squeezelite-esp32/components/platform_console/cmd_config.c

/* cmd_i2ctools.c

   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.
*/
//#define LOG_LOCAL_LEVEL ESP_LOG_DEBUG
#include <stdio.h>
#include "cmd_config.h"
#include "argtable3/argtable3.h"
#include "platform_console.h"
#include "esp_log.h"
#include "string.h"
#include "stdio.h"
#include "platform_config.h"
#include "trace.h"
#include "messaging.h"
#include "accessors.h"

const char * desc_squeezelite ="Squeezelite Options";
const char * desc_dac= "DAC Options";
const char * desc_spdif= "SPDIF Options";
const char * desc_audio= "General Audio Options";


#define CODECS_BASE "flac,pcm,mp3,ogg"
#if NO_FAAD
#define CODECS_AAC  ""
#else
#define CODECS_AAC  ",aac"
#endif
#if FFMPEG
#define CODECS_FF   ",wma,alac"
#else
#define CODECS_FF   ""
#endif
#if DSD
#define CODECS_DSD  ",dsd"
#else
#define CODECS_DSD  ""
#endif
#define CODECS_MP3  " (mad,mpg for specific mp3 codec)"

#define CODECS CODECS_BASE CODECS_AAC CODECS_FF CODECS_DSD CODECS_MP3
#define NOT_OUTPUT "has input capabilities only"
#define NOT_GPIO "is not a GPIO"

static const char *TAG = "cmd_config";
extern struct arg_end *getParmsEnd(struct arg_hdr * * argtable);
//bck=<gpio>,ws=<gpio>,do=<gpio>[,mute=<gpio>[:0|1][,model=TAS57xx|TAS5713|AC101|I2S][,sda=<gpio>,scl=gpio[,i2c=<addr>]]
static struct {
	struct arg_str *model_name;
    struct arg_int *clock;
    struct arg_int *wordselect;
    struct arg_int *data;
    struct arg_int *mute_gpio;
	struct arg_lit *mute_level;
    struct arg_int *dac_sda;
    struct arg_int *dac_scl;
    struct arg_int *dac_i2c;
	struct arg_lit *clear;
    struct arg_end *end;
} i2s_args;
static struct {
    struct arg_int *clock;
    struct arg_int *wordselect;
    struct arg_int *data;
	struct arg_lit *clear;	
    struct arg_end *end;
} spdif_args;
static struct {
    struct arg_str *jack_behavior;	
    struct arg_end *end;
} audio_args;
static struct {
	struct arg_str * server; // -s <server>[:<port>]\tConnect to specified server, otherwise uses autodiscovery to find server\n"
	struct arg_str * buffers;//			   "  -b <stream>:<output>\tSpecify internal Stream and Output buffer sizes in Kbytes\n"
	struct arg_str * codecs;//			   "  -c <codec1>,<codec2>\tRestrict codecs to those specified, otherwise load all available codecs; known codecs: " CODECS "\n"
	struct arg_int * timeout;//			   "  -C <timeout>\t\tClose output device when idle after timeout seconds, default is to keep it open while player is 'on'\n"
	struct arg_str * log_level; // "  -d <log>=<level>\tSet logging level, logs: all|slimproto|stream|decode|output|ir, level: info|debug|sdebug\n"
	// struct arg_str * log_level_all; // "  -d <log>=<level>\tSet logging level, logs: all|slimproto|stream|decode|output|ir, level: info|debug|sdebug\n"
	// struct arg_str * log_level_slimproto; // "  -d <log>=<level>\tSet logging level, logs: all|slimproto|stream|decode|output|ir, level: info|debug|sdebug\n"
	// struct arg_str * log_level_stream;
	// struct arg_str * log_level_decode;
	// struct arg_str * log_level_output;
	#if IR
	struct arg_str * log_level_ir;
	#endif
	struct arg_str * output_device; // "  -d <log>=<level>\tSet logging level, logs: all|slimproto|stream|decode|output|ir, level: info|debug|sdebug\n"
	//			   "  -e <codec1>,<codec2>\tExplicitly exclude native support of one or more codecs; known codecs: " CODECS "\n"
	//			   "  -f <logfile>\t\tWrite debug to logfile\n"
	//	#if IR
	//			   "  -i [<filename>]\tEnable lirc remote control support (lirc config file ~/.lircrc used if filename not specified)\n"
	//	#endif
	struct arg_str * mac_addr; //			   "  -m <mac addr>\t\tSet mac address, format: ab:cd:ef:12:34:56\n"
	struct arg_str * model_name;//			   "  -M <modelname>\tSet the squeezelite player model name sent to the server (default: " MODEL_NAME_STRING ")\n"
	struct arg_str * name;//			   "  -n <name>\t\tSet the player name\n"
	struct arg_lit * header_format;//			   "  -W\t\t\tRead wave and aiff format from header, ignore server parameters\n"
	struct arg_str * rates; //			   "  -r <rates>[:<delay>]\tSample rates supported, allows output to be off when squeezelite is started; rates = <maxrate>|<minrate>-<maxrate>|<rate1>,<rate2>,<rate3>; delay = optional delay switching rates in ms\n"
	#if RESAMPLE
	struct arg_lit * resample;
	struct arg_str * resample_parms; //"  -R -u [params]\tResample, params = <recipe>:<flags>:<attenuation>:<precision>:<passband_end>:<stopband_start>:<phase_response>,\n"
	#endif
	#if RESAMPLE16
	struct arg_lit * resample;
	struct arg_str * resample_parms; //" -R -u [params]\tResample, params = (b|l|m)[:i],\n"
	//			   "   \t\t\t b = basic linear interpolation, l = 13 taps, m = 21 taps, i = interpolate filter coefficients\n"
	#endif
	struct arg_int * rate;//			   "  -Z <rate>\t\tReport rate to server in helo as the maximum sample rate we can support\n"

