Callum and Adel's changes on 12/02/19
Dependencies: Crypto
main.cpp
- Committer:
- adehadd
- Date:
- 2019-03-18
- Revision:
- 31:b10ca6cf39bf
- Parent:
- 30:fbae0e5f200d
- Child:
- 32:fc5e00d9f74d
File content as of revision 31:b10ca6cf39bf:
#include "SHA256.h" #include "mbed.h" // #include <iostream> // #include "rtos.h" /*TODO: Change Indx newCmd MAXCMDLENGTH move the global variables to a class because we arent paeasents */ //Photointerrupter input pins #define I1pin D3 #define I2pin D6 #define I3pin D5 //Incremental encoder input pins #define CHApin D12 #define CHBpin D11 //Motor Drive output pins //Mask in output byte #define L1Lpin D1 //0x01 #define L1Hpin A3 //0x02 #define L2Lpin D0 //0x04 #define L2Hpin A6 //0x08 #define L3Lpin D10 //0x10 #define L3Hpin D2 //0x20 #define PWMpin D9 //Motor current sense #define MCSPpin A1 #define MCSNpin A0 //Mapping from sequential drive states to motor phase outputs /* State L1 L2 L3 0 H - L 1 - H L 2 L H - 3 L - H 4 - L H 5 H L - 6 - - - 7 - - - */ //Status LED DigitalOut led1(LED1); //Photointerrupter inputs InterruptIn I1(I1pin); InterruptIn I2(I2pin); InterruptIn I3(I3pin); //Motor Drive outputs DigitalOut L1L(L1Lpin); DigitalOut L1H(L1Hpin); DigitalOut L2L(L2Lpin); DigitalOut L2H(L2Hpin); DigitalOut L3L(L3Lpin); DigitalOut L3H(L3Hpin); PwmOut pwmCtrl(PWMpin); //Drive state to output table const int8_t driveTable[] = {0x12,0x18,0x09,0x21,0x24,0x06,0x00,0x00}; //Mapping from interrupter inputs to sequential rotor states. 0x00 and 0x07 are not valid const int8_t stateMap[] = {0x07,0x05,0x03,0x04,0x01,0x00,0x02,0x07}; //const int8_t stateMap[] = {0x07,0x01,0x03,0x02,0x05,0x00,0x04,0x07}; //Alternative if phase order of input or drive is reversed //Phase lead to make motor spin const int8_t lead = 2; //2 for forwards, -2 for backwards class Comm /*: public T_*/{ public: Thread t_comm_out; // Thread *p_motor_ctrl; bool _RUN; RawSerial pc; // Queue<void, 8> inCharQ; // Input Character Queue static const char MsgChar[11]; uint8_t MAXCMDLENGTH; volatile uint8_t cmdIndx; volatile uint8_t inCharQIdx; volatile uint32_t motorPower; // motor toque volatile float targetVel; volatile float targetRot; enum msgType {motorState, posIn, velIn, posOut, velOut, hashRate, keyAdded, nonceMatch, torque, rotations, error}; typedef struct { msgType type; uint32_t message; } msg; Mail<msg, 32> mailStack; void serialISR(){ if (pc.readable()) { char newChar = pc.getc(); // inCharQ.put((void*)newChar); // void* = pointer to an unknown type that cannot be dereferenced if (inCharQIdx == (MAXCMDLENGTH)) { inCharQ[MAXCMDLENGTH] = '\0'; // force the string to have an end character putMessage(error, 1); inCharQIdx = 0; // reset buffer index // pc.putc('\r'); // carriage return moves to the start of the line // for (int i = 0; i < MAXCMDLENGTH; ++i) // { // inCharQ[i] = ' '; // pc.putc(' '); // } // pc.putc('\r'); // carriage return moves to the start of the line } else{ if(newChar != '\r'){ //While the command is not over, inCharQ[inCharQIdx] = newChar; //save input character and inCharQIdx++; //advance index pc.putc(newChar); } else{ inCharQ[inCharQIdx] = '\0'; //When the command is finally over, strncpy(newCmd, inCharQ, MAXCMDLENGTH); // Will copy 18 characters from inCharQ to newCmd cmdParser(); //parse the