#include #include #include #include #include #include #include #include #include #include #include #include #include "sway/config.h" #include "sway/input/cursor.h" #include "sway/output.h" #include "sway/server.h" #include "sway/tree/root.h" #include "log.h" #include "util.h" #if WLR_HAS_DRM_BACKEND #include #endif int output_name_cmp(const void *item, const void *data) { const struct output_config *output = item; const char *name = data; return strcmp(output->name, name); } void output_get_identifier(char *identifier, size_t len, struct sway_output *output) { struct wlr_output *wlr_output = output->wlr_output; snprintf(identifier, len, "%s %s %s", wlr_output->make ? wlr_output->make : "Unknown", wlr_output->model ? wlr_output->model : "Unknown", wlr_output->serial ? wlr_output->serial : "Unknown"); } const char *sway_output_scale_filter_to_string(enum scale_filter_mode scale_filter) { switch (scale_filter) { case SCALE_FILTER_DEFAULT: return "smart"; case SCALE_FILTER_LINEAR: return "linear"; case SCALE_FILTER_NEAREST: return "nearest"; case SCALE_FILTER_SMART: return "smart"; } sway_assert(false, "Unknown value for scale_filter."); return NULL; } struct output_config *new_output_config(const char *name) { struct output_config *oc = calloc(1, sizeof(struct output_config)); if (oc == NULL) { return NULL; } oc->name = strdup(name); if (oc->name == NULL) { free(oc); return NULL; } oc->enabled = -1; oc->width = oc->height = -1; oc->refresh_rate = -1; oc->custom_mode = -1; oc->drm_mode.type = -1; oc->x = oc->y = -1; oc->scale = -1; oc->scale_filter = SCALE_FILTER_DEFAULT; oc->transform = -1; oc->subpixel = WL_OUTPUT_SUBPIXEL_UNKNOWN; oc->max_render_time = -1; oc->adaptive_sync = -1; oc->render_bit_depth = RENDER_BIT_DEPTH_DEFAULT; oc->set_color_transform = false; oc->color_transform = NULL; oc->power = -1; oc->allow_tearing = -1; return oc; } // supersede_output_config clears all fields in dst that were set in src static void supersede_output_config(struct output_config *dst, struct output_config *src) { if (src->enabled != -1) { dst->enabled = -1; } if (src->width != -1) { dst->width = -1; } if (src->height != -1) { dst->height = -1; } if (src->x != -1) { dst->x = -1; } if (src->y != -1) { dst->y = -1; } if (src->scale != -1) { dst->scale = -1; } if (src->scale_filter != SCALE_FILTER_DEFAULT) { dst->scale_filter = SCALE_FILTER_DEFAULT; } if (src->subpixel != WL_OUTPUT_SUBPIXEL_UNKNOWN) { dst->subpixel = WL_OUTPUT_SUBPIXEL_UNKNOWN; } if (src->refresh_rate != -1) { dst->refresh_rate = -1; } if (src->custom_mode != -1) { dst->custom_mode = -1; } if (src->drm_mode.type != (uint32_t) -1) { dst->drm_mode.type = -1; } if (src->transform != -1) { dst->transform = -1; } if (src->max_render_time != -1) { dst->max_render_time = -1; } if (src->adaptive_sync != -1) { dst->adaptive_sync = -1; } if (src->render_bit_depth != RENDER_BIT_DEPTH_DEFAULT) { dst->render_bit_depth = RENDER_BIT_DEPTH_DEFAULT; } if (src->background) { free(dst->background); dst->background = NULL; } if (src->background_option) { free(dst->background_option); dst->background_option = NULL; } if (src->background_fallback) { free(dst->background_fallback); dst->background_fallback = NULL; } if (src->power != -1) { dst->power = -1; } } // merge_output_config sets all fields in dst that were set in src static void merge_output_config(struct output_config *dst, struct output_config *src) { if (src->enabled != -1) { dst->enabled = src->enabled; } if (src->width != -1) { dst->width = src->width; } if (src->height != -1) { dst->height = src->height; } if (src->x != -1) { dst->x = src->x; } if (src->y != -1) { dst->y = src->y; } if (src->scale != -1) { dst->scale = src->scale; } if (src->scale_filter != SCALE_FILTER_DEFAULT) { dst->scale_filter = src->scale_filter; } if (src->subpixel != WL_OUTPUT_SUBPIXEL_UNKNOWN) { dst->subpixel = src->subpixel; } if (src->refresh_rate != -1) { dst->refresh_rate = src->refresh_rate; } if (src->custom_mode != -1) { dst->custom_mode = src->custom_mode; } if (src->drm_mode.type != (uint32_t) -1) { memcpy(&dst->drm_mode, &src->drm_mode, sizeof(src->drm_mode)); } if (src->transform != -1) { dst->transform = src->transform; } if (src->max_render_time != -1) { dst->max_render_time = src->max_render_time; } if (src->adaptive_sync != -1) { dst->adaptive_sync = src->adaptive_sync; } if (src->render_bit_depth != RENDER_BIT_DEPTH_DEFAULT) { dst->render_bit_depth = src->render_bit_depth; } if (src->set_color_transform) { if (src->color_transform) { wlr_color_transform_ref(src->color_transform); } wlr_color_transform_unref(dst->color_transform); dst->set_color_transform = true; dst->color_transform = src->color_transform; } if (src->background) { free(dst->background); dst->background = strdup(src->background); } if (src->background_option) { free(dst->background_option); dst->background_option = strdup(src->background_option); } if (src->background_fallback) { free(dst->background_fallback); dst->background_fallback = strdup(src->background_fallback); } if (src->power != -1) { dst->power = src->power; } if (src->allow_tearing != -1) { dst->allow_tearing = src->allow_tearing; } } void store_output_config(struct output_config *oc) { bool merged = false; bool wildcard = strcmp(oc->name, "*") == 0; struct sway_output *output = wildcard ? NULL : all_output_by_name_or_id(oc->name); char id[128]; if (output) { output_get_identifier(id, sizeof(id), output); } for (int i = 0; i < config->output_configs->length; i++) { struct output_config *old = config->output_configs->items[i]; // If the old config matches the new config's name, regardless of // whether it was name or identifier, merge on top of the existing // config. If the new config is a wildcard, this also merges on top of // old wildcard configs. if (strcmp(old->name, oc->name) == 0) { merge_output_config(old, oc); merged = true; continue; } // If the new config is a wildcard config we supersede all non-wildcard // configs. Old wildcard configs have already been handled above. if (wildcard) { supersede_output_config(old, oc); continue; } // If the new config matches an output's name, and the old config // matches on that output's identifier, supersede it. if (output && strcmp(old->name, id) == 0 && strcmp(oc->name, output->wlr_output->name) == 0) { supersede_output_config(old, oc); } } sway_log(SWAY_DEBUG, "Config stored for output %s (enabled: %d) (%dx%d@%fHz " "position %d,%d scale %f subpixel %s transform %d) (bg %s %s) (power %d) " "(max render time: %d) (allow tearing: %d)", oc->name, oc->enabled, oc->width, oc->height, oc->refresh_rate, oc->x, oc->y, oc->scale, sway_wl_output_subpixel_to_string(oc->subpixel), oc->transform, oc->background, oc->background_option, oc->power, oc->max_render_time, oc->allow_tearing); // If the configuration was not merged into an existing configuration, add // it to the list. Otherwise we're done with it and can free it. if (!merged) { list_add(config->output_configs, oc); } else { free_output_config(oc); } } static void set_mode(struct wlr_output *output, struct wlr_output_state *pending, int width, int height, float refresh_rate, bool custom) { // Not all floating point integers can be represented exactly // as (int)(1000 * mHz / 1000.f) // round() the result to avoid any error int mhz = (int)roundf(refresh_rate * 1000); // If no target refresh rate is given, match highest available mhz = mhz <= 0 ? INT_MAX : mhz; if (wl_list_empty(&output->modes) || custom) { sway_log(SWAY_DEBUG, "Assigning custom mode to %s", output->name); wlr_output_state_set_custom_mode(pending, width, height, refresh_rate > 0 ? mhz : 0); return; } struct wlr_output_mode *mode, *best = NULL; int best_diff_mhz = INT_MAX; wl_list_for_each(mode, &output->modes, link) { if (mode->width == width && mode->height == height) { int diff_mhz = abs(mode->refresh - mhz); if (diff_mhz < best_diff_mhz) { best_diff_mhz = diff_mhz; best = mode; if (best_diff_mhz == 0) { break; } } } } if (best) { sway_log(SWAY_INFO, "Assigning configured mode (%dx%d@%.3fHz) to %s", best->width, best->height, best->refresh / 1000.f, output->name); } else { best = wlr_output_preferred_mode(output); sway_log(SWAY_INFO, "Configured mode (%dx%d@%.3fHz) not available, " "applying preferred mode (%dx%d@%.3fHz)", width, height, refresh_rate, best->width, best->height, best->refresh / 1000.f); } wlr_output_state_set_mode(pending, best); } static void set_modeline(struct wlr_output *output, struct wlr_output_state *pending, drmModeModeInfo *drm_mode) { #if WLR_HAS_DRM_BACKEND if (!wlr_output_is_drm(output)) { sway_log(SWAY_ERROR, "Modeline can only be set to DRM output"); return; } sway_log(SWAY_DEBUG, "Assigning custom modeline to %s", output->name); struct wlr_output_mode *mode = wlr_drm_connector_add_mode(output, drm_mode); if (mode) { wlr_output_state_set_mode(pending, mode); } #else sway_log(SWAY_ERROR, "Modeline can only be set to DRM output"); #endif } /* Some manufacturers hardcode the aspect-ratio of the output in the physical * size field. */ static bool phys_size_is_aspect_ratio(struct wlr_output *output) { return (output->phys_width == 1600 && output->phys_height == 900) || (output->phys_width == 1600 && output->phys_height == 1000) || (output->phys_width == 160 && output->phys_height == 90) || (output->phys_width == 160 && output->phys_height == 100) || (output->phys_width == 16 && output->phys_height == 9) || (output->phys_width == 16 && output->phys_height == 10); } // The minimum DPI at which we turn on a scale of 2 #define HIDPI_DPI_LIMIT (2 * 96) // The minimum screen height at which we turn on a scale of 2 #define HIDPI_MIN_HEIGHT 1200 // 1 inch = 25.4 mm #define MM_PER_INCH 25.4 static int compute_default_scale(struct wlr_output *output, struct wlr_output_state *pending) { struct wlr_box box = { .width = output->width, .height = output->height }; if (pending->committed & WLR_OUTPUT_STATE_MODE) { switch (pending->mode_type) { case WLR_OUTPUT_STATE_MODE_FIXED: box.width = pending->mode->width; box.height = pending->mode->height; break; case WLR_OUTPUT_STATE_MODE_CUSTOM: box.width = pending->custom_mode.width; box.height = pending->custom_mode.height; break; } } enum wl_output_transform transform = output->transform; if (pending->committed & WLR_OUTPUT_STATE_TRANSFORM) { transform = pending->transform; } wlr_box_transform(&box, &box, transform, box.width, box.height); int width = box.width; int height = box.height; if (height < HIDPI_MIN_HEIGHT) { return 1; } if (output->phys_width == 0 || output->phys_height == 0) { return 1; } if (phys_size_is_aspect_ratio(output)) { return 1; } double dpi_x = (double) width / (output->phys_width / MM_PER_INCH); double dpi_y = (double) height / (output->phys_height / MM_PER_INCH); sway_log(SWAY_DEBUG, "Output DPI: %fx%f", dpi_x, dpi_y); if (dpi_x <= HIDPI_DPI_LIMIT || dpi_y <= HIDPI_DPI_LIMIT) { return 1; } return 2; } static bool render_format_is_10bit(uint32_t render_format) { return render_format == DRM_FORMAT_XRGB2101010 || render_format == DRM_FORMAT_XBGR2101010; } static bool render_format_is_bgr(uint32_t fmt) { return fmt == DRM_FORMAT_XBGR2101010 || fmt == DRM_FORMAT_XBGR8888; } static bool output_config_is_disabling(struct output_config *oc) { return oc && (!oc->enabled || oc->power == 0); } static void queue_output_config(struct output_config *oc, struct sway_output *output, struct wlr_output_state *pending) { if (output == root->fallback_output) { return; } struct wlr_output *wlr_output = output->wlr_output; if (output_config_is_disabling(oc)) { sway_log(SWAY_DEBUG, "Turning off output %s", wlr_output->name); wlr_output_state_set_enabled(pending, false); return; } sway_log(SWAY_DEBUG, "Turning on output %s", wlr_output->name); wlr_output_state_set_enabled(pending, true); if (oc && oc->drm_mode.type != 0 && oc->drm_mode.type != (uint32_t) -1) { sway_log(SWAY_DEBUG, "Set %s modeline", wlr_output->name); set_modeline(wlr_output, pending, &oc->drm_mode); } else if (oc && oc->width > 0 && oc->height > 0) { sway_log(SWAY_DEBUG, "Set %s mode to %dx%d (%f Hz)", wlr_output->name, oc->width, oc->height, oc->refresh_rate); set_mode(wlr_output, pending, oc->width, oc->height, oc->refresh_rate, oc->custom_mode == 1); } else if (!wl_list_empty(&wlr_output->modes)) { sway_log(SWAY_DEBUG, "Set preferred mode"); struct wlr_output_mode *preferred_mode = wlr_output_preferred_mode(wlr_output); wlr_output_state_set_mode(pending, preferred_mode); } if (oc && (oc->subpixel != WL_OUTPUT_SUBPIXEL_UNKNOWN || config->reloading)) { sway_log(SWAY_DEBUG, "Set %s subpixel to %s", oc->name, sway_wl_output_subpixel_to_string(oc->subpixel)); wlr_output_state_set_subpixel(pending, oc->subpixel); } enum wl_output_transform tr = WL_OUTPUT_TRANSFORM_NORMAL; if (oc && oc->transform >= 0) { tr = oc->transform; #if WLR_HAS_DRM_BACKEND } else if (wlr_output_is_drm(wlr_output)) { tr = wlr_drm_connector_get_panel_orientation(wlr_output); sway_log(SWAY_DEBUG, "Auto-detected output transform: %d", tr); #endif } if (wlr_output->transform != tr) { sway_log(SWAY_DEBUG, "Set %s transform to %d", wlr_output->name, tr); wlr_output_state_set_transform(pending, tr); } // Apply the scale last before the commit, because the scale auto-detection // reads the pending output size float scale; if (oc && oc->scale > 0) { scale = oc->scale; // The factional-scale-v1 protocol uses increments of 120ths to send // the scale factor to the client. Adjust the scale so that we use the // same value as the clients'. float adjusted_scale = round(scale * 120) / 120; if (scale != adjusted_scale) { sway_log(SWAY_INFO, "Adjusting output scale from %f to %f", scale, adjusted_scale); scale = adjusted_scale; } } else { scale = compute_default_scale(wlr_output, pending); sway_log(SWAY_DEBUG, "Auto-detected output scale: %f", scale); } if (scale != wlr_output->scale) { sway_log(SWAY_DEBUG, "Set %s scale to %f", wlr_output->name, scale); wlr_output_state_set_scale(pending, scale); } if (oc && oc->adaptive_sync != -1 && wlr_output->adaptive_sync_supported) { sway_log(SWAY_DEBUG, "Set %s adaptive sync to %d", wlr_output->name, oc->adaptive_sync); wlr_output_state_set_adaptive_sync_enabled(pending, oc->adaptive_sync == 1); } if (oc && oc->render_bit_depth != RENDER_BIT_DEPTH_DEFAULT) { if (oc->render_bit_depth == RENDER_BIT_DEPTH_10 && render_format_is_10bit(output->wlr_output->render_format)) { // 10-bit was set successfully before, try to save some tests by reusing the format wlr_output_state_set_render_format(pending, output->wlr_output->render_format); } else if (oc->render_bit_depth == RENDER_BIT_DEPTH_10) { wlr_output_state_set_render_format(pending, DRM_FORMAT_XRGB2101010); } else { wlr_output_state_set_render_format(pending, DRM_FORMAT_XRGB8888); } } } static bool finalize_output_config(struct output_config *oc, struct sway_output *output) { if (output == root->fallback_output) { return false; } struct wlr_output *wlr_output = output->wlr_output; if (oc && !oc->enabled) { sway_log(SWAY_DEBUG, "Disabling output %s", oc->name); if (output->enabled) { output_disable(output); wlr_output_layout_remove(root->output_layout, wlr_output); } return true; } if (oc) { enum scale_filter_mode scale_filter_old = output->scale_filter; switch (oc->scale_filter) { case SCALE_FILTER_DEFAULT: case SCALE_FILTER_SMART: output->scale_filter = ceilf(wlr_output->scale) == wlr_output->scale ? SCALE_FILTER_NEAREST : SCALE_FILTER_LINEAR; break; case SCALE_FILTER_LINEAR: case SCALE_FILTER_NEAREST: output->scale_filter = oc->scale_filter; break; } if (scale_filter_old != output->scale_filter) { sway_log(SWAY_DEBUG, "Set %s scale_filter to %s", oc->name, sway_output_scale_filter_to_string(output->scale_filter)); wlr_damage_ring_add_whole(&output->scene_output->damage_ring); } } // Find position for it if (oc && (oc->x != -1 || oc->y != -1)) { sway_log(SWAY_DEBUG, "Set %s position to %d, %d", oc->name, oc->x, oc->y); wlr_output_layout_add(root->output_layout, wlr_output, oc->x, oc->y); } else { wlr_output_layout_add_auto(root->output_layout, wlr_output); } // Update output->{lx, ly, width, height} struct wlr_box output_box; wlr_output_layout_get_box(root->output_layout, wlr_output, &output_box); output->lx = output_box.x; output->ly = output_box.y; output->width = output_box.width; output->height = output_box.height; if (!output->enabled) { output_enable(output); } if (oc && oc->max_render_time >= 0) { sway_log(SWAY_DEBUG, "Set %s max render time to %d", oc->name, oc->max_render_time); output->max_render_time = oc->max_render_time; } if (oc && oc->set_color_transform) { if (oc->color_transform) { wlr_color_transform_ref(oc->color_transform); } wlr_color_transform_unref(output->color_transform); output->color_transform = oc->color_transform; } if (oc && oc->allow_tearing >= 0) { sway_log(SWAY_DEBUG, "Set %s allow tearing to %d", oc->name, oc->allow_tearing); output->allow_tearing = oc->allow_tearing; } return true; } static void default_output_config(struct output_config *oc, struct wlr_output *wlr_output) { oc->enabled = 1; oc->power = 1; struct wlr_output_mode *mode = wlr_output_preferred_mode(wlr_output); if (mode != NULL) { oc->width = mode->width; oc->height = mode->height; oc->refresh_rate = mode->refresh / 1000.f; } oc->x = oc->y = -1; oc->scale = 0; // auto oc->scale_filter = SCALE_FILTER_DEFAULT; struct sway_output *output = wlr_output->data; oc->subpixel = output->detected_subpixel; oc->transform = WL_OUTPUT_TRANSFORM_NORMAL; oc->max_render_time = 0; oc->allow_tearing = 0; } // find_output_config returns a merged output_config containing all stored // configuration that applies to the specified output. struct output_config *find_output_config(struct sway_output *sway_output) { const char *name = sway_output->wlr_output->name; struct output_config *oc = NULL; struct output_config *result = new_output_config(name); if (config->reloading) { default_output_config(result, sway_output->wlr_output); } char id[128]; output_get_identifier(id, sizeof(id), sway_output); int i; bool match = false; if ((i = list_seq_find(config->output_configs, output_name_cmp, "*")) >= 0) { match = true; oc = config->output_configs->items[i]; merge_output_config(result, oc); } if ((i = list_seq_find(config->output_configs, output_name_cmp, name)) >= 0) { match = true; oc = config->output_configs->items[i]; merge_output_config(result, oc); } if ((i = list_seq_find(config->output_configs, output_name_cmp, id)) >= 0) { match = true; oc = config->output_configs->items[i]; merge_output_config(result, oc); } if (!match && !config->reloading) { // No name, identifier, or wildcard config. Since we are not // reloading with defaults, the output config will be empty, so // just return NULL free_output_config(result); return NULL; } return result; } static bool config_has_auto_mode(struct output_config *oc) { if (!oc) { return true; } if (oc->drm_mode.type != 0 && oc->drm_mode.type != (uint32_t)-1) { return true; } else if (oc->width > 0 && oc->height > 0) { return true; } return false; } struct search_context { struct wlr_output_swapchain_manager *swapchain_mgr; struct wlr_backend_output_state *states; struct matched_output_config *configs; size_t configs_len; bool degrade_to_off; }; static void dump_output_state(struct wlr_output *wlr_output, struct wlr_output_state *state) { sway_log(SWAY_DEBUG, "Output state for %s", wlr_output->name); if (state->committed & WLR_OUTPUT_STATE_ENABLED) { sway_log(SWAY_DEBUG, " enabled: %s", state->enabled ? "yes" : "no"); } if (state->committed & WLR_OUTPUT_STATE_RENDER_FORMAT) { sway_log(SWAY_DEBUG, " render_format: %d", state->render_format); } if (state->committed & WLR_OUTPUT_STATE_MODE) { if (state->mode_type == WLR_OUTPUT_STATE_MODE_CUSTOM) { sway_log(SWAY_DEBUG, " custom mode: %dx%d@%dmHz", state->custom_mode.width, state->custom_mode.height, state->custom_mode.refresh); } else { sway_log(SWAY_DEBUG, " mode: %dx%d@%dmHz%s", state->mode->width, state->mode->height, state->mode->refresh, state->mode->preferred ? " (preferred)" : ""); } } if (state->committed & WLR_OUTPUT_STATE_ADAPTIVE_SYNC_ENABLED) { sway_log(SWAY_DEBUG, " adaptive_sync: %s", state->adaptive_sync_enabled ? "enabled": "disabled"); } } static bool search_valid_config(struct search_context *ctx, size_t output_idx); static void reset_output_state(struct wlr_output_state *state) { wlr_output_state_finish(state); wlr_output_state_init(state); state->committed = 0; } static void clear_later_output_states(struct wlr_backend_output_state *states, size_t configs_len, size_t output_idx) { // Clear and disable all output states after this one to avoid conflict // with previous tests. for (size_t idx = output_idx+1; idx < configs_len; idx++) { struct wlr_backend_output_state *backend_state = &states[idx]; struct wlr_output_state *state = &backend_state->base; reset_output_state(state); wlr_output_state_set_enabled(state, false); } } static bool search_finish(struct search_context *ctx, size_t output_idx) { struct wlr_backend_output_state *backend_state = &ctx->states[output_idx]; struct wlr_output_state *state = &backend_state->base; struct wlr_output *wlr_output = backend_state->output; clear_later_output_states(ctx->states, ctx->configs_len, output_idx); dump_output_state(wlr_output, state); return