u-blox
This class provides an API to communicate with a u-blox GNSS chip. The files here were originally part of the C027_Support library (https://developer.mbed.org/teams/ublox/code/C027_Support/ at revision 138:dafbbf31bf76) but have been separated out, primarily for use on the u-blox C030 board where the cellular interace portion of the C027_Support library will instead be provided through the new mbed Cellular API.
Dependents: example-ublox-at-cellular-interface-ext example-low-power-sleep example-C030-out-of-box-demo example-C030-out-of-box-demo ... more
gnss.cpp
- Committer:
- fahim.alavi@u-blox.com
- Date:
- 2018-10-16
- Revision:
- 22:d8cd4cf0fcc0
- Parent:
- 21:f91c0334d017
- Child:
- 25:f538f1dc4121
File content as of revision 22:d8cd4cf0fcc0:
/* mbed Microcontroller Library
* Copyright (c) 2017 u-blox
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/**
* @file gnss.cpp
* This file defines a class that communicates with a u-blox GNSS chip.
*/
#include "mbed.h"
#include "ctype.h"
#include "gnss.h"
#ifdef UBLOX_WEARABLE_FRAMEWORK
#include "SDCardModel.h"
#else
#define SEND_LOGGING_MESSAGE printf
#endif
GnssParser::GnssParser(void)
{
// Create the enable pin but set everything to disabled
_gnssEnable = NULL;
#ifdef TARGET_UBLOX_C030
_gnssEnable = new DigitalInOut(GNSSEN, PIN_OUTPUT, PushPullNoPull, 0);
#else
_gnssEnable = new DigitalInOut(GNSSEN, PIN_OUTPUT, PullNone, 1);
#endif
}
GnssParser::~GnssParser(void)
{
if (_gnssEnable != NULL) {
*_gnssEnable = 0;
delete _gnssEnable;
}
}
void GnssParser::powerOff(void)
{
// Set the GNSS into backup mode using the command RMX-LPREQ
struct { unsigned long dur; unsigned long flags; } msg = {0/*endless*/,0/*backup*/};
sendUbx(0x02, 0x41, &msg, sizeof(msg));
}
void GnssParser::cutOffPower(void)
{
//Disabling PA15 to cut off power supply
if (_gnssEnable != NULL)
*_gnssEnable = 0;
wait_ms(1);
}
void GnssParser::_powerOn(void)
{
if (_gnssEnable != NULL) {
*_gnssEnable = 1;
}
wait_ms (1);
}
int GnssParser::_getMessage(Pipe<char>* pipe, char* buf, int len)
{
int unkn = 0;
int sz = pipe->size();
int fr = pipe->free();
if (len > sz)
len = sz;
while (len > 0)
{
// NMEA protocol
pipe->set(unkn);
int nmea = _parseNmea(pipe,len);
if ((nmea != NOT_FOUND) && (unkn > 0))
return UNKNOWN | pipe->get(buf,unkn);
if (nmea == WAIT && fr)
return WAIT;
if (nmea > 0)
return NMEA | pipe->get(buf,nmea);
// UBX protocol
pipe->set(unkn);
int ubx = _parseUbx(pipe,len);
if ((ubx != NOT_FOUND) && (unkn > 0))
return UNKNOWN | pipe->get(buf,unkn);
if (ubx == WAIT && fr)
return WAIT;
if (ubx > 0)
return UBX | pipe->get(buf,ubx);
// UNKNOWN
unkn ++;
len--;
}
if (unkn > 0)
return UNKNOWN | pipe->get(buf,unkn);
return WAIT;
}
int GnssParser::_parseNmea(Pipe<char>* pipe, int len)
{
int o = 0;
int c = 0;
char ch;
if (++o > len) return WAIT;
if ('$' != pipe->next()) return NOT_FOUND;
// This needs to be extended by crc checking
