fd
Dependents: xtoff3 CYS_Receiver
Fork of RF24Network by
Diff: RF24Network.cpp
- Revision:
- 3:dfc8da7ac18c
- Parent:
- 2:a5f8e04bd02b
- Child:
- 4:75c5aa56411f
- Child:
- 6:80195a45b25c
--- a/RF24Network.cpp Thu Nov 05 05:40:44 2015 +0000 +++ b/RF24Network.cpp Thu Nov 05 05:54:47 2015 +0000 @@ -6,33 +6,18 @@ version 2 as published by the Free Software Foundation. */ -#include "RF24Network_config.h" - - - - - - +/* +* Mbed support added by Akash Vibhute <akash.roboticist@gmail.com> +* Porting completed on Nov/05/2015 +* +* Updated with TMRh20's RF24 library on Nov/04/2015 from https://github.com/TMRh20 +* +*/ - - - - - - - - +#include "RF24Network_config.h" #include <RF24.h> #include "RF24Network.h" - - - - - - - - uint16_t RF24NetworkHeader::next_id = 1; #if defined ENABLE_NETWORK_STATS uint32_t RF24Network::nFails = 0; @@ -45,85 +30,78 @@ bool is_valid_address( uint16_t node ); /******************************************************************/ - - - - - - - - #if !defined (DUAL_HEAD_RADIO) -RF24Network::RF24Network( RF24& _radio ): radio(_radio), next_frame(frame_queue) +RF24Network::RF24Network( RF24& _radio ): radio(_radio), next_frame(frame_queue) { - #if !defined ( DISABLE_FRAGMENTATION ) - frag_queue.message_buffer=&frag_queue_message_buffer[0]; - frag_ptr = &frag_queue; - #endif +#if !defined ( DISABLE_FRAGMENTATION ) + frag_queue.message_buffer=&frag_queue_message_buffer[0]; + frag_ptr = &frag_queue; +#endif } #else RF24Network::RF24Network( RF24& _radio, RF24& _radio1 ): radio(_radio), radio1(_radio1), next_frame(frame_queue) { - #if !defined ( DISABLE_FRAGMENTATION ) - frag_queue.message_buffer=&frag_queue_message_buffer[0]; - frag_ptr = &frag_queue; - #endif +#if !defined ( DISABLE_FRAGMENTATION ) + frag_queue.message_buffer=&frag_queue_message_buffer[0]; + frag_ptr = &frag_queue; +#endif } #endif /******************************************************************/ void RF24Network::begin(uint8_t _channel, uint16_t _node_address ) { -rf24netTimer.start(); -if (! is_valid_address(_node_address) ) - return; - - node_address = _node_address; + rf24netTimer.start(); + if (! is_valid_address(_node_address) ) + return; - if ( ! radio.isValid() ){ - return; - } + node_address = _node_address; + + if ( ! radio.isValid() ) { + return; + } - // Set up the radio the way we want it to look - if(_channel != USE_CURRENT_CHANNEL){ - radio.setChannel(_channel); - } - //radio.enableDynamicAck(); - radio.setAutoAck(0,0); - - #if defined (ENABLE_DYNAMIC_PAYLOADS) - radio.enableDynamicPayloads(); - #endif - - // Use different retry periods to reduce data collisions - uint8_t retryVar = (((node_address % 6)+1) *2) + 3; - radio.setRetries(retryVar, 5); - txTimeout = 25; - routeTimeout = txTimeout*9; // Adjust for max delay per node + // Set up the radio the way we want it to look + if(_channel != USE_CURRENT_CHANNEL) { + radio.setChannel(_channel); + } + //radio.enableDynamicAck(); + radio.setAutoAck(0,0); + +#if defined (ENABLE_DYNAMIC_PAYLOADS) + radio.enableDynamicPayloads(); +#endif + + // Use different retry periods to reduce data collisions + uint8_t retryVar = (((node_address % 6)+1) *2) + 3; + radio.setRetries(retryVar, 5); + txTimeout = 25; + routeTimeout = txTimeout*9; // Adjust for max delay per node #if defined (DUAL_HEAD_RADIO) - radio1.setChannel(_channel); - radio1.enableDynamicAck(); - radio1.enableDynamicPayloads(); + radio1.setChannel(_channel); + radio1.enableDynamicAck(); + radio1.enableDynamicPayloads(); #endif - // Setup our address helper cache - setup_address(); + // Setup our address helper cache + setup_address(); - // Open up all listening pipes - uint8_t i = 6; - while (i--){ - radio.openReadingPipe(i,pipe_address(_node_address,i)); - } - radio.startListening(); - + // Open up all listening pipes + uint8_t i = 6; + while (i--) { + radio.openReadingPipe(i,pipe_address(_node_address,i)); + } + radio.startListening(); + } /******************************************************************/ #if defined ENABLE_NETWORK_STATS -void RF24Network::failures(uint32_t *_fails, uint32_t *_ok){ +void RF24Network::failures(uint32_t *_fails, uint32_t *_ok) +{ *_fails = nFails; *_ok = nOK; } @@ -133,71 +111,64 @@ uint8_t RF24Network::update(void) { - // if there is data ready - uint8_t pipe_num; - uint8_t returnVal = 0; - - // If bypass is enabled, continue although incoming user data may be dropped - // Allows system payloads to be read while user cache is full - // Incoming Hold prevents data from being read from the radio, preventing incoming payloads from being acked - + // if there is data ready + uint8_t pipe_num; + uint8_t returnVal = 0; + + // If bypass is enabled, continue although incoming user data may be dropped + // Allows system payloads to be read while user cache is full + // Incoming Hold prevents data from being read from the radio, preventing incoming payloads from being acked + - if(!(networkFlags & FLAG_BYPASS_HOLDS)){ - if( (networkFlags & FLAG_HOLD_INCOMING) || (next_frame-frame_queue) + 34 > MAIN_BUFFER_SIZE ){ - if(!available()){ - networkFlags &= ~FLAG_HOLD_INCOMING; - }else{ - return 0; - } + if(!(networkFlags & FLAG_BYPASS_HOLDS)) { + if( (networkFlags & FLAG_HOLD_INCOMING) || (next_frame-frame_queue) + 34 > MAIN_BUFFER_SIZE ) { + if(!available()) { + networkFlags &= ~FLAG_HOLD_INCOMING; + } else { + return 0; + } + } } - } + - - while ( radio.isValid() && radio.available(&pipe_num) ){ + while ( radio.isValid() && radio.available(&pipe_num) ) { - #if defined (ENABLE_DYNAMIC_PAYLOADS) - if( (frame_size = radio.getDynamicPayloadSize() ) < sizeof(RF24NetworkHeader)){ - wait_ms(10); - continue; - } - #else - frame_size=32; - #endif - // Dump the payloads until we've gotten everything - // Fetch the payload, and see if this was the last one. - radio.read( frame_buffer, frame_size ); - - // Read the beginning of the frame as the header - RF24NetworkHeader *header = (RF24NetworkHeader*)(&frame_buffer); - +#if defined (ENABLE_DYNAMIC_PAYLOADS) + if( (frame_size = radio.getDynamicPayloadSize() ) < sizeof(RF24NetworkHeader)) { + wait_ms(10); + continue; + } +#else + frame_size=32; +#endif + // Dump the payloads until we've gotten everything + // Fetch the payload, and see if this was the last one. + radio.read( frame_buffer, frame_size ); + + // Read the beginning of the frame as the header + RF24NetworkHeader *header = (RF24NetworkHeader*)(&frame_buffer); + + IF_SERIAL_DEBUG(printf_P(PSTR("%lu: MAC Received on %u %s\n\r"),millis(),pipe_num,header->toString())); + IF_SERIAL_DEBUG(const uint16_t* i = reinterpret_cast<const uint16_t*>(frame_buffer + sizeof(RF24NetworkHeader)); printf_P(PSTR("%lu: NET message %04x\n\r"),millis(),*i)); - - - - - - - IF_SERIAL_DEBUG(printf_P(PSTR("%lu: MAC Received on %u %s\n\r"),millis(),pipe_num,header->toString())); - IF_SERIAL_DEBUG(const uint16_t* i = reinterpret_cast<const uint16_t*>(frame_buffer + sizeof(RF24NetworkHeader));printf_P(PSTR("%lu: NET message %04x\n\r"),millis(),*i)); + + // Throw