// Start a response, returns the partial CRC
void ICACHE_FLASH_ATTR
cmdResponseStart(uint16_t cmd, uint32_t value, uint16_t argc) {
DBG("cmdResponse: cmd=%d val=%d argc=%d\n", cmd, value, argc);
uart0_write_char(SLIP_END);
cmdProtoWriteBuf((uint8_t*)&cmd, 2);
resp_crc = crc16_data((uint8_t*)&cmd, 2, 0);
cmdProtoWriteBuf((uint8_t*)&argc, 2);
resp_crc = crc16_data((uint8_t*)&argc, 2, resp_crc);
cmdProtoWriteBuf((uint8_t*)&value, 4);
resp_crc = crc16_data((uint8_t*)&value, 4, resp_crc);
}
// Start a response, returns the partial CRC
uint16_t ICACHE_FLASH_ATTR
CMD_ResponseStart(uint16_t cmd, uint32_t callback, uint32_t _return, uint16_t argc) {
uint16_t crc = 0;
uart0_write_char(SLIP_START);
CMD_ProtoWriteBuf((uint8_t*)&cmd, 2);
crc = crc16_data((uint8_t*)&cmd, 2, crc);
CMD_ProtoWriteBuf((uint8_t*)&callback, 4);
crc = crc16_data((uint8_t*)&callback, 4, crc);
CMD_ProtoWriteBuf((uint8_t*)&_return, 4);
crc = crc16_data((uint8_t*)&_return, 4, crc);
CMD_ProtoWriteBuf((uint8_t*)&argc, 2);
crc = crc16_data((uint8_t*)&argc, 2, crc);
return crc;
}
// Adds data to a response, returns the partial CRC
void ICACHE_FLASH_ATTR
cmdResponseBody(const void *data, uint16_t len) {
cmdProtoWriteBuf((uint8_t*)&len, 2);
resp_crc = crc16_data((uint8_t*)&len, 2, resp_crc);
cmdProtoWriteBuf(data, len);
resp_crc = crc16_data(data, len, resp_crc);
uint16_t pad = (4-((len+2)&3))&3; // get to multiple of 4
if (pad > 0) {
uint32_t temp = 0;
cmdProtoWriteBuf((uint8_t*)&temp, pad);
resp_crc = crc16_data((uint8_t*)&temp, pad, resp_crc);
}
}
/*---------------------------------------------------------------------------*/
static void
recv_trickle(struct trickle_conn *c)
{
struct trickle_msg *msg;
uint16_t crc;
int len;
msg = packetbuf_dataptr();
if(packetbuf_datalen() > 1 + TRICKLEMSG_HDR_SIZE) {
/* First ensure that the old process is killed. */
process_exit(&shell_netcmd_server_process);
len = packetbuf_datalen() - 1 - TRICKLEMSG_HDR_SIZE;
/* Make sure that the incoming command is null-terminated. */
msg->netcmd[len] = 0;
memcpy(&crc, &msg->crc, sizeof(crc));
if(crc == crc16_data(msg->netcmd, len, 0)) {
/* Start the server process with the incoming command. */
process_start(&shell_netcmd_server_process, (void *)msg->netcmd);
}
}
}
// SLIP process a packet or a bunch of debug console chars
static void ICACHE_FLASH_ATTR
slip_process() {
if (slip_len < 1) return;
if (!slip_inpkt) {
// debug console stuff
console_process(slip_buf, slip_len);
} else {
// proper SLIP packet, invoke command processor after checking CRC
//os_printf("SLIP: rcv %d\n", slip_len);
if (slip_len > 2) {
uint16_t crc = crc16_data((uint8_t*)slip_buf, slip_len-2, 0);
uint16_t rcv = ((uint16_t)slip_buf[slip_len-2]) | ((uint16_t)slip_buf[slip_len-1] << 8);
if (crc == rcv) {
CMD_parse_packet((uint8_t*)slip_buf, slip_len-2);
} else {
os_printf("SLIP: bad CRC, crc=%x rcv=%x\n", crc, rcv);
#ifdef SLIP_DBG
for (short i=0; i<slip_len; i++) {
if (slip_buf[i] >= ' ' && slip_buf[i] <= '~')
os_printf("%c", slip_buf[i]);
else
os_printf("\\%02X", slip_buf[i]);
}
os_printf("\n");
#endif
}
}
}
}
/*---------------------------------------------------------------------------*/
static int
prepare(const void *payload, unsigned short payload_len)
{
uint8_t i;
uint16_t checksum;
RIMESTATS_ADD(lltx);
if(tx_in_progress) {
return 1;
}
if(payload_len > 127 || payload == NULL) {
return 1;
}
/* Copy payload to (soft) Ttx buffer */
memcpy(tx_frame_buffer.uPayload.au8Byte, payload, payload_len);
i = payload_len;
#if CRC_SW
/* Compute CRC */
checksum = crc16_data(payload, payload_len, 0);
tx_frame_buffer.uPayload.au8Byte[i++] = checksum;
tx_frame_buffer.uPayload.au8Byte[i++] = (checksum >> 8) & 0xff;
tx_frame_buffer.u8PayloadLength = payload_len + CHECKSUM_LEN;
#else
tx_frame_buffer.u8PayloadLength = payload_len;
#endif
return 0;
}
/*---------------------------------------------------------------------------*/
static int
cc2420_prepare(const void *payload, unsigned short payload_len)
{
uint8_t total_len;
#if CC2420_CONF_CHECKSUM
uint16_t checksum;
#endif /* CC2420_CONF_CHECKSUM */
GET_LOCK();
PRINTF("cc2420: sending %d bytes\n", payload_len);
RIMESTATS_ADD(lltx);
/* Wait for any previous transmission to finish. */
/* while(status() & BV(CC2420_TX_ACTIVE));*/
/* Write packet to TX FIFO. */
strobe(CC2420_SFLUSHTX);
#if CC2420_CONF_CHECKSUM
checksum = crc16_data(payload, payload_len, 0);
#endif /* CC2420_CONF_CHECKSUM */
total_len = payload_len + AUX_LEN;
CC2420_WRITE_FIFO_BUF(&total_len, 1);
CC2420_WRITE_FIFO_BUF(payload, payload_len);
#if CC2420_CONF_CHECKSUM
CC2420_WRITE_FIFO_BUF(&checksum, CHECKSUM_LEN);
#endif /* CC2420_CONF_CHECKSUM */
RELEASE_LOCK();
return 0;
}
/*---------------------------------------------------------------------------*/
static void
recv_uc(struct unicast_conn *c, const linkaddr_t *from)
{
struct cmd_msg *msg;
uint16_t crc;
int len;
msg = packetbuf_dataptr();
if(packetbuf_datalen() > 1 + CMDMSG_HDR_SIZE) {
/* First ensure that the old process is killed. */
process_exit(&shell_sendcmd_server_process);
len = packetbuf_datalen() - 1 - CMDMSG_HDR_SIZE;
/* Make sure that the incoming command is null-terminated. */
msg->sendcmd[len] = 0;
memcpy(&crc, &msg->crc, sizeof(crc));
if(crc == crc16_data((unsigned char *)msg->sendcmd, len, 0)) {
/* Start the server process with the incoming command. */
process_start(&shell_sendcmd_server_process, (void *)msg->sendcmd);
}
}
}
static void
send_page(struct deluge_object *obj, unsigned pagenum)
{
unsigned char buf[S_PAGE];
struct deluge_msg_packet pkt;
unsigned char *cp;
pkt.cmd = DELUGE_CMD_PACKET;
pkt.pagenum = pagenum;
pkt.version = obj->pages[pagenum].version;
pkt.packetnum = 0;
