#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "backend/drm/drm.h" #include "backend/drm/fb.h" #include "backend/drm/iface.h" #include "backend/drm/util.h" #include "render/pixel_format.h" #include "render/drm_format_set.h" #include "render/wlr_renderer.h" #include "types/wlr_output.h" #include "util/env.h" #include "config.h" #if HAVE_LIBLIFTOFF #include #endif // Output state which needs a KMS commit to be applied static const uint32_t COMMIT_OUTPUT_STATE = WLR_OUTPUT_STATE_BUFFER | WLR_OUTPUT_STATE_MODE | WLR_OUTPUT_STATE_ENABLED | WLR_OUTPUT_STATE_GAMMA_LUT | WLR_OUTPUT_STATE_ADAPTIVE_SYNC_ENABLED | WLR_OUTPUT_STATE_LAYERS; static const uint32_t SUPPORTED_OUTPUT_STATE = WLR_OUTPUT_STATE_BACKEND_OPTIONAL | COMMIT_OUTPUT_STATE; bool check_drm_features(struct wlr_drm_backend *drm) { if (drmGetCap(drm->fd, DRM_CAP_CURSOR_WIDTH, &drm->cursor_width)) { drm->cursor_width = 64; } if (drmGetCap(drm->fd, DRM_CAP_CURSOR_HEIGHT, &drm->cursor_height)) { drm->cursor_height = 64; } uint64_t cap; if (drmGetCap(drm->fd, DRM_CAP_PRIME, &cap) || !(cap & DRM_PRIME_CAP_IMPORT)) { wlr_log(WLR_ERROR, "PRIME import not supported"); return false; } if (drm->parent) { if (drmGetCap(drm->parent->fd, DRM_CAP_PRIME, &cap) || !(cap & DRM_PRIME_CAP_EXPORT)) { wlr_log(WLR_ERROR, "PRIME export not supported on primary GPU"); return false; } } if (drmSetClientCap(drm->fd, DRM_CLIENT_CAP_UNIVERSAL_PLANES, 1)) { wlr_log(WLR_ERROR, "DRM universal planes unsupported"); return false; } if (drmGetCap(drm->fd, DRM_CAP_CRTC_IN_VBLANK_EVENT, &cap) || !cap) { wlr_log(WLR_ERROR, "DRM_CRTC_IN_VBLANK_EVENT unsupported"); return false; } if (drmGetCap(drm->fd, DRM_CAP_TIMESTAMP_MONOTONIC, &cap) || !cap) { wlr_log(WLR_ERROR, "DRM_CAP_TIMESTAMP_MONOTONIC unsupported"); return false; } if (env_parse_bool("WLR_DRM_FORCE_LIBLIFTOFF")) { #if HAVE_LIBLIFTOFF wlr_log(WLR_INFO, "WLR_DRM_FORCE_LIBLIFTOFF set, forcing libliftoff interface"); if (drmSetClientCap(drm->fd, DRM_CLIENT_CAP_ATOMIC, 1) != 0) { wlr_log_errno(WLR_ERROR, "drmSetClientCap(ATOMIC) failed"); return false; } drm->iface = &liftoff_iface; #else wlr_log(WLR_ERROR, "libliftoff interface not available"); return false; #endif } else if (env_parse_bool("WLR_DRM_NO_ATOMIC")) { wlr_log(WLR_DEBUG, "WLR_DRM_NO_ATOMIC set, forcing legacy DRM interface"); drm->iface = &legacy_iface; } else if (drmSetClientCap(drm->fd, DRM_CLIENT_CAP_ATOMIC, 1)) { wlr_log(WLR_DEBUG, "Atomic modesetting unsupported, using legacy DRM interface"); drm->iface = &legacy_iface; } else { wlr_log(WLR_DEBUG, "Using atomic DRM interface"); drm->iface = &atomic_iface; } #ifdef DRM_CLIENT_CAP_CURSOR_PLANE_HOTSPOT if (drm->iface == &atomic_iface && drmSetClientCap(drm->fd, DRM_CLIENT_CAP_CURSOR_PLANE_HOTSPOT, 1) == 0) { wlr_log(WLR_INFO, "DRM_CLIENT_CAP_CURSOR_PLANE_HOTSPOT supported"); } #endif if (drm->iface == &legacy_iface) { drm->supports_tearing_page_flips = drmGetCap(drm->fd, DRM_CAP_ASYNC_PAGE_FLIP, &cap) == 0 && cap == 1; } else { drm->supports_tearing_page_flips = drmGetCap(drm->fd, DRM_CAP_ATOMIC_ASYNC_PAGE_FLIP, &cap) == 0 && cap == 1; } if (env_parse_bool("WLR_DRM_NO_MODIFIERS")) { wlr_log(WLR_DEBUG, "WLR_DRM_NO_MODIFIERS set, disabling modifiers"); } else { int ret = drmGetCap(drm->fd, DRM_CAP_ADDFB2_MODIFIERS, &cap); drm->addfb2_modifiers = ret == 0 && cap == 1; wlr_log(WLR_DEBUG, "ADDFB2 modifiers %s", drm->addfb2_modifiers ? "supported" : "unsupported"); } return true; } static bool init_plane_cursor_sizes(struct wlr_drm_plane *plane, const struct drm_plane_size_hint *hints, size_t hints_len) { assert(hints_len > 0); plane->cursor_sizes = calloc(hints_len, sizeof(plane->cursor_sizes[0])); if (plane->cursor_sizes == NULL) { return false; } plane->cursor_sizes_len = hints_len; for (size_t i = 0; i < hints_len; i++) { const struct drm_plane_size_hint hint = hints[i]; plane->cursor_sizes[i] = (struct wlr_output_cursor_size){ .width = hint.width, .height = hint.height, }; } return true; } static bool init_plane(struct wlr_drm_backend *drm, struct wlr_drm_plane *p, const drmModePlane *drm_plane) { uint32_t id = drm_plane->plane_id; struct wlr_drm_plane_props props = {0}; if (!get_drm_plane_props(drm->fd, id, &props)) { return false; } uint64_t type; if (!get_drm_prop(drm->fd, id, props.type, &type)) { return false; } p->type = type; p->id = drm_plane->plane_id; p->props = props; p->initial_crtc_id = drm_plane->crtc_id; for (size_t i = 0; i < drm_plane->count_formats; ++i) { // Force a LINEAR layout for the cursor if the driver doesn't support // modifiers wlr_drm_format_set_add(&p->formats, drm_plane->formats[i], DRM_FORMAT_MOD_LINEAR); if (type != DRM_PLANE_TYPE_CURSOR) { wlr_drm_format_set_add(&p->formats, drm_plane->formats[i], DRM_FORMAT_MOD_INVALID); } } if (p->props.in_formats && drm->addfb2_modifiers) { uint64_t blob_id; if (!get_drm_prop(drm->fd, p->id, p->props.in_formats, &blob_id)) { wlr_log(WLR_ERROR, "Failed to read IN_FORMATS property"); return false; } drmModePropertyBlobRes *blob = drmModeGetPropertyBlob(drm->fd, blob_id); if (!blob) { wlr_log(WLR_ERROR, "Failed to read IN_FORMATS blob"); return false; } drmModeFormatModifierIterator iter = {0}; while (drmModeFormatModifierBlobIterNext(blob, &iter)) { wlr_drm_format_set_add(&p->formats, iter.fmt, iter.mod); } drmModeFreePropertyBlob(blob); } uint64_t size_hints_blob_id = 0; if (p->props.size_hints) { if (!get_drm_prop(drm->fd, p->id, p->props.size_hints, &size_hints_blob_id)) { wlr_log(WLR_ERROR, "Failed to read SIZE_HINTS property"); return false; } } if (size_hints_blob_id != 0) { drmModePropertyBlobRes *blob = drmModeGetPropertyBlob(drm->fd, size_hints_blob_id); if (!blob) { wlr_log(WLR_ERROR, "Failed to read SIZE_HINTS blob"); return false; } const struct drm_plane_size_hint *size_hints = blob->data; size_t size_hints_len = blob->length / sizeof(size_hints[0]); if (!init_plane_cursor_sizes(p, size_hints, size_hints_len)) { return false; } drmModeFreePropertyBlob(blob); } else { const struct drm_plane_size_hint size_hint = { .width = drm->cursor_width, .height = drm->cursor_height, }; if (!init_plane_cursor_sizes(p, &size_hint, 1)) { return false; } } assert(drm->num_crtcs <= 32); for (size_t j = 0; j < drm->num_crtcs; j++) { uint32_t crtc_bit = 1 << j; if ((drm_plane->possible_crtcs & crtc_bit) == 0) { continue; } struct wlr_drm_crtc *crtc = &drm->crtcs[j]; if (type == DRM_PLANE_TYPE_PRIMARY && !crtc->primary) { crtc->primary = p; break; } if (type == DRM_PLANE_TYPE_CURSOR && !crtc->cursor) { crtc->cursor = p; break; } } return true; } static bool init_planes(struct wlr_drm_backend *drm) { drmModePlaneRes *plane_res = drmModeGetPlaneResources(drm->fd); if (!plane_res) { wlr_log_errno(WLR_ERROR, "Failed to get DRM plane resources"); return false; } wlr_log(WLR_INFO, "Found %"PRIu32" DRM planes", plane_res->count_planes); drm->num_planes = plane_res->count_planes; drm->planes = calloc(drm->num_planes, sizeof(*drm->planes)); if (drm->planes == NULL) { wlr_log_errno(WLR_ERROR, "Allocation failed"); goto error; } for (uint32_t i = 0; i < plane_res->count_planes; ++i) { uint32_t id = plane_res->planes[i]; drmModePlane *drm_plane = drmModeGetPlane(drm->fd, id); if (!drm_plane) { wlr_log_errno(WLR_ERROR, "Failed to get DRM plane"); goto error; } struct wlr_drm_plane *plane = &drm->planes[i]; if (!init_plane(drm, plane, drm_plane)) { goto error; } drmModeFreePlane(drm_plane); } drmModeFreePlaneResources(plane_res); return