for (;;)
{
if (++o > len) return WAIT;
ch = pipe->next();
if ('*' == ch) break; // crc delimiter
if (!isprint(ch)) return NOT_FOUND;
c ^= ch;
}
if (++o > len) return WAIT;
ch = _toHex[(c >> 4) & 0xF]; // high nibble
if (ch != pipe->next()) return NOT_FOUND;
if (++o > len) return WAIT;
ch = _toHex[(c >> 0) & 0xF]; // low nibble
if (ch != pipe->next()) return NOT_FOUND;
if (++o > len) return WAIT;
if ('\r' != pipe->next()) return NOT_FOUND;
if (++o > len) return WAIT;
if ('\n' != pipe->next()) return NOT_FOUND;
return o;
}
int GnssParser::_parseUbx(Pipe<char>* pipe, int l)
{
int o = 0;
if (++o > l) return WAIT;
if ('\xB5' != pipe->next()) return NOT_FOUND;
if (++o > l) return WAIT;
if ('\x62' != pipe->next()) return NOT_FOUND;
o += 4;
if (o > l) return WAIT;
int i,j,ca,cb;
i = pipe->next(); ca = i; cb = ca; // cls
i = pipe->next(); ca += i; cb += ca; // id
i = pipe->next(); ca += i; cb += ca; // len_lsb
j = pipe->next(); ca += j; cb += ca; // len_msb
j = i + (j << 8);
while (j--)
{
if (++o > l) return WAIT;
i = pipe->next();
ca += i;
cb += ca;
}
ca &= 0xFF; cb &= 0xFF;
if (++o > l) return WAIT;
if (ca != pipe->next()) return NOT_FOUND;
if (++o > l) return WAIT;
if (cb != pipe->next()) return NOT_FOUND;
return o;
}
int GnssParser::send(const char* buf, int len)
{
return _send(buf, len);
}
int GnssParser::sendNmea(const char* buf, int len)
{
char head[1] = { '$' };
char tail[5] = { '*', 0x00/*crc_high*/, 0x00/*crc_low*/, '\r', '\n' };
int i;
int crc = 0;
for (i = 0; i < len; i ++)
crc ^= *buf++;
i = _send(head, sizeof(head));
i += _send(buf, len);
tail[1] = _toHex[(crc > 4) & 0xF0];
tail[2] = _toHex[(crc > 0) & 0x0F];
i += _send(tail, sizeof(tail));
return i;
}
int GnssParser::sendUbx(unsigned char cls, unsigned char id, const void* buf /*= NULL*/, int len /*= 0*/)
{
char head[6] = { 0xB5, 0x62, cls, id, (char) len, (char) (len >> 8)};
char crc[2];
int i;
int ca = 0;
int cb = 0;
for (i = 2; i < 6; i ++)
{
ca += head[i];
cb += ca;
}
for (i = 0; i < len; i ++)
{
ca += ((char*)buf)[i];
cb += ca;
}
i = _send(head, sizeof(head));
i += _send(buf, len);
crc[0] = ca & 0xFF;
crc[1] = cb & 0xFF;
i += _send(crc, sizeof(crc));
return i;
}
const char* GnssParser::findNmeaItemPos(int ix, const char* start, const char* end)
{
// Find the start
for (; (start < end) && (ix > 0); start ++)
{
if (*start == ',')
ix --;
}
// Found and check bounds
if ((ix == 0) && (start < end) &&
(*start != ',') && (*start != '*') && (*start != '\r') && (*start != '\n'))
return start;
else
return NULL;
}
bool GnssParser::getNmeaItem(int ix, char* buf, int len, double& val)
{
char* end = &buf[len];
const char* pos = findNmeaItemPos(ix, buf, end);
// Find the start
if (!pos)
return false;
val = strtod(pos, &end);
// Restore the last character
return (end > pos);
}
bool GnssParser::getNmeaItem(int ix, char* buf, int len, int& val, int base /*=10*/)