pkt.object_id = obj->object_id;
pkt.crc = 0;
read_page(obj, pagenum, buf);
/* Divide the page into packets and send them one at a time. */
for(cp = buf; cp + S_PKT <= (unsigned char *)&buf[S_PAGE]; cp += S_PKT) {
if(obj->tx_set & (1 << pkt.packetnum)) {
pkt.crc = crc16_data(cp, S_PKT, 0);
memcpy(pkt.payload, cp, S_PKT);
packetbuf_copyfrom(&pkt, sizeof(pkt));
broadcast_send(&deluge_broadcast);
}
pkt.packetnum++;
}
obj->tx_set = 0;
}
/*---------------------------------------------------------------------------*/
PROCESS_THREAD(shell_netcmd_process, ev, data)
{
struct trickle_msg *msg;
int len;
PROCESS_BEGIN();
/* Get the length of the command line, excluding a terminating NUL character. */
len = strlen((char *)data);
/* Check the length of the command line to see that it is small
enough to fit in a packet. We count with 32 bytes of header,
which may be a little too much, but at least we are on the safe
side. */
if(len > PACKETBUF_SIZE - 32) {
char buf[32];
snprintf(buf, sizeof(buf), "%d", len);
shell_output_str(&netcmd_command, "command line too large: ", buf);
} else {
packetbuf_clear();
msg = packetbuf_dataptr();
packetbuf_set_datalen(len + 1 + TRICKLEMSG_HDR_SIZE);
strcpy(msg->netcmd, data);
/* Terminate the string with a NUL character. */
msg->netcmd[len] = 0;
msg->crc = crc16_data(msg->netcmd, len, 0);
printf("netcmd sending '%s'\n", msg->netcmd);
trickle_send(&trickle);
}
PROCESS_END();
}
// Adds data to a response, returns the partial CRC
uint16_t ICACHE_FLASH_ATTR
CMD_ResponseBody(uint16_t crc_in, uint8_t* data, short len) {
short pad_len = len+3 - (len+3)%4; // round up to multiple of 4
CMD_ProtoWriteBuf((uint8_t*)&pad_len, 2);
crc_in = crc16_data((uint8_t*)&pad_len, 2, crc_in);
CMD_ProtoWriteBuf(data, len);
crc_in = crc16_data(data, len, crc_in);
if (pad_len > len) {
uint32_t temp = 0;
CMD_ProtoWriteBuf((uint8_t*)&temp, pad_len-len);
crc_in = crc16_data((uint8_t*)&temp, pad_len-len, crc_in);
}
return crc_in;
}
uint16_t ESP::request(uint16_t cmd, uint32_t callback, uint32_t _return, uint16_t argc)
{
uint16_t crc = 0;
_serial->write(0x7E);
write((uint8_t*)&cmd, 2);
crc = crc16_data((uint8_t*)&cmd, 2, crc);
write((uint8_t*)&callback, 4);
crc = crc16_data((uint8_t*)&callback, 4, crc);
write((uint8_t*)&_return, 4);
crc = crc16_data((uint8_t*)&_return, 4, crc);
write((uint8_t*)&argc, 2);
crc = crc16_data((uint8_t*)&argc, 2, crc);
return crc;
}
/*---------------------------------------------------------------------------*/
static int
read(void *buf, unsigned short bufsize)
{
int len = 0;
uint16_t radio_last_rx_crc;
uint8_t radio_last_rx_crc_ok = 1;
len = input_frame_buffer->u8PayloadLength;
if(len <= CHECKSUM_LEN) {
input_frame_buffer->u8PayloadLength = 0;
return 0;
} else {
len -= CHECKSUM_LEN;
/* Check CRC */
#if CRC_SW
uint16_t checksum = crc16_data(input_frame_buffer->uPayload.au8Byte, len, 0);
radio_last_rx_crc =
(uint16_t)(input_frame_buffer->uPayload.au8Byte[len + 1] << (uint16_t)8)
| input_frame_buffer->uPayload.au8Byte[len];
radio_last_rx_crc_ok = (checksum == radio_last_rx_crc);
if(!radio_last_rx_crc_ok) {
RIMESTATS_ADD(badcrc);
}
#endif /* CRC_SW */
if(radio_last_rx_crc_ok) {
/* If we are in poll mode we need to check the frame here */
if(poll_mode) {
if(frame_filtering &&
!is_packet_for_us(input_frame_buffer->uPayload.au8Byte, len, 0)) {
len = 0;
} else {
read_last_rssi();
}
}
if(len != 0) {
bufsize = MIN(len, bufsize);
memcpy(buf, input_frame_buffer->uPayload.au8Byte, bufsize);
RIMESTATS_ADD(llrx);
if(!poll_mode) {
/* Not in poll mode: packetbuf should not be accessed in interrupt context */
packetbuf_set_attr(PACKETBUF_ATTR_RSSI, radio_last_rssi);
packetbuf_set_attr(PACKETBUF_ATTR_LINK_QUALITY, radio_last_correlation);
}
}
} else {
len = 0;
}
/* Disable further read attempts */
input_frame_buffer->u8PayloadLength = 0;
}
return len;
}
void ESP::protoCompletedCb(void)
{
PACKET_CMD *cmd = (PACKET_CMD*)_proto.buf;
uint16_t crc = 0, argc, len, resp_crc;
uint8_t *data_ptr;
argc = cmd->argc;
data_ptr = (uint8_t*)&cmd->args ;
crc = crc16_data((uint8_t*)&cmd->cmd, 12, crc);
while(argc--){
len = *((uint16_t*)data_ptr);
crc = crc16_data(data_ptr, 2, crc);
data_ptr += 2;
while(len --){
crc = crc16_data(data_ptr, 1, crc);
data_ptr ++;
}
}
resp_crc = *(uint16_t*)data_ptr;
if(crc != resp_crc) {
INFO("ARDUINO: Invalid CRC");
return;
}
FP<void, void*> *fp;
if(cmd->callback != 0){
fp = (FP<void, void*>*)cmd->callback;
return_cmd = cmd->cmd;
return_value = cmd->_return;
if(fp->attached())
(*fp)((void*)cmd);
} else {
if(cmd->argc == 0) {
is_return = true;
return_cmd = cmd->cmd;
return_value = cmd->_return;
}
}
}
uint16_t ESP::request(uint16_t crc_in, uint8_t* data, uint16_t len)
{
uint8_t temp = 0;
uint16_t pad_len = len;
while(pad_len % 4 != 0)
pad_len++;
write((uint8_t*)&pad_len, 2);
crc_in = crc16_data((uint8_t*)&pad_len, 2, crc_in);
while(len --){
write(*data);
crc_in = crc16_data((uint8_t*)data, 1, crc_in);
data ++;
if(pad_len > 0) pad_len --;
}
while(pad_len --){
write(temp);
crc_in = crc16_data((uint8_t*)&temp, 1, crc_in);
}
return crc_in;
}
static void ICACHE_FLASH_ATTR
protoCompletedCb()
{
uint16_t crc = 0, argc, len, resp_crc, argn = 0;
uint8_t *data_ptr;
PACKET_CMD *packet;
packet = (PACKET_CMD*)protoRxBuf;
data_ptr = (uint8_t*)&packet->args ;
crc = crc16_data((uint8_t*)&packet->cmd, 12, crc);
argc = packet->argc;
INFO("CMD: %d, cb: %d, ret: %d, argc: %d\r\n", packet->cmd, packet->callback, packet->_return, packet->argc);
while(argc--){
len = *((uint16_t*)data_ptr);
INFO("Arg[%d], len: %d:", argn++, len);
crc = crc16_data(data_ptr, 2, crc);
data_ptr += 2;
crc = crc16_data(data_ptr, len, crc);
while(len --){
INFO("%02X-", *data_ptr);
data_ptr ++;
}
