Nemanja Neskovic
hgjh
Dependencies: BSP_DISCO_F469NIa EEPROM_DISCO_F469NI LCD_DISCO_F469NIa SD_DISCO_F469NI mbed
Fork of
IntegrationCAN_28jun
by 
Nenad Djalovic
CAN_library.cpp
- Committer:
- nemanja1994
- Date:
- 2018-07-05
- Revision:
- 3:a06e417a5a2c
- Parent:
- 2:f54f01527ebb
File content as of revision 3:a06e417a5a2c:
#include "CAN_library.h"
extern CAN can;
extern Serial pc;
extern SD_DISCO_F469NI sd;
//extern EEPROM_DISCO_F469NI eep;
extern Timer t_int,t_store;
extern CANMessage msgDTA1, msgDTA2, msgDTA3, msgDTA4, msgDTA5, msgDTA6, msgLVDTFront, msgLVDTRear, msgBrakes, msgDistance;
extern uint16_t rx_flag;
extern uint8_t distance_flag;
extern uint8_t lvdtref;
extern uint16_t Rpm0, Speed0, Gear0, Water_Temp0, Oil_Temp0, TPS0, Brakes0, Oil_P0, MAP0, Air_Temp0, Lambda0, Volts0, Crank0;
extern uint16_t Rpm, Speed, Gear, Water_Temp, Oil_Temp, TPS, Brakes, Oil_P, MAP, Air_Temp, Lambda, Volts, Crank;
extern int FL_LVDT0, FR_LVDT0, RL_LVDT0, RR_LVDT0, FL_LVDT, FR_LVDT, RL_LVDT, RR_LVDT;
extern int FL_LVDT_Ref,FR_LVDT_Ref,RL_LVDT_Ref,RR_LVDT_Ref;
int LVDT_Max=150;
extern float Meter_counter,Meter_counter0;
extern char cmd[3];
extern int addr;
extern I2C i2c;
extern void showLedRpm(int rpm);
void CANMsgReceive(){ // CAN RX Interrupt Function
CANMessage tmpMsg;
if (can.read(tmpMsg)) { //Detect message
//pc.printf("%x\n",tmpMsg.id);
switch(tmpMsg.id){ //Find which DTA message is received
case(0x2000):
rx_flag|=(1<<0);
msgDTA1=tmpMsg;
//pc.printf("%x\n", tmpMsg.id);
break;
case(0x2001):
rx_flag|=(1<<1);
msgDTA2=tmpMsg;
//pc.printf("rx_flag=%x\n",rx_flag);
break;
case(0x2002):
rx_flag|=(1<<2);
msgDTA3=tmpMsg;
break;
case(0x2003):
rx_flag|=(1<<3);
msgDTA4=tmpMsg;
break;
case(0x2004):
rx_flag|=(1<<4);
msgDTA5=tmpMsg;
break;
case(0x2005):
rx_flag|=(1<<5);
msgDTA6=tmpMsg;
break;
case(0x1006):
rx_flag|=(1<<6);
msgLVDTFront=tmpMsg;
break;
case(0x1007):
rx_flag|=(1<<7);
msgLVDTRear=tmpMsg;
break;
case(0x1008):
rx_flag|=(1<<8);
msgBrakes=tmpMsg;
break;
case(0x1009):
rx_flag|=(1<<9);
msgDistance=tmpMsg;
};
//pc.printf("rx_flag=%d\n",rx_flag);
};
};
void UpdateInfo(){ // Update info for received values
int noID=10;
uint16_t *newData;
for (int i=0;i<noID;i++){ //For loop goes trough Message IDs
uint16_t flagBit;
flagBit = rx_flag & (1<<i); //Set flag bit for adequate message. If there is a message waiting to be stored, flagBit will be different than 0.
