncoderPtr current_encoder; /* * Bitmasks of encoder position in the resources array (used during clone * setup). */ uint32_t encoder_mask; uint32_t enc_clone_mask; uint32_t dpms_prop_id; uint32_t edid_blob_id; uint32_t tile_blob_id; int suggested_x; int suggested_y; uint32_t hotplug_mode_update; gboolean has_scaling; } MetaOutputKms; typedef struct { uint32_t underscan_prop_id; uint32_t underscan_hborder_prop_id; uint32_t underscan_vborder_prop_id; uint32_t primary_plane_id; uint32_t rotation_prop_id; uint32_t rotation_map[ALL_TRANSFORMS]; uint32_t all_hw_transforms; } MetaCrtcKms; typedef struct { GSource source; gpointer fd_tag; MetaMonitorManagerKms *manager_kms; } MetaKmsSource; struct _MetaMonitorManagerKms { MetaMonitorManager parent_instance; int fd; MetaKmsSource *source; drmModeConnector **connectors; unsigned int n_connectors; GUdevClient *udev; GSettings *desktop_settings; gboolean page_flips_not_supported; guint handle_hotplug_timeout; int read_edid_tries; }; struct _MetaMonitorManagerKmsClass { MetaMonitorManagerClass parent_class; }; G_DEFINE_TYPE (MetaMonitorManagerKms, meta_monitor_manager_kms, META_TYPE_MONITOR_MANAGER); static void free_resources (MetaMonitorManagerKms *manager_kms) { unsigned i; for (i = 0; i < manager_kms->n_connectors; i++) drmModeFreeConnector (manager_kms->connectors[i]); g_free (manager_kms->connectors); } static int compare_outputs (const void *one, const void *two) { const MetaOutput *o_one = one, *o_two = two; return strcmp (o_one->name, o_two->name); } static char * make_output_name (drmModeConnector *connector) { static const char * const connector_type_names[] = { "None", "VGA", "DVI-I", "DVI-D", "DVI-A", "Composite", "SVIDEO", "LVDS", "Component", "DIN", "DP", "HDMI", "HDMI-B", "TV", "eDP", "Virtual", "DSI", }; if (connector->connector_type < G_N_ELEMENTS (connector_type_names)) return g_strdup_printf ("%s-%d", connector_type_names[connector->connector_type], connector->connector_type_id); else return g_strdup_printf ("Unknown%d-%d", connector->connector_type, connector->connector_type_id); } static void meta_output_destroy_notify (MetaOutput *output) { MetaOutputKms *output_kms; unsigned i; output_kms = output->driver_private; for (i = 0; i < output_kms->n_encoders; i++) drmModeFreeEncoder (output_kms->encoders[i]); g_free (output_kms->encoders); g_slice_free (MetaOutputKms, output_kms); } static void meta_monitor_mode_destroy_notify (MetaCrtcMode *mode) { g_slice_free (drmModeModeInfo, mode->driver_private); } static void meta_crtc_destroy_notify (MetaCrtc *crtc) { g_free (crtc->driver_private); } static gboolean drm_mode_equal (gconstpointer one, gconstpointer two) { const drmModeModeInfo *m_one = one; const drmModeModeInfo *m_two = two; return m_one->clock == m_two->clock && m_one->hdisplay == m_two->hdisplay && m_one->hsync_start == m_two->hsync_start && m_one->hsync_end == m_two->hsync_end && m_one->htotal == m_two->htotal && m_one->hskew == m_two->hskew && m_one->vdisplay == m_two->vdisplay && m_one->vsync_start == m_two->vsync_start && m_one->vsync_end == m_two->vsync_end && m_one->vtotal == m_two->vtotal && m_one->vscan == m_two->vscan && m_one->vrefresh == m_two->vrefresh && m_one->flags == m_two->flags && m_one->type == m_two->type && strncmp (m_one->name, m_two->name, DRM_DISPLAY_MODE_LEN) == 0; } static guint drm_mode_hash (gconstpointer ptr) { const drmModeModeInfo *mode = ptr; guint hash = 0; /* We don't include the name in the hash because it's generally derived from the other fields (hdisplay, vdisplay and flags) */ hash ^= mode->clock; hash ^= mode->hdisplay ^ mode->hsync_start ^ mode->hsync_end; hash ^= mode->vdisplay ^ mode->vsync_start ^ mode->vsync_end; hash ^= mode->vrefresh; hash ^= mode->flags ^ mode->type; return hash; } static void find_connector_properties (MetaMonitorManagerKms *manager_kms, MetaOutputKms *output_kms) { int i; output_kms->hotplug_mode_update = 0; output_kms->suggested_x = -1; output_kms->suggested_y = -1; for (i = 0; i < output_kms->connector->count_props; i++) { drmModePropertyPtr prop = drmModeGetProperty (manager_kms->fd, output_kms->connector->props[i]); if (!prop) continue; if ((prop->flags & DRM_MODE_PROP_ENUM) && strcmp (prop->name, "DPMS") == 0) output_kms->dpms_prop_id = prop->prop_id; else if ((prop->flags & DRM_MODE_PROP_BLOB) && strcmp (prop->name, "EDID") == 0) output_kms->edid_blob_id = output_kms->connector->prop_values[i]; else if ((prop->flags & DRM_MODE_PROP_BLOB) && strcmp (prop->name, "TILE") == 0) output_kms->tile_blob_id = output_kms->connector->prop_values[i]; else if ((prop->flags & DRM_MODE_PROP_RANGE) && strcmp (prop->name, "suggested X") == 0) output_kms->suggested_x = output_kms->connector->prop_values[i]; else if ((prop->flags & DRM_MODE_PROP_RANGE) && strcmp (prop->name, "suggested Y") == 0) output_kms->suggested_y = output_kms->connector->prop_values[i]; else if ((prop->flags & DRM_MODE_PROP_RANGE) && strcmp (prop->name, "hotplug_mode_update") == 0) output_kms->hotplug_mode_update = output_kms->connector->prop_values[i]; else if (strcmp (prop->name, "scaling mode") == 0) output_kms->has_scaling = TRUE; drmModeFreeProperty (prop); } } static void find_crtc_properties (MetaMonitorManagerKms *manager_kms, MetaCrtc *meta_crtc) { MetaCrtcKms *crtc_kms; drmModeObjectPropertiesPtr props; size_t i; crtc_kms = meta_crtc->driver_private; props = drmModeObjectGetProperties (manager_kms->fd, meta_crtc->crtc_id, DRM_MODE_OBJECT_CRTC); if (!props) return; for (i = 0; i < props->count_props; i++) { drmModePropertyPtr prop = drmModeGetProperty (manager_kms->fd, props->props[i]); if (!prop) continue; if ((prop->flags & DRM_MODE_PROP_ENUM) && strcmp (prop->name, "underscan") == 0) crtc_kms->underscan_prop_id = prop->prop_id; else if ((prop->flags & DRM_MODE_PROP_RANGE) && strcmp (prop->name, "underscan hborder") == 0) crtc_kms->underscan_hborder_prop_id = prop->prop_id; else if ((prop->flags & DRM_MODE_PROP_RANGE) && strcmp (prop->name, "underscan vborder") == 0) crtc_kms->underscan_vborder_prop_id = prop->prop_id; drmModeFreeProperty (prop); } } static drmModePropertyBlobPtr read_edid_blob (MetaMonitorManagerKms *manager_kms, uint32_t edid_blob_id, GError **error) { drmModePropertyBlobPtr edid_blob = NULL; edid_blob = drmModeGetPropertyBlob (manager_kms->fd, edid_blob_id); if (!edid_blob) { g_set_error (error, G_IO_ERROR, g_io_error_from_errno (errno), "Failed to get EDID property blob: %s", strerror (errno)); return NULL; } return edid_blob; } static GBytes * read_output_edid (MetaMonitorManagerKms *manager_kms, MetaOutput *output, GError **error) { MetaOutputKms *output_kms = output->driver_private; drmModePropertyBlobPtr edid_blob; g_assert (output_kms->edid_blob_id != 0); edid_blob = read_edid_blob (manager_kms, output_kms->edid_blob_id, error); if (!edid_blob) return NULL; if (edid_blob->length == 0) { g_set_error (error, G_IO_ERROR, G_IO_ERROR_FAILED, "EDID blob was empty"); drmModeFreePropertyBlob (edid_blob); return NULL; } return g_bytes_new_with_free_func (edid_blob->data, edid_blob->length, (GDestroyNotify) drmModeFreePropertyBlob, edid_blob); } static gboolean output_get_tile_info (MetaMonitorManagerKms *manager_kms, MetaOutput *output) { MetaOutputKms *output_kms = output->driver_private; drmModePropertyBlobPtr tile_blob = NULL; int ret; if (output_kms->tile_blob_id == 0) return FALSE; tile_blob = drmModeGetPropertyBlob (manager_kms->fd, output_kms->tile_blob_id); if (!tile_blob) { meta_warning ("Failed to read TILE of output %s: %s\n", output->name, strerror(errno)); return FALSE; } if (tile_blob->length > 0) { ret = sscanf ((char *)tile_blob->data, "%d:%d:%d:%d:%d:%d:%d:%d", &output->tile_info.group_id, &output->tile_info.flags, &output->tile_info.max_h_tiles, &output->tile_info.max_v_tiles, &output->tile_info.loc_h_tile, &output->tile_info.loc_v_tile, &output->tile_info.tile_w, &output->tile_info.tile_h); drmModeFreePropertyBlob (tile_blob); if (ret != 8) { meta_warning ("Couldn't understand output tile property blob\n"); return FALSE; } return TRUE; } else { drmModeFreePropertyBlob (tile_blob); return FALSE; } } static MetaCrtcMode * find_meta_mode (MetaMonitorManager *manager, const drmModeModeInfo *drm_mode) { unsigned k; for (k = 0; k < manager->n_modes; k++) { if (drm_mode_equal (drm_mode, manager->modes[k].driver_private)) return &manager->modes[k]; } g_assert_not_reached (); return NULL; } static float drm_mode_vrefresh (const drmModeModeInfo *mode) { float refresh = 0.0; if (mode->htotal > 0 && mode->vtotal > 0) { /* Calculate refresh rate in milliHz first for extra precision. */ refresh = (mode->clock * 1000000LL) / mode->htotal; refresh += (mode->vtotal / 2); refresh /= mode->vtotal; if (mode->vscan > 1) refresh /= mode->vscan; refresh /= 1000.0; } return refresh; } static void init_mode (MetaCrtcMode *mode, const drmModeModeInfo *drm_mode, long mode_id) { mode->mode_id = mode_id; mode->name = g_strndup (drm_mode->name, DRM_DISPLAY_MODE_LEN); mode->width = drm_mode->hdisplay; mode->height = drm_mode->vdisplay; mode->flags = drm_mode->flags; mode->refresh_rate = drm_mode_vrefresh (drm_mode); mode->driver_private = g_slice_dup (drmModeModeInfo, drm_mode); mode->driver_notify = (GDestroyNotify)meta_monitor_mode_destroy_notify; } static int compare_modes (const void *one, const void *two) { MetaCrtcMode *a = *(MetaCrtcMode **) one; MetaCrtcMode *b = *(MetaCrtcMode **) two; if (a->width != b->width) return a->width > b->width ? -1 : 1; if (a->height != b->height) return a->height > b->height ? -1 : 1; if (a->refresh_rate != b->refresh_rate) return a->refresh_rate > b->refresh_rate ? -1 : 1; return g_strcmp0 (b->name, a->name); } static MetaOutput * find_output_by_id (MetaOutput *outputs, unsigned n_outputs, glong id) { unsigned i; for (i = 0; i < n_outputs; i++) if (outputs[i].winsys_id == id) return &outputs[i]; return NULL; } /* 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 /* Based on code from gnome-settings-daemon */ static int compute_scale (MetaOutput *output) { int scale = 1; if (!output->crtc) goto out; /* Scaling makes no sense */ if (output->crtc->rect.width < HIDPI_MIN_HEIGHT) goto out; /* 4K TV */ if (output->name != NULL && strstr(output->name, "HDMI") != NULL && output->crtc->rect.width >= SMALLEST_4K_WIDTH) goto out; /* Somebody encoded the aspect ratio (16/9 or 16/10) * instead of the physical size */ if ((output->width_mm == 160 && output->height_mm == 90) || (output->width_mm == 160 && output->height_mm == 100) || (output->width_mm == 16 && output->height_mm == 9) || (output->width_mm == 16 && output->height_mm == 10)) goto out; if (output->width_mm > 0 && output->height_mm > 0) { double dpi_x, dpi_y; dpi_x = (double)output->crtc->rect.width / (output->width_mm / 25.4); dpi_y = (double)output->crtc->rect.height / (output->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; } out: return scale; } static int get_output_scale (MetaMonitorManager *manager, MetaOutput *output) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (manager); int scale = g_settings_get_uint (manager_kms->desktop_settings, "scaling-factor"); if (scale > 0) return scale; else return compute_scale (output); } static int find_property_index (MetaMonitorManager *manager, drmModeObjectPropertiesPtr props, const gchar *prop_name, drmModePropertyPtr *found) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (manager); unsigned int i; for (i = 0; i < props->count_props; i++) { drmModePropertyPtr prop; prop = drmModeGetProperty (manager_kms->fd, props->props[i]); if (!prop) continue; if (strcmp (prop->name, prop_name) == 0) { *found = prop; return i; } drmModeFreeProperty (prop); } return -1; } static void parse_transforms (MetaMonitorManager *manager, drmModePropertyPtr prop, MetaCrtc *crtc) { MetaCrtcKms *crtc_kms = crtc->driver_private; int i; for (i = 0; i < prop->count_enums; i++) { int cur = -1; if (strcmp (prop->enums[i].name, "rotate-0") == 0) cur = META_MONITOR_TRANSFORM_NORMAL; else if (strcmp (prop->enums[i].name, "rotate-90") == 0) cur = META_MONITOR_TRANSFORM_90; else if (strcmp (prop->enums[i].name, "rotate-180") == 0) cur = META_MONITOR_TRANSFORM_180; else if (strcmp (prop->enums[i].name, "rotate-270") == 0) cur = META_MONITOR_TRANSFORM_270; if (cur != -1) { crtc_kms->all_hw_transforms |= 1 << cur; crtc_kms->rotation_map[cur] = 1 << prop->enums[i].value; } } } static gboolean is_primary_plane (MetaMonitorManager *manager, drmModeObjectPropertiesPtr props) { drmModePropertyPtr prop; int idx; idx = find_property_index (manager, props, "type", &prop); if (idx < 0) return FALSE; drmModeFreeProperty (prop); return props->prop_values[idx] == DRM_PLANE_TYPE_PRIMARY; } static void init_crtc_rotations (MetaMonitorManager *manager, MetaCrtc *crtc, unsigned int idx) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (manager); drmModeObjectPropertiesPtr props; drmModePlaneRes *planes; drmModePlane *drm_plane; MetaCrtcKms *crtc_kms; unsigned int i; crtc_kms = crtc->driver_private; planes = drmModeGetPlaneResources(manager_kms->fd); if (planes == NULL) return; for (i = 0; i < planes->count_planes; i++) { drmModePropertyPtr prop; drm_plane = drmModeGetPlane (manager_kms->fd, planes->planes[i]); if (!drm_plane) continue; if ((drm_plane->possible_crtcs & (1 << idx))) { props = drmModeObjectGetProperties (manager_kms->fd, drm_plane->plane_id, DRM_MODE_OBJECT_PLANE); if (props && is_primary_plane (manager, props)) { int rotation_idx; crtc_kms->primary_plane_id = drm_plane->plane_id; rotation_idx = find_property_index (manager, props, "rotation", &prop); if (rotation_idx >= 0) { crtc_kms->rotation_prop_id = props->props[rotation_idx]; parse_transforms (manager, prop, crtc); drmModeFreeProperty (prop); } } if (props) drmModeFreeObjectProperties (props); } drmModeFreePlane (drm_plane); } crtc->all_transforms |= crtc_kms->all_hw_transforms; drmModeFreePlaneResources (planes); } static void add_common_modes (MetaMonitorManager *manager, MetaOutput *output) { const drmModeModeInfo *mode; GPtrArray *array; unsigned i; unsigned max_hdisplay = 0; unsigned max_vdisplay = 0; float max_vrefresh = 0.0; for (i = 0; i < output->n_modes; i++) { mode = output->modes[i]->driver_private; max_hdisplay = MAX (max_hdisplay, mode->hdisplay); max_vdisplay = MAX (max_vdisplay, mode->vdisplay); max_vrefresh = MAX (max_vrefresh, drm_mode_vrefresh (mode)); } max_vrefresh = MAX (max_vrefresh, 60.0); max_vrefresh *= (1 + SYNC_TOLERANCE); array = g_ptr_array_new (); for (i = 0; i < G_N_ELEMENTS (meta_default_drm_mode_infos); i++) { mode = &meta_default_drm_mode_infos[i]; if (mode->hdisplay > max_hdisplay || mode->vdisplay > max_vdisplay || drm_mode_vrefresh (mode) > max_vrefresh) continue; g_ptr_array_add (array, find_meta_mode (manager, mode)); } output->modes = g_renew (MetaCrtcMode *, output->modes, output->n_modes + array->len); memcpy (output->modes + output->n_modes, array->pdata, array->len * sizeof (MetaCrtcMode *)); output->n_modes += array->len; g_ptr_array_free (array, TRUE); } static void init_crtc (MetaCrtc *crtc, MetaMonitorManager *manager, drmModeCrtc *drm_crtc) { unsigned int i; crtc->crtc_id = drm_crtc->crtc_id; crtc->rect.x = drm_crtc->x; crtc->rect.y = drm_crtc->y; crtc->rect.width = drm_crtc->width; crtc->rect.height = drm_crtc->height; crtc->is_dirty = FALSE; crtc->transform = META_MONITOR_TRANSFORM_NORMAL; crtc->all_transforms = meta_is_stage_views_enabled () ? ALL_TRANSFORMS_MASK : META_MONITOR_TRANSFORM_NORMAL; if (drm_crtc->mode_valid) { for (i = 0; i < manager->n_modes; i++) { if (drm_mode_equal (&drm_crtc->mode, manager->modes[i].driver_private)) { crtc->current_mode = &manager->modes[i]; break; } } } crtc->driver_private = g_new0 (MetaCrtcKms, 1); crtc->driver_notify = (GDestroyNotify) meta_crtc_destroy_notify; } static void init_output (MetaOutput *output, MetaMonitorManager *manager, drmModeConnector *connector, MetaOutput *old_output) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (manager); MetaOutputKms *output_kms; GArray *crtcs; GBytes *edid; unsigned int i; unsigned int crtc_mask; output_kms = g_slice_new0 (MetaOutputKms); output->driver_private = output_kms; output->driver_notify = (GDestroyNotify)meta_output_destroy_notify; output->winsys_id = connector->connector_id; output->name = make_output_name (connector); output->width_mm = connector->mmWidth; output->height_mm = connector->mmHeight; switch (connector->subpixel) { case DRM_MODE_SUBPIXEL_NONE: output->subpixel_order = COGL_SUBPIXEL_ORDER_NONE; break; case DRM_MODE_SUBPIXEL_HORIZONTAL_RGB: output->subpixel_order = COGL_SUBPIXEL_ORDER_HORIZONTAL_RGB; break; case DRM_MODE_SUBPIXEL_HORIZONTAL_BGR: output->subpixel_order = COGL_SUBPIXEL_ORDER_HORIZONTAL_BGR; break; case DRM_MODE_SUBPIXEL_VERTICAL_RGB: output->subpixel_order = COGL_SUBPIXEL_ORDER_VERTICAL_RGB; break; case DRM_MODE_SUBPIXEL_VERTICAL_BGR: output->subpixel_order = COGL_SUBPIXEL_ORDER_VERTICAL_BGR; break; case DRM_MODE_SUBPIXEL_UNKNOWN: default: output->subpixel_order = COGL_SUBPIXEL_ORDER_UNKNOWN; break; } output->preferred_mode = NULL; output->n_modes = connector->count_modes; output->modes = g_new0 (MetaCrtcMode *, output->n_modes); for (i = 0; i < output->n_modes; i++) { output->modes[i] = find_meta_mode (manager, &connector->modes[i]); if (connector->modes[i].type & DRM_MODE_TYPE_PREFERRED) output->preferred_mode = output->modes[i]; } if (!output->preferred_mode) output->preferred_mode = output->modes[0]; output_kms->connector = connector; find_connector_properties (manager_kms, output_kms); /* FIXME: MSC feature bit? */ /* Presume that if the output supports scaling, then we have * a panel fitter capable of adjusting any mode to suit. */ if (output_kms->has_scaling) add_common_modes (manager, output); qsort (output->modes, output->n_modes, sizeof (MetaCrtcMode *), compare_modes); output_kms->n_encoders = connector->count_encoders; output_kms->encoders = g_new0 (drmModeEncoderPtr, output_kms->n_encoders); crtc_mask = ~(unsigned int) 0; for (i = 0; i < output_kms->n_encoders; i++) { output_kms->encoders[i] = drmModeGetEncoder (manager_kms->fd, connector->encoders[i]); if (!output_kms->encoders[i]) continue; /* We only list CRTCs as supported if they are supported by all encoders for this connectors. This is what xf86-video-modesetting does (see drmmode_output_init()) */ crtc_mask &= output_kms->encoders[i]->possible_crtcs; if (output_kms->encoders[i]->encoder_id == connector->encoder_id) output_kms->current_encoder = output_kms->encoders[i]; } crtcs = g_array_new (FALSE, FALSE, sizeof (MetaCrtc*)); for (i = 0; i < manager->n_crtcs; i++) { if (crtc_mask & (1 << i)) { MetaCrtc *crtc = &manager->crtcs[i]; g_array_append_val (crtcs, crtc); } } output->n_possible_crtcs = crtcs->len; output->possible_crtcs = (void*)g_array_free (crtcs, FALSE); if (output_kms->current_encoder && output_kms->current_encoder->crtc_id != 0) { for (i = 0; i < manager->n_crtcs; i++) { if (manager->crtcs[i].crtc_id == output_kms->current_encoder->crtc_id) { output->crtc = &manager->crtcs[i]; break; } } } else { output->crtc = NULL; } if (old_output) { output->is_primary = old_output->is_primary; output->is_presentation = old_output->is_presentation; } else { output->is_primary = FALSE; output->is_presentation = FALSE; } output->suggested_x = output_kms->suggested_x; output->suggested_y = output_kms->suggested_y; output->hotplug_mode_update = output_kms->hotplug_mode_update; if (output_kms->edid_blob_id != 0) { GError *error = NULL; edid = read_output_edid (manager_kms, output, &error); if (!edid) { g_warning ("Failed to read EDID: %s", error->message); g_error_free (error); } } else { edid = NULL; } meta_output_parse_edid (output, edid); g_bytes_unref (edid); /* MetaConnectorType matches DRM's connector types */ output->connector_type = (MetaConnectorType) connector->connector_type; output->scale = get_output_scale (manager, output); output_get_tile_info (manager_kms, output); /* FIXME: backlight is a very driver specific thing unfortunately, every DDX does its own thing, and the dumb KMS API does not include it. For example, xf86-video-intel has a list of paths to probe in /sys/class/backlight (one for each major HW maker, and then some). We can't do the same because we're not root. It might be best to leave backlight out of the story and rely on the setuid helper in gnome-settings-daemon. */ output->backlight_min = 0; output->backlight_max = 0; output->backlight = -1; } static void detect_and_setup_output_clones (MetaMonitorManager *manager, drmModeRes *resources) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (manager); drmModeEncoder **encoders; unsigned int i, n_encoders; n_encoders = (unsigned int) resources->count_encoders; encoders = g_new (drmModeEncoder *, n_encoders); for (i = 0; i < n_encoders; i++) encoders[i] = drmModeGetEncoder (manager_kms->fd, resources->encoders[i]); /* * Setup encoder position mask and encoder clone mask. */ for (i = 0; i < manager->n_outputs; i++) { MetaOutput *output; MetaOutputKms *output_kms; unsigned int j; output = &manager->outputs[i]; output_kms = output->driver_private; output_kms->enc_clone_mask = 0xff; output_kms->encoder_mask = 0; for (j = 0; j < output_kms->n_encoders; j++) { unsigned int k; for (k = 0; k < n_encoders; k++) { if (output_kms->encoders[j] && encoders[k] && output_kms->encoders[j]->encoder_id == encoders[k]->encoder_id) { output_kms->encoder_mask |= (1 << k); break; } } output_kms->enc_clone_mask &= output_kms->encoders[j]->possible_clones; } } for (i = 0; i < (unsigned)resources->count_encoders; i++) drmModeFreeEncoder (encoders[i]); g_free (encoders); /* * Setup MetaOutput <-> MetaOutput clone associations. */ for (i = 0; i < manager->n_outputs; i++) { MetaOutput *output; MetaOutputKms *output_kms; unsigned int j; output = &manager->outputs[i]; output_kms = output->driver_private; if (output_kms->enc_clone_mask == 0) continue; for (j = 0; j < manager->n_outputs; j++) { MetaOutput *meta_clone; MetaOutputKms *clone_kms; meta_clone = &manager->outputs[i]; clone_kms = meta_clone->driver_private; if (meta_clone == output) continue; if (clone_kms->encoder_mask == 0) continue; if (clone_kms->encoder_mask == output_kms->enc_clone_mask) { output->n_possible_clones++; output->possible_clones = g_renew (MetaOutput *, output->possible_clones, output->n_possible_clones); output->possible_clones[output->n_possible_clones - 1] = meta_clone; } } } } static void init_connectors (MetaMonitorManager *manager, drmModeRes *resources) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (manager); unsigned int i; manager_kms->n_connectors = resources->count_connectors; manager_kms->connectors = g_new (drmModeConnector *, manager_kms->n_connectors); for (i = 0; i < manager_kms->n_connectors; i++) { drmModeConnector *drm_connector; drm_connector = drmModeGetConnector (manager_kms->fd, resources->connectors[i]); manager_kms->connectors[i] = drm_connector; } } static void init_modes (MetaMonitorManager *manager, drmModeRes *resources) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (manager); GHashTable *modes; GHashTableIter iter; drmModeModeInfo *drm_mode; unsigned int i; long mode_id; /* * Gather all modes on all connected connectors. */ modes = g_hash_table_new (drm_mode_hash, drm_mode_equal); for (i = 0; i < manager_kms->n_connectors; i++) { drmModeConnector *drm_connector; drm_connector = manager_kms->connectors[i]; if (drm_connector && drm_connector->connection == DRM_MODE_CONNECTED) { unsigned int j; for (j = 0; j < (unsigned int) drm_connector->count_modes; j++) g_hash_table_add (modes, &drm_connector->modes[j]); } } manager->n_modes = g_hash_table_size (modes) + G_N_ELEMENTS (meta_default_drm_mode_infos); manager->modes = g_new0 (MetaCrtcMode, manager->n_modes); g_hash_table_iter_init (&iter, modes); mode_id = 0; while (g_hash_table_iter_next (&iter, NULL, (gpointer *) &drm_mode)) { MetaCrtcMode *mode; mode = &manager->modes[mode_id]; init_mode (mode, drm_mode, (long) mode_id); mode_id++; } g_hash_table_destroy (modes); for (i = 0; i < G_N_ELEMENTS (meta_default_drm_mode_infos); i++) { MetaCrtcMode *mode; mode = &manager->modes[mode_id]; init_mode (mode, &meta_default_drm_mode_infos[i], (long) mode_id); mode_id++; } } static void init_crtcs (MetaMonitorManager *manager, drmModeRes *resources) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (manager); unsigned int i; manager->n_crtcs = resources->count_crtcs; manager->crtcs = g_new0 (MetaCrtc, manager->n_crtcs); for (i = 0; i < (unsigned)resources->count_crtcs; i++) { drmModeCrtc *drm_crtc; MetaCrtc *crtc; drm_crtc = drmModeGetCrtc (manager_kms->fd, resources->crtcs[i]); crtc = &manager->crtcs[i]; init_crtc (crtc, manager, drm_crtc); find_crtc_properties (manager_kms, crtc); init_crtc_rotations (manager, crtc, i); drmModeFreeCrtc (drm_crtc); } } static void init_outputs (MetaMonitorManager *manager, drmModeRes *resources) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (manager); MetaOutput *old_outputs; unsigned int n_old_outputs; unsigned int n_actual_outputs; unsigned int i; old_outputs = manager->outputs; n_old_outputs = manager->n_outputs; manager->outputs = g_new0 (MetaOutput, manager_kms->n_connectors); n_actual_outputs = 0; for (i = 0; i < manager_kms->n_connectors; i++) { drmModeConnector *connector; MetaOutput *output; connector = manager_kms->connectors[i]; output = &manager->outputs[n_actual_outputs]; if (connector && connector->connection == DRM_MODE_CONNECTED) { MetaOutput *old_output; old_output = find_output_by_id (old_outputs, n_old_outputs, output->winsys_id); init_output (output, manager, connector, old_output); n_actual_outputs++; } } manager->n_outputs = n_actual_outputs; manager->outputs = g_renew (MetaOutput, manager->outputs, manager->n_outputs); /* Sort the outputs for easier handling in MetaMonitorConfig */ qsort (manager->outputs, manager->n_outputs, sizeof (MetaOutput), compare_outputs); detect_and_setup_output_clones (manager, resources); } static void meta_monitor_manager_kms_read_current (MetaMonitorManager *manager) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (manager); drmModeRes *resources; resources = drmModeGetResources (manager_kms->fd); /* TODO: max screen width only matters for stage views is not enabled. */ manager->max_screen_width = resources->max_width; manager->max_screen_height = resources->max_height; manager->power_save_mode = META_POWER_SAVE_ON; /* Note: we must not free the public structures (output, crtc, monitor mode and monitor info) here, they must be kept alive until the API users are done with them after we emit monitors-changed, and thus are freed by the platform-independent layer. */ free_resources (manager_kms); init_connectors (manager, resources); init_modes (manager, resources); init_crtcs (manager, resources); init_outputs (manager, resources); drmModeFreeResources (resources); } static GBytes * meta_monitor_manager_kms_read_edid (MetaMonitorManager *manager, MetaOutput *output) { MetaOutputKms *output_kms = output->driver_private; MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (manager); GError *error = NULL; GBytes *edid; if (output_kms->edid_blob_id == 0) return NULL; edid = read_output_edid (manager_kms, output, &error); if (!edid) { g_warning ("Failed to read EDID from '%s': %s", output->name, error->message); g_error_free (error); return NULL; } return edid; } static void meta_monitor_manager_kms_set_power_save_mode (MetaMonitorManager *manager, MetaPowerSave mode) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (manager); uint64_t state; unsigned i; switch (mode) { case META_POWER_SAVE_ON: state = DRM_MODE_DPMS_ON; break; case META_POWER_SAVE_STANDBY: state = DRM_MODE_DPMS_STANDBY; break; case META_POWER_SAVE_SUSPEND: state = DRM_MODE_DPMS_SUSPEND; break; case META_POWER_SAVE_OFF: state = DRM_MODE_DPMS_OFF; break; default: return; } for (i = 0; i < manager->n_outputs; i++) { MetaOutput *output; MetaOutputKms *output_kms; output = &manager->outputs[i]; output_kms = output->driver_private; if (output_kms->dpms_prop_id != 0) { int ok = drmModeObjectSetProperty (manager_kms->fd, output->winsys_id, DRM_MODE_OBJECT_CONNECTOR, output_kms->dpms_prop_id, state); if (ok < 0) meta_warning ("Failed to set power save mode for output %s: %s\n", output->name, strerror (errno)); } } } static void set_underscan (MetaMonitorManagerKms *manager_kms, MetaOutput *output) { if (!output->crtc) return; MetaCrtc *crtc = output->crtc; MetaCrtcKms *crtc_kms = crtc->driver_private; if (!crtc_kms->underscan_prop_id) return; if (output->is_underscanning) { drmModeObjectSetProperty (manager_kms->fd, crtc->crtc_id, DRM_MODE_OBJECT_CRTC, crtc_kms->underscan_prop_id, (uint64_t) 1); if (crtc_kms->underscan_hborder_prop_id) { uint64_t value = crtc->current_mode->width * 0.05; drmModeObjectSetProperty (manager_kms->fd, crtc->crtc_id, DRM_MODE_OBJECT_CRTC, crtc_kms->underscan_hborder_prop_id, value); } if (crtc_kms->underscan_vborder_prop_id) { uint64_t value = crtc->current_mode->height * 0.05; drmModeObjectSetProperty (manager_kms->fd, crtc->crtc_id, DRM_MODE_OBJECT_CRTC, crtc_kms->underscan_vborder_prop_id, value); } } else { drmModeObjectSetProperty (manager_kms->fd, crtc->crtc_id, DRM_MODE_OBJECT_CRTC, crtc_kms->underscan_prop_id, (uint64_t) 0); } } static void meta_monitor_manager_kms_ensure_initial_config (MetaMonitorManager *manager) { MetaMonitorsConfig *config; config = meta_monitor_manager_ensure_configured (manager); if (manager->config_manager) meta_monitor_manager_update_logical_state (manager, config); else meta_monitor_manager_update_logical_state_derived (manager); } static void apply_crtc_assignments (MetaMonitorManager *manager, MetaCrtcInfo **crtcs, unsigned int n_crtcs, MetaOutputInfo **outputs, unsigned int n_outputs) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (manager); unsigned i; for (i = 0; i < n_crtcs; i++) { MetaCrtcInfo *crtc_info = crtcs[i]; MetaCrtc *crtc = crtc_info->crtc; MetaCrtcKms *crtc_kms = crtc->driver_private; MetaMonitorTransform hw_transform; crtc->is_dirty = TRUE; if (crtc_info->mode == NULL) { crtc->rect.x = 0; crtc->rect.y = 0; crtc->rect.width = 0; crtc->rect.height = 0; crtc->current_mode = NULL; } else { MetaCrtcMode *mode; unsigned int j; int width, height; mode = crtc_info->mode; if (meta_monitor_transform_is_rotated (crtc_info->transform)) { width = mode->height; height = mode->width; } else { width = mode->width; height = mode->height; } crtc->rect.x = crtc_info->x; crtc->rect.y = crtc_info->y; crtc->rect.width = width; crtc->rect.height = height; crtc->current_mode = mode; crtc->transform = crtc_info->transform; for (j = 0; j < crtc_info->outputs->len; j++) { MetaOutput *output = g_ptr_array_index (crtc_info->outputs, j); output->is_dirty = TRUE; output->crtc = crtc; output->scale = get_output_scale (manager, output); } } if (crtc_kms->all_hw_transforms & (1 << crtc->transform)) hw_transform = crtc->transform; else hw_transform = META_MONITOR_TRANSFORM_NORMAL; if (drmModeObjectSetProperty (manager_kms->fd, crtc_kms->primary_plane_id, DRM_MODE_OBJECT_PLANE, crtc_kms->rotation_prop_id, crtc_kms->rotation_map[hw_transform]) != 0) { g_warning ("Failed to apply DRM plane transform %d: %m", hw_transform); /* Blacklist this HW transform, we want to fallback to our * fallbacks in this case. */ crtc_kms->all_hw_transforms &= ~(1 << hw_transform); } } /* Disable CRTCs not mentioned in the list (they have is_dirty == FALSE, because they weren't seen in the first loop) */ for (i = 0; i < manager->n_crtcs; i++) { MetaCrtc *crtc = &manager->crtcs[i]; crtc->logical_monitor = NULL; if (crtc->is_dirty) { crtc->is_dirty = FALSE; continue; } crtc->rect.x = 0; crtc->rect.y = 0; crtc->rect.width = 0; crtc->rect.height = 0; crtc->current_mode = NULL; } for (i = 0; i < n_outputs; i++) { MetaOutputInfo *output_info = outputs[i]; MetaOutput *output = output_info->output; output->is_primary = output_info->is_primary; output->is_presentation = output_info->is_presentation; output->is_underscanning = output_info->is_underscanning; set_underscan (manager_kms, output); } /* Disable outputs not mentioned in the list */ for (i = 0; i < manager->n_outputs; i++) { MetaOutput *output = &manager->outputs[i]; if (output->is_dirty) { output->is_dirty = FALSE; continue; } output->crtc = NULL; output->is_primary = FALSE; } } static void update_screen_size (MetaMonitorManager *manager, MetaMonitorsConfig *config) { GList *l; int screen_width = 0; int screen_height = 0; for (l = config->logical_monitor_configs; l; l = l->next) { MetaLogicalMonitorConfig *logical_monitor_config = l->data; int right_edge; int bottom_edge; right_edge = (logical_monitor_config->layout.width + logical_monitor_config->layout.x); if (right_edge > screen_width) screen_width = right_edge; bottom_edge = (logical_monitor_config->layout.height + logical_monitor_config->layout.y); if (bottom_edge > screen_height) screen_height = bottom_edge; } manager->screen_width = screen_width; manager->screen_height = screen_height; } static gboolean meta_monitor_manager_kms_apply_monitors_config (MetaMonitorManager *manager, MetaMonitorsConfig *config, GError **error) { GPtrArray *crtc_infos; GPtrArray *output_infos; if (!config) { manager->screen_width = 0; manager->screen_height = 0; return TRUE; } if (!meta_monitor_config_manager_assign (manager, config, &crtc_infos, &output_infos, error)) return FALSE; apply_crtc_assignments (manager, (MetaCrtcInfo **) crtc_infos->pdata, crtc_infos->len, (MetaOutputInfo **) output_infos->pdata, output_infos->len); g_ptr_array_free (crtc_infos, TRUE); g_ptr_array_free (output_infos, TRUE); update_screen_size (manager, config); meta_monitor_manager_rebuild (manager, config); return TRUE; } static void legacy_calculate_screen_size (MetaMonitorManager *manager) { unsigned int i; int width = 0, height = 0; for (i = 0; i < manager->n_crtcs; i++) { MetaCrtc *crtc = &manager->crtcs[i]; width = MAX (width, crtc->rect.x + crtc->rect.width); height = MAX (height, crtc->rect.y + crtc->rect.height); } manager->screen_width = width; manager->screen_height = height; } static void meta_monitor_manager_kms_apply_configuration (MetaMonitorManager *manager, MetaCrtcInfo **crtcs, unsigned int n_crtcs, MetaOutputInfo **outputs, unsigned int n_outputs) { apply_crtc_assignments (manager, crtcs, n_crtcs, outputs, n_outputs); legacy_calculate_screen_size (manager); meta_monitor_manager_rebuild_derived (manager); } static void meta_monitor_manager_kms_get_crtc_gamma (MetaMonitorManager *manager, MetaCrtc *crtc, gsize *size, unsigned short **red, unsigned short **green, unsigned short **blue) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (manager); drmModeCrtc *kms_crtc; kms_crtc = drmModeGetCrtc (manager_kms->fd, crtc->crtc_id); *size = kms_crtc->gamma_size; *red = g_new (unsigned short, *size); *green = g_new (unsigned short, *size); *blue = g_new (unsigned short, *size); drmModeCrtcGetGamma (manager_kms->fd, crtc->crtc_id, *size, *red, *green, *blue); drmModeFreeCrtc (kms_crtc); } static void meta_monitor_manager_kms_set_crtc_gamma (MetaMonitorManager *manager, MetaCrtc *crtc, gsize size, unsigned short *red, unsigned short *green, unsigned short *blue) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (manager); drmModeCrtcSetGamma (manager_kms->fd, crtc->crtc_id, size, red, green, blue); } static gboolean has_pending_edid_blob (MetaMonitorManagerKms *manager_kms) { drmModeRes *resources; int n_connectors; int i, j; gboolean edid_blob_pending; resources = drmModeGetResources (manager_kms->fd); n_connectors = resources->count_connectors; edid_blob_pending = FALSE; for (i = 0; i < n_connectors; i++) { drmModeConnector *drm_connector; uint32_t edid_blob_id; drm_connector = drmModeGetConnector (manager_kms->fd, resources->connectors[i]); edid_blob_id = 0; for (j = 0; j < drm_connector->count_props; j++) { drmModePropertyPtr prop; prop = drmModeGetProperty (manager_kms->fd, drm_connector->props[j]); if (prop->flags & DRM_MODE_PROP_BLOB && g_str_equal (prop->name, "EDID")) edid_blob_id = drm_connector->prop_values[j]; drmModeFreeProperty (prop); if (edid_blob_id) break; } drmModeFreeConnector (drm_connector); if (edid_blob_id) { GError *error = NULL; drmModePropertyBlobPtr edid_blob; edid_blob = read_edid_blob (manager_kms, edid_blob_id, &error); if (!edid_blob && g_error_matches (error, G_IO_ERROR, G_IO_ERROR_NOT_FOUND)) { edid_blob_pending = TRUE; g_error_free (error); } else if (!edid_blob) { g_error_free (error); } else { drmModeFreePropertyBlob (edid_blob); } } if (edid_blob_pending) break; } drmModeFreeResources (resources); return edid_blob_pending; } static void handle_hotplug_event (MetaMonitorManager *manager) { meta_monitor_manager_read_current_state (manager); meta_monitor_manager_on_hotplug (manager); } static gboolean handle_hotplug_event_timeout (gpointer user_data) { MetaMonitorManager *manager = user_data; MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (user_data); if (!has_pending_edid_blob (manager_kms)) { handle_hotplug_event (manager); manager_kms->handle_hotplug_timeout = 0; return G_SOURCE_REMOVE; } manager_kms->read_edid_tries++; if (manager_kms->read_edid_tries > EDID_MAX_NUM_RETRIES) { g_warning ("Tried to read the EDID %d times, " "but one or more are still missing, continuing without", manager_kms->read_edid_tries); handle_hotplug_event (manager); manager_kms->handle_hotplug_timeout = 0; return G_SOURCE_REMOVE; } return G_SOURCE_CONTINUE; } static void on_uevent (GUdevClient *client, const char *action, GUdevDevice *device, gpointer user_data) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (user_data); MetaMonitorManager *manager = META_MONITOR_MANAGER (manager_kms); if (!g_udev_device_get_property_as_boolean (device, "HOTPLUG")) return; if (manager_kms->handle_hotplug_timeout) { g_source_remove (manager_kms->handle_hotplug_timeout); manager_kms->handle_hotplug_timeout = 0; } /* * On a hot-plug event, the EDID of one or more connectors might not yet be * ready at this point, resulting in invalid configuration potentially being * applied. Avoid this by first checking whether the EDID is ready at this * point, or otherwise wait a bit and try again. */ manager_kms->read_edid_tries = 0; if (has_pending_edid_blob (manager_kms)) { manager_kms->handle_hotplug_timeout = g_timeout_add (EDID_RETRY_TIMEOUT_MS, handle_hotplug_event_timeout, manager); return; } handle_hotplug_event (manager); } static gboolean kms_event_check (GSource *source) { MetaKmsSource *kms_source = (MetaKmsSource *) source; return g_source_query_unix_fd (source, kms_source->fd_tag) & G_IO_IN; } static gboolean kms_event_dispatch (GSource *source, GSourceFunc callback, gpointer user_data) { MetaKmsSource *kms_source = (MetaKmsSource *) source; meta_monitor_manager_kms_wait_for_flip (kms_source->manager_kms); return G_SOURCE_CONTINUE; } static GSourceFuncs kms_event_funcs = { NULL, kms_event_check, kms_event_dispatch }; static void meta_monitor_manager_kms_init (MetaMonitorManagerKms *manager_kms) { MetaBackend *backend = meta_get_backend (); MetaRenderer *renderer = meta_backend_get_renderer (backend); MetaRendererNative *renderer_native = META_RENDERER_NATIVE (renderer); GSource *source; manager_kms->fd = meta_renderer_native_get_kms_fd (renderer_native); drmSetClientCap (manager_kms->fd, DRM_CLIENT_CAP_UNIVERSAL_PLANES, 1); const char *subsystems[2] = { "drm", NULL }; manager_kms->udev = g_udev_client_new (subsystems); g_signal_connect (manager_kms->udev, "uevent", G_CALLBACK (on_uevent), manager_kms); source = g_source_new (&kms_event_funcs, sizeof (MetaKmsSource)); manager_kms->source = (MetaKmsSource *) source; manager_kms->source->fd_tag = g_source_add_unix_fd (source, manager_kms->fd, G_IO_IN | G_IO_ERR); manager_kms->source->manager_kms = manager_kms; g_source_attach (source, NULL); manager_kms->desktop_settings = g_settings_new ("org.gnome.desktop.interface"); } static void get_crtc_connectors (MetaMonitorManager *manager, MetaCrtc *crtc, uint32_t **connectors, unsigned int *n_connectors) { unsigned int i; GArray *connectors_array = g_array_new (FALSE, FALSE, sizeof (uint32_t)); for (i = 0; i < manager->n_outputs; i++) { MetaOutput *output = &manager->outputs[i]; if (output->crtc == crtc) g_array_append_val (connectors_array, output->winsys_id); } *n_connectors = connectors_array->len; *connectors = (uint32_t *) g_array_free (connectors_array, FALSE); } gboolean meta_monitor_manager_kms_apply_crtc_mode (MetaMonitorManagerKms *manager_kms, MetaCrtc *crtc, int x, int y, uint32_t fb_id) { MetaMonitorManager *manager = META_MONITOR_MANAGER (manager_kms); uint32_t *connectors; unsigned int n_connectors; drmModeModeInfo *mode; get_crtc_connectors (manager, crtc, &connectors, &n_connectors); if (connectors) mode = crtc->current_mode->driver_private; else mode = NULL; if (drmModeSetCrtc (manager_kms->fd, crtc->crtc_id, fb_id, x, y, connectors, n_connectors, mode) != 0) { g_warning ("Failed to set CRTC mode %s: %m", crtc->current_mode->name); return FALSE; } g_free (connectors); return TRUE; } static void invoke_flip_closure (GClosure *flip_closure) { GValue param = G_VALUE_INIT; g_value_init (¶m, G_TYPE_POINTER); g_value_set_pointer (¶m, flip_closure); g_closure_invoke (flip_closure, NULL, 1, ¶m, NULL); g_closure_unref (flip_closure); } gboolean meta_monitor_manager_kms_is_crtc_active (MetaMonitorManagerKms *manager_kms, MetaCrtc *crtc) { MetaMonitorManager *manager = META_MONITOR_MANAGER (manager_kms); unsigned int i; gboolean connected_crtc_found; if (manager->power_save_mode != META_POWER_SAVE_ON) return FALSE; connected_crtc_found = FALSE; for (i = 0; i < manager->n_outputs; i++) { MetaOutput *output = &manager->outputs[i]; if (output->crtc == crtc) { connected_crtc_found = TRUE; break; } } if (!connected_crtc_found) return FALSE; return TRUE; } gboolean meta_monitor_manager_kms_flip_crtc (MetaMonitorManagerKms *manager_kms, MetaCrtc *crtc, int x, int y, uint32_t fb_id, GClosure *flip_closure, gboolean *fb_in_use) { MetaMonitorManager *manager = META_MONITOR_MANAGER (manager_kms); uint32_t *connectors; unsigned int n_connectors; int ret = -1; g_assert (manager->power_save_mode == META_POWER_SAVE_ON); get_crtc_connectors (manager, crtc, &connectors, &n_connectors); g_assert (n_connectors > 0); if (!manager_kms->page_flips_not_supported) { ret = drmModePageFlip (manager_kms->fd, crtc->crtc_id, fb_id, DRM_MODE_PAGE_FLIP_EVENT, flip_closure); if (ret != 0 && ret != -EACCES) { g_warning ("Failed to flip: %s", strerror (-ret)); manager_kms->page_flips_not_supported = TRUE; } } if (manager_kms->page_flips_not_supported) { if (meta_monitor_manager_kms_apply_crtc_mode (manager_kms, crtc, x, y, fb_id)) { *fb_in_use = TRUE; return FALSE; } } if (ret != 0) return FALSE; *fb_in_use = TRUE; g_closure_ref (flip_closure); return TRUE; } static void page_flip_handler (int fd, unsigned int frame, unsigned int sec, unsigned int usec, void *data) { GClosure *flip_closure = data; invoke_flip_closure (flip_closure); } void meta_monitor_manager_kms_wait_for_flip (MetaMonitorManagerKms *manager_kms) { drmEventContext evctx; if (manager_kms->page_flips_not_supported) return; memset (&evctx, 0, sizeof evctx); evctx.version = DRM_EVENT_CONTEXT_VERSION; evctx.page_flip_handler = page_flip_handler; drmHandleEvent (manager_kms->fd, &evctx); } static gboolean meta_monitor_manager_kms_is_transform_handled (MetaMonitorManager *manager, MetaCrtc *crtc, MetaMonitorTransform transform) { MetaCrtcKms *crtc_kms = crtc->driver_private; if ((1 << crtc->transform) & crtc_kms->all_hw_transforms) return TRUE; else return FALSE; } static void meta_monitor_manager_kms_dispose (GObject *object) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (object); g_clear_object (&manager_kms->udev); g_clear_object (&manager_kms->desktop_settings); G_OBJECT_CLASS (meta_monitor_manager_kms_parent_class)->dispose (object); } static void meta_monitor_manager_kms_finalize (GObject *object) { MetaMonitorManagerKms *manager_kms = META_MONITOR_MANAGER_KMS (object); free_resources (manager_kms); g_source_destroy ((GSource *) manager_kms->source); G_OBJECT_CLASS (meta_monitor_manager_kms_parent_class)->finalize (object); } static void meta_monitor_manager_kms_class_init (MetaMonitorManagerKmsClass *klass) { MetaMonitorManagerClass *manager_class = META_MONITOR_MANAGER_CLASS (klass); GObjectClass *object_class = G_OBJECT_CLASS (klass); object_class->dispose = meta_monitor_manager_kms_dispose; object_class->finalize = meta_monitor_manager_kms_finalize; manager_class->read_current = meta_monitor_manager_kms_read_current; manager_class->read_edid = meta_monitor_manager_kms_read_edid; manager_class->ensure_initial_config = meta_monitor_manager_kms_ensure_initial_config; manager_class->apply_monitors_config = meta_monitor_manager_kms_apply_monitors_config; manager_class->apply_configuration = meta_monitor_manager_kms_apply_configuration; manager_class->set_power_save_mode = meta_monitor_manager_kms_set_power_save_mode; manager_class->get_crtc_gamma = meta_monitor_manager_kms_get_crtc_gamma; manager_class->set_crtc_gamma = meta_monitor_manager_kms_set_crtc_gamma; manager_class->is_transform_handled = meta_monitor_manager_kms_is_transform_handled; }