INFO("\r\n\r\n");
}
resp_crc = *(uint16_t*)data_ptr;
INFO("Read CRC: %04X, calculated crc: %04X\r\n", resp_crc, crc);
if(crc != resp_crc) {
INFO("ESP: Invalid CRC\r\n");
INFO("");
return;
}
CMD_Exec(commands, packet);
}
/*---------------------------------------------------------------------------*/
static void
recv_collect(const rimeaddr_t *originator, u8_t seqno, u8_t hops)
{
struct collect_msg *collect_msg;
rtimer_clock_t latency;
int len;
collect_msg = packetbuf_dataptr();
#if TIMESYNCH_CONF_ENABLED
latency = timesynch_time() - collect_msg->timestamp;
#else
latency = 0;
#endif
if(waiting_for_collect) {
struct {
uint16_t len;
uint16_t originator;
uint16_t seqno;
uint16_t hops;
uint16_t latency;
} msg;
if(packetbuf_datalen() >= COLLECT_MSG_HDRSIZE) {
len = packetbuf_datalen() - COLLECT_MSG_HDRSIZE;
if(collect_msg->crc == crc16_data(collect_msg->data, len, 0)) {
msg.len = 5 + (packetbuf_datalen() - COLLECT_MSG_HDRSIZE) / 2;
rimeaddr_copy((rimeaddr_t *)&msg.originator, originator);
msg.seqno = seqno;
msg.hops = hops;
msg.latency = latency;
/* printf("recv_collect datalen %d\n", packetbuf_datalen());*/
shell_output(&collect_command,
&msg, sizeof(msg),
collect_msg->data, packetbuf_datalen() - COLLECT_MSG_HDRSIZE);
}
}
} else if(waiting_for_nodes) {
char buf[40];
snprintf(buf, sizeof(buf), "%d.%d, %d hops, latency %lu ms",
originator->u8[0], originator->u8[1],
hops, (1000L * latency) / RTIMER_ARCH_SECOND);
shell_output_str(&nodes_command, "Message from node ", buf);
messages_received++;
}
}
ICACHE_FLASH_ATTR
uint16 CMD_ResponseBody(uint16_t crc_in, uint8_t* data, uint16_t len)
{
uint8_t temp = 0;
uint16_t pad_len = len;
while(pad_len % 4 != 0)
pad_len++;
CMD_ProtoWriteBuf((uint8_t*)&pad_len, 2);
crc_in = crc16_data((uint8_t*)&pad_len, 2, crc_in);
while(len --){
CMD_ProtoWrite(*data);
crc_in = crc16_data((uint8_t*)data, 1, crc_in);
data ++;
if(pad_len > 0) pad_len --;
}
while(pad_len --){
CMD_ProtoWrite(temp);
crc_in = crc16_data((uint8_t*)&temp, 1, crc_in);
}
return crc_in;
}
/*---------------------------------------------------------------------------*/
PROCESS_THREAD(shell_sendcmd_process, ev, data)
{
struct cmd_msg *msg;
int len;
linkaddr_t addr;
const char *nextptr;
char buf[32];
PROCESS_BEGIN();
addr.u8[0] = shell_strtolong(data, &nextptr);
if(nextptr == data || *nextptr != '.') {
shell_output_str(&sendcmd_command,
"sendcmd <node addr>: receiver must be specified", "");
PROCESS_EXIT();
}
++nextptr;
addr.u8[1] = shell_strtolong(nextptr, &nextptr);
snprintf(buf, sizeof(buf), "%d.%d", addr.u8[0], addr.u8[1]);
shell_output_str(&sendcmd_command, "Sending command to ", buf);
/* Get the length of the command line, excluding a terminating NUL character. */
len = strlen((char *)nextptr);
/* Check the length of the command line to see that it is small
enough to fit in a packet. We count with 32 bytes of header,
which may be a little too much, but at least we are on the safe
side. */
if(len > PACKETBUF_SIZE - 32) {
snprintf(buf, sizeof(buf), "%d", len);
shell_output_str(&sendcmd_command, "command line too large: ", buf);
PROCESS_EXIT();
}
packetbuf_clear();
msg = packetbuf_dataptr();
packetbuf_set_datalen(len + 1 + CMDMSG_HDR_SIZE);
strcpy(msg->sendcmd, nextptr);
/* Terminate the string with a NUL character. */
msg->sendcmd[len] = 0;
msg->crc = crc16_data((unsigned char *)msg->sendcmd, len, 0);
/* printf("sendcmd sending '%s'\n", msg->sendcmd);*/
unicast_send(&uc, &addr);
PROCESS_END();
}
static void
init_page(struct deluge_object *obj, int pagenum, int have)
{
struct deluge_page *page;
unsigned char buf[S_PAGE];
page = &obj->pages[pagenum];
page->flags = 0;
page->last_request = 0;
page->last_data = 0;
if(have) {
page->version = obj->version;
page->packet_set = ALL_PACKETS;
page->flags |= PAGE_COMPLETE;
read_page(obj, pagenum, buf);
page->crc = crc16_data(buf, S_PAGE, 0);
} else {
page->version = 0;
page->packet_set = 0;
}
}
// SLIP process a packet or a bunch of debug console chars
static void ICACHE_FLASH_ATTR
slip_process() {
if (slip_len > 2) {
// proper SLIP packet, invoke command processor after checking CRC
//os_printf("SLIP: rcv %d\n", slip_len);
uint16_t crc = crc16_data((uint8_t*)slip_buf, slip_len-2, 0);
uint16_t rcv = ((uint16_t)slip_buf[slip_len-2]) | ((uint16_t)slip_buf[slip_len-1] << 8);
if (crc == rcv) {
cmdParsePacket((uint8_t*)slip_buf, slip_len-2);
} else {
os_printf("SLIP: bad CRC, crc=%04x rcv=%04x len=%d\n", crc, rcv, slip_len);
for (short i=0; i<slip_len; i++) {
if (slip_buf[i] >= ' ' && slip_buf[i] <= '~') {
DBG("%c", slip_buf[i]);
} else {
DBG("\\%02X", slip_buf[i]);
}
}
DBG("\n");
}
}
}
/*---------------------------------------------------------------------------*/
PROCESS_THREAD(shell_send_process, ev, data)
{
struct shell_input *input;
int len;
struct collect_msg *msg;
PROCESS_BEGIN();
while(1) {
PROCESS_WAIT_EVENT_UNTIL(ev == shell_event_input);
input = data;
len = input->len1 + input->len2;
if(len == 0) {
PROCESS_EXIT();
}
if(len < PACKETBUF_SIZE) {
packetbuf_clear();
packetbuf_set_datalen(len + COLLECT_MSG_HDRSIZE);
msg = packetbuf_dataptr();
memcpy(msg->data, input->data1, input->len1);
memcpy(msg->data + input->len1, input->data2, input->len2);
#if TIMESYNCH_CONF_ENABLED
msg->timestamp = timesynch_time();
#else
msg->timestamp = 0;
#endif
msg->crc = crc16_data(msg->data, len, 0);
/* printf("Sending %d bytes\n", len);*/
collect_send(&collect, COLLECT_REXMITS);
}
}
PROCESS_END();
}
/*!
*\brief This callback is called by the kernel when a packet is
* received on the epoch-syncer broadcast channel. In here we compute
* the time offsets that we use to control the epoch timing, e.g. by
* delaying or anticipating the next epoch.