if (flagBit) { // =/=0, there is a message, =0, there is no message
switch(i){
case(0):
newData=AllocData(msgDTA1); //Allocate message to a receiver
UpdateInfoDTA1(newData); //Update variables
rx_flag = rx_flag ^ (1<<0); //Set flag of adequate bit to 0
break;
case(1):
newData=AllocData(msgDTA2);
UpdateInfoDTA2(newData);
rx_flag = rx_flag ^ (1<<1);
break;
case(2):
newData=AllocData(msgDTA3);
UpdateInfoDTA3(newData);
rx_flag = rx_flag ^ (1<<2);
break;
case(3):
newData=AllocData(msgDTA4);
UpdateInfoDTA4(newData);
rx_flag = rx_flag ^ (1<<3);
break;
case(4):
newData=AllocData(msgDTA5);
UpdateInfoDTA5(newData);
rx_flag = rx_flag ^ (1<<4);
break;
case(5):
newData=AllocData(msgDTA6);
UpdateInfoDTA6(newData);
rx_flag = rx_flag ^ (1<<5);
break;
case(6):
newData=AllocData(msgLVDTFront);
UpdateInfoLVDTFront(newData);
rx_flag = rx_flag ^ (1<<6);
break;
case(7):
newData=AllocData(msgLVDTRear);
UpdateInfoLVDTRear(newData);
rx_flag = rx_flag ^ (1<<7);
break;
case(8):
newData=AllocData(msgBrakes);
UpdateInfoBrakes(newData);
rx_flag = rx_flag ^ (1<<8);
break;
case(9):
newData=AllocData(msgDistance);
if(distance_flag==0){
InitDistanceMeter(newData);
distance_flag=1;
};
rx_flag = rx_flag ^ (1<<9);
// for each new id add new case statement
};
};
};
UpdateMeterCounter();
};
uint16_t * AllocData(CANMessage msg){ //Unpack CAN message
uint16_t newData[4];
newData[0]=(msg.data[1]<<8) | msg.data[0];
newData[1]=(msg.data[3]<<8) | msg.data[2];
newData[2]=(msg.data[5]<<8) | msg.data[4];
newData[3]=(msg.data[7]<<8) | msg.data[6];
return newData;
};
void InitDistanceMeter(uint16_t newData[4]){
uint32_t DistanceBuffer;
DistanceBuffer=(uint32_t)((newData[1]<<16) | (newData[0]));
Meter_counter=float(DistanceBuffer)*10;
pc.printf("Init success, start km=%d,%f\n",DistanceBuffer,Meter_counter);
t_int.start();
t_store.start();
};
/*void InitDistanceMeter(){
uint32_t distance_buffer;
if(sd.ReadBlocks((uint32_t*)distance_buffer,DISTANCE_MEMORY_ADDR ,1,SD_DATATIMEOUT)){
Meter_counter=(float(distance_buffer))/100;
};*/
/*void InitDistanceMeter(){
uint8_t DistanceBuffer8[4];
uint32_t DistanceBuffer32;
if(eep.ReadBuffer(DistanceBuffer8, 0, (uint16_t*)4)){
pc.printf("Read success\n");
}
DistanceBuffer32=(DistanceBuffer8[0]<<24) | (DistanceBuffer8[1]<<16) | (DistanceBuffer8[2]<<8) | DistanceBuffer8[3];
Meter_counter=(float(DistanceBuffer32))/100;
pc.printf("Meter_counter=%f\n",Meter_counter);
};*/
void UpdateInfoDTA1(uint16_t newData[4]){ //Update values for DTA1 message
Rpm0=Rpm;
Rpm=newData[0];
showLedRpm(Rpm);
TPS0=TPS;
TPS=newData[1];
Water_Temp0=Water_Temp;
Water_Temp=newData[2];
Air_Temp0=Air_Temp;
Air_Temp=newData[3];
//pc.printf("%d %d %d %d", Rpm, TPS,Water_Temp,Air_Temp);
};
void UpdateInfoDTA2(uint16_t newData[4]){ //Update values for DTA2 message
MAP0=MAP;
MAP=newData[0];
Lambda0=Lambda;
Lambda=newData[1];
Speed0=Speed;
Speed=newData[2];
Oil_P0=Oil_P;
Oil_P=newData[3];
//pc.printf("MAP=%d, Lambda=%d, Speed=%d, Oil_P=%d\n",MAP,Lambda,Speed,Oil_P);
};
void UpdateInfoDTA3(uint16_t newData[4]){ //Update values for DTA3 message
Oil_Temp0=Oil_Temp;
Oil_Temp=newData[1];
Volts0=Volts;
Volts=newData[2];
};
void UpdateInfoDTA4(uint16_t newData[4]){ //Update values for DTA4 message
Gear0=Gear;
Gear=newData[0];
};
void UpdateInfoDTA5(uint16_t newData[4]){ //Update values for DTA5 message
};
void UpdateInfoDTA6(uint16_t newData[4]){ //Update values for DTA6 message
Crank0=Crank;
Crank=newData[2];
};
void UpdateMeterCounter(){
float ti=t_int.read();
if(ti>0.1){
Meter_counter0=Meter_counter;
Meter_counter=Meter_counter+(float)(Speed*0.0277778); // 0.1*1000/3600
t_int.reset();
};
if(t_store>2){
char DistanceBuffer8[8];
uint32_t DistanceBuffer32=uint32_t(Meter_counter);
DistanceBuffer32=uint32_t(Meter_counter);
DistanceBuffer8[0]=uint8_t(DistanceBuffer32>>24);
DistanceBuffer8[1]=uint8_t((DistanceBuffer32 & (uint32_t)0x00FF0000)>>16);
DistanceBuffer8[2]=uint8_t((DistanceBuffer32 & (uint32_t)0x0000FF00)>>8);
DistanceBuffer8[3]=uint8_t((DistanceBuffer32 & (uint32_t)0x000000FF));
CANMessage msg;
if(can.write(CANMessage((uint16_t)DISTANCE,DistanceBuffer8, 8))) {
pc.printf("%d\n",DistanceBuffer32);
};
t_store.reset();
/*uint32_t distance_buffer;
//distance_buffer=uint32_t(Meter_counter) ;
pc.printf("distance=%d\n",distance_buffer);
distance_buffer=0xFF000000;
if(sd.WriteBlocks((uint32_t*)distance_buffer,DISTANCE_MEMORY_ADDR,1,SD_DATATIMEOUT)){
pc.printf("Storage success\n");
}else{
pc.printf("Storage failed\n");
};*/
/*uint32_t DistanceBuffer32;
uint8_t DistanceBuffer8[4];
DistanceBuffer32=uint32_t(Meter_counter);
DistanceBuffer8[0]=DistanceBuffer32>>24;
DistanceBuffer8[1]=(DistanceBuffer32 & (uint32_t)0x00FF0000)>>16;
DistanceBuffer8[2]=(DistanceBuffer32 & (uint32_t)0x0000FF00)>>8;
DistanceBuffer8[3]=(DistanceBuffer32 & (uint32_t)0x000000FF);
if(eep.WriteBuffer(DistanceBuffer8,0,4)){
pc.printf("Write success,Distance=%d\n",DistanceBuffer32);
};*/
};
};
void send(uint16_t ID, char dta[8]) {
if(can.write(CANMessage((uint16_t)ID,dta, 8))) {
printf("%x\n",ID);
printf("Message sent: info1=%x%x, info2=%x%x, info3=%x%x, info4=%x%x\n", dta[1],dta[0],dta[3],dta[2],dta[5],dta[4],dta[7],dta[6]);
}else{
printf("Shit\n");
}
};
void UpdateInfoLVDTFront(uint16_t newData[4]){ //Update values for LVDTFront message
FL_LVDT0=FL_LVDT; //LVDTs are firstly written their voltage value, then overwritten by calculated pertentage value.
