/************************************************************************** * * Tint2 : battery * * Copyright (C) 2009 Sebastian Reichel * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License version 2 * or any later version as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. **************************************************************************/ #include #include #include #include #include #include #if defined(__OpenBSD__) || defined(__NetBSD__) #include #include #include #include #endif #if defined(__FreeBSD__) #include #include #endif #include "window.h" #include "server.h" #include "panel.h" #include "battery.h" #include "timer.h" #include "common.h" PangoFontDescription *bat1_font_desc; PangoFontDescription *bat2_font_desc; struct batstate battery_state; int battery_enabled; int percentage_hide; static timeout* battery_timeout; static char buf_bat_percentage[10]; static char buf_bat_time[20]; int8_t battery_low_status; unsigned char battery_low_cmd_sent; char *battery_low_cmd; gchar *path_energy_now; gchar *path_energy_full; gchar *path_current_now; gchar *path_status; int battery_found; #if defined(__OpenBSD__) || defined(__NetBSD__) int apm_fd; #endif void update_battery_tick(void* arg) { if (!battery_enabled) return; int old_found = battery_found; int old_percentage = battery_state.percentage; int16_t old_hours = battery_state.time.hours; int8_t old_minutes = battery_state.time.minutes; if (!battery_found) { init_battery(); } if (update_battery() != 0) { // Reconfigure init_battery(); // Try again update_battery(); } if (old_found == battery_found && old_percentage == battery_state.percentage && old_hours == battery_state.time.hours && old_minutes == battery_state.time.minutes) { return; } if (battery_state.percentage < battery_low_status && battery_state.state == BATTERY_DISCHARGING && !battery_low_cmd_sent) { tint_exec(battery_low_cmd); battery_low_cmd_sent = 1; } if (battery_state.percentage > battery_low_status && battery_state.state == BATTERY_CHARGING && battery_low_cmd_sent) { battery_low_cmd_sent = 0; } int i; for (i = 0; i < nb_panel; i++) { if (!battery_found) { if (panel1[i].battery.area.on_screen == 1) { hide(&panel1[i].battery.area); panel_refresh = 1; } } else { if (battery_state.percentage >= percentage_hide) { if (panel1[i].battery.area.on_screen == 1) { hide(&panel1[i].battery.area); panel_refresh = 1; } } else { if (panel1[i].battery.area.on_screen == 0) { show(&panel1[i].battery.area); panel_refresh = 1; } } } if (panel1[i].battery.area.on_screen == 1) { panel1[i].battery.area.resize = 1; panel_refresh = 1; } } } void default_battery() { battery_enabled = 0; battery_found = 0; percentage_hide = 101; battery_low_cmd_sent = 0; battery_timeout = NULL; bat1_font_desc = NULL; bat2_font_desc = NULL; battery_low_cmd = NULL; path_energy_now = NULL; path_energy_full = NULL; path_current_now = NULL; path_status = NULL; battery_state.percentage = 0; battery_state.time.hours = 0; battery_state.time.minutes = 0; battery_state.time.seconds = 0; battery_state.state = BATTERY_UNKNOWN; #if defined(__OpenBSD__) || defined(__NetBSD__) apm_fd = -1; #endif } void cleanup_battery() { pango_font_description_free(bat1_font_desc); bat1_font_desc = NULL; pango_font_description_free(bat2_font_desc); bat2_font_desc = NULL; g_free(path_energy_now); path_energy_now = NULL; g_free(path_energy_full); path_energy_full = NULL; g_free(path_current_now); path_current_now = NULL; g_free(path_status); path_status = NULL; free(battery_low_cmd); battery_low_cmd = NULL; stop_timeout(battery_timeout); battery_timeout = NULL; battery_found = 0; #if defined(__OpenBSD__) || defined(__NetBSD__) if ((apm_fd != -1) && (close(apm_fd) == -1)) warn("cannot close /dev/apm"); apm_fd = -1; #endif } void init_battery() { if (!battery_enabled) return; battery_found = 0; #if defined(__OpenBSD__) || defined(__NetBSD__) if (apm_fd > 0) close(apm_fd); apm_fd = open("/dev/apm", O_RDONLY); if (apm_fd < 0) { warn("ERROR: battery applet cannot open /dev/apm."); battery_found = 0; } else { battery_found = 1; } #elif defined(__FreeBSD__) int sysctl_out = 0; size_t len = sizeof(sysctl_out); battery_found = (sysctlbyname("hw.acpi.battery.state", &sysctl_out, &len, NULL, 0) == 0) || (sysctlbyname("hw.acpi.battery.time", &sysctl_out, &len, NULL, 0) == 0) || (sysctlbyname("hw.acpi.battery.life", &sysctl_out, &len, NULL, 0) == 0); #else // Linux GDir *directory = 0; GError *error = NULL; const char *entryname; gchar *battery_dir = 0; directory = g_dir_open("/sys/class/power_supply", 0, &error); if (error) { g_error_free(error); } else { while ((entryname = g_dir_read_name(directory))) { if (strncmp(entryname, "AC", 2) == 0) continue; gchar *path1 = g_build_filename("/sys/class/power_supply", entryname, "present", NULL); if (g_file_test(path1, G_FILE_TEST_EXISTS)) { g_free(path1); battery_dir = g_build_filename("/sys/class/power_supply", entryname, NULL); break; } g_free(path1); } } if (directory) g_dir_close(directory); if (!battery_dir) { fprintf(stderr, "ERROR: battery applet cannot find any battery\n"); battery_found = 0; } else { battery_found = 1; g_free(path_energy_now); path_energy_now = g_build_filename(battery_dir, "energy_now", NULL); if (!g_file_test(path_energy_now, G_FILE_TEST_EXISTS)) { g_free(path_energy_now); path_energy_now = g_build_filename(battery_dir, "charge_now", NULL); } if (!g_file_test(path_energy_now, G_FILE_TEST_EXISTS)) { fprintf(stderr, "ERROR: battery applet cannot find energy_now nor charge_now\n"); g_free(path_energy_now); path_energy_now = NULL; } g_free(path_energy_full); path_energy_full = g_build_filename(battery_dir, "energy_full", NULL); if (!g_file_test(path_energy_full, G_FILE_TEST_EXISTS)) { g_free(path_energy_full); path_energy_full = g_build_filename(battery_dir, "charge_full", NULL); } if (!g_file_test(path_energy_full, G_FILE_TEST_EXISTS)) { fprintf(stderr, "ERROR: battery applet cannot find energy_now nor charge_now\n"); g_free(path_energy_full); path_energy_full = NULL; } g_free(path_current_now); path_current_now = g_build_filename(battery_dir, "power_now", NULL); if (!g_file_test(path_current_now, G_FILE_TEST_EXISTS)) { g_free(path_current_now); path_current_now = g_build_filename(battery_dir, "current_now", NULL); } if (!g_file_test(path_current_now, G_FILE_TEST_EXISTS)) { fprintf(stderr, "ERROR: battery applet cannot find power_now nor current_now\n"); g_free(path_current_now); path_current_now = NULL; } g_free(path_status); path_status = g_build_filename(battery_dir, "status", NULL); if (!g_file_test(path_status, G_FILE_TEST_EXISTS)) { fprintf(stderr, "ERROR: battery applet cannot find battery status\n"); g_free(path_status); path_status = NULL; } g_free(battery_dir); battery_dir = NULL; } if (!path_status) { battery_found = 0; fprintf(stderr, "ERROR: battery applet cannot find any batteries\n"); } #endif if (!battery_timeout) battery_timeout = add_timeout(10, 30000, update_battery_tick, 0, &battery_timeout); } void init_battery_panel(void *p) { Panel *panel = (Panel*)p; Battery *battery = &panel->battery; if (!battery_enabled) return; if (!bat1_font_desc) bat1_font_desc = pango_font_description_from_string(DEFAULT_FONT); if (!bat2_font_desc) bat2_font_desc = pango_font_description_from_string(DEFAULT_FONT); if (battery->area.bg == 0) battery->area.bg = &g_array_index(backgrounds, Background, 0); battery->area.parent = p; battery->area.panel = p; battery->area._draw_foreground = draw_battery; battery->area.size_mode = SIZE_BY_CONTENT; battery->area._resize = resize_battery; battery->area.on_screen = 1; battery->area.resize = 1; } int update_battery() { int64_t energy_now = 0, energy_full = 0; int seconds = 0; int8_t new_percentage = 0; int errors = 0; battery_state.state = BATTERY_UNKNOWN; #if defined(__OpenBSD__) || defined(__NetBSD__) struct apm_power_info info; if (apm_fd > 0 && ioctl(apm_fd, APM_IOC_GETPOWER, &(info)) == 0) { // best attempt at mapping to Linux battery states switch (info.battery_state) { case APM_BATT_CHARGING: battery_state.state = BATTERY_CHARGING; break; default: battery_state.state = BATTERY_DISCHARGING; break; } if (info.battery_life == 100) battery_state.state = BATTERY_FULL; // no mapping for openbsd really energy_full = 0; energy_now = 0; if (info.minutes_left != -1) seconds = info.minutes_left * 60; else seconds = -1; new_percentage = info.battery_life; } else { warn("power update: APM_IOC_GETPOWER"); errors = 1; } #elif defined(__FreeBSD__) int sysctl_out = 0; size_t len = sizeof(sysctl_out); if (sysctlbyname("hw.acpi.battery.state", &sysctl_out, &len, NULL, 0) == 0) { // attemp to map the battery state to Linux battery_state.state = BATTERY_UNKNOWN; switch(sysctl_out) { case 1: battery_state.state = BATTERY_DISCHARGING; break; case 2: battery_state.state = BATTERY_CHARGING; break; default: battery_state.state = BATTERY_FULL; break; } } else { fprintf(stderr, "power update: no such sysctl"); errors = 1; } // no mapping for freebsd energy_full = 0; energy_now = 0; if (sysctlbyname("hw.acpi.battery.time", &sysctl_out, &len, NULL, 0) != 0) seconds = -1; else seconds = sysctl_out * 60; // charging or error if (seconds < 0) seconds = 0; if (sysctlbyname("hw.acpi.battery.life", &sysctl_out, &len, NULL, 0) != 0) new_percentage = -1; else new_percentage = sysctl_out; #else FILE *fp = NULL; char tmp[25] = ""; int64_t current_now = 0; if (path_status) { fp = fopen(path_status, "r"); if (fp != NULL) { if (fgets(tmp, sizeof(tmp), fp)) { if (strcasecmp(tmp, "Charging\n") == 0) battery_state.state = BATTERY_CHARGING; if (strcasecmp(tmp, "Discharging\n") == 0) battery_state.state = BATTERY_DISCHARGING; if (strcasecmp(tmp, "Full\n") == 0) battery_state.state = BATTERY_FULL; } fclose(fp); } else { errors = 1; } } else { errors = 1; } if (path_energy_now) { fp = fopen(path_energy_now, "r"); if (fp != NULL) { if (fgets(tmp, sizeof tmp, fp)) energy_now = atoi(tmp); fclose(fp); } else { errors = 1; } } else { errors = 1; } if (path_energy_full) { fp = fopen(path_energy_full, "r"); if (fp != NULL) { if (fgets(tmp, sizeof tmp, fp)) energy_full = atoi(tmp); fclose(fp); } else { errors = 1; } } else { errors = 1; } if (path_current_now) { fp = fopen(path_current_now, "r"); if (fp != NULL) { if (fgets(tmp, sizeof tmp, fp)) current_now = atoi(tmp); fclose(fp); } else { errors = 1; } } else { errors = 1; } if (current_now > 0) { switch (battery_state.state) { case BATTERY_CHARGING: seconds = 3600 * (energy_full - energy_now) / current_now; break; case BATTERY_DISCHARGING: seconds = 3600 * energy_now / current_now; break; default: seconds = 0; break; } } else { seconds = 0; } #endif