1 /*-*- Mode: C; c-basic-offset: 8; indent-tabs-mode: nil -*-*/
4 This file is part of systemd.
6 Copyright (C) 2014 David Herrmann <dh.herrmann@gmail.com>
8 systemd is free software; you can redistribute it and/or modify it
9 under the terms of the GNU Lesser General Public License as published by
10 the Free Software Foundation; either version 2.1 of the License, or
11 (at your option) any later version.
13 systemd is distributed in the hope that it will be useful, but
14 WITHOUT ANY WARRANTY; without even the implied warranty of
15 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
16 Lesser General Public License for more details.
18 You should have received a copy of the GNU Lesser General Public License
19 along with systemd; If not, see <http://www.gnu.org/licenses/>.
27 #include <sys/ioctl.h>
29 #include <sys/types.h>
30 #include <systemd/sd-bus.h>
31 #include <systemd/sd-event.h>
34 /* Yuck! DRM headers need system headers included first.. but we have to
35 * include it before shared/missing.h to avoid redefining ioctl bits */
37 #include <drm_fourcc.h>
43 #include "grdev-internal.h"
45 #include "udev-util.h"
48 #define GRDRM_MAX_TRIES (16)
50 typedef struct grdrm_object grdrm_object;
51 typedef struct grdrm_plane grdrm_plane;
52 typedef struct grdrm_connector grdrm_connector;
53 typedef struct grdrm_encoder grdrm_encoder;
54 typedef struct grdrm_crtc grdrm_crtc;
56 typedef struct grdrm_fb grdrm_fb;
57 typedef struct grdrm_pipe grdrm_pipe;
58 typedef struct grdrm_card grdrm_card;
59 typedef struct unmanaged_card unmanaged_card;
60 typedef struct managed_card managed_card;
79 void (*free_fn) (grdrm_object *object);
102 struct grdrm_connector {
108 uint32_t used_encoder;
115 uint32_t max_encoders;
119 struct drm_mode_modeinfo *modes;
123 uint64_t *prop_values;
127 struct grdrm_encoder {
148 uint32_t fb_offset_x;
149 uint32_t fb_offset_y;
152 uint32_t n_used_connectors;
153 uint32_t max_used_connectors;
154 uint32_t *used_connectors;
157 struct drm_mode_modeinfo mode;
167 uint32_t n_connectors;
168 uint32_t *connectors;
171 struct drm_mode_modeinfo mode;
175 struct drm_mode_modeinfo mode;
176 uint32_t n_connectors;
177 uint32_t max_connectors;
178 uint32_t *connectors;
186 #define GRDRM_OBJECT_INIT(_card, _id, _index, _type, _free_fn) ((grdrm_object){ \
191 .free_fn = (_free_fn), \
194 grdrm_object *grdrm_find_object(grdrm_card *card, uint32_t id);
195 int grdrm_object_add(grdrm_object *object);
196 grdrm_object *grdrm_object_free(grdrm_object *object);
198 DEFINE_TRIVIAL_CLEANUP_FUNC(grdrm_object*, grdrm_object_free);
200 int grdrm_plane_new(grdrm_plane **out, grdrm_card *card, uint32_t id, uint32_t index);
201 int grdrm_connector_new(grdrm_connector **out, grdrm_card *card, uint32_t id, uint32_t index);
202 int grdrm_encoder_new(grdrm_encoder **out, grdrm_card *card, uint32_t id, uint32_t index);
203 int grdrm_crtc_new(grdrm_crtc **out, grdrm_card *card, uint32_t id, uint32_t index);
205 #define plane_from_object(_obj) container_of((_obj), grdrm_plane, object)
206 #define connector_from_object(_obj) container_of((_obj), grdrm_connector, object)
207 #define encoder_from_object(_obj) container_of((_obj), grdrm_encoder, object)
208 #define crtc_from_object(_obj) container_of((_obj), grdrm_crtc, object)
224 static int grdrm_fb_new(grdrm_fb **out, grdrm_card *card, const struct drm_mode_modeinfo *mode);
225 grdrm_fb *grdrm_fb_free(grdrm_fb *fb);
227 DEFINE_TRIVIAL_CLEANUP_FUNC(grdrm_fb*, grdrm_fb_free);
229 #define fb_from_base(_fb) container_of((_fb), grdrm_fb, base)
241 #define grdrm_pipe_from_base(_e) container_of((_e), grdrm_pipe, base)
243 #define GRDRM_PIPE_NAME_MAX (GRDRM_CARD_NAME_MAX + 1 + DECIMAL_STR_MAX(uint32_t))
245 static const grdev_pipe_vtable grdrm_pipe_vtable;
247 static int grdrm_pipe_new(grdrm_pipe **out, grdrm_crtc *crtc, struct drm_mode_modeinfo *mode, size_t n_fbs);
257 sd_event_source *fd_src;
261 uint32_t n_connectors;
266 bool async_hotplug : 1;
271 bool cap_monotonic : 1;
274 struct unmanaged_card {
279 struct managed_card {
283 sd_bus_slot *slot_pause_device;
284 sd_bus_slot *slot_resume_device;
285 sd_bus_slot *slot_take_device;
287 bool requested : 1; /* TakeDevice() was sent */
288 bool acquired : 1; /* TakeDevice() was successful */
289 bool master : 1; /* we are DRM-Master */
292 #define grdrm_card_from_base(_e) container_of((_e), grdrm_card, base)
293 #define unmanaged_card_from_base(_e) \
294 container_of(grdrm_card_from_base(_e), unmanaged_card, card)
295 #define managed_card_from_base(_e) \
296 container_of(grdrm_card_from_base(_e), managed_card, card)
298 #define GRDRM_CARD_INIT(_vtable, _session) ((grdrm_card){ \
299 .base = GRDEV_CARD_INIT((_vtable), (_session)), \
304 #define GRDRM_CARD_NAME_MAX (6 + DECIMAL_STR_MAX(unsigned) * 2)
306 static const grdev_card_vtable unmanaged_card_vtable;
307 static const grdev_card_vtable managed_card_vtable;
309 static int grdrm_card_open(grdrm_card *card, int dev_fd);
310 static void grdrm_card_close(grdrm_card *card);
311 static bool grdrm_card_async(grdrm_card *card, int r);
314 * The page-flip event of the kernel provides 64bit of arbitrary user-data. As
315 * drivers tend to drop events on intermediate deep mode-sets or because we
316 * might receive events during session activation, we try to avoid allocaing
317 * dynamic data on those events. Instead, we safe the CRTC id plus a 32bit
318 * counter in there. This way, we only get 32bit counters, not 64bit, but that
319 * should be more than enough. On the bright side, we no longer care whether we
320 * lose events. No memory leaks will occur.
321 * Modern DRM drivers might be fixed to no longer leak events, but we want to
322 * be safe. And associating dynamically allocated data with those events is
323 * kinda ugly, anyway.
326 static uint64_t grdrm_encode_vblank_data(uint32_t id, uint32_t counter) {
327 return id | ((uint64_t)counter << 32);
330 static void grdrm_decode_vblank_data(uint64_t data, uint32_t *out_id, uint32_t *out_counter) {
332 *out_id = data & 0xffffffffU;
334 *out_counter = (data >> 32) & 0xffffffffU;
337 static bool grdrm_modes_compatible(const struct drm_mode_modeinfo *a, const struct drm_mode_modeinfo *b) {
341 /* Test whether both modes are compatible according to our internal
342 * assumptions on modes. This comparison is highly dependent on how
343 * we treat modes in grdrm. If we export mode details, we need to
344 * make this comparison much stricter. */
346 if (a->hdisplay != b->hdisplay)
348 if (a->vdisplay != b->vdisplay)
350 if (a->vrefresh != b->vrefresh)
360 grdrm_object *grdrm_find_object(grdrm_card *card, uint32_t id) {
361 assert_return(card, NULL);
363 return id > 0 ? hashmap_get(card->object_map, UINT32_TO_PTR(id)) : NULL;
366 int grdrm_object_add(grdrm_object *object) {
370 assert(object->card);
371 assert(object->id > 0);
372 assert(IN_SET(object->type, GRDRM_TYPE_CRTC, GRDRM_TYPE_ENCODER, GRDRM_TYPE_CONNECTOR, GRDRM_TYPE_PLANE));
373 assert(object->free_fn);
375 if (object->index >= 32)
376 log_debug("grdrm: %s: object index exceeds 32bit masks: type=%u, index=%" PRIu32,
377 object->card->base.name, object->type, object->index);
379 r = hashmap_put(object->card->object_map, UINT32_TO_PTR(object->id), object);
386 grdrm_object *grdrm_object_free(grdrm_object *object) {
390 assert(object->card);
391 assert(object->id > 0);
392 assert(IN_SET(object->type, GRDRM_TYPE_CRTC, GRDRM_TYPE_ENCODER, GRDRM_TYPE_CONNECTOR, GRDRM_TYPE_PLANE));
393 assert(object->free_fn);
395 hashmap_remove_value(object->card->object_map, UINT32_TO_PTR(object->id), object);
397 object->free_fn(object);
405 static void plane_free(grdrm_object *object) {
406 grdrm_plane *plane = plane_from_object(object);
408 free(plane->kern.formats);
409 free(plane->kern.crtcs);
413 int grdrm_plane_new(grdrm_plane **out, grdrm_card *card, uint32_t id, uint32_t index) {
414 _cleanup_(grdrm_object_freep) grdrm_object *object = NULL;
420 plane = new0(grdrm_plane, 1);
424 object = &plane->object;
425 *object = GRDRM_OBJECT_INIT(card, id, index, GRDRM_TYPE_PLANE, plane_free);
427 plane->kern.max_crtcs = 32;
428 plane->kern.crtcs = new0(uint32_t, plane->kern.max_crtcs);
429 if (!plane->kern.crtcs)
432 plane->kern.max_formats = 32;
433 plane->kern.formats = new0(uint32_t, plane->kern.max_formats);
434 if (!plane->kern.formats)
437 r = grdrm_object_add(object);
447 static int grdrm_plane_resync(grdrm_plane *plane) {
448 grdrm_card *card = plane->object.card;
454 for (tries = 0; tries < GRDRM_MAX_TRIES; ++tries) {
455 struct drm_mode_get_plane res;
456 grdrm_object *object;
457 bool resized = false;
461 res.plane_id = plane->object.id;
462 res.format_type_ptr = PTR_TO_UINT64(plane->kern.formats);