true; error: free(drm->planes); drmModeFreePlaneResources(plane_res); return false; } bool init_drm_resources(struct wlr_drm_backend *drm) { drmModeRes *res = drmModeGetResources(drm->fd); if (!res) { wlr_log_errno(WLR_ERROR, "Failed to get DRM resources"); return false; } wlr_log(WLR_INFO, "Found %d DRM CRTCs", res->count_crtcs); drm->num_crtcs = res->count_crtcs; if (drm->num_crtcs == 0) { drmModeFreeResources(res); return true; } drm->crtcs = calloc(drm->num_crtcs, sizeof(drm->crtcs[0])); if (!drm->crtcs) { wlr_log_errno(WLR_ERROR, "Allocation failed"); goto error_res; } for (size_t i = 0; i < drm->num_crtcs; ++i) { struct wlr_drm_crtc *crtc = &drm->crtcs[i]; crtc->id = res->crtcs[i]; drmModeCrtc *drm_crtc = drmModeGetCrtc(drm->fd, crtc->id); if (drm_crtc == NULL) { wlr_log_errno(WLR_ERROR, "drmModeGetCrtc failed"); goto error_res; } crtc->legacy_gamma_size = drm_crtc->gamma_size; drmModeFreeCrtc(drm_crtc); if (!get_drm_crtc_props(drm->fd, crtc->id, &crtc->props)) { goto error_crtcs; } wl_list_init(&crtc->layers); } if (!init_planes(drm)) { goto error_crtcs; } if (drm->iface->init != NULL && !drm->iface->init(drm)) { goto error_crtcs; } drmModeFreeResources(res); return true; error_crtcs: free(drm->crtcs); error_res: drmModeFreeResources(res); return false; } static void drm_plane_finish_surface(struct wlr_drm_plane *plane) { if (!plane) { return; } drm_fb_clear(&plane->queued_fb); drm_fb_clear(&plane->current_fb); finish_drm_surface(&plane->mgpu_surf); } void finish_drm_resources(struct wlr_drm_backend *drm) { if (!drm) { return; } if (drm->iface->finish != NULL) { drm->iface->finish(drm); } for (size_t i = 0; i < drm->num_crtcs; ++i) { struct wlr_drm_crtc *crtc = &drm->crtcs[i]; if (crtc->mode_id && crtc->own_mode_id) { drmModeDestroyPropertyBlob(drm->fd, crtc->mode_id); } if (crtc->gamma_lut) { drmModeDestroyPropertyBlob(drm->fd, crtc->gamma_lut); } } free(drm->crtcs); for (size_t i = 0; i < drm->num_planes; ++i) { struct wlr_drm_plane *plane = &drm->planes[i]; drm_plane_finish_surface(plane); wlr_drm_format_set_finish(&plane->formats); } free(drm->planes); } static struct wlr_drm_connector *get_drm_connector_from_output( struct wlr_output *wlr_output) { assert(wlr_output_is_drm(wlr_output)); struct wlr_drm_connector *conn = wl_container_of(wlr_output, conn, output); return conn; } static void layer_handle_addon_destroy(struct wlr_addon *addon) { struct wlr_drm_layer *layer = wl_container_of(addon, layer, addon); wlr_addon_finish(&layer->addon); wl_list_remove(&layer->link); #if HAVE_LIBLIFTOFF liftoff_layer_destroy(layer->liftoff); #endif drm_fb_clear(&layer->pending_fb); drm_fb_clear(&layer->queued_fb); drm_fb_clear(&layer->current_fb); free(layer->candidate_planes); free(layer); } const struct wlr_addon_interface layer_impl = { .name = "wlr_drm_layer", .destroy = layer_handle_addon_destroy, }; struct wlr_drm_layer *get_drm_layer(struct wlr_drm_backend *drm, struct wlr_output_layer *wlr_layer) { struct wlr_addon *addon = wlr_addon_find(&wlr_layer->addons, drm, &layer_impl); assert(addon != NULL); struct wlr_drm_layer *layer = wl_container_of(addon, layer, addon); return layer; } static struct wlr_drm_layer *get_or_create_layer(struct wlr_drm_backend *drm, struct wlr_drm_crtc *crtc, struct wlr_output_layer *wlr_layer) { struct wlr_drm_layer *layer; struct wlr_addon *addon = wlr_addon_find(&wlr_layer->addons, drm, &layer_impl); if (addon != NULL) { layer = wl_container_of(addon, layer, addon); return layer; } layer = calloc(1, sizeof(*layer)); if (layer == NULL) { return NULL; } layer->wlr = wlr_layer; #if HAVE_LIBLIFTOFF layer->liftoff = liftoff_layer_create(crtc->liftoff); if (layer->liftoff == NULL) { free(layer); return NULL; } #else abort(); // unreachable #endif layer->candidate_planes = calloc(drm->num_planes, sizeof(layer->candidate_planes[0])); if (layer->candidate_planes == NULL) { #if HAVE_LIBLIFTOFF liftoff_layer_destroy(layer->liftoff); #endif free(layer); return NULL; } wlr_addon_init(&layer->addon, &wlr_layer->addons, drm, &layer_impl); wl_list_insert(&crtc->layers, &layer->link); return layer; } void drm_page_flip_destroy(struct wlr_drm_page_flip *page_flip) { if (!page_flip) { return; } wl_list_remove(&page_flip->link); free(page_flip->connectors); free(page_flip); } static struct wlr_drm_page_flip *drm_page_flip_create(struct wlr_drm_backend *drm, const struct wlr_drm_device_state *state) { struct wlr_drm_page_flip *page_flip = calloc(1, sizeof(*page_flip)); if (page_flip == NULL) { return NULL; } page_flip->connectors_len = state->connectors_len; page_flip->connectors = calloc(page_flip->connectors_len, sizeof(page_flip->connectors[0])); if (page_flip->connectors == NULL) { free(page_flip); return NULL; } for (size_t i = 0; i < state->connectors_len; i++) { struct wlr_drm_connector *conn = state->connectors[i].connector; page_flip->connectors[i] = (struct wlr_drm_page_flip_connector){ .connector = conn, .crtc_id = conn->crtc->id, }; } wl_list_insert(&drm->page_flips, &page_flip->link); return page_flip; } static struct wlr_drm_connector *drm_page_flip_pop( struct wlr_drm_page_flip *page_flip, uint32_t crtc_id) { bool found = false; size_t i; for (i = 0; i < page_flip->connectors_len; i++) { if (page_flip->connectors[i].crtc_id == crtc_id) { found = true; break; } } if (!found) { return NULL; } struct wlr_drm_connector *conn = page_flip->connectors[i].connector; if (i != page_flip->connectors_len - 1) { page_flip->connectors[i] = page_flip->connectors[page_flip->connectors_len - 1]; } page_flip->connectors_len--; return conn; } static void drm_connector_set_pending_page_flip(struct wlr_drm_connector *conn, struct wlr_drm_page_flip *page_flip) { if (conn->pending_page_flip != NULL) { struct wlr_drm_page_flip *page_flip = conn->pending_page_flip; for (size_t i = 0; i < page_flip->connectors_len; i++) { if (page_flip->connectors[i].connector == conn) { page_flip->connectors[i].connector = NULL; } } } conn->pending_page_flip = page_flip; } static void drm_connector_apply_commit(const struct wlr_drm_connector_state *state, struct wlr_drm_page_flip *page_flip) { struct wlr_drm_connector *conn = state->connector; struct wlr_drm_crtc *crtc = conn->crtc; drm_fb_copy(&crtc->primary->queued_fb, state->primary_fb); if (crtc->cursor != NULL) { drm_fb_copy(&crtc->cursor->queued_fb, state->cursor_fb); } drm_fb_clear(&conn->cursor_pending_fb); struct wlr_drm_layer *layer; wl_list_for_each(layer, &crtc->layers, link) { drm_fb_move(&layer->queued_fb, &layer->pending_fb); } drm_connector_set_pending_page_flip(conn, page_flip); if (state->base->committed & WLR_OUTPUT_STATE_MODE) { conn->refresh = calculate_refresh_rate(&state->mode); } if (!state->active) { drm_plane_finish_surface(crtc->primary); drm_plane_finish_surface(crtc->cursor); drm_fb_clear(&conn->cursor_pending_fb); conn->cursor_enabled = false; conn->crtc = NULL; } } static void drm_connector_rollback_commit(const struct wlr_drm_connector_state *state) { struct wlr_drm_crtc *crtc = state->connector->crtc; // The set_cursor() hook is a bit special: it's not really synchronized // to commit() or test(). Once set_cursor() returns true, the new // cursor is effectively committed. So don't roll it back here, or we // risk ending up in a state where we don't have a cursor FB but // wlr_drm_connector.cursor_enabled is true. // TODO: fix our output interface