{
char* end = &buf[len];
const char* pos = findNmeaItemPos(ix, buf, end);
// Find the start
if (!pos)
return false;
val = (int)strtol(pos, &end, base);
return (end > pos);
}
bool GnssParser::getNmeaItem(int ix, char* buf, int len, char& val)
{
const char* end = &buf[len];
const char* pos = findNmeaItemPos(ix, buf, end);
// Find the start
if (!pos)
return false;
// Skip leading spaces
while ((pos < end) && isspace(*pos))
pos++;
// Check bound
if ((pos < end) &&
(*pos != ',') && (*pos != '*') && (*pos != '\r') && (*pos != '\n'))
{
val = *pos;
return true;
}
return false;
}
bool GnssParser::getNmeaAngle(int ix, char* buf, int len, double& val)
{
char ch;
if (getNmeaItem(ix,buf,len,val) && getNmeaItem(ix+1,buf,len,ch) &&
((ch == 'S') || (ch == 'N') || (ch == 'E') || (ch == 'W')))
{
val *= 0.01;
int i = (int)val;
val = (val - i) / 0.6 + i;
if (ch == 'S' || ch == 'W')
val = -val;
return true;
}
return false;
}
int GnssParser::enable_ubx() {
unsigned char ubx_cfg_prt[]={0x01, 0x00, 0x00, 0x00, 0xD0, 0x08, 0x00, 0x00, 0x00, 0x84, 0x03, 0x00, 0x03, 0x00, 0x03, 0x00, 0x00, 0x00,0x00, 0x00};
int conf = RETRY;
int length = 0;
while(conf)
{
length = sendUbx(0x06, 0x00, ubx_cfg_prt, sizeof(ubx_cfg_prt));
if(length >= (int)(sizeof(ubx_cfg_prt) + UBX_FRAME_SIZE))
{
wait(5);
break;
}
else
{
conf = conf - 1;
}
}
return (conf == 0) ? 0 : 1;
}
eUBX_MESSAGE GnssParser::get_ubx_message(char *buff) {
eUBX_MESSAGE return_value = UNKNOWN_UBX;
if(buff[SYNC_CHAR_INDEX_1] == 0xB5 && buff[SYNC_CHAR_INDEX_2] == 0x62) {
switch (buff[MSG_CLASS_INDEX]) {
case NAV: {
switch (buff[MSG_ID_INDEX]) {
case 0x07: {
return_value = UBX_NAV_PVT;
}
break;
case 0x09: {
return_value = UBX_NAV_ODO;
}
break;
case 0x03: {
return_value = NAV_STATUS;
}
break;
default:
{
return_value = UNKNOWN_UBX;
}
break;
}
}
break;
case ACK: {
switch (buff[MSG_ID_INDEX]) {
case 0x00: {
return_value = UBX_ACK_NAK;
}
break;
case 0x01: {
return_value = UBX_ACK_ACK;
}
break;
default:
{
return_value = UNKNOWN_UBX;
}
break;
}
}
break;
case LOG: {
switch (buff[MSG_ID_INDEX]) {
case 0x11: {
return_value = UBX_LOG_BATCH;
}
break;
default:
{
return_value = UNKNOWN_UBX;
}
break;
}
}
break;
default:
{
return_value = UNKNOWN_UBX;
}
break;
}
}
return return_value;
}
tUBX_ACK_ACK GnssParser::decode_ubx_cfg_ack_nak_msg(char *buf) {
tUBX_ACK_ACK return_decoded_msg;
uint8_t index = UBX_PAYLOAD_INDEX;
return_decoded_msg.msg_class = buf[index++];
return_decoded_msg.msg_id = buf[index];
return return_decoded_msg;
}
tUBX_NAV_ODO GnssParser::decode_ubx_nav_odo_msg(char *buf) {
tUBX_NAV_ODO return_decoded_msg;
uint8_t index = UBX_PAYLOAD_INDEX;
return_decoded_msg.version = buf[index++];
index +=3; // 3 bytes are reserved
return_decoded_msg.itow = buf[index++];
return_decoded_msg.itow |= (buf[index++] << 8);
return_decoded_msg.itow |= (buf[index++] << 16);
return_decoded_msg.itow |= (buf[index++] << 24);
