/*-*- Mode: C; c-basic-offset: 8; indent-tabs-mode: nil -*-*/ /*** This file is part of systemd. Copyright (C) 2014 David Herrmann systemd is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. systemd 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 Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with systemd; If not, see . ***/ #include #include #include #include #include #include #include #include #include #include #include /* Yuck! DRM headers need system headers included first.. but we have to * include it before shared/missing.h to avoid redefining ioctl bits */ #include #include #include #include "bus-util.h" #include "hashmap.h" #include "grdev.h" #include "grdev-internal.h" #include "macro.h" #include "udev-util.h" #include "util.h" #define GRDRM_MAX_TRIES (16) typedef struct grdrm_object grdrm_object; typedef struct grdrm_plane grdrm_plane; typedef struct grdrm_connector grdrm_connector; typedef struct grdrm_encoder grdrm_encoder; typedef struct grdrm_crtc grdrm_crtc; typedef struct grdrm_fb grdrm_fb; typedef struct grdrm_pipe grdrm_pipe; typedef struct grdrm_card grdrm_card; typedef struct unmanaged_card unmanaged_card; typedef struct managed_card managed_card; /* * Objects */ enum { GRDRM_TYPE_CRTC, GRDRM_TYPE_ENCODER, GRDRM_TYPE_CONNECTOR, GRDRM_TYPE_PLANE, GRDRM_TYPE_CNT }; struct grdrm_object { grdrm_card *card; uint32_t id; uint32_t index; unsigned int type; void (*free_fn) (grdrm_object *object); bool present : 1; bool assigned : 1; }; struct grdrm_plane { grdrm_object object; struct { uint32_t used_crtc; uint32_t used_fb; uint32_t gamma_size; uint32_t n_crtcs; uint32_t max_crtcs; uint32_t *crtcs; uint32_t n_formats; uint32_t max_formats; uint32_t *formats; } kern; }; struct grdrm_connector { grdrm_object object; struct { uint32_t type; uint32_t type_id; uint32_t used_encoder; uint32_t connection; uint32_t mm_width; uint32_t mm_height; uint32_t subpixel; uint32_t n_encoders; uint32_t max_encoders; uint32_t *encoders; uint32_t n_modes; uint32_t max_modes; struct drm_mode_modeinfo *modes; uint32_t n_props; uint32_t max_props; uint32_t *prop_ids; uint64_t *prop_values; } kern; }; struct grdrm_encoder { grdrm_object object; struct { uint32_t type; uint32_t used_crtc; uint32_t n_crtcs; uint32_t max_crtcs; uint32_t *crtcs; uint32_t n_clones; uint32_t max_clones; uint32_t *clones; } kern; }; struct grdrm_crtc { grdrm_object object; struct { uint32_t used_fb; uint32_t fb_offset_x; uint32_t fb_offset_y; uint32_t gamma_size; uint32_t n_used_connectors; uint32_t max_used_connectors; uint32_t *used_connectors; bool mode_set; struct drm_mode_modeinfo mode; } kern; struct { bool set; uint32_t fb; uint32_t fb_x; uint32_t fb_y; uint32_t gamma; uint32_t n_connectors; uint32_t *connectors; bool mode_set; struct drm_mode_modeinfo mode; } old; struct { struct drm_mode_modeinfo mode; uint32_t n_connectors; uint32_t max_connectors; uint32_t *connectors; } set; grdrm_pipe *pipe; bool applied : 1; }; #define GRDRM_OBJECT_INIT(_card, _id, _index, _type, _free_fn) ((grdrm_object){ \ .card = (_card), \ .id = (_id), \ .index = (_index), \ .type = (_type), \ .free_fn = (_free_fn), \ }) grdrm_object *grdrm_find_object(grdrm_card *card, uint32_t id); int grdrm_object_add(grdrm_object *object); grdrm_object *grdrm_object_free(grdrm_object *object); DEFINE_TRIVIAL_CLEANUP_FUNC(grdrm_object*, grdrm_object_free); int grdrm_plane_new(grdrm_plane **out, grdrm_card *card, uint32_t id, uint32_t index); int grdrm_connector_new(grdrm_connector **out, grdrm_card *card, uint32_t id, uint32_t index); int grdrm_encoder_new(grdrm_encoder **out, grdrm_card *card, uint32_t id, uint32_t index); int grdrm_crtc_new(grdrm_crtc **out, grdrm_card *card, uint32_t id, uint32_t index); #define plane_from_object(_obj) container_of((_obj), grdrm_plane, object) #define connector_from_object(_obj) container_of((_obj), grdrm_connector, object) #define encoder_from_object(_obj) container_of((_obj), grdrm_encoder, object) #define crtc_from_object(_obj) container_of((_obj), grdrm_crtc, object) /* * Framebuffers */ struct grdrm_fb { grdev_fb base; grdrm_card *card; uint32_t id; uint32_t handles[4]; uint32_t offsets[4]; uint32_t sizes[4]; uint32_t flipid; }; static int grdrm_fb_new(grdrm_fb **out, grdrm_card *card, const struct drm_mode_modeinfo *mode); grdrm_fb *grdrm_fb_free(grdrm_fb *fb); DEFINE_TRIVIAL_CLEANUP_FUNC(grdrm_fb*, grdrm_fb_free); #define fb_from_base(_fb) container_of((_fb), grdrm_fb, base) /* * Pipes */ struct grdrm_pipe { grdev_pipe base; grdrm_crtc *crtc; uint32_t counter; }; #define grdrm_pipe_from_base(_e) container_of((_e), grdrm_pipe, base) #define GRDRM_PIPE_NAME_MAX (GRDRM_CARD_NAME_MAX + 1 + DECIMAL_STR_MAX(uint32_t)) static const grdev_pipe_vtable grdrm_pipe_vtable; static int grdrm_pipe_new(grdrm_pipe **out, grdrm_crtc *crtc, struct drm_mode_modeinfo *mode, size_t n_fbs); /* * Cards */ struct grdrm_card { grdev_card base; int fd; sd_event_source *fd_src; uint32_t n_crtcs; uint32_t n_encoders; uint32_t n_connectors; uint32_t n_planes; uint32_t max_ids; Hashmap *object_map; bool async_hotplug : 1; bool running : 1; bool ready : 1; bool cap_dumb : 1; bool cap_monotonic : 1; }; struct unmanaged_card { grdrm_card card; char *devnode; }; struct managed_card { grdrm_card card; dev_t devnum; sd_bus_slot *slot_pause_device; sd_bus_slot *slot_resume_device; sd_bus_slot *slot_take_device; bool requested : 1; /* TakeDevice() was sent */ bool acquired : 1; /* TakeDevice() was successful */ bool master : 1; /* we are DRM-Master */ }; #define grdrm_card_from_base(_e) container_of((_e), grdrm_card, base) #define unmanaged_card_from_base(_e) \ container_of(grdrm_card_from_base(_e), unmanaged_card, card) #define managed_card_from_base(_e) \ container_of(grdrm_card_from_base(_e), managed_card, card) #define GRDRM_CARD_INIT(_vtable, _session) ((grdrm_card){ \ .base = GRDEV_CARD_INIT((_vtable), (_session)), \ .fd = -1, \ .max_ids = 32, \ }) #define GRDRM_CARD_NAME_MAX (6 + DECIMAL_STR_MAX(unsigned) * 2) static const grdev_card_vtable unmanaged_card_vtable; static const grdev_card_vtable managed_card_vtable; static int grdrm_card_open(grdrm_card *card, int dev_fd); static void grdrm_card_close(grdrm_card *card); static bool grdrm_card_async(grdrm_card *card, int r); /* * The page-flip event of the kernel provides 64bit of arbitrary user-data. As * drivers tend to drop events on intermediate deep mode-sets or because we * might receive events during session activation, we try to avoid allocaing * dynamic data on those events. Instead, we safe the CRTC id plus a 32bit * counter in there. This way, we only get 32bit counters, not 64bit, but that * should be more than enough. On the bright side, we no longer care whether we * lose events. No memory leaks will occur. * Modern DRM drivers might be fixed to no longer leak events, but we want to * be safe. And associating dynamically allocated data with those events is * kinda ugly, anyway. */ static uint64_t grdrm_encode_vblank_data(uint32_t id, uint32_t counter) { return id | ((uint64_t)counter << 32); } static void grdrm_decode_vblank_data(uint64_t data, uint32_t *out_id, uint32_t *out_counter) { if (out_id) *out_id = data & 0xffffffffU; if (out_counter) *out_counter = (data >> 32) & 0xffffffffU; } static bool grdrm_modes_compatible(const struct drm_mode_modeinfo *a, const struct drm_mode_modeinfo *b) { assert(a); assert(b); /* Test whether both modes are compatible according to our internal * assumptions on modes. This comparison is highly dependent on how * we treat modes in grdrm. If we export mode details, we need to * make this comparison much stricter. */ if (a->hdisplay != b->hdisplay) return false; if (a->vdisplay != b->vdisplay) return false; return true; } /* * Objects */ grdrm_object *grdrm_find_object(grdrm_card *card, uint32_t id) { assert_return(card, NULL); return id > 0 ? hashmap_get(card->object_map, UINT32_TO_PTR(id)) : NULL; } int grdrm_object_add(grdrm_object *object) { int r; assert(object); assert(object->card); assert(object->id > 0); assert(IN_SET(object->type, GRDRM_TYPE_CRTC, GRDRM_TYPE_ENCODER, GRDRM_TYPE_CONNECTOR, GRDRM_TYPE_PLANE)); assert(object->free_fn); if (object->index >= 32) log_debug("grdrm: %s: object index exceeds 32bit masks: type=%u, index=%" PRIu32, object->card->base.name, object->type, object->index); r = hashmap_put(object->card->object_map, UINT32_TO_PTR(object->id), object); if (r < 0) return r; return 0; } grdrm_object *grdrm_object_free(grdrm_object *object) { if (!object) return NULL; assert(object->card); assert(object->id > 0); assert(IN_SET(object->type, GRDRM_TYPE_CRTC, GRDRM_TYPE_ENCODER, GRDRM_TYPE_CONNECTOR, GRDRM_TYPE_PLANE)); assert(object->free_fn); hashmap_remove_value(object->card->object_map, UINT32_TO_PTR(object->id), object); object->free_fn(object); return NULL; } /* * Planes */ static void plane_free(grdrm_object *object) { grdrm_plane *plane = plane_from_object(object); free(plane->kern.formats); free(plane->kern.crtcs); free(plane); } int grdrm_plane_new(grdrm_plane **out, grdrm_card *card, uint32_t id, uint32_t index) { _cleanup_(grdrm_object_freep) grdrm_object *object = NULL; grdrm_plane *plane; int r; assert(card); plane = new0(grdrm_plane, 1); if (!plane) return -ENOMEM; object = &plane->object; *object = GRDRM_OBJECT_INIT(card, id, index, GRDRM_TYPE_PLANE, plane_free); plane->kern.max_crtcs = 32; plane->kern.crtcs = new0(uint32_t, plane->kern.max_crtcs); if (!plane->kern.crtcs) return -ENOMEM; plane->kern.max_formats = 32; plane->kern.formats = new0(uint32_t, plane->kern.max_formats); if (!plane->kern.formats) return -ENOMEM; r = grdrm_object_add(object); if (r < 0) return r; if (out) *out = plane; object = NULL; return 0; } static int grdrm_plane_resync(grdrm_plane *plane) { grdrm_card *card = plane->object.card; size_t tries; int r; assert(plane); for (tries = 0; tries < GRDRM_MAX_TRIES; ++tries) { struct drm_mode_get_plane res; grdrm_object *object; bool resized = false; Iterator iter; zero(res); res.plane_id = plane->object.id; res.format_type_ptr = PTR_TO_UINT64(plane->kern.formats); res.count_format_types = plane->kern.max_formats; r = ioctl(card->fd, DRM_IOCTL_MODE_GETPLANE, &res); if (r < 0) { r = -errno; if (r == -ENOENT) { card->async_hotplug = true; r = 0; log_debug("grdrm: %s: plane %u removed during resync", card->base.name, plane->object.id); } else { log_debug("grdrm: %s: cannot retrieve plane %u: %m", card->base.name, plane->object.id); } return r; } plane->kern.n_crtcs = 0; memzero(plane->kern.crtcs, sizeof(uint32_t) * plane->kern.max_crtcs); HASHMAP_FOREACH(object, card->object_map, iter) { if (object->type != GRDRM_TYPE_CRTC || object->index >= 32) continue; if (!