to avoid this issue. struct wlr_drm_layer *layer; wl_list_for_each(layer, &crtc->layers, link) { drm_fb_clear(&layer->pending_fb); } } static bool drm_commit(struct wlr_drm_backend *drm, const struct wlr_drm_device_state *state, uint32_t flags, bool test_only) { // Disallow atomic-only flags assert((flags & ~DRM_MODE_PAGE_FLIP_FLAGS) == 0); struct wlr_drm_page_flip *page_flip = NULL; if (flags & DRM_MODE_PAGE_FLIP_EVENT) { page_flip = drm_page_flip_create(drm, state); if (page_flip == NULL) { return false; } } bool ok = drm->iface->commit(drm, state, page_flip, flags, test_only); if (ok && !test_only) { for (size_t i = 0; i < state->connectors_len; i++) { drm_connector_apply_commit(&state->connectors[i], page_flip); } } else { for (size_t i = 0; i < state->connectors_len; i++) { drm_connector_rollback_commit(&state->connectors[i]); } drm_page_flip_destroy(page_flip); } return ok; } static void drm_connector_state_init(struct wlr_drm_connector_state *state, struct wlr_drm_connector *conn, const struct wlr_output_state *base) { *state = (struct wlr_drm_connector_state){ .connector = conn, .base = base, .active = output_pending_enabled(&conn->output, base), }; struct wlr_output_mode *mode = conn->output.current_mode; int32_t width = conn->output.width; int32_t height = conn->output.height; int32_t refresh = conn->output.refresh; if (base->committed & WLR_OUTPUT_STATE_MODE) { switch (base->mode_type) { case WLR_OUTPUT_STATE_MODE_FIXED:; mode = base->mode; break; case WLR_OUTPUT_STATE_MODE_CUSTOM: mode = NULL; width = base->custom_mode.width; height = base->custom_mode.height; refresh = base->custom_mode.refresh; break; } } if (mode) { struct wlr_drm_mode *drm_mode = wl_container_of(mode, drm_mode, wlr_mode); state->mode = drm_mode->drm_mode; } else { generate_cvt_mode(&state->mode, width, height, (float)refresh / 1000); state->mode.type = DRM_MODE_TYPE_USERDEF; } if (output_pending_enabled(&conn->output, base)) { // The CRTC must be set up before this function is called assert(conn->crtc != NULL); struct wlr_drm_plane *primary = conn->crtc->primary; if (primary->queued_fb != NULL) { state->primary_fb = drm_fb_lock(primary->queued_fb); } else if (primary->current_fb != NULL) { state->primary_fb = drm_fb_lock(primary->current_fb); } if (conn->cursor_enabled) { struct wlr_drm_plane *cursor = conn->crtc->cursor; assert(cursor != NULL); if (conn->cursor_pending_fb != NULL) { state->cursor_fb = drm_fb_lock(conn->cursor_pending_fb); } else if (cursor->queued_fb != NULL) { state->cursor_fb = drm_fb_lock(cursor->queued_fb); } else if (cursor->current_fb != NULL) { state->cursor_fb = drm_fb_lock(cursor->current_fb); } } } } static void drm_connector_state_finish(struct wlr_drm_connector_state *state) { drm_fb_clear(&state->primary_fb); drm_fb_clear(&state->cursor_fb); } static bool drm_connector_state_update_primary_fb(struct wlr_drm_connector *conn, struct wlr_drm_connector_state *state) { struct wlr_drm_backend *drm = conn->backend; assert(state->base->committed & WLR_OUTPUT_STATE_BUFFER); struct wlr_drm_crtc *crtc = conn->crtc; assert(crtc != NULL); struct wlr_drm_plane *plane = crtc->primary; struct wlr_buffer *source_buf = state->base->buffer; struct wlr_buffer *local_buf; if (drm->parent) { struct wlr_drm_format format = {0}; if (!drm_plane_pick_render_format(plane, &format, &drm->mgpu_renderer)) { wlr_log(WLR_ERROR, "Failed to pick primary plane format"); return false; } // TODO: fallback to modifier-less buffer allocation bool ok = init_drm_surface(&plane->mgpu_surf, &drm->mgpu_renderer, source_buf->width, source_buf->height, &format); wlr_drm_format_finish(&format); if (!ok) { return false; } local_buf = drm_surface_blit(&plane->mgpu_surf, source_buf); if (local_buf == NULL) { return false; } } else { local_buf = wlr_buffer_lock(source_buf); } bool ok = drm_fb_import(&state->primary_fb, drm, local_buf, &plane->formats); wlr_buffer_unlock(local_buf); if (!ok) { wlr_drm_conn_log(conn, WLR_DEBUG, "Failed to import buffer for scan-out"); return false; } return true; } static bool drm_connector_set_pending_layer_fbs(struct wlr_drm_connector *conn, const struct wlr_output_state *state) { struct wlr_drm_backend *drm = conn->backend; struct wlr_drm_crtc *crtc = conn->crtc; if (!crtc || drm->parent) { return false; } if (!crtc->liftoff) { return true; // libliftoff is disabled } assert(state->committed & WLR_OUTPUT_STATE_LAYERS); for (size_t i = 0; i < state->layers_len; i++) { struct wlr_output_layer_state *layer_state = &state->layers[i]; struct wlr_drm_layer *layer = get_or_create_layer(drm, crtc, layer_state->layer); if (!layer) { return false; } if (layer_state->buffer != NULL) { drm_fb_import(&layer->pending_fb, drm, layer_state->buffer, NULL); } else { drm_fb_clear(&layer->pending_fb); } } return true; } static bool drm_connector_alloc_crtc(struct wlr_drm_connector *conn); static bool drm_connector_prepare(struct wlr_drm_connector_state *conn_state, bool test_only) { const struct wlr_output_state *state = conn_state->base; struct wlr_drm_connector *conn = conn_state->connector; struct wlr_output *output = &conn->output; uint32_t unsupported = state->committed & ~SUPPORTED_OUTPUT_STATE; if (unsupported != 0) { wlr_log(WLR_DEBUG, "Unsupported output state fields: 0x%"PRIx32, unsupported); return false; } if ((state->committed & WLR_OUTPUT_STATE_ENABLED) && state->enabled) { if (output->current_mode == NULL && !(state->committed & WLR_OUTPUT_STATE_MODE)) { wlr_drm_conn_log(conn, WLR_DEBUG, "Can't enable an output without a mode"); return false; } } if ((state->committed & WLR_OUTPUT_STATE_ADAPTIVE_SYNC_ENABLED) && state->adaptive_sync_enabled && !output->adaptive_sync_supported) { wlr_drm_conn_log(conn, WLR_DEBUG, "Can't enable adaptive sync: connector doesn't support VRR"); return false; } if (test_only && conn->backend->parent) { // If we're running as a secondary GPU, we can't perform an atomic // commit without blitting a buffer. return true; } if (state->committed & WLR_OUTPUT_STATE_BUFFER) { if (!drm_connector_state_update_primary_fb(conn, conn_state)) { return false; } if (conn_state->base->tearing_page_flip && !conn->backend->supports_tearing_page_flips) { wlr_log(WLR_ERROR, "Attempted to submit a tearing page flip to an unsupported backend!"); return false; } } if (state->committed & WLR_OUTPUT_STATE_LAYERS) { if (!drm_connector_set_pending_layer_fbs(conn, conn_state->base)) { return false; } } if (conn_state->active && !conn_state->primary_fb) { wlr_drm_conn_log(conn, WLR_DEBUG, "No primary frame buffer available for this connector"); return false; } return true; } static bool drm_connector_commit_state(struct wlr_drm_connector *conn, const struct wlr_output_state *state, bool test_only) { struct wlr_drm_backend *drm = conn->backend; if (!drm->session->active) { return false; } if (test_only && (state->committed & COMMIT_OUTPUT_STATE) == 0) { // This commit doesn't change the KMS state return true; } if (output_pending_enabled(&conn->output, state) && !drm_connector_alloc_crtc(conn)) { wlr_drm_conn_log(conn, WLR_DEBUG, "No CRTC available for this connector"); return false; } bool ok = false; struct wlr_drm_connector_state pending = {0}; drm_connector_state_init(&pending, conn, state); struct wlr_drm_device_state pending_dev = { .modeset = state->allow_reconfiguration, // The wlr_output API requires non-modeset commits with a new buffer to // wait