UKESF Headstart Summer School
Modified version of the UKESF lab source which can be carried out with no knowledge of C
Fork of
PsiSwarm-Headstart
by 
UKESF Headstart Summer School
eprom.cpp
- Committer:
- YRL50
- Date:
- 2018-09-14
- Revision:
- 5:f6be169e465b
- Parent:
- 4:dc77a25f29de
File content as of revision 5:f6be169e465b:
/** University of York Robotics Laboratory PsiSwarm Library: Eprom Functions Source File
*
* File: eprom.cpp
*
* (C) Dept. Electronics & Computer Science, University of York
* James Hilder, Alan Millard, Alexander Horsfield, Homero Elizondo, Jon Timmis
*
* PsiSwarm Library Version: 0.5
*
* April 2016
*
* Functions for accessing the 64Kb EPROM chip and reading the reserved firmware block
*
* Example:
* @code
* #include "psiswarm.h"
*
* int main() {
* init();
* write_eeprom_byte(0,0xDD); //Writes byte 0xDD in EPROM address 0
* char c = read_eeprom_byte(0); //c will hold 0xDD
* //Valid address range is from 0 to 65279
* }
* @endcode
*/
#include "psiswarm.h"
/** Write a single byte to the EPROM
*
* @param address The address to store the data, range 0-65279
* @param data The character to store
*/
void write_eeprom_byte ( int address, char data )
{
char write_array[3];
if(address > 65279) {
debug("WARNING: Attempt to write to invalid EPROM address: %X",address);
} else {
write_array[0] = address / 256;
write_array[1] = address % 256;
write_array[2] = data;
primary_i2c.write(EEPROM_ADDRESS, write_array, 3, false);
//Takes 5ms to write a page: ideally this could be done with a timer or RTOS
wait(0.005);
}
}
/** Read a single byte from the EPROM
*
* @param address The address to read from, range 0-65279
* @return The character stored at address
*/
char read_eeprom_byte ( int address )
{
char address_array [2];
address_array[0] = address / 256;
address_array[1] = address % 256;
char data [1];
primary_i2c.write(EEPROM_ADDRESS, address_array, 2, false);
primary_i2c.read(EEPROM_ADDRESS, data, 1, false);
return data [0];
}
/** Read the next byte from the EPROM, to be called after read_eeprom_byte
*
* @return The character stored at address after the previous one read from
*/
char read_next_eeprom_byte ()
{
char data [1];
primary_i2c.read(EEPROM_ADDRESS, data, 1, false);
return data [0];
}
/** Read the data stored in the reserved firmware area of the EPROM
*
* @return 1 if a valid firmware is read, 0 otherwise
*/
char read_firmware ()
{
char address_array [2] = {255,0};
primary_i2c.write(EEPROM_ADDRESS, address_array, 2, false);
primary_i2c.read(EEPROM_ADDRESS, firmware_bytes, 21, false);
if(firmware_bytes[0] == PSI_BYTE) {
// Parse firmware
char firmware_string [8];
sprintf(firmware_string,"%d.%d",firmware_bytes[9],firmware_bytes[10]);
firmware_version = atof(firmware_string);
char pcb_version_string [8];
sprintf(pcb_version_string,"%d.%d",firmware_bytes[7],firmware_bytes[8]);
pcb_version = atof(pcb_version_string);
char serial_number_string [8];
sprintf(serial_number_string,"%d.%d",firmware_bytes[5],firmware_bytes[6]);
serial_number = atof(serial_number_string);
has_compass = firmware_bytes[11];
has_side_ir = firmware_bytes[12];
has_base_ir = firmware_bytes[13];
has_base_colour_sensor= firmware_bytes[14];
has_top_colour_sensor= firmware_bytes[15];
has_wheel_encoders= firmware_bytes[16];
has_audio_pic= firmware_bytes[17];
has_ultrasonic_sensor= firmware_bytes[18];
has_temperature_sensor= firmware_bytes[19];
has_recharging_circuit= firmware_bytes[20];
has_433_radio= firmware_bytes[21];
if(firmware_version > 1.0){
motor_calibration_set = firmware_bytes[22];
if(motor_calibration_set == 1){
left_motor_calibration_value = (float) firmware_bytes[23] * 65536;
left_motor_calibration_value += ((float) firmware_bytes[24] * 256);
left_motor_calibration_value += firmware_bytes[25];
left_motor_calibration_value /= 16777216;
right_motor_calibration_value = (float) firmware_bytes[26] * 65536;
right_motor_calibration_value += ((float) firmware_bytes[27] * 256);
right_motor_calibration_value += firmware_bytes[28];
right_motor_calibration_value /= 16777216;
}
} else motor_calibration_set = 0;
return 1;
}
return 0;
}