    struct arg_end *end;
} squeezelite_args;

int is_output_gpio(struct arg_int * gpio, FILE * f, int * gpio_out, bool mandatory){
	int res = 0;
	const char * name = gpio->hdr.longopts?gpio->hdr.longopts:gpio->hdr.glossary;
	*gpio_out=-1;
	int t_gpio=gpio->ival[0];
	if(gpio->count==0){
		if(mandatory){
			fprintf(f,"Missing: %s\n", name);
			res++;
		}
	} else  if(!GPIO_IS_VALID_OUTPUT_GPIO(t_gpio)){
		fprintf(f,"Invalid %s gpio: [%d] %s\n",name, t_gpio, GPIO_IS_VALID_GPIO(t_gpio)?NOT_OUTPUT:NOT_GPIO );
		res++;
	}
	else{
		*gpio_out = t_gpio;
	}
	return res;
}

int check_missing_parm(struct arg_int * int_parm, FILE * f){
	int res=0;
	const char * name = int_parm->hdr.longopts?int_parm->hdr.longopts:int_parm->hdr.glossary;
	if(int_parm->count==0){
		fprintf(f,"Missing: %s\n", name);
		res++;
	} 
	return res;
}
	
static int do_audio_cmd(int argc, char **argv){
	esp_err_t err=ESP_OK;
	int nerrors = arg_parse(argc, argv,(void **)&audio_args);
	char *buf = NULL;
	size_t buf_size = 0;
	FILE *f = open_memstream(&buf, &buf_size);
	if (f == NULL) {
		cmd_send_messaging(argv[0],MESSAGING_ERROR,"Unable to open memory stream.\n");
		return 1;
	}
	if(nerrors >0){
		arg_print_errors(f,audio_args.end,desc_audio);
		return 1;
	}

    if(audio_args.jack_behavior->count>0){
        err = ESP_OK; // suppress any error code that might have happened in a previous step
        if(strcasecmp(audio_args.jack_behavior->sval[0],"Headphones")){
            err = config_set_value(NVS_TYPE_STR, "jack_mutes_amp", "y");
        }
        else if(strcasecmp(audio_args.jack_behavior->sval[0],"Subwoofer")){
            err = config_set_value(NVS_TYPE_STR, "jack_mutes_amp", "n");
        }
        else {
            nerrors++;
            fprintf(f,"Unknown Audio Jack Behavior %s.\n",audio_args.jack_behavior->sval[0]);
        }

        if(err!=ESP_OK){
            nerrors++;
            fprintf(f,"Error setting Audio Jack Behavior %s. %s\n",audio_args.jack_behavior->sval[0], esp_err_to_name(err));
        }
        else {
            fprintf(f,"Audio Jack Behavior changed to %s\n",audio_args.jack_behavior->sval[0]);
        }        
    }

