/* Console example — various system commands This example code is in the Public Domain (or CC0 licensed, at your option.) Unless required by applicable law or agreed to in writing, this software is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. */ #include #include #include #include "esp_log.h" #include "esp_console.h" #include "esp_system.h" #include "esp_spi_flash.h" #include "driver/rtc_io.h" #include "driver/uart.h" #include "argtable3/argtable3.h" #include "freertos/FreeRTOS.h" #include "freertos/task.h" #include "soc/rtc_cntl_reg.h" #include "esp_rom_uart.h" #include "cmd_system.h" #include "sdkconfig.h" #include "esp_partition.h" #include "esp_ota_ops.h" #include "platform_esp32.h" #include "Configurator.h" #include "esp_sleep.h" #include "messaging.h" #include "platform_console.h" #include "tools.h" #if defined(CONFIG_WITH_METRICS) #include "Metrics.h" #endif #ifdef CONFIG_FREERTOS_GENERATE_RUN_TIME_STATS #pragma message("Runtime stats enabled") #define WITH_TASKS_INFO 1 #else #pragma message("Runtime stats disabled") #endif EXT_RAM_ATTR static struct { struct arg_str * device; // AirPlay device name struct arg_str * airplay; // Spotify device name struct arg_str * spotify; // Bluetooth player name advertized struct arg_str * bluetooth; // Player name reported to the Logitech Media Server struct arg_str * squeezelite; // Wifi Access Point name struct arg_str * wifi_ap_name; struct arg_lit * all; struct arg_end *end; } names_args; static const char * TAG = "cmd_system"; static void register_free(); static void register_setdevicename(); static void register_heap(); static void register_dump_heap(); static void register_version(); static void register_restart(); #if CONFIG_WITH_CONFIG_UI static void register_deep_sleep(); static void register_light_sleep(); #endif static void register_factory_boot(); static void register_restart_ota(); // static void register_set_services(); #if WITH_TASKS_INFO static void register_tasks(); #endif extern BaseType_t network_manager_task; FILE * system_open_memstream(const char * cmdname,char **buf,size_t *buf_size){ FILE *f = open_memstream(buf, buf_size); if (f == NULL) { cmd_send_messaging(cmdname,MESSAGING_ERROR,"Unable to open memory stream."); } return f; } void register_system() { // register_set_services(); register_setdevicename(); register_free(); register_heap(); register_dump_heap(); register_version(); register_restart(); register_factory_boot(); register_restart_ota(); #if WITH_TASKS_INFO register_tasks(); #endif #if CONFIG_WITH_CONFIG_UI register_deep_sleep(); register_light_sleep(); #endif } void simple_restart() { log_send_messaging(MESSAGING_WARNING,"Rebooting."); if(!configurator_waitcommit()){ log_send_messaging(MESSAGING_WARNING,"Unable to commit configuration. "); } vTaskDelay(750/ portTICK_PERIOD_MS); esp_restart(); } /* 'version' command */ static int get_version(int argc, char **argv) { esp_chip_info_t info; esp_chip_info(&info); cmd_send_messaging(argv[0],MESSAGING_INFO, "IDF Version:%s\r\n" "Chip info:\r\n" "\tmodel:%s\r\n" "\tcores:%d\r\n" "\tfeature:%s%s%s%s%d%s\r\n" "\trevision number:%d\r\n", esp_get_idf_version(), info.model == CHIP_ESP32 ? "ESP32" : "Unknow", info.cores, info.features & CHIP_FEATURE_WIFI_BGN ? "/802.11bgn" : "", info.features & CHIP_FEATURE_BLE ? "/BLE" : "", info.features & CHIP_FEATURE_BT ? "/BT" : "", info.features & CHIP_FEATURE_EMB_FLASH ? "/Embedded-Flash:" : "/External-Flash:", spi_flash_get_chip_size() / (1024 * 1024), " MB", info.revision); return 0; } static void register_version() { const esp_console_cmd_t cmd = { .command = "version", .help = "Get version of chip and SDK", .hint = NULL, .func = &get_version, }; cmd_to_json(&cmd); ESP_ERROR_CHECK( esp_console_cmd_register(&cmd) ); } esp_err_t guided_boot(esp_partition_subtype_t partition_subtype) { if(is_recovery_running){ if(partition_subtype ==ESP_PARTITION_SUBTYPE_APP_FACTORY){ // log_send_messaging(MESSAGING_WARNING,"RECOVERY application is already active"); simple_restart(); } } else { if(partition_subtype !=ESP_PARTITION_SUBTYPE_APP_FACTORY){ // log_send_messaging(MESSAGING_WARNING,"SQUEEZELITE application is already active"); simple_restart(); } } esp_err_t err = ESP_OK; // log_send_messaging(MESSAGING_INFO, "Looking for partition type %u",partition_subtype); const esp_partition_t *partition; esp_partition_iterator_t it = esp_partition_find(ESP_PARTITION_TYPE_APP, partition_subtype, NULL); if(it == NULL){ log_send_messaging(MESSAGING_ERROR,"Reboot failed. Partitions error"); } else { ESP_LOGD(TAG, "Found partition. Getting info."); partition = (esp_partition_t *) esp_partition_get(it); ESP_LOGD(TAG, "Releasing partition iterator"); esp_partition_iterator_release(it); if(partition != NULL){ log_send_messaging(MESSAGING_INFO, "Rebooting to %s", partition->label); err=esp_ota_set_boot_partition(partition); if(err!=ESP_OK){ log_send_messaging(MESSAGING_ERROR,"Unable to select partition for reboot: %s",esp_err_to_name(err)); } } else { log_send_messaging(MESSAGING_ERROR,"partition type %u not found! Unable to reboot to recovery.",partition_subtype); } ESP_LOGD(TAG, "Yielding to other processes"); taskYIELD(); simple_restart(); } return ESP_OK; } static int restart(int argc, char **argv) { simple_restart(); return 0; } esp_err_t guided_restart_ota(){ log_send_messaging(MESSAGING_WARNING,"Booting to Squeezelite"); guided_boot(ESP_PARTITION_SUBTYPE_APP_OTA_0); return ESP_FAIL; // return fail. This should never return... we're rebooting! } esp_err_t guided_factory(){ log_send_messaging(MESSAGING_WARNING,"Booting to recovery"); guided_boot(ESP_PARTITION_SUBTYPE_APP_FACTORY); return ESP_FAIL; // return fail. This should never return... we're rebooting! } static int restart_factory(int argc, char **argv) { cmd_send_messaging(argv[0],MESSAGING_WARNING, "Booting to Recovery"); guided_boot(ESP_PARTITION_SUBTYPE_APP_FACTORY); return 0; // return fail. This should never return... we're rebooting! } static int restart_ota(int argc, char **argv) { cmd_send_messaging(argv[0],MESSAGING_WARNING, "Booting to Squeezelite"); guided_boot(ESP_PARTITION_SUBTYPE_APP_OTA_0); return 0; // return fail. This should never return... we're rebooting! } static void register_restart() { const esp_console_cmd_t cmd = { .command = "restart", .help = "Reboot system", .hint = NULL, .func = &restart, }; #if CONFIG_WITH_CONFIG_UI cmd_to_json(&cmd); #endif ESP_ERROR_CHECK( esp_console_cmd_register(&cmd) ); } static void register_restart_ota() { const esp_console_cmd_t cmd = { .command = "restart_ota", .help = "Reboot system to Squeezelite", .hint = NULL, .func = &restart_ota, }; #if CONFIG_WITH_CONFIG_UI cmd_to_json(&cmd); #endif ESP_ERROR_CHECK( esp_console_cmd_register(&cmd) ); } static void register_factory_boot() { const esp_console_cmd_t cmd = { .command = "recovery", .help = "Reboot system to Recovery", .hint = NULL, .func = &restart_factory, }; #if CONFIG_WITH_CONFIG_UI cmd_to_json(&cmd); #endif ESP_ERROR_CHECK( esp_console_cmd_register(&cmd) ); } /** 'free' command prints available heap memory */ static int free_mem(int argc, char **argv) { cmd_send_messaging(argv[0],MESSAGING_INFO,"%d", esp_get_free_heap_size()); return 0; } static void register_free() { const esp_console_cmd_t cmd = { .command = "free", .help = "Get free heap memory", .hint = NULL, .func = &free_mem, }; #if CONFIG_WITH_CONFIG_UI cmd_to_json(&cmd); #endif ESP_ERROR_CHECK( esp_console_cmd_register(&cmd) ); } static int dump_heap(int argc, char **argv) { ESP_LOGD(TAG, "Dumping heap"); heap_caps_dump_all(); return 0; } /* 'heap' command prints minumum heap size */ static int heap_size(int argc, char **argv) { // ESP_LOGI(TAG,"Heap internal:%zu (min:%zu) (largest block:%zu)\nexternal:%zu (min:%zu) (largest block:%zd)\ndma :%zu (min:%zu) (largest block:%zd)", // heap_caps_get_free_size(MALLOC_CAP_INTERNAL), // heap_caps_get_minimum_free_size(MALLOC_CAP_INTERNAL), // heap_caps_get_largest_free_block(MALLOC_CAP_INTERNAL), // heap_caps_get_free_size(MALLOC_CAP_SPIRAM), // heap_caps_get_minimum_free_size(MALLOC_CAP_SPIRAM), // heap_caps_get_largest_free_block(MALLOC_CAP_SPIRAM), // heap_caps_get_free_size(MALLOC_CAP_DMA), // heap_caps_get_minimum_free_size(MALLOC_CAP_DMA), // heap_caps_get_largest_free_block(MALLOC_CAP_DMA)); cmd_send_messaging(argv[0],MESSAGING_INFO,"Heap internal:%zu (min:%zu) (largest block:%zu)\nexternal:%zu (min:%zu) (largest block:%zd)\ndma :%zu (min:%zu) (largest block:%zd)", heap_caps_get_free_size(MALLOC_CAP_INTERNAL), heap_caps_get_minimum_free_size(MALLOC_CAP_INTERNAL), heap_caps_get_largest_free_block(MALLOC_CAP_INTERNAL), heap_caps_get_free_size(MALLOC_CAP_SPIRAM), heap_caps_get_minimum_free_size(MALLOC_CAP_SPIRAM), heap_caps_get_largest_free_block(MALLOC_CAP_SPIRAM), heap_caps_get_free_size(MALLOC_CAP_DMA), heap_caps_get_minimum_free_size(MALLOC_CAP_DMA), heap_caps_get_largest_free_block(MALLOC_CAP_DMA)); return 0; } cJSON * setdevicename_cb(){ // char * default_host_name = config_alloc_get_str("host_name",NULL,"Squeezelite"); cJSON * values = cJSON_CreateObject(); // cJSON_AddStringToObject(values,"name",default_host_name); // free(default_host_name); // TODO: Add support for the commented code") return values; } static int setnamevar(char * nvsname, FILE *f, char * value){ esp_err_t err=ESP_OK; // if((err=config_set_value(NVS_TYPE_STR, nvsname, value))!=ESP_OK){ // fprintf(f,"Unable to set %s=%s. %s\n",nvsname,value,esp_err_to_name(err)); // } // TODO: Add support for the commented code") return err==ESP_OK?0:1; } typedef enum { SCANNING, PROCESSING_NAME } scanstate_t; int set_cspot_player_name(FILE * f,const char * name){ int ret=0; // cJSON * cspot_config = config_alloc_get_cjson("cspot_config"); // if(cspot_config==NULL){ // fprintf(f,"Unable to get cspot_config\n"); // return 1; // } // cJSON * player_name = cJSON_GetObjectItemCaseSensitive(cspot_config,"deviceName"); // if(player_name==NULL){ // fprintf(f,"Unable to get deviceName\n"); // ret=1; // } // if(strcmp(player_name->valuestring,name)==0){ // fprintf(f,"CSpot device name not changed.\n"); // ret=0; // } // else{ // cJSON_SetValuestring(player_name,name); // if(setnamevar("cspot_config",f,cJSON_Print(cspot_config))!=0){ // fprintf(f,"Unable to set cspot_config\n"); // ret=1; // } // else{ // fprintf(f,"CSpot device name set to %s\n",name); // } // } // cJSON_Delete(cspot_config); // TODO: Add support for the commented code") return ret; } int set_squeezelite_player_name(FILE * f,const char * name){ int nerrors=0; // TODO: Add support for the commented code") // char * nvs_config= config_alloc_get(NVS_TYPE_STR, "autoexec1"); // char **argv = NULL; // esp_err_t err=ESP_OK; // bool bFoundParm=false; // scanstate_t state=SCANNING; // char * newCommandLine = NULL; // char * parm = " -n "; // char * cleaned_name = strdup(name); // for(char * p=cleaned_name;*p!='\0';p++){ // if(*p == ' '){ // *p='_'; // no spaces allowed // } // } // if(nvs_config && strlen(nvs_config)>0){ // // allocate enough memory to hold the new command line // size_t cmdLength = strlen(nvs_config) + strlen(cleaned_name) + strlen(parm) +1 ; // newCommandLine = malloc_init_external(cmdLength); // ESP_LOGD(TAG,"Parsing command %s",nvs_config); // argv = (char **) malloc_init_external(22* sizeof(char *)); // if (argv == NULL) { // FREE_AND_NULL(nvs_config); // return 1; // } // size_t argc = esp_console_split_argv(nvs_config, argv,22); // for(int i=0;i0){ // strcat(newCommandLine," "); // } // switch (state) // { // case SCANNING: // strcat(newCommandLine,argv[i]); // if(strcasecmp(argv[i],"--name")==0 || strcasecmp(argv[i],"-n")==0 ){ // state = PROCESSING_NAME; // } // break; // case PROCESSING_NAME: // bFoundParm=true; // strcat(newCommandLine,cleaned_name); // state = SCANNING; // break; // default: // break; // } // } // if(!bFoundParm){ // strcat(newCommandLine,parm); // strcat(newCommandLine,name); // } // fprintf(f,"Squeezelite player name changed to %s\n",newCommandLine); // if((err=config_set_value(NVS_TYPE_STR, "autoexec1",newCommandLine))!=ESP_OK){ // nerrors++; // fprintf(f,"Failed updating squeezelite command. %s", esp_err_to_name(err)); // } // } // FREE_AND_NULL(nvs_config); // FREE_AND_NULL(argv); // free(cleaned_name); return nerrors; } static int setdevicename(int argc, char **argv) { bool changed = false; int nerrors = arg_parse_msg(argc, argv,(struct arg_hdr **)&names_args); if (nerrors != 0) { return 1; } if (names_args.device->count >0){ changed = changed | configurator_set_string(&sys_Names_msg,sys_Names_device_tag, &platform->names,names_args.device->sval[0]); } else { ESP_LOGE(TAG,"Device name must be specified"); return 1; } if (names_args.airplay->count >0){ changed = changed | configurator_set_string(&sys_Names_msg,sys_Names_airplay_tag, &platform->names,names_args.airplay->sval[0]); } if (names_args.bluetooth->count >0){ changed = changed | configurator_set_string(&sys_Names_msg,sys_Names_bluetooth_tag, &platform->names,names_args.bluetooth->sval[0]); } if (names_args.spotify->count >0){ changed = changed | configurator_set_string(&sys_Names_msg,sys_Names_spotify_tag, &platform->names,names_args.spotify->sval[0]); } if (names_args.squeezelite->count >0){ changed = changed | configurator_set_string(&sys_Names_msg,sys_Names_squeezelite_tag, &platform->names,names_args.squeezelite->sval[0]); } if (names_args.wifi_ap_name->count >0){ changed = changed | configurator_set_string(&sys_Names_msg,sys_Names_wifi_ap_name_tag, &platform->names,names_args.wifi_ap_name->sval[0]); } if (names_args.all->count >0){ ESP_LOGI(TAG,"Setting all names to %s", platform->names.device); changed = changed | configurator_set_string(&sys_Names_msg,sys_Names_airplay_tag, &platform->names,platform->names.device); changed = changed | configurator_set_string(&sys_Names_msg,sys_Names_bluetooth_tag, &platform->names,platform->names.device); changed = changed | configurator_set_string(&sys_Names_msg,sys_Names_spotify_tag, &platform->names,platform->names.device); changed = changed | configurator_set_string(&sys_Names_msg,sys_Names_squeezelite_tag, &platform->names,platform->names.device); changed = changed | configurator_set_string(&sys_Names_msg,sys_Names_wifi_ap_name_tag, &platform->names,platform->names.device); } if(changed){ ESP_LOGI(TAG,"Found change(s). Saving"); configurator_raise_changed(); } else { ESP_LOGW(TAG,"No change detected."); } return nerrors; } static void register_heap() { const esp_console_cmd_t heap_cmd = { .command = "heap", .help = "Get minimum size of free heap memory", .hint = NULL, .func = &heap_size, }; #if CONFIG_WITH_CONFIG_UI cmd_to_json(&heap_cmd); #endif ESP_ERROR_CHECK( esp_console_cmd_register(&heap_cmd) ); } static void register_dump_heap() { const esp_console_cmd_t heap_cmd = { .command = "dump_heap", .help = "Dumps the content of the heap to serial output", .hint = NULL, .func = &dump_heap, }; ESP_ERROR_CHECK( esp_console_cmd_register(&heap_cmd) ); } static void register_setdevicename() { char * default_host_name = platform->names.device; names_args.device = arg_str0("n", "device", default_host_name, "New Name"); names_args.airplay = arg_str0("a", "airplay", default_host_name, "New Airplay Device Name"); names_args.bluetooth = arg_str0("b", "bt", default_host_name, "New Bluetooth Device Name"); names_args.spotify = arg_str0("s", "spotify", default_host_name, "New Spotify Device Name"); names_args.squeezelite = arg_str0("l", "squeezelite", default_host_name, "New Squeezelite Player Name"); names_args.wifi_ap_name = arg_str0("w", "wifiap", default_host_name, "New Wifi AP Name"); names_args.all = arg_lit0(NULL, "all", "Set all names to device name"); names_args.end = arg_end(2); const esp_console_cmd_t set_name= { .command = CFG_TYPE_SYST("name"), .help="Device Name", .hint = NULL, .func = &setdevicename, .argtable = &names_args }; ESP_ERROR_CHECK(esp_console_cmd_register(&set_name)); } /** 'tasks' command prints the list of tasks and related information */ #if WITH_TASKS_INFO static int tasks_info(int argc, char **argv) { const size_t bytes_per_task = 40; /* see vTaskList description */ char *task_list_buffer = malloc_init_external(uxTaskGetNumberOfTasks() * bytes_per_task); if (task_list_buffer == NULL) { cmd_send_messaging(argv[0],MESSAGING_ERROR, "failed to allocate buffer for vTaskList output"); return 1; } cmd_send_messaging(argv[0],MESSAGING_INFO,"Task Name\tStatus\tPrio\tHWM\tTask#" #ifdef