battery_state.time.hours = seconds / 3600; seconds -= 3600 * battery_state.time.hours; battery_state.time.minutes = seconds / 60; seconds -= 60 * battery_state.time.minutes; battery_state.time.seconds = seconds; if (energy_full > 0) new_percentage = 0.5 + ((energy_now <= energy_full ? energy_now : energy_full) * 100.0) / energy_full; battery_state.percentage = new_percentage; // clamp percentage to 100 in case battery is misreporting that its current charge is more than its max if (battery_state.percentage > 100) { battery_state.percentage = 100; } return errors; } void draw_battery (void *obj, cairo_t *c) { Battery *battery = obj; PangoLayout *layout; layout = pango_cairo_create_layout (c); // draw layout pango_layout_set_font_description(layout, bat1_font_desc); pango_layout_set_width(layout, battery->area.width * PANGO_SCALE); pango_layout_set_alignment(layout, PANGO_ALIGN_CENTER); pango_layout_set_text(layout, buf_bat_percentage, strlen(buf_bat_percentage)); cairo_set_source_rgba(c, battery->font.color[0], battery->font.color[1], battery->font.color[2], battery->font.alpha); pango_cairo_update_layout(c, layout); draw_text(layout, c, 0, battery->bat1_posy, &battery->font, ((Panel*)battery->area.panel)->font_shadow); pango_layout_set_font_description(layout, bat2_font_desc); pango_layout_set_indent(layout, 0); pango_layout_set_text(layout, buf_bat_time, strlen(buf_bat_time)); pango_layout_set_width(layout, battery->area.width * PANGO_SCALE); pango_cairo_update_layout(c, layout); draw_text(layout, c, 0, battery->bat2_posy, &battery->font, ((Panel*)battery->area.panel)->font_shadow); pango_cairo_show_layout(c, layout); g_object_unref(layout); } int resize_battery(void *obj) { Battery *battery = obj; Panel *panel = battery->area.panel; int bat_percentage_height, bat_percentage_width, bat_percentage_height_ink; int bat_time_height, bat_time_width, bat_time_height_ink; int ret = 0; battery->area.redraw = 1; snprintf(buf_bat_percentage, sizeof(buf_bat_percentage), "%d%%", battery_state.percentage); if (battery_state.state == BATTERY_FULL) { strcpy(buf_bat_time, "Full"); } else { snprintf(buf_bat_time, sizeof(buf_bat_time), "%02d:%02d", battery_state.time.hours, battery_state.time.minutes); } get_text_size2(bat1_font_desc, &bat_percentage_height_ink, &bat_percentage_height, &bat_percentage_width, panel->area.height, panel->area.width, buf_bat_percentage, strlen(buf_bat_percentage)); get_text_size2(bat2_font_desc, &bat_time_height_ink, &bat_time_height, &bat_time_width, panel->area.height, panel->area.width, buf_bat_time, strlen(buf_bat_time)); if (panel_horizontal) { int new_size = (bat_percentage_width > bat_time_width) ? bat_percentage_width : bat_time_width; new_size += 2 * battery->area.paddingxlr + 2 * battery->area.bg->border.width; if (new_size > battery->area.width || new_size < battery->area.width - 2) { // we try to limit the number of resize battery->area.width = new_size; battery->bat1_posy = (battery->area.height - bat_percentage_height - bat_time_height) / 2; battery->bat2_posy = battery->bat1_posy + bat_percentage_height; ret = 1; } } else { int new_size = bat_percentage_height + bat_time_height + (2 * (battery->area.paddingxlr + battery->area.bg->border.width)); if (new_size > battery->area.height || new_size < battery->area.height - 2) { battery->area.height = new_size; battery->bat1_posy = (battery->area.height - bat_percentage_height - bat_time_height - 2) / 2; battery->bat2_posy = battery->bat1_posy + bat_percentage_height + 2; ret = 1; } } return ret; }