Joe Knapp
Changes Lat & Long Binary variable to be 32 bit integers representing micro-degrees.
Fork of
lib_gps
by 
wayne roberts
gps.cpp
- Committer:
- jknapp_smtc
- Date:
- 2016-08-15
- Revision:
- 6:1a45aa41ec15
- Parent:
- 5:f06be7a1f427
File content as of revision 6:1a45aa41ec15:
#include "mbed.h"
#include "gps.h"
#define LAT_UNFIXED 0x07270e00
#define LONG_UNFIXED 0x47868c00
const char NmeaDataTypeGPGGA[] = "GPGGA";
//const char NmeaDataTypeGPGSA[] = "GPGSA";
//const char NmeaDataTypeGPGSV[] = "GPGSV";
const char NmeaDataTypeGPRMC[] = "GPRMC";
//InterruptIn pps_pin(PC_5);
GPS::GPS(PinName uart_tx, PinName uart_rx, PinName en) : m_uart(uart_tx, uart_rx), m_en_pin(en)
{
have_fix = false;
}
GPS::~GPS()
{
}
/*void GPS::pps()
{
pps_occurred = true;
}*/
void GPS::on_uart_rx()
{
//uint8_t *len = &rx_buf_lens[rx_bufs_in_idx];
uint8_t len = rx_buf_lens[rx_bufs_in_idx];
char ch;
do {
ch = m_uart.getc();
if (ch != '$') {
if (len < RX_BUF_SIZE) {
rx_bufs[rx_bufs_in_idx][len] = ch;
rx_buf_lens[rx_bufs_in_idx]++;
} /*else
printf("S");*/
} /*else if (len != 0) {
printf("$ at %d\r\n", len);
}*/
if (ch == '\n') {
rx_bufs[rx_bufs_in_idx][len] = 0; // null terminate
if (++rx_bufs_in_idx == NUM_RX_BUFS)
rx_bufs_in_idx = 0;
/* just let it overflow -- if (rx_bufs_in_idx == rx_bufs_out_idx)
printf("gps overflow\r\n");*/
rx_buf_lens[rx_bufs_in_idx] = 0;
}
} while (m_uart.readable());
}
void GPS::init()
{
rx_bufs_in_idx = 0;
rx_buf_lens[rx_bufs_in_idx] = 0;
rx_bufs_out_idx = 0;
//gps_uart.baud(57600);
m_uart.attach(this, &GPS::on_uart_rx);
//pps_pin.rise(this, &GPS::pps);
}
void GPS::enable(bool en)
{
if (en) {
if (en_invert)
m_en_pin = 0;
else
m_en_pin = 1;
} else {
if (en_invert)
m_en_pin = 1;
else
m_en_pin = 0;
}
// reset current string index
rx_buf_lens[rx_bufs_in_idx] = 0;
}
bool GPS::enabled()
{
if (en_invert)
return !m_en_pin.read();
else
return m_en_pin.read();
}
/*char GPS::Nibble2HexChar( char a );
{
if( a < 10 )
{
return '0' + a;
}
else if( a < 16 )
{
return 'A' + ( a - 10 );
}
else
{
return '?';
}
}*/
int GPS::NmeaChecksum( char *nmeaStr, uint8_t nmeaStrSize, char * checksum )
{
int i = 0;
uint8_t checkNum = 0;
// Check input parameters
if( ( nmeaStr == NULL ) || ( checksum == NULL ) || ( nmeaStrSize <= 1 ) )
{
return -1;
}
// Skip the first '$' if necessary
if( nmeaStr[i] == '$' )
{
i += 1;
}
// XOR until '*' or max length is reached
while( nmeaStr[i] != '*' )
{
checkNum ^= nmeaStr[i];
i += 1;
if( i >= nmeaStrSize )
{
return -1;
}
}
// Convert checksum value to 2 hexadecimal characters
/*checksum[0] = Nibble2HexChar( checkNum / 16 ); // upper nibble
checksum[1] = Nibble2HexChar( checkNum % 16 ); // lower nibble
*/
sprintf(checksum, "%02X", checkNum);
return i + 1;
}
bool GPS::NmeaValidateChecksum(int idx)
{
int checksumIndex;
char checksum[4];
char *NmeaString = rx_bufs[idx];
checksumIndex = NmeaChecksum( NmeaString, rx_buf_lens[idx], checksum );
// could we calculate a verification checksum ?