return_decoded_msg.distance = buf[index++];
return_decoded_msg.distance |= (buf[index++] << 8);
return_decoded_msg.distance |= (buf[index++] << 16);
return_decoded_msg.distance |= (buf[index++] << 24);
return_decoded_msg.totalDistance = buf[index++];
return_decoded_msg.totalDistance |= (buf[index++] << 8);
return_decoded_msg.totalDistance |= (buf[index++] << 16);
return_decoded_msg.totalDistance |= (buf[index++] << 24);
return_decoded_msg.distanceSTD = buf[index++];
return_decoded_msg.distanceSTD |= (buf[index++] << 8);
return_decoded_msg.distanceSTD |= (buf[index++] << 16);
return_decoded_msg.distanceSTD |= (buf[index++] << 24);
return return_decoded_msg;
}
tUBX_NAV_PVT GnssParser::decode_ubx_nav_pvt_msg(char *buf) {
tUBX_NAV_PVT return_decoded_msg;
uint8_t index = UBX_PAYLOAD_INDEX;
return_decoded_msg.itow = buf[index++];
return_decoded_msg.itow |= (buf[index++] << 8);
return_decoded_msg.itow |= (buf[index++] << 16);
return_decoded_msg.itow |= (buf[index++] << 24);
return_decoded_msg.year = buf[index++];
return_decoded_msg.year |= (buf[index++] << 8);
return_decoded_msg.month = buf[index++];
return_decoded_msg.day = buf[index++];
// Go to Fix type
index = UBX_PAYLOAD_INDEX + 20;
return_decoded_msg.fixType = buf[index];
// Go to lon
index = UBX_PAYLOAD_INDEX + 24;
return_decoded_msg.lon = buf[index++];
return_decoded_msg.lon |= (buf[index++] << 8);
return_decoded_msg.lon |= (buf[index++] << 16);
return_decoded_msg.lon |= (buf[index++] << 24);
return_decoded_msg.lat = buf[index++];
return_decoded_msg.lat |= (buf[index++] << 8);
return_decoded_msg.lat |= (buf[index++] << 16);
return_decoded_msg.lat |= (buf[index++] << 24);
return_decoded_msg.height = buf[index++];
return_decoded_msg.height |= (buf[index++] << 8);
return_decoded_msg.height |= (buf[index++] << 16);
return_decoded_msg.height |= (buf[index++] << 24);
// Go to gSpeed
index = UBX_PAYLOAD_INDEX + 60;
return_decoded_msg.speed = buf[index++];
return_decoded_msg.speed |= (buf[index++] << 8);
return_decoded_msg.speed |= (buf[index++] << 16);
return_decoded_msg.speed |= (buf[index++] << 24);
return return_decoded_msg;
}
tUBX_LOG_BATCH GnssParser::decode_ubx_log_batch_msg(char *buf) {
tUBX_LOG_BATCH return_decoded_msg;
uint8_t index = UBX_PAYLOAD_INDEX;
// move index itow
index = UBX_PAYLOAD_INDEX + 4;
return_decoded_msg.itow = buf[index++];
return_decoded_msg.itow |= (buf[index++] << 8);
return_decoded_msg.itow |= (buf[index++] << 16);
return_decoded_msg.itow |= (buf[index++] << 24);
// move index lon
index = UBX_PAYLOAD_INDEX + 24;
return_decoded_msg.lon = buf[index++];
return_decoded_msg.lon |= (buf[index++] << 8);
return_decoded_msg.lon |= (buf[index++] << 16);
return_decoded_msg.lon |= (buf[index++] << 24);
return_decoded_msg.lat = buf[index++];
return_decoded_msg.lat |= (buf[index++] << 8);
return_decoded_msg.lat |= (buf[index++] << 16);
