void dataAvailable(struct dummy_packet * received, uint8_t src_addr){
uint8_t i;
for(i=0; i< MAX_SERVER_SOCK_NUM; i++){
// TODO: check if socket is still connected.
if (data_request[i]){
stream_set_sock(i);
fprintf(&sock_stream, "%u :: ", src_addr);
send_result(received);
}
}
sock_stream_flush();
}
void net_dataAvailable(struct dummy_packet * received, uint8_t src_addr){
// This function is called, everytime, a set o measurement results from
// one collector board was successfully received.
uint8_t i;
// make a backup of currently active socket
// as we have to switch socket to db socket
uint8_t currSock = stream_get_sock();
// flush the active socket here?
sock_stream_flush();
//puts_P(PSTR("."));
// send data to the database, if required:
if(cfg.send_db){
net_sendResultToDB(received, src_addr);
//puts_P(PSTR(","));
}
// now send data to user intrefaces, if they requested so:
for(i=0; i< MAX_SERVER_SOCK_NUM; i++){
if (data_request[i]){
if(W5100.readSnSR(i+FIRST_SERVER_SOCK) == SnSR::ESTABLISHED){
stream_set_sock(i+FIRST_SERVER_SOCK);
fprintf_P(&sock_stream, PSTR("\n%u :: "), src_addr);
send_result(received);
sock_stream_flush();
}else{
// if no the requesting client is already disconnected,
// remove him from the request list:
data_request[i] = 0;
}
}
}
//puts_P(PSTR("-"));
// restore socket:
stream_set_sock(currSock);
}
void handle_db_response(){
// Couchdb will send responses after receiving json documents.
// we have to receive these in order for the w5100 receive buffer
// not to overflow.
// Alternatively we can just clear the whole receive queue, as
// receiving the whole data will take a lot of time
//
// here both approaches are implemented, as it might be useful to see
// the database response for debugging. In this case, the response
// can be redirected to the TCP user interface (redirect_flag)
uint8_t b;
uint8_t index;
uint8_t content_flag = 0;
uint8_t redirect_flag = 0;
for(index = 0; index< MAX_SERVER_SOCK_NUM; index++){
if(db_response_request[index]){
redirect_flag = 1;
}
}
if(redirect_flag == 0){
// if no one wants to have the data, we can just clear the whole socket receive buffer.
net_clear_rcv_buf(DB_CLIENT_SOCK);
}else{
// if at leat one wants to have the DB response redirected,
// we receive byte by byte and forward them to the apropriate user interface:
// Do not need to backup the current socket here, because it is not in serve function
while(recv(DB_CLIENT_SOCK, &b, 1) > 0){
content_flag = 1;
for(index = 0; index< MAX_SERVER_SOCK_NUM; index++){
if(db_response_request[index]){
stream_set_sock(index+FIRST_SERVER_SOCK);
fputc(b, &sock_stream);
sock_stream_flush();
}
}
}
if(!content_flag){
// no data was available:
return;
}
}
}
void net_sendResultToDB(struct dummy_packet *packets, uint8_t board_addr){
// Sends a set of 8 measurement results to the couchdb database
int8_t sensor_index;
int8_t comma_flag = 0;
int16_t value;
uint16_t len=0;
PORTB &= ~(1<<PB1);
PORTD &= ~(1<<PD5);
if( W5100.readSnSR(DB_CLIENT_SOCK) != SnSR::ESTABLISHED ){
if(!connect_db(cfg.port+1)){
return;
}
}
// Calculate length for the JSON header:
for (sensor_index=0; sensor_index<8; sensor_index++){
if(packets[sensor_index].header.error && packets[sensor_index].header.connected){
// We do not send data, which might have an error
continue;
}
if(packets[sensor_index].header.connected){
switch(packets[sensor_index].header.type){
case PACKET_TYPE_TSIC:
len += JSON_TEMP_LEN;
// length of "," or "}" at the end
len++;
break;
case PACKET_TYPE_HYT:
// There is no difference in temperature length
// for HYT and TSIC.
len += JSON_TEMP_LEN;
len++;
len += JSON_HUM_LEN;
len++;
break;
default:
break;
}
}
}
PORTB |= (1<<PB1);
if(len==0){
return;
}
len+=JSON_PREFIX_LEN;
// length of "}" at the end
len++;
// Now we start sending data to couchdb
stream_set_sock(DB_CLIENT_SOCK);
net_sendHeadToDB(len);
#ifdef DEBUG
printf_P(PSTR("Send Head \n\r"));
#endif
/* convert packet data to json format
* {"type":"value","data",{"bdddsdTEMP":"ddd.dd","bdddsdHUM":"ddd.dd"}}
*/
fputs_P(PSTR(JSON_PREFIX), &sock_stream);
#ifdef DEBUG
printf_P(PSTR("Send PREFIX \n\r"));
#endif
comma_flag = 0;
//puts_P(PSTR("+"));
PORTB &= ~(1<<PB1);
PORTD |= (1<<PD5);
for (sensor_index=0;sensor_index<8;sensor_index++){
if(packets[sensor_index].header.error && packets[sensor_index].header.connected){
continue;
}
if(packets[sensor_index].header.connected){
switch(packets[sensor_index].header.type){
case PACKET_TYPE_TSIC:
if(comma_flag){
fputc(',', &sock_stream);
}else{
comma_flag = 1;
}
value = ((struct tsic_packet *)(packets))[sensor_index].temperature;
fprintf_P(&sock_stream, PSTR(JSON_TEMP), JSON_OUTPUT);
#ifdef DEBUG
printf_P(PSTR("Send temperature \n\r"));
#endif
break;
case PACKET_TYPE_HYT:
if(comma_flag){
fputc(',', &sock_stream);
}else{
comma_flag = 1;
}
value = ((struct hyt_packet *)(packets))[sensor_index].temperature;
fprintf_P(&sock_stream, PSTR(JSON_TEMP), JSON_OUTPUT);
value = ((struct hyt_packet *)(packets) )[sensor_index].humidity;
fputc(',', &sock_stream);
fprintf_P(&sock_stream, PSTR(JSON_HUM), JSON_OUTPUT);
break;
default:
break;
}
}
}
fputc('}', &sock_stream);
fputc('}', &sock_stream);
#ifdef DEBUG
printf_P(PSTR("Send finished \n\r"));
#endif
sock_stream_flush();
PORTB |= (1<<PB1);
}