	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==0 && err==ESP_OK)?0:1;
}
static int do_spdif_cmd(int argc, char **argv){
		i2s_platform_config_t i2s_dac_pin = {
		.i2c_addr = -1,
		.sda= -1,
		.scl = -1,
		.mute_gpio = -1,
		.mute_level = -1
	};
	if(is_spdif_config_locked()){
		cmd_send_messaging(argv[0],MESSAGING_ERROR,"SPDIF Configuration is locked on this platform\n");
		return 1;
	}
	esp_err_t err=ESP_OK;
	int nerrors = arg_parse(argc, argv,(void **)&spdif_args);
	if (spdif_args.clear->count) {
		cmd_send_messaging(argv[0],MESSAGING_WARNING,"SPDIF config cleared\n");
		config_set_value(NVS_TYPE_STR, "spdif_config", "");
		return 0;
	}

	char *buf = NULL;
	size_t buf_size = 0;
	FILE *f = open_memstream(&buf, &buf_size);
	if (f == NULL) {
		cmd_send_messaging(argv[0],MESSAGING_ERROR,"Unable to open memory stream.\n");
		return 1;
	}
	if(nerrors >0){
		arg_print_errors(f,spdif_args.end,desc_dac);
		return 1;
	}
	nerrors+=is_output_gpio(spdif_args.clock, f, &i2s_dac_pin.pin.bck_io_num, true);
	nerrors+=is_output_gpio(spdif_args.wordselect, f, &i2s_dac_pin.pin.ws_io_num, true);
	nerrors+=is_output_gpio(spdif_args.data, f, &i2s_dac_pin.pin.data_out_num, true);
	if(!nerrors ){
		fprintf(f,"Storing SPDIF parameters.\n");
		nerrors+=(config_spdif_set(&i2s_dac_pin )!=ESP_OK);
	}
	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==0 && err==ESP_OK)?0:1;
}

static int do_i2s_cmd(int argc, char **argv)
{
	i2s_platform_config_t i2s_dac_pin = {
		.i2c_addr = -1,
		.sda= -1,
		.scl = -1,
		.mute_gpio = -1,
		.mute_level = -1
	};
	if(is_dac_config_locked()){
		cmd_send_messaging(argv[0],MESSAGING_ERROR,"DAC Configuration is locked on this platform\n");
		return 1;
	}
	strcpy(i2s_dac_pin.model, "I2S");

	esp_err_t err=ESP_OK;
	int nerrors = arg_parse(argc, argv,(void **)&i2s_args);
	if (i2s_args.clear->count) {
		cmd_send_messaging(argv[0],MESSAGING_WARNING,"DAC config cleared\n");
		config_set_value(NVS_TYPE_STR, "dac_config", "");
		return 0;
	}

	char *buf = NULL;
	size_t buf_size = 0;
	FILE *f = open_memstream(&buf, &buf_size);
	if (f == NULL) {
		cmd_send_messaging(argv[0],MESSAGING_ERROR,"Unable to open memory stream.\n");
		return 1;
	}
	if(nerrors >0){
		arg_print_errors(f,i2s_args.end,desc_dac);
		return 1;
	}
	nerrors+=is_output_gpio(i2s_args.clock, f, &i2s_dac_pin.pin.bck_io_num, true);
	nerrors+=is_output_gpio(i2s_args.wordselect, f, &i2s_dac_pin.pin.ws_io_num, true);
	nerrors+=is_output_gpio(i2s_args.data, f, &i2s_dac_pin.pin.data_out_num, true);
	nerrors+=is_output_gpio(i2s_args.mute_gpio, f, &i2s_dac_pin.mute_gpio, false);
	if(i2s_dac_pin.mute_gpio>0){
		i2s_dac_pin.mute_level = i2s_args.mute_level->count>0?1:0;
	}
	if(i2s_args.dac_sda->count>0 && i2s_args.dac_sda->ival[0]>=0){
		// if SDA specified, then SDA and SCL are both mandatory
		nerrors+=is_output_gpio(i2s_args.dac_sda, f, &i2s_dac_pin.sda, false);
		nerrors+=is_output_gpio(i2s_args.dac_scl, f, &i2s_dac_pin.scl, false);
	}
	if(i2s_args.dac_sda->count==0&& i2s_args.dac_i2c->count>0){
		fprintf(f,"warning: ignoring i2c address, since dac i2c gpios config is incomplete\n");
	}
	else if(i2s_args.dac_i2c->count>0){
		i2s_dac_pin.i2c_addr = i2s_args.dac_i2c->ival[0];
	}
	if(i2s_args.model_name->count>0 && strlen(i2s_args.model_name->sval[0])>0){
		strncpy(i2s_dac_pin.model,i2s_args.model_name->sval[0],sizeof(i2s_dac_pin.model));
	}
	if(!nerrors ){
		fprintf(f,"Storing i2s parameters.\n");
		 nerrors+=(config_i2s_set(&i2s_dac_pin, "dac_config")!=ESP_OK);
	}
	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==0 && err==ESP_OK)?0:1;
}