CONFIG_FREERTOS_VTASKLIST_INCLUDE_COREID "\tAffinity" #endif "\n"); vTaskList(task_list_buffer); cmd_send_messaging(argv[0],MESSAGING_INFO,"%s", task_list_buffer); free(task_list_buffer); return 0; } static void register_tasks() { const esp_console_cmd_t cmd = { .command = "tasks", .help = "Get information about running tasks", .hint = NULL, .func = &tasks_info, }; ESP_ERROR_CHECK( esp_console_cmd_register(&cmd) ); } #endif // WITH_TASKS_INFO /** 'deep_sleep' command puts the chip into deep sleep mode */ #if CONFIG_WITH_CONFIG_UI static struct { struct arg_int *wakeup_time; struct arg_int *wakeup_gpio_num; struct arg_int *wakeup_gpio_level; struct arg_end *end; } deep_sleep_args; static int deep_sleep(int argc, char **argv) { int nerrors = arg_parse_msg(argc, argv,(struct arg_hdr **)&deep_sleep_args); if (nerrors != 0) { return 1; } if (deep_sleep_args.wakeup_time->count) { uint64_t timeout = 1000ULL * deep_sleep_args.wakeup_time->ival[0]; cmd_send_messaging(argv[0],MESSAGING_INFO, "Enabling timer wakeup, timeout=%lluus", timeout); ESP_ERROR_CHECK( esp_sleep_enable_timer_wakeup(timeout) ); } if (deep_sleep_args.wakeup_gpio_num->count) { int io_num = deep_sleep_args.wakeup_gpio_num->ival[0]; if (!rtc_gpio_is_valid_gpio(io_num)) { cmd_send_messaging(argv[0],MESSAGING_ERROR, "GPIO %d is not an RTC IO", io_num); return 1; } int level = 0; if (deep_sleep_args.wakeup_gpio_level->count) { level = deep_sleep_args.wakeup_gpio_level->ival[0]; if (level != 0 && level != 1) { cmd_send_messaging(argv[0],MESSAGING_ERROR, "Invalid wakeup level: %d", level); return 1; } } cmd_send_messaging(argv[0],MESSAGING_INFO, "Enabling wakeup on GPIO%d, wakeup on %s level", io_num, level ? "HIGH" : "LOW"); ESP_ERROR_CHECK( esp_sleep_enable_ext1_wakeup(1ULL << io_num, level) ); } rtc_gpio_isolate(GPIO_NUM_12); esp_deep_sleep_start(); return 0; // this code will never run. deep sleep will cause the system to restart } static void register_deep_sleep() { deep_sleep_args.wakeup_time = arg_int0("t", "time", "", "Wake up time, ms"); deep_sleep_args.wakeup_gpio_num = arg_int0(NULL, "io", "", "If specified, wakeup using GPIO with given number"); deep_sleep_args.wakeup_gpio_level = arg_int0(NULL, "io_level", "<0|1>", "GPIO level to trigger wakeup"); deep_sleep_args.end = arg_end(3); const esp_console_cmd_t cmd = { .command = "deep_sleep", .help = "Enter deep sleep mode. ", .hint = NULL, .func = &deep_sleep, .argtable = &deep_sleep_args }; ESP_ERROR_CHECK( esp_console_cmd_register(&cmd) ); } #endif static int enable_disable(FILE * f,char * nvs_name, struct arg_lit *arg){ esp_err_t err = ESP_OK; // err= config_set_value(NVS_TYPE_STR, nvs_name, arg->count>0?"Y":"N"); // const char * name = arg->hdr.longopts?arg->hdr.longopts:arg->hdr.glossary; // if(err!=ESP_OK){ // fprintf(f,"Error %s %s. %s\n",arg->count>0?"Enabling":"Disabling", name, esp_err_to_name(err)); // } // else { // fprintf(f,"%s %s\n",arg->count>0?"Enabled":"Disabled",name); // } return err; } // static int do_set_services(int argc, char **argv) // { // esp_err_t err = ESP_OK; // int nerrors = arg_parse_msg(argc, argv,(struct arg_hdr **)&set_services_args); // if (nerrors != 0) { // return 1; // } // char *buf = NULL; // size_t buf_size = 0; // FILE *f = system_open_memstream(argv[0],&buf, &buf_size); // if (f == NULL) { // return 1; // } // nerrors += enable_disable(f,"enable_airplay",set_services_args.airplay); // nerrors += enable_disable(f,"enable_bt_sink",set_services_args.btspeaker); // #if CONFIG_CSPOT_SINK // nerrors += enable_disable(f,"enable_cspot",set_services_args.cspot); // #endif // if(set_services_args.telnet->count>0){ // // if(strcasecmp(set_services_args.telnet->sval[0],"Disabled") == 0){ // // err = config_set_value(NVS_TYPE_STR, "telnet_enable", "N"); // // } // // else if(strcasecmp(set_services_args.telnet->sval[0],"Telnet Only") == 0){ // // err = config_set_value(NVS_TYPE_STR, "telnet_enable", "Y"); // // } // // else if(strcasecmp(set_services_args.telnet->sval[0],"Telnet and Serial") == 0){ // // err = config_set_value(NVS_TYPE_STR, "telnet_enable", "D"); // // } // // TODO: Add support for the commented code") // if(err!=ESP_OK){ // nerrors++; // fprintf(f,"Error setting telnet to %s. %s\n",set_services_args.telnet->sval[0], esp_err_to_name(err)); // } // else { // fprintf(f,"Telnet service changed to %s\n",set_services_args.telnet->sval[0]); // } // } // #if WITH_TASKS_INFO // nerrors += enable_disable(f,"stats",set_services_args.stats); // #endif // if(!nerrors ){ // fprintf(f,"Done.\n"); // } // fflush (f); // cmd_send_messaging(argv[0],nerrors>0?MESSAGING_ERROR:MESSAGING_INFO,"%s", buf); // fclose(f); // FREE_AND_NULL(buf); // return nerrors; // } // cJSON * set_services_cb(){ // cJSON * values = cJSON_CreateObject(); // char * p=NULL; // console_set_bool_parameter(values,"enable_bt_sink",set_services_args.btspeaker); // console_set_bool_parameter(values,"enable_airplay",set_services_args.airplay); // #if CONFIG_CSPOT_SINK // console_set_bool_parameter(values,"enable_cspot",set_services_args.cspot); // #endif // #if WITH_TASKS_INFO // console_set_bool_parameter(values,"stats",set_services_args.stats); // #endif // // if ((p = config_alloc_get(NVS_TYPE_STR, "telnet_enable")) != NULL) { // // if(strcasestr("YX",p)!=NULL){ // // cJSON_AddStringToObject(values,set_services_args.telnet->hdr.longopts,"Telnet Only"); // // } // // else if(strcasestr("D",p)!=NULL){ // // cJSON_AddStringToObject(values,set_services_args.telnet->hdr.longopts,"Telnet and Serial"); // // } // // else { // // cJSON_AddStringToObject(values,set_services_args.telnet->hdr.longopts,"Disabled"); // // } // // #if defined(CONFIG_WITH_METRICS) // // metrics_add_feature_variant("telnet",p); // // #endif // // FREE_AND_NULL(p); // // } // // TODO: Add support for the commented code") // return values; // } // static void register_set_services(){ // set_services_args.airplay = arg_lit0(NULL, "AirPlay", "AirPlay"); // #if CONFIG_CSPOT_SINK // set_services_args.cspot = arg_lit0(NULL, "cspot", "Spotify (cspot)"); // #endif // set_services_args.btspeaker = arg_lit0(NULL, "BT_Speaker", "Bluetooth Speaker"); // set_services_args.telnet= arg_str0("t", "telnet","Disabled|Telnet Only|Telnet and Serial","Telnet server. Use only for troubleshooting"); // #if WITH_TASKS_INFO // set_services_args.stats= arg_lit0(NULL, "stats", "System Statistics. Use only for troubleshooting"); // #endif // set_services_args.end=arg_end(2); // const esp_console_cmd_t cmd = { // .command = CFG_TYPE_SYST("services"), // .help = "Services", // .argtable = &set_services_args, // .hint = NULL, // .func = &do_set_services, // }; // cmd_to_json_with_cb(&cmd,&set_services_cb); // ESP_ERROR_CHECK( esp_console_cmd_register(&cmd) ); // } #if CONFIG_WITH_CONFIG_UI static struct { struct arg_int *wakeup_time; struct arg_int *wakeup_gpio_num; struct arg_int *wakeup_gpio_level; struct arg_end *end; } light_sleep_args; static int light_sleep(int argc, char **argv) { int nerrors = arg_parse_msg(argc, argv,(struct arg_hdr **)&light_sleep_args); if (nerrors != 0) { return 1; } esp_sleep_disable_wakeup_source(ESP_SLEEP_WAKEUP_ALL); if (light_sleep_args.wakeup_time->count) { uint64_t timeout = 1000ULL * light_sleep_args.wakeup_time->ival[0]; cmd_send_messaging(argv[0],MESSAGING_INFO, "Enabling timer wakeup, timeout=%lluus", timeout); ESP_ERROR_CHECK( esp_sleep_enable_timer_wakeup(timeout) ); } int io_count = light_sleep_args.wakeup_gpio_num->count; if (io_count != light_sleep_args.wakeup_gpio_level->count) { cmd_send_messaging(argv[0],MESSAGING_INFO, "Should have same number of 'io' and 'io_level' arguments"); return 1; } for (int i = 0; i < io_count; ++i) { int io_num = light_sleep_args.wakeup_gpio_num->ival[i]; int level = light_sleep_args.wakeup_gpio_level->ival[i]; if (level != 0 && level != 1) { cmd_send_messaging(argv[0],MESSAGING_ERROR, "Invalid wakeup level: %d", level); return 1; } cmd_send_messaging(argv[0],MESSAGING_INFO, "Enabling wakeup on GPIO%d, wakeup on %s level", io_num, level ? "HIGH" : "LOW"); ESP_ERROR_CHECK( gpio_wakeup_enable(io_num, level ? GPIO_INTR_HIGH_LEVEL : GPIO_INTR_LOW_LEVEL) ); } if (io_count > 0) { ESP_ERROR_CHECK( esp_sleep_enable_gpio_wakeup() ); } if (CONFIG_ESP_CONSOLE_UART_NUM <= UART_NUM_1) { cmd_send_messaging(argv[0],MESSAGING_INFO, "Enabling UART wakeup (press ENTER to exit light sleep)"); ESP_ERROR_CHECK( uart_set_wakeup_threshold(CONFIG_ESP_CONSOLE_UART_NUM, 3) ); ESP_ERROR_CHECK( esp_sleep_enable_uart_wakeup(CONFIG_ESP_CONSOLE_UART_NUM) ); } fflush(stdout); esp_rom_uart_tx_wait_idle(CONFIG_ESP_CONSOLE_UART_NUM); esp_light_sleep_start(); esp_sleep_wakeup_cause_t cause = esp_sleep_get_wakeup_cause(); const char *cause_str; switch (cause) { case ESP_SLEEP_WAKEUP_GPIO: cause_str = "GPIO"; break; case ESP_SLEEP_WAKEUP_UART: cause_str = "UART"; break; case ESP_SLEEP_WAKEUP_TIMER: cause_str = "timer"; break; default: cause_str = "unknown"; printf("%d\n", cause); } cmd_send_messaging(argv[0],MESSAGING_INFO, "Woke up from: %s", cause_str); return 0; } static void register_light_sleep() { light_sleep_args.wakeup_time = arg_int0("t", "time", "", "Wake up time, ms"); light_sleep_args.wakeup_gpio_num = arg_intn(NULL, "io", "", 0, 8, "If specified, wakeup using GPIO with given number"); light_sleep_args.wakeup_gpio_level = arg_intn(NULL, "io_level", "<0|1>", 0, 8, "GPIO level to trigger wakeup"); light_sleep_args.end = arg_end(3); const esp_console_cmd_t cmd = { .command = "light_sleep", .help = "Enter light sleep mode. " "Two wakeup modes are supported: timer and GPIO. " "Multiple GPIO pins can be specified using pairs of " "'io' and 'io_level' arguments. " "Will also wake up on UART input.", .hint = NULL, .func = &light_sleep, .argtable = &light_sleep_args }; ESP_ERROR_CHECK( esp_console_cmd_register(&cmd) ); } #endif