463 res.count_format_types = plane->kern.max_formats;
465 r = ioctl(card->fd, DRM_IOCTL_MODE_GETPLANE, &res);
469 card->async_hotplug = true;
471 log_debug("grdrm: %s: plane %u removed during resync", card->base.name, plane->object.id);
473 log_debug("grdrm: %s: cannot retrieve plane %u: %m", card->base.name, plane->object.id);
479 plane->kern.n_crtcs = 0;
480 memzero(plane->kern.crtcs, sizeof(uint32_t) * plane->kern.max_crtcs);
482 HASHMAP_FOREACH(object, card->object_map, iter) {
483 if (object->type != GRDRM_TYPE_CRTC || object->index >= 32)
485 if (!(res.possible_crtcs & (1 << object->index)))
487 if (plane->kern.n_crtcs >= 32) {
488 log_debug("grdrm: %s: possible_crtcs of plane %" PRIu32 " exceeds 32bit mask",
489 card->base.name, plane->object.id);
493 plane->kern.crtcs[plane->kern.n_crtcs++] = object->id;
496 if (res.count_format_types > plane->kern.max_formats) {
499 max = ALIGN_POWER2(res.count_format_types);
500 if (!max || max > UINT16_MAX) {
501 log_debug("grdrm: %s: excessive plane resource limit: %" PRIu32, card->base.name, max);
505 t = realloc(plane->kern.formats, sizeof(*t) * max);
509 plane->kern.formats = t;
510 plane->kern.max_formats = max;
517 plane->kern.n_formats = res.count_format_types;
518 plane->kern.used_crtc = res.crtc_id;
519 plane->kern.used_fb = res.fb_id;
520 plane->kern.gamma_size = res.gamma_size;
525 if (tries >= GRDRM_MAX_TRIES) {
526 log_debug("grdrm: %s: plane %u not settled for retrieval", card->base.name, plane->object.id);
537 static void connector_free(grdrm_object *object) {
538 grdrm_connector *connector = connector_from_object(object);
540 free(connector->kern.prop_values);
541 free(connector->kern.prop_ids);
542 free(connector->kern.modes);
543 free(connector->kern.encoders);
547 int grdrm_connector_new(grdrm_connector **out, grdrm_card *card, uint32_t id, uint32_t index) {
548 _cleanup_(grdrm_object_freep) grdrm_object *object = NULL;
549 grdrm_connector *connector;
554 connector = new0(grdrm_connector, 1);
558 object = &connector->object;
559 *object = GRDRM_OBJECT_INIT(card, id, index, GRDRM_TYPE_CONNECTOR, connector_free);
561 connector->kern.max_encoders = 32;
562 connector->kern.encoders = new0(uint32_t, connector->kern.max_encoders);
563 if (!connector->kern.encoders)
566 connector->kern.max_modes = 32;
567 connector->kern.modes = new0(struct drm_mode_modeinfo, connector->kern.max_modes);
568 if (!connector->kern.modes)
571 connector->kern.max_props = 32;
572 connector->kern.prop_ids = new0(uint32_t, connector->kern.max_props);
573 connector->kern.prop_values = new0(uint64_t, connector->kern.max_props);
574 if (!connector->kern.prop_ids || !connector->kern.prop_values)
577 r = grdrm_object_add(object);
587 static int grdrm_connector_resync(grdrm_connector *connector) {
588 grdrm_card *card = connector->object.card;
594 for (tries = 0; tries < GRDRM_MAX_TRIES; ++tries) {
595 struct drm_mode_get_connector res;
596 bool resized = false;
600 res.connector_id = connector->object.id;
601 res.encoders_ptr = PTR_TO_UINT64(connector->kern.encoders);
602 res.props_ptr = PTR_TO_UINT64(connector->kern.prop_ids);
603 res.prop_values_ptr = PTR_TO_UINT64(connector->kern.prop_values);
604 res.count_encoders = connector->kern.max_encoders;
605 res.count_props = connector->kern.max_props;
607 /* The kernel reads modes from the EDID information only if we
608 * pass count_modes==0. This is a legacy hack for libdrm (which
609 * called every ioctl twice). Now we have to adopt.. *sigh*.
610 * If we never received an hotplug event, there's no reason to
611 * sync modes. EDID reads are heavy, so skip that if not
615 res.modes_ptr = PTR_TO_UINT64(connector->kern.modes);
616 res.count_modes = connector->kern.max_modes;
622 r = ioctl(card->fd, DRM_IOCTL_MODE_GETCONNECTOR, &res);
626 card->async_hotplug = true;
628 log_debug("grdrm: %s: connector %u removed during resync", card->base.name, connector->object.id);
630 log_debug("grdrm: %s: cannot retrieve connector %u: %m", card->base.name, connector->object.id);
636 if (res.count_encoders > connector->kern.max_encoders) {
639 max = ALIGN_POWER2(res.count_encoders);
640 if (!max || max > UINT16_MAX) {
641 log_debug("grdrm: %s: excessive connector resource limit: %" PRIu32, card->base.name, max);
645 t = realloc(connector->kern.encoders, sizeof(*t) * max);
649 connector->kern.encoders = t;
650 connector->kern.max_encoders = max;
654 if (res.count_modes > connector->kern.max_modes) {
655 struct drm_mode_modeinfo *t;
657 max = ALIGN_POWER2(res.count_modes);
658 if (!max || max > UINT16_MAX) {
659 log_debug("grdrm: %s: excessive connector resource limit: %" PRIu32, card->base.name, max);
663 t = realloc(connector->kern.modes, sizeof(*t) * max);
667 connector->kern.modes = t;
668 connector->kern.max_modes = max;
672 if (res.count_props > connector->kern.max_props) {
676 max = ALIGN_POWER2(res.count_props);
677 if (!max || max > UINT16_MAX) {
678 log_debug("grdrm: %s: excessive connector resource limit: %" PRIu32, card->base.name, max);
682 tids = realloc(connector->kern.prop_ids, sizeof(*tids) * max);
685 connector->kern.prop_ids = tids;
687 tvals = realloc(connector->kern.prop_values, sizeof(*tvals) * max);
690 connector->kern.prop_values = tvals;
692 connector->kern.max_props = max;
699 connector->kern.n_encoders = res.count_encoders;
700 connector->kern.n_props = res.count_props;
701 connector->kern.type = res.connector_type;
702 connector->kern.type_id = res.connector_type_id;
703 connector->kern.used_encoder = res.encoder_id;
704 connector->kern.connection = res.connection;
705 connector->kern.mm_width = res.mm_width;
706 connector->kern.mm_height = res.mm_height;
707 connector->kern.subpixel = res.subpixel;
708 if (res.modes_ptr == PTR_TO_UINT64(connector->kern.modes))
709 connector->kern.n_modes = res.count_modes;
714 if (tries >= GRDRM_MAX_TRIES) {
715 log_debug("grdrm: %s: connector %u not settled for retrieval", card->base.name, connector->object.id);
726 static void encoder_free(grdrm_object *object) {
727 grdrm_encoder *encoder = encoder_from_object(object);
729 free(encoder->kern.clones);
730 free(encoder->kern.crtcs);
734 int grdrm_encoder_new(grdrm_encoder **out, grdrm_card *card, uint32_t id, uint32_t index) {
735 _cleanup_(grdrm_object_freep) grdrm_object *object = NULL;
736 grdrm_encoder *encoder;
741 encoder = new0(grdrm_encoder, 1);
745 object = &encoder->object;
746 *object = GRDRM_OBJECT_INIT(card, id, index, GRDRM_TYPE_ENCODER, encoder_free);
748 encoder->kern.max_crtcs = 32;
749 encoder->kern.crtcs = new0(uint32_t, encoder->kern.max_crtcs);
750 if (!encoder->kern.crtcs)
753 encoder->kern.max_clones = 32;
754 encoder->kern.clones = new0(uint32_t, encoder->kern.max_clones);
755 if (!encoder->kern.clones)
758 r = grdrm_object_add(object);
768 static int grdrm_encoder_resync(grdrm_encoder *encoder) {
769 grdrm_card *card = encoder->object.card;
770 struct drm_mode_get_encoder res;
771 grdrm_object *object;
778 res.encoder_id = encoder->object.id;
780 r = ioctl(card->fd, DRM_IOCTL_MODE_GETENCODER, &res);
784 card->async_hotplug = true;
786 log_debug("grdrm: %s: encoder %u removed during resync", card->base.name, encoder->object.id);
788 log_debug("grdrm: %s: cannot retrieve encoder %u: %m", card->base.name, encoder->object.id);
794 encoder->kern.type = res.encoder_type;
795 encoder->kern.used_crtc = res.crtc_id;
797 encoder->kern.n_crtcs = 0;
798 memzero(encoder->kern.crtcs, sizeof(uint32_t) * encoder->kern.max_crtcs);
800 HASHMAP_FOREACH(object, card->object_map, iter) {
801 if (object->type != GRDRM_TYPE_CRTC || object->index >= 32)
803 if (!(res.possible_crtcs & (1 << object->index)))
805 if (encoder->kern.n_crtcs >= 32) {
806 log_debug("grdrm: %s: possible_crtcs exceeds 32bit mask", card->base.name);
810 encoder->kern.crtcs[encoder->kern.n_crtcs++] = object->id;
813 encoder->kern.n_clones = 0;
814 memzero(encoder->kern.clones, sizeof(uint32_t) * encoder->kern.max_clones);
816 HASHMAP_FOREACH(object, card->object_map, iter) {
817 if (object->type != GRDRM_TYPE_ENCODER || object->index >= 32)
819 if (!(res.possible_clones & (1 << object->index)))
821 if (encoder->kern.n_clones >= 32) {
822 log_debug("grdrm: %s: possible_encoders exceeds 32bit mask", card->base.name);
826 encoder->kern.clones[encoder->kern.n_clones++] = object->id;
836 static void crtc_free(grdrm_object *object) {
837 grdrm_crtc *crtc = crtc_from_object(object);
840 grdev_pipe_free(&crtc->pipe->base);
841 free(crtc->set.connectors);
842 free(crtc->old.connectors);
843 free(crtc->kern.used_connectors);
847 int grdrm_crtc_new(grdrm_crtc **out, grdrm_card *card, uint32_t id, uint32_t index) {
848 _cleanup_(grdrm_object_freep) grdrm_object *object = NULL;