command for decoding. for (int i = 0; i < MAXCMDLENGTH; ++i) // reset buffer inCharQ[i] = ' '; inCharQIdx = 0; // reset index } } } } void returnCursor() { pc.putc('>'); for (int i = 0; i < inCharQIdx; ++i) // reset cursor position pc.putc(inCharQ[i]); // for (int i = inCharQIdx; i < MAXCMDLENGTH; ++i) // fill remaining with blanks // pc.putc(' '); // pc.putc('<'); } void cmdParser(){ switch(newCmd[0]) { case 'K': //(MsgChar[keyAdded]):// newKey_mutex.lock(); //Ensure there is no deadlock sscanf(newCmd, "K%x", &newKey); //Find desired the Key code putMessage(keyAdded, newKey); //Print it out newKey_mutex.unlock(); break; case 'V': //(MsgChar[velIn]):// sscanf(newCmd, "V%f", &targetVel); //Find desired the target velocity putMessage(velIn, targetVel); //Print it out break; case 'R': //(MsgChar[posIn]):// sscanf(newCmd, "R%f", &targetRot); //Find desired target rotation putMessage(posIn, targetRot); //Print it out break; case 'T': //(MsgChar[torque]):// sscanf(newCmd, "T%d", &motorPower); //Find desired target torque putMessage(torque, motorPower); //Print it out break; default: break; } } //~~~~~Decode messages to print on serial port~~~~~ void commOutFn() { while (_RUN) { osEvent newEvent = mailStack.get(); msg *pMessage = (msg *) newEvent.value.p; //Case switch to choose serial output based on incoming message switch (pMessage->type) { case motorState: pc.printf("The motor is currently in state %x\n\r", pMessage->message); break; case hashRate: pc.printf("\r>%s< Mining: %.4u Hash/s\r", inCharQ, (uint32_t) pMessage->message); returnCursor(); break; case nonceMatch: pc.printf("\r>%s< Nonce found: %x\r", inCharQ, pMessage->message); returnCursor(); break; case keyAdded: pc.printf("New Key Added:\t0x%016x\n\r", pMessage->message); break; case torque: pc.printf("Motor Torque set to:\t%d\n\r", pMessage->message); break; case velIn: pc.printf("Target Velocity set to:\t%.2f\n\r", targetVel); break; case velOut: pc.printf("Current Velocity:\t%.2f\n\r", \ (float) ((int32_t) pMessage->message / 6)); break; case posIn: pc.printf("Target Rotation set to:\t%.2f\n\r", \ (float) ((int32_t) pMessage->message / 6)); break; case posOut: pc.printf("Current Position:\t%.2f\n\r", \ (float) ((int32_t) pMessage->message / 6)); break; case error: pc.printf("\r>%s< Debugging position:%x\n\r", inCharQ, pMessage->message); for (int i = 0; i < MAXCMDLENGTH; ++i) // reset buffer inCharQ[i] = ' '; break; default: pc.printf("Unknown Error. Message: %x\n\r", pMessage->message); break; } mailStack.free(pMessage); } } //TODO: stop function, maybe use parent de-constructor //void stop_comm{} // public: volatile uint64_t newKey; // hash key Mutex newKey_mutex; // Restrict access to prevent deadlock. Comm() : pc(SERIAL_TX, SERIAL_RX), t_comm_out(osPriorityAboveNormal, 1024) { // inherit from the RawSerial constructor pc.printf("%s\n\r", "Welcome" ); MAXCMDLENGTH = 18; // reset buffer // MbedOS prints 'Embedded Systems are fun and do awesome things!' // if you print a null terminator pc.putc('>'); for (int i = 0; i < MAXCMDLENGTH; ++i) { inCharQ[i] = '.'; pc.putc('.'); } pc.putc('<'); pc.putc('\r'); inCharQ[MAXCMDLENGTH] = '\0'; strncpy(newCmd, inCharQ, MAXCMDLENGTH); cmdIndx = 0; inCharQIdx = 0; // inCharQIdx = MAXCMDLENGTH-1; pc.attach(callback(this, &Comm::serialