int main(int argc, char **argv) {
// memtrack();
atomicinit();
gc_attach(main_gc);
/* Catch all exit signals for gc */
gc_catch();
log_shell_enable();
log_file_disable();
log_level_set(LOG_NOTICE);
if((progname = MALLOC(16)) == NULL) {
fprintf(stderr, "out of memory\n");
exit(EXIT_FAILURE);
}
strcpy(progname, "pilight-receive");
struct options_t *options = NULL;
struct ssdp_list_t *ssdp_list = NULL;
char *server = NULL;
unsigned short port = 0;
unsigned short stats = 0;
char *args = NULL;
options_add(&options, 'H', "help", OPTION_NO_VALUE, 0, JSON_NULL, NULL, NULL);
options_add(&options, 'V', "version", OPTION_NO_VALUE, 0, JSON_NULL, NULL, NULL);
options_add(&options, 'S', "server", OPTION_HAS_VALUE, 0, JSON_NULL, NULL, "^(([0-9]|[1-9][0-9]|1[0-9]{2}|2[0-4][0-9]|25[0-5]).){3}([0-9]|[1-9][0-9]|1[0-9]{2}|2[0-4][0-9]|25[0-5])$");
options_add(&options, 'P', "port", OPTION_HAS_VALUE, 0, JSON_NULL, NULL, "[0-9]{1,4}");
options_add(&options, 's', "stats", OPTION_NO_VALUE, 0, JSON_NULL, NULL, "[0-9]{1,4}");
/* Store all CLI arguments for later usage
and also check if the CLI arguments where
used correctly by the user. This will also
fill all necessary values in the options struct */
while(1) {
int c;
c = options_parse(&options, argc, argv, 1, &args);
if(c == -1)
break;
if(c == -2)
c = 'H';
switch(c) {
case 'H':
printf("\t -H --help\t\t\tdisplay this message\n");
printf("\t -V --version\t\t\tdisplay version\n");
printf("\t -S --server=x.x.x.x\t\tconnect to server address\n");
printf("\t -P --port=xxxx\t\t\tconnect to server port\n");
printf("\t -s --stats\t\t\tshow CPU and RAM statistics\n");
exit(EXIT_SUCCESS);
break;
case 'V':
printf("%s v%s\n", progname, PILIGHT_VERSION);
exit(EXIT_SUCCESS);
break;
case 'S':
if((server = MALLOC(strlen(args)+1)) == NULL) {
fprintf(stderr, "out of memory\n");
exit(EXIT_FAILURE);
}
strcpy(server, args);
break;
case 'P':
port = (unsigned short)atoi(args);
break;
case 's':
stats = 1;
break;
default:
printf("Usage: %s -l location -d device\n", progname);
exit(EXIT_SUCCESS);
break;
}
}
options_delete(options);
if(server != NULL && port > 0) {
if((sockfd = socket_connect(server, port)) == -1) {
logprintf(LOG_ERR, "could not connect to pilight-daemon");
return EXIT_FAILURE;
}
} else if(ssdp_seek(&ssdp_list) == -1) {
logprintf(LOG_NOTICE, "no pilight ssdp connections found");
goto close;
} else {
if((sockfd = socket_connect(ssdp_list->ip, ssdp_list->port)) == -1) {
logprintf(LOG_ERR, "could not connect to pilight-daemon");
goto close;
}
}
if(ssdp_list != NULL) {
ssdp_free(ssdp_list);
}
if(server != NULL) {
FREE(server);
}
struct JsonNode *jclient = json_mkobject();
struct JsonNode *joptions = json_mkobject();
json_append_member(jclient, "action", json_mkstring("identify"));
json_append_member(joptions, "receiver", json_mknumber(1, 0));
json_append_member(joptions, "stats", json_mknumber(stats, 0));
json_append_member(jclient, "options", joptions);
char *out = json_stringify(jclient, NULL);
socket_write(sockfd, out);
json_free(out);
json_delete(jclient);
if(socket_read(sockfd, &recvBuff, 0) != 0 ||
strcmp(recvBuff, "{\"status\":\"success\"}") != 0) {
goto close;
}
while(main_loop) {
if(socket_read(sockfd, &recvBuff, 0) != 0) {