854 crtc = new0(grdrm_crtc, 1);
858 object = &crtc->object;
859 *object = GRDRM_OBJECT_INIT(card, id, index, GRDRM_TYPE_CRTC, crtc_free);
861 crtc->kern.max_used_connectors = 32;
862 crtc->kern.used_connectors = new0(uint32_t, crtc->kern.max_used_connectors);
863 if (!crtc->kern.used_connectors)
866 crtc->old.connectors = new0(uint32_t, crtc->kern.max_used_connectors);
867 if (!crtc->old.connectors)
870 r = grdrm_object_add(object);
880 static int grdrm_crtc_resync(grdrm_crtc *crtc) {
881 grdrm_card *card = crtc->object.card;
882 struct drm_mode_crtc res = { .crtc_id = crtc->object.id };
887 /* make sure we can cache any combination later */
888 if (card->n_connectors > crtc->kern.max_used_connectors) {
891 max = ALIGN_POWER2(card->n_connectors);
895 t = realloc_multiply(crtc->kern.used_connectors, sizeof(*t), max);
899 crtc->kern.used_connectors = t;
900 crtc->kern.max_used_connectors = max;
902 if (!crtc->old.set) {
903 crtc->old.connectors = calloc(sizeof(*t), max);
904 if (!crtc->old.connectors)
909 /* GETCRTC doesn't return connectors. We have to read all
910 * encoder-state and deduce the setup ourselves.. */
911 crtc->kern.n_used_connectors = 0;
913 r = ioctl(card->fd, DRM_IOCTL_MODE_GETCRTC, &res);
917 card->async_hotplug = true;
919 log_debug("grdrm: %s: crtc %u removed during resync", card->base.name, crtc->object.id);
921 log_debug("grdrm: %s: cannot retrieve crtc %u: %m", card->base.name, crtc->object.id);
927 crtc->kern.used_fb = res.fb_id;
928 crtc->kern.fb_offset_x = res.x;
929 crtc->kern.fb_offset_y = res.y;
930 crtc->kern.gamma_size = res.gamma_size;
931 crtc->kern.mode_set = res.mode_valid;
932 crtc->kern.mode = res.mode;
937 static void grdrm_crtc_assign(grdrm_crtc *crtc, grdrm_connector *connector) {
938 uint32_t n_connectors;
942 assert(!crtc->object.assigned);
943 assert(!connector || !connector->object.assigned);
945 /* always mark both as assigned; even if assignments cannot be set */
946 crtc->object.assigned = true;
948 connector->object.assigned = true;
950 /* we will support hw clone mode in the future */
951 n_connectors = connector ? 1 : 0;
953 /* bail out if configuration is preserved */
954 if (crtc->set.n_connectors == n_connectors &&
955 (n_connectors == 0 || crtc->set.connectors[0] == connector->object.id))
958 crtc->applied = false;
959 crtc->set.n_connectors = 0;
961 if (n_connectors > crtc->set.max_connectors) {
964 max = ALIGN_POWER2(n_connectors);
970 t = realloc(crtc->set.connectors, sizeof(*t) * max);
976 crtc->set.connectors = t;
977 crtc->set.max_connectors = max;
981 struct drm_mode_modeinfo *m, *pref = NULL;
984 for (i = 0; i < connector->kern.n_modes; ++i) {
985 m = &connector->kern.modes[i];
987 /* ignore 3D modes by default */
988 if (m->flags & DRM_MODE_FLAG_3D_MASK)
996 /* use PREFERRED over non-PREFERRED */
997 if ((pref->type & DRM_MODE_TYPE_PREFERRED) &&
998 !(m->type & DRM_MODE_TYPE_PREFERRED))
1001 /* use DRIVER over non-PREFERRED|DRIVER */
1002 if ((pref->type & DRM_MODE_TYPE_DRIVER) &&
1003 !(m->type & (DRM_MODE_TYPE_DRIVER | DRM_MODE_TYPE_PREFERRED)))
1006 /* always prefer higher resolution */
1007 if (pref->hdisplay > m->hdisplay ||
1008 (pref->hdisplay == m->hdisplay && pref->vdisplay > m->vdisplay))
1015 crtc->set.mode = *pref;
1016 crtc->set.n_connectors = 1;
1017 crtc->set.connectors[0] = connector->object.id;
1018 log_debug("grdrm: %s: assigned connector %" PRIu32 " to crtc %" PRIu32 " with mode %s",
1019 crtc->object.card->base.name, connector->object.id, crtc->object.id, pref->name);
1021 log_debug("grdrm: %s: connector %" PRIu32 " to be assigned but has no valid mode",
1022 crtc->object.card->base.name, connector->object.id);
1029 log_debug("grdrm: %s: cannot assign crtc %" PRIu32 ": %s",
1030 crtc->object.card->base.name, crtc->object.id, strerror(-r));
1033 static void grdrm_crtc_expose(grdrm_crtc *crtc) {
1040 assert(crtc->object.assigned);
1042 if (crtc->set.n_connectors < 1) {
1044 grdev_pipe_free(&crtc->pipe->base);
1051 if (pipe->base.width != crtc->set.mode.hdisplay ||
1052 pipe->base.height != crtc->set.mode.vdisplay ||
1053 pipe->base.vrefresh != crtc->set.mode.vrefresh) {
1054 grdev_pipe_free(&pipe->base);
1061 pipe->base.front = NULL;
1062 pipe->base.back = NULL;
1063 for (i = 0; i < pipe->base.max_fbs; ++i) {
1064 fb = fb_from_base(pipe->base.fbs[i]);
1065 if (fb->id == crtc->kern.used_fb)
1066 pipe->base.front = &fb->base;
1067 else if (!fb->flipid)
1068 pipe->base.back = &fb->base;
1071 r = grdrm_pipe_new(&pipe, crtc, &crtc->set.mode, 2);
1073 log_debug("grdrm: %s: cannot create pipe for crtc %" PRIu32 ": %s",
1074 crtc->object.card->base.name, crtc->object.id, strerror(-r));
1078 for (i = 0; i < pipe->base.max_fbs; ++i) {
1079 r = grdrm_fb_new(&fb, crtc->object.card, &crtc->set.mode);
1081 log_debug("grdrm: %s: cannot allocate framebuffer for crtc %" PRIu32 ": %s",
1082 crtc->object.card->base.name, crtc->object.id, strerror(-r));
1083 grdev_pipe_free(&pipe->base);
1087 pipe->base.fbs[i] = &fb->base;
1090 pipe->base.front = NULL;
1091 pipe->base.back = pipe->base.fbs[0];
1095 grdev_pipe_ready(&crtc->pipe->base, true);
1098 static void grdrm_crtc_commit_deep(grdrm_crtc *crtc, grdev_fb **slot) {
1099 struct drm_mode_crtc set_crtc = { .crtc_id = crtc->object.id };
1100 grdrm_card *card = crtc->object.card;
1101 grdrm_pipe *pipe = crtc->pipe;
1102 grdrm_fb *fb = fb_from_base(*slot);
1111 set_crtc.set_connectors_ptr = PTR_TO_UINT64(crtc->set.connectors);
1112 set_crtc.count_connectors = crtc->set.n_connectors;
1113 set_crtc.fb_id = fb->id;
1116 set_crtc.mode_valid = 1;
1117 set_crtc.mode = crtc->set.mode;
1119 r = ioctl(card->fd, DRM_IOCTL_MODE_SETCRTC, &set_crtc);
1122 log_debug("grdrm: %s: cannot set crtc %" PRIu32 ": %m",
1123 card->base.name, crtc->object.id);
1125 grdrm_card_async(card, r);
1129 if (!crtc->applied) {
1130 log_debug("grdrm: %s: crtc %" PRIu32 " applied via deep modeset",
1131 card->base.name, crtc->object.id);
1132 crtc->applied = true;
1136 pipe->base.front = &fb->base;
1139 pipe->base.flipping = false;
1140 pipe->base.flip = false;
1142 /* We cannot schedule dummy page-flips on pipes, hence, the
1143 * application would have to schedule their own frame-timers.
1144 * To avoid duplicating that everywhere, we schedule our own
1145 * timer and raise a fake FRAME event when it fires. */
1146 grdev_pipe_schedule(&pipe->base, 1);
1148 if (!pipe->base.back) {
1149 for (i = 0; i < pipe->base.max_fbs; ++i) {
1150 if (!pipe->base.fbs[i])
1153 fb = fb_from_base(pipe->base.fbs[i]);
1154 if (&fb->base == pipe->base.front)
1158 pipe->base.back = &fb->base;
1164 static int grdrm_crtc_commit_flip(grdrm_crtc *crtc, grdev_fb **slot) {
1165 struct drm_mode_crtc_page_flip page_flip = { .crtc_id = crtc->object.id };
1166 grdrm_card *card = crtc->object.card;
1167 grdrm_pipe *pipe = crtc->pipe;
1168 grdrm_fb *fb = fb_from_base(*slot);
1178 if (!crtc->applied && !grdrm_modes_compatible(&crtc->kern.mode, &crtc->set.mode))
1181 cnt = ++pipe->counter ? : ++pipe->counter;
1182 page_flip.fb_id = fb->id;
1183 page_flip.flags = DRM_MODE_PAGE_FLIP_EVENT;
1184 page_flip.user_data = grdrm_encode_vblank_data(crtc->object.id, cnt);
1186 r = ioctl(card->fd, DRM_IOCTL_MODE_PAGE_FLIP, &page_flip);
1189 /* Avoid excessive logging on EINVAL; it is currently not
1190 * possible to see whether cards support page-flipping, so
1191 * avoid logging on each frame. */
1193 log_debug("grdrm: %s: cannot schedule page-flip on crtc %" PRIu32 ": %m",
1194 card->base.name, crtc->object.id);
1196 if (grdrm_card_async(card, r))
1202 if (!crtc->applied) {
1203 log_debug("grdrm: %s: crtc %" PRIu32 " applied via page flip",
1204 card->base.name, crtc->object.id);
1205 crtc->applied = true;
1208 pipe->base.flipping = true;
1209 pipe->base.flip = false;
1210 pipe->counter = cnt;
1214 /* Raise fake FRAME event if it takes longer than 2
1215 * frames to receive the pageflip event. We assume the
1216 * queue ran over or some other error happened. */
1217 grdev_pipe_schedule(&pipe->base, 2);
1219 if (!pipe->base.back) {
1220 for (i = 0; i < pipe->base.max_fbs; ++i) {
1221 if (!pipe->base.fbs[i])
1224 fb = fb_from_base(pipe->base.fbs[i]);
1225 if (&fb->base == pipe->base.front)
1230 pipe->base.back = &fb->base;
1238 static void grdrm_crtc_commit(grdrm_crtc *crtc) {
1239 struct drm_mode_crtc set_crtc = { .crtc_id = crtc->object.id };
1240 grdrm_card *card = crtc->object.card;
1246 assert(crtc->object.assigned);
1250 /* If a crtc is not assigned any connector, we want any
1251 * previous setup to be cleared, so make sure the CRTC is
1252 * disabled. Otherwise, there might be content on the CRTC
1253 * while we run, which is not what we want.