(res.possible_crtcs & (1 << object->index))) continue; if (plane->kern.n_crtcs >= 32) { log_debug("grdrm: %s: possible_crtcs of plane %" PRIu32 " exceeds 32bit mask", card->base.name, plane->object.id); continue; } plane->kern.crtcs[plane->kern.n_crtcs++] = object->id; } if (res.count_format_types > plane->kern.max_formats) { uint32_t max, *t; max = ALIGN_POWER2(res.count_format_types); if (!max || max > UINT16_MAX) { log_debug("grdrm: %s: excessive plane resource limit: %" PRIu32, card->base.name, max); return -ERANGE; } t = realloc(plane->kern.formats, sizeof(*t) * max); if (!t) return -ENOMEM; plane->kern.formats = t; plane->kern.max_formats = max; resized = true; } if (resized) continue; plane->kern.n_formats = res.count_format_types; plane->kern.used_crtc = res.crtc_id; plane->kern.used_fb = res.fb_id; plane->kern.gamma_size = res.gamma_size; break; } if (tries >= GRDRM_MAX_TRIES) { log_debug("grdrm: %s: plane %u not settled for retrieval", card->base.name, plane->object.id); return -EFAULT; } return 0; } /* * Connectors */ static void connector_free(grdrm_object *object) { grdrm_connector *connector = connector_from_object(object); free(connector->kern.prop_values); free(connector->kern.prop_ids); free(connector->kern.modes); free(connector->kern.encoders); free(connector); } int grdrm_connector_new(grdrm_connector **out, grdrm_card *card, uint32_t id, uint32_t index) { _cleanup_(grdrm_object_freep) grdrm_object *object = NULL; grdrm_connector *connector; int r; assert(card); connector = new0(grdrm_connector, 1); if (!connector) return -ENOMEM; object = &connector->object; *object = GRDRM_OBJECT_INIT(card, id, index, GRDRM_TYPE_CONNECTOR, connector_free); connector->kern.max_encoders = 32; connector->kern.encoders = new0(uint32_t, connector->kern.max_encoders); if (!connector->kern.encoders) return -ENOMEM; connector->kern.max_modes = 32; connector->kern.modes = new0(struct drm_mode_modeinfo, connector->kern.max_modes); if (!connector->kern.modes) return -ENOMEM; connector->kern.max_props = 32; connector->kern.prop_ids = new0(uint32_t, connector->kern.max_props); connector->kern.prop_values = new0(uint64_t, connector->kern.max_props); if (!connector->kern.prop_ids || !connector->kern.prop_values) return -ENOMEM; r = grdrm_object_add(object); if (r < 0) return r; if (out) *out = connector; object = NULL; return 0; } static int grdrm_connector_resync(grdrm_connector *connector) { grdrm_card *card = connector->object.card; size_t tries; int r; assert(connector); for (tries = 0; tries < GRDRM_MAX_TRIES; ++tries) { struct drm_mode_get_connector res; bool resized = false; uint32_t max; zero(res); res.connector_id = connector->object.id; res.encoders_ptr = PTR_TO_UINT64(connector->kern.encoders); res.props_ptr = PTR_TO_UINT64(connector->kern.prop_ids); res.prop_values_ptr = PTR_TO_UINT64(connector->kern.prop_values); res.count_encoders = connector->kern.max_encoders; res.count_props = connector->kern.max_props; /* Retrieve modes only if we have none. This avoids expensive * EDID reads in the kernel, that can slow down resyncs * considerably! */ if (connector->kern.n_modes == 0) { res.modes_ptr = PTR_TO_UINT64(connector->kern.modes); res.count_modes = connector->kern.max_modes; } r = ioctl(card->fd, DRM_IOCTL_MODE_GETCONNECTOR, &res); if (r < 0) { r = -errno; if (r == -ENOENT) { card->async_hotplug = true; r = 0; log_debug("grdrm: %s: connector %u removed during resync", card->base.name, connector->object.id); } else { log_debug("grdrm: %s: cannot retrieve connector %u: %m", card->base.name, connector->object.id); } return r; } if (res.count_encoders > connector->kern.max_encoders) { uint32_t *t; max = ALIGN_POWER2(res.count_encoders); if (!max || max > UINT16_MAX) { log_debug("grdrm: %s: excessive connector resource limit: %" PRIu32, card->base.name, max); return -ERANGE; } t = realloc(connector->kern.encoders, sizeof(*t) * max); if (!t) return -ENOMEM; connector->kern.encoders = t; connector->kern.max_encoders = max; resized = true; } if (res.count_modes > connector->kern.max_modes) { struct drm_mode_modeinfo *t; max = ALIGN_POWER2(res.count_modes); if (!max || max > UINT16_MAX) { log_debug("grdrm: %s: excessive connector resource limit: %" PRIu32, card->base.name, max); return -ERANGE; } t = realloc(connector->kern.modes, sizeof(*t) * max); if (!t) return -ENOMEM; connector->kern.modes = t; connector->kern.max_modes = max; resized = true; } if (res.count_props > connector->kern.max_props) { uint32_t *tids; uint64_t *tvals; max = ALIGN_POWER2(res.count_props); if (!max || max > UINT16_MAX) { log_debug("grdrm: %s: excessive connector resource limit: %" PRIu32, card->base.name, max); return -ERANGE; } tids = realloc(connector->kern.prop_ids, sizeof(*tids) * max); if (!tids) return -ENOMEM; connector->kern.prop_ids = tids; tvals = realloc(connector->kern.prop_values, sizeof(*tvals) * max); if (!tvals) return -ENOMEM; connector->kern.prop_values = tvals; connector->kern.max_props = max; resized = true; } if (resized) continue; connector->kern.n_encoders = res.count_encoders; connector->kern.n_modes = res.count_modes; connector->kern.n_props = res.count_props; connector->kern.type = res.connector_type; connector->kern.type_id = res.connector_type_id; connector->kern.used_encoder = res.encoder_id; connector->kern.connection = res.connection; connector->kern.mm_width = res.mm_width; connector->kern.mm_height = res.mm_height; connector->kern.subpixel = res.subpixel; break; } if (tries >= GRDRM_MAX_TRIES) { log_debug("grdrm: %s: connector %u not settled for retrieval", card->base.name, connector->object.id); return -EFAULT; } return 0; } /* * Encoders */ static void encoder_free(grdrm_object *object) { grdrm_encoder *encoder = encoder_from_object(object); free(encoder->kern.clones); free(encoder->kern.crtcs); free(encoder); } int grdrm_encoder_new(grdrm_encoder **out, grdrm_card *card, uint32_t id, uint32_t index) { _cleanup_(grdrm_object_freep) grdrm_object *object = NULL; grdrm_encoder *encoder; int r; assert(card); encoder = new0(grdrm_encoder, 1); if (!encoder) return -ENOMEM; object = &encoder->object; *object = GRDRM_OBJECT_INIT(card, id, index, GRDRM_TYPE_ENCODER, encoder_free); encoder->kern.max_crtcs = 32; encoder->kern.crtcs = new0(uint32_t, encoder->kern.max_crtcs); if (!encoder->kern.crtcs) return -ENOMEM; encoder->kern.max_clones = 32; encoder->kern.clones = new0(uint32_t, encoder->kern.max_clones); if (!encoder->kern.clones) return -ENOMEM; r = grdrm_object_add(object); if (r < 0) return r; if (out) *out = encoder; object = NULL; return 0; } static int grdrm_encoder_resync(grdrm_encoder *encoder) { grdrm_card *card = encoder->object.card; struct drm_mode_get_encoder res; grdrm_object *object; Iterator iter; int r; assert(encoder); zero(res); res.encoder_id = encoder->object.id; r = ioctl(card->fd, DRM_IOCTL_MODE_GETENCODER, &res); if (r < 0) { r = -errno; if (r == -ENOENT) { card->async_hotplug = true; r = 0; log_debug("grdrm: %s: encoder %u removed during resync", card->base.name, encoder->object.id); } else { log_debug("grdrm: %s: cannot retrieve encoder %u: %m", card->base.name, encoder->object.id); } return r; } encoder->kern.type = res.encoder_type; encoder->kern.used_crtc = res.crtc_id; encoder->kern.n_crtcs = 0; memzero(encoder->kern.crtcs, sizeof(uint32_t) * encoder->kern.max_crtcs); HASHMAP_FOREACH(object, card->object_map, iter) { if (object->type != GRDRM_TYPE_CRTC || object->index >= 32) continue; if (!(res.possible_crtcs & (1 << object->index))) continue; if (encoder->kern.n_crtcs >= 32) { log_debug("grdrm: %s: possible_crtcs exceeds 32bit mask", card->base.name); continue; } encoder->kern.crtcs[encoder->kern.n_crtcs++] = object->id; } encoder->kern.n_clones = 0; memzero(encoder->kern.clones, sizeof(uint32_t) * encoder->kern.max_clones); HASHMAP_FOREACH(object, card->object_map, iter) { if (object->type != GRDRM_TYPE_ENCODER || object->index >= 32) continue; if (!