*/
static void __broadcast_recv_cb(struct broadcast_conn *ptr, const rimeaddr_t *sender) {
int datalen;
int distance_nr_epochs;
long int now, offset;
struct epoch_sync_packet packet;
/*
* Get the current time first-thing; this will be used in the
* computation of the epoch offset
*/
now = clock_time();
/*
* TODO: we could use the packet rssi to seed tha random number generator
*
* ! iff the radio operates on lower power modes: otherwise the rssi is the same
* constant all the time
*
* if (0) {
* uint16_t rssi;
*
* rssi = packetbuf_attr(PACKETBUF_ATTR_RSSI);
* printf("rssi=0x%.4x\n", rssi);
* }
*/
datalen = packetbuf_datalen();
if (datalen != sizeof(struct epoch_sync_packet)) {
/*
* xfer corruption; happens rarely.
*/
trace("@%d sync xfer corruption, datalen %d\n", __epoch_syncer.epoch, datalen);
return;
}
/*
* Copy the received packet into local storage
*
* ! the pointer returned by packetbuf_dataptr() is not necesserely aligned
* wrt the mcu platform requirements, thus we cannot simply dereference
* it into a 'struct epoch_sync_packet'. The msp430, in particular, can
* have undefined behaviour when loading from unaligned addresses.
*/
memcpy(&packet, packetbuf_dataptr(), datalen);
#ifdef XFER_CRC16
{
uint16_t recv_crc16, crc16;
/*
* Compute the received packet crc with the .crc16 field zeroed
*/
recv_crc16 = packet.crc16;
packet.crc16 = 0;
crc16 = crc16_data((const unsigned char *)&packet, sizeof(struct epoch_sync_packet), 0);
if (recv_crc16 != crc16) {
/*
* xfer corruption; happens rarely.
*/
trace("@%d sync xfer crc mismatch\n", __epoch_syncer.epoch);
return;
}
}
#endif
/*
* The packet is valid: compute the offset between our and the
* other node's `time to end of epoch`.
*
* ! If we are sufficiently out-of-sync than this node and the
* sender node are currently in different epochs and we need to
* special case a bit.
*/
offset = 0;
distance_nr_epochs = __epoch_syncer.epoch - packet.epoch;
if (distance_nr_epochs > 0) {
/*
* We are going too fast but we don't care, we simply let slower
* nodes adjust to us.
*
* ! don't trace the sender and return.
*/
printf("epoch-syncer: discarding packet from epoch %d at epoch %d\n", packet.epoch, __epoch_syncer.epoch);
return;
} else if (distance_nr_epochs < 0) {
long int time_to_epoch_end;
/*
* We are going too slow !
*/
if (distance_nr_epochs == -1) {
assert(__epoch_syncer.epoch_end_time > now);
time_to_epoch_end = (long int)__epoch_syncer.epoch_end_time - now;
offset = time_to_epoch_end + packet.time_from_epoch_start;
} else {
offset = __epoch_syncer.epoch_interval*(packet.epoch - __epoch_syncer.epoch);
}
} else {
long int time_from_epoch_start, time_to_epoch_end;
/*
* Both this node and the sender node are in the same epoch.
*/
if (now > __epoch_syncer.epoch_end_time) {
/*
* The epoch is expired but the epoch counter has not been updated yet.
* If this happens there is a *bug*: something is delaying the epoch_timer `is-expired`
* check in the process main loop.
*
* ! we can't and don't want to recover from this situation: go fix your changes in the code :)
*/
printf("@%d BUG epoch-syncer: packet received after end-of-epoch %ld\n", __epoch_syncer.epoch, now - (long int)__epoch_syncer.epoch_end_time);
return;
}
/*
* compute this node's `time from epoch start` and `time to epoch end`
*/
assert(now <= __epoch_syncer.epoch_end_time);
assert(__epoch_syncer.epoch_start_time <= now);
assert(__epoch_syncer.epoch_end_time >__epoch_syncer.epoch_start_time);
time_from_epoch_start = now - __epoch_syncer.epoch_start_time;
assert(time_from_epoch_start >= 0);
assert(time_from_epoch_start < (__epoch_syncer.epoch_end_time -__epoch_syncer.epoch_start_time));
time_to_epoch_end = __epoch_syncer.epoch_end_time - now;
/*
* compute the `time to epoch end` offset between this node and the sender node
*/
offset = time_to_epoch_end - packet.time_to_epoch_end;
/*
* linearly interpolate to guess the eventual offset at end of this node epoch
*/
offset = (offset*__epoch_syncer.epoch_interval)/time_from_epoch_start;
}
/* update offset statistics */
__epoch_syncer.max_offset = max(offset, __epoch_syncer.max_offset);
__epoch_syncer.min_offset = min(offset, __epoch_syncer.min_offset);
/*
* Accumulate the offsets: from this sum the `offset-average` can be computed.
* This average is then used to adjust the timing of the next epoch.
*/
__epoch_syncer.sum_sync_offsets += offset;
__epoch_syncer.nr_offsets++;
#ifdef TRACK_CONNECTIONS
/* trace the xfer */
connection_track(CONNECTION_TRACK_SYNC, packet.board_id16, __epoch_syncer.epoch);
#endif
}
static void
handle_packet(struct deluge_msg_packet *msg)
{
struct deluge_page *page;
uint16_t crc;
struct deluge_msg_packet packet;
memcpy(&packet, msg, sizeof(packet));
PRINTF("Incoming packet for object id %u, version %u, page %u, packet num %u!\n",
(unsigned)packet.object_id, (unsigned)packet.version,
(unsigned)packet.pagenum, (unsigned)packet.packetnum);
if(packet.pagenum != current_object.current_rx_page) {
return;
}
if(packet.version != current_object.version) {
neighbor_inconsistency = 1;
}
page = ¤t_object.pages[packet.pagenum];
if(packet.version == page->version && !(page->flags & PAGE_COMPLETE)) {
memcpy(¤t_object.current_page[S_PKT * packet.packetnum],
packet.payload, S_PKT);
crc = crc16_data(packet.payload, S_PKT, 0);
if(packet.crc != crc) {
PRINTF("packet crc: %hu, calculated crc: %hu\n", packet.crc, crc);
return;
}
page->last_data = clock_time();
page->packet_set |= (1 << packet.packetnum);
if(page->packet_set == ALL_PACKETS) {
/* This is the last packet of the requested page; stop streaming. */
packetbuf_set_attr(PACKETBUF_ATTR_PACKET_TYPE,
PACKETBUF_ATTR_PACKET_TYPE_STREAM_END);
write_page(¤t_object, packet.pagenum, current_object.current_page);
page->version = packet.version;
page->flags = PAGE_COMPLETE;
PRINTF("Page %u completed\n", packet.pagenum);
current_object.current_rx_page++;
if(packet.pagenum == OBJECT_PAGE_COUNT(current_object) - 1) {
current_object.version = current_object.update_version;
leds_on(LEDS_RED);
PRINTF("Update completed for object %u, version %u\n",
(unsigned)current_object.object_id, packet.version);
} else if(current_object.current_rx_page < OBJECT_PAGE_COUNT(current_object)) {
if(ctimer_expired(&rx_timer)) {
ctimer_set(&rx_timer,
CONST_OMEGA * ESTIMATED_TX_TIME + (random_rand() % T_R),
send_request, ¤t_object);
}
}
/* Deluge R.3 */
transition(DELUGE_STATE_MAINTAIN);
} else {
/* More packets to come. Put lower layers in streaming mode. */
packetbuf_set_attr(PACKETBUF_ATTR_PACKET_TYPE,
PACKETBUF_ATTR_PACKET_TYPE_STREAM);
}
}
}
PROCESS_THREAD(proc_epoch_syncer, ev, data) {
static struct etimer send_timer;
static struct etimer epoch_timer;
static const struct broadcast_callbacks broadcast_cbs = {__broadcast_recv_cb, __broadcast_sent_cb};
static struct broadcast_conn conn;
PROCESS_EXITHANDLER(broadcast_close(&conn));
PROCESS_BEGIN();
#ifdef TRACK_CONNECTIONS
/* Log the node id */
printf("board-id64 0x%.16llx\n", board_get_id64());
#endif
#ifdef XFER_CRC16
/* Log the node id */
printf("xfer crc16\n");
#endif
printf("epoch interval %ld ticks\n", EPOCH_INTERVAL);
/*
* Alloc the two syncer events
*/
evt_epoch_synced = process_alloc_event();
evt_end_of_epoch = process_alloc_event();
/*
* Open a `connection` on the syncer broadcasting channel
*/
broadcast_open(&conn, BROADCAST_CHANNEL_TIMESYNC, &broadcast_cbs);
/*
* init the epoch-syncer instance
*/
epoch_syncer_init(&__epoch_syncer);
/*
* This is the main syncer loop. Initially we try to sync the
* epoch between nodes without concurrently running any other
* algo. After a period, at which time the network is synced,
* we start generating epoch events which can be
* consumed by, e.g., the estimator process.