1254 * If you want to avoid modesets on specific CRTCs, you should
1255 * still keep their assignment, but never enable the resulting
1256 * pipe. This way, we wouldn't touch it at all. */
1257 if (!crtc->applied) {
1258 crtc->applied = true;
1259 r = ioctl(card->fd, DRM_IOCTL_MODE_SETCRTC, &set_crtc);
1262 log_debug("grdrm: %s: cannot shutdown crtc %" PRIu32 ": %m",
1263 card->base.name, crtc->object.id);
1265 grdrm_card_async(card, r);
1269 log_debug("grdrm: %s: crtc %" PRIu32 " applied via shutdown",
1270 card->base.name, crtc->object.id);
1276 /* we always fully ignore disabled pipes */
1277 if (!pipe->base.enabled)
1280 assert(crtc->set.n_connectors > 0);
1282 if (pipe->base.flip)
1283 slot = &pipe->base.back;
1284 else if (!crtc->applied)
1285 slot = &pipe->base.front;
1292 r = grdrm_crtc_commit_flip(crtc, slot);
1294 /* in case we couldn't page-flip, perform deep modeset */
1295 grdrm_crtc_commit_deep(crtc, slot);
1299 static void grdrm_crtc_restore(grdrm_crtc *crtc) {
1300 struct drm_mode_crtc set_crtc = { .crtc_id = crtc->object.id };
1301 grdrm_card *card = crtc->object.card;
1307 set_crtc.set_connectors_ptr = PTR_TO_UINT64(crtc->old.connectors);
1308 set_crtc.count_connectors = crtc->old.n_connectors;
1309 set_crtc.fb_id = crtc->old.fb;
1310 set_crtc.x = crtc->old.fb_x;
1311 set_crtc.y = crtc->old.fb_y;
1312 set_crtc.gamma_size = crtc->old.gamma;
1313 set_crtc.mode_valid = crtc->old.mode_set;
1314 set_crtc.mode = crtc->old.mode;
1316 r = ioctl(card->fd, DRM_IOCTL_MODE_SETCRTC, &set_crtc);
1319 log_debug("grdrm: %s: cannot restore crtc %" PRIu32 ": %m",
1320 card->base.name, crtc->object.id);
1322 grdrm_card_async(card, r);
1327 ++crtc->pipe->counter;
1328 crtc->pipe->base.front = NULL;
1329 crtc->pipe->base.flipping = false;
1332 log_debug("grdrm: %s: crtc %" PRIu32 " restored", card->base.name, crtc->object.id);
1335 static void grdrm_crtc_flip_complete(grdrm_crtc *crtc, uint32_t counter, struct drm_event_vblank *event) {
1336 bool flipped = false;
1338 grdrm_fb *back = NULL;
1348 /* We got a page-flip event. To be safe, we reset all FBs on the same
1349 * pipe that have smaller flipids than the flip we got as we know they
1350 * are executed in order. We need to do this to guarantee
1351 * queue-overflows or other missed events don't cause starvation.
1352 * Furthermore, if we find the exact FB this event is for, *and* this
1353 * is the most recent event, we mark it as front FB and raise a
1356 for (i = 0; i < pipe->base.max_fbs; ++i) {
1359 if (!pipe->base.fbs[i])
1362 fb = fb_from_base(pipe->base.fbs[i]);
1363 if (counter != 0 && counter == pipe->counter && fb->flipid == counter) {
1364 pipe->base.front = &fb->base;
1368 if (counter - fb->flipid < UINT16_MAX) {
1371 } else if (fb->flipid == 0) {
1376 if (!pipe->base.back)
1377 pipe->base.back = &back->base;
1380 crtc->pipe->base.flipping = false;
1381 grdev_pipe_frame(&pipe->base);
1389 static int grdrm_fb_new(grdrm_fb **out, grdrm_card *card, const struct drm_mode_modeinfo *mode) {
1390 _cleanup_(grdrm_fb_freep) grdrm_fb *fb = NULL;
1391 struct drm_mode_create_dumb create_dumb = { };
1392 struct drm_mode_map_dumb map_dumb = { };
1393 struct drm_mode_fb_cmd2 add_fb = { };
1397 assert_return(out, -EINVAL);
1398 assert_return(card, -EINVAL);
1400 fb = new0(grdrm_fb, 1);
1404 /* TODO: we should choose a compatible format of the previous CRTC
1405 * setting to allow page-flip to it. Only choose fallback if the
1406 * previous setting was crap (non xrgb32'ish). */
1409 fb->base.format = DRM_FORMAT_XRGB8888;
1410 fb->base.width = mode->hdisplay;
1411 fb->base.height = mode->vdisplay;
1413 for (i = 0; i < ELEMENTSOF(fb->base.maps); ++i)
1414 fb->base.maps[i] = MAP_FAILED;
1416 create_dumb.width = fb->base.width;
1417 create_dumb.height = fb->base.height;
1418 create_dumb.bpp = 32;
1420 r = ioctl(card->fd, DRM_IOCTL_MODE_CREATE_DUMB, &create_dumb);
1423 log_debug("grdrm: %s: cannot create dumb buffer %" PRIu32 "x%" PRIu32": %m",
1424 card->base.name, fb->base.width, fb->base.height);
1428 fb->handles[0] = create_dumb.handle;
1429 fb->base.strides[0] = create_dumb.pitch;
1430 fb->sizes[0] = create_dumb.size;
1432 map_dumb.handle = fb->handles[0];
1434 r = ioctl(card->fd, DRM_IOCTL_MODE_MAP_DUMB, &map_dumb);
1437 log_debug("grdrm: %s: cannot map dumb buffer %" PRIu32 "x%" PRIu32": %m",
1438 card->base.name, fb->base.width, fb->base.height);
1442 fb->base.maps[0] = mmap(0, fb->sizes[0], PROT_WRITE, MAP_SHARED, card->fd, map_dumb.offset);
1443 if (fb->base.maps[0] == MAP_FAILED) {
1445 log_debug("grdrm: %s: cannot memory-map dumb buffer %" PRIu32 "x%" PRIu32": %m",
1446 card->base.name, fb->base.width, fb->base.height);
1450 memzero(fb->base.maps[0], fb->sizes[0]);
1452 add_fb.width = fb->base.width;
1453 add_fb.height = fb->base.height;
1454 add_fb.pixel_format = fb->base.format;
1456 memcpy(add_fb.handles, fb->handles, sizeof(fb->handles));
1457 memcpy(add_fb.pitches, fb->base.strides, sizeof(fb->base.strides));
1458 memcpy(add_fb.offsets, fb->offsets, sizeof(fb->offsets));
1460 r = ioctl(card->fd, DRM_IOCTL_MODE_ADDFB2, &add_fb);
1463 log_debug("grdrm: %s: cannot add framebuffer %" PRIu32 "x%" PRIu32": %m",
1464 card->base.name, fb->base.width, fb->base.height);
1468 fb->id = add_fb.fb_id;
1475 grdrm_fb *grdrm_fb_free(grdrm_fb *fb) {
1484 if (fb->id > 0 && fb->card->fd >= 0) {
1485 r = ioctl(fb->card->fd, DRM_IOCTL_MODE_RMFB, fb->id);
1487 log_debug("grdrm: %s: cannot delete framebuffer %" PRIu32 ": %m",
1488 fb->card->base.name, fb->id);
1491 for (i = 0; i < ELEMENTSOF(fb->handles); ++i) {
1492 struct drm_mode_destroy_dumb destroy_dumb = { };
1494 if (fb->base.maps[i] != MAP_FAILED)
1495 munmap(fb->base.maps[i], fb->sizes[i]);
1497 if (fb->handles[i] > 0 && fb->card->fd >= 0) {
1498 destroy_dumb.handle = fb->handles[i];
1499 r = ioctl(fb->card->fd, DRM_IOCTL_MODE_DESTROY_DUMB, &destroy_dumb);
1501 log_debug("grdrm: %s: cannot destroy dumb-buffer %" PRIu32 ": %m",
1502 fb->card->base.name, fb->handles[i]);
1515 static void grdrm_pipe_name(char *out, grdrm_crtc *crtc) {
1516 /* @out must be at least of size GRDRM_PIPE_NAME_MAX */
1517 sprintf(out, "%s/%" PRIu32, crtc->object.card->base.name, crtc->object.id);
1520 static int grdrm_pipe_new(grdrm_pipe **out, grdrm_crtc *crtc, struct drm_mode_modeinfo *mode, size_t n_fbs) {
1521 _cleanup_(grdev_pipe_freep) grdev_pipe *basepipe = NULL;
1522 grdrm_card *card = crtc->object.card;
1523 char name[GRDRM_PIPE_NAME_MAX];
1527 assert_return(crtc, -EINVAL);
1528 assert_return(grdev_is_drm_card(&card->base), -EINVAL);
1530 pipe = new0(grdrm_pipe, 1);
1534 basepipe = &pipe->base;
1535 pipe->base = GRDEV_PIPE_INIT(&grdrm_pipe_vtable, &card->base);
1537 pipe->base.width = mode->hdisplay;
1538 pipe->base.height = mode->vdisplay;
1539 pipe->base.vrefresh = mode->vrefresh ? : 25;
1541 grdrm_pipe_name(name, crtc);
1542 r = grdev_pipe_add(&pipe->base, name, n_fbs);
1552 static void grdrm_pipe_free(grdev_pipe *basepipe) {
1553 grdrm_pipe *pipe = grdrm_pipe_from_base(basepipe);
1558 for (i = 0; i < pipe->base.max_fbs; ++i)
1559 if (pipe->base.fbs[i])
1560 grdrm_fb_free(fb_from_base(pipe->base.fbs[i]));
1565 static const grdev_pipe_vtable grdrm_pipe_vtable = {
1566 .free = grdrm_pipe_free,
1573 static void grdrm_name(char *out, dev_t devnum) {
1574 /* @out must be at least of size GRDRM_CARD_NAME_MAX */
1575 sprintf(out, "drm/%u:%u", major(devnum), minor(devnum));
1578 static void grdrm_card_print(grdrm_card *card) {
1579 grdrm_object *object;
1581 grdrm_encoder *encoder;
1582 grdrm_connector *connector;
1588 log_debug("grdrm: %s: state dump", card->base.name);
1590 log_debug(" crtcs:");
1591 HASHMAP_FOREACH(object, card->object_map, iter) {
1592 if (object->type != GRDRM_TYPE_CRTC)
1595 crtc = crtc_from_object(object);
1596 log_debug(" (id: %u index: %d)", object->id, object->index);
1598 if (crtc->kern.mode_set)
1599 log_debug(" mode: %dx%d", crtc->kern.mode.hdisplay, crtc->kern.mode.vdisplay);
1601 log_debug(" mode: <none>");
1604 log_debug(" encoders:");
1605 HASHMAP_FOREACH(object, card->object_map, iter) {
1606 if (object->type != GRDRM_TYPE_ENCODER)
1609 encoder = encoder_from_object(object);
1610 log_debug(" (id: %u index: %d)", object->id, object->index);
1612 if (encoder->kern.used_crtc)
1613 log_debug(" crtc: %u", encoder->kern.used_crtc);
1615 log_debug(" crtc: <none>");
1617 buf = malloc((DECIMAL_STR_MAX(uint32_t) + 1) * encoder->kern.n_crtcs + 1);
1622 for (i = 0; i < encoder->kern.n_crtcs; ++i)
1623 p += sprintf(p, " %" PRIu32, encoder->kern.crtcs[i]);
1625 log_debug(" possible crtcs:%s", buf);
1629 buf = malloc((DECIMAL_STR_MAX(uint32_t) + 1) * encoder->kern.n_clones + 1);
1634 for (i = 0; i < encoder->kern.n_clones; ++i)
1635 p += sprintf(p, " %" PRIu32, encoder->kern.clones[i]);
1637 log_debug(" possible clones:%s", buf);
1642 log_debug(" connectors:");
1643 HASHMAP_FOREACH(object, card->object_map, iter) {
1644 if (object->type != GRDRM_TYPE_CONNECTOR)
1647 connector = connector_from_object(object);
1648 log_debug(" (id: %u index: %d)", object->id, object->index);
1649 log_debug(" type: %" PRIu32 "-%" PRIu32 " connection: %" PRIu32 " subpixel: %" PRIu32 " extents: %" PRIu32 "x%" PRIu32,
1650 connector->kern.type, connector->kern.type_id, connector->kern.connection, connector->kern.subpixel,
1651 connector->kern.mm_width, connector->kern.mm_height);
1653 if (connector->kern.used_encoder)