it away if it's not a valid address + if ( !is_valid_address(header->to_node) ) { + continue; + } + + uint8_t returnVal = header->type; - - // Throw it away if it's not a valid address - if ( !is_valid_address(header->to_node) ){ - continue; - } - - uint8_t returnVal = header->type; + // Is this for us? + if ( header->to_node == node_address ) { - // Is this for us? - if ( header->to_node == node_address ){ - - if(header->type == NETWORK_PING){ - continue; + if(header->type == NETWORK_PING) { + continue; } - if(header->type == NETWORK_ADDR_RESPONSE ){ - uint16_t requester = frame_buffer[8]; + if(header->type == NETWORK_ADDR_RESPONSE ) { + uint16_t requester = frame_buffer[8]; requester |= frame_buffer[9] << 8; - if(requester != node_address){ + if(requester != node_address) { header->to_node = requester; write(header->to_node,USER_TX_TO_PHYSICAL_ADDRESS); wait_ms(10); @@ -206,361 +177,213 @@ continue; } } - if(header->type == NETWORK_REQ_ADDRESS && node_address){ + if(header->type == NETWORK_REQ_ADDRESS && node_address) { //printf("Fwd add req to 0\n"); header->from_node = node_address; header->to_node = 0; write(header->to_node,TX_NORMAL); continue; } - - if( (returnSysMsgs && header->type > 127) || header->type == NETWORK_ACK ){ + + if( (returnSysMsgs && header->type > 127) || header->type == NETWORK_ACK ) { //IF_SERIAL_DEBUG_ROUTING( printf_P(PSTR("%lu MAC: System payload rcvd %d\n"),millis(),returnVal); ); //if( (header->type < 148 || header->type > 150) && header->type != NETWORK_MORE_FRAGMENTS_NACK && header->type != EXTERNAL_DATA_TYPE && header->type!= NETWORK_LAST_FRAGMENT){ - if( header->type != NETWORK_FIRST_FRAGMENT && header->type != NETWORK_MORE_FRAGMENTS && header->type != NETWORK_MORE_FRAGMENTS_NACK && header->type != EXTERNAL_DATA_TYPE && header->type!= NETWORK_LAST_FRAGMENT){ + if( header->type != NETWORK_FIRST_FRAGMENT && header->type != NETWORK_MORE_FRAGMENTS && header->type != NETWORK_MORE_FRAGMENTS_NACK && header->type != EXTERNAL_DATA_TYPE && header->type!= NETWORK_LAST_FRAGMENT) { return returnVal; } } - if( enqueue(header) == 2 ){ //External data received - #if defined (SERIAL_DEBUG_MINIMAL) - printf("ret ext\n"); - #endif - return EXTERNAL_DATA_TYPE; + if( enqueue(header) == 2 ) { //External data received +#if defined (SERIAL_DEBUG_MINIMAL) + printf("ret ext\n"); +#endif + return EXTERNAL_DATA_TYPE; } - }else{ + } else { - #if defined (RF24NetworkMulticast) +#if defined (RF24NetworkMulticast) - if( header->to_node == 0100){ - + if( header->to_node == 0100) { - if(header->type == NETWORK_POLL ){ + + if(header->type == NETWORK_POLL ) { //Serial.println("Send poll"); header->to_node = header->from_node; - header->from_node = node_address; + header->from_node = node_address; //delay((node_address%5)*3); write(header->to_node,USER_TX_TO_PHYSICAL_ADDRESS); continue; } uint8_t val = enqueue(header); - - if(multicastRelay){ + + if(multicastRelay) { //IF_SERIAL_DEBUG_ROUTING( printf_P(PSTR("%u MAC: FWD multicast frame from 0%o to level %u\n"),millis(),header->from_node,multicast_level+1); ); write(levelToAddress(multicast_level)<<3,4); } - if( val == 2 ){ //External data received - //Serial.println("ret ext multicast"); + if( val == 2 ) { //External data received + //Serial.println("ret ext multicast"); return EXTERNAL_DATA_TYPE; } - }else{ + } else { write(header->to_node,1); //Send it on, indicate it is a routed payload } - #else - write(header->to_node,1); //Send it on, indicate it is a routed payload - #endif - } - - } - return returnVal; +#else + write(header->to_node,1); //Send it on, indicate it is a routed payload +#endif + } + + } + return returnVal; } - - -/******************************************************************/ - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -/******************************************************************/ -/******************************************************************/ - - // Not defined RF24_Linux: - -/******************************************************************/ /******************************************************************/ uint8_t RF24Network::enqueue(RF24NetworkHeader* header) { - bool result = false; - uint8_t message_size = frame_size - sizeof(RF24NetworkHeader); - - IF_SERIAL_DEBUG(printf_P(PSTR("%lu: NET Enqueue @%x "),millis(),next_frame-frame_queue)); - -#if !defined ( DISABLE_FRAGMENTATION ) + bool result = false; + uint8_t message_size = frame_size - sizeof(RF24NetworkHeader); + + IF_SERIAL_DEBUG(printf_P(PSTR("%lu: NET Enqueue @%x "),millis(),next_frame-frame_queue)); + +#if !defined ( DISABLE_FRAGMENTATION ) - bool isFragment = header->type == NETWORK_FIRST_FRAGMENT || header->type == NETWORK_MORE_FRAGMENTS || header->type == NETWORK_LAST_FRAGMENT || header->type == NETWORK_MORE_FRAGMENTS_NACK ; + bool isFragment = header->type == NETWORK_FIRST_FRAGMENT || header->type == NETWORK_MORE_FRAGMENTS || header->type == NETWORK_LAST_FRAGMENT || header->type == NETWORK_MORE_FRAGMENTS_NACK ; - if(isFragment){ + if(isFragment) { - if(header->type == NETWORK_FIRST_FRAGMENT){ - // Drop frames exceeding max size and duplicates (MAX_PAYLOAD_SIZE needs to be divisible by 24) - if(header->reserved > (MAX_PAYLOAD_SIZE / max_frame_payload_size) ){ + if(header->type == NETWORK_FIRST_FRAGMENT) { + // Drop frames exceeding max size and duplicates (MAX_PAYLOAD_SIZE needs to be divisible by 24) + if(header->reserved > (MAX_PAYLOAD_SIZE / max_frame_payload_size) ) { - #if defined (SERIAL_DEBUG_FRAGMENTATION) || defined (SERIAL_DEBUG_MINIMAL) - printf_P(PSTR("Frag frame with %d frags exceeds MAX_PAYLOAD_SIZE or out of sequence\n"),header->reserved); - #endif - frag_queue.header.reserved = 0; - return false; - }else - if(frag_queue.header.id == header->id && frag_queue.header.from_node == header->from_node){ +#if defined (SERIAL_DEBUG_FRAGMENTATION) || defined (SERIAL_DEBUG_MINIMAL) + printf_P(PSTR("Frag frame with %d frags exceeds MAX_PAYLOAD_SIZE or out of sequence\n"),header->reserved); +#endif + frag_queue.header.reserved = 0; + return false; + } else if(frag_queue.header.id == header->id && frag_queue.header.from_node == header->from_node) { + return true; + } + + if( (header->reserved * 24) > (MAX_PAYLOAD_SIZE - (next_frame-frame_queue)) ) { + networkFlags |= FLAG_HOLD_INCOMING; + radio.stopListening(); + } + + memcpy(&frag_queue,&frame_buffer,8); + memcpy(frag_queue.message_buffer,frame_buffer+sizeof(RF24NetworkHeader),message_size); + +//IF_SERIAL_DEBUG_FRAGMENTATION( Serial.print(F("queue first, total frags ")); Serial.println(header->reserved); ); + //Store the total size of the stored frame in message_size + frag_queue.message_size = message_size; + --frag_queue.header.reserved; + + IF_SERIAL_DEBUG_FRAGMENTATION_L2( for(int i=0; i<frag_queue.message_size; i++) { + Serial.println(frag_queue.message_buffer[i],HEX); + } ); + return true; - } - - if( (header->reserved * 24) > (MAX_PAYLOAD_SIZE - (next_frame-frame_queue)) ){ - networkFlags |= FLAG_HOLD_INCOMING; - radio.stopListening(); - } - - memcpy(&frag_queue,&frame_buffer,8); - memcpy(frag_queue.message_buffer,frame_buffer+sizeof(RF24NetworkHeader),message_size); - -//IF_SERIAL_DEBUG_FRAGMENTATION( Serial.print(F("queue first, total frags ")); Serial.println(header->reserved); ); - //Store the total size of the stored frame in message_size - frag_queue.message_size = message_size; - --frag_queue.header.reserved; - -IF_SERIAL_DEBUG_FRAGMENTATION_L2( for(int i=0; i<frag_queue.message_size;i++){ Serial.println(frag_queue.message_buffer[i],HEX); } ); - - return true; + + } else // NETWORK_MORE_FRAGMENTS + if(header->type == NETWORK_LAST_FRAGMENT || header->type == NETWORK_MORE_FRAGMENTS || header->type == NETWORK_MORE_FRAGMENTS_NACK) { - }else // NETWORK_MORE_FRAGMENTS - if(header->type == NETWORK_LAST_FRAGMENT || header->type == NETWORK_MORE_FRAGMENTS || header->type == NETWORK_MORE_FRAGMENTS_NACK){ - - if(frag_queue.message_size + message_size > MAX_PAYLOAD_SIZE){ - #if defined (SERIAL_DEBUG_FRAGMENTATION) || defined (SERIAL_DEBUG_MINIMAL) - Serial.print(F("Drop frag ")); Serial.print(header->reserved); - Serial.println(F(" Size exceeds max")); - #endif - frag_queue.header.reserved=0; - return false; - } - if( frag_queue.header.reserved == 0 || (header->type != NETWORK_LAST_FRAGMENT && header->reserved != frag_queue.header.reserved ) || frag_queue.header.id != header->id ){ - #if defined (SERIAL_DEBUG_FRAGMENTATION) || defined (SERIAL_DEBUG_MINIMAL) - Serial.print(F("Drop frag ")); Serial.print(header->reserved); - //Serial.print(F(" header id ")); Serial.print(header->id); - Serial.println(F(" Out of order ")); - #endif - return false; - } - - memcpy(frag_queue.message_buffer+frag_queue.message_size,frame_buffer+sizeof(RF24NetworkHeader),message_size); - frag_queue.message_size += message_size; - - if(header->type != NETWORK_LAST_FRAGMENT){ - --frag_queue.header.reserved; - return true; - } - frag_queue.header.reserved = 0; - frag_queue.header.type = header->reserved; - -IF_SERIAL_DEBUG_FRAGMENTATION( printf(PSTR("fq 3: %d\n"),frag_queue.message_size); ); -IF_SERIAL_DEBUG_FRAGMENTATION_L2(for(int i=0; i< frag_queue.message_size;i++){ Serial.println(frag_queue.message_buffer[i],HEX); } ); - - //Frame assembly complete, copy to main buffer if OK - if(frag_queue.header.type == EXTERNAL_DATA_TYPE){ - return 2; - } - #if defined (DISABLE_USER_PAYLOADS) - return 0; - #endif - - if(MAX_PAYLOAD_SIZE - (next_frame-frame_queue) >= frag_queue.message_size){ - memcpy(next_frame,&frag_queue,10); - memcpy(next_frame+10,frag_queue.message_buffer,frag_queue.message_size); - next_frame += (10+frag_queue.message_size); - IF_SERIAL_DEBUG_FRAGMENTATION( printf(PSTR("enq size %d\n"),frag_queue.message_size); ); - return true; - }else{ - radio.stopListening(); - networkFlags |= FLAG_HOLD_INCOMING; - } - IF_SERIAL_DEBUG_FRAGMENTATION( printf(PSTR("Drop frag payload, queue full\n")); ); - return false; - }//If more or last fragments + if(frag_queue.message_size + message_size > MAX_PAYLOAD_SIZE) { +#if defined (SERIAL_DEBUG_FRAGMENTATION) || defined (SERIAL_DEBUG_MINIMAL) + Serial.print(F("Drop frag ")); + Serial.print(header->reserved); + Serial.println(F(" Size exceeds max")); +#endif + frag_queue.header.reserved=0; + return false; + } + if( frag_queue.header.reserved == 0 || (header->type != NETWORK_LAST_FRAGMENT && header->reserved != frag_queue.header.reserved ) || frag_queue.header.id != header->id ) { +#if defined (SERIAL_DEBUG_FRAGMENTATION) || defined (SERIAL_DEBUG_MINIMAL) + Serial.print(F("Drop frag ")); + Serial.print(header->reserved); + //Serial.print(F(" header id ")); Serial.print(header->id); + Serial.println(F(" Out of order ")); +#endif + return false; + } + + memcpy(frag_queue.message_buffer+frag_queue.message_size,frame_buffer+sizeof(RF24NetworkHeader),message_size); + frag_queue.message_size += message_size; + + if(header->type != NETWORK_LAST_FRAGMENT) { + --frag_queue.header.reserved; + return true; + } + frag_queue.header.reserved = 0; + frag_queue.header.type = header->reserved; - }else //else is not a fragment - #endif // End fragmentation enabled + IF_SERIAL_DEBUG_FRAGMENTATION( printf(PSTR("fq 3: %d\n"),frag_queue.message_size); ); + IF_SERIAL_DEBUG_FRAGMENTATION_L2(for(int i=0; i< frag_queue.message_size; i++) { + Serial.println(frag_queue.message_buffer[i],HEX); + } ); + + //Frame assembly complete, copy to main buffer if OK + if(frag_queue.header.type == EXTERNAL_DATA_TYPE) { + return 2; + } +#if defined (DISABLE_USER_PAYLOADS) + return 0; +#endif - // Copy the current frame into the frame queue + if(MAX_PAYLOAD_SIZE - (next_frame-frame_queue) >= frag_queue.message_size) { + memcpy(next_frame,&frag_queue,10); + memcpy(next_frame+10,frag_queue.message_buffer,frag_queue.message_size); + next_frame += (10+frag_queue.message_size); + IF_SERIAL_DEBUG_FRAGMENTATION( printf(PSTR("enq size %d\n"),frag_queue.message_size); ); + return true; + } else { + radio.stopListening(); + networkFlags |= FLAG_HOLD_INCOMING; + } + IF_SERIAL_DEBUG_FRAGMENTATION( printf(PSTR("Drop frag payload, queue full\n")); ); + return false; + }//If more or last fragments + + } else //else is not a fragment +#endif // End fragmentation enabled + + // Copy the current frame into the frame queue #if !defined( DISABLE_FRAGMENTATION ) - if(header->type == EXTERNAL_DATA_TYPE){ - memcpy(&frag_queue,&frame_buffer,8); - frag_queue.message_buffer = frame_buffer+sizeof(RF24NetworkHeader); - frag_queue.message_size = message_size; - return 2; - } -#endif + if(header->type == EXTERNAL_DATA_TYPE) { + memcpy(&frag_queue,&frame_buffer,8); + frag_queue.message_buffer = frame_buffer+sizeof(RF24NetworkHeader); + frag_queue.message_size = message_size; + return 2; + } +#endif #if defined (DISABLE_USER_PAYLOADS) return 0; - } +} #else - if(message_size + (next_frame-frame_queue) <= MAIN_BUFFER_SIZE){ - memcpy(next_frame,&frame_buffer,8); - RF24NetworkFrame *f = (RF24NetworkFrame*)next_frame; - f->message_size = message_size; - memcpy(next_frame+10,frame_buffer+sizeof(RF24NetworkHeader),message_size); + if(message_size + (next_frame-frame_queue) <= MAIN_BUFFER_SIZE) + { + memcpy(next_frame,&frame_buffer,8); + RF24NetworkFrame *f = (RF24NetworkFrame*)next_frame; + f->message_size = message_size; + memcpy(next_frame+10,frame_buffer+sizeof(RF24NetworkHeader),message_size); - IF_SERIAL_DEBUG_FRAGMENTATION( for(int i=0; i<message_size;i++){ Serial.print(next_frame[i],HEX); Serial.print(" : "); } Serial.println(""); ); - - next_frame += (message_size + 10); - IF_SERIAL_DEBUG_FRAGMENTATION( Serial.print("Enq "); Serial.println(next_frame-frame_queue); );//printf_P(PSTR("enq %d\n"),next_frame-frame_queue); ); - - result = true; - }else{ - result = false; - IF_SERIAL_DEBUG(printf_P(PSTR("NET **Drop Payload** Buffer Full"))); - } - return result; + IF_SERIAL_DEBUG_FRAGMENTATION( for(int i=0; i<message_size; i++) { + Serial.print(next_frame[i],HEX); + Serial.print(" : "); + } + Serial.println(""); ); + + next_frame += (message_size + 10); + IF_SERIAL_DEBUG_FRAGMENTATION( Serial.print("Enq "); Serial.println(next_frame-frame_queue); );//printf_P(PSTR("enq %d\n"),next_frame-frame_queue); ); + + result = true; + } else + { + result = false; + IF_SERIAL_DEBUG(printf_P(PSTR("NET **Drop Payload** Buffer Full"))); + } + return result; } #endif //USER_PAYLOADS_ENABLED @@ -569,584 +392,549 @@ bool RF24Network::available(void) { - - + // Are there frames on the queue for us? + return (next_frame > frame_queue); - // Are there frames on the queue for us? - return (next_frame > frame_queue); - } /******************************************************************/ uint16_t RF24Network::parent() const { - if ( node_address == 0 ) - return -1; - else - return parent_node; + if ( node_address == 0 ) + return -1; + else + return parent_node; } /******************************************************************/ /*uint8_t RF24Network::peekData(){ - + return frame_queue[0]; }*/ uint16_t RF24Network::peek(RF24NetworkHeader& header) { - if ( available() ) - { + if ( available() ) { + RF24NetworkFrame *frame = (RF24NetworkFrame*)(frame_queue); + memcpy(&header,&frame->header,sizeof(RF24NetworkHeader)); + return frame->message_size; - - - - - RF24NetworkFrame *frame = (RF24NetworkFrame*)(frame_queue); - memcpy(&header,&frame->header,sizeof(RF24NetworkHeader)); - return frame->message_size; - - } - return 0; + } + return 0; } /******************************************************************/ uint16_t RF24Network::read(RF24NetworkHeader& header,void* message, uint16_t maxlen) { - uint16_t bufsize = 0; + uint16_t bufsize = 0; + + if ( available() ) { + memcpy(&header,frame_queue,8); + RF24NetworkFrame *f = (RF24NetworkFrame*)frame_queue; + bufsize = f->message_size; + + if (maxlen > 0) { + maxlen = min(maxlen,bufsize); + memcpy(message,frame_queue+10,maxlen); + IF_SERIAL_DEBUG(printf("%lu: NET message size %d\n",millis(),bufsize);); - - - - - - - - - - - - - - - - - if ( available() ) - { - - memcpy(&header,frame_queue,8); - RF24NetworkFrame *f = (RF24NetworkFrame*)frame_queue; - bufsize = f->message_size; + IF_SERIAL_DEBUG( uint16_t len = maxlen; printf_P(PSTR("%lu: NET r message "),millis()); const uint8_t* charPtr = reinterpret_cast<const uint8_t*>(message); while(len--) { + printf("%02x ",charPtr[len]); + } + printf_P(PSTR("\n\r") ) ); - if (maxlen > 0) - { - maxlen = min(maxlen,bufsize); - memcpy(message,frame_queue+10,maxlen); - IF_SERIAL_DEBUG(printf("%lu: NET message size %d\n",millis(),bufsize);); + } + memmove(frame_queue,frame_queue+bufsize+10,sizeof(frame_queue)- bufsize); + next_frame-=bufsize+10; - - IF_SERIAL_DEBUG( uint16_t len = maxlen; printf_P(PSTR("%lu: NET r message "),millis());const uint8_t* charPtr = reinterpret_cast<const uint8_t*>(message);while(len--){ printf("%02x ",charPtr[len]);} printf_P(PSTR("\n\r") ) ); - + //IF_SERIAL_DEBUG(printf_P(PSTR("%lu: NET Received %s\n\r"),millis(),header.toString())); } - memmove(frame_queue,frame_queue+bufsize+10,sizeof(frame_queue)- bufsize); - next_frame-=bufsize+10; - //IF_SERIAL_DEBUG(printf_P(PSTR("%lu: NET Received %s\n\r"),millis(),header.toString())); - } - - return bufsize; + return bufsize; } #if defined RF24NetworkMulticast /******************************************************************/ -bool RF24Network::multicast(RF24NetworkHeader& header,const void* message, uint16_t len, uint8_t level){ +bool RF24Network::multicast(RF24NetworkHeader& header,const void* message, uint16_t len, uint8_t level) +{ // Fill out the header - header.to_node = 0100; - header.from_node = node_address; - return write(header, message, len, levelToAddress(level)); + header.to_node = 0100; + header.from_node = node_address; + return write(header, message, len, levelToAddress(level)); } #endif /******************************************************************/ -bool RF24Network::write(RF24NetworkHeader& header,const void* message, uint16_t len){ +bool RF24Network::write(RF24NetworkHeader& header,const void* message, uint16_t len) +{ return write(header,message,len,070); } /******************************************************************/ -bool RF24Network::write(RF24NetworkHeader& header,const void* message, uint16_t len, uint16_t writeDirect){ - +bool RF24Network::write(RF24NetworkHeader& header,const void* message, uint16_t len, uint16_t writeDirect) +{ + //Allows time for requests (RF24Mesh) to get through between failed writes on busy nodes - while(rf24netTimer.read_ms()-txTime < 25){ if(update() > 127){break;} } + while(rf24netTimer.read_ms()-txTime < 25) { + if(update() > 127) { + break; + } + } wait_us(200); #if defined (DISABLE_FRAGMENTATION) frame_size = rf24_min(len+sizeof(RF24NetworkHeader),MAX_FRAME_SIZE); return _write(header,message,rf24_min(len,max_frame_payload_size),writeDirect); -#else - if(len <= max_frame_payload_size){ - //Normal Write (Un-Fragmented) - frame_size = len + sizeof(RF24NetworkHeader); - if(_write(header,message,len,writeDirect)){ - return 1; +#else + if(len <= max_frame_payload_size) { + //Normal Write (Un-Fragmented) + frame_size = len + sizeof(RF24NetworkHeader); + if(_write(header,message,len,writeDirect)) { + return 1; + } + txTime = rf24netTimer.read_ms(); + return 0; } - txTime = rf24netTimer.read_ms(); - return 0; - } - //Check payload size - if (len > MAX_PAYLOAD_SIZE) { - IF_SERIAL_DEBUG(printf("%u: NET write message failed. Given 'len' %d is bigger than the MAX Payload size %i\n\r",millis(),len,MAX_PAYLOAD_SIZE);); - return false; - } - - //Divide the message payload into chunks of max_frame_payload_size - uint8_t fragment_id = (len % max_frame_payload_size != 0) + ((len ) / max_frame_payload_size); //the number of fragments to send = ceil(len/max_frame_payload_size) - - uint8_t msgCount = 0; - - IF_SERIAL_DEBUG_FRAGMENTATION(printf("%lu: FRG Total message fragments %d\n\r",millis(),fragment_id);); - - if(header.to_node != 0100){ - networkFlags |= FLAG_FAST_FRAG; - #if !defined (DUAL_HEAD_RADIO) - radio.stopListening(); - #endif - } - - uint8_t retriesPerFrag = 0; - uint8_t type = header.type; - - while (fragment_id > 0) { + //Check payload size + if (len > MAX_PAYLOAD_SIZE) { + IF_SERIAL_DEBUG(printf("%u: NET write message failed. Given 'len' %d is bigger than the MAX Payload size %i\n\r",millis(),len,MAX_PAYLOAD_SIZE);); + return false; + } - //Copy and fill out the header - //RF24NetworkHeader fragmentHeader = header; - header.reserved = fragment_id; + //Divide the message payload into chunks of max_frame_payload_size + uint8_t fragment_id = (len % max_frame_payload_size != 0) + ((len ) / max_frame_payload_size); //the number of fragments to send = ceil(len/max_frame_payload_size) - if (fragment_id == 1) { - header.type = NETWORK_LAST_FRAGMENT; //Set the last fragment flag to indicate the last fragment - header.reserved = type; //The reserved field is used to transmit the header type - } else { - if (msgCount == 0) { - header.type = NETWORK_FIRST_FRAGMENT; - }else{ - header.type = NETWORK_MORE_FRAGMENTS; //Set the more fragments flag to indicate a fragmented frame - } - } - - uint16_t offset = msgCount*max_frame_payload_size; - uint16_t fragmentLen = rf24_min((uint16_t)(len-offset),max_frame_payload_size); + uint8_t msgCount = 0; - //Try to send the payload chunk with the copied header - frame_size = sizeof(RF24NetworkHeader)+fragmentLen; - bool ok = _write(header,((char *)message)+offset,fragmentLen,writeDirect); - - if (!ok) { - wait_ms(2); - ++retriesPerFrag; + IF_SERIAL_DEBUG_FRAGMENTATION(printf("%lu: FRG Total message fragments %d\n\r",millis(),fragment_id);); - }else{ - retriesPerFrag = 0; - fragment_id--; - msgCount++; - } - - if(writeDirect != 070){ wait_ms(2); } //Delay 2ms between sending multicast payloads - - if (!ok && retriesPerFrag >= 3) { - IF_SERIAL_DEBUG_FRAGMENTATION(printf("%lu: FRG TX with fragmentID '%d' failed after %d fragments. Abort.