#define _POSIX_C_SOURCE 200809L #include #include #include #include #include #include #include #include #include #include "backend/drm/drm.h" #include "backend/drm/util.h" int32_t calculate_refresh_rate(const drmModeModeInfo *mode) { int32_t refresh = (mode->clock * 1000000LL / mode->htotal + mode->vtotal / 2) / mode->vtotal; if (mode->flags & DRM_MODE_FLAG_INTERLACE) { refresh *= 2; } if (mode->flags & DRM_MODE_FLAG_DBLSCAN) { refresh /= 2; } if (mode->vscan > 1) { refresh /= mode->vscan; } return refresh; } static const char *get_manufacturer(struct udev_hwdb *hwdb, uint16_t code) { static char pnp_id[4]; // The ASCII 3-letter manufacturer PnP ID is encoded in 5-bit codes pnp_id[0] = ((code >> 10) & 0x1F) + '@'; pnp_id[1] = ((code >> 5) & 0x1F) + '@'; pnp_id[2] = ((code >> 0) & 0x1F) + '@'; pnp_id[3] = '\0'; if (hwdb == NULL) { return pnp_id; } char query[32]; snprintf(query, sizeof(query), "acpi:%s:", pnp_id); struct udev_list_entry *acpi_entry = udev_hwdb_get_properties_list_entry(hwdb, query, 0); if (acpi_entry == NULL) { return pnp_id; } struct udev_list_entry *vendor_entry = udev_list_entry_get_by_name(acpi_entry, "ID_VENDOR_FROM_DATABASE"); if (vendor_entry == NULL) { return pnp_id; } return udev_list_entry_get_value(vendor_entry); } /* See https://en.wikipedia.org/wiki/Extended_Display_Identification_Data for layout of EDID data. * We don't parse the EDID properly. We just expect to receive valid data. */ void parse_edid(struct wlr_drm_connector *conn, size_t len, const uint8_t *data) { struct wlr_output *output = &conn->output; free(output->make); free(output->model); free(output->serial); output->make = NULL; output->model = NULL; output->serial = NULL; if (!data || len < 128) { return; } uint16_t id = (data[8] << 8) | data[9]; output->make = strdup(get_manufacturer(conn->backend->hwdb, id)); uint16_t model = data[10] | (data[11] << 8); char model_str[32]; snprintf(model_str, sizeof(model_str), "0x%04" PRIX16, model); uint32_t serial = data[12] | (data[13] << 8) | (data[14] << 8) | (data[15] << 8); char serial_str[32]; snprintf(serial_str, sizeof(serial_str), "0x%08" PRIX32, serial); for (size_t i = 72; i <= 108; i += 18) { uint16_t flag = (data[i] << 8) | data[i + 1]; if (flag == 0 && data[i + 3] == 0xFC) { snprintf(model_str, sizeof(model_str), "%.13s", &data[i + 5]); // Monitor names are terminated by newline if they're too short char *nl = strchr(model_str, '\n'); if (nl) { *nl = '\0'; } } else if (flag == 0 && data[i + 3] == 0xFF) { snprintf(serial_str, sizeof(serial_str), "%.13s", &data[i + 5]); // Monitor serial numbers are terminated by newline if they're too // short char *nl = strchr(output->serial, '\n'); if (nl) { *nl = '\0'; } } } output->model = strdup(model_str); output->serial = strdup(serial_str); } const char *conn_get_name(uint32_t type_id) { switch (type_id) { case DRM_MODE_CONNECTOR_Unknown: return "Unknown"; case DRM_MODE_CONNECTOR_VGA: return "VGA"; case DRM_MODE_CONNECTOR_DVII: return "DVI-I"; case DRM_MODE_CONNECTOR_DVID: return "DVI-D"; case DRM_MODE_CONNECTOR_DVIA: return "DVI-A"; case DRM_MODE_CONNECTOR_Composite: return "Composite"; case DRM_MODE_CONNECTOR_SVIDEO: return "SVIDEO"; case DRM_MODE_CONNECTOR_LVDS: return "LVDS"; case DRM_MODE_CONNECTOR_Component: return "Component"; case DRM_MODE_CONNECTOR_9PinDIN: return "DIN"; case DRM_MODE_CONNECTOR_DisplayPort: return "DP"; case DRM_MODE_CONNECTOR_HDMIA: return "HDMI-A"; case DRM_MODE_CONNECTOR_HDMIB: return "HDMI-B"; case DRM_MODE_CONNECTOR_TV: return "TV"; case DRM_MODE_CONNECTOR_eDP: return "eDP"; case DRM_MODE_CONNECTOR_VIRTUAL: return "Virtual"; case DRM_MODE_CONNECTOR_DSI: return "DSI"; case DRM_MODE_CONNECTOR_DPI: return "DPI"; case DRM_MODE_CONNECTOR_WRITEBACK: return "Writeback"; #ifdef DRM_MODE_CONNECTOR_SPI case DRM_MODE_CONNECTOR_SPI: return "SPI"; #endif #ifdef DRM_MODE_CONNECTOR_USB case DRM_MODE_CONNECTOR_USB: return "USB"; #endif default: return "Unknown"; } } static bool is_taken(size_t n, const uint32_t arr[static n], uint32_t key) { for (size_t i = 0; i < n; ++i) { if (arr[i] == key) { return true; } } return false; } /* * Store all of the non-recursive state in a struct, so we aren't literally * passing 12 arguments to a function. */ struct match_state { const size_t num_objs; const uint32_t *restrict objs; const size_t num_res; size_t score; size_t replaced; uint32_t *restrict res; uint32_t *restrict best; const uint32_t *restrict orig; bool exit_early; }; /* * skips: The number of SKIP elements encountered so far. * score: The number of resources we've matched so far. * replaced: The number of changes from the original solution. * i: The index of the current element. * * This tries to match a solution as close to st->orig as it can. * * Returns whether we've set a new best element with this solution. */ static bool match_obj_(struct match_state *st, size_t skips, size_t score, size_t replaced, size_t i) { // Finished if (i >= st->num_res) { if (score > st->score || (score == st->score && replaced < st->replaced)) { st->score = score; st->replaced = replaced; memcpy(st->best, st->res, sizeof(st->best[0]) * st->num_res); st->exit_early = (st->score == st->num_res - skips || st->score == st->num_objs) && st->replaced == 0; return true; } else { return false; } } if (st->orig[i] == SKIP) { st->res[i] = SKIP; return match_obj_(st, skips + 1, score, replaced, i + 1); } bool has_best = false; /* * Attempt to use the current solution first, to try and avoid * recalculating everything */ if (st->orig[i] != UNMATCHED && !is_taken(i, st->res, st->orig[i])) { st->res[i] = st->orig[i]; size_t obj_score = st->objs[st->res[i]] != 0 ? 1 : 0; if (match_obj_(st, skips, score + obj_score, replaced, i + 1)) { has_best = true; } } if (st->orig[i] == UNMATCHED) { st->res[i] = UNMATCHED; if (match_obj_(st, skips, score, replaced, i + 1)) { has_best = true; } } if (st->exit_early) { return true; } if (st->orig[i] != UNMATCHED) { ++replaced; } for (size_t candidate = 0; candidate < st->num_objs; ++candidate) { // We tried this earlier if (candidate == st->orig[i]) { continue; } // Not compatible if (!(st->objs[candidate] & (1 << i))) { continue; } // Already taken if (is_taken(i, st->res, candidate)) { continue; } st->res[i] = candidate; size_t obj_score = st->objs[candidate] != 0 ? 1 : 0; if (match_obj_(st, skips, score + obj_score, replaced, i + 1)) { has_best = true; } if (st->exit_early) { return true; } } if (has_best) { return true; } // Maybe this resource can't be matched st->res[i] = UNMATCHED; return match_obj_(st, skips, score, replaced, i + 1); } size_t match_obj(size_t num_objs, const uint32_t objs[static restrict num_objs], size_t num_res, const uint32_t res[static restrict num_res], uint32_t out[static restrict num_res]) { uint32_t solution[num_res]; for (size_t i = 0; i < num_res; ++i) { solution[i] = UNMATCHED; } struct match_state st = { .num_objs = num_objs, .num_res = num_res, .score = 0, .replaced = SIZE_MAX, .objs = objs, .res = solution, .best = out, .orig = res, .exit_early = false, }; match_obj_(&st, 0, 0, 0, 0); return st.score; }