cJSON * example_cb(){
	cJSON * values = cJSON_CreateObject();
//	int i2c_port;
//	const i2c_config_t * i2c= config_i2c_get(&i2c_port);
//	if(i2c->scl_io_num>0) {
//		cJSON_AddNumberToObject(values,"scl",i2c->scl_io_num);
//	}
//	if(i2c->sda_io_num>0) {
//		cJSON_AddNumberToObject(values,"sda",i2c->sda_io_num);
//	}
//	if(i2c->master.clk_speed>0) {
//		cJSON_AddNumberToObject(values,"freq",i2c->master.clk_speed);
//	}
//	if(i2c_port>0) {
//		cJSON_AddNumberToObject(values,"port",i2c_port);
//	}
	return values;
}

//const i2s_pin_config_t * 	config_get_spdif_pin_struct( );

cJSON * i2s_cb(){
	cJSON * values = cJSON_CreateObject();
	const i2s_platform_config_t * i2s_conf= 	config_dac_get( );
	if(i2s_conf->pin.bck_io_num>0 ) {
		cJSON_AddNumberToObject(values,"clock",i2s_conf->pin.bck_io_num);
	}
	if(i2s_conf->pin.ws_io_num>=0 ) {
		cJSON_AddNumberToObject(values,"wordselect",i2s_conf->pin.ws_io_num);
	}
	if(i2s_conf->pin.data_out_num>=0 ) {
		cJSON_AddNumberToObject(values,"data",i2s_conf->pin.data_out_num);
	}
	if(i2s_conf->sda>=0 ) {
		cJSON_AddNumberToObject(values,"dac_sda",i2s_conf->sda);
	}
	if(i2s_conf->scl>=0 ) {
		cJSON_AddNumberToObject(values,"dac_scl",i2s_conf->scl);
	}	
	if(i2s_conf->i2c_addr>=0 ) {
		cJSON_AddNumberToObject(values,"dac_i2c",i2s_conf->i2c_addr);
	}		
	if(i2s_conf->mute_gpio>=0 ) {
		cJSON_AddNumberToObject(values,"mute_gpio",i2s_conf->mute_gpio);
	}		
	if(i2s_conf->mute_level>=0 ) {
		cJSON_AddBoolToObject(values,"mute_level",i2s_conf->mute_level>0);
	}		
	if(strlen(i2s_conf->model)>0){
		cJSON_AddStringToObject(values,"model_name",i2s_conf->model);
	}
	else {
		cJSON_AddStringToObject(values,"model_name","I2S");
	}
	
	return values;
}
cJSON * spdif_cb(){
	cJSON * values = cJSON_CreateObject();
	const i2s_platform_config_t * spdif_conf= 	config_spdif_get( );
	if(spdif_conf->pin.bck_io_num>0 ) {
		cJSON_AddNumberToObject(values,"clock",spdif_conf->pin.bck_io_num);
	}
	if(spdif_conf->pin.ws_io_num>=0 ) {
		cJSON_AddNumberToObject(values,"wordselect",spdif_conf->pin.ws_io_num);
	}
	if(spdif_conf->pin.data_out_num>=0 ) {
		cJSON_AddNumberToObject(values,"data",spdif_conf->pin.data_out_num);
	}
		