\n\r",millis(),fragment_id,msgCount);); - break; + if(header.to_node != 0100) { + networkFlags |= FLAG_FAST_FRAG; +#if !defined (DUAL_HEAD_RADIO) + radio.stopListening(); +#endif } - - //Message was successful sent - #if defined SERIAL_DEBUG_FRAGMENTATION_L2 - printf("%lu: FRG message transmission with fragmentID '%d' sucessfull.\n\r",millis(),fragment_id); - #endif + uint8_t retriesPerFrag = 0; + uint8_t type = header.type; + + while (fragment_id > 0) { + + //Copy and fill out the header + //RF24NetworkHeader fragmentHeader = header; + header.reserved = fragment_id; - } + if (fragment_id == 1) { + header.type = NETWORK_LAST_FRAGMENT; //Set the last fragment flag to indicate the last fragment + header.reserved = type; //The reserved field is used to transmit the header type + } else { + if (msgCount == 0) { + header.type = NETWORK_FIRST_FRAGMENT; + } else { + header.type = NETWORK_MORE_FRAGMENTS; //Set the more fragments flag to indicate a fragmented frame + } + } + + uint16_t offset = msgCount*max_frame_payload_size; + uint16_t fragmentLen = rf24_min((uint16_t)(len-offset),max_frame_payload_size); + + //Try to send the payload chunk with the copied header + frame_size = sizeof(RF24NetworkHeader)+fragmentLen; + bool ok = _write(header,((char *)message)+offset,fragmentLen,writeDirect); + + if (!ok) { + wait_ms(2); + ++retriesPerFrag; - #if !defined (DUAL_HEAD_RADIO) - if(networkFlags & FLAG_FAST_FRAG){ - radio.startListening(); - } - #endif - networkFlags &= ~FLAG_FAST_FRAG - //int frag_delay = uint8_t(len/48); - //delay( rf24_min(len/48,20)); + } else { + retriesPerFrag = 0; + fragment_id--; + msgCount++; + } + + if(writeDirect != 070) { + wait_ms(2); //Delay 2ms between sending multicast payloads + } + + if (!ok && retriesPerFrag >= 3) { + IF_SERIAL_DEBUG_FRAGMENTATION(printf("%lu: FRG TX with fragmentID '%d' failed after %d fragments. Abort.\n\r",millis(),fragment_id,msgCount);); + break; + } + + //Message was successful sent +#if defined SERIAL_DEBUG_FRAGMENTATION_L2 + printf("%lu: FRG message transmission with fragmentID '%d' sucessfull.\n\r",millis(),fragment_id); +#endif - //Return true if all the chunks where sent successfully - - IF_SERIAL_DEBUG_FRAGMENTATION(printf("%u: FRG total message fragments sent %i. \n",millis(),msgCount); ); - if(fragment_id > 0){ - txTime = rf24netTimer.read_ms(); - return false; - } - return true; - + } + +#if !defined (DUAL_HEAD_RADIO) + if(networkFlags & FLAG_FAST_FRAG) { + radio.startListening(); + } +#endif + networkFlags &= ~FLAG_FAST_FRAG + //int frag_delay = uint8_t(len/48); + //delay( rf24_min(len/48,20)); + + //Return true if all the chunks where sent successfully + + IF_SERIAL_DEBUG_FRAGMENTATION(printf("%u: FRG total message fragments sent %i. \n",millis(),msgCount); ); + if(fragment_id > 0) { + txTime = rf24netTimer.read_ms(); + return false; + } + return true; + #endif //Fragmentation enabled } /******************************************************************/ bool RF24Network::_write(RF24NetworkHeader& header,const void* message, uint16_t len, uint16_t writeDirect) { - // Fill out the header - header.from_node = node_address; - - // Build the full frame to send - memcpy(frame_buffer,&header,sizeof(RF24NetworkHeader)); - + // Fill out the header + header.from_node = node_address; - - + // Build the full frame to send + memcpy(frame_buffer,&header,sizeof(RF24NetworkHeader)); + IF_SERIAL_DEBUG(printf_P(PSTR("%lu: NET Sending %s\n\r"),millis(),header.toString())); - if (len){ + if (len) { + + memcpy(frame_buffer + sizeof(RF24NetworkHeader),message,len); - - - - - - memcpy(frame_buffer + sizeof(RF24NetworkHeader),message,len); - - IF_SERIAL_DEBUG(uint16_t tmpLen = len;printf_P(PSTR("%lu: NET message "),millis());const uint8_t* charPtr = reinterpret_cast<const uint8_t*>(message);while(tmpLen--){ printf("%02x ",charPtr[tmpLen]);} printf_P(PSTR("\n\r") ) ); + IF_SERIAL_DEBUG(uint16_t tmpLen = len; printf_P(PSTR("%lu: NET message "),millis()); const uint8_t* charPtr = reinterpret_cast<const uint8_t*>(message); while(tmpLen--) { + printf("%02x ",charPtr[tmpLen]); + } + printf_P(PSTR("\n\r") ) ); - } + } - // If the user is trying to send it to himself - /*if ( header.to_node == node_address ){ - #if defined (RF24_LINUX) - RF24NetworkFrame frame = RF24NetworkFrame(header,message,rf24_min(MAX_FRAME_SIZE-sizeof(RF24NetworkHeader),len)); - #else - RF24NetworkFrame frame(header,len); - #endif - // Just queue it in the received queue - return enqueue(frame); - }*/ - // Otherwise send it out over the air - - - if(writeDirect != 070){ + // If the user is trying to send it to himself + /*if ( header.to_node == node_address ){ + #if defined (RF24_LINUX) + RF24NetworkFrame frame = RF24NetworkFrame(header,message,rf24_min(MAX_FRAME_SIZE-sizeof(RF24NetworkHeader),len)); + #else + RF24NetworkFrame frame(header,len); + #endif + // Just queue it in the received queue + return enqueue(frame); + }*/ + // Otherwise send it out over the air + + + if(writeDirect != 070) { uint8_t sendType = USER_TX_TO_LOGICAL_ADDRESS; // Payload is multicast to the first node, and routed normally to the next - - if(header.to_node == 0100){ - sendType = USER_TX_MULTICAST; + + if(header.to_node == 0100) { + sendType = USER_TX_MULTICAST; } - if(header.to_node == writeDirect){ - sendType = USER_TX_TO_PHYSICAL_ADDRESS; // Payload is multicast to the first node, which is the recipient + if(header.to_node == writeDirect) { + sendType = USER_TX_TO_PHYSICAL_ADDRESS; // Payload is multicast to the first node, which is the recipient } - return write(writeDirect,sendType); + return write(writeDirect,sendType); } return write(header.to_node,TX_NORMAL); - + } /******************************************************************/ bool RF24Network::write(uint16_t to_node, uint8_t directTo) // Direct To: 0 = First Payload, standard routing, 1=routed payload, 2=directRoute to host, 3=directRoute to Route { - bool ok = false; - bool isAckType = false; - if(frame_buffer[6] > 64 && frame_buffer[6] < 192 ){ isAckType=true; } - - /*if( ( (frame_buffer[7] % 