(res.possible_clones & (1 << object->index))) continue; if (encoder->kern.n_clones >= 32) { log_debug("grdrm: %s: possible_encoders exceeds 32bit mask", card->base.name); continue; } encoder->kern.clones[encoder->kern.n_clones++] = object->id; } return 0; } /* * Crtcs */ static void crtc_free(grdrm_object *object) { grdrm_crtc *crtc = crtc_from_object(object); if (crtc->pipe) grdev_pipe_free(&crtc->pipe->base); free(crtc->set.connectors); free(crtc->old.connectors); free(crtc->kern.used_connectors); free(crtc); } int grdrm_crtc_new(grdrm_crtc **out, grdrm_card *card, uint32_t id, uint32_t index) { _cleanup_(grdrm_object_freep) grdrm_object *object = NULL; grdrm_crtc *crtc; int r; assert(card); crtc = new0(grdrm_crtc, 1); if (!crtc) return -ENOMEM; object = &crtc->object; *object = GRDRM_OBJECT_INIT(card, id, index, GRDRM_TYPE_CRTC, crtc_free); crtc->kern.max_used_connectors = 32; crtc->kern.used_connectors = new0(uint32_t, crtc->kern.max_used_connectors); if (!crtc->kern.used_connectors) return -ENOMEM; crtc->old.connectors = new0(uint32_t, crtc->kern.max_used_connectors); if (!crtc->old.connectors) return -ENOMEM; r = grdrm_object_add(object); if (r < 0) return r; if (out) *out = crtc; object = NULL; return 0; } static int grdrm_crtc_resync(grdrm_crtc *crtc) { grdrm_card *card = crtc->object.card; struct drm_mode_crtc res = { .crtc_id = crtc->object.id }; int r; assert(crtc); /* make sure we can cache any combination later */ if (card->n_connectors > crtc->kern.max_used_connectors) { uint32_t max, *t; max = ALIGN_POWER2(card->n_connectors); if (!max) return -ENOMEM; t = realloc_multiply(crtc->kern.used_connectors, sizeof(*t), max); if (!t) return -ENOMEM; crtc->kern.used_connectors = t; crtc->kern.max_used_connectors = max; if (!crtc->old.set) { crtc->old.connectors = calloc(sizeof(*t), max); if (!crtc->old.connectors) return -ENOMEM; } } /* GETCRTC doesn't return connectors. We have to read all * encoder-state and deduce the setup ourselves.. */ crtc->kern.n_used_connectors = 0; r = ioctl(card->fd, DRM_IOCTL_MODE_GETCRTC, &res); if (r < 0) { r = -errno; if (r == -ENOENT) { card->async_hotplug = true; r = 0; log_debug("grdrm: %s: crtc %u removed during resync", card->base.name, crtc->object.id); } else { log_debug("grdrm: %s: cannot retrieve crtc %u: %m", card->base.name, crtc->object.id); } return r; } crtc->kern.used_fb = res.fb_id; crtc->kern.fb_offset_x = res.x; crtc->kern.fb_offset_y = res.y; crtc->kern.gamma_size = res.gamma_size; crtc->kern.mode_set = res.mode_valid; crtc->kern.mode = res.mode; return 0; } static void grdrm_crtc_assign(grdrm_crtc *crtc, grdrm_connector *connector) { uint32_t n_connectors; int r; assert(crtc); assert(!crtc->object.assigned); assert(!connector || !connector->object.assigned); /* always mark both as assigned; even if assignments cannot be set */ crtc->object.assigned = true; if (connector) connector->object.assigned = true; /* we will support hw clone mode in the future */ n_connectors = connector ? 1 : 0; /* bail out if configuration is preserved */ if (crtc->set.n_connectors == n_connectors && (n_connectors == 0 || crtc->set.connectors[0] == connector->object.id)) return; crtc->applied = false; crtc->set.n_connectors = 0; if (n_connectors > crtc->set.max_connectors) { uint32_t max, *t; max = ALIGN_POWER2(n_connectors); if (!max) { r = -ENOMEM; goto error; } t = realloc(crtc->set.connectors, sizeof(*t) * max); if (!t) { r = -ENOMEM; goto error; } crtc->set.connectors = t; crtc->set.max_connectors = max; } if (connector) { struct drm_mode_modeinfo *m, *pref = NULL; uint32_t i; for (i = 0; i < connector->kern.n_modes; ++i) { m = &connector->kern.modes[i]; /* ignore 3D modes by default */ if (m->flags & DRM_MODE_FLAG_3D_MASK) continue; if (!pref) { pref = m; continue; } /* use PREFERRED over non-PREFERRED */ if ((pref->type & DRM_MODE_TYPE_PREFERRED) && !(m->type & DRM_MODE_TYPE_PREFERRED)) continue; /* use DRIVER over non-PREFERRED|DRIVER */ if ((pref->type & DRM_MODE_TYPE_DRIVER) && !(m->type & (DRM_MODE_TYPE_DRIVER | DRM_MODE_TYPE_PREFERRED))) continue; /* always prefer higher resolution */ if (pref->hdisplay > m->hdisplay || (pref->hdisplay == m->hdisplay && pref->vdisplay > m->vdisplay)) continue; pref = m; } if (pref) { crtc->set.mode = *pref; crtc->set.n_connectors = 1; crtc->set.connectors[0] = connector->object.id; log_debug("grdrm: %s: assigned connector %" PRIu32 " to crtc %" PRIu32 " with mode %s", crtc->object.card->base.name, connector->object.id, crtc->object.id, pref->name); } else { log_debug("grdrm: %s: connector %" PRIu32 " to be assigned but has no valid mode", crtc->object.card->base.name, connector->object.id); } } return; error: log_debug("grdrm: %s: cannot assign crtc %" PRIu32 ": %s", crtc->object.card->base.name, crtc->object.id, strerror(-r)); } static void grdrm_crtc_expose(grdrm_crtc *crtc) { grdrm_pipe *pipe; grdrm_fb *fb; size_t i; int r; assert(crtc); assert(crtc->object.assigned); if (crtc->set.n_connectors < 1) { if (crtc->pipe) grdev_pipe_free(&crtc->pipe->base); crtc->pipe = NULL; return; } pipe = crtc->pipe; if (pipe) { if (pipe->base.width != crtc->set.mode.hdisplay || pipe->base.height != crtc->set.mode.vdisplay) { grdev_pipe_free(&pipe->base); crtc->pipe = NULL; pipe = NULL; } } if (crtc->pipe) { pipe->base.front = NULL; pipe->base.back = NULL; for (i = 0; i < pipe->base.max_fbs; ++i) { fb = fb_from_base(pipe->base.fbs[i]); if (fb->id == crtc->kern.used_fb) pipe->base.front = &fb->base; else if (!fb->flipid) pipe->base.back = &fb->base; } } else { r = grdrm_pipe_new(&pipe, crtc, &crtc->set.mode, 2); if (r < 0) { log_debug("grdrm: %s: cannot create pipe for crtc %" PRIu32 ": %s", crtc->object.card->base.name, crtc->object.id, strerror(-r)); return; } for (i = 0; i < pipe->base.max_fbs; ++i) { r = grdrm_fb_new(&fb, crtc->object.card, &crtc->set.mode); if (r < 0) { log_debug("grdrm: %s: cannot allocate framebuffer for crtc %" PRIu32 ": %s", crtc->object.card->base.name, crtc->object.id, strerror(-r)); grdev_pipe_free(&pipe->base); return; } pipe->base.fbs[i] = &fb->base; } pipe->base.front = NULL; pipe->base.back = pipe->base.fbs[0]; crtc->pipe = pipe; } grdev_pipe_ready(&crtc->pipe->base, true); } static void grdrm_crtc_commit_deep(grdrm_crtc *crtc, grdev_fb **slot) { struct drm_mode_crtc set_crtc = { .crtc_id = crtc->object.id }; grdrm_card *card = crtc->object.card; grdrm_pipe *pipe = crtc->pipe; grdrm_fb *fb = fb_from_base(*slot); size_t i; int r; assert(crtc); assert(slot); assert(*slot); assert(pipe); set_crtc.set_connectors_ptr = PTR_TO_UINT64(crtc->set.connectors); set_crtc.count_connectors = crtc->set.n_connectors; set_crtc.fb_id = fb->id; set_crtc.x = 0; set_crtc.y = 0; set_crtc.mode_valid = 1; set_crtc.mode = crtc->set.mode; r = ioctl(card->fd, DRM_IOCTL_MODE_SETCRTC, &set_crtc); if (r < 0) { r = -errno; log_debug("grdrm: %s: cannot set crtc %" PRIu32 ": %m", card->base.name, crtc->object.id); grdrm_card_async(card, r); return; } if (!crtc->applied) { log_debug("grdrm: %s: crtc %" PRIu32 " applied via deep modeset", card->base.name, crtc->object.id); crtc->applied = true; } *slot = NULL; pipe->base.front = &fb->base; fb->flipid = 0; ++pipe->counter; pipe->base.flipping = false; pipe->base.flip = false; if (!pipe->base.back) { for (i = 0; i < pipe->base.max_fbs; ++i) { if (!pipe->base.fbs[i]) continue; fb = fb_from_base(pipe->base.fbs[i]); if (&fb->base == pipe->base.front) continue; fb->flipid = 0; pipe->base.back = &fb->base; break; } } } static int grdrm_crtc_commit_flip(grdrm_crtc *crtc, grdev_fb **slot) { struct drm_mode_crtc_page_flip page_flip = { .crtc_id = crtc->object.id }; grdrm_card *card = crtc->object.card; grdrm_pipe *pipe = crtc->pipe; grdrm_fb *fb = fb_from_base(*slot); uint32_t cnt; size_t i; int r; assert(crtc); assert(slot); assert(*slot); assert(pipe); if (!crtc->applied && !grdrm_modes_compatible(&crtc->kern.mode, &crtc->set.mode)) return 0; cnt = ++pipe->counter ? : ++pipe->counter; page_flip.fb_id = fb->id; page_flip.flags = DRM_MODE_PAGE_FLIP_EVENT; page_flip.user_data = grdrm_encode_vblank_data(crtc->object.id, cnt); r = ioctl(card->fd, DRM_IOCTL_MODE_PAGE_FLIP, &page_flip); if (r < 0) { r = -errno; log_debug("grdrm: %s: cannot schedule page-flip on crtc %" PRIu32 ": %m", card->base.name, crtc->object.id); if (grdrm_card_async(card, r)) return r; return 0; } if (!crtc->applied) { log_debug("grdrm: %s: crtc %" PRIu32 " applied via page flip", card->base.name, crtc->object.id); crtc->applied = true; } pipe->base.flipping = true; pipe->base.flip = false; pipe->counter = cnt; fb->flipid = cnt; *slot = NULL; if (!pipe->base.back) { for (i = 0; i < pipe->base.max_fbs; ++i) { if (!pipe->base.fbs[i]) continue; fb = fb_from_base(pipe->base.fbs[i]); if (&fb->base == pipe->base.front) continue; if (fb->flipid) continue; pipe->base.back = &fb->base; break; } } return 1; } static void grdrm_crtc_commit(grdrm_crtc *crtc) { struct drm_mode_crtc set_crtc = { .crtc_id = crtc->object.id }; grdrm_card *card = crtc->object.card; grdrm_pipe *pipe; grdev_fb **slot; int r; assert(crtc); assert(crtc->object.assigned); pipe = crtc->pipe; if (!pipe) { /* If a crtc is not assigned any connector, we want any * previous setup to be cleared, so make sure the CRTC is * disabled. Otherwise, there might be content on the CRTC * while we run, which is not what we want. * If you want to avoid modesets on specific CRTCs, you should * still keep their assignment, but never enable the resulting * pipe. This way, we wouldn't touch it at all. */ if (!crtc->applied) { crtc->applied = true; r = ioctl(card->fd, DRM_IOCTL_MODE_SETCRTC, &set_crtc); if (r < 0) { r = -errno; log_debug("grdrm: %s: cannot shutdown crtc %" PRIu32 ": %m", card->base.name, crtc->object.id); grdrm_card_async(card, r); return; } log_debug("grdrm: %s: crtc %" PRIu32 " applied via shutdown", card->base.name, crtc->object.id); } return; } /* we always fully ignore disabled pipes */ if (!pipe->base.enabled) return; assert(crtc->set.n_connectors > 0); if (pipe->base.flip) slot = &pipe->base.back; else if (!crtc->applied) slot = &pipe->base.front; else return; if (!