	return values;
}
cJSON * audio_cb(){
	cJSON * values = cJSON_CreateObject();
	char * 	p = config_alloc_get_default(NVS_TYPE_STR, "jack_mutes_amp", "n", 0);
    cJSON_AddBoolToObject(values,"jack_behavior",(strcmp(p,"1") == 0 ||strcasecmp(p,"y") == 0));
    FREE_AND_NULL(p);    
	return values;
}


void get_str_parm_json(struct arg_str * parm, cJSON * entry){
	const char * name = parm->hdr.longopts?parm->hdr.longopts:parm->hdr.glossary;
	if(parm->count>0){
		cJSON_AddStringToObject(entry,name,parm->sval[0]);
	}
}
void get_file_parm_json(struct arg_file * parm, cJSON * entry){
	const char * name = parm->hdr.longopts?parm->hdr.longopts:parm->hdr.glossary;
	if(parm->count>0){
		cJSON_AddStringToObject(entry,name,parm->filename[0]);
	}
}
void get_lit_parm_json(struct arg_lit * parm, cJSON * entry){
	const char * name = parm->hdr.longopts?parm->hdr.longopts:parm->hdr.glossary;
	cJSON_AddBoolToObject(entry,name,(parm->count>0));
}
void get_int_parm_json(struct arg_int * parm, cJSON * entry){
	const char * name = parm->hdr.longopts?parm->hdr.longopts:parm->hdr.glossary;
	if(parm->count>0){
		cJSON_AddNumberToObject(entry,name,parm->ival[0]);
	}
}

static int do_squeezelite_cmd(int argc, char **argv)
{
	esp_err_t err=ESP_OK;
	int nerrors = arg_parse_msg(argc, argv,(struct arg_hdr ** )&squeezelite_args);
    char *buf = NULL;
	size_t buf_size = 0;
	FILE *f = open_memstream(&buf, &buf_size);
	if (f == NULL) {
		cmd_send_messaging(argv[0],MESSAGING_ERROR,"Unable to open memory stream.\n");
		return 1;
	}
	fprintf(f,"Not yet implemented!");
	nerrors+=1;
	fflush (f);
	cmd_send_messaging(argv[0],nerrors>0?MESSAGING_ERROR:MESSAGING_INFO,"%s", buf);
	fclose(f);
	FREE_AND_NULL(buf);
	return (nerrors==0 && err==ESP_OK)?0:1;
}

cJSON * squeezelite_cb(){
	cJSON * values = cJSON_CreateObject();
	char * nvs_config= config_alloc_get(NVS_TYPE_STR, "autoexec1");
	char **argv = NULL;
	char *buf = NULL;
	size_t buf_size = 0;
    int nerrors=1;
	FILE *f = open_memstream(&buf, &buf_size);
	if (f == NULL) {
		log_send_messaging(MESSAGING_ERROR,"Unable to parse squeezelite parameters");
	}
	else {

		if(nvs_config && strlen(nvs_config)>0){
			ESP_LOGD(TAG,"Parsing command %s",nvs_config);
			argv = (char **) calloc(22, sizeof(char *));
			if (argv == NULL) {
				FREE_AND_NULL(nvs_config);
				return values;
			}
			size_t argc = esp_console_split_argv(nvs_config, argv,22);
			if (argc != 0) {
				nerrors = arg_parse(argc, argv,(void **)&squeezelite_args);
				ESP_LOGD(TAG,"Parsing completed");
			}
		}
		if (nerrors == 0) {
			get_str_parm_json(squeezelite_args.buffers, values);
			get_str_parm_json(squeezelite_args.codecs, values);
			get_lit_parm_json(squeezelite_args.header_format, values);
			get_str_parm_json(squeezelite_args.log_level, values);
			