*/
etimer_set(&epoch_timer, __epoch_syncer.epoch_interval);
__epoch_syncer.epoch_start_time = clock_time();
__epoch_syncer.epoch_end_time = etimer_expiration_time(&epoch_timer);
while (1) {
/*
* The start of a new epoch !
*/
epoch_syncer_at_epoch_start(&__epoch_syncer);
clock_time_t now;
clock_time_t time_to_epoch_end;
now = clock_time();
assert(__epoch_syncer.epoch_end_time == etimer_expiration_time(&epoch_timer));
assert(__epoch_syncer.epoch_end_time > now);
time_to_epoch_end = __epoch_syncer.epoch_end_time - now;
/*
* Setup a random wait time before sending the sync packet
*
* ! we cannot let send_timer delay the epoch_timer, especially
* when the next `end-of-epoch-time` has been anticipated by a lot
* (this can happen at startup)
*/
if (time_to_epoch_end > __epoch_syncer.epoch_sync_start) {
long int send_wait;
long int send_wait_rnd;
long int rnd;
rnd = rand();
send_wait_rnd = (unsigned)rnd % (unsigned) __epoch_syncer.epoch_sync_xfer_interval;
send_wait = __epoch_syncer.epoch_sync_start + send_wait_rnd;
assert(send_wait >= __epoch_syncer.epoch_sync_start);
assert(send_wait <= __epoch_syncer.epoch_sync_start + __epoch_syncer.epoch_sync_xfer_interval);
if (send_wait > time_to_epoch_end)
send_wait = __epoch_syncer.epoch_sync_start;
assert(send_wait < time_to_epoch_end);
etimer_set(&send_timer, send_wait);
PROCESS_WAIT_UNTIL(etimer_expired(&send_timer));
/*
* Acquire the radio lock
*
* ! we don't use WAIT/YIELD_UNTIL() because
* 1) we do not want to yield if we can acquire the lock on the first try
* 2) no kernel signal is generated when the lock is released (we would `deadlock')
*/
do {
if (!radio_trylock())
break;
PROCESS_PAUSE();
} while (1);
{
clock_time_t now;
struct epoch_sync_packet packet;
/*
* broadcast the sync packet
*
* ! We put this part into its own block since non static stack
* variables/allocations in the parent block wouldn't get preserved trough
* kernel calls (e.g. the PROCESS_PAUSE() a few lines above)
*/
#ifdef TRACK_CONNECTIONS
packet.board_id16 = board_get_id16();
#endif
packet.epoch = __epoch_syncer.epoch;
now = clock_time();
assert(now > __epoch_syncer.epoch_start_time);
assert(__epoch_syncer.epoch_end_time > now);
packet.time_from_epoch_start = now - __epoch_syncer.epoch_start_time;
packet.time_to_epoch_end = __epoch_syncer.epoch_end_time - now;
#ifdef XFER_CRC16
/*
* Compute the packet crc with the .crc16 field zeroed
*/
{
uint16_t crc16;
packet.crc16 = 0;
crc16 = crc16_data((const unsigned char *)&packet, sizeof(struct epoch_sync_packet), 0);
packet.crc16 = crc16;
}
#endif
packetbuf_copyfrom(&packet, sizeof(struct epoch_sync_packet));
broadcast_send(&conn);
}
} else {
printf("epoch-syncer: skipping sync send\n");
}
/*
* We cannot YIELD here: if epoch_timer has already expired there won't be
* any event to wake us up.
*
* FIXME: if we get here and the epoch timer has fired
* already print by how much we are late: this can be terribly useful
* to trace bugs in the epoch sync code or the kernel.
*/
if (etimer_expired(&epoch_timer)) {
long int now;
now = clock_time();
assert(now > __epoch_syncer.epoch_end_time);
} else {
char do_wait;
do_wait = 1;
if (__epoch_syncer.sum_sync_offsets) {
long int avg_offset = __epoch_syncer.sum_sync_offsets / __epoch_syncer.nr_offsets;
const long int threshold = CLOCK_SECOND;
if (avg_offset > threshold) {
/*
* if we are late don't wait until the timer expires
* ! this migth give us the opportunity to re-enter the right sync_xfer_interval
*/
do_wait = 0;
} else if (avg_offset < -threshold) {
/*
* we are too fast, delay end of epoch
*/
clock_time_t now;
clock_time_t time_to_epoch_end;
now = clock_time();
assert(__epoch_syncer.epoch_end_time == etimer_expiration_time(&epoch_timer));
assert(__epoch_syncer.epoch_end_time > now);
time_to_epoch_end = __epoch_syncer.epoch_end_time - now;
long int delay = time_to_epoch_end + (-avg_offset/2);
static struct etimer delay_timer;
trace("epoch-syncer: delaying end-of-epoch by %ld ticks\n", (-avg_offset/2));
etimer_set(&delay_timer, delay);
__epoch_syncer.epoch_end_time += (-avg_offset/2);
PROCESS_WAIT_UNTIL(etimer_expired(&delay_timer));
}
}
if (do_wait) {
PROCESS_WAIT_UNTIL(etimer_expired(&epoch_timer));
} else {
trace("epoch-syncer: not waiting for end-of-epoch\n");
}
}
trace("epoch-syncer: epoch %d ended\n", __epoch_syncer.epoch);
#ifdef TRACK_CONNECTIONS
connection_print_and_zero(CONNECTION_TRACK_SYNC, __epoch_syncer.epoch);
#endif
/*
* Re-Set the end-of-epoch timer
*/
if (__epoch_syncer.epoch == EPOCHS_UNTIL_SYNCED) {
/*
* We have hopefully achieved sync at this point
*
* 1) update the epoch timings, and set the epoch timer
*
* 2) signal the size-estimator process that the epoch is now synced
*/
__epoch_syncer.epoch_interval = EPOCH_INTERVAL;
__epoch_syncer.epoch_sync_start = EPOCH_SYNC_START;
__epoch_syncer.epoch_sync_xfer_interval = EPOCH_SYNC_XFER_INTERVAL;
etimer_stop(&epoch_timer);
etimer_set(&epoch_timer, __epoch_syncer.epoch_interval);
/*
* The epoch timer has been re-set: update the time until the next epoch end
* Increase the epoch count.