*slot) return; r = grdrm_crtc_commit_flip(crtc, slot); if (r == 0) { /* in case we couldn't page-flip, perform deep modeset */ grdrm_crtc_commit_deep(crtc, slot); } } static void grdrm_crtc_restore(grdrm_crtc *crtc) { struct drm_mode_crtc set_crtc = { .crtc_id = crtc->object.id }; grdrm_card *card = crtc->object.card; int r; if (!crtc->old.set) return; set_crtc.set_connectors_ptr = PTR_TO_UINT64(crtc->old.connectors); set_crtc.count_connectors = crtc->old.n_connectors; set_crtc.fb_id = crtc->old.fb; set_crtc.x = crtc->old.fb_x; set_crtc.y = crtc->old.fb_y; set_crtc.gamma_size = crtc->old.gamma; set_crtc.mode_valid = crtc->old.mode_set; set_crtc.mode = crtc->old.mode; r = ioctl(card->fd, DRM_IOCTL_MODE_SETCRTC, &set_crtc); if (r < 0) { r = -errno; log_debug("grdrm: %s: cannot restore crtc %" PRIu32 ": %m", card->base.name, crtc->object.id); grdrm_card_async(card, r); return; } if (crtc->pipe) { ++crtc->pipe->counter; crtc->pipe->base.front = NULL; crtc->pipe->base.flipping = false; } log_debug("grdrm: %s: crtc %" PRIu32 " restored", card->base.name, crtc->object.id); } static void grdrm_crtc_flip_complete(grdrm_crtc *crtc, uint32_t counter, struct drm_event_vblank *event) { bool flipped = false; grdrm_pipe *pipe; grdrm_fb *back = NULL; size_t i; assert(crtc); assert(event); pipe = crtc->pipe; if (!pipe) return; /* We got a page-flip event. To be safe, we reset all FBs on the same * pipe that have smaller flipids than the flip we got as we know they * are executed in order. We need to do this to guarantee * queue-overflows or other missed events don't cause starvation. * Furthermore, if we find the exact FB this event is for, *and* this * is the most recent event, we mark it as front FB and raise a * frame event. */ for (i = 0; i < pipe->base.max_fbs; ++i) { grdrm_fb *fb; if (!pipe->base.fbs[i]) continue; fb = fb_from_base(pipe->base.fbs[i]); if (counter != 0 && counter == pipe->counter && fb->flipid == counter) { pipe->base.front = &fb->base; flipped = true; } if (counter - fb->flipid < UINT16_MAX) { fb->flipid = 0; back = fb; } else if (fb->flipid == 0) { back = fb; } } if (!pipe->base.back) pipe->base.back = &back->base; if (flipped) { crtc->pipe->base.flipping = false; grdev_pipe_frame(&pipe->base); } } /* * Framebuffers */ static int grdrm_fb_new(grdrm_fb **out, grdrm_card *card, const struct drm_mode_modeinfo *mode) { _cleanup_(grdrm_fb_freep) grdrm_fb *fb = NULL; struct drm_mode_create_dumb create_dumb = { }; struct drm_mode_map_dumb map_dumb = { }; struct drm_mode_fb_cmd2 add_fb = { }; unsigned int i; int r; assert_return(out, -EINVAL); assert_return(card, -EINVAL); fb = new0(grdrm_fb, 1); if (!fb) return -ENOMEM; /* TODO: we should choose a compatible format of the previous CRTC * setting to allow page-flip to it. Only choose fallback if the * previous setting was crap (non xrgb32'ish). */ fb->card = card; fb->base.format = DRM_FORMAT_XRGB8888; fb->base.width = mode->hdisplay; fb->base.height = mode->vdisplay; for (i = 0; i < ELEMENTSOF(fb->base.maps); ++i) fb->base.maps[i] = MAP_FAILED; create_dumb.width = fb->base.width; create_dumb.height = fb->base.height; create_dumb.bpp = 32; r = ioctl(card->fd, DRM_IOCTL_MODE_CREATE_DUMB, &create_dumb); if (r < 0) { r = -errno; log_debug("grdrm: %s: cannot create dumb buffer %" PRIu32 "x%" PRIu32": %m", card->base.name, fb->base.width, fb->base.height); return r; } fb->handles[0] = create_dumb.handle; fb->base.strides[0] = create_dumb.pitch; fb->sizes[0] = create_dumb.size; map_dumb.handle = fb->handles[0]; r = ioctl(card->fd, DRM_IOCTL_MODE_MAP_DUMB, &map_dumb); if (r < 0) { r = -errno; log_debug("grdrm: %s: cannot map dumb buffer %" PRIu32 "x%" PRIu32": %m", card->base.name, fb->base.width, fb->base.height); return r; } fb->base.maps[0] = mmap(0, fb->sizes[0], PROT_WRITE, MAP_SHARED, card->fd, map_dumb.offset); if (fb->base.maps[0] == MAP_FAILED) { r = -errno; log_debug("grdrm: %s: cannot memory-map dumb buffer %" PRIu32 "x%" PRIu32": %m", card->base.name, fb->base.width, fb->base.height); return r; } memzero(fb->base.maps[0], fb->sizes[0]); add_fb.width = fb->base.width; add_fb.height = fb->base.height; add_fb.pixel_format = fb->base.format; add_fb.flags = 0; memcpy(add_fb.handles, fb->handles, sizeof(fb->handles)); memcpy(add_fb.pitches, fb->base.strides, sizeof(fb->base.strides)); memcpy(add_fb.offsets, fb->offsets, sizeof(fb->offsets)); r = ioctl(card->fd, DRM_IOCTL_MODE_ADDFB2, &add_fb); if (r < 0) { r = -errno; log_debug("grdrm: %s: cannot add framebuffer %" PRIu32 "x%" PRIu32": %m", card->base.name, fb->base.width, fb->base.height); return r; } fb->id = add_fb.fb_id; *out = fb; fb = NULL; return 0; } grdrm_fb *grdrm_fb_free(grdrm_fb *fb) { unsigned int i; if (!fb) return NULL; assert(fb->card); if (fb->id > 0 && fb->card->fd >= 0) ioctl(fb->card->fd, DRM_IOCTL_MODE_RMFB, fb->id); for (i = 0; i < ELEMENTSOF(fb->handles); ++i) { struct drm_mode_destroy_dumb destroy_dumb = { }; if (fb->base.maps[i] != MAP_FAILED) munmap(fb->base.maps[i], fb->sizes[i]); if (fb->handles[i] > 0 && fb->card->fd >= 0) { destroy_dumb.handle = fb->handles[i]; ioctl(fb->card->fd, DRM_IOCTL_MODE_DESTROY_DUMB, &destroy_dumb); } } free(fb); return NULL; } /* * Pipes */ static void grdrm_pipe_name(char *out, grdrm_crtc *crtc) { /* @out must be at least of size GRDRM_PIPE_NAME_MAX */ sprintf(out, "%s/%" PRIu32, crtc->object.card->base.name, crtc->object.id); } static int grdrm_pipe_new(grdrm_pipe **out, grdrm_crtc *crtc, struct drm_mode_modeinfo *mode, size_t n_fbs) { _cleanup_(grdev_pipe_freep) grdev_pipe *basepipe = NULL; grdrm_card *card = crtc->object.card; char name[GRDRM_PIPE_NAME_MAX]; grdrm_pipe *pipe; int r; assert_return(crtc, -EINVAL); assert_return(grdev_is_drm_card(&card->base), -EINVAL); pipe = new0(grdrm_pipe, 1); if (!pipe) return -ENOMEM; basepipe = &pipe->base; pipe->base = GRDEV_PIPE_INIT(&grdrm_pipe_vtable, &card->base); pipe->crtc = crtc; pipe->base.width = mode->hdisplay; pipe->base.height = mode->vdisplay; grdrm_pipe_name(name, crtc); r = grdev_pipe_add(&pipe->base, name, n_fbs); if (r < 0) return r; if (out) *out = pipe; basepipe = NULL; return 0; } static void grdrm_pipe_free(grdev_pipe *basepipe) { grdrm_pipe *pipe = grdrm_pipe_from_base(basepipe); size_t i; assert(pipe->crtc); for (i = 0; i < pipe->base.max_fbs; ++i) if (pipe->base.fbs[i]) grdrm_fb_free(fb_from_base(pipe->base.fbs[i])); free(pipe); } static const grdev_pipe_vtable grdrm_pipe_vtable = { .free = grdrm_pipe_free, }; /* * Cards */ static void grdrm_name(char *out, dev_t devnum) { /* @out must be at least of size GRDRM_CARD_NAME_MAX */ sprintf(out, "drm/%u:%u", major(devnum), minor(devnum)); } static void grdrm_card_print(grdrm_card *card) { grdrm_object *object; grdrm_crtc *crtc; grdrm_encoder *encoder; grdrm_connector *connector; grdrm_plane *plane; Iterator iter; uint32_t i; char *p, *buf; log_debug("grdrm: %s: state dump", card->base.name); log_debug(" crtcs:"); HASHMAP_FOREACH(object, card->object_map, iter) { if (object->type != GRDRM_TYPE_CRTC) continue; crtc = crtc_from_object(object); log_debug(" (id: %u index: %d)", object->id, object->index); if (crtc->kern.mode_set) log_debug(" mode: %dx%d", crtc->kern.mode.hdisplay, crtc->kern.mode.vdisplay); else log_debug(" mode: "); } log_debug(" encoders:"); HASHMAP_FOREACH(object, card->object_map, iter) { if (object->type != GRDRM_TYPE_ENCODER) continue; encoder = encoder_from_object(object); log_debug(" (id: %u index: %d)", object->id, object->index); if (encoder->kern.used_crtc) log_debug(" crtc: %u", encoder->kern.used_crtc); else log_debug(" crtc: "); buf = malloc((DECIMAL_STR_MAX(uint32_t) + 1) * encoder->kern.n_crtcs + 1); if (buf) { buf[0] = 0; p = buf; for (i = 0; i < encoder->kern.n_crtcs; ++i) p += sprintf(p, " %" PRIu32, encoder->kern.crtcs[i]); log_debug(" possible crtcs:%s", buf); free(buf); } buf = malloc((DECIMAL_STR_MAX(uint32_t) + 1) * encoder->kern.n_clones + 1); if (buf) { buf[0] = 0; p = buf; for (i = 0; i < encoder->kern.n_clones; ++i) p += sprintf(p, " %" PRIu32, encoder->kern.clones[i]); log_debug(" possible clones:%s", buf); free(buf); } } log_debug(" connectors:"); HASHMAP_FOREACH(object, card->object_map, iter) { if (object->type != GRDRM_TYPE_CONNECTOR) continue; connector = connector_from_object(object); log_debug(" (id: %u index: %d)", object->id, object->index); log_debug(" type: %" PRIu32 "-%" PRIu32 " connection: %" PRIu32 " subpixel: %" PRIu32 " extents: %" PRIu32 "x%" PRIu32, connector->kern.type, connector->kern.type_id, connector->kern.connection, connector->kern.subpixel, connector->kern.mm_width, connector->kern.mm_height); if (connector->kern.used_encoder) log_debug(" encoder: %" PRIu32, connector->kern.used_encoder); else log_debug(" encoder: "); buf = malloc((DECIMAL_STR_MAX(uint32_t) + 1) * connector->kern.n_encoders + 1); if (buf) { buf[0] = 0; p = buf; for (i = 0; i < connector->kern.n_encoders; ++i) p += sprintf(p, " %" PRIu32, connector->kern.encoders[i]); log_debug(" possible encoders:%s", buf); free(buf); } for (i = 0; i < connector->kern.n_modes; ++i) { struct drm_mode_modeinfo *mode = &connector->kern.modes[i]; log_debug(" mode: %" PRIu32 "x%" PRIu32, mode->hdisplay, mode->vdisplay); } } log_debug(" planes:"); HASHMAP_FOREACH(object, card->object_map, iter) { if (object->type != GRDRM_TYPE_PLANE) continue; plane = plane_from_object(object); log_debug(" (id: %u index: %d)", object->id, object->index); log_debug(" gamma-size: %" PRIu32, plane->kern.gamma_size); if (plane->kern.used_crtc) log_debug(" crtc: %" PRIu32, plane->kern.used_crtc); else log_debug(" crtc: "); buf = malloc((DECIMAL_STR_MAX(uint32_t) + 1) * plane->kern.n_crtcs + 1); if (buf) { buf[0] = 0; p = buf; for (i = 0; i < plane->kern.n_crtcs; ++i) p += sprintf(p, " %" PRIu32, plane->kern.crtcs[i]); log_debug(" possible crtcs:%s", buf); free(buf); } buf = malloc((DECIMAL_STR_MAX(unsigned int) + 3) * plane->kern.n_formats + 1); if (buf) { buf[0] = 0; p = buf; for (i = 0; i < plane->kern.n_formats; ++i) p += sprintf(p, " 0x%x", (unsigned int)plane->kern.formats[i]); log_debug(" possible formats:%s", buf); free(buf); } } } static int grdrm_card_resync(grdrm_card *card) { _cleanup_free_ uint32_t *crtc_ids = NULL, *encoder_ids = NULL, *connector_ids = NULL, *plane_ids = NULL; uint32_t allocated = 0; grdrm_object *object; Iterator iter; size_t tries; int r; assert(card); card->async_hotplug = false; allocated = 0; /* mark existing objects for possible removal */ HASHMAP_FOREACH(object, card->object_map, iter) object->present = false; for (tries = 0; tries < GRDRM_MAX_TRIES; ++tries) { struct drm_mode_get_plane_res pres; struct drm_mode_card_res res; uint32_t i, max; if (allocated < card->max_ids) { free(crtc_ids); free(encoder_ids); free(connector_ids); free(plane_ids); crtc_ids = new0(uint32_t, card->max_ids); encoder_ids = new0(uint32_t, card->max_ids); connector_ids = new0(uint32_t, card->max_ids); plane_ids = new0(uint32_t, card->max_ids); if (!crtc_ids || !encoder_ids || !connector_ids || !plane_ids) return -ENOMEM; allocated = card->max_ids; } zero(res); res.crtc_id_ptr = PTR_TO_UINT64(crtc_ids); res.connector_id_ptr = PTR_TO_UINT64(connector_ids); res.encoder_id_ptr = PTR_TO_UINT64(encoder_ids); res.count_crtcs = allocated; res.count_encoders = allocated; res.count_connectors = allocated; r = ioctl(card->fd, DRM_IOCTL_MODE_GETRESOURCES, &res); if (r < 0) { r = -errno; log_debug("grdrm: %s: cannot retrieve drm resources: %m", card->base.name); return r; } zero(pres); pres.plane_id_ptr = PTR_TO_UINT64(plane_ids); pres.count_planes = allocated; r = ioctl(card->fd, DRM_IOCTL_MODE_GETPLANERESOURCES, &pres); if (r < 0) { r = -errno; log_debug("grdrm: %s: cannot retrieve drm plane-resources: %m", card->base.name); return r; } max = MAX(MAX(res.count_crtcs, res.count_encoders), MAX(res.count_connectors, pres.count_planes)); if (max > allocated) { uint32_t n; n = ALIGN_POWER2(max); if (!n || n > UINT16_MAX) { log_debug("grdrm: %s: excessive DRM resource limit: %" PRIu32, card->base.name, max); return -ERANGE; } /* retry with resized buffers */ card->max_ids = n; continue; } /* mark available objects as present */ for (i = 0; i < res.count_crtcs; ++i) { object = grdrm_find_object(card, crtc_ids[i]); if (object && object->type == GRDRM_TYPE_CRTC) { object->present = true; object->index = i; crtc_ids[i] = 0; } } for (i = 0; i < res.count_encoders; ++i) { object = grdrm_find_object(card, encoder_ids[i]); if (object && object->type == GRDRM_TYPE_ENCODER) { object->present = true; object->index = i; encoder_ids[i] = 0; } } for (i = 0; i < res.count_connectors; ++i) { object = grdrm_find_object(card, connector_ids[i]); if (object && object->type == GRDRM_TYPE_CONNECTOR) { object->present = true; object->index = i; connector_ids[i] = 0; } } for (i = 0; i < pres.count_planes; ++i) { object = grdrm_find_object(card, plane_ids[i]); if (object && object->type == GRDRM_TYPE_PLANE) { object->present = true; object->index = i; plane_ids[i] = 0; } } /* drop removed objects */ HASHMAP_FOREACH(object, card->object_map, iter) if (!object->present) grdrm_object_free(object); /* add new objects */ card->n_crtcs = res.count_crtcs; for (i = 0; i < res.count_crtcs; ++i) { if (crtc_ids[i] < 1) continue; r = grdrm_crtc_new(NULL, card, crtc_ids[i], i); if (r < 0) return r; } card->n_encoders = res.count_encoders; for (i = 0; i < res.count_encoders; ++i) { if (encoder_ids[i] < 1) continue; r = grdrm_encoder_new(NULL, card, encoder_ids[i], i); if (r < 0) return r; } card->n_connectors = res.count_connectors; for (i = 0; i < res.count_connectors; ++i) { if (connector_ids[i] < 1) continue; r = grdrm_connector_new(NULL, card, connector_ids[i], i); if (r < 0) return r; } card->n_planes = pres.count_planes; for (i = 0; i < pres.count_planes; ++i) { if (plane_ids[i] < 1) continue; r = grdrm_plane_new(NULL, card, plane_ids[i], i); if (r < 0) return r; } /* re-sync objects after object_map is synced */ HASHMAP_FOREACH(object, card->object_map, iter) { switch (object->type) { case GRDRM_TYPE_CRTC: r = grdrm_crtc_resync(crtc_from_object(object)); break; case GRDRM_TYPE_ENCODER: r = grdrm_encoder_resync(encoder_from_object(object)); break; case GRDRM_TYPE_CONNECTOR: r = grdrm_connector_resync(connector_from_object(object)); break; case GRDRM_TYPE_PLANE: r = grdrm_plane_resync(plane_from_object(object)); break; default: assert_not_reached("grdrm: invalid object type"); r = 0; } if (r < 0) return r; if (card->async_hotplug) break; } /* if modeset objects change during sync, start over */ if (card->async_hotplug) { card->async_hotplug = false; continue; } /* cache crtc/connector relationship */ HASHMAP_FOREACH(object, card->object_map, iter) { grdrm_connector *connector; grdrm_encoder *encoder; grdrm_crtc *crtc; if (object->type != GRDRM_TYPE_CONNECTOR) continue; connector = connector_from_object(object); if (connector->kern.connection != 1 || connector->kern.used_encoder < 1) continue; object = grdrm_find_object(card, connector->kern.used_encoder); if (!object || object->type != GRDRM_TYPE_ENCODER) continue; encoder = encoder_from_object(object); if (encoder->kern.used_crtc < 1) continue; object = grdrm_find_object(card, encoder->kern.used_crtc); if (!object || object->type != GRDRM_TYPE_CRTC) continue; crtc = crtc_from_object(object); assert(crtc->kern.n_used_connectors < crtc->kern.max_used_connectors); crtc->kern.used_connectors[crtc->kern.n_used_connectors++] = connector->object.id; } /* cache old crtc settings for later restore */ HASHMAP_FOREACH(object, card->object_map, iter) { grdrm_crtc *crtc; if (object->type != GRDRM_TYPE_CRTC) continue; crtc = crtc_from_object(object); /* Save data if it is the first time we refresh the CRTC. This data can * be used optionally to restore any previous configuration. For * instance, it allows us to restore VT configurations after we close * our session again. */ if (!crtc->old.set) { crtc->old.fb = crtc->kern.used_fb; crtc->old.fb_x = crtc->kern.fb_offset_x; crtc->old.fb_y = crtc->kern.fb_offset_y; crtc->old.gamma = crtc->kern.gamma_size; crtc->old.n_connectors = crtc->kern.n_used_connectors; if (crtc->old.n_connectors) memcpy(crtc->old.connectors, crtc->kern.used_connectors, sizeof(uint32_t) * crtc->old.n_connectors); crtc->old.mode_set = crtc->kern.mode_set; crtc->old.mode = crtc->kern.mode; crtc->old.set = true; } } /* everything synced */ break; } if (tries >= GRDRM_MAX_TRIES) { /* * Ugh! We were unable to sync the DRM card state due to heavy * hotplugging. This should never happen, so print a debug * message and bail out. The next uevent will trigger * this again. */ log_debug("grdrm: %s: hotplug-storm when syncing card", card->base.name); return -EFAULT; } return 0; } static bool card_configure_crtc(grdrm_crtc *crtc, grdrm_connector *connector) { grdrm_card *card = crtc->object.card; grdrm_encoder *encoder; grdrm_object *object; uint32_t i, j; if (crtc->object.assigned || connector->object.assigned) return false; if (connector->kern.connection != 1) return false; for (i = 0; i < connector->kern.n_encoders; ++i) { object = grdrm_find_object(card, connector->kern.encoders[i]); if (!object || object->type != GRDRM_TYPE_ENCODER) continue; encoder = encoder_from_object(object); for (j = 0; j < encoder->kern.n_crtcs; ++j) { if (encoder->kern.crtcs[j] == crtc->object.id) { grdrm_crtc_assign(crtc, connector); return true; } } } return false; } static void grdrm_card_configure(grdrm_card *card) { /* * Modeset Configuration * This is where we update our modeset configuration and assign * connectors to CRTCs. This means, each connector that we want to * enable needs a CRTC, disabled (or unavailable) connectors are left * alone in the dark. Once all CRTCs are assigned, the remaining CRTCs * are disabled. * Sounds trivial, but there're several caveats: * * * Multiple connectors can be driven