#include #include #include #include #include #include #include #include #include #include #include #include #include /* ------------------------------------------------------------------------- */ static const gchar* dbus_object_path = "/org/openbmc/control"; static const gchar* instance_name = "power0"; static const gchar* dbus_name = "org.openbmc.control.Power"; static int g_pci_reset_held = 1; static GpioConfigs g_gpio_configs; static GDBusObjectManagerServer *manager = NULL; time_t pgood_timeout_start = 0; // TODO: Change to interrupt driven instead of polling static gboolean poll_pgood(gpointer user_data) { ControlPower *control_power = object_get_control_power((Object*)user_data); Control* control = object_get_control((Object*)user_data); //send the heartbeat guint poll_int = control_get_poll_interval(control); if(poll_int == 0) { g_print("ERROR PowerControl: Poll interval cannot be 0\n"); return FALSE; } //handle timeout time_t current_time = time(NULL); if(difftime(current_time,pgood_timeout_start) > control_power_get_pgood_timeout(control_power) && pgood_timeout_start != 0) { g_print("ERROR PowerControl: Pgood poll timeout\n"); // set timeout to 0 so timeout doesn't happen again control_power_set_pgood_timeout(control_power,0); pgood_timeout_start = 0; return TRUE; } uint8_t pgood_state; int rc = gpio_open(&g_gpio_configs.power_gpio.power_good_in); if(rc != GPIO_OK) { g_print("ERROR PowerControl: GPIO open error (gpio=%s,rc=%d)\n", g_gpio_configs.power_gpio.power_good_in.name, rc); return FALSE; } rc = gpio_read(&g_gpio_configs.power_gpio.power_good_in, &pgood_state); gpio_close(&g_gpio_configs.power_gpio.power_good_in); if(rc == GPIO_OK) { //if changed, set property and emit signal if(pgood_state != control_power_get_pgood(control_power)) { int i; uint8_t reset_state; control_power_set_pgood(control_power, pgood_state); if(pgood_state == 0) { control_power_emit_power_lost(control_power); control_emit_goto_system_state(control,"HOST_POWERED_OFF"); g_pci_reset_held = 1; } else { control_power_emit_power_good(control_power); control_emit_goto_system_state(control,"HOST_POWERED_ON"); } for(i = 0; i < g_gpio_configs.power_gpio.num_reset_outs; i++) { GPIO *reset_out = &g_gpio_configs.power_gpio.reset_outs[i]; rc = gpio_open(reset_out); if(rc != GPIO_OK) { g_print("ERROR PowerControl: GPIO open error (gpio=%s,rc=%d)\n", reset_out->name, rc); continue; } reset_state = pgood_state ^ g_gpio_configs.power_gpio.reset_pols[i]; g_print("PowerControl: pgood: %d, setting reset %s to %d\n", (int)pgood_state, reset_out->name, (int)reset_state); gpio_write(reset_out, reset_state); gpio_close(reset_out); } for(i = 0; i < g_gpio_configs.power_gpio.num_pci_reset_outs; i++) { GPIO *pci_reset_out = &g_gpio_configs.power_gpio.pci_reset_outs[i]; if(pgood_state == 1) { /* * When powering on, hold PCI reset until * the processor can forward clocks and control reset. */ if(g_gpio_configs.power_gpio.pci_reset_holds[i]) { g_print("Holding pci reset: %s\n", pci_reset_out->name); continue; } } rc = gpio_open(pci_reset_out); if(rc != GPIO_OK) { g_print("ERROR PowerControl: GPIO open error (gpio=%s,rc=%d)\n", pci_reset_out->name, rc); continue; } reset_state = pgood_state ^ g_gpio_configs.power_gpio.pci_reset_pols[i]; g_print("PowerControl: pgood: %d, setting pci reset %s to %d\n", (int)pgood_state, pci_reset_out->name, (int)reset_state); gpio_write(pci_reset_out, reset_state); gpio_close(pci_reset_out); } } } else { g_print("ERROR PowerControl: GPIO read error (gpio=%s,rc=%d)\n", g_gpio_configs.power_gpio.power_good_in.name, rc); //return false so poll won't get called anymore return FALSE; } //pgood is not at desired state yet if(pgood_state != control_power_get_state(control_power) && control_power_get_pgood_timeout(control_power) > 0) { if(pgood_timeout_start == 0 ) { pgood_timeout_start = current_time; } } else { pgood_timeout_start = 0; } return TRUE; } /* Handler for BootProgress signal from BootProgress sensor */ static void on_boot_progress(GDBusConnection *connection, const gchar *sender_name, const gchar *object_path, const gchar *interface_name, const gchar *signal_name, GVariant *parameters, gpointer user_data) { gchar *interface; GVariantIter *properties; GVariantIter *dummy; gchar *boot_progress = NULL; gchar *property; GVariant *value; uint8_t pgood_state; uint8_t reset_state; int rc; int i; int ignore; if(!parameters) return; /* prevent release again */ if(!g_pci_reset_held) return; g_variant_get(parameters, "(&sa{sv}as)", &interface, &properties, &dummy); for(i = 0; g_variant_iter_next(properties, "{&sv}", &property, &value); i++) { if (strcmp(property, "BootProgress") == 0) { gchar* tmp; g_variant_get(value, "&s", &tmp); boot_progress = g_strdup(tmp); g_print("BootProgress: %s\n", boot_progress); g_variant_unref(value); } } g_variant_iter_free(properties); g_variant_iter_free(dummy); if (boot_progress == NULL) return; /* Release PCI reset when FW boot progress goes beyond 'Baseboard Init' */ ignore = strcmp(boot_progress, "xyz.openbmc_project.State.Boot.Progress.ProgressStages.MotherboardInit") == 0; g_free(boot_progress); if (ignore) return; rc = gpio_open(&g_gpio_configs.power_gpio.power_good_in); if(rc != GPIO_OK) { g_print("ERROR PowerControl: on_boot_progress(): GPIO open error (gpio=%s,rc=%d)\n", g_gpio_configs.power_gpio.power_good_in.name, rc); return; } rc = gpio_read(&g_gpio_configs.power_gpio.power_good_in, &pgood_state); gpio_close(&g_gpio_configs.power_gpio.power_good_in); if(rc != GPIO_OK || pgood_state != 1) return; for(i = 0; i < g_gpio_configs.power_gpio.num_pci_reset_outs; i++) { GPIO *pci_reset_out = &g_gpio_configs.power_gpio.pci_reset_outs[i]; if(!g_gpio_configs.power_gpio.pci_reset_holds[i]) continue; rc = gpio_open(pci_reset_out); if(rc != GPIO_OK) { g_print("ERROR PowerControl: GPIO open error (gpio=%s,rc=%d)\n", pci_reset_out->name, rc); continue; } reset_state = pgood_state ^ g_gpio_configs.power_gpio.pci_reset_pols[i]; g_print("PowerControl: pgood: %d, setting pci reset %s to %d\n", (int)pgood_state, pci_reset_out->name, (int)reset_state); gpio_write(pci_reset_out, reset_state); gpio_close(pci_reset_out); g_print("Released pci reset: %s\n", pci_reset_out->name); } g_pci_reset_held = 0; } static gboolean on_set_power_state(ControlPower *pwr, GDBusMethodInvocation *invocation, guint state, gpointer user_data) { Control* control = object_get_control((Object*)user_data); PowerGpio *power_gpio = &g_gpio_configs.power_gpio; if(state > 1) { g_dbus_method_invocation_return_dbus_error(invocation, "org.openbmc.ControlPower.Error.Failed", "Invalid power state"); return TRUE; } // return from method call control_power_complete_set_power_state(pwr,invocation); if(state == control_power_get_state(pwr)) { g_print("Power already at requested