FL_LVDT=newData[0];
FR_LVDT0=FR_LVDT;
FR_LVDT=newData[1];
if(!(lvdtref & (1<<3))){ //Check if its the first time LVDT value is received. If yes than store it as Referrent value.
if (FL_LVDT>FL_LVDT_Ref){
FL_LVDT=(FL_LVDT-FL_LVDT_Ref)*100/(LVDT_Max-FL_LVDT_Ref);
}else{
FL_LVDT=(FL_LVDT-FL_LVDT_Ref)*100/FL_LVDT_Ref;
};
//pc.printf("Im in 1\n");
}else{
FL_LVDT_Ref=FL_LVDT;
FL_LVDT=0;
lvdtref=lvdtref^(1<<3);
//pc.printf("Ref=%d\n",FL_LVDT_Ref);
};
//pc.printf("FL_LVDT=%d, FL_LVDT0=%d\n",abs(FL_LVDT),abs(FL_LVDT0));
//pc.printf("FR_LVDT=%d, FR_LVDT0=%d\n",abs(FR_LVDT),abs(FR_LVDT0));
if(!(lvdtref & (1<<2))){
if (FR_LVDT>FR_LVDT_Ref){
FR_LVDT=(FR_LVDT-FR_LVDT_Ref)*100/(LVDT_Max-FR_LVDT_Ref);
}else{
FR_LVDT=(FR_LVDT-FR_LVDT_Ref)*100/FR_LVDT_Ref;
};
}else{
FR_LVDT_Ref=FR_LVDT;
FR_LVDT=0;
lvdtref=lvdtref^(1<<2);
};
//printf("FL_Ref=%d, FR_Ref=%d, RL_Ref=%d, RR_Ref=%d\n",FL_LVDT_Dpos,FR_LVDT_Dpos,RL_LVDT_Dpos,RR_LVDT_Dpos);
};
void UpdateInfoLVDTRear(uint16_t newData[4]){ //Update values for LVDTRear message
RL_LVDT0=RL_LVDT;
RL_LVDT=newData[0];
RR_LVDT0=RR_LVDT;
RR_LVDT=newData[1];
if(!(lvdtref & (1<<1))){
if (RL_LVDT>RL_LVDT_Ref){
RL_LVDT=(RL_LVDT-RL_LVDT_Ref)*100/(LVDT_Max-RL_LVDT_Ref);
}else{
RL_LVDT=(RL_LVDT-RL_LVDT_Ref)*100/RL_LVDT_Ref;
};
}else{
RL_LVDT_Ref=RL_LVDT;
RL_LVDT=0;
lvdtref=lvdtref^(1<<1);
};
if(!(lvdtref & (1<<0))){
if (RR_LVDT>RR_LVDT_Ref){
RR_LVDT=(RR_LVDT-RR_LVDT_Ref)*100/(LVDT_Max-RR_LVDT_Ref);
}else{
RR_LVDT=(RR_LVDT-RR_LVDT_Ref)*100/RR_LVDT_Ref;
};
}else{
RR_LVDT_Ref=RR_LVDT;
RR_LVDT=0;
lvdtref=lvdtref^(1<<0);
};
//pc.printf("RL_LVDT=%d, RL_LVDT0=%d\n",abs(RL_LVDT),abs(RL_LVDT0));
//pc.printf("RR_LVDT=%d, RR_LVDT0=%d\n",abs(RR_LVDT),abs(RR_LVDT0));
};
void UpdateInfoBrakes(uint16_t newData[4]){ //Update values for Brakes message
Brakes0=Brakes;
Brakes=newData[0];
};