* ! these operations must happen in a block which cannot block in kernel calls
*/
__epoch_syncer.epoch_start_time = clock_time();
__epoch_syncer.epoch_end_time = etimer_expiration_time(&epoch_timer);
__epoch_syncer.epoch++;
process_post(&proc_size_estimator, evt_epoch_synced, NULL);
} else {
/*
* Re-set and adjust the epoch timer using the data received trough sync packets
* (in this epoch)
*
* ! using re-set (instead of, e.g., restart) is important here in order to avoid
* drifting
*/
etimer_reset(&epoch_timer);
/*
* The epoch timer has been re-set: update the time until the next epoch end
* Increase the epoch count.
* ! these operations must happen in a block which cannot block in kernel calls
*/
//__epoch_syncer.epoch_start_time = epoch_timer.timer.start;
__epoch_syncer.epoch_start_time = clock_time();
__epoch_syncer.epoch_end_time = etimer_expiration_time(&epoch_timer);
__epoch_syncer.epoch++;
if (__epoch_syncer.sum_sync_offsets) {
long int avg_offset = __epoch_syncer.sum_sync_offsets / __epoch_syncer.nr_offsets;
const long int threshold = 1;//(CLOCK_SECOND/32);//*3;
#if __CONTIKI_NETSTACK_RDC==__CONTIKI_NETSTACK_RDC_NULL
const int tx_delay = 0;
#elif __CONTIKI_NETSTACK_RDC==__CONTIKI_NETSTACK_RDC_CXMAC
/*
* When the cxmac RDC is used we must consider an added delay due to the fact that when
* other nodes radios are turned off the sync packet must be re-sent.
*/
const int tx_delay = 8;
#endif
/*
* estimate the avg tx delay
*/
avg_offset += tx_delay;
trace("epoch-syncer: sync offsets %d ~ %ld < %ld < %ld\n", __epoch_syncer.nr_offsets, __epoch_syncer.min_offset + tx_delay, avg_offset, __epoch_syncer.max_offset+tx_delay);
if ((avg_offset < -threshold) || (avg_offset > threshold)) {
clock_time_t new_expiration_time;
const long int adjust_threshold = CLOCK_SECOND/2;
long int adjust;
/*
* feedback control the next expiration time
*/
adjust = -avg_offset/2;
adjust = min(adjust, adjust_threshold);
adjust = max(adjust, -adjust_threshold);
if (adjust)
etimer_adjust(&epoch_timer, adjust);
new_expiration_time = etimer_expiration_time(&epoch_timer);
__epoch_syncer.epoch_end_time = new_expiration_time;
}
}
if (__epoch_syncer.epoch > EPOCHS_UNTIL_SYNCED) {
/*
* Signal the estimator-process that this epoch has ended
*/
process_post(&proc_size_estimator, evt_end_of_epoch, NULL);
}
}
}
PROCESS_END();
}
/*---------------------------------------------------------------------------*/
int
nrf24l01_read(void *buf, unsigned short bufsize)
{
uint8_t *framep;
// uint8_t footer[2];
uint8_t len;
#if RF230_CONF_CHECKSUM
uint16_t checksum;
#endif /* RF230_CONF_CHECKSUM */
#if RF230_CONF_TIMESTAMPS
struct timestamp t;
#endif /* RF230_CONF_TIMESTAMPS */
PRINTF("rf230_read: %u bytes lqi %u crc %u\n",rxframe.length,rxframe.lqi,rxframe.crc);
#if DEBUG>1
for (len=0;len<rxframe.length;len++) PRINTF(" %x",rxframe.data[len]);PRINTF("\n");
#endif
if (rxframe.length==0) {
return 0;
}
#if RF230_CONF_TIMESTAMPS
bomb
if(interrupt_time_set) {
rf230_time_of_arrival = interrupt_time;
interrupt_time_set = 0;
} else {
rf230_time_of_arrival = 0;
}
rf230_time_of_departure = 0;
#endif /* RF230_CONF_TIMESTAMPS */
GET_LOCK();
// if(rxframe.length > RF230_MAX_PACKET_LEN) {
// // Oops, we must be out of sync.
// flushrx();
// RIMESTATS_ADD(badsynch);
// RELEASE_LOCK();
// return 0;
// }
//hal returns two extra bytes containing the checksum
//below works because auxlen is 2
len = rxframe.length;
if(len <= AUX_LEN) {
// flushrx();
RIMESTATS_ADD(tooshort);
RELEASE_LOCK();
return 0;
}
if(len - AUX_LEN > bufsize) {
// flushrx();
RIMESTATS_ADD(toolong);
RELEASE_LOCK();
return 0;
}
/* Transfer the frame, stripping the checksum */
framep=&(rxframe.data[0]);
memcpy(buf,framep,len-2);
/* Clear the length field to allow buffering of the next packet */
rxframe.length=0;
// framep+=len-AUX_LEN+2;
#if RADIOSTATS
RF230_receivepackets++;
#endif
#if RF230_CONF_CHECKSUM
bomb
memcpy(&checksum,framep,CHECKSUM_LEN);
framep+=CHECKSUM_LEN;
#endif /* RF230_CONF_CHECKSUM */
#if RF230_CONF_TIMESTAMPS
bomb
memcpy(&t,framep,TIMESTAMP_LEN);
framep+=TIMESTAMP_LEN;
#endif /* RF230_CONF_TIMESTAMPS */
// memcpy(&footer,framep,FOOTER_LEN);
#if RF230_CONF_CHECKSUM
bomb
if(checksum != crc16_data(buf, len - AUX_LEN, 0)) {
PRINTF("rf230: checksum failed 0x%04x != 0x%04x\n",
checksum, crc16_data(buf, len - AUX_LEN, 0));
}
if(footer[1] & FOOTER1_CRC_OK &&
checksum == crc16_data(buf, len - AUX_LEN, 0)) {
#else
if (rxframe.crc) {
#endif /* RF230_CONF_CHECKSUM */
#if RADIOSTATS
RF230_rsigsi=hal_subregister_read( SR_RSSI );
#endif
//nick packetbuf_set_attr(PACKETBUF_ATTR_RSSI, hal_subregister_read( SR_RSSI ));
//nick packetbuf_set_attr(PACKETBUF_ATTR_LINK_QUALITY, rxframe.lqi);
RIMESTATS_ADD(llrx);
#if RF230_CONF_TIMESTAMPS
bomb
rf230_time_of_departure =
t.time +
setup_time_for_transmission +
(total_time_for_transmission * (len - 2)) / total_transmission_len;
rf230_authority_level_of_sender = t.authority_level;
packetbuf_set_attr(PACKETBUF_ATTR_TIMESTAMP, t.time);
#endif /* RF230_CONF_TIMESTAMPS */
} else {
PRINTF("rf230: Bad CRC\n");
#if RADIOSTATS
RF230_receivefail++;
#endif
RIMESTATS_ADD(badcrc);
len = AUX_LEN;
}
// if (?)