2) && frame_buffer[6] == NETWORK_MORE_FRAGMENTS) ){ - isAckType = 0; - }*/ - - // Throw it away if it's not a valid address - if ( !is_valid_address(to_node) ) - return false; - - //Load info into our conversion structure, and get the converted address info - logicalToPhysicalStruct conversion = { to_node,directTo,0}; - logicalToPhysicalAddress(&conversion); - + bool ok = false; + bool isAckType = false; + if(frame_buffer[6] > 64 && frame_buffer[6] < 192 ) { + isAckType=true; + } + + /*if( ( (frame_buffer[7] % 2) && frame_buffer[6] == NETWORK_MORE_FRAGMENTS) ){ + isAckType = 0; + }*/ + + // Throw it away if it's not a valid address + if ( !is_valid_address(to_node) ) + return false; - - - IF_SERIAL_DEBUG(printf_P(PSTR("%lu: MAC Sending to 0%o via 0%o on pipe %x\n\r"),millis(),to_node,conversion.send_node,conversion.send_pipe)); + //Load info into our conversion structure, and get the converted address info + logicalToPhysicalStruct conversion = { to_node,directTo,0}; + logicalToPhysicalAddress(&conversion); + + + IF_SERIAL_DEBUG(printf_P(PSTR("%lu: MAC Sending to 0%o via 0%o on pipe %x\n\r"),millis(),to_node,conversion.send_node,conversion.send_pipe)); - /**Write it*/ - ok=write_to_pipe(conversion.send_node, conversion.send_pipe, conversion.multicast); - - - if(!ok){ + /**Write it*/ + ok=write_to_pipe(conversion.send_node, conversion.send_pipe, conversion.multicast); - - - - IF_SERIAL_DEBUG_ROUTING( printf_P(PSTR("%lu: MAC Send fail to 0%o via 0%o on pipe %x\n\r"),millis(),to_node,conversion.send_node,conversion.send_pipe);); + + if(!ok) { + IF_SERIAL_DEBUG_ROUTING( printf_P(PSTR("%lu: MAC Send fail to 0%o via 0%o on pipe %x\n\r"),millis(),to_node,conversion.send_node,conversion.send_pipe);); } - - if( directTo == TX_ROUTED && ok && conversion.send_node == to_node && isAckType){ - - RF24NetworkHeader* header = (RF24NetworkHeader*)&frame_buffer; - header->type = NETWORK_ACK; // Set the payload type to NETWORK_ACK - header->to_node = header->from_node; // Change the 'to' address to the 'from' address + + if( directTo == TX_ROUTED && ok && conversion.send_node == to_node && isAckType) { + + RF24NetworkHeader* header = (RF24NetworkHeader*)&frame_buffer; + header->type = NETWORK_ACK; // Set the payload type to NETWORK_ACK + header->to_node = header->from_node; // Change the 'to' address to the 'from' address - conversion.send_node = header->from_node; - conversion.send_pipe = TX_ROUTED; - conversion.multicast = 0; - logicalToPhysicalAddress(&conversion); - - //Write the data using the resulting physical address - frame_size = sizeof(RF24NetworkHeader); - write_to_pipe(conversion.send_node, conversion.send_pipe, conversion.multicast); - - //dynLen=0; + conversion.send_node = header->from_node; + conversion.send_pipe = TX_ROUTED; + conversion.multicast = 0; + logicalToPhysicalAddress(&conversion); - - - IF_SERIAL_DEBUG_ROUTING( printf_P(PSTR("%lu MAC: Route OK to 0%o ACK sent to 0%o\n"),millis(),to_node,header->from_node); ); + //Write the data using the resulting physical address + frame_size = sizeof(RF24NetworkHeader); + write_to_pipe(conversion.send_node, conversion.send_pipe, conversion.multicast); + + //dynLen=0; + + IF_SERIAL_DEBUG_ROUTING( printf_P(PSTR("%lu MAC: Route OK to 0%o ACK sent to 0%o\n"),millis(),to_node,header->from_node); ); } - - if( ok && conversion.send_node != to_node && (directTo==0 || directTo==3) && isAckType){ - #if !defined (DUAL_HEAD_RADIO) - // Now, continue listening - if(networkFlags & FLAG_FAST_FRAG){ - radio.txStandBy(txTimeout); - networkFlags &= ~FLAG_FAST_FRAG; - } - radio.startListening(); - #endif - uint32_t reply_time = rf24netTimer.read_ms(); + if( ok && conversion.send_node != to_node && (directTo==0 || directTo==3) && isAckType) { +#if !defined (DUAL_HEAD_RADIO) + // Now, continue listening + if(networkFlags & FLAG_FAST_FRAG) { + radio.txStandBy(txTimeout); + networkFlags &= ~FLAG_FAST_FRAG; + } + radio.startListening(); +#endif + uint32_t reply_time = rf24netTimer.read_ms(); - while( update() != NETWORK_ACK){ + while( update() != NETWORK_ACK) { wait_us(900); - if(rf24netTimer.read_ms() - reply_time > routeTimeout){ + if(rf24netTimer.read_ms() - reply_time > routeTimeout) { - - - IF_SERIAL_DEBUG_ROUTING( printf_P(PSTR("%lu: MAC Network ACK fail from 0%o via 0%o on pipe %x\n\r"),millis(),to_node,conversion.send_node,conversion.send_pipe); ); + IF_SERIAL_DEBUG_ROUTING( printf_P(PSTR("%lu: MAC Network ACK fail from 0%o via 0%o on pipe %x\n\r"),millis(),to_node,conversion.send_node,conversion.send_pipe); ); ok=false; - break; + break; } } } - if( !(networkFlags & FLAG_FAST_FRAG) ){ - #if !defined (DUAL_HEAD_RADIO) - // Now, continue listening - radio.startListening(); - #endif + if( !(networkFlags & FLAG_FAST_FRAG) ) { +#if !defined (DUAL_HEAD_RADIO) + // Now, continue listening + radio.startListening(); +#endif } #if defined ENABLE_NETWORK_STATS - if(ok == true){ - ++nOK; - }else{ ++nFails; - } + if(ok == true) { + ++nOK; + } else { + ++nFails; + } #endif - return ok; + return ok; } /******************************************************************/ - // Provided the to_node and directTo option, it will return the resulting node and pipe -bool RF24Network::logicalToPhysicalAddress(logicalToPhysicalStruct *conversionInfo){ +// Provided the to_node and directTo option, it will return the resulting node and pipe +bool RF24Network::logicalToPhysicalAddress(logicalToPhysicalStruct *conversionInfo) +{ + + //Create pointers so this makes sense.. kind of + //We take in the to_node(logical) now, at the end of the function, output the send_node(physical) address, etc. + //back to the original memory address that held the logical information. + uint16_t *to_node = &conversionInfo->send_node; + uint8_t *directTo = &conversionInfo->send_pipe; + bool *multicast = &conversionInfo->multicast; - //Create pointers so this makes sense.. kind of - //We take in the to_node(logical) now, at the end of the function, output the send_node(physical) address, etc. - //back to the original memory address that held the logical information. - uint16_t *to_node = &conversionInfo->send_node; - uint8_t *directTo = &conversionInfo->send_pipe; - bool *multicast = &conversionInfo->multicast; - - // Where do we send this? By default, to our parent - uint16_t pre_conversion_send_node = parent_node; + // Where do we send this? By default, to our parent + uint16_t pre_conversion_send_node = parent_node; - // On which pipe - uint8_t pre_conversion_send_pipe = parent_pipe %5; - - if(*directTo > TX_ROUTED ){ - pre_conversion_send_node = *to_node; - *multicast = 1; - //if(*directTo == USER_TX_MULTICAST || *directTo == USER_TX_TO_PHYSICAL_ADDRESS){ + // On which pipe + uint8_t pre_conversion_send_pipe = parent_pipe %5; + + if(*directTo > TX_ROUTED ) { + pre_conversion_send_node = *to_node; + *multicast = 1; + //if(*directTo == USER_TX_MULTICAST || *directTo == USER_TX_TO_PHYSICAL_ADDRESS){ pre_conversion_send_pipe=0; - //} - } - // If the node is a direct