goto close;
}
char **array = NULL;
unsigned int n = explode(recvBuff, "\n", &array), i = 0;
for(i=0;i<n;i++) {
struct JsonNode *jcontent = json_decode(array[i]);
struct JsonNode *jtype = json_find_member(jcontent, "type");
if(jtype != NULL) {
json_remove_from_parent(jtype);
json_delete(jtype);
}
char *content = json_stringify(jcontent, "\t");
printf("%s\n", content);
json_delete(jcontent);
json_free(content);
}
array_free(&array, n);
}
close:
if(sockfd > 0) {
socket_close(sockfd);
}
if(recvBuff != NULL) {
FREE(recvBuff);
recvBuff = NULL;
}
options_gc();
log_shell_disable();
log_gc();
FREE(progname);
return EXIT_SUCCESS;
}
int main(int argc, char **argv) {
// memtrack();
atomicinit();
gc_attach(main_gc);
/* Catch all exit signals for gc */
gc_catch();
log_shell_enable();
log_file_disable();
log_level_set(LOG_NOTICE);
struct options_t *options = NULL;
char *p = NULL;
char *args = NULL;
if((progname = MALLOC(13)) == NULL) {
fprintf(stderr, "out of memory\n");
exit(EXIT_FAILURE);
}
strcpy(progname, "pilight-uuid");
options_add(&options, 'H', "help", OPTION_NO_VALUE, 0, JSON_NULL, NULL, NULL);
options_add(&options, 'V', "version", OPTION_NO_VALUE, 0, JSON_NULL, NULL, NULL);
while (1) {
int c;
c = options_parse(&options, argc, argv, 1, &args);
if(c == -1)
break;
if(c == -2)
c = 'H';
switch (c) {
case 'H':
printf("Usage: %s [options]\n", progname);
printf("\t -H --help\t\tdisplay usage summary\n");
printf("\t -V --version\t\tdisplay version\n");
return (EXIT_SUCCESS);
break;
case 'V':
printf("%s v%s\n", progname, PILIGHT_VERSION);
return (EXIT_SUCCESS);
break;
default:
printf("Usage: %s [options]\n", progname);
return (EXIT_FAILURE);
break;
}
}
options_delete(options);
int nrdevs = 0, x = 0;
char **devs = NULL;
if((nrdevs = inetdevs(&devs)) > 0) {
for(x=0;x<nrdevs;x++) {
if((p = genuuid(devs[x])) == NULL) {
logprintf(LOG_ERR, "could not generate the device uuid");
} else {
strcpy(pilight_uuid, p);
FREE(p);
break;
}
}
}
array_free(&devs, nrdevs);
printf("%s\n", pilight_uuid);
main_gc();
return (EXIT_FAILURE);
}
int main(int argc, char **argv)
{
unsigned short port = 0;
char* server = NULL;
unsigned short stats = 0;
struct ssdp_list_t *ssdp_list = NULL;
atomicinit();
gc_attach(main_gc);
gc_catch();
if(server != NULL && port > 0) {
if((sockfd = socket_connect(server, port)) == -1){
printf("error: could not connect to pilight-daemon\n");
return EXIT_FAILURE;
}
}
else if(ssdp_seek(&ssdp_list) == -1){
printf("error: no pilight ssdp connections found\n");
goto close;
}
else{
if((sockfd = socket_connect(ssdp_list->ip, ssdp_list->port)) == -1){
printf("error: could not connect to pilight-daemon\n");
goto close;
}
}
if(ssdp_list != NULL)
ssdp_free(ssdp_list);
if(server != NULL)
FREE(server);
struct JsonNode *jclient = json_mkobject();
struct JsonNode *joptions = json_mkobject();
json_append_member(jclient, "action", json_mkstring("identify"));
json_append_member(joptions, "receiver", json_mknumber(1, 0));
json_append_member(joptions, "stats", json_mknumber(stats, 0));
json_append_member(jclient, "options", joptions);
char *out = json_stringify(jclient, NULL);
socket_write(sockfd, out);
json_free(out);
json_delete(jclient);