wlr_output_swapchain_manager_prepare(ctx->swapchain_mgr, ctx->states, ctx->configs_len) && search_valid_config(ctx, output_idx+1); } static bool search_adaptive_sync(struct search_context *ctx, size_t output_idx) { struct matched_output_config *cfg = &ctx->configs[output_idx]; struct wlr_backend_output_state *backend_state = &ctx->states[output_idx]; struct wlr_output_state *state = &backend_state->base; if (!backend_state->output->adaptive_sync_supported) { return search_finish(ctx, output_idx); } if (cfg->config && cfg->config->adaptive_sync == 1) { wlr_output_state_set_adaptive_sync_enabled(state, true); if (search_finish(ctx, output_idx)) { return true; } } wlr_output_state_set_adaptive_sync_enabled(state, false); return search_finish(ctx, output_idx); } static bool search_mode(struct search_context *ctx, size_t output_idx) { struct matched_output_config *cfg = &ctx->configs[output_idx]; struct wlr_backend_output_state *backend_state = &ctx->states[output_idx]; struct wlr_output_state *state = &backend_state->base; struct wlr_output *wlr_output = backend_state->output; if (!config_has_auto_mode(cfg->config)) { return search_adaptive_sync(ctx, output_idx); } struct wlr_output_mode *preferred_mode = wlr_output_preferred_mode(wlr_output); if (preferred_mode) { wlr_output_state_set_mode(state, preferred_mode); if (search_adaptive_sync(ctx, output_idx)) { return true; } } if (wl_list_empty(&wlr_output->modes)) { state->committed &= ~WLR_OUTPUT_STATE_MODE; return search_adaptive_sync(ctx, output_idx); } struct wlr_output_mode *mode; wl_list_for_each(mode, &backend_state->output->modes, link) { if (mode == preferred_mode) { continue; } wlr_output_state_set_mode(state, mode); if (search_adaptive_sync(ctx, output_idx)) { return true; } } return false; } static bool search_render_format(struct search_context *ctx, size_t output_idx) { struct matched_output_config *cfg = &ctx->configs[output_idx]; struct wlr_backend_output_state *backend_state = &ctx->states[output_idx]; struct wlr_output_state *state = &backend_state->base; struct wlr_output *wlr_output = backend_state->output; uint32_t fmts[] = { DRM_FORMAT_XRGB2101010, DRM_FORMAT_XBGR2101010, DRM_FORMAT_XRGB8888, DRM_FORMAT_INVALID, }; if (render_format_is_bgr(wlr_output->render_format)) { // Start with BGR in the unlikely event that we previously required it. fmts[0] = DRM_FORMAT_XBGR2101010; fmts[1] = DRM_FORMAT_XRGB2101010; } const struct wlr_drm_format_set *primary_formats = wlr_output_get_primary_formats(wlr_output, WLR_BUFFER_CAP_DMABUF); bool need_10bit = cfg->config && cfg->config->render_bit_depth == RENDER_BIT_DEPTH_10; for (size_t idx = 0; fmts[idx] != DRM_FORMAT_INVALID; idx++) { if (!need_10bit && render_format_is_10bit(fmts[idx])) { continue; } if (!wlr_drm_format_set_get(primary_formats, fmts[idx])) { // This is not a supported format for this output continue; } wlr_output_state_set_render_format(state, fmts[idx]); if (search_mode(ctx, output_idx)) { return true; } } return false; } static bool search_valid_config(struct search_context *ctx, size_t output_idx) { if (output_idx >= ctx->configs_len) { // We reached the end of the search, all good! return true; } struct matched_output_config *cfg = &ctx->configs[output_idx]; struct wlr_backend_output_state *backend_state = &ctx->states[output_idx]; struct wlr_output_state *state = &backend_state->base; struct wlr_output *wlr_output = backend_state->output; if (!output_config_is_disabling(cfg->config)) { // Search through our possible configurations, doing a depth-first // through render_format, modes, adaptive_sync and the next output's // config. queue_output_config(cfg->config, cfg->output, &backend_state->base); if (search_render_format(ctx, output_idx)) { return true; } else if (!ctx->degrade_to_off) { return false; } // We could not get anything to work, try to disable this output to see // if we can at least make the outputs before us work. sway_log(SWAY_DEBUG, "Unable to find valid config with output %s, disabling", wlr_output->name); reset_output_state(state); } wlr_output_state_set_enabled(state, false); return search_finish(ctx, output_idx); } static int compare_matched_output_config_priority(const