child, - else - if ( is_direct_child(*to_node) ) - { - // Send directly - pre_conversion_send_node = *to_node; - // To its listening pipe - pre_conversion_send_pipe = 5; - } - // If the node is a child of a child - // talk on our child's listening pipe, - // and let the direct child relay it. - else if ( is_descendant(*to_node) ) - { - pre_conversion_send_node = direct_child_route_to(*to_node); - pre_conversion_send_pipe = 5; - } - - *to_node = pre_conversion_send_node; - *directTo = pre_conversion_send_pipe; - - return 1; - + //} + } + // If the node is a direct child, + else if ( is_direct_child(*to_node) ) { + // Send directly + pre_conversion_send_node = *to_node; + // To its listening pipe + pre_conversion_send_pipe = 5; + } + // If the node is a child of a child + // talk on our child's listening pipe, + // and let the direct child relay it. + else if ( is_descendant(*to_node) ) { + pre_conversion_send_node = direct_child_route_to(*to_node); + pre_conversion_send_pipe = 5; + } + + *to_node = pre_conversion_send_node; + *directTo = pre_conversion_send_pipe; + + return 1; + } /********************************************************/ - bool RF24Network::write_to_pipe( uint16_t node, uint8_t pipe, bool multicast ) { - bool ok = false; - uint64_t out_pipe = pipe_address( node, pipe ); - - #if !defined (DUAL_HEAD_RADIO) - // Open the correct pipe for writing. - // First, stop listening so we can talk + bool ok = false; + uint64_t out_pipe = pipe_address( node, pipe ); + +#if !defined (DUAL_HEAD_RADIO) + // Open the correct pipe for writing. + // First, stop listening so we can talk + + if(!(networkFlags & FLAG_FAST_FRAG)) { + radio.stopListening(); + } - if(!(networkFlags & FLAG_FAST_FRAG)){ - radio.stopListening(); - } - - if(multicast){ radio.setAutoAck(0,0);}else{radio.setAutoAck(0,1);} - - radio.openWritingPipe(out_pipe); - radio.writeFast(frame_buffer, frame_size,multicast); - ok = radio.txStandBy(txTimeout); - - radio.setAutoAck(0,0); - + if(multicast) { + radio.setAutoAck(0,0); + } else { + radio.setAutoAck(0,1); + } + + radio.openWritingPipe(out_pipe); + radio.writeFast(frame_buffer, frame_size,multicast); + ok = radio.txStandBy(txTimeout); + + radio.setAutoAck(0,0); + #else - radio1.openWritingPipe(out_pipe); - radio1.writeFast(frame_buffer, frame_size); - ok = radio1.txStandBy(txTimeout,multicast); + radio1.openWritingPipe(out_pipe); + radio1.writeFast(frame_buffer, frame_size); + ok = radio1.txStandBy(txTimeout,multicast); #endif - - + IF_SERIAL_DEBUG(printf_P(PSTR("%lu: MAC Sent on %lx %S\n\r"),rf24netTimer.read_ms(),(uint32_t)out_pipe,ok?PSTR("ok"):PSTR("failed"))); - IF_SERIAL_DEBUG(printf_P(PSTR("%lu: MAC Sent on %lx %S\n\r"),rf24netTimer.read_ms(),(uint32_t)out_pipe,ok?PSTR("ok"):PSTR("failed"))); - - - return ok; + return ok; } /******************************************************************/ const char* RF24NetworkHeader::toString(void) const { - static char buffer[45]; - //snprintf_P(buffer,sizeof(buffer),PSTR("id %04x from 0%o to 0%o type %c"),id,from_node,to_node,type); - sprintf(buffer,PSTR("id %u from 0%o to 0%o type %d"),id,from_node,to_node,type); - return buffer; + static char buffer[45]; + //snprintf_P(buffer,sizeof(buffer),PSTR("id %04x from 0%o to 0%o type %c"),id,from_node,to_node,type); + sprintf(buffer,PSTR("id %u from 0%o to 0%o type %d"),id,from_node,to_node,type); + return buffer; } /******************************************************************/ bool RF24Network::is_direct_child( uint16_t node ) { - bool result = false; + bool result = false; - // A direct child of ours has the same low numbers as us, and only - // one higher number. - // - // e.g. node 0234 is a direct child of 034, and node 01234 is a - // descendant but not a direct child + // A direct child of ours has the same low numbers as us, and only + // one higher number. + // + // e.g. node 0234 is a direct child of 034, and node 01234 is a + // descendant but not a direct child - // First, is it even a descendant? - if ( is_descendant(node) ) - { - // Does it only have ONE more level than us? - uint16_t child_node_mask = ( ~ node_mask ) << 3; - result = ( node & child_node_mask ) == 0 ; - } - return result; + // First, is it even a descendant? + if ( is_descendant(node) ) { + // Does it only have ONE more level than us? + uint16_t child_node_mask = ( ~ node_mask ) << 3; + result = ( node & child_node_mask ) == 0 ; + } + return result; } /******************************************************************/ bool RF24Network::is_descendant( uint16_t node ) { - return ( node & node_mask ) == node_address; + return ( node & node_mask ) == node_address; } /******************************************************************/ void RF24Network::setup_address(void) { - // First, establish the node_mask - uint16_t node_mask_check = 0xFFFF; - #if defined (RF24NetworkMulticast) - uint8_t count = 0; - #endif - - while ( node_address & node_mask_check ){ - node_mask_check <<= 3; - #if defined (RF24NetworkMulticast) - count++; - } - multicast_level = count; - #else - } - #endif - - node_mask = ~ node_mask_check; + // First, establish the node_mask + uint16_t node_mask_check = 0xFFFF; +#if defined (RF24NetworkMulticast) + uint8_t count = 0; +#endif + + while ( node_address & node_mask_check ) { + node_mask_check <<= 3; +#if defined (RF24NetworkMulticast) + count++; + } + multicast_level = count; +#else + } +#endif + + node_mask = ~ node_mask_check; - // parent mask is the next level down - uint16_t parent_mask = node_mask >> 3; + // parent mask is the next level down + uint16_t parent_mask = node_mask >> 3; - // parent node is the part IN the mask - parent_node = node_address & parent_mask; + // parent node is the part IN the mask + parent_node = node_address & parent_mask; - // parent pipe is the part OUT of the mask - uint16_t i = node_address; - uint16_t m = parent_mask; - while (m) - { - i >>= 3; - m >>= 3; - } - parent_pipe = i; + // parent pipe is the part OUT of the mask + uint16_t i = node_address; + uint16_t m = parent_mask; + while (m) + { + i >>= 3; + m >>= 3; + } + parent_pipe = i; - IF_SERIAL_DEBUG( printf_P(PSTR("setup_address node=0%o mask=0%o parent=0%o pipe=0%o\n\r"),node_address,node_mask,parent_node,parent_pipe);); + IF_SERIAL_DEBUG( printf_P(PSTR("setup_address node=0%o mask=0%o parent=0%o pipe=0%o\n\r"),node_address,node_mask,parent_node,parent_pipe);); } /******************************************************************/ uint16_t RF24Network::addressOfPipe( uint16_t node, uint8_t pipeNo ) { - //Say this node is 013 (1011), mask is 077 or (00111111) - //Say we want to use pipe 3 (11) - //6 bits in node mask, so shift pipeNo 6 times left and | into address + //Say this node is 013 (1011), mask is 077 or (00111111) + //Say we want to use pipe 3 (11) + //6 bits in node mask, so shift pipeNo 6 times left and | into address uint16_t m = node_mask >> 3; uint8_t i=0; - - while (m){ //While there are bits left in the node mask + + while (m) { //While