1654 log_debug(" encoder: %" PRIu32, connector->kern.used_encoder);
1656 log_debug(" encoder: <none>");
1658 buf = malloc((DECIMAL_STR_MAX(uint32_t) + 1) * connector->kern.n_encoders + 1);
1663 for (i = 0; i < connector->kern.n_encoders; ++i)
1664 p += sprintf(p, " %" PRIu32, connector->kern.encoders[i]);
1666 log_debug(" possible encoders:%s", buf);
1670 for (i = 0; i < connector->kern.n_modes; ++i) {
1671 struct drm_mode_modeinfo *mode = &connector->kern.modes[i];
1672 log_debug(" mode: %" PRIu32 "x%" PRIu32, mode->hdisplay, mode->vdisplay);
1676 log_debug(" planes:");
1677 HASHMAP_FOREACH(object, card->object_map, iter) {
1678 if (object->type != GRDRM_TYPE_PLANE)
1681 plane = plane_from_object(object);
1682 log_debug(" (id: %u index: %d)", object->id, object->index);
1683 log_debug(" gamma-size: %" PRIu32, plane->kern.gamma_size);
1685 if (plane->kern.used_crtc)
1686 log_debug(" crtc: %" PRIu32, plane->kern.used_crtc);
1688 log_debug(" crtc: <none>");
1690 buf = malloc((DECIMAL_STR_MAX(uint32_t) + 1) * plane->kern.n_crtcs + 1);
1695 for (i = 0; i < plane->kern.n_crtcs; ++i)
1696 p += sprintf(p, " %" PRIu32, plane->kern.crtcs[i]);
1698 log_debug(" possible crtcs:%s", buf);
1702 buf = malloc((DECIMAL_STR_MAX(unsigned int) + 3) * plane->kern.n_formats + 1);
1707 for (i = 0; i < plane->kern.n_formats; ++i)
1708 p += sprintf(p, " 0x%x", (unsigned int)plane->kern.formats[i]);
1710 log_debug(" possible formats:%s", buf);
1716 static int grdrm_card_resync(grdrm_card *card) {
1717 _cleanup_free_ uint32_t *crtc_ids = NULL, *encoder_ids = NULL, *connector_ids = NULL, *plane_ids = NULL;
1718 uint32_t allocated = 0;
1719 grdrm_object *object;
1726 card->async_hotplug = false;
1729 /* mark existing objects for possible removal */
1730 HASHMAP_FOREACH(object, card->object_map, iter)
1731 object->present = false;
1733 for (tries = 0; tries < GRDRM_MAX_TRIES; ++tries) {
1734 struct drm_mode_get_plane_res pres;
1735 struct drm_mode_card_res res;
1738 if (allocated < card->max_ids) {
1741 free(connector_ids);
1743 crtc_ids = new0(uint32_t, card->max_ids);
1744 encoder_ids = new0(uint32_t, card->max_ids);
1745 connector_ids = new0(uint32_t, card->max_ids);
1746 plane_ids = new0(uint32_t, card->max_ids);
1748 if (!crtc_ids || !encoder_ids || !connector_ids || !plane_ids)
1751 allocated = card->max_ids;
1755 res.crtc_id_ptr = PTR_TO_UINT64(crtc_ids);
1756 res.connector_id_ptr = PTR_TO_UINT64(connector_ids);
1757 res.encoder_id_ptr = PTR_TO_UINT64(encoder_ids);
1758 res.count_crtcs = allocated;
1759 res.count_encoders = allocated;
1760 res.count_connectors = allocated;
1762 r = ioctl(card->fd, DRM_IOCTL_MODE_GETRESOURCES, &res);
1765 log_debug("grdrm: %s: cannot retrieve drm resources: %m", card->base.name);
1770 pres.plane_id_ptr = PTR_TO_UINT64(plane_ids);
1771 pres.count_planes = allocated;
1773 r = ioctl(card->fd, DRM_IOCTL_MODE_GETPLANERESOURCES, &pres);
1776 log_debug("grdrm: %s: cannot retrieve drm plane-resources: %m", card->base.name);
1780 max = MAX(MAX(res.count_crtcs, res.count_encoders),
1781 MAX(res.count_connectors, pres.count_planes));
1782 if (max > allocated) {
1785 n = ALIGN_POWER2(max);
1786 if (!n || n > UINT16_MAX) {
1787 log_debug("grdrm: %s: excessive DRM resource limit: %" PRIu32, card->base.name, max);
1791 /* retry with resized buffers */
1796 /* mark available objects as present */
1798 for (i = 0; i < res.count_crtcs; ++i) {
1799 object = grdrm_find_object(card, crtc_ids[i]);
1800 if (object && object->type == GRDRM_TYPE_CRTC) {
1801 object->present = true;
1807 for (i = 0; i < res.count_encoders; ++i) {
1808 object = grdrm_find_object(card, encoder_ids[i]);
1809 if (object && object->type == GRDRM_TYPE_ENCODER) {
1810 object->present = true;
1816 for (i = 0; i < res.count_connectors; ++i) {
1817 object = grdrm_find_object(card, connector_ids[i]);
1818 if (object && object->type == GRDRM_TYPE_CONNECTOR) {
1819 object->present = true;
1821 connector_ids[i] = 0;
1825 for (i = 0; i < pres.count_planes; ++i) {
1826 object = grdrm_find_object(card, plane_ids[i]);
1827 if (object && object->type == GRDRM_TYPE_PLANE) {
1828 object->present = true;
1834 /* drop removed objects */
1836 HASHMAP_FOREACH(object, card->object_map, iter)
1837 if (!object->present)
1838 grdrm_object_free(object);
1840 /* add new objects */
1842 card->n_crtcs = res.count_crtcs;
1843 for (i = 0; i < res.count_crtcs; ++i) {
1844 if (crtc_ids[i] < 1)
1847 r = grdrm_crtc_new(NULL, card, crtc_ids[i], i);
1852 card->n_encoders = res.count_encoders;
1853 for (i = 0; i < res.count_encoders; ++i) {
1854 if (encoder_ids[i] < 1)
1857 r = grdrm_encoder_new(NULL, card, encoder_ids[i], i);
1862 card->n_connectors = res.count_connectors;
1863 for (i = 0; i < res.count_connectors; ++i) {
1864 if (connector_ids[i] < 1)
1867 r = grdrm_connector_new(NULL, card, connector_ids[i], i);
1872 card->n_planes = pres.count_planes;
1873 for (i = 0; i < pres.count_planes; ++i) {
1874 if (plane_ids[i] < 1)
1877 r = grdrm_plane_new(NULL, card, plane_ids[i], i);
1882 /* re-sync objects after object_map is synced */
1884 HASHMAP_FOREACH(object, card->object_map, iter) {
1885 switch (object->type) {
1886 case GRDRM_TYPE_CRTC:
1887 r = grdrm_crtc_resync(crtc_from_object(object));
1889 case GRDRM_TYPE_ENCODER:
1890 r = grdrm_encoder_resync(encoder_from_object(object));
1892 case GRDRM_TYPE_CONNECTOR:
1893 r = grdrm_connector_resync(connector_from_object(object));
1895 case GRDRM_TYPE_PLANE:
1896 r = grdrm_plane_resync(plane_from_object(object));
1899 assert_not_reached("grdrm: invalid object type");
1906 if (card->async_hotplug)
1910 /* if modeset objects change during sync, start over */
1911 if (card->async_hotplug) {
1912 card->async_hotplug = false;
1916 /* cache crtc/connector relationship */
1917 HASHMAP_FOREACH(object, card->object_map, iter) {
1918 grdrm_connector *connector;
1919 grdrm_encoder *encoder;
1922 if (object->type != GRDRM_TYPE_CONNECTOR)
1925 connector = connector_from_object(object);
1926 if (connector->kern.connection != 1 || connector->kern.used_encoder < 1)
1929 object = grdrm_find_object(card, connector->kern.used_encoder);
1930 if (!object || object->type != GRDRM_TYPE_ENCODER)
1933 encoder = encoder_from_object(object);
1934 if (encoder->kern.used_crtc < 1)
1937 object = grdrm_find_object(card, encoder->kern.used_crtc);
1938 if (!object || object->type != GRDRM_TYPE_CRTC)
1941 crtc = crtc_from_object(object);
1942 assert(crtc->kern.n_used_connectors < crtc->kern.max_used_connectors);
1943 crtc->kern.used_connectors[crtc->kern.n_used_connectors++] = connector->object.id;
1946 /* cache old crtc settings for later restore */
1947 HASHMAP_FOREACH(object, card->object_map, iter) {
1950 if (object->type != GRDRM_TYPE_CRTC)
1953 crtc = crtc_from_object(object);
1955 /* Save data if it is the first time we refresh the CRTC. This data can
1956 * be used optionally to restore any previous configuration. For
1957 * instance, it allows us to restore VT configurations after we close
1958 * our session again. */
1959 if (!crtc->old.set) {
1960 crtc->old.fb = crtc->kern.used_fb;
1961 crtc->old.fb_x = crtc->kern.fb_offset_x;
1962 crtc->old.fb_y = crtc->kern.fb_offset_y;
1963 crtc->old.gamma = crtc->kern.gamma_size;
1964 crtc->old.n_connectors = crtc->kern.n_used_connectors;
1965 if (crtc->old.n_connectors)
1966 memcpy(crtc->old.connectors, crtc->kern.used_connectors, sizeof(uint32_t) * crtc->old.n_connectors);
1967 crtc->old.mode_set = crtc->kern.mode_set;
1968 crtc->old.mode = crtc->kern.mode;
1969 crtc->old.set = true;
1973 /* everything synced */
1977 if (tries >= GRDRM_MAX_TRIES) {
1979 * Ugh! We were unable to sync the DRM card state due to heavy
1980 * hotplugging. This should never happen, so print a debug
1981 * message and bail out. The next uevent will trigger
1985 log_debug("grdrm: %s: hotplug-storm when syncing card", card->base.name);
1992 static bool card_configure_crtc(grdrm_crtc *crtc, grdrm_connector *connector) {
1993 grdrm_card *card = crtc->object.card;
1994 grdrm_encoder *encoder;
1995 grdrm_object *object;
1998 if (crtc->object.assigned || connector->object.assigned)
2000 if (connector->kern.connection != 1)
2003 for (i = 0; i < connector->kern.n_encoders; ++i) {
2004 object = grdrm_find_object(card, connector->kern.encoders[i]);
2005 if (!object || object->type != GRDRM_TYPE_ENCODER)
2008 encoder = encoder_from_object(object);
2009 for (j = 0; j < encoder->kern.n_crtcs; ++j) {
2010 if (encoder->kern.crtcs[j] == crtc->object.id) {
2011 grdrm_crtc_assign(crtc, connector);
2020 static void grdrm_card_configure(grdrm_card *card) {
2022 * Modeset Configuration
2023 * This is where we update our modeset configuration and assign
2024 * connectors to CRTCs. This means, each connector that we want to
2025 * enable needs a CRTC, disabled (or unavailable) connectors are left
2026 * alone in the dark. Once all CRTCs are assigned, the remaining CRTCs
2028 * Sounds trivial, but there're several caveats:
2030 * * Multiple connectors can be driven by the same CRTC. This is
2031 * known as 'hardware clone mode'. Advantage over software clone
2032 * mode is that only a single CRTC is needed to drive multiple
2033 * displays. However, few hardware supports this and it's a huge
2034 * headache to configure on dynamic demands. Therefore, we only
2035 * support it if configured statically beforehand.