if(socket_read(sockfd, &recvBuff, 0)!=0 || strcmp(recvBuff, "{\"status\":\"success\"}")!=0)
goto close;
if(iniInit("config.ini")) // get values from config.ini
goto close;
display(0, 0, 0); // init display
unsigned short filteropt = 1;
int lastmin = -1, firstrx = 0;
while(main_loop){
if(socket_read(sockfd, &recvBuff, 0) != 0)
goto close;
char **array = NULL;
unsigned int n = explode(recvBuff, "\n", &array), i = 0;
for(i=0; i<n; i++){
struct JsonNode *jcontent = json_decode(array[i]);
struct JsonNode *jtype = json_find_member(jcontent, "type");
if(jtype != NULL){
json_remove_from_parent(jtype);
json_delete(jtype);
}
if(filteropt == 1){
char *pr = NULL;
double id = 0.0;
double ch = 0.0;
struct JsonNode *jmessage = json_find_member(jcontent, "message");
json_find_string(jcontent, "protocol", &pr);
json_find_number(jmessage, "id", &id);
json_find_number(jmessage, "channel", &ch);
int j = 0;
for(j=0; j<stations; j++){ // step through protocol filters
if(strcmp(station[j].pr, "-")==0 || strcmp(station[j].pr, pr)==0){ // protocol not specified or found
if(j == 0){ // datetime protocol is the first
if(firstrx){
double min = 0.0;
json_find_number(jmessage, "minute", &min);
if((int)min != lastmin){
display(-1, 0.0, 0.0);
lastmin = (int)min;
}
}
}
else if(strcmp(station[j].id, "-")==0 || (int)id==atoi(station[j].id)){ // id not specified or found
if(strcmp(station[j].ch, "-")==0 || (int)ch==atoi(station[j].ch)){ // channel not specified or found
double temp = 0.0, humi = 0.0;
json_find_number(jmessage, "temperature", &temp);
json_find_number(jmessage, "humidity", &humi);
display(j-1, temp, humi);
firstrx = 1;
break;
}
}
}
}
}
else{
char *content = json_stringify(jcontent, "\t");
printf("%s\n", content);
json_free(content);
}
json_delete(jcontent);
}
array_free(&array, n);
}
close:
if(sockfd > 0)
socket_close(sockfd);
if(recvBuff != NULL){
FREE(recvBuff);
recvBuff = NULL;
}
iniClean();
return EXIT_SUCCESS;
}
int main(int argc, char **argv) {
// memtrack();
atomicinit();
struct options_t *options = NULL;
struct ssdp_list_t *ssdp_list = NULL;
struct devices_t *dev = NULL;
struct JsonNode *json = NULL;
struct JsonNode *tmp = NULL;
char *recvBuff = NULL, *message = NULL, *output = NULL;
char *device = NULL, *state = NULL, *values = NULL;
char *server = NULL;
int has_values = 0, sockfd = 0, hasconfarg = 0;
unsigned short port = 0, showhelp = 0, showversion = 0;
log_file_disable();
log_shell_enable();
log_level_set(LOG_NOTICE);
#ifndef _WIN32
wiringXLog = logprintf;
#endif
if((progname = MALLOC(16)) == NULL) {
fprintf(stderr, "out of memory\n");
exit(EXIT_FAILURE);
}
strcpy(progname, "pilight-control");
/* Define all CLI arguments of this program */
options_add(&options, 'H', "help", OPTION_NO_VALUE, 0, JSON_NULL, NULL, NULL);
options_add(&options, 'V', "version", OPTION_NO_VALUE, 0, JSON_NULL, NULL, NULL);
options_add(&options, 'd', "device", OPTION_HAS_VALUE, 0, JSON_NULL, NULL, NULL);
options_add(&options, 's', "state", OPTION_HAS_VALUE, 0, JSON_NULL, NULL, NULL);
options_add(&options, 'v', "values", OPTION_HAS_VALUE, 0, JSON_NULL, NULL, NULL);
options_add(&options, 'S', "server", OPTION_HAS_VALUE, 0, JSON_NULL, NULL, "^(([0-9]|[1-9][0-9]|1[0-9]{2}|2[0-4][0-9]|25[0-5]).){3}([0-9]|[1-9][0-9]|1[0-9]{2}|2[0-4][0-9]|25[0-5])$");