void *a, const void *b) { const struct matched_output_config *amc = a; const struct matched_output_config *bmc = b; bool a_disabling = output_config_is_disabling(amc->config); bool b_disabling = output_config_is_disabling(bmc->config); bool a_enabled = amc->output->enabled; bool b_enabled = bmc->output->enabled; // We want to give priority to existing enabled outputs. To do so, we want // the configuration order to be: // 1. Existing, enabled outputs // 2. Outputs that need to be enabled // 3. Disabled or disabling outputs if (a_enabled && !a_disabling) { return -1; } else if (b_enabled && !b_disabling) { return 1; } else if (b_disabling && !a_disabling) { return -1; } else if (a_disabling && !b_disabling) { return 1; } return 0; } void sort_output_configs_by_priority(struct matched_output_config *configs, size_t configs_len) { qsort(configs, configs_len, sizeof(*configs), compare_matched_output_config_priority); } bool apply_output_configs(struct matched_output_config *configs, size_t configs_len, bool test_only, bool degrade_to_off) { struct wlr_backend_output_state *states = calloc(configs_len, sizeof(*states)); if (!states) { return false; } sway_log(SWAY_DEBUG, "Committing %zd outputs", configs_len); for (size_t idx = 0; idx < configs_len; idx++) { struct matched_output_config *cfg = &configs[idx]; struct wlr_backend_output_state *backend_state = &states[idx]; backend_state->output = cfg->output->wlr_output; wlr_output_state_init(&backend_state->base); sway_log(SWAY_DEBUG, "Preparing config for %s", cfg->output->wlr_output->name); queue_output_config(cfg->config, cfg->output, &backend_state->base); } struct wlr_output_swapchain_manager swapchain_mgr; wlr_output_swapchain_manager_init(&swapchain_mgr, server.backend); bool ok = wlr_output_swapchain_manager_prepare(&swapchain_mgr, states, configs_len); if (!ok) { sway_log(SWAY_ERROR, "Requested backend configuration failed, searching for valid fallbacks"); struct search_context ctx = { .swapchain_mgr = &swapchain_mgr, .states = states, .configs = configs, .configs_len = configs_len, .degrade_to_off = degrade_to_off, }; if (!search_valid_config(&ctx, 0)) { sway_log(SWAY_ERROR, "Search for valid config failed"); goto out; } } if (test_only) { // The swapchain manager already did a test for us goto out; } for (size_t idx = 0; idx < configs_len; idx++) { struct matched_output_config *cfg = &configs[idx]; struct wlr_backend_output_state *backend_state = &states[idx]; struct wlr_scene_output_state_options opts = { .swapchain = wlr_output_swapchain_manager_get_swapchain( &swapchain_mgr, backend_state->output), .color_transform = cfg->output->color_transform, }; struct wlr_scene_output *scene_output = cfg->output->scene_output; struct wlr_output_state *state = &backend_state->base; if (!wlr_scene_output_build_state(scene_output, state, &opts)) { sway_log(SWAY_ERROR, "Building output state for '%s' failed", backend_state->output->name); goto out; } } ok = wlr_backend_commit(server.backend, states, configs_len); if (!ok) { sway_log(SWAY_ERROR, "Backend commit failed"); goto out; } sway_log(SWAY_DEBUG, "Commit of %zd outputs succeeded", configs_len); wlr_output_swapchain_manager_apply(&swapchain_mgr); for (size_t idx = 0; idx < configs_len; idx++) { struct matched_output_config *cfg = &configs[idx]; sway_log(SWAY_DEBUG, "Finalizing config for %s", cfg->output->wlr_output->name); finalize_output_config(cfg->config, cfg->output); } out: wlr_output_swapchain_manager_finish(&swapchain_mgr); for (size_t idx = 0; idx < configs_len; idx++) { struct wlr_backend_output_state *backend_state = &states[idx]; wlr_output_state_finish(&backend_state->base); } free(states); // Reconfigure all devices, since input config may have been applied before // this output came online, and some config items (like map_to_output) are // dependent on an output being present. input_manager_configure_all_input_mappings(); // Reconfigure the cursor images, since the scale may have changed. input_manager_configure_xcursor(); struct sway_seat *seat; wl_list_for_each(seat, &server.input->seats, link) { wlr_seat_pointer_notify_clear_focus(seat->wlr_seat); cursor_rebase(seat->cursor); } return ok; } void apply_all_output_configs(void) { size_t