2037 * * CRTCs are not created equal. Some might be much more poweful
2038 * than others, including more advanced plane support. So far, our
2039 * CRTC selection is random. You need to supply static
2040 * configuration if you want special setups. So far, there is no
2041 * proper way to do advanced CRTC selection on dynamic demands. It
2042 * is not really clear which demands require what CRTC, so, like
2043 * everyone else, we do random CRTC selection unless explicitly
2046 * * Each Connector has a list of possible encoders that can drive
2047 * it, and each encoder has a list of possible CRTCs. If this graph
2048 * is a tree, assignment is trivial. However, if not, we cannot
2049 * reliably decide on configurations beforehand. The encoder is
2050 * always selected by the kernel, so we have to actually set a mode
2051 * to know which encoder is used. There is no way to ask the kernel
2052 * whether a given configuration is possible. This will change with
2053 * atomic-modesetting, but until then, we keep our configurations
2054 * simple and assume they work all just fine. If one fails
2055 * unexpectedly, we print a warning and disable it.
2057 * Configuring a card consists of several steps:
2059 * 1) First of all, we apply any user-configuration. If a user wants
2060 * a fixed configuration, we apply it and preserve it.
2061 * So far, we don't support user configuration files, so this step
2064 * 2) Secondly, we need to apply any quirks from hwdb. Some hardware
2065 * might only support limited configurations or require special
2066 * CRTC/Connector mappings. We read this from hwdb and apply it, if
2068 * So far, we don't support this as there is no known quirk, so
2069 * this step is skipped.
2071 * 3) As deep modesets are expensive, we try to avoid them if
2072 * possible. Therefore, we read the current configuration from the
2073 * kernel and try to preserve it, if compatible with our demands.
2074 * If not, we break it and reassign it in a following step.
2076 * 4) The main step involves configuring all remaining objects. By
2077 * default, all available connectors are enabled, except for those
2078 * disabled by user-configuration. We lookup a suitable CRTC for
2079 * each connector and assign them. As there might be more
2080 * connectors than CRTCs, we apply some ordering so users can
2081 * select which connectors are more important right now.
2082 * So far, we only apply the default ordering, more might be added
2086 grdrm_object *object;
2090 /* clear assignments */
2091 HASHMAP_FOREACH(object, card->object_map, i)
2092 object->assigned = false;
2094 /* preserve existing configurations */
2095 HASHMAP_FOREACH(object, card->object_map, i) {
2096 if (object->type != GRDRM_TYPE_CRTC || object->assigned)
2099 crtc = crtc_from_object(object);
2101 if (crtc->applied) {
2102 /* If our mode is set, preserve it. If no connector is
2103 * set, modeset either failed or the pipe is unused. In
2104 * both cases, leave it alone. It might be tried again
2105 * below in case there're remaining connectors.
2106 * Otherwise, try restoring the assignments. If they
2107 * are no longer valid, leave the pipe untouched. */
2109 if (crtc->set.n_connectors < 1)
2112 assert(crtc->set.n_connectors == 1);
2114 object = grdrm_find_object(card, crtc->set.connectors[0]);
2115 if (!object || object->type != GRDRM_TYPE_CONNECTOR)
2118 card_configure_crtc(crtc, connector_from_object(object));
2119 } else if (crtc->kern.mode_set && crtc->kern.n_used_connectors != 1) {
2120 /* If our mode is not set on the pipe, we know the kern
2121 * information is valid. Try keeping it. If it's not
2122 * possible, leave the pipe untouched for later
2125 object = grdrm_find_object(card, crtc->kern.used_connectors[0]);
2126 if (!object || object->type != GRDRM_TYPE_CONNECTOR)
2129 card_configure_crtc(crtc, connector_from_object(object));
2133 /* assign remaining objects */
2134 HASHMAP_FOREACH(object, card->object_map, i) {
2135 if (object->type != GRDRM_TYPE_CRTC || object->assigned)
2138 crtc = crtc_from_object(object);
2140 HASHMAP_FOREACH(object, card->object_map, j) {
2141 if (object->type != GRDRM_TYPE_CONNECTOR)
2144 if (card_configure_crtc(crtc, connector_from_object(object)))
2148 if (!crtc->object.assigned)
2149 grdrm_crtc_assign(crtc, NULL);
2152 /* expose configuration */
2153 HASHMAP_FOREACH(object, card->object_map, i) {
2154 if (object->type != GRDRM_TYPE_CRTC)
2157 grdrm_crtc_expose(crtc_from_object(object));
2161 static void grdrm_card_hotplug(grdrm_card *card) {
2169 log_debug("grdrm: %s/%s: reconfigure card", card->base.session->name, card->base.name);
2171 card->ready = false;
2172 r = grdrm_card_resync(card);
2174 log_debug("grdrm: %s/%s: cannot re-sync card: %s",
2175 card->base.session->name, card->base.name, strerror(-r));
2179 grdev_session_pin(card->base.session);
2181 /* debug statement to print card information */
2183 grdrm_card_print(card);
2185 grdrm_card_configure(card);
2187 card->hotplug = false;
2189 grdev_session_unpin(card->base.session);
2192 static int grdrm_card_io_fn(sd_event_source *s, int fd, uint32_t revents, void *userdata) {
2193 grdrm_card *card = userdata;
2194 struct drm_event_vblank *vblank;
2195 struct drm_event *event;
2196 uint32_t id, counter;
2197 grdrm_object *object;
2201 if (revents & (EPOLLHUP | EPOLLERR)) {
2202 /* Immediately close device on HUP; no need to flush pending
2203 * data.. there're no events we care about here. */
2204 log_debug("grdrm: %s/%s: HUP", card->base.session->name, card->base.name);
2205 grdrm_card_close(card);
2209 if (revents & (EPOLLIN)) {
2210 l = read(card->fd, buf, sizeof(buf));
2212 if (errno == EAGAIN || errno == EINTR)
2215 log_debug("grdrm: %s/%s: read error: %m", card->base.session->name, card->base.name);
2216 grdrm_card_close(card);
2218 } else if ((size_t)l < sizeof(*event)) {
2219 log_debug("grdrm: %s/%s: short read of %zd bytes", card->base.session->name, card->base.name, l);
2223 for (i = 0; i < l; i += event->length) {
2224 event = (void*)&buf[i];
2226 if (i + (ssize_t)sizeof(*event) > l || i + (ssize_t)event->length > l) {
2227 log_debug("grdrm: %s/%s: truncated event", card->base.session->name, card->base.name);
2231 switch (event->type) {
2232 case DRM_EVENT_FLIP_COMPLETE:
2233 vblank = (void*)event;
2234 if (event->length < sizeof(*vblank)) {
2235 log_debug("grdrm: %s/%s: truncated vblank event", card->base.session->name, card->base.name);
2239 grdrm_decode_vblank_data(vblank->user_data, &id, &counter);
2240 object = grdrm_find_object(card, id);
2241 if (!object || object->type != GRDRM_TYPE_CRTC)
2244 grdrm_crtc_flip_complete(crtc_from_object(object), counter, vblank);
2253 static int grdrm_card_add(grdrm_card *card, const char *name) {
2255 assert(card->fd < 0);
2257 card->object_map = hashmap_new(&trivial_hash_ops);
2258 if (!card->object_map)
2261 return grdev_card_add(&card->base, name);
2264 static void grdrm_card_destroy(grdrm_card *card) {
2266 assert(!card->running);
2267 assert(card->fd < 0);
2268 assert(hashmap_size(card->object_map) == 0);
2270 hashmap_free(card->object_map);
2273 static void grdrm_card_commit(grdev_card *basecard) {
2274 grdrm_card *card = grdrm_card_from_base(basecard);
2275 grdrm_object *object;
2278 HASHMAP_FOREACH(object, card->object_map, iter) {
2282 if (object->type != GRDRM_TYPE_CRTC)
2285 grdrm_crtc_commit(crtc_from_object(object));
2289 static void grdrm_card_restore(grdev_card *basecard) {
2290 grdrm_card *card = grdrm_card_from_base(basecard);
2291 grdrm_object *object;
2294 HASHMAP_FOREACH(object, card->object_map, iter) {
2298 if (object->type != GRDRM_TYPE_CRTC)
2301 grdrm_crtc_restore(crtc_from_object(object));
2305 static void grdrm_card_enable(grdrm_card *card) {
2308 if (card->fd < 0 || card->running)
2311 /* ignore cards without DUMB_BUFFER capability */
2312 if (!card->cap_dumb)
2315 assert(card->fd_src);
2317 log_debug("grdrm: %s/%s: enable", card->base.session->name, card->base.name);
2319 card->running = true;
2320 sd_event_source_set_enabled(card->fd_src, SD_EVENT_ON);
2321 grdrm_card_hotplug(card);
2324 static void grdrm_card_disable(grdrm_card *card) {
2325 grdrm_object *object;
2330 if (card->fd < 0 || !card->running)
2333 assert(card->fd_src);
2335 log_debug("grdrm: %s/%s: disable", card->base.session->name, card->base.name);
2337 card->running = false;
2338 card->ready = false;
2339 sd_event_source_set_enabled(card->fd_src, SD_EVENT_OFF);
2341 /* stop all pipes */
2342 HASHMAP_FOREACH(object, card->object_map, iter) {
2345 if (object->type != GRDRM_TYPE_CRTC)
2348 crtc = crtc_from_object(object);
2349 crtc->applied = false;
2351 grdev_pipe_ready(&crtc->pipe->base, false);
2355 static int grdrm_card_open(grdrm_card *card, int dev_fd) {
2356 _cleanup_(grdev_session_unpinp) grdev_session *pin = NULL;
2357 _cleanup_close_ int fd = dev_fd;
2358 struct drm_get_cap cap;
2362 assert(dev_fd >= 0);
2363 assert(card->fd != dev_fd);
2365 pin = grdev_session_pin(card->base.session);
2366 grdrm_card_close(card);
2368 log_debug("grdrm: %s/%s: open", card->base.session->name, card->base.name);
2370 r = fd_nonblock(fd, true);
2374 r = fd_cloexec(fd, true);
2378 flags = fcntl(fd, F_GETFL, 0);
2381 if ((flags & O_ACCMODE) != O_RDWR)
2384 r = sd_event_add_io(card->base.session->context->event,
2387 EPOLLHUP | EPOLLERR | EPOLLIN,
2393 sd_event_source_set_enabled(card->fd_src, SD_EVENT_OFF);
2395 card->hotplug = true;
2399 /* cache DUMB_BUFFER capability */
2400 cap.capability = DRM_CAP_DUMB_BUFFER;
2402 r = ioctl(card->fd, DRM_IOCTL_GET_CAP, &cap);
2403 card->cap_dumb = r >= 0 && cap.value;
2405 log_debug("grdrm: %s/%s: cannot retrieve DUMB_BUFFER capability: %s",
2406 card->base.session->name, card->base.name, strerror(-r));
2407 else if (!card->cap_dumb)
2408 log_debug("grdrm: %s/%s: DUMB_BUFFER capability not supported",
2409 card->base.session->name, card->base.name);
2411 /* cache TIMESTAMP_MONOTONIC capability */
2412 cap.capability = DRM_CAP_TIMESTAMP_MONOTONIC;
2414 r = ioctl(card->fd, DRM_IOCTL_GET_CAP, &cap);
2415 card->cap_monotonic = r >= 0 && cap.value;
2417 log_debug("grdrm: %s/%s: cannot retrieve TIMESTAMP_MONOTONIC capability: %s",
2418 card->base.session->name, card->base.name, strerror(-r));
2419 else if (!card->cap_monotonic)
2420 log_debug("grdrm: %s/%s: TIMESTAMP_MONOTONIC is disabled globally, fix this NOW!",
2421 card->base.session->name, card->base.name);
2426 static void grdrm_card_close(grdrm_card *card) {
2427 grdrm_object *object;
2432 log_debug("grdrm: %s/%s: close", card->base.session->name, card->base.name);
2434 grdrm_card_disable(card);
2436 card->fd_src = sd_event_source_unref(card->fd_src);
2437 card->fd = safe_close(card->fd);
2439 grdev_session_pin(card->base.session);
2440 while ((object = hashmap_first(card->object_map)))
2441 grdrm_object_free(object);
2442 grdev_session_unpin(card->base.session);
2445 static bool grdrm_card_async(grdrm_card *card, int r) {
2448 /* If we get EACCES on runtime DRM calls, we lost DRM-Master
2449 * (or we did something terribly wrong). Immediately disable
2450 * the card, so we stop all pipes and wait to be activated
2452 grdrm_card_disable(card);
2455 /* DRM objects can be hotplugged at any time. If an object is
2456 * removed that we use, we remember that state so a following
2457 * call can test for this.