options_add(&options, 'P', "port", OPTION_HAS_VALUE, 0, JSON_NULL, NULL, "[0-9]{1,4}");
options_add(&options, 'C', "config", OPTION_HAS_VALUE, 0, JSON_NULL, NULL, NULL);
/* Store all CLI arguments for later usage
and also check if the CLI arguments where
used correctly by the user. This will also
fill all necessary values in the options struct */
while(1) {
int c;
c = options_parse(&options, argc, argv, 1, &optarg);
if(c == -1)
break;
if(c == -2) {
showhelp = 1;
break;
}
switch(c) {
case 'H':
showhelp = 1;
break;
case 'V':
showversion = 1;
break;
case 'd':
if((device = REALLOC(device, strlen(optarg)+1)) == NULL) {
fprintf(stderr, "out of memory\n");
exit(EXIT_FAILURE);
}
strcpy(device, optarg);
break;
case 's':
if((state = REALLOC(state, strlen(optarg)+1)) == NULL) {
fprintf(stderr, "out of memory\n");
exit(EXIT_FAILURE);
}
strcpy(state, optarg);
break;
case 'v':
if((values = REALLOC(values, strlen(optarg)+1)) == NULL) {
fprintf(stderr, "out of memory\n");
exit(EXIT_FAILURE);
}
strcpy(values, optarg);
break;
case 'C':
if(config_set_file(optarg) == EXIT_FAILURE) {
return EXIT_FAILURE;
}
hasconfarg = 1;
break;
case 'S':
if(!(server = REALLOC(server, strlen(optarg)+1))) {
fprintf(stderr, "out of memory\n");
exit(EXIT_FAILURE);
}
strcpy(server, optarg);
break;
case 'P':
port = (unsigned short)atoi(optarg);
break;
default:
printf("Usage: %s -l location -d device -s state\n", progname);
goto close;
break;
}
}
options_delete(options);
if(showversion == 1) {
printf("%s v%s\n", progname, PILIGHT_VERSION);
goto close;
}
if(showhelp == 1) {
printf("\t -H --help\t\t\tdisplay this message\n");
printf("\t -V --version\t\t\tdisplay version\n");
printf("\t -S --server=x.x.x.x\t\tconnect to server address\n");
printf("\t -C --config\t\t\tconfig file\n");
printf("\t -P --port=xxxx\t\t\tconnect to server port\n");
printf("\t -d --device=device\t\tthe device that you want to control\n");
printf("\t -s --state=state\t\tthe new state of the device\n");
printf("\t -v --values=values\t\tspecific comma separated values, e.g.:\n");
printf("\t\t\t\t\t-v dimlevel=10\n");
goto close;
}
if(device == NULL || state == NULL ||
strlen(device) == 0 || strlen(state) == 0) {
printf("Usage: %s -d device -s state\n", progname);
goto close;
}
if(server && port > 0) {
if((sockfd = socket_connect(server, port)) == -1) {
logprintf(LOG_ERR, "could not connect to pilight-daemon");
goto close;
}
} else if(ssdp_seek(&ssdp_list) == -1) {
logprintf(LOG_NOTICE, "no pilight ssdp connections found");
goto close;
} else {
if((sockfd = socket_connect(ssdp_list->ip, ssdp_list->port)) == -1) {
logprintf(LOG_ERR, "could not connect to pilight-daemon");
goto close;
}
}
if(ssdp_list) {
ssdp_free(ssdp_list);
}
protocol_init();
config_init();
if(hasconfarg == 1) {
if(config_read() != EXIT_SUCCESS) {
goto close;
}
}
socket_write(sockfd, "{\"action\":\"identify\"}");
if(socket_read(sockfd, &recvBuff, 0) != 0
|| strcmp(recvBuff, "{\"status\":\"success\"}") != 0) {
goto close;
}
json = json_mkobject();
json_append_member(json, "action", json_mkstring("request config"));
output = json_stringify(json, NULL);