/* Another packet has been received and needs attention. */
// process_poll(&nrf24l01_process);
// }
RELEASE_LOCK();
if(len < AUX_LEN) {
return 0;
}
return len - AUX_LEN;
}
/*---------------------------------------------------------------------------*/
void
nrf24l01_init(uint8_t mode)
{
rf_mode = mode;
/* Initialize Hardware Abstraction Layer. */
//hal_init();
//init the spi functions
spi_init();
SPI_CHIP_ENABLE();
if(RF_TX_MODE == mode) //tx mode
{
SPI_WRITE_REG(WRITE_REG, 0x0C); //RX_DR, TX_DS, MAX_RT interrupts enabled, CRC enabled, CRC encoding with 2bytes and as PTX
//SPI_WRITE_REG(WRITE_REG+EN_AA, 0x3F); //Enable auto-acknowledge for all data pipe
//SPI_WRITE_REG(WRITE_REG+EN_RXADDR, 0x01); //Enable RX address data pipe 0, reset value is 0x03 (data pipe 0 and 1)
//SPI_WRITE_REG(WRITE_REG+SETUP_AW, 0x03); //Setup of address width, reset value is 0x33--5 bytes
SPI_WRITE_REG(WRITE_REG+SETUP_RETR, 0xFF); //Set auto-retransmision, ARD(auto retransmit delay): 1111, ARC(auto retransmit count): 1111
//SPI_WRITE_REG(WRITE_REG+RF_CH, 0x02); //RF Channel 2 (default, not really needed)
//SPI_WRITE_REG(WRITE_REG+RF_SETUP, 0x03); //Air data rate 1Mbit, -12dBm, Setup LNA
//SPI_WRITE_BUF(WRITE_REG+RX_ADDR_P0, (uint8_t*)&TX_ADDRESS, ADDR_WIDTH); //Set receive address to receive aut-ACK, it is equal to TX_ADDR if enbel enhanced shock burst
//SPI_WRITE_BUF(WRITE_REG+TX_ADDR, (uint8_t*)&TX_ADDRESS, ADDR_WIDTH); //Set transmit address: 0xE7E7E7E7E7
SPI_WRITE_REG(WRITE_REG+RX_PW_P0, 0x04); // 4 byte receive payload
//the next 2 commands are relative with dynamic payload lenght, you need disable them if use static payload length
//enable dynamic payload length, enable dynamic ACK in specific package(then you can
//use command W_TX_PAYLOAD_NOACK to set a specfic package that needn't wait for ACK)
SPI_WRITE_REG(WRITE_REG+DYNPD, 0x01); //as PTX, at least enable pipe 0
SPI_WRITE_REG(WRITE_REG+FEATURE, 0x05);
//SPI_WRITE_REG(WRITE_REG, 0x0E); //power upr
}
else //rx mode
{
SPI_WRITE_REG(WRITE_REG, 0x0D); //RX_DR, TX_DS, MAX_RT interrupts enabled, CRC enabled, CRC encoding with 2bytes and as PRX
//SPI_WRITE_REG(WRITE_REG+EN_AA, 0x3F); //Enable auto-acknowledge for all data pipes(0-5)
SPI_WRITE_REG(WRITE_REG+EN_RXADDR, 0x3F); //Enable RX address for all data pipes(0-5)
//SPI_WRITE_REG(WRITE_REG+SETUP_AW, 0x03); //Setup of address width, reset value is 0x33--5 bytes
SPI_WRITE_REG(WRITE_REG+SETUP_RETR, 0xFF); //Set auto-retransmision, ARD(auto retransmit delay): 1111, ARC(auto retransmit count): 1111
//SPI_WRITE_REG(WRITE_REG+RF_CH, 0x02); //RF Channel 2 (default, not really needed)
//SPI_WRITE_REG(WRITE_REG+RF_SETUP, 0x03); //Air data rate 1Mbit, -12dBm, Setup LNA
//SPI_WRITE_BUF(WRITE_REG+RX_ADDR_P0, (uint8_t*)&TX_ADDRESS, ADDR_WIDTH); //Set receive address for pipe0
//SPI_WRITE_BUF(WRITE_REG+RX_ADDR_P1, (uint8_t*)&RX_ADDRESS, ADDR_WIDTH); //Set receive address for pipe1
//SPI_WRITE_REG(WRITE_REG+RX_ADDR_P2, 0XC3); //Set receive address for pipe2
//SPI_WRITE_REG(WRITE_REG+RX_ADDR_P3, 0XC4); //Set receive address for pipe3
//SPI_WRITE_REG(WRITE_REG+RX_ADDR_P4, 0XC5); //Set receive address for pipe4
//SPI_WRITE_REG(WRITE_REG+RX_ADDR_P5, 0XC6); //Set receive address for pipe5
SPI_WRITE_REG(WRITE_REG+RX_PW_P0, 0x04); // 4 byte receive payload for pipe 0
SPI_WRITE_REG(WRITE_REG+RX_PW_P1, 0x04); // 4 byte receive payload
SPI_WRITE_REG(WRITE_REG+RX_PW_P2, 0x04); // 4 byte receive payload
SPI_WRITE_REG(WRITE_REG+RX_PW_P3, 0x04); // 4 byte receive payload
SPI_WRITE_REG(WRITE_REG+RX_PW_P4, 0x04); // 4 byte receive payload
SPI_WRITE_REG(WRITE_REG+RX_PW_P5, 0x04); // 4 byte receive payload for pipe 5
//don't use static payload length
/*SPI_WRITE_REG(WRITE_REG+RX_PW_P0, 0xFF); //data pipe 0, number of bytes: 32
SPI_WRITE_REG(WRITE_REG+RX_PW_P1, 0xFF); //data pipe 1, number of bytes: 32
SPI_WRITE_REG(WRITE_REG+RX_PW_P2, 0xFF); //data pipe 2, number of bytes: 32
SPI_WRITE_REG(WRITE_REG+RX_PW_P3, 0xFF); //data pipe 3, number of bytes: 32
SPI_WRITE_REG(WRITE_REG+RX_PW_P4, 0xFF); //data pipe 4, number of bytes: 32
SPI_WRITE_REG(WRITE_REG+RX_PW_P5, 0xFF); //data pipe 5, number of bytes: 32
*/
SPI_WRITE_REG(WRITE_REG+DYNPD, 0x3F); //as PRX, enable all pipes
SPI_WRITE_REG(WRITE_REG+FEATURE, 0x05); //enable dynamic payload length
//SPI_WRITE_REG(WRITE_REG, 0x0F); //power upr
}
SPI_CHIP_DISABLE();
/* Start the packet receive process */
process_start(&nrf24l01_process, NULL);
}
/*---------------------------------------------------------------------------*/
static int
cc2420_read(void *buf, unsigned short bufsize)
{
uint8_t footer[2];
uint8_t len;
#if CC2420_CONF_CHECKSUM
uint16_t checksum;
#endif /* CC2420_CONF_CHECKSUM */
if(!CC2420_FIFOP_IS_1) {
return 0;
}
/* if(!pending) {
return 0;
}*/
pending = 0;
GET_LOCK();
cc2420_packets_read++;
getrxbyte(&len);
if(len > CC2420_MAX_PACKET_LEN) {
/* Oops, we must be out of sync. */
flushrx();
RIMESTATS_ADD(badsynch);
RELEASE_LOCK();
return 0;
}
if(len <= AUX_LEN) {
flushrx();
RIMESTATS_ADD(tooshort);
RELEASE_LOCK();
return 0;
}
if(len - AUX_LEN > bufsize) {
flushrx();
RIMESTATS_ADD(toolong);
RELEASE_LOCK();
return 0;
}
getrxdata(buf, len - AUX_LEN);
#if CC2420_CONF_CHECKSUM
getrxdata(&checksum, CHECKSUM_LEN);
#endif /* CC2420_CONF_CHECKSUM */
getrxdata(footer, FOOTER_LEN);
#if CC2420_CONF_CHECKSUM
if(checksum != crc16_data(buf, len - AUX_LEN, 0)) {
PRINTF("checksum failed 0x%04x != 0x%04x\n",
checksum, crc16_data(buf, len - AUX_LEN, 0));
}
if(footer[1] & FOOTER1_CRC_OK &&
checksum == crc16_data(buf, len - AUX_LEN, 0)) {
#else
if(footer[1] & FOOTER1_CRC_OK) {