by the same CRTC. This is * known as 'hardware clone mode'. Advantage over software clone * mode is that only a single CRTC is needed to drive multiple * displays. However, few hardware supports this and it's a huge * headache to configure on dynamic demands. Therefore, we only * support it if configured statically beforehand. * * * CRTCs are not created equal. Some might be much more poweful * than others, including more advanced plane support. So far, our * CRTC selection is random. You need to supply static * configuration if you want special setups. So far, there is no * proper way to do advanced CRTC selection on dynamic demands. It * is not really clear which demands require what CRTC, so, like * everyone else, we do random CRTC selection unless explicitly * states otherwise. * * * Each Connector has a list of possible encoders that can drive * it, and each encoder has a list of possible CRTCs. If this graph * is a tree, assignment is trivial. However, if not, we cannot * reliably decide on configurations beforehand. The encoder is * always selected by the kernel, so we have to actually set a mode * to know which encoder is used. There is no way to ask the kernel * whether a given configuration is possible. This will change with * atomic-modesetting, but until then, we keep our configurations * simple and assume they work all just fine. If one fails * unexpectedly, we print a warning and disable it. * * Configuring a card consists of several steps: * * 1) First of all, we apply any user-configuration. If a user wants * a fixed configuration, we apply it and preserve it. * So far, we don't support user configuration files, so this step * is skipped. * * 2) Secondly, we need to apply any quirks from hwdb. Some hardware * might only support limited configurations or require special * CRTC/Connector mappings. We read this from hwdb and apply it, if * present. * So far, we don't support this as there is no known quirk, so * this step is skipped. * * 3) As deep modesets are expensive, we try to avoid them if * possible. Therefore, we read the current configuration from the * kernel and try to preserve it, if compatible with our demands. * If not, we break it and reassign it in a following step. * * 4) The main step involves configuring all remaining objects. By * default, all available connectors are enabled, except for those * disabled by user-configuration. We lookup a suitable CRTC for * each connector and assign them. As there might be more * connectors than CRTCs, we apply some ordering so users can * select which connectors are more important right now. * So far, we only apply the default ordering, more might be added * in the future. */ grdrm_object *object; grdrm_crtc *crtc; Iterator i, j; /* clear assignments */ HASHMAP_FOREACH(object, card->object_map, i) object->assigned = false; /* preserve existing configurations */ HASHMAP_FOREACH(object, card->object_map, i) { if (object->type != GRDRM_TYPE_CRTC || object->assigned) continue; crtc = crtc_from_object(object); if (crtc->applied) { /* If our mode is set, preserve it. If no connector is * set, modeset either failed or the pipe is unused. In * both cases, leave it alone. It might be tried again * below in case there're remaining connectors. * Otherwise, try restoring the assignments. If they * are no longer valid, leave the pipe untouched. */ if (crtc->set.n_connectors < 1) continue; assert(crtc->set.n_connectors == 1); object = grdrm_find_object(card, crtc->set.connectors[0]); if (!object || object->type != GRDRM_TYPE_CONNECTOR) continue; card_configure_crtc(crtc, connector_from_object(object)); } else if (crtc->kern.mode_set && crtc->kern.n_used_connectors != 1) { /* If our mode is not set on the pipe, we know the kern * information is valid. Try keeping it. If it's not * possible, leave the pipe untouched for later * assignements. */ object = grdrm_find_object(card, crtc->kern.used_connectors[0]); if (!object || object->type != GRDRM_TYPE_CONNECTOR) continue; card_configure_crtc(crtc, connector_from_object(object)); } } /* assign remaining objects */ HASHMAP_FOREACH(object, card->object_map, i) { if (object->type != GRDRM_TYPE_CRTC || object->assigned) continue; crtc = crtc_from_object(object); HASHMAP_FOREACH(object, card->object_map, j) { if (object->type != GRDRM_TYPE_CONNECTOR) continue; if (card_configure_crtc(crtc, connector_from_object(object))) break; } if (!crtc->object.assigned) grdrm_crtc_assign(crtc, NULL); } /* expose configuration */ HASHMAP_FOREACH(object, card->object_map, i) { if (object->type != GRDRM_TYPE_CRTC) continue; grdrm_crtc_expose(crtc_from_object(object)); } } static void grdrm_card_hotplug(grdrm_card *card) { int r; assert(card); if (!card->running) return; card->ready = false; r = grdrm_card_resync(card); if (r < 0) { log_debug("grdrm: %s/%s: cannot re-sync card: %s", card->base.session->name, card->base.name, strerror(-r)); return; } grdev_session_pin(card->base.session); grdrm_card_print(card); grdrm_card_configure(card); card->ready = true; grdev_session_unpin(card->base.session); } static int grdrm_card_io_fn(sd_event_source *s, int fd, uint32_t revents, void *userdata) { grdrm_card *card = userdata; struct drm_event_vblank *vblank; struct drm_event *event; uint32_t id, counter; grdrm_object *object; char buf[4096]; ssize_t l, i; if (revents & (EPOLLHUP | EPOLLERR)) { /* Immediately close device on HUP; no need to flush pending * data.. there're no events we care about here. */ log_debug("grdrm: %s/%s: HUP", card->base.session->name, card->base.name); grdrm_card_close(card); return 0; } if (revents & (EPOLLIN)) { l = read(card->fd, buf, sizeof(buf)); if (l < 0) { if (errno == EAGAIN || errno == EINTR) return 0; log_debug("grdrm: %s/%s: read error: %m", card->base.session->name, card->base.name); grdrm_card_close(card); return 0; } else if ((size_t)l < sizeof(*event)) { log_debug("grdrm: %s/%s: short read of %zd bytes", card->base.session->name, card->base.name, l); return 0; } for (i = 0; i < l; i += event->length) { event = (void*)&buf[i]; if (i + event->length > l) { log_debug("grdrm: %s/%s: truncated event", card->base.session->name, card->base.name); break; } switch (event->type) { case DRM_EVENT_FLIP_COMPLETE: vblank = (void*)event; if (event->length < sizeof(*vblank)) { log_debug("grdrm: %s/%s: truncated vblank event", card->base.session->name, card->base.name); break; } grdrm_decode_vblank_data(vblank->user_data, &id, &counter); object = grdrm_find_object(card, id); if (!object || object->type != GRDRM_TYPE_CRTC) break; grdrm_crtc_flip_complete(crtc_from_object(object), counter, vblank); break; } } } return 0; } static int grdrm_card_add(grdrm_card *card, const char *name) { assert(card); assert(card->fd < 0); card->object_map = hashmap_new(&trivial_hash_ops); if (!card->object_map) return -ENOMEM; return grdev_card_add(&card->base, name); } static void grdrm_card_destroy(grdrm_card *card) { assert(card); assert(!card->running); assert(card->fd < 0); assert(hashmap_size(card->object_map) == 0); hashmap_free(card->object_map); } static void grdrm_card_commit(grdev_card *basecard) { grdrm_card *card = grdrm_card_from_base(basecard); grdrm_object *object; Iterator iter; HASHMAP_FOREACH(object, card->object_map, iter) { if (!card->ready) break; if (object->type != GRDRM_TYPE_CRTC) continue; grdrm_crtc_commit(crtc_from_object(object)); } } static void grdrm_card_restore(grdev_card *basecard) { grdrm_card *card = grdrm_card_from_base(basecard); grdrm_object *object; Iterator iter; HASHMAP_FOREACH(object, card->object_map, iter) { if (!card->ready) break; if (object->type != GRDRM_TYPE_CRTC) continue; grdrm_crtc_restore(crtc_from_object(object)); } } static void grdrm_card_enable(grdrm_card *card) { assert(card); if (card->fd < 0 || card->running) return; /* ignore cards without DUMB_BUFFER capability */ if (!card->cap_dumb) return; assert(card->fd_src); log_debug("grdrm: %s/%s: enable", card->base.session->name, card->base.name); card->running = true; sd_event_source_set_enabled(card->fd_src, SD_EVENT_ON); grdrm_card_hotplug(card); } static void grdrm_card_disable(grdrm_card *card) { grdrm_object *object; Iterator iter; assert(card); if (card->fd < 0 || !card->running) return; assert(card->fd_src); log_debug("grdrm: %s/%s: disable", card->base.session->name, card->base.name); card->running = false; card->ready = false; sd_event_source_set_enabled(card->fd_src, SD_EVENT_OFF); /* stop all pipes */ HASHMAP_FOREACH(object, card->object_map, iter) { grdrm_crtc *crtc; if (object->type != GRDRM_TYPE_CRTC) continue; crtc = crtc_from_object(object); crtc->applied = false; if (crtc->pipe) grdev_pipe_ready(&crtc->pipe->base, false); } } static int grdrm_card_open(grdrm_card *card, int dev_fd) { _cleanup_(grdev_session_unpinp) grdev_session *pin = NULL; _cleanup_close_ int fd = dev_fd; struct drm_get_cap cap; int r, flags; assert(card); assert(dev_fd >= 0); assert(card->fd != dev_fd); pin = grdev_session_pin(card->base.session); grdrm_card_close(card); log_debug("grdrm: %s/%s: open", card->base.session->name, card->base.name); r = fd_nonblock(fd, true); if (r < 0) return r; r = fd_cloexec(fd, true); if (r < 0) return r; flags = fcntl(fd, F_GETFL, 0); if (flags < 0) return -errno; if ((flags & O_ACCMODE) != O_RDWR) return -EACCES; r = sd_event_add_io(card->base.session->context->event, &card->fd_src, fd, EPOLLHUP | EPOLLERR | EPOLLIN, grdrm_card_io_fn, card); if (r < 0) return r; sd_event_source_set_enabled(card->fd_src, SD_EVENT_OFF); card->fd = fd; fd = -1; /* cache DUMB_BUFFER capability */ cap.capability = DRM_CAP_DUMB_BUFFER; cap.value = 0; r = ioctl(card->fd, DRM_IOCTL_GET_CAP, &cap); card->cap_dumb = r >= 0 && cap.value; if (r < 0) log_debug("grdrm: %s/%s: cannot retrieve DUMB_BUFFER capability: %s", card->base.session->name, card->base.name, strerror(-r)); else if (!card->cap_dumb) log_debug("grdrm: %s/%s: DUMB_BUFFER capability not supported", card->base.session->name, card->base.name); /* cache TIMESTAMP_MONOTONIC capability */ cap.capability = DRM_CAP_TIMESTAMP_MONOTONIC; cap.value = 0; r = ioctl(card->fd, DRM_IOCTL_GET_CAP, &cap); card->cap_monotonic = r >= 0 && cap.value; if (r < 0) log_debug("grdrm: %s/%s: cannot retrieve TIMESTAMP_MONOTONIC capability: %s", card->base.session->name, card->base.name, strerror(-r)); else if (!card->cap_monotonic) log_debug("grdrm: %s/%s: TIMESTAMP_MONOTONIC is disabled globally, fix this NOW!", card->base.session->name, card->base.name); return 0; } static void grdrm_card_close(grdrm_card *card) { grdrm_object *object; if (card->fd < 0) return; log_debug("grdrm: %s/%s: close", card->base.session->name, card->base.name); grdrm_card_disable(card); card->fd_src = sd_event_source_unref(card->fd_src); card->fd = safe_close(card->fd); grdev_session_pin(card->base.session); while ((object = hashmap_first(card->object_map))) grdrm_object_free(object); grdev_session_unpin(card->base.session); } static bool grdrm_card_async(grdrm_card *card, int r) { switch (r) { case -EACCES: /* If we get EACCES on runtime DRM calls, we lost DRM-Master * (or we did something terribly wrong). Immediately disable * the card, so we stop all pipes and wait to be activated * again. */ grdrm_card_disable(card); break; case -ENOENT: /* DRM objects can be hotplugged at any time. If an object is * removed that we use, we remember that state so a following * call can test for this. * Note that we also get a uevent as followup, this will resync * the whole device. */ card->async_hotplug = true; break; } return !card->ready; } /* * Unmanaged Cards * The unmanaged DRM card opens the device node for a given DRM device * directly (/dev/dri/cardX) and thus needs sufficient privileges. It opens * the device only if we really require it and releases it as soon as we're * disabled or closed. * The unmanaged element can be used in all situations where you have direct * access to DRM device nodes. Unlike managed DRM elements, it can be used * outside of user sessions and in emergency situations where logind is not * available. */ static void unmanaged_card_enable(grdev_card *basecard) { unmanaged_card *cu = unmanaged_card_from_base(basecard); int r, fd; if (cu->card.fd < 0) { /* try open on activation if it failed during allocation */ fd = open(cu->devnode, O_RDWR | O_CLOEXEC | O_NOCTTY | O_NONBLOCK); if (fd < 0) { /* not fatal; simply ignore the device */ log_debug("grdrm: %s/%s: cannot open node %s: %m", basecard->session->name, basecard->name, cu->devnode); return; } /* we might already be DRM-Master by open(); that's fine */ r = grdrm_card_open(&cu->card, fd); if (r < 0) { log_debug("grdrm: %s/%s: cannot open: %s", basecard->session->name, basecard->name, strerror(-r)); return; } } r = ioctl(cu->card.fd, DRM_IOCTL_SET_MASTER, 0); if (r < 0) { log_debug("grdrm: %s/%s: cannot acquire DRM-Master: %m", basecard->session->name, basecard->name); return; } grdrm_card_enable(&cu->card); } static void unmanaged_card_disable(grdev_card *basecard) { unmanaged_card *cu = unmanaged_card_from_base(basecard); grdrm_card_disable(&cu->card); } static int unmanaged_card_new(grdev_card **out, grdev_session *session, struct udev_device *ud) { _cleanup_(grdev_card_freep) grdev_card *basecard = NULL; char name[GRDRM_CARD_NAME_MAX]; unmanaged_card *cu; const char *devnode; dev_t devnum; int r, fd; assert_return(session, -EINVAL); assert_return(ud, -EINVAL); devnode = udev_device_get_devnode(ud); devnum = udev_device_get_devnum(ud); if (!devnode || devnum == 0) return -ENODEV; grdrm_name(name, devnum); cu = new0(unmanaged_card, 1); if (!cu) return -ENOMEM; basecard = &cu->card.base; cu->card = GRDRM_CARD_INIT(&unmanaged_card_vtable, session); cu->devnode = strdup(devnode); if (!cu->devnode) return -ENOMEM; r = grdrm_card_add(&cu->card, name); if (r < 0) return r; /* try to open but ignore errors */ fd = open(cu->devnode, O_RDWR | O_CLOEXEC | O_NOCTTY | O_NONBLOCK); if (fd < 0) { /* not fatal; allow uaccess based control on activation */ log_debug("grdrm: %s/%s: cannot open node %s: %m", basecard->session->name, basecard->name, cu->devnode); } else { /* We might get DRM-Master implicitly on open(); drop it immediately * so we acquire it only once we're actually enabled. */ ioctl(fd, DRM_IOCTL_DROP_MASTER, 0); r = grdrm_card_open(&cu->card, fd); if (r < 0) log_debug("grdrm: %s/%s: cannot open: %s", basecard->session->name, basecard->name, strerror(-r)); } if (out) *out = basecard; basecard = NULL; return 0; } static void unmanaged_card_free(grdev_card *basecard) { unmanaged_card *cu = unmanaged_card_from_base(basecard); assert(!basecard->enabled); grdrm_card_close(&cu->card); grdrm_card_destroy(&cu->card); free(cu->devnode); free(cu); } static const grdev_card_vtable unmanaged_card_vtable = { .free = unmanaged_card_free, .enable = unmanaged_card_enable, .disable = unmanaged_card_disable, .commit = grdrm_card_commit, .restore = grdrm_card_restore, }; /* * Managed Cards * The managed DRM card uses systemd-logind to acquire DRM devices. This * means, we do not open the device node /dev/dri/cardX directly. Instead, * logind passes us a file-descriptor whenever our session is activated. Thus, * we don't need access to the device node directly. * Furthermore, whenever the session is put asleep, logind revokes the * file-descriptor so we loose access to the device. * Managed DRM cards should be preferred over unmanaged DRM cards whenever * you run inside a user session with exclusive device access. */ static void managed_card_enable(grdev_card *card) { managed_card *cm = managed_card_from_base(card); /* If the device is manually re-enabled, we try to resume our card * management. Note that we have no control over DRM-Master and the fd, * so we have to take over the state from the last logind event. */ if (cm->master) grdrm_card_enable(&cm->card); } static void managed_card_disable(grdev_card *card) { managed_card *cm = managed_card_from_base(card); /* If the device is manually disabled, we keep the FD but put our card * management asleep. This way, we can wake up at any time, but don't * touch the device while asleep. */ grdrm_card_disable(&cm->card); } static int managed_card_pause_device_fn(sd_bus *bus, sd_bus_message *signal, void *userdata, sd_bus_error *ret_error) { managed_card *cm = userdata; grdev_session *session = cm->card.base.session; uint32_t major, minor; const char *mode; int r; /* * We get PauseDevice() signals from logind whenever a device we * requested was, or is about to be, paused. Arguments are major/minor * number of the device and the mode of the operation. * In case the event is not about our device, we ignore it. Otherwise, * we treat it as asynchronous DRM-DROP-MASTER. Note that we might have * already handled an EACCES error from a modeset ioctl, in which case * we already disabled the device. * * @mode can be one of the following: * "pause": The device is about to be paused. We must react * immediately and respond with PauseDeviceComplete(). Once * we replied, logind will pause the device. Note that * logind might apply any kind of timeout and force pause * the device if we don't respond in a timely manner. In * this case, we will receive a second PauseDevice event * with @mode set to "force" (or similar). * "force": The device was disabled forecfully by logind. DRM-Master * was already dropped. This is just an asynchronous * notification so we can put the device asleep (in case * we didn't already notice the dropped DRM-Master). * "gone": This is like "force" but is sent if the device was * paused due to a device-removal event. * * We always handle PauseDevice signals as "force" as we properly * support asynchronously dropping DRM-Master, anyway. But in case * logind sent mode "pause", we also call PauseDeviceComplete() to * immediately acknowledge the request. */ r = sd_bus_message_read(signal, "uus", &major, &minor, &mode); if (r < 0) { log_debug("grdrm: %s/%s: erroneous PauseDevice signal", session->name, cm->card.base.name); return 0; } /* not our device? */ if (makedev(major, minor) != cm->devnum) return 0; cm->master = false; grdrm_card_disable(&cm->card); if (streq(mode, "pause")) { _cleanup_bus_message_unref_ sd_bus_message *m = NULL; /* * Sending PauseDeviceComplete() is racy if logind triggers the * timeout. That is, if we take too long and logind pauses the * device by sending a forced PauseDevice, our * PauseDeviceComplete call will be stray. That's fine, though. * logind ignores such stray calls. Only if logind also sent a * further PauseDevice() signal, it might match our call * incorrectly to the newer PauseDevice(). That's fine, too, as * we handle that event asynchronously, anyway. Therefore, * whatever happens, we're fine. Yay! */ r = sd_bus_message_new_method_call(session->context->sysbus, &m, "org.freedesktop.login1", session->path, "org.freedesktop.login1.Session", "PauseDeviceComplete"); if (r >= 0) { r = sd_bus_message_append(m, "uu", major, minor); if (r >= 0) r = sd_bus_send(session->context->sysbus, m, NULL); } if (r < 0) log_debug("grdrm: %s/%s: cannot send PauseDeviceComplete: %s", session->name, cm->card.base.name, strerror(-r)); } return 0; } static int managed_card_resume_device_fn(sd_bus *bus, sd_bus_message *signal, void *userdata, sd_bus_error *ret_error) { managed_card *cm = userdata; grdev_session *session = cm->card.base.session; uint32_t major, minor; int r, fd; /* * We get ResumeDevice signals whenever logind resumed a previously * paused device. The arguments contain the major/minor number of the * related device and a new file-descriptor for the freshly opened * device-node. * If the signal is not about our device, we simply ignore it. * Otherwise, we immediately resume the device. Note that we drop the * new file-descriptor as we already have one from TakeDevice(). logind * preserves the file-context across pause/resume for DRM but only * drops/acquires DRM-Master accordingly. This way, our context (like * DRM-FBs and BOs) is preserved. */ r = sd_bus_message_read(signal, "uuh", &major, &minor, &fd); if (r < 0) { log_debug("grdrm: %s/%s: erroneous ResumeDevice signal", session->name, cm->card.base.name); return 0; } /* not our device? */ if (makedev(major, minor) != cm->devnum) return 0; if (cm->card.fd < 0) { /* This shouldn't happen. We should already own an FD from * TakeDevice(). However, lets be safe and use this FD in case * we really don't have one. There is no harm in doing this * and our code works fine this way. */ fd = fcntl(fd, F_DUPFD_CLOEXEC, 3); if (fd < 0) { log_debug("grdrm: %s/%s: cannot duplicate fd: %m", session->name, cm->card.base.name); return 0; } r = grdrm_card_open(&cm->card, fd); if (r < 0) { log_debug("grdrm: %s/%s: cannot open: %s", session->name, cm->card.base.name, strerror(-r)); return 0; } } cm->master = true; if (cm->card.base.enabled) grdrm_card_enable(&cm->card); return 0; } static int managed_card_setup_bus(managed_card *cm) { grdev_session *session = cm->card.base.session; _cleanup_free_ char *match = NULL; int r; match = strjoin("type='signal'," "sender='org.freedesktop.login1'," "interface='org.freedesktop.login1.Session'," "member='PauseDevice'," "path='", session->path, "'", NULL); if (!match) return -ENOMEM; r = sd_bus_add_match(session->context->sysbus, &cm->slot_pause_device, match, managed_card_pause_device_fn, cm); if (r < 0) return r; free(match); match = strjoin("type='signal'," "sender='org.freedesktop.login1'," "interface='org.freedesktop.login1.Session'," "member='ResumeDevice'," "path='", session->path, "'", NULL); if (!match) return -ENOMEM; r = sd_bus_add_match(session->context->sysbus, &cm->slot_resume_device, match, managed_card_resume_device_fn, cm); if (r < 0) return r; return 0; } static int managed_card_take_device_fn(sd_bus *bus, sd_bus_message *reply, void *userdata, sd_bus_error *ret_error) { managed_card *cm = userdata; grdev_session *session = cm->card.base.session; int r, paused, fd; cm->slot_take_device = sd_bus_slot_unref(cm->slot_take_device); if (sd_bus_message_is_method_error(reply, NULL)) { const sd_bus_error *error = sd_bus_message_get_error(reply); log_debug("grdrm: %s/%s: TakeDevice failed: %s: %s", session->name, cm->card.base.name, error->name, error->message); return 0; } cm->acquired = true; r = sd_bus_message_read(reply, "hb", &fd, &paused); if (r < 0) { log_debug("grdrm: %s/%s: erroneous TakeDevice reply", session->name, cm->card.base.name); return 0; } fd = fcntl(fd, F_DUPFD_CLOEXEC, 3); if (fd < 0) { log_debug("grdrm: %s/%s: cannot duplicate fd: %m", session->name, cm->card.base.name); return 0; } r = grdrm_card_open(&cm->card, fd); if (r < 0) { log_debug("grdrm: %s/%s: cannot open: %s", session->name, cm->card.base.name, strerror(-r)); return 0; } if (!paused && cm->card.base.enabled) grdrm_card_enable(&cm->card); return 0; } static void managed_card_take_device(managed_card *cm) { _cleanup_bus_message_unref_ sd_bus_message *m = NULL; grdev_session *session = cm->card.base.session; int r; r = sd_bus_message_new_method_call(session->context->sysbus, &m, "org.freedesktop.login1", session->path, "org.freedesktop.login1.Session", "TakeDevice"); if (r < 0) goto error; r = sd_bus_message_append(m, "uu", major(cm->devnum), minor(cm->devnum)); if (r < 0) goto error; r = sd_bus_call_async(session->context->sysbus, &cm->slot_take_device, m, managed_card_take_device_fn, cm, 0); if (r < 0) goto error; cm->requested = true; return; error: log_debug("grdrm: %s/%s: cannot send TakeDevice request: %s", session->name, cm->card.base.name, strerror(-r)); } static void managed_card_release_device(managed_card *cm) { _cleanup_bus_message_unref_ sd_bus_message *m = NULL; grdev_session *session = cm->card.base.session; int r; /* * If TakeDevice() is pending or was successful, make sure to * release the device again. We don't care for return-values, * so send it without waiting or callbacks. * If a failed TakeDevice() is pending, but someone else took * the device on the same bus-connection, we might incorrectly * release their device. This is an unlikely race, though. * Furthermore, you really shouldn't have two users of the * controller-API on the same session, on the same devices, *AND* on * the same bus-connection. So we don't care for that race.. */ grdrm_card_close(&cm->card); cm->requested = false; if (!cm->acquired && !cm->slot_take_device) return; cm->slot_take_device = sd_bus_slot_unref(cm->slot_take_device); cm->acquired = false; r = sd_bus_message_new_method_call(session->context->sysbus, &m, "org.freedesktop.login1", session->path, "org.freedesktop.login1.Session", "ReleaseDevice"); if (r >= 0) { r = sd_bus_message_append(m, "uu", major(cm->devnum), minor(cm->devnum)); if (r >= 0) r = sd_bus_send(session->context->sysbus, m, NULL); } if (r < 0 && r != -ENOTCONN) log_debug("grdrm: %s/%s: cannot send ReleaseDevice: %s", session->name, cm->card.base.name, strerror(-r)); } static int managed_card_new(grdev_card **out, grdev_session *session, struct udev_device *ud) { _cleanup_(grdev_card_freep) grdev_card *basecard = NULL; char name[GRDRM_CARD_NAME_MAX]; managed_card *cm; dev_t devnum; int r; assert_return(session, -EINVAL); assert_return(session->managed, -EINVAL); assert_return(session->context->sysbus, -EINVAL); assert_return(ud, -EINVAL); devnum = udev_device_get_devnum(ud); if (devnum == 0) return -ENODEV; grdrm_name(name, devnum); cm = new0(managed_card, 1); if (!cm) return -ENOMEM; basecard = &cm->card.base; cm->card = GRDRM_CARD_INIT(&managed_card_vtable, session); cm->devnum = devnum; r = managed_card_setup_bus(cm); if (r < 0) return r; r = grdrm_card_add(&cm->card, name); if (r < 0) return r; managed_card_take_device(cm); if (out) *out = basecard; basecard = NULL; return 0; } static void managed_card_free(grdev_card *basecard) { managed_card *cm = managed_card_from_base(basecard); assert(!basecard->enabled); managed_card_release_device(cm); cm->slot_resume_device = sd_bus_slot_unref(cm->slot_resume_device); cm->slot_pause_device = sd_bus_slot_unref(cm->slot_pause_device); grdrm_card_destroy(&cm->card); free(cm); } static const grdev_card_vtable managed_card_vtable = { .free = managed_card_free, .enable = managed_card_enable, .disable = managed_card_disable, .commit = grdrm_card_commit, .restore = grdrm_card_restore, }; /* * Generic Constructor * Instead of relying on the caller to choose between managed and unmanaged * DRM devices, the grdev_drm_new() constructor does that for you (by * looking at session->managed). */ bool grdev_is_drm_card(grdev_card *basecard) { return basecard && (basecard->vtable == &unmanaged_card_vtable || basecard->vtable == &managed_card_vtable); } grdev_card *grdev_find_drm_card(grdev_session *session, dev_t devnum) { char name[GRDRM_CARD_NAME_MAX]; assert_return(session, NULL); assert_return(devnum != 0, NULL); grdrm_name(name, devnum); return grdev_find_card(session, name); } int grdev_drm_card_new(grdev_card **out, grdev_session *session, struct udev_device *ud) { assert_return(session, -EINVAL); assert_return(ud, -EINVAL); return session->managed ? managed_card_new(out, session, ud) : unmanaged_card_new(out, session, ud); } void grdev_drm_card_hotplug(grdev_card *basecard, struct udev_device *ud) { const char *p, *action; grdrm_card *card; dev_t devnum; assert(basecard); assert(grdev_is_drm_card(basecard)); assert(ud); card = grdrm_card_from_base(basecard); action = udev_device_get_action(ud); if (!action || streq(action, "add") || streq(action, "remove")) { /* If we get add/remove events on DRM nodes without devnum, we * got hotplugged DRM objects so refresh the device. */ devnum = udev_device_get_devnum(ud); if (devnum == 0) grdrm_card_hotplug(card); } else if (streq_ptr(action, "change")) { /* A change event with HOTPLUG=1 is sent whenever a connector * changed state. Refresh the device to update our state. */ p = udev_device_get_property_value(ud, "HOTPLUG"); if (streq_ptr(p, "1")) grdrm_card_hotplug(card); } }