there are bits left in the node mask m>>=1; //Shift to the right i++; //Count the # of increments } - return node | (pipeNo << i); + return node | (pipeNo << i); } /******************************************************************/ uint16_t RF24Network::direct_child_route_to( uint16_t node ) { - // Presumes that this is in fact a child!! - uint16_t child_mask = ( node_mask << 3 ) | 7; - return node & child_mask; - + // Presumes that this is in fact a child!! + uint16_t child_mask = ( node_mask << 3 ) | 7; + return node & child_mask; + } /******************************************************************/ /* uint8_t RF24Network::pipe_to_descendant( uint16_t node ) { - uint16_t i = node; + uint16_t i = node; uint16_t m = node_mask; while (m) @@ -1162,155 +950,138 @@ bool RF24Network::is_valid_address( uint16_t node ) { - bool result = true; + bool result = true; - while(node) - { - uint8_t digit = node & 7; - #if !defined (RF24NetworkMulticast) - if (digit < 1 || digit > 5) - #else - if (digit < 0 || digit > 5) //Allow our out of range multicast address - #endif - { - result = false; - IF_SERIAL_DEBUG_MINIMAL(printf_P(PSTR("*** WARNING *** Invalid address 0%o\n\r"),node);); - break; + while(node) { + uint8_t digit = node & 7; +#if !defined (RF24NetworkMulticast) + if (digit < 1 || digit > 5) +#else + if (digit < 0 || digit > 5) //Allow our out of range multicast address +#endif + { + result = false; + IF_SERIAL_DEBUG_MINIMAL(printf_P(PSTR("*** WARNING *** Invalid address 0%o\n\r"),node);); + break; + } + node >>= 3; } - node >>= 3; - } - return result; + return result; } /******************************************************************/ #if defined (RF24NetworkMulticast) -void RF24Network::multicastLevel(uint8_t level){ - multicast_level = level; - //radio.stopListening(); - radio.openReadingPipe(0,pipe_address(levelToAddress(level),0)); - //radio.startListening(); - } - -uint16_t levelToAddress(uint8_t level){ - +void RF24Network::multicastLevel(uint8_t level) +{ + multicast_level = level; + //radio.stopListening(); + radio.openReadingPipe(0,pipe_address(levelToAddress(level),0)); + //radio.startListening(); +} + +uint16_t levelToAddress(uint8_t level) +{ + uint16_t levelAddr = 1; - if(level){ + if(level) { levelAddr = levelAddr << ((level-1) * 3); - }else{ - return 0; + } else { + return 0; } return levelAddr; -} +} #endif /******************************************************************/ uint64_t pipe_address( uint16_t node, uint8_t pipe ) { - - static uint8_t address_translation[] = { 0xc3,0x3c,0x33,0xce,0x3e,0xe3,0xec }; - uint64_t result = 0xCCCCCCCCCCLL; - uint8_t* out = reinterpret_cast<uint8_t*>(&result); - - // Translate the address to use our optimally chosen radio address bytes - uint8_t count = 1; uint16_t dec = node; + + static uint8_t address_translation[] = { 0xc3,0x3c,0x33,0xce,0x3e,0xe3,0xec }; + uint64_t result = 0xCCCCCCCCCCLL; + uint8_t* out = reinterpret_cast<uint8_t*>(&result); + + // Translate the address to use our optimally chosen radio address bytes + uint8_t count = 1; + uint16_t dec = node; - while(dec){ - #if defined (RF24NetworkMulticast) - if(pipe != 0 || !node) - #endif - out[count]=address_translation[(dec % 8)]; // Convert our decimal values to octal, translate them to address bytes, and set our address - - dec /= 8; - count++; + while(dec) { +#if defined (RF24NetworkMulticast) + if(pipe != 0 || !node) +#endif + out[count]=address_translation[(dec % 8)]; // Convert our decimal values to octal, translate them to address bytes, and set our address + + dec /= 8; + count++; } - - #if defined (RF24NetworkMulticast) - if(pipe != 0 || !node) - #endif - out[0] = address_translation[pipe]; - #if defined (RF24NetworkMulticast) - else - out[1] = address_translation[count-1]; - #endif - - +#if defined (RF24NetworkMulticast) + if(pipe != 0 || !node) +#endif + out[0] = address_translation[pipe]; +#if defined (RF24NetworkMulticast) + else + out[1] = address_translation[count-1]; +#endif - - - IF_SERIAL_DEBUG(uint32_t* top = reinterpret_cast<uint32_t*>(out+1);printf_P(PSTR("%lu: NET Pipe %i on node 0%o has address %lx%x\n\r"),millis(),pipe,node,*top,*out)); - - return result; + IF_SERIAL_DEBUG(uint32_t* top = reinterpret_cast<uint32_t*>(out+1); printf_P(PSTR("%lu: NET Pipe %i on node 0%o has address %lx%x\n\r"),millis(),pipe,node,*top,*out)); + + return result; } /************************ Sleep Mode ******************************************/ - #if defined ENABLE_SLEEP_MODE -#if !defined(__arm__) && !defined(__ARDUINO_X86__) - -void wakeUp(){ - wasInterrupted=true; - sleep_cycles_remaining = 0; +void wakeUp() +{ + wasInterrupted=true; + sleep_cycles_remaining = 0; } -ISR(WDT_vect){ - --sleep_cycles_remaining; +ISR(WDT_vect) +{ + --sleep_cycles_remaining; } -bool RF24Network::sleepNode( unsigned int cycles, int interruptPin ){ - - - sleep_cycles_remaining = cycles; - set_sleep_mode(SLEEP_MODE_PWR_DOWN); // sleep mode is set here - sleep_enable(); - if(interruptPin != 255){ - wasInterrupted = false; //Reset Flag - attachInterrupt(interruptPin,wakeUp, LOW); - } - - - - - WDTCSR |= _BV(WDIE); - - - while(sleep_cycles_remaining){ - sleep_mode(); // System sleeps here - } // The WDT_vect interrupt wakes the MCU from here - sleep_disable(); // System continues execution here when watchdog timed out - detachInterrupt(interruptPin); +bool RF24Network::sleepNode( unsigned int cycles, int interruptPin ) +{ - - - + sleep_cycles_remaining = cycles; + set_sleep_mode(SLEEP_MODE_PWR_DOWN); // sleep mode is set here + sleep_enable(); + //if(interruptPin != 255){ + // wasInterrupted = false; //Reset Flag + // attachInterrupt(interruptPin,wakeUp, LOW); + //} + + WDTCSR |= _BV(WDIE); + + while(sleep_cycles_remaining) { + sleep_mode(); // System sleeps here + } // The WDT_vect interrupt wakes the MCU from here + sleep_disable(); // System continues execution here when watchdog timed out + //detachInterrupt(interruptPin); + WDTCSR &= ~_BV(WDIE); - - return !wasInterrupted; + return !wasInterrupted; } -void RF24Network::setup_watchdog(uint8_t prescalar){ - - uint8_t wdtcsr = prescalar & 7; - if ( prescalar & 8 ) - wdtcsr |= _BV(WDP3); - MCUSR &= ~_BV(WDRF); // Clear the WD System Reset Flag +void RF24Network::setup_watchdog(uint8_t prescalar) +{ + uint8_t wdtcsr = prescalar & 7; + if ( prescalar & 8 ) + wdtcsr |= _BV(WDP3); + MCUSR &= ~_BV(WDRF); // Clear the WD System Reset Flag - - - WDTCSR = _BV(WDCE) | _BV(WDE); // Write the WD Change enable bit to enable changing the prescaler and enable system reset - WDTCSR = _BV(WDCE) | wdtcsr | _BV(WDIE); // Write the prescalar bits (how long to sleep, enable the interrupt to wake the MCU - + WDTCSR = _BV(WDCE) | _BV(WDE); // Write the WD Change enable bit to enable changing the prescaler and enable system reset + WDTCSR = _BV(WDCE) | wdtcsr | _BV(WDIE); // Write the prescalar bits (how long to sleep, enable the interrupt to wake the MCU } - -#endif // not ATTiny -#endif // Enable sleep mode +#endif