			// get_str_parm_json(squeezelite_args.log_level_all, values);
			// get_str_parm_json(squeezelite_args.log_level_decode, values);
			// get_str_parm_json(squeezelite_args.log_level_output, values);
			// get_str_parm_json(squeezelite_args.log_level_slimproto, values);
			// get_str_parm_json(squeezelite_args.log_level_stream, values);
			get_str_parm_json(squeezelite_args.mac_addr, values);
			get_str_parm_json(squeezelite_args.output_device, values);
			get_str_parm_json(squeezelite_args.model_name, values);
			get_str_parm_json(squeezelite_args.name, values);
			get_int_parm_json(squeezelite_args.rate, values);
			get_str_parm_json(squeezelite_args.rates, values);
			get_str_parm_json(squeezelite_args.server, values);
			get_int_parm_json(squeezelite_args.timeout, values);
			char * p = cJSON_Print(values);
			ESP_LOGD(TAG,"%s",p);
			free(p);
		}
		else {
			arg_print_errors(f, squeezelite_args.end, desc_squeezelite);
		}
		fflush (f);
		if(strlen(buf)>0){
			log_send_messaging(nerrors?MESSAGING_ERROR:MESSAGING_INFO,"%s", buf);
		}
		fclose(f);
		FREE_AND_NULL(buf);
	}
	FREE_AND_NULL(nvs_config);
	FREE_AND_NULL(argv);
	return values;
}
static char * get_log_level_options(const char * longname){
	const char * template = "<%s=info|%s=debug|%s=sdebug>";
	char * options = NULL;
	int len = snprintf(NULL,0,template,longname,longname,longname);
	if(len>0){
		options = malloc(len+1);
		snprintf(options,len,template,longname,longname,longname);
	}
	return options;
}
static void register_i2s_config(void){
	i2s_args.model_name = arg_str1(NULL,"model_name","TAS57xx|TAS5713|AC101|I2S","DAC Model Name");
	i2s_args.clear = arg_lit0(NULL, "clear", "Clear configuration");
    i2s_args.clock = arg_int1(NULL,"clock","<n>","Clock GPIO. e.g. 33");
    i2s_args.wordselect = arg_int1(NULL,"wordselect","<n>","Word Select GPIO. e.g. 25");
    i2s_args.data = arg_int1(NULL,"data","<n>","Data GPIO. e.g. 32");
    i2s_args.mute_gpio = arg_int0(NULL,"mute_gpio", "<n>", "Mute GPIO. e.g. 14");
	i2s_args.mute_level = arg_lit0(NULL,"mute_level","Mute GPIO level. Checked=HIGH, Unchecked=LOW");
    i2s_args.dac_sda = arg_int0(NULL,"dac_sda", "<n>", "SDA GPIO. e.g. 27");
    i2s_args.dac_scl = arg_int0(NULL,"dac_scl", "<n>", "SCL GPIO. e.g. 26");
    i2s_args.dac_i2c = arg_int0(NULL,"dac_i2c", "<n>", "I2C device address. e.g. 106");
    i2s_args.end = arg_end(6);

	 const esp_console_cmd_t cmd = {
        .command = CFG_TYPE_HW("dac"),
        .help = desc_dac,
        .hint = NULL,
        .func = &do_i2s_cmd,
        .argtable = &i2s_args
    };
    cmd_to_json_with_cb(&cmd,&i2s_cb);
    ESP_ERROR_CHECK(esp_console_cmd_register(&cmd));
}


static void register_audio_config(void){
	audio_args.jack_behavior = arg_str0("j", "jack_behavior","Headphones|Subwoofer","On supported DAC, determines the audio jack behavior. Selecting headphones will cause the external amp to be muted on insert, while selecting Subwoofer will keep the amp active all the time.");
    audio_args.end = arg_end(6);
	const esp_console_cmd_t cmd = {
        .command = CFG_TYPE_AUDIO("general"),
        .help = desc_audio,
        .hint = NULL,
        .func = &do_audio_cmd,
        .argtable = &audio_args
    };
    cmd_to_json_with_cb(&cmd,&audio_cb);
    ESP_ERROR_CHECK(esp_console_cmd_register(&cmd));
}static void register_spdif_config(void){
	spdif_args.clear = arg_lit0(NULL, "clear", "Clear configuration");
    spdif_args.clock = arg_int1(NULL,"clock","<n>","Clock GPIO. e.g. 33");
    spdif_args.wordselect = arg_int1(NULL,"wordselect","<n>","Word Select GPIO. e.g. 25");
    spdif_args.data = arg_int1(NULL,"data","<n>","Data GPIO. e.g. 32");
    spdif_args.end = arg_end(6);