2458 * Note that we also get a uevent as followup, this will resync
2459 * the whole device. */
2460 card->async_hotplug = true;
2464 return !card->ready;
2469 * The unmanaged DRM card opens the device node for a given DRM device
2470 * directly (/dev/dri/cardX) and thus needs sufficient privileges. It opens
2471 * the device only if we really require it and releases it as soon as we're
2472 * disabled or closed.
2473 * The unmanaged element can be used in all situations where you have direct
2474 * access to DRM device nodes. Unlike managed DRM elements, it can be used
2475 * outside of user sessions and in emergency situations where logind is not
2479 static void unmanaged_card_enable(grdev_card *basecard) {
2480 unmanaged_card *cu = unmanaged_card_from_base(basecard);
2483 if (cu->card.fd < 0) {
2484 /* try open on activation if it failed during allocation */
2485 fd = open(cu->devnode, O_RDWR | O_CLOEXEC | O_NOCTTY | O_NONBLOCK);
2487 /* not fatal; simply ignore the device */
2488 log_debug("grdrm: %s/%s: cannot open node %s: %m",
2489 basecard->session->name, basecard->name, cu->devnode);
2493 /* we might already be DRM-Master by open(); that's fine */
2495 r = grdrm_card_open(&cu->card, fd);
2497 log_debug("grdrm: %s/%s: cannot open: %s",
2498 basecard->session->name, basecard->name, strerror(-r));
2503 r = ioctl(cu->card.fd, DRM_IOCTL_SET_MASTER, 0);
2505 log_debug("grdrm: %s/%s: cannot acquire DRM-Master: %m",
2506 basecard->session->name, basecard->name);
2510 grdrm_card_enable(&cu->card);
2513 static void unmanaged_card_disable(grdev_card *basecard) {
2514 unmanaged_card *cu = unmanaged_card_from_base(basecard);
2516 grdrm_card_disable(&cu->card);
2519 static int unmanaged_card_new(grdev_card **out, grdev_session *session, struct udev_device *ud) {
2520 _cleanup_(grdev_card_freep) grdev_card *basecard = NULL;
2521 char name[GRDRM_CARD_NAME_MAX];
2523 const char *devnode;
2527 assert_return(session, -EINVAL);
2528 assert_return(ud, -EINVAL);
2530 devnode = udev_device_get_devnode(ud);
2531 devnum = udev_device_get_devnum(ud);
2532 if (!devnode || devnum == 0)
2535 grdrm_name(name, devnum);
2537 cu = new0(unmanaged_card, 1);
2541 basecard = &cu->card.base;
2542 cu->card = GRDRM_CARD_INIT(&unmanaged_card_vtable, session);
2544 cu->devnode = strdup(devnode);
2548 r = grdrm_card_add(&cu->card, name);
2552 /* try to open but ignore errors */
2553 fd = open(cu->devnode, O_RDWR | O_CLOEXEC | O_NOCTTY | O_NONBLOCK);
2555 /* not fatal; allow uaccess based control on activation */
2556 log_debug("grdrm: %s/%s: cannot open node %s: %m",
2557 basecard->session->name, basecard->name, cu->devnode);
2559 /* We might get DRM-Master implicitly on open(); drop it immediately
2560 * so we acquire it only once we're actually enabled. We don't
2561 * really care whether this call fails or not, but lets log any
2562 * weird errors, anyway. */
2563 r = ioctl(fd, DRM_IOCTL_DROP_MASTER, 0);
2564 if (r < 0 && errno != EACCES && errno != EINVAL)
2565 log_debug("grdrm: %s/%s: cannot drop DRM-Master: %m",
2566 basecard->session->name, basecard->name);
2568 r = grdrm_card_open(&cu->card, fd);
2570 log_debug("grdrm: %s/%s: cannot open: %s",
2571 basecard->session->name, basecard->name, strerror(-r));
2580 static void unmanaged_card_free(grdev_card *basecard) {
2581 unmanaged_card *cu = unmanaged_card_from_base(basecard);
2583 assert(!basecard->enabled);
2585 grdrm_card_close(&cu->card);
2586 grdrm_card_destroy(&cu->card);
2591 static const grdev_card_vtable unmanaged_card_vtable = {
2592 .free = unmanaged_card_free,
2593 .enable = unmanaged_card_enable,
2594 .disable = unmanaged_card_disable,
2595 .commit = grdrm_card_commit,
2596 .restore = grdrm_card_restore,
2601 * The managed DRM card uses systemd-logind to acquire DRM devices. This
2602 * means, we do not open the device node /dev/dri/cardX directly. Instead,
2603 * logind passes us a file-descriptor whenever our session is activated. Thus,
2604 * we don't need access to the device node directly.
2605 * Furthermore, whenever the session is put asleep, logind revokes the
2606 * file-descriptor so we loose access to the device.
2607 * Managed DRM cards should be preferred over unmanaged DRM cards whenever
2608 * you run inside a user session with exclusive device access.
2611 static void managed_card_enable(grdev_card *card) {
2612 managed_card *cm = managed_card_from_base(card);
2614 /* If the device is manually re-enabled, we try to resume our card
2615 * management. Note that we have no control over DRM-Master and the fd,
2616 * so we have to take over the state from the last logind event. */
2619 grdrm_card_enable(&cm->card);
2622 static void managed_card_disable(grdev_card *card) {
2623 managed_card *cm = managed_card_from_base(card);
2625 /* If the device is manually disabled, we keep the FD but put our card
2626 * management asleep. This way, we can wake up at any time, but don't
2627 * touch the device while asleep. */
2629 grdrm_card_disable(&cm->card);
2632 static int managed_card_pause_device_fn(sd_bus *bus,
2633 sd_bus_message *signal,
2635 sd_bus_error *ret_error) {
2636 managed_card *cm = userdata;
2637 grdev_session *session = cm->card.base.session;
2638 uint32_t major, minor;
2643 * We get PauseDevice() signals from logind whenever a device we
2644 * requested was, or is about to be, paused. Arguments are major/minor
2645 * number of the device and the mode of the operation.
2646 * In case the event is not about our device, we ignore it. Otherwise,
2647 * we treat it as asynchronous DRM-DROP-MASTER. Note that we might have
2648 * already handled an EACCES error from a modeset ioctl, in which case
2649 * we already disabled the device.
2651 * @mode can be one of the following:
2652 * "pause": The device is about to be paused. We must react
2653 * immediately and respond with PauseDeviceComplete(). Once
2654 * we replied, logind will pause the device. Note that
2655 * logind might apply any kind of timeout and force pause
2656 * the device if we don't respond in a timely manner. In
2657 * this case, we will receive a second PauseDevice event
2658 * with @mode set to "force" (or similar).
2659 * "force": The device was disabled forecfully by logind. DRM-Master
2660 * was already dropped. This is just an asynchronous
2661 * notification so we can put the device asleep (in case
2662 * we didn't already notice the dropped DRM-Master).
2663 * "gone": This is like "force" but is sent if the device was
2664 * paused due to a device-removal event.
2666 * We always handle PauseDevice signals as "force" as we properly
2667 * support asynchronously dropping DRM-Master, anyway. But in case
2668 * logind sent mode "pause", we also call PauseDeviceComplete() to
2669 * immediately acknowledge the request.
2672 r = sd_bus_message_read(signal, "uus", &major, &minor, &mode);
2674 log_debug("grdrm: %s/%s: erroneous PauseDevice signal",
2675 session->name, cm->card.base.name);
2679 /* not our device? */
2680 if (makedev(major, minor) != cm->devnum)
2684 grdrm_card_disable(&cm->card);
2686 if (streq(mode, "pause")) {
2687 _cleanup_bus_message_unref_ sd_bus_message *m = NULL;
2690 * Sending PauseDeviceComplete() is racy if logind triggers the
2691 * timeout. That is, if we take too long and logind pauses the
2692 * device by sending a forced PauseDevice, our
2693 * PauseDeviceComplete call will be stray. That's fine, though.