if( checksumIndex < 0 )
{
//printf("gps:checksumIndex:%d\r\n", checksumIndex);
return false;
}
// check if there are enough char in the serial buffer to read checksum
if( checksumIndex >= ( rx_buf_lens[idx] - 2 ) )
{
//printf("gps:checksumIndex:%d\r\n", checksumIndex);
return false;
}
// check the checksum
if( ( NmeaString[checksumIndex] == checksum[0] ) && ( NmeaString[checksumIndex + 1] == checksum[1] ) )
{
return true;
}
else
{
if (verbose)
printf("gps:checksum fail idx:%d %c%c %c%c\r\n", checksumIndex, checksum[0], checksum[1], NmeaString[checksumIndex], NmeaString[checksumIndex+1]);
return false;
}
}
void GPS::ConvertPositionFromStringToNumerical( )
{
int i;
double valueTmp1;
double valueTmp2;
double valueTmp3;
double valueTmp4;
// Convert the latitude from ASCII to uint8_t values
for( i = 0 ; i < 10 ; i++ )
{
NmeaGpsData.NmeaLatitude[i] = NmeaGpsData.NmeaLatitude[i] & 0xF;
}
// Convert latitude from degree/minute/second (DMS) format into decimal
valueTmp1 = ( double )NmeaGpsData.NmeaLatitude[0] * 10.0 + ( double )NmeaGpsData.NmeaLatitude[1];
valueTmp2 = ( double )NmeaGpsData.NmeaLatitude[2] * 10.0 + ( double )NmeaGpsData.NmeaLatitude[3];
valueTmp3 = ( double )NmeaGpsData.NmeaLatitude[5] * 1000.0 + ( double )NmeaGpsData.NmeaLatitude[6] * 100.0 +
( double )NmeaGpsData.NmeaLatitude[7] * 10.0 + ( double )NmeaGpsData.NmeaLatitude[8];
Latitude = valueTmp1 + ( ( valueTmp2 + ( valueTmp3 * 0.0001 ) ) / 60.0 );
if( NmeaGpsData.NmeaLatitudePole[0] == 'S' )
{
Latitude *= -1;
}
// Convert the longitude from ASCII to uint8_t values
for( i = 0 ; i < 10 ; i++ )
{
NmeaGpsData.NmeaLongitude[i] = NmeaGpsData.NmeaLongitude[i] & 0xF;
}
// Convert longitude from degree/minute/second (DMS) format into decimal
valueTmp1 = ( double )NmeaGpsData.NmeaLongitude[0] * 100.0 + ( double )NmeaGpsData.NmeaLongitude[1] * 10.0 + ( double )NmeaGpsData.NmeaLongitude[2];
valueTmp2 = ( double )NmeaGpsData.NmeaLongitude[3] * 10.0 + ( double )NmeaGpsData.NmeaLongitude[4];
valueTmp3 = ( double )NmeaGpsData.NmeaLongitude[6] * 1000.0 + ( double )NmeaGpsData.NmeaLongitude[7] * 100;
valueTmp4 = ( double )NmeaGpsData.NmeaLongitude[8] * 10.0 + ( double )NmeaGpsData.NmeaLongitude[9];
Longitude = valueTmp1 + ( valueTmp2 / 60.0 ) + ( ( ( valueTmp3 + valueTmp4 ) * 0.0001 ) / 60.0 );
if( NmeaGpsData.NmeaLongitudePole[0] == 'W' )
{
Longitude *= -1;
}
//printf("DD %f, %f\r\n", Latitude, Longitude);
}
void GPS::ConvertPositionIntoBinary( )
{
LatitudeBinary32 = (int)(Latitude * 1e6);
LongitudeBinary32 = (int)(Longitude * 1e6);
//printf("binary: %d %d\r\n", LatitudeBinary32, LongitudeBinary32);
if (LatitudeBinary32 == LAT_UNFIXED && LongitudeBinary32 == LONG_UNFIXED)
have_fix = false;
else
have_fix = true;
}
int GPS::ParseGPSData(int idx)
{
uint8_t i, j, fieldSize;
char *NmeaString;
if (NmeaValidateChecksum(idx) == false) {
if (verbose)
printf("gps:bad nmea checksum:%s\r\n", rx_bufs[rx_bufs_out_idx]);
return FAIL;
}
NmeaString = rx_bufs[idx];
if (NmeaString[0] == 'P' && NmeaString[1] == 'M' && NmeaString[2] == 'T' && NmeaString[3] == 'K') {
/* anything useful from PMTK packets? */
return SUCCESS;
}
fieldSize = 0;
i = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 6 )
{
printf("gps parse:%s\r\n", NmeaString);
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaDataType[j] = NmeaString[i];
}
// Parse the GPGGA data
if( strncmp( ( const char* )NmeaGpsData.NmeaDataType, ( const char* )NmeaDataTypeGPGGA, 5 ) == 0 )
{
// NmeaUtcTime
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 11 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaUtcTime[j] = NmeaString[i];
}
// NmeaLatitude
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 10 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaLatitude[j] = NmeaString[i];
}
// NmeaLatitudePole