return_decoded_msg.lat |= (buf[index++] << 24);
return_decoded_msg.height = buf[index++];
return_decoded_msg.height |= (buf[index++] << 8);
return_decoded_msg.height |= (buf[index++] << 16);
return_decoded_msg.height |= (buf[index++] << 24);
// move index to distance
index = UBX_PAYLOAD_INDEX + 84;
return_decoded_msg.distance = buf[index++];
return_decoded_msg.distance |= (buf[index++] << 8);
return_decoded_msg.distance |= (buf[index++] << 16);
return_decoded_msg.distance |= (buf[index++] << 24);
return_decoded_msg.totalDistance = buf[index++];
return_decoded_msg.totalDistance |= (buf[index++] << 8);
return_decoded_msg.totalDistance |= (buf[index++] << 16);
return_decoded_msg.totalDistance |= (buf[index++] << 24);
return_decoded_msg.distanceSTD = buf[index++];
return_decoded_msg.distanceSTD |= (buf[index++] << 8);
return_decoded_msg.distanceSTD |= (buf[index++] << 16);
return_decoded_msg.distanceSTD |= (buf[index++] << 24);
return return_decoded_msg;
}
tUBX_NAV_STATUS GnssParser::decode_ubx_nav_status_msg(char *buf) {
tUBX_NAV_STATUS return_decoded_msg;
uint8_t index = UBX_PAYLOAD_INDEX;
return_decoded_msg.itow = buf[index++];
return_decoded_msg.itow |= (buf[index++] << 8);
return_decoded_msg.itow |= (buf[index++] << 16);
return_decoded_msg.itow |= (buf[index++] << 24);
// move index flag
return_decoded_msg.fix = buf[index++];
return_decoded_msg.flags = buf[index++];
// move to ttff
index+=2;
return_decoded_msg.ttff = buf[index++];
return_decoded_msg.ttff |= (buf[index++] << 8);
return_decoded_msg.ttff |= (buf[index++] << 16);
return_decoded_msg.ttff |= (buf[index++] << 24);
return_decoded_msg.msss = buf[index++];
return_decoded_msg.msss |= (buf[index++] << 8);
return_decoded_msg.msss |= (buf[index++] << 16);
return_decoded_msg.msss |= (buf[index++] << 24);
return return_decoded_msg;
}
int GnssParser::ubx_request_batched_data(bool sendMonFirst) {
unsigned char ubx_log_retrieve_batch[]={0x00, 0x00, 0x00, 0x00};
ubx_log_retrieve_batch[1] = (sendMonFirst == true) ? 0x01 : 0x00;
int conf = RETRY;
while(conf)
{
int length = sendUbx(0x21, 0x10, ubx_log_retrieve_batch, sizeof(ubx_log_retrieve_batch));
if(length >= (int)(sizeof(ubx_log_retrieve_batch) + UBX_FRAME_SIZE))
{
wait(5);
break;
}
else
{
conf = conf - 1;
}
}
if(conf == 0)
{
return 1;
}
return 0;
}
const char GnssParser::_toHex[] = { '0','1','2','3','4','5','6','7','8','9','A','B','C','D','E','F' };
// ----------------------------------------------------------------
// Serial Implementation
// ----------------------------------------------------------------
GnssSerial::GnssSerial(PinName tx /*= GNSSTXD */, PinName rx /*= GNSSRXD */, int baudrate /*= GNSSBAUD */,
int rxSize /*= 256 */, int txSize /*= 128 */) :
SerialPipe(tx, rx, baudrate, rxSize, txSize)
{
baud(baudrate);
}
GnssSerial::~GnssSerial(void)
{
powerOff();
}
bool GnssSerial::init(PinName pn)
{
Timer timer;
int size;