socket_write(sockfd, output);
json_free(output);
json_delete(json);
if(socket_read(sockfd, &recvBuff, 0) == 0) {
if(json_validate(recvBuff) == true) {
json = json_decode(recvBuff);
if(json_find_string(json, "message", &message) == 0) {
if(strcmp(message, "config") == 0) {
struct JsonNode *jconfig = NULL;
if((jconfig = json_find_member(json, "config")) != NULL) {
int match = 1;
while(match) {
struct JsonNode *jchilds = json_first_child(jconfig);
match = 0;
while(jchilds) {
if(strcmp(jchilds->key, "devices") != 0) {
json_remove_from_parent(jchilds);
tmp = jchilds;
match = 1;
}
jchilds = jchilds->next;
if(tmp != NULL) {
json_delete(tmp);
}
tmp = NULL;
}
}
config_parse(jconfig);
if(devices_get(device, &dev) == 0) {
JsonNode *joutput = json_mkobject();
JsonNode *jcode = json_mkobject();
JsonNode *jvalues = json_mkobject();
json_append_member(jcode, "device", json_mkstring(device));
if(values != NULL) {
char **array = NULL;
unsigned int n = explode(values, ",=", &array), q = 0;
for(q=0;q<n;q+=2) {
char *name = MALLOC(strlen(array[q])+1);
if(name == NULL) {
logprintf(LOG_ERR, "out of memory\n");
exit(EXIT_FAILURE);
}
strcpy(name, array[q]);
if(q+1 == n) {
array_free(&array, n);
logprintf(LOG_ERR, "\"%s\" is missing a value for device \"%s\"", name, device);
FREE(name);
break;
} else {
char *val = MALLOC(strlen(array[q+1])+1);
if(val == NULL) {
logprintf(LOG_ERR, "out of memory\n");
exit(EXIT_FAILURE);
}
strcpy(val, array[q+1]);
if(devices_valid_value(device, name, val) == 0) {
if(isNumeric(val) == EXIT_SUCCESS) {
json_append_member(jvalues, name, json_mknumber(atof(val), nrDecimals(val)));
} else {
json_append_member(jvalues, name, json_mkstring(val));
}
has_values = 1;
} else {
logprintf(LOG_ERR, "\"%s\" is an invalid value for device \"%s\"", name, device);
array_free(&array, n);
FREE(name);
json_delete(json);
goto close;
}
}
FREE(name);
}
array_free(&array, n);
}
if(devices_valid_state(device, state) == 0) {
json_append_member(jcode, "state", json_mkstring(state));
} else {
logprintf(LOG_ERR, "\"%s\" is an invalid state for device \"%s\"", state, device);
json_delete(json);
goto close;
}
if(has_values == 1) {
json_append_member(jcode, "values", jvalues);
} else {
json_delete(jvalues);
}
json_append_member(joutput, "action", json_mkstring("control"));
json_append_member(joutput, "code", jcode);
output = json_stringify(joutput, NULL);
socket_write(sockfd, output);
json_free(output);
json_delete(joutput);
if(socket_read(sockfd, &recvBuff, 0) != 0
|| strcmp(recvBuff, "{\"status\":\"success\"}") != 0) {
logprintf(LOG_ERR, "failed to control %s", device);
}
} else {
logprintf(LOG_ERR, "the device \"%s\" does not exist", device);
json_delete(json);
goto close;
}
}
}
}
json_delete(json);
}
}
close:
if(recvBuff) {
FREE(recvBuff);
}
if(sockfd > 0) {
socket_close(sockfd);
}
if(server != NULL) {
FREE(server);
}
if(device != NULL) {
FREE(device);
}
if(state != NULL) {
FREE(state);
}
if(values != NULL) {
FREE(values);
}
log_shell_disable();
socket_gc();
config_gc();
protocol_gc();
options_gc();
#ifdef EVENTS
events_gc();
#endif
dso_gc();
log_gc();
threads_gc();
gc_clear();
FREE(progname);
xfree();
#ifdef _WIN32
WSACleanup();
#endif
return EXIT_SUCCESS;
}