for the frame event. However compositors often perform // non-modesets commits without a new buffer without waiting for the // frame event. In that case we need to make the KMS commit blocking, // otherwise the kernel will error out with EBUSY. .nonblock = !state->allow_reconfiguration && (state->committed & WLR_OUTPUT_STATE_BUFFER), .connectors = &pending, .connectors_len = 1, }; if (!drm_connector_prepare(&pending, test_only)) { goto out; } if (test_only && conn->backend->parent) { // If we're running as a secondary GPU, we can't perform an atomic // commit without blitting a buffer. ok = true; goto out; } if (!pending.active && conn->crtc == NULL) { // Disabling an already-disabled connector ok = true; goto out; } if (!test_only && pending_dev.modeset) { if (pending.active) { wlr_drm_conn_log(conn, WLR_INFO, "Modesetting with %dx%d @ %.3f Hz", pending.mode.hdisplay, pending.mode.vdisplay, (float)calculate_refresh_rate(&pending.mode) / 1000); } else { wlr_drm_conn_log(conn, WLR_INFO, "Turning off"); } } // wlr_drm_interface.crtc_commit will perform either a non-blocking // page-flip, either a blocking modeset. When performing a blocking modeset // we'll wait for all queued page-flips to complete, so we don't need this // safeguard. if (!test_only && pending_dev.nonblock && conn->pending_page_flip != NULL) { wlr_drm_conn_log(conn, WLR_ERROR, "Failed to page-flip output: " "a page-flip is already pending"); goto out; } uint32_t flags = 0; if (!test_only && pending.active) { flags |= DRM_MODE_PAGE_FLIP_EVENT; } if (pending.base->tearing_page_flip) { flags |= DRM_MODE_PAGE_FLIP_ASYNC; } ok = drm_commit(drm, &pending_dev, flags, test_only); out: drm_connector_state_finish(&pending); return ok; } static bool drm_connector_test(struct wlr_output *output, const struct wlr_output_state *state) { struct wlr_drm_connector *conn = get_drm_connector_from_output(output); return drm_connector_commit_state(conn, state, true); } static bool drm_connector_commit(struct wlr_output *output, const struct wlr_output_state *state) { struct wlr_drm_connector *conn = get_drm_connector_from_output(output); return drm_connector_commit_state(conn, state, false); } size_t drm_crtc_get_gamma_lut_size(struct wlr_drm_backend *drm, struct wlr_drm_crtc *crtc) { if (crtc->props.gamma_lut_size == 0 || drm->iface == &legacy_iface) { return (size_t)crtc->legacy_gamma_size; } uint64_t gamma_lut_size; if (!get_drm_prop(drm->fd, crtc->id, crtc->props.gamma_lut_size, &gamma_lut_size)) { wlr_log(WLR_ERROR, "Unable to get gamma lut size"); return 0; } return gamma_lut_size; } static size_t drm_connector_get_gamma_size(struct wlr_output *output) { struct wlr_drm_connector *conn = get_drm_connector_from_output(output); struct wlr_drm_backend *drm = conn->backend; struct wlr_drm_crtc *crtc = conn->crtc; if (crtc == NULL) { return 0; } return drm_crtc_get_gamma_lut_size(drm, crtc); } static void realloc_crtcs(struct wlr_drm_backend *drm, struct wlr_drm_connector *want_conn); static bool drm_connector_alloc_crtc(struct wlr_drm_connector *conn) { if (conn->crtc == NULL) { realloc_crtcs(conn->backend, conn); } bool ok = conn->crtc != NULL; if (!ok) { wlr_drm_conn_log(conn, WLR_DEBUG, "Failed to find free CRTC"); } return ok; } static struct wlr_drm_mode *drm_mode_create(const drmModeModeInfo *modeinfo) { struct wlr_drm_mode *mode = calloc(1, sizeof(*mode)); if (!mode) { return NULL; } mode->drm_mode = *modeinfo; mode->wlr_mode.width = mode->drm_mode.hdisplay; mode->wlr_mode.height = mode->drm_mode.vdisplay; mode->wlr_mode.refresh = calculate_refresh_rate(modeinfo); mode->wlr_mode.picture_aspect_ratio = get_picture_aspect_ratio(modeinfo); if (modeinfo->type & DRM_MODE_TYPE_PREFERRED) { mode->wlr_mode.preferred = true; } return mode; } struct wlr_output_mode *wlr_drm_connector_add_mode(struct wlr_output *output, const drmModeModeInfo *modeinfo) { struct wlr_drm_connector *conn = get_drm_connector_from_output(output); if (modeinfo->type != DRM_MODE_TYPE_USERDEF) { return NULL; } struct wlr_output_mode *wlr_mode; wl_list_for_each(wlr_mode, &conn->output.modes, link) { struct wlr_drm_mode *mode = wl_container_of(wlr_mode, mode, wlr_mode); if (memcmp(&mode->drm_mode, modeinfo, sizeof(*modeinfo)) == 0) { return wlr_mode; } } struct wlr_drm_mode *mode = drm_mode_create(modeinfo); if (!mode) { return NULL; } wl_list_insert(&conn->output.modes, &mode->wlr_mode.link); wlr_drm_conn_log(conn, WLR_INFO, "Registered custom mode " "%"PRId32"x%"PRId32"@%"PRId32, mode->wlr_mode.width, mode->wlr_mode.height, mode->wlr_mode.refresh); return &mode->wlr_mode; } const drmModeModeInfo *wlr_drm_mode_get_info(struct wlr_output_mode *wlr_mode) { const struct wlr_drm_mode *mode = wl_container_of(wlr_mode, mode, wlr_mode); return &mode->drm_mode; } static bool drm_connector_set_cursor(struct wlr_output *output, struct wlr_buffer *buffer, int hotspot_x, int hotspot_y) { struct wlr_drm_connector *conn = get_drm_connector_from_output(output); struct wlr_drm_backend *drm = conn->backend; struct wlr_drm_crtc *crtc = conn->crtc; if (!crtc) { return false; } struct wlr_drm_plane *plane = crtc->cursor; if (plane == NULL) { return false; } if (conn->cursor_hotspot_x != hotspot_x || conn->cursor_hotspot_y != hotspot_y) { // Update cursor hotspot conn->cursor_x -= hotspot_x - conn->cursor_hotspot_x; conn->cursor_y -= hotspot_y - conn->cursor_hotspot_y; conn->cursor_hotspot_x = hotspot_x; conn->cursor_hotspot_y = hotspot_y; } conn->cursor_enabled = false; drm_fb_clear(&conn->cursor_pending_fb); if (buffer != NULL) { bool found = false; for (size_t i = 0; i < plane->cursor_sizes_len; i++) { struct wlr_output_cursor_size size = plane->cursor_sizes[i]; if (size.width == buffer->width && size.height == buffer->height) { found = true; break; } } if (!found) { wlr_drm_conn_log(conn, WLR_DEBUG, "Cursor buffer size mismatch"); return false; } struct wlr_buffer *local_buf; if (drm->parent) { struct wlr_drm_format format = {0}; if (!drm_plane_pick_render_format(plane, &format, &drm->mgpu_renderer)) { wlr_log(WLR_ERROR, "Failed to pick cursor plane format"); return false; } bool ok = init_drm_surface(&plane->mgpu_surf, &drm->mgpu_renderer, buffer->width, buffer->height, &format); wlr_drm_format_finish(&format); if (!ok) { return false; } local_buf = drm_surface_blit(&plane->mgpu_surf, buffer); if (local_buf == NULL) { return false; } } else { local_buf = wlr_buffer_lock(buffer); } bool ok = drm_fb_import(&conn->cursor_pending_fb, drm, local_buf, &plane->formats); wlr_buffer_unlock(local_buf); if (!ok) { return false; } conn->cursor_enabled = true; conn->cursor_width = buffer->width; conn->cursor_height = buffer->height; } wlr_output_update_needs_frame(output); return true; } static bool drm_connector_move_cursor(struct wlr_output *output, int x, int y) { struct wlr_drm_connector *conn = get_drm_connector_from_output(output); if (!conn->crtc) { return false; } struct wlr_drm_plane *plane = conn->crtc->cursor; if (!plane) { return false; } struct wlr_box box = { .x = x, .y = y }; int width, height; wlr_output_transformed_resolution(output, &width, &height); enum wl_output_transform transform = wlr_output_transform_invert(output->transform); wlr_box_transform(&box, &box, transform, width, height); box.x -= conn->cursor_hotspot_x; box.y -= conn->cursor_hotspot_y; conn->cursor_x = box.x; conn->cursor_y = box.y; wlr_output_update_needs_frame(output); return