configs_len = wl_list_length(&root->all_outputs); struct matched_output_config *configs = calloc(configs_len, sizeof(*configs)); if (!configs) { return; } int config_idx = 0; struct sway_output *sway_output; wl_list_for_each(sway_output, &root->all_outputs, link) { if (sway_output == root->fallback_output) { configs_len--; continue; } struct matched_output_config *config = &configs[config_idx++]; config->output = sway_output; config->config = find_output_config(sway_output); } sort_output_configs_by_priority(configs, configs_len); apply_output_configs(configs, configs_len, false, true); for (size_t idx = 0; idx < configs_len; idx++) { struct matched_output_config *cfg = &configs[idx]; free_output_config(cfg->config); } free(configs); } void free_output_config(struct output_config *oc) { if (!oc) { return; } free(oc->name); free(oc->background); free(oc->background_option); wlr_color_transform_unref(oc->color_transform); free(oc); } static void handle_swaybg_client_destroy(struct wl_listener *listener, void *data) { struct sway_config *sway_config = wl_container_of(listener, sway_config, swaybg_client_destroy); wl_list_remove(&sway_config->swaybg_client_destroy.link); wl_list_init(&sway_config->swaybg_client_destroy.link); sway_config->swaybg_client = NULL; } static bool _spawn_swaybg(char **command) { if (config->swaybg_client != NULL) { wl_client_destroy(config->swaybg_client); } int sockets[2]; if (socketpair(AF_UNIX, SOCK_STREAM, 0, sockets) != 0) { sway_log_errno(SWAY_ERROR, "socketpair failed"); return false; } if (!sway_set_cloexec(sockets[0], true) || !sway_set_cloexec(sockets[1], true)) { return false; } config->swaybg_client = wl_client_create(server.wl_display, sockets[0]); if (config->swaybg_client == NULL) { sway_log_errno(SWAY_ERROR, "wl_client_create failed"); return false; } config->swaybg_client_destroy.notify = handle_swaybg_client_destroy; wl_client_add_destroy_listener(config->swaybg_client, &config->swaybg_client_destroy); pid_t pid = fork(); if (pid < 0) { sway_log_errno(SWAY_ERROR, "fork failed"); return false; } else if (pid == 0) { restore_nofile_limit(); pid = fork(); if (pid < 0) { sway_log_errno(SWAY_ERROR, "fork failed"); _exit(EXIT_FAILURE); } else if (pid == 0) { if (!sway_set_cloexec(sockets[1], false)) { _exit(EXIT_FAILURE); } char wayland_socket_str[16]; snprintf(wayland_socket_str, sizeof(wayland_socket_str), "%d", sockets[1]); setenv("WAYLAND_SOCKET", wayland_socket_str, true); execvp(command[0], command); sway_log_errno(SWAY_ERROR, "failed to execute '%s' " "(background configuration probably not applied)", command[0]); _exit(EXIT_FAILURE); } _exit(EXIT_SUCCESS); } if (close(sockets[1]) != 0) { sway_log_errno(SWAY_ERROR, "close failed"); return false; } int fork_status = 0; if (waitpid(pid, &fork_status, 0) < 0) { sway_log_errno(SWAY_ERROR, "waitpid failed"); return false; } return WIFEXITED(fork_status) && WEXITSTATUS(fork_status) == EXIT_SUCCESS; } bool spawn_swaybg(void) { if (!config->swaybg_command) { return true; } size_t length = 2; for (int i = 0; i < config->output_configs->length; i++) { struct output_config *oc = config->output_configs->items[i]; if (!oc->background) { continue; } if (strcmp(oc->background_option, "solid_color") == 0) { length += 4; } else if (oc->background_fallback) { length += 8; } else { length += 6; } } char **cmd = calloc(length, sizeof(char *)); if (!cmd) { sway_log(SWAY_ERROR, "Failed to allocate spawn_swaybg command"); return false; } size_t i = 0; cmd[i++] = config->swaybg_command; for (int j = 0; j < config->output_configs->length; j++) { struct output_config *oc = config->output_configs->items[j]; if (!oc->background) { continue; } if (strcmp(oc->background_option, "solid_color") == 0) { cmd[i++] = "-o"; cmd[i++] = oc->name; cmd[i++] = "-c"; cmd[i++] = oc->background; } else { cmd[i++] = "-o"; cmd[i++] = oc->name; cmd[i++] = "-i"; cmd[i++] = oc->background; cmd[i++] = "-m"; cmd[i++] = oc->background_option; if (oc->background_fallback) { cmd[i++] = "-c"; cmd[i++] = oc->background_fallback; } } assert(i <= length); } for (size_t k = 0; k < i; k++) { sway_log(SWAY_DEBUG, "spawn_swaybg cmd[%zd] = %s", k, cmd[k]); } bool result = _spawn_swaybg(cmd); free(cmd); return result; }