	 const esp_console_cmd_t cmd = {
        .command = CFG_TYPE_HW("spdif"),
        .help = desc_spdif,
        .hint = NULL,
        .func = &do_spdif_cmd,
        .argtable = &spdif_args
    };
    cmd_to_json_with_cb(&cmd,&spdif_cb);
    ESP_ERROR_CHECK(esp_console_cmd_register(&cmd));
}
static void register_squeezelite_config(void){
	squeezelite_args.server = arg_str0("s","server","<server>[:<port>]","Connect to specified server, otherwise uses autodiscovery to find server");
	squeezelite_args.buffers = arg_str0("b","buffers","<stream>:<output>","Internal Stream and Output buffer sizes in Kbytes");
	squeezelite_args.codecs = arg_strn("c","codecs","<codec1>,<codec2>",0,20,"Restrict codecs to those specified, otherwise load all available codecs; known codecs");
	squeezelite_args.timeout = arg_int0("C","timeout","<n>","Close output device when idle after timeout seconds, default is to keep it open while player is 'on");
	squeezelite_args.log_level = arg_str0("d","loglevel","log=level","Set logging level, logs: all|slimproto|stream|decode|output|ir, level: info|debug|sdebug"); // "  -d <log>=<level>\tSet logging level, logs: all|slimproto|stream|decode|output|ir, level: info|debug|sdebug\n"
//	squeezelite_args.log_level_all = arg_str0(NULL,"all",get_log_level_options("all"),"Overall Logging Level");
//	squeezelite_args.log_level_slimproto = arg_str0(NULL,"loglevel_slimproto",get_log_level_options("slimproto"),"Slimproto Logging Level");
//	squeezelite_args.log_level_stream= arg_str0(NULL,"loglevel_stream",get_log_level_options("stream"),"Stream Logging Level");
//	squeezelite_args.log_level_decode= arg_str0(NULL,"loglevel_decode",get_log_level_options("decode"),"Decode Logging Level");
//	squeezelite_args.log_level_output= arg_str0(NULL,"loglevel_output",get_log_level_options("output"),"Output Logging Level");
	#if IR
	squeezelite_args.log_level_ir= arg_str0(NULL,"loglevel_ir",get_log_level_options("ir"),"IR Logging Level");
	#endif

	squeezelite_args.output_device = arg_str0("o","output_device","<string>","Output device");
	squeezelite_args.mac_addr = arg_str0("m","mac_addr","<string>","Mac address, format: ab:cd:ef:12:34:56");
	squeezelite_args.model_name = arg_str0("M", "modelname", "<string>","Squeezelite player model name sent to the server");
	squeezelite_args.name = arg_str0("n","name","<string>","Player name");
	squeezelite_args.header_format = arg_lit0("W","header_format","Read wave and aiff format from header, ignore server parameters");
	squeezelite_args.rates = arg_str0("r","rates","<rates>[:<delay>]", "Sample rates supported, allows output to be off when squeezelite is started; rates = <maxrate>|<minrate>-<maxrate>|<rate1>,<rate2>,<rate3>; delay = optional delay switching rates in ms\n");
	#if RESAMPLE
	squeezelite_args.resample = arg_lit0("R","resample","Activate Resample");
	squeezelite_args.resample_parms = arg_str0("u","resample_parms","<recipe>:<flags>:<attenuation>:<precision>:<passband_end>:<stopband_start>:<phase_response>","Resample, params");
	#endif
	#if RESAMPLE16
	squeezelite_args.resample = arg_lit0("R","resample","Activate Resample");
	squeezelite_args.resample_parms = arg_str0("u","resample_parms","(b|l|m)[:i]","Resample, params. b = basic linear interpolation, l = 13 taps, m = 21 taps, i = interpolate filter coefficients");
	#endif
	squeezelite_args.rate = arg_int0("Z","max_rate", "<n>", "Report rate to server in helo as the maximum sample rate we can support");
	squeezelite_args.end = arg_end(6);
    const esp_console_cmd_t cmd = {
        .command = CFG_TYPE_AUDIO("squeezelite"),
        .help = desc_squeezelite,
        .hint = NULL,
        .func = &do_squeezelite_cmd,
        .argtable = &squeezelite_args
    };
    cmd_to_json_with_cb(&cmd,&squeezelite_cb);
    ESP_ERROR_CHECK(esp_console_cmd_register(&cmd));
}

void register_config_cmd(void){
	register_audio_config();
	register_squeezelite_config();
	register_i2s_config();
	register_spdif_config();
}