true; } bool drm_connector_is_cursor_visible(struct wlr_drm_connector *conn) { return conn->cursor_enabled && conn->cursor_x < conn->output.width && conn->cursor_y < conn->output.height && conn->cursor_x + conn->cursor_width >= 0 && conn->cursor_y + conn->cursor_height >= 0; } static void dealloc_crtc(struct wlr_drm_connector *conn); /** * Destroy the compositor-facing part of a connector. * * The connector isn't destroyed when disconnected. Only the compositor-facing * wlr_output interface is cleaned up. */ static void drm_connector_destroy_output(struct wlr_output *output) { struct wlr_drm_connector *conn = get_drm_connector_from_output(output); dealloc_crtc(conn); conn->status = DRM_MODE_DISCONNECTED; drm_connector_set_pending_page_flip(conn, NULL); struct wlr_drm_mode *mode, *mode_tmp; wl_list_for_each_safe(mode, mode_tmp, &conn->output.modes, wlr_mode.link) { wl_list_remove(&mode->wlr_mode.link); free(mode); } conn->output = (struct wlr_output){0}; } static const struct wlr_drm_format_set *drm_connector_get_cursor_formats( struct wlr_output *output, uint32_t buffer_caps) { if (!(buffer_caps & WLR_BUFFER_CAP_DMABUF)) { return NULL; } struct wlr_drm_connector *conn = get_drm_connector_from_output(output); if (!drm_connector_alloc_crtc(conn)) { return NULL; } struct wlr_drm_plane *plane = conn->crtc->cursor; if (!plane) { return NULL; } if (conn->backend->parent) { return &conn->backend->mgpu_formats; } return &plane->formats; } static const struct wlr_output_cursor_size *drm_connector_get_cursor_sizes(struct wlr_output *output, size_t *len) { struct wlr_drm_connector *conn = get_drm_connector_from_output(output); if (!drm_connector_alloc_crtc(conn)) { return NULL; } struct wlr_drm_plane *plane = conn->crtc->cursor; if (!plane) { return NULL; } *len = plane->cursor_sizes_len; return plane->cursor_sizes; } static const struct wlr_drm_format_set *drm_connector_get_primary_formats( struct wlr_output *output, uint32_t buffer_caps) { if (!(buffer_caps & WLR_BUFFER_CAP_DMABUF)) { return NULL; } struct wlr_drm_connector *conn = get_drm_connector_from_output(output); if (!drm_connector_alloc_crtc(conn)) { return NULL; } if (conn->backend->parent) { return &conn->backend->mgpu_formats; } return &conn->crtc->primary->formats; } static const struct wlr_output_impl output_impl = { .set_cursor = drm_connector_set_cursor, .move_cursor = drm_connector_move_cursor, .destroy = drm_connector_destroy_output, .test = drm_connector_test, .commit = drm_connector_commit, .get_gamma_size = drm_connector_get_gamma_size, .get_cursor_formats = drm_connector_get_cursor_formats, .get_cursor_sizes = drm_connector_get_cursor_sizes, .get_primary_formats = drm_connector_get_primary_formats, }; bool wlr_output_is_drm(struct wlr_output *output) { return output->impl == &output_impl; } uint32_t wlr_drm_connector_get_id(struct wlr_output *output) { struct wlr_drm_connector *conn = get_drm_connector_from_output(output); return conn->id; } enum wl_output_transform wlr_drm_connector_get_panel_orientation( struct wlr_output *output) { struct wlr_drm_connector *conn = get_drm_connector_from_output(output); if (!conn->props.panel_orientation) { return WL_OUTPUT_TRANSFORM_NORMAL; } char *orientation = get_drm_prop_enum(conn->backend->fd, conn->id, conn->props.panel_orientation); if (orientation == NULL) { return WL_OUTPUT_TRANSFORM_NORMAL; } enum wl_output_transform tr; if (strcmp(orientation, "Normal") == 0) { tr = WL_OUTPUT_TRANSFORM_NORMAL; } else if (strcmp(orientation, "Left Side Up") == 0) { tr = WL_OUTPUT_TRANSFORM_90; } else if (strcmp(orientation, "Upside Down") == 0) { tr = WL_OUTPUT_TRANSFORM_180; } else if (strcmp(orientation, "Right Side Up") == 0) { tr = WL_OUTPUT_TRANSFORM_270; } else { wlr_drm_conn_log(conn, WLR_ERROR, "Unknown panel orientation: %s", orientation); tr = WL_OUTPUT_TRANSFORM_NORMAL; } free(orientation); return tr; } static const int32_t subpixel_map[] = { [DRM_MODE_SUBPIXEL_UNKNOWN] = WL_OUTPUT_SUBPIXEL_UNKNOWN, [DRM_MODE_SUBPIXEL_HORIZONTAL_RGB] = WL_OUTPUT_SUBPIXEL_HORIZONTAL_RGB, [DRM_MODE_SUBPIXEL_HORIZONTAL_BGR] = WL_OUTPUT_SUBPIXEL_HORIZONTAL_BGR, [DRM_MODE_SUBPIXEL_VERTICAL_RGB] = WL_OUTPUT_SUBPIXEL_VERTICAL_RGB, [DRM_MODE_SUBPIXEL_VERTICAL_BGR] = WL_OUTPUT_SUBPIXEL_VERTICAL_BGR, [DRM_MODE_SUBPIXEL_NONE] = WL_OUTPUT_SUBPIXEL_NONE, }; static void dealloc_crtc(struct wlr_drm_connector *conn) { if (conn->crtc == NULL) { return; } wlr_drm_conn_log(conn, WLR_DEBUG, "De-allocating CRTC %" PRIu32, conn->crtc->id); struct wlr_output_state state; wlr_output_state_init(&state); wlr_output_state_set_enabled(&state, false); if (!drm_connector_commit_state(conn, &state, false)) { // On GPU unplug, disabling the CRTC can fail with EPERM wlr_drm_conn_log(conn, WLR_ERROR, "Failed to disable CRTC %"PRIu32, conn->crtc->id); } wlr_output_state_finish(&state); } static void format_nullable_crtc(char *str, size_t size, struct wlr_drm_crtc *crtc) { if (crtc != NULL) { snprintf(str, size, "CRTC %"PRIu32, crtc->id); } else { snprintf(str, size, "no CRTC"); } } static void realloc_crtcs(struct wlr_drm_backend *drm, struct wlr_drm_connector *want_conn) { assert(drm->num_crtcs > 0); size_t num_connectors = wl_list_length(&drm->connectors); if (num_connectors == 0) { return; } wlr_log(WLR_DEBUG, "Reallocating CRTCs"); struct wlr_drm_connector *connectors[num_connectors]; uint32_t connector_constraints[num_connectors]; uint32_t previous_match[drm->num_crtcs]; uint32_t new_match[drm->num_crtcs]; for (size_t i = 0; i < drm->num_crtcs; ++i) { previous_match[i] = UNMATCHED; } size_t i = 0; struct wlr_drm_connector *conn; wl_list_for_each(conn, &drm->connectors, link) { connectors[i] = conn; if (conn->crtc) { previous_match[conn->crtc - drm->crtcs] = i; } // Only request a CRTC if the connected is currently enabled or it's the // connector the user wants to enable bool want_crtc = conn == want_conn || conn->output.enabled; if (conn->status == DRM_MODE_CONNECTED && want_crtc) { connector_constraints[i] = conn->possible_crtcs; } else { // Will always fail to match anything connector_constraints[i] = 0; } ++i; } match_obj(num_connectors, connector_constraints, drm->num_crtcs, previous_match, new_match); // Converts our crtc=>connector result into a connector=>crtc one. struct wlr_drm_crtc *connector_match[num_connectors]; for (size_t i = 0 ; i < num_connectors; ++i) { connector_match[i] = NULL; } for (size_t i = 0; i < drm->num_crtcs; ++i) { if (new_match[i] != UNMATCHED) { connector_match[new_match[i]] = &drm->crtcs[i]; } } for (size_t i = 0; i < num_connectors; ++i) { struct wlr_drm_connector *conn = connectors[i]; struct wlr_drm_crtc *new_crtc = connector_match[i]; char old_crtc_str[16], new_crtc_str[16]; format_nullable_crtc(old_crtc_str, sizeof(old_crtc_str), conn->crtc); format_nullable_crtc(new_crtc_str, sizeof(new_crtc_str), new_crtc); char crtc_str[64]; if (conn->crtc != new_crtc) { snprintf(crtc_str, sizeof(crtc_str), "%s → %s", old_crtc_str, new_crtc_str); } else { snprintf(crtc_str, sizeof(crtc_str), "%s (no change)", new_crtc_str); } wlr_log(WLR_DEBUG, " Connector %s (%s%s): %s", conn->name, drm_connector_status_str(conn->status), connector_constraints[i] != 0 ? ", needs CRTC" : "", crtc_str); } // Refuse to remove a CRTC from an enabled connector, and refuse to // change the CRTC of an enabled connector. for (size_t i = 0; i < num_connectors; ++i) { struct