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 2 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaLatitudePole[j] = NmeaString[i];
}
// NmeaLongitude
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 11 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaLongitude[j] = NmeaString[i];
}
// NmeaLongitudePole
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 2 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaLongitudePole[j] = NmeaString[i];
}
// NmeaFixQuality
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 2 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaFixQuality[j] = NmeaString[i];
}
// NmeaSatelliteTracked
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 3 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaSatelliteTracked[j] = NmeaString[i];
}
// NmeaHorizontalDilution
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 6 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaHorizontalDilution[j] = NmeaString[i];
}
// NmeaAltitude
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 8 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaAltitude[j] = NmeaString[i];
}
// NmeaAltitudeUnit
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 2 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaAltitudeUnit[j] = NmeaString[i];
}
// NmeaHeightGeoid
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 8 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaHeightGeoid[j] = NmeaString[i];
}
// NmeaHeightGeoidUnit
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 2 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaHeightGeoidUnit[j] = NmeaString[i];
}
//FormatGpsData( );
ConvertPositionFromStringToNumerical( );
ConvertPositionIntoBinary( );
return SUCCESS;
}
else if ( strncmp( ( const char* )NmeaGpsData.NmeaDataType, ( const char* )NmeaDataTypeGPRMC, 5 ) == 0 )
{
// NmeaUtcTime
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 11 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaUtcTime[j] = NmeaString[i];
}
// NmeaDataStatus
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 2 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaDataStatus[j] = NmeaString[i];
}
// NmeaLatitude
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 10 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaLatitude[j] = NmeaString[i];
}
// NmeaLatitudePole
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 2 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaLatitudePole[j] = NmeaString[i];
}
// NmeaLongitude
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 11 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaLongitude[j] = NmeaString[i];
}
// NmeaLongitudePole
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 2 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaLongitudePole[j] = NmeaString[i];
}
// NmeaSpeed
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 8 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaSpeed[j] = NmeaString[i];
}
// NmeaDetectionAngle
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 8 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaDetectionAngle[j] = NmeaString[i];
}
// NmeaDate
fieldSize = 0;
while( NmeaString[i + fieldSize++] != ',' )
{
if( fieldSize > 8 )
{
return FAIL;
}
}
for( j = 0; j < fieldSize; j++, i++ )
{
NmeaGpsData.NmeaDate[j] = NmeaString[i];
}
//FormatGpsData( );
ConvertPositionFromStringToNumerical( );
ConvertPositionIntoBinary( );
return SUCCESS;
}
else
{
return FAIL;
}
}
void GPS::service()
{
while (rx_bufs_in_idx != rx_bufs_out_idx) {
//printf("%02d:%s\r\n", rx_buf_lens[rx_bufs_out_idx], rx_bufs[rx_bufs_out_idx]);
if (verbose)
printf("gps:%s\r\n", rx_bufs[rx_bufs_out_idx]);
ParseGPSData(rx_bufs_out_idx);
if (++rx_bufs_out_idx == NUM_RX_BUFS)
rx_bufs_out_idx = 0;
}
/*if (pps_occurred) {
pps_occurred = false;
if (verbose)
printf("gps:pps\r\n");
}*/
}