#endif /* CC2420_CONF_CHECKSUM */
cc2420_last_rssi = footer[0];
cc2420_last_correlation = footer[1] & FOOTER1_CORRELATION;
packetbuf_set_attr(PACKETBUF_ATTR_RSSI, cc2420_last_rssi);
packetbuf_set_attr(PACKETBUF_ATTR_LINK_QUALITY, cc2420_last_correlation);
RIMESTATS_ADD(llrx);
} else {
RIMESTATS_ADD(badcrc);
len = AUX_LEN;
}
if(CC2420_FIFOP_IS_1) {
if(!CC2420_FIFO_IS_1) {
/* Clean up in case of FIFO overflow! This happens for every
* full length frame and is signaled by FIFOP = 1 and FIFO =
* 0. */
flushrx();
} else {
/* Another packet has been received and needs attention. */
process_poll(&cc2420_process);
}
}
RELEASE_LOCK();
if(len < AUX_LEN) {
return 0;
}
return len - AUX_LEN;
}
/*---------------------------------------------------------------------------*/
void
cc2420_set_txpower(uint8_t power)
{
GET_LOCK();
set_txpower(power);
RELEASE_LOCK();
}
/*---------------------------------------------------------------------------*/
int
cc2420_send(const void *payload, unsigned short payload_len)
{
int i;
uint8_t total_len;
struct timestamp timestamp;
uint16_t checksum;
GET_LOCK();
PRINTF("cc2420: sending %d bytes\n", payload_len);
RIMESTATS_ADD(lltx);
/* Wait for any previous transmission to finish. */
while(status() & BV(CC2420_TX_ACTIVE));
/* Write packet to TX FIFO. */
strobe(CC2420_SFLUSHTX);
checksum = crc16_data(payload, payload_len, 0);
total_len = payload_len + AUX_LEN;
FASTSPI_WRITE_FIFO(&total_len, 1);
FASTSPI_WRITE_FIFO(payload, payload_len);
FASTSPI_WRITE_FIFO(&checksum, CHECKSUM_LEN);
#if CC2420_CONF_TIMESTAMPS
timestamp.authority_level = timesynch_authority_level();
timestamp.time = timesynch_time();
FASTSPI_WRITE_FIFO(×tamp, TIMESTAMP_LEN);
#endif /* CC2420_CONF_TIMESTAMPS */
/* The TX FIFO can only hold one packet. Make sure to not overrun
* FIFO by waiting for transmission to start here and synchronizing
* with the CC2420_TX_ACTIVE check in cc2420_send.
*
* Note that we may have to wait up to 320 us (20 symbols) before
* transmission starts.
*/
#ifdef TMOTE_SKY
#define LOOP_20_SYMBOLS 100 /* 326us (msp430 @ 2.4576MHz) */
#elif __AVR__
#define LOOP_20_SYMBOLS 500 /* XXX */
#endif
#if WITH_SEND_CCA
strobe(CC2420_SRXON);
while(!(status() & BV(CC2420_RSSI_VALID)));
strobe(CC2420_STXONCCA);
#else /* WITH_SEND_CCA */
strobe(CC2420_STXON);
#endif /* WITH_SEND_CCA */
for(i = LOOP_20_SYMBOLS; i > 0; i--) {
if(SFD_IS_1) {
#if CC2420_CONF_TIMESTAMPS
rtimer_clock_t txtime = timesynch_time();
#endif /* CC2420_CONF_TIMESTAMPS */
if(receive_on) {
ENERGEST_OFF(ENERGEST_TYPE_LISTEN);
}
ENERGEST_ON(ENERGEST_TYPE_TRANSMIT);
/* We wait until transmission has ended so that we get an
accurate measurement of the transmission time.*/
while(status() & BV(CC2420_TX_ACTIVE));
#if CC2420_CONF_TIMESTAMPS
setup_time_for_transmission = txtime - timestamp.time;
if(num_transmissions < 10000) {
total_time_for_transmission += timesynch_time() - txtime;
total_transmission_len += total_len;
num_transmissions++;
}
#endif /* CC2420_CONF_TIMESTAMPS */
#ifdef ENERGEST_CONF_LEVELDEVICE_LEVELS
ENERGEST_OFF_LEVEL(ENERGEST_TYPE_TRANSMIT,cc2420_get_txpower());
#endif
ENERGEST_OFF(ENERGEST_TYPE_TRANSMIT);
if(receive_on) {
ENERGEST_ON(ENERGEST_TYPE_LISTEN);
}
RELEASE_LOCK();
return 0;
}
}
/* If we are using WITH_SEND_CCA, we get here if the packet wasn't
transmitted because of other channel activity. */
RIMESTATS_ADD(contentiondrop);
PRINTF("cc2420: do_send() transmission never started\n");
RELEASE_LOCK();
return -3; /* Transmission never started! */
}
/*---------------------------------------------------------------------------*/
int
cc2420_read(void *buf, unsigned short bufsize)
{
uint8_t footer[2];
uint8_t len;
uint16_t checksum;
struct timestamp t;
if(!FIFOP_IS_1) {
/* If FIFOP is 0, there is no packet in the RXFIFO. */
return 0;
}
if(interrupt_time_set) {
#if CC2420_CONF_TIMESTAMPS
cc2420_time_of_arrival = interrupt_time;
#endif /* CC2420_CONF_TIMESTAMPS */
interrupt_time_set = 0;
} else {
cc2420_time_of_arrival = 0;
}
cc2420_time_of_departure = 0;
GET_LOCK();
getrxbyte(&len);
if(len > CC2420_MAX_PACKET_LEN) {
/* Oops, we must be out of sync. */
flushrx();
RIMESTATS_ADD(badsynch);
RELEASE_LOCK();
return 0;
}
if(len <= AUX_LEN) {
flushrx();
RIMESTATS_ADD(tooshort);
RELEASE_LOCK();
return 0;
}
if(len - AUX_LEN > bufsize) {
flushrx();
RIMESTATS_ADD(toolong);
RELEASE_LOCK();
return 0;
}
getrxdata(buf, len - AUX_LEN);
getrxdata(&checksum, CHECKSUM_LEN);
getrxdata(&t, TIMESTAMP_LEN);
getrxdata(footer, FOOTER_LEN);
if(footer[1] & FOOTER1_CRC_OK &&
checksum == crc16_data(buf, len - AUX_LEN, 0)) {
cc2420_last_rssi = footer[0];
cc2420_last_correlation = footer[1] & FOOTER1_CORRELATION;
RIMESTATS_ADD(llrx);
#if CC2420_CONF_TIMESTAMPS
cc2420_time_of_departure =
t.time +
setup_time_for_transmission +
(total_time_for_transmission * (len - 2)) / total_transmission_len;
cc2420_authority_level_of_sender = t.authority_level;
#endif /* CC2420_CONF_TIMESTAMPS */
} else {
RIMESTATS_ADD(badcrc);
len = AUX_LEN;
}
/* Clean up in case of FIFO overflow! This happens for every full
* length frame and is signaled by FIFOP = 1 and FIFO = 0.
*/
if(FIFOP_IS_1 && !FIFO_IS_1) {
/* printf("cc2420_read: FIFOP_IS_1 1\n");*/
flushrx();
} else if(FIFOP_IS_1) {
/* Another packet has been received and needs attention. */
process_poll(&cc2420_process);
}
RELEASE_LOCK();
if(len < AUX_LEN) {
return 0;
}
return len - AUX_LEN;
}
/*---------------------------------------------------------------------------*/
static uint16_t packet_hash(const void *data, size_t length)
{
return crc16_data(data, length, 0) & 0xFFFF;
}