wlr_drm_connector *conn = connectors[i]; if (conn->status != DRM_MODE_CONNECTED || !conn->output.enabled) { continue; } if (connector_match[i] == NULL) { wlr_log(WLR_DEBUG, "Could not match a CRTC for previously connected output; " "keeping old configuration"); return; } assert(conn->crtc != NULL); if (connector_match[i] != conn->crtc) { wlr_log(WLR_DEBUG, "Cannot switch CRTC for enabled output; " "keeping old configuration"); return; } } // Apply new configuration for (size_t i = 0; i < num_connectors; ++i) { struct wlr_drm_connector *conn = connectors[i]; if (conn->crtc != NULL && connector_match[i]) { // We don't need to change anything continue; } dealloc_crtc(conn); if (connector_match[i] != NULL) { conn->crtc = connector_match[i]; } } } static struct wlr_drm_crtc *connector_get_current_crtc( struct wlr_drm_connector *wlr_conn, const drmModeConnector *drm_conn) { struct wlr_drm_backend *drm = wlr_conn->backend; uint32_t crtc_id = 0; if (wlr_conn->props.crtc_id != 0) { uint64_t value; if (!get_drm_prop(drm->fd, wlr_conn->id, wlr_conn->props.crtc_id, &value)) { wlr_drm_conn_log(wlr_conn, WLR_ERROR, "Failed to get CRTC_ID connector property"); return NULL; } crtc_id = (uint32_t)value; } else if (drm_conn->encoder_id != 0) { // Fallback to the legacy API drmModeEncoder *enc = drmModeGetEncoder(drm->fd, drm_conn->encoder_id); if (enc == NULL) { wlr_drm_conn_log(wlr_conn, WLR_ERROR, "drmModeGetEncoder() failed"); return NULL; } crtc_id = enc->crtc_id; drmModeFreeEncoder(enc); } if (crtc_id == 0) { return NULL; } for (size_t i = 0; i < drm->num_crtcs; ++i) { if (drm->crtcs[i].id == crtc_id) { return &drm->crtcs[i]; } } wlr_drm_conn_log(wlr_conn, WLR_ERROR, "Failed to find current CRTC ID %" PRIu32, crtc_id); return NULL; } static struct wlr_drm_connector *create_drm_connector(struct wlr_drm_backend *drm, const drmModeConnector *drm_conn) { struct wlr_drm_connector *wlr_conn = calloc(1, sizeof(*wlr_conn)); if (!wlr_conn) { wlr_log_errno(WLR_ERROR, "Allocation failed"); return NULL; } wlr_conn->backend = drm; wlr_conn->status = DRM_MODE_DISCONNECTED; wlr_conn->id = drm_conn->connector_id; if (!get_drm_connector_props(drm->fd, wlr_conn->id, &wlr_conn->props)) { free(wlr_conn); return NULL; } const char *conn_name = drmModeGetConnectorTypeName(drm_conn->connector_type); if (conn_name == NULL) { conn_name = "Unknown"; } snprintf(wlr_conn->name, sizeof(wlr_conn->name), "%s-%"PRIu32, conn_name, drm_conn->connector_type_id); wlr_conn->possible_crtcs = drmModeConnectorGetPossibleCrtcs(drm->fd, drm_conn); if (wlr_conn->possible_crtcs == 0) { wlr_drm_conn_log(wlr_conn, WLR_ERROR, "No CRTC possible"); } wlr_conn->crtc = connector_get_current_crtc(wlr_conn, drm_conn); wl_list_insert(drm->connectors.prev, &wlr_conn->link); return wlr_conn; } static drmModeModeInfo *connector_get_current_mode(struct wlr_drm_connector *wlr_conn) { struct wlr_drm_backend *drm = wlr_conn->backend; if (wlr_conn->crtc == NULL) { return NULL; } if (wlr_conn->crtc->props.mode_id != 0) { size_t size = 0; drmModeModeInfo *mode = get_drm_prop_blob(drm->fd, wlr_conn->crtc->id, wlr_conn->crtc->props.mode_id, &size); assert(mode == NULL || size == sizeof(*mode)); return mode; } else { // Fallback to the legacy API drmModeCrtc *drm_crtc = drmModeGetCrtc(drm->fd, wlr_conn->crtc->id); if (drm_crtc == NULL) { wlr_log_errno(WLR_ERROR, "drmModeGetCrtc failed"); return NULL; } if (!drm_crtc->mode_valid) { drmModeFreeCrtc(drm_crtc); return NULL; } drmModeModeInfo *mode = malloc(sizeof(*mode)); if (mode == NULL) { wlr_log_errno(WLR_ERROR, "Allocation failed"); drmModeFreeCrtc(drm_crtc); return NULL; } *mode = drm_crtc->mode; drmModeFreeCrtc(drm_crtc); return mode; } } static bool connect_drm_connector(struct wlr_drm_connector *wlr_conn, const drmModeConnector *drm_conn) { struct wlr_drm_backend *drm = wlr_conn->backend; struct wlr_output *output = &wlr_conn->output; wlr_log(WLR_DEBUG, "Current CRTC: %d", wlr_conn->crtc ? (int)wlr_conn->crtc->id : -1); // keep track of all the modes ourselves first. We must only fill out // the modes list after wlr_output_init() struct wl_list modes; wl_list_init(&modes); struct wlr_output_state state; wlr_output_state_init(&state); wlr_output_state_set_enabled(&state, wlr_conn->crtc != NULL); drmModeModeInfo *current_modeinfo = connector_get_current_mode(wlr_conn); wlr_log(WLR_INFO, "Detected modes:"); for (int i = 0; i < drm_conn->count_modes; ++i) { if (drm_conn->modes[i].flags & DRM_MODE_FLAG_INTERLACE) { continue; } struct wlr_drm_mode *mode = drm_mode_create(&drm_conn->modes[i]); if (!mode) { wlr_log_errno(WLR_ERROR, "Allocation failed"); free(current_modeinfo); wlr_output_state_finish(&state); return false; } // If this is the current mode set on the conn's crtc, // then set it as the conn's output current mode. if (current_modeinfo != NULL && memcmp(&mode->drm_mode, current_modeinfo, sizeof(*current_modeinfo)) == 0) { wlr_output_state_set_mode(&state, &mode->wlr_mode); uint64_t mode_id = 0; get_drm_prop(drm->fd, wlr_conn->crtc->id, wlr_conn->crtc->props.mode_id, &mode_id); wlr_conn->crtc->own_mode_id = false; wlr_conn->crtc->mode_id = mode_id; wlr_conn->refresh = calculate_refresh_rate(current_modeinfo); } wlr_log(WLR_INFO, " %"PRId32"x%"PRId32" @ %.3f Hz %s", mode->wlr_mode.width, mode->wlr_mode.height, (float)mode->wlr_mode.refresh / 1000, mode->wlr_mode.preferred ? "(preferred)" : ""); wl_list_insert(modes.prev, &mode->wlr_mode.link); } free(current_modeinfo); wlr_output_init(output, &drm->backend, &output_impl, drm->session->event_loop, &state); wlr_output_state_finish(&state); // fill out the modes wl_list_insert_list(&output->modes, &modes); wlr_output_set_name(output, wlr_conn->name); output->phys_width = drm_conn->mmWidth; output->phys_height = drm_conn->mmHeight; wlr_log(WLR_INFO, "Physical size: %"PRId32"x%"PRId32, output->phys_width, output->phys_height); if (drm_conn->subpixel < sizeof(subpixel_map) / sizeof(subpixel_map[0])) { output->subpixel = subpixel_map[drm_conn->subpixel]; } else { wlr_log(WLR_ERROR, "Unknown subpixel value: %d", (int)drm_conn->subpixel); } uint64_t non_desktop; if (get_drm_prop(drm->fd, wlr_conn->id, wlr_conn->props.non_desktop, &non_desktop)) { if (non_desktop == 1) { wlr_log(WLR_INFO, "Non-desktop connector"); } output->non_desktop = non_desktop; } memset(wlr_conn->max_bpc_bounds, 0, sizeof(wlr_conn->max_bpc_bounds)); if (wlr_conn->props.max_bpc != 0) { if (!introspect_drm_prop_range(drm->fd, wlr_conn->props.max_bpc, &wlr_conn->max_bpc_bounds[0], &wlr_conn->max_bpc_bounds[1])) { wlr_log(WLR_ERROR, "Failed to introspect 'max bpc' property"); } } uint64_t vrr_capable = 0; if (wlr_conn->props.vrr_capable != 0) { get_drm_prop(drm->fd, wlr_conn->id, wlr_conn->props.vrr_capable, &vrr_capable); } output->adaptive_sync_supported = vrr_capable; size_t edid_len = 0; uint8_t *edid = get_drm_prop_blob(drm->fd, wlr_conn->id, wlr_conn->props.edid, &edid_len); parse_edid(wlr_conn, edid_len, edid); free(edid); char *subconnector = NULL; if (wlr_conn->props.subconnector) { subconnector = get_drm_prop_enum(drm->fd, wlr_conn->id, wlr_conn->props.subconnector); } if (subconnector && strcmp(subconnector, "Native") == 0) { free(subconnector); subconnector = NULL; } char description[128]; snprintf(description, sizeof(description), "%s %s%s%s (%s%s%s)", output->make, output->model, output->serial ? " " : "", output->serial ? output->serial : "", output->name, subconnector ? " via " : "", subconnector ? subconnector : ""); wlr_output_set_description(output, description); free(subconnector); wlr_conn->status = DRM_MODE_CONNECTED; return true; } static void disconnect_drm_connector(struct wlr_drm_connector *conn); void scan_drm_connectors(struct wlr_drm_backend *drm, struct wlr_device_hotplug_event *event) { if (event != NULL && event->connector_id != 0) { wlr_log(WLR_INFO, "Scanning DRM connector %"PRIu32" on %s", event->connector_id, drm->name); } else { wlr_log(WLR_INFO, "Scanning DRM connectors on %s", drm->name); } drmModeRes *res = drmModeGetResources(drm->fd); if (!res) { wlr_log_errno(WLR_ERROR, "Failed to get DRM resources"); return; } size_t seen_len = wl_list_length(&drm->connectors); // +1 so length can never be 0, which is undefined behaviour. // Last element isn't used. bool seen[seen_len + 1]; memset(seen, false, sizeof(seen)); size_t new_outputs_len = 0; struct wlr_drm_connector *new_outputs[res->count_connectors + 1]; for (int i = 0; i < res->count_connectors; ++i) { uint32_t conn_id = res->connectors[i]; ssize_t index = -1; struct wlr_drm_connector *c, *wlr_conn = NULL; wl_list_for_each(c, &drm->connectors, link) { index++; if (c->id == conn_id) { wlr_conn = c; break; } } // If the hotplug event contains a connector ID, ignore any other // connector. if (event != NULL && event->connector_id != 0 && event->connector_id != conn_id) { if (wlr_conn != NULL) { seen[index] = true; } continue; } drmModeConnector *drm_conn = drmModeGetConnector(drm->fd, conn_id); if (!drm_conn) { wlr_log_errno(WLR_ERROR, "Failed to get DRM connector"); continue; } if (!wlr_conn) { wlr_conn = create_drm_connector(drm, drm_conn); if (wlr_conn == NULL) { continue; } wlr_log(WLR_INFO, "Found connector '%s'", wlr_conn->name); } else { seen[index] = true; } // This can only happen *after* hotplug, since we haven't read the // connector properties yet if (wlr_conn->props.link_status != 0) { uint64_t link_status; if (!get_drm_prop(drm->fd, wlr_conn->id, wlr_conn->props.link_status, &link_status)) { wlr_drm_conn_log(wlr_conn, WLR_ERROR, "Failed to get link status prop"); continue; } if (link_status == DRM_MODE_LINK_STATUS_BAD) { // We need to reload our list of modes and force a modeset wlr_drm_conn_log(wlr_conn, WLR_INFO, "Bad link detected"); disconnect_drm_connector(wlr_conn); } } if (wlr_conn->status == DRM_MODE_DISCONNECTED && drm_conn->connection == DRM_MODE_CONNECTED) { wlr_log(WLR_INFO, "'%s' connected", wlr_conn->name); if (!connect_drm_connector(wlr_conn, drm_conn)) { wlr_drm_conn_log(wlr_conn, WLR_ERROR, "Failed to connect DRM connector"); continue; } new_outputs[new_outputs_len++] = wlr_conn; } else if (wlr_conn->status == DRM_MODE_CONNECTED && drm_conn->connection != DRM_MODE_CONNECTED) { wlr_log(WLR_INFO, "'%s' disconnected", wlr_conn->name); disconnect_drm_connector(wlr_conn); } drmModeFreeConnector(drm_conn); } drmModeFreeResources(res); // Iterate in reverse order because we'll remove items from the list and // still want indices to remain correct. struct wlr_drm_connector *conn, *tmp_conn; size_t index = wl_list_length(&drm->connectors); wl_list_for_each_reverse_safe(conn, tmp_conn, &drm->connectors, link) { index--; if (index >= seen_len || seen[index]) { continue; } wlr_log(WLR_INFO, "'%s' disappeared", conn->name); destroy_drm_connector(conn); } realloc_crtcs(drm, NULL); for (size_t i = 0; i < new_outputs_len; ++i) { struct wlr_drm_connector *conn = new_outputs[i]; wlr_drm_conn_log(conn, WLR_INFO, "Requesting modeset"); wl_signal_emit_mutable(&drm->backend.events.new_output, &conn->output); } } void scan_drm_leases(struct wlr_drm_backend *drm) { drmModeLesseeListRes *list = drmModeListLessees(drm->fd); if (list == NULL) { wlr_log_errno(WLR_ERROR, "drmModeListLessees failed"); return; } struct wlr_drm_connector *conn; wl_list_for_each(conn, &drm->connectors, link) { if (conn->lease == NULL) { continue; } bool found = false; for (size_t i = 0; i < list->count; i++) { if (list->lessees[i] == conn->lease->lessee_id) { found = true; break; } } if (!found) { wlr_log(WLR_DEBUG, "DRM lease %"PRIu32" has been terminated", conn->lease->lessee_id); drm_lease_destroy(conn->lease); } } drmFree(list); } static void build_current_connector_state(struct wlr_output_state *state, struct wlr_drm_connector *conn) { bool enabled = conn->status != DRM_MODE_DISCONNECTED && conn->output.enabled; wlr_output_state_init(state); wlr_output_state_set_enabled(state, enabled); if (!enabled) { return; } if (conn->output.current_mode != NULL) { wlr_output_state_set_mode(state, conn->output.current_mode); } else { wlr_output_state_set_custom_mode(state, conn->output.width, conn->output.height, conn->output.refresh); } } /** * Check whether we need to perform a full reset after a VT switch. * * If any connector or plane has a different CRTC, we need to perform a full * reset to restore our mapping. We couldn't avoid a full reset even if we * used a single KMS atomic commit to apply our state: the kernel rejects * commits which migrate a plane from one CRTC to another without going through * an intermediate state where the plane is disabled. */ static bool skip_reset_for_restore(struct wlr_drm_backend *drm) { struct wlr_drm_connector *conn; wl_list_for_each(conn, &drm->connectors, link) { drmModeConnector *drm_conn = drmModeGetConnectorCurrent(drm->fd, conn->id); if (drm_conn == NULL) { return false; } struct wlr_drm_crtc *crtc = connector_get_current_crtc(conn, drm_conn); drmModeFreeConnector(drm_conn); if (crtc != NULL && conn->crtc != crtc) { return false; } } for (size_t i = 0; i < drm->num_planes; i++) { struct wlr_drm_plane *plane = &drm->planes[i]; drmModePlane *drm_plane = drmModeGetPlane(drm->fd, plane->id); if (drm_plane == NULL) { return false; } uint32_t crtc_id = drm_plane->crtc_id; drmModeFreePlane(drm_plane); struct wlr_drm_crtc *crtc = NULL; for (size_t i = 0; i < drm->num_crtcs; i++) { if (drm->crtcs[i].id == crtc_id) { crtc = &drm->crtcs[i]; break; } } if (crtc == NULL) { continue; } bool ok = false; switch (plane->type) { case DRM_PLANE_TYPE_PRIMARY: ok = crtc->primary == plane; break; case DRM_PLANE_TYPE_CURSOR: ok = crtc->cursor == plane; break; } if (!ok) { return false; } } return true; } void restore_drm_device(struct wlr_drm_backend *drm) { // The previous DRM master leaves KMS in an undefined state. We need // to restore our own state, but be careful to avoid invalid // configurations. The connector/CRTC mapping may have changed, so // first disable all CRTCs, then light up the ones we were using // before the VT switch. // TODO: better use the atomic API to improve restoration after a VT switch if (!skip_reset_for_restore(drm) && !drm->iface->reset(drm)) { wlr_log(WLR_ERROR, "Failed to reset state after VT switch"); } struct wlr_drm_connector *conn; wl_list_for_each(conn, &drm->connectors, link) { struct wlr_output_state state; build_current_connector_state(&state, conn); if (!drm_connector_commit_state(conn, &state, false)) { wlr_drm_conn_log(conn, WLR_ERROR, "Failed to restore state after VT switch"); } wlr_output_state_finish(&state); } } bool commit_drm_device(struct wlr_drm_backend *drm, const struct wlr_backend_output_state *output_states, size_t output_states_len, bool test_only) { if (!drm->session->active) { return false; } struct wlr_drm_connector_state *conn_states = calloc(output_states_len, sizeof(conn_states[0])); if (conn_states == NULL) { return false; } bool ok = false; bool modeset = false; size_t conn_states_len = 0; for (size_t i = 0; i < output_states_len; i++) { const struct wlr_backend_output_state *output_state = &output_states[i]; struct wlr_output *output = output_state->output; if (!output->enabled && !output_pending_enabled(output, &output_state->base)) { // KMS rejects commits which disable already-disabled connectors // and have the DRM_MODE_PAGE_FLIP_EVENT flag continue; } struct wlr_drm_connector *conn = get_drm_connector_from_output(output); if (output_pending_enabled(output, &output_state->base) && !drm_connector_alloc_crtc(conn)) { wlr_drm_conn_log(conn, WLR_DEBUG, "No CRTC available for this connector"); goto out; } struct wlr_drm_connector_state *conn_state = &conn_states[conn_states_len]; drm_connector_state_init(conn_state, conn, &output_state->base); conn_states_len++; if (!drm_connector_prepare(conn_state, test_only)) { goto out; } if (output_state->base.tearing_page_flip) { wlr_log(WLR_DEBUG, "Tearing not supported for DRM device-wide commits"); goto out; } modeset |= output_state->base.allow_reconfiguration; } if (test_only && drm->parent) { // If we're running as a secondary GPU, we can't perform an atomic // commit without blitting a buffer. ok = true; goto out; } uint32_t flags = 0; if (!test_only) { flags |= DRM_MODE_PAGE_FLIP_EVENT; } struct wlr_drm_device_state dev_state = { .modeset = modeset, .connectors = conn_states, .connectors_len = conn_states_len, }; ok = drm_commit(drm, &dev_state, flags, test_only); out: for (size_t i = 0; i < conn_states_len; i++) { drm_connector_state_finish(&conn_states[i]); } free(conn_states); return ok; } static int mhz_to_nsec(int mhz) { return 1000000000000LL / mhz; } static void handle_page_flip(int fd, unsigned seq, unsigned tv_sec, unsigned tv_usec, unsigned crtc_id, void *data) { struct wlr_drm_page_flip *page_flip = data; struct wlr_drm_connector *conn = drm_page_flip_pop(page_flip, crtc_id); if (conn != NULL) { conn->pending_page_flip = NULL; } if (page_flip->connectors_len == 0) { drm_page_flip_destroy(page_flip); } if (conn == NULL) { return; } struct wlr_drm_backend *drm = conn->backend; if (conn->status != DRM_MODE_CONNECTED || conn->crtc == NULL) { wlr_drm_conn_log(conn, WLR_DEBUG, "Ignoring page-flip event for disabled connector"); return; } struct wlr_drm_plane *plane = conn->crtc->primary; if (plane->queued_fb) { drm_fb_move(&plane->current_fb, &plane->queued_fb); } if (conn->crtc->cursor && conn->crtc->cursor->queued_fb) { drm_fb_move(&conn->crtc->cursor->current_fb, &conn->crtc->cursor->queued_fb); } struct wlr_drm_layer *layer; wl_list_for_each(layer, &conn->crtc->layers, link) { drm_fb_move(&layer->current_fb, &layer->queued_fb); } uint32_t present_flags = WLR_OUTPUT_PRESENT_VSYNC | WLR_OUTPUT_PRESENT_HW_CLOCK | WLR_OUTPUT_PRESENT_HW_COMPLETION; /* Don't report ZERO_COPY in multi-gpu situations, because we had to copy * data between the GPUs, even if we were using the direct scanout * interface. */ if (!drm->parent) { present_flags |= WLR_OUTPUT_PRESENT_ZERO_COPY; } struct timespec present_time = { .tv_sec = tv_sec, .tv_nsec = tv_usec * 1000, }; struct wlr_output_event_present present_event = { /* The DRM backend guarantees that the presentation event will be for * the last submitted frame. */ .commit_seq = conn->output.commit_seq, .presented = drm->session->active, .when = &present_time, .seq = seq, .refresh = mhz_to_nsec(conn->refresh), .flags = present_flags, }; wlr_output_send_present(&conn->output, &present_event); if (drm->session->active) { wlr_output_send_frame(&conn->output); } } int handle_drm_event(int fd, uint32_t mask, void *data) { struct wlr_drm_backend *drm = data; drmEventContext event = { .version = 3, .page_flip_handler2 = handle_page_flip, }; if (drmHandleEvent(fd, &event) != 0) { wlr_log(WLR_ERROR, "drmHandleEvent failed"); wlr_backend_destroy(&drm->backend); } return 1; } static void disconnect_drm_connector(struct wlr_drm_connector *conn) { if (conn->status == DRM_MODE_DISCONNECTED) { return; } // This will cleanup the compositor-facing wlr_output, but won't destroy // our wlr_drm_connector. wlr_output_destroy(&conn->output); assert(conn->status == DRM_MODE_DISCONNECTED); } void destroy_drm_connector(struct wlr_drm_connector *conn) { disconnect_drm_connector(conn); wl_list_remove(&conn->link); free(conn); } int wlr_drm_backend_get_non_master_fd(struct wlr_backend *backend) { assert(backend); struct wlr_drm_backend *drm = get_drm_backend_from_backend(backend); int fd = open(drm->name, O_RDWR | O_CLOEXEC); if (fd < 0) { wlr_log_errno(WLR_ERROR, "Unable to clone DRM fd for client fd"); return -1; } if (drmIsMaster(fd) && drmDropMaster(fd) < 0) { wlr_log_errno(WLR_ERROR, "Failed to drop master"); return -1; } return fd; } struct wlr_drm_lease *wlr_drm_create_lease(struct wlr_output **outputs, size_t n_outputs, int *lease_fd_ptr) { assert(outputs); if (n_outputs == 0) { wlr_log(WLR_ERROR, "Can't lease 0 outputs"); return NULL; } struct wlr_drm_backend *drm = get_drm_backend_from_backend(outputs[0]->backend); int n_objects = 0; uint32_t objects[4 * n_outputs + 1]; for (size_t i = 0; i < n_outputs; ++i) { struct wlr_drm_connector *conn = get_drm_connector_from_output(outputs[i]); assert(conn->lease == NULL); if (conn->backend != drm) { wlr_log(WLR_ERROR, "Can't lease output from different backends"); return NULL; } objects[n_objects++] = conn->id; wlr_log(WLR_DEBUG, "Connector %d", conn->id); if (!drm_connector_alloc_crtc(conn)) { wlr_log(WLR_ERROR, "Failled to allocate connector CRTC"); return NULL; } objects[n_objects++] = conn->crtc->id; wlr_log(WLR_DEBUG, "CRTC %d", conn->crtc->id); objects[n_objects++] = conn->crtc->primary->id; wlr_log(WLR_DEBUG, "Primary plane %d", conn->crtc->primary->id); if (conn->crtc->cursor) { wlr_log(WLR_DEBUG, "Cursor plane %d", conn->crtc->cursor->id); objects[n_objects++] = conn->crtc->cursor->id; } } assert(n_objects != 0); struct wlr_drm_lease *lease = calloc(1, sizeof(*lease)); if (lease == NULL) { return NULL; } lease->backend = drm; wl_signal_init(&lease->events.destroy); wlr_log(WLR_DEBUG, "Issuing DRM lease with %d objects", n_objects); int lease_fd = drmModeCreateLease(drm->fd, objects, n_objects, O_CLOEXEC, &lease->lessee_id); if (lease_fd < 0) { free(lease); return NULL; } *lease_fd_ptr = lease_fd; wlr_log(WLR_DEBUG, "Issued DRM lease %"PRIu32, lease->lessee_id); for (size_t i = 0; i < n_outputs; ++i) { struct wlr_drm_connector *conn = get_drm_connector_from_output(outputs[i]); conn->lease = lease; conn->crtc->lease = lease; } return lease; } void wlr_drm_lease_terminate(struct wlr_drm_lease *lease) { struct wlr_drm_backend *drm = lease->backend; wlr_log(WLR_DEBUG, "Terminating DRM lease %d", lease->lessee_id); int ret = drmModeRevokeLease(drm->fd, lease->lessee_id); if (ret < 0) { wlr_log_errno(WLR_ERROR, "Failed to terminate lease"); } drm_lease_destroy(lease); } void drm_lease_destroy(struct wlr_drm_lease *lease) { struct wlr_drm_backend *drm = lease->backend; wl_signal_emit_mutable(&lease->events.destroy, NULL); struct wlr_drm_connector *conn; wl_list_for_each(conn, &drm->connectors, link) { if (conn->lease == lease) { conn->lease = NULL; } } for (size_t i = 0; i < drm->num_crtcs; ++i) { if (drm->crtcs[i].lease == lease) { drm->crtcs[i].lease = NULL; } } free(lease); }