// Unused (kept only for compatibility with the I2C version)
(void)pn;
// Power up and enable the module
_powerOn();
// Send a byte to wakup the device again
putc(0xFF);
// Wait until we get some bytes
size = _pipeRx.size();
timer.start();
while ((timer.read_ms() < 1000) && (size == _pipeRx.size())) {
/* Nothing, just wait */
}
timer.stop();
enable_ubx();
wait_ms(1000);
baud(230400);
// Send a byte to wakup the device again
putc(0xFF);
// Wait until we get some bytes
size = _pipeRx.size();
timer.start();
while ((timer.read_ms() < 1000) && (size == _pipeRx.size())) {
/* Nothing, just wait */
}
return (size != _pipeRx.size());
}
int GnssSerial::getMessage(char* buf, int len)
{
return _getMessage(&_pipeRx, buf, len);
}
int GnssSerial::_send(const void* buf, int len)
{
GET_SDCARD_INSTANCE->write(logging_file_name, (void *)buf, len);
return put((const char*)buf, len, true/*=blocking*/);
}
// ----------------------------------------------------------------
// I2C Implementation
// ----------------------------------------------------------------
GnssI2C::GnssI2C(PinName sda /*= NC */, PinName scl /*= NC */,
unsigned char i2cAdr /*= (66<<1) */, int rxSize /*= 256 */) :
I2C(sda,scl),
_pipe(rxSize),
_i2cAdr(i2cAdr)
{
frequency(100000);
}
GnssI2C::~GnssI2C(void)
{
powerOff();
}
bool GnssI2C::init(PinName pn)
{
// Power up and enable the module
_powerOn();
if (pn != NC) {
DigitalOut pin(pn, 0);
::wait_us(1);
pin = 1;
::wait_ms(100);
}
return !I2C::write(_i2cAdr,®STREAM,sizeof(REGSTREAM));
}
int GnssI2C::getMessage(char* buf, int len)
{
// Fill the pipe
int sz = _pipe.free();
if (sz)
sz = _get(buf, sz);
if (sz)
_pipe.put(buf, sz);
// Now parse it
return _getMessage(&_pipe, buf, len);
}
int GnssI2C::send(const char* buf, int len)
{
int sent = 0;
if (len)
{
if (!I2C::write(_i2cAdr,®STREAM,sizeof(REGSTREAM),true))
sent = send(buf, len);
stop();
}
return sent;
}
int GnssI2C::sendNmea(const char* buf, int len)
{
int sent = 0;
if (!I2C::write(_i2cAdr,®STREAM,sizeof(REGSTREAM),true))
sent = GnssParser::sendNmea(buf, len);
stop();
return sent;
}
int GnssI2C::sendUbx(unsigned char cls, unsigned char id, const void* buf, int len)
{
int sent = 0;
if (!I2C::write(_i2cAdr,®STREAM,sizeof(REGSTREAM),true))
sent = GnssParser::sendUbx(cls, id, buf, len);
I2C::stop();
return sent;
}
int GnssI2C::_get(char* buf, int len)
{
int read = 0;
unsigned char sz[2] = {0,0};
if (!I2C::write(_i2cAdr,®LEN,sizeof(REGLEN),true) &&
!I2C::read(_i2cAdr,(char*)sz,sizeof(sz)))
{
int size = 256 * (int)sz[0] + sz[1];
if (size > len)
size = len;
if (size > 0)
{
if (!I2C::write(_i2cAdr,®STREAM,sizeof(REGSTREAM),true) &&
!I2C::read(_i2cAdr,buf,size)) {
read = size;
}
}
}
return read;
}
int GnssI2C::_send(const void* buf, int len)
{
return !I2C::write(_i2cAdr,(const char*)buf,len,true) ? len : 0;
}
const char GnssI2C::REGLEN = 0xFD;
const char GnssI2C::REGSTREAM = 0xFF;
// End Of File