state: %d\n",state); } else { int error = 0; do { int i; uint8_t power_up_out; if(state == 1) { control_emit_goto_system_state(control,"HOST_POWERING_ON"); } else { control_emit_goto_system_state(control,"HOST_POWERING_OFF"); } for (i = 0; i < power_gpio->num_power_up_outs; i++) { GPIO *power_pin = &power_gpio->power_up_outs[i]; error = gpio_open(power_pin); if(error != GPIO_OK) { g_print("ERROR PowerControl: GPIO open error (gpio=%s,rc=%d)\n", power_gpio->power_up_outs[i].name, error); continue; } power_up_out = state ^ !power_gpio->power_up_pols[i]; g_print("PowerControl: setting power up %s to %d\n", power_gpio->power_up_outs[i].name, (int)power_up_out); error = gpio_write(power_pin, power_up_out); if(error != GPIO_OK) { continue; } gpio_close(power_pin); } if(error != GPIO_OK) { break; } control_power_set_state(pwr,state); } while(0); if(error != GPIO_OK) { g_print("ERROR PowerControl: GPIO set power state (rc=%d)\n",error); } /* If there's a latch, it should be enabled following changes to the * power pins' states. This commits the changes to the latch states. */ if (power_gpio->latch_out.name != NULL) { int rc; uint8_t latch_value = 0; rc = gpio_open(&power_gpio->latch_out); if (rc != GPIO_OK) { /* Failures are non-fatal. */ g_print("PowerControl ERROR failed to open latch %s rc=%d\n", power_gpio->latch_out.name, rc); return TRUE; } /* Make the latch transparent for as brief of a time as possible. */ rc = gpio_write(&power_gpio->latch_out, 1); if (rc != GPIO_OK) { g_print("PowerControl ERROR failed to assert latch %s rc=%d\n", power_gpio->latch_out.name, rc); } else { g_print("PowerControl asserted latch %s\n", power_gpio->latch_out.name); } rc = gpio_write(&power_gpio->latch_out, 0); if (rc != GPIO_OK) { g_print("PowerControl ERROR failed to clear latch %s rc=%d\n", power_gpio->latch_out.name, rc); } gpio_close(&power_gpio->latch_out); } } return TRUE; } static gboolean on_init(Control *control, GDBusMethodInvocation *invocation, gpointer user_data) { pgood_timeout_start = 0; //guint poll_interval = control_get_poll_interval(control); //g_timeout_add(poll_interval, poll_pgood, user_data); control_complete_init(control,invocation); return TRUE; } static gboolean on_get_power_state(ControlPower *pwr, GDBusMethodInvocation *invocation, gpointer user_data) { guint pgood = control_power_get_pgood(pwr); control_power_complete_get_power_state(pwr,invocation,pgood); return TRUE; } static int set_up_gpio(GDBusConnection *connection, PowerGpio *power_gpio, ControlPower* control_power) { int error = GPIO_OK; int rc; int i; uint8_t pgood_state; // get gpio device paths if(power_gpio->latch_out.name != NULL) { /* latch is optional */ rc = gpio_init(connection, &power_gpio->latch_out); if(rc != GPIO_OK) { error = rc; } } rc = gpio_init(connection, &power_gpio->power_good_in); if(rc != GPIO_OK) { error = rc; } for(int i = 0; i < power_gpio->num_power_up_outs; i++) { rc = gpio_init(connection, &power_gpio->power_up_outs[i]); if(rc != GPIO_OK) { error = rc; } } for(int i = 0; i < power_gpio->num_reset_outs; i++) { rc = gpio_init(connection, &power_gpio->reset_outs[i]); if(rc != GPIO_OK) { error = rc; } } for(int i = 0; i < power_gpio->num_pci_reset_outs; i++) { rc = gpio_init(connection, &power_gpio->pci_reset_outs[i]); if(rc != GPIO_OK) { error = rc; } } rc = gpio_open(&power_gpio->power_good_in); if(rc != GPIO_OK) { return rc; } rc = gpio_read(&power_gpio->power_good_in, &pgood_state); if(rc != GPIO_OK) { return rc; } gpio_close(&power_gpio->power_good_in); control_power_set_pgood(control_power, pgood_state); control_power_set_state(control_power, pgood_state); g_print("Pgood state: %d\n", pgood_state); return error; } static void on_bus_acquired(GDBusConnection *connection, const gchar *name, gpointer user_data) { ObjectSkeleton *object; cmdline *cmd = user_data; if(cmd->argc < 3) { g_print("Usage: power_control.exe [poll interval] [timeout]\n"); return; } manager = g_dbus_object_manager_server_new(dbus_object_path); gchar *s; s = g_strdup_printf("%s/%s",dbus_object_path,instance_name); object = object_skeleton_new(s); g_free(s); ControlPower* control_power = control_power_skeleton_new(); object_skeleton_set_control_power(object, control_power); g_object_unref(control_power); Control* control = control_skeleton_new(); object_skeleton_set_control(object, control); g_object_unref(control); //define method callbacks here g_signal_connect(control_power, "handle-set-power-state", G_CALLBACK(on_set_power_state), object); /* user_data */ g_signal_connect(control_power, "handle-get-power-state", G_CALLBACK(on_get_power_state), NULL); /* user_data */ g_signal_connect(control, "handle-init", G_CALLBACK(on_init), object); /* user_data */ /* Listen for BootProgress signal from BootProgress sensor */ g_dbus_connection_signal_subscribe(connection, NULL, /* service */ "org.freedesktop.DBus.Properties", /* interface_name */ "PropertiesChanged", /* member: name of the signal */ "/xyz/openbmc_project/state/host0", /* obj path */ NULL, /* arg0 */ G_DBUS_SIGNAL_FLAGS_NONE, (GDBusSignalCallback) on_boot_progress, object, /* user data */ NULL ); /* Export the object (@manager takes its own reference to @object) */ g_dbus_object_manager_server_set_connection(manager, connection); g_dbus_object_manager_server_export(manager, G_DBUS_OBJECT_SKELETON(object)); g_object_unref(object); if(read_gpios(connection, &g_gpio_configs) != TRUE) { g_print("ERROR PowerControl: could not read power GPIO configuration\n"); } int rc = set_up_gpio(connection, &g_gpio_configs.power_gpio, control_power); if(rc != GPIO_OK) { g_print("ERROR PowerControl: GPIO setup (rc=%d)\n",rc); } //start poll pgood_timeout_start = 0; int poll_interval = atoi(cmd->argv[1]); int pgood_timeout = atoi(cmd->argv[2]); if(poll_interval < 500 || pgood_timeout <5) { g_print("ERROR PowerControl: poll_interval < 500 or pgood_timeout < 5\n"); } else { control_set_poll_interval(control,poll_interval); control_power_set_pgood_timeout(control_power,pgood_timeout); g_timeout_add(poll_interval, poll_pgood, object); } } static void on_name_acquired(GDBusConnection *connection, const gchar *name, gpointer user_data) { } static void on_name_lost(GDBusConnection *connection, const gchar *name, gpointer user_data) { free_gpios(&g_gpio_configs); } /*----------------------------------------------------------------*/ /* Main Event Loop */ gint main(gint argc, gchar *argv[]) { GMainLoop *loop; cmdline cmd; cmd.argc = argc; cmd.argv = argv; guint id; loop = g_main_loop_new(NULL, FALSE); id = g_bus_own_name(DBUS_TYPE, dbus_name, G_BUS_NAME_OWNER_FLAGS_ALLOW_REPLACEMENT | G_BUS_NAME_OWNER_FLAGS_REPLACE, on_bus_acquired, on_name_acquired, on_name_lost, &cmd, NULL); g_main_loop_run(loop); g_bus_unown_name(id); g_main_loop_unref(loop); return 0; }