2694 * logind ignores such stray calls. Only if logind also sent a
2695 * further PauseDevice() signal, it might match our call
2696 * incorrectly to the newer PauseDevice(). That's fine, too, as
2697 * we handle that event asynchronously, anyway. Therefore,
2698 * whatever happens, we're fine. Yay!
2701 r = sd_bus_message_new_method_call(session->context->sysbus,
2703 "org.freedesktop.login1",
2705 "org.freedesktop.login1.Session",
2706 "PauseDeviceComplete");
2708 r = sd_bus_message_append(m, "uu", major, minor);
2710 r = sd_bus_send(session->context->sysbus, m, NULL);
2714 log_debug("grdrm: %s/%s: cannot send PauseDeviceComplete: %s",
2715 session->name, cm->card.base.name, strerror(-r));
2721 static int managed_card_resume_device_fn(sd_bus *bus,
2722 sd_bus_message *signal,
2724 sd_bus_error *ret_error) {
2725 managed_card *cm = userdata;
2726 grdev_session *session = cm->card.base.session;
2727 uint32_t major, minor;
2731 * We get ResumeDevice signals whenever logind resumed a previously
2732 * paused device. The arguments contain the major/minor number of the
2733 * related device and a new file-descriptor for the freshly opened
2735 * If the signal is not about our device, we simply ignore it.
2736 * Otherwise, we immediately resume the device. Note that we drop the
2737 * new file-descriptor as we already have one from TakeDevice(). logind
2738 * preserves the file-context across pause/resume for DRM but only
2739 * drops/acquires DRM-Master accordingly. This way, our context (like
2740 * DRM-FBs and BOs) is preserved.
2743 r = sd_bus_message_read(signal, "uuh", &major, &minor, &fd);
2745 log_debug("grdrm: %s/%s: erroneous ResumeDevice signal",
2746 session->name, cm->card.base.name);
2750 /* not our device? */
2751 if (makedev(major, minor) != cm->devnum)
2754 if (cm->card.fd < 0) {
2755 /* This shouldn't happen. We should already own an FD from
2756 * TakeDevice(). However, lets be safe and use this FD in case
2757 * we really don't have one. There is no harm in doing this
2758 * and our code works fine this way. */
2759 fd = fcntl(fd, F_DUPFD_CLOEXEC, 3);
2761 log_debug("grdrm: %s/%s: cannot duplicate fd: %m",
2762 session->name, cm->card.base.name);
2766 r = grdrm_card_open(&cm->card, fd);
2768 log_debug("grdrm: %s/%s: cannot open: %s",
2769 session->name, cm->card.base.name, strerror(-r));
2775 if (cm->card.base.enabled)
2776 grdrm_card_enable(&cm->card);
2781 static int managed_card_setup_bus(managed_card *cm) {
2782 grdev_session *session = cm->card.base.session;
2783 _cleanup_free_ char *match = NULL;
2786 match = strjoin("type='signal',"
2787 "sender='org.freedesktop.login1',"
2788 "interface='org.freedesktop.login1.Session',"
2789 "member='PauseDevice',"
2790 "path='", session->path, "'",
2795 r = sd_bus_add_match(session->context->sysbus,
2796 &cm->slot_pause_device,
2798 managed_card_pause_device_fn,
2804 match = strjoin("type='signal',"
2805 "sender='org.freedesktop.login1',"
2806 "interface='org.freedesktop.login1.Session',"
2807 "member='ResumeDevice',"
2808 "path='", session->path, "'",
2813 r = sd_bus_add_match(session->context->sysbus,
2814 &cm->slot_resume_device,
2816 managed_card_resume_device_fn,
2824 static int managed_card_take_device_fn(sd_bus *bus,
2825 sd_bus_message *reply,
2827 sd_bus_error *ret_error) {
2828 managed_card *cm = userdata;
2829 grdev_session *session = cm->card.base.session;
2832 cm->slot_take_device = sd_bus_slot_unref(cm->slot_take_device);
2834 if (sd_bus_message_is_method_error(reply, NULL)) {
2835 const sd_bus_error *error = sd_bus_message_get_error(reply);
2837 log_debug("grdrm: %s/%s: TakeDevice failed: %s: %s",
2838 session->name, cm->card.base.name, error->name, error->message);
2842 cm->acquired = true;
2844 r = sd_bus_message_read(reply, "hb", &fd, &paused);
2846 log_debug("grdrm: %s/%s: erroneous TakeDevice reply",
2847 session->name, cm->card.base.name);
2851 fd = fcntl(fd, F_DUPFD_CLOEXEC, 3);
2853 log_debug("grdrm: %s/%s: cannot duplicate fd: %m",
2854 session->name, cm->card.base.name);
2858 r = grdrm_card_open(&cm->card, fd);
2860 log_debug("grdrm: %s/%s: cannot open: %s",
2861 session->name, cm->card.base.name, strerror(-r));
2865 if (!paused && cm->card.base.enabled)
2866 grdrm_card_enable(&cm->card);
2871 static void managed_card_take_device(managed_card *cm) {
2872 _cleanup_bus_message_unref_ sd_bus_message *m = NULL;
2873 grdev_session *session = cm->card.base.session;
2876 r = sd_bus_message_new_method_call(session->context->sysbus,
2878 "org.freedesktop.login1",
2880 "org.freedesktop.login1.Session",
2885 r = sd_bus_message_append(m, "uu", major(cm->devnum), minor(cm->devnum));
2889 r = sd_bus_call_async(session->context->sysbus,
2890 &cm->slot_take_device,
2892 managed_card_take_device_fn,
2898 cm->requested = true;
2902 log_debug("grdrm: %s/%s: cannot send TakeDevice request: %s",
2903 session->name, cm->card.base.name, strerror(-r));
2906 static void managed_card_release_device(managed_card *cm) {
2907 _cleanup_bus_message_unref_ sd_bus_message *m = NULL;
2908 grdev_session *session = cm->card.base.session;
2912 * If TakeDevice() is pending or was successful, make sure to
2913 * release the device again. We don't care for return-values,
2914 * so send it without waiting or callbacks.
2915 * If a failed TakeDevice() is pending, but someone else took
2916 * the device on the same bus-connection, we might incorrectly
2917 * release their device. This is an unlikely race, though.
2918 * Furthermore, you really shouldn't have two users of the
2919 * controller-API on the same session, on the same devices, *AND* on
2920 * the same bus-connection. So we don't care for that race..
2923 grdrm_card_close(&cm->card);
2924 cm->requested = false;
2926 if (!cm->acquired && !cm->slot_take_device)
2929 cm->slot_take_device = sd_bus_slot_unref(cm->slot_take_device);
2930 cm->acquired = false;
2932 r = sd_bus_message_new_method_call(session->context->sysbus,
2934 "org.freedesktop.login1",
2936 "org.freedesktop.login1.Session",
2939 r = sd_bus_message_append(m, "uu", major(cm->devnum), minor(cm->devnum));
2941 r = sd_bus_send(session->context->sysbus, m, NULL);
2944 if (r < 0 && r != -ENOTCONN)
2945 log_debug("grdrm: %s/%s: cannot send ReleaseDevice: %s",
2946 session->name, cm->card.base.name, strerror(-r));
2949 static int managed_card_new(grdev_card **out, grdev_session *session, struct udev_device *ud) {
2950 _cleanup_(grdev_card_freep) grdev_card *basecard = NULL;
2951 char name[GRDRM_CARD_NAME_MAX];
2956 assert_return(session, -EINVAL);
2957 assert_return(session->managed, -EINVAL);
2958 assert_return(session->context->sysbus, -EINVAL);
2959 assert_return(ud, -EINVAL);
2961 devnum = udev_device_get_devnum(ud);
2965 grdrm_name(name, devnum);
2967 cm = new0(managed_card, 1);
2971 basecard = &cm->card.base;
2972 cm->card = GRDRM_CARD_INIT(&managed_card_vtable, session);
2973 cm->devnum = devnum;
2975 r = managed_card_setup_bus(cm);
2979 r = grdrm_card_add(&cm->card, name);
2983 managed_card_take_device(cm);
2991 static void managed_card_free(grdev_card *basecard) {
2992 managed_card *cm = managed_card_from_base(basecard);
2994 assert(!basecard->enabled);
2996 managed_card_release_device(cm);
2997 cm->slot_resume_device = sd_bus_slot_unref(cm->slot_resume_device);
2998 cm->slot_pause_device = sd_bus_slot_unref(cm->slot_pause_device);
2999 grdrm_card_destroy(&cm->card);
3003 static const grdev_card_vtable managed_card_vtable = {
3004 .free = managed_card_free,
3005 .enable = managed_card_enable,
3006 .disable = managed_card_disable,
3007 .commit = grdrm_card_commit,
3008 .restore = grdrm_card_restore,
3012 * Generic Constructor
3013 * Instead of relying on the caller to choose between managed and unmanaged
3014 * DRM devices, the grdev_drm_new() constructor does that for you (by
3015 * looking at session->managed).
3018 bool grdev_is_drm_card(grdev_card *basecard) {
3019 return basecard && (basecard->vtable == &unmanaged_card_vtable ||
3020 basecard->vtable == &managed_card_vtable);
3023 grdev_card *grdev_find_drm_card(grdev_session *session, dev_t devnum) {
3024 char name[GRDRM_CARD_NAME_MAX];
3026 assert_return(session, NULL);
3027 assert_return(devnum != 0, NULL);
3029 grdrm_name(name, devnum);
3030 return grdev_find_card(session, name);
3033 int grdev_drm_card_new(grdev_card **out, grdev_session *session, struct udev_device *ud) {
3034 assert_return(session, -EINVAL);
3035 assert_return(ud, -EINVAL);
3037 return session->managed ? managed_card_new(out, session, ud) : unmanaged_card_new(out, session, ud);
3040 void grdev_drm_card_hotplug(grdev_card *basecard, struct udev_device *ud) {
3041 const char *p, *action;
3046 assert(grdev_is_drm_card(basecard));
3049 card = grdrm_card_from_base(basecard);
3051 action = udev_device_get_action(ud);
3052 if (!action || streq(action, "add") || streq(action, "remove")) {
3053 /* If we get add/remove events on DRM nodes without devnum, we
3054 * got hotplugged DRM objects so refresh the device. */
3055 devnum = udev_device_get_devnum(ud);
3057 card->hotplug = true;
3058 grdrm_card_hotplug(card);
3060 } else if (streq_ptr(action, "change")) {
3061 /* A change event with HOTPLUG=1 is sent whenever a connector
3062 * changed state. Refresh the device to update our state. */
3063 p = udev_device_get_property_value(ud, "HOTPLUG");
3064 if (streq_ptr(p, "1")) {
3065 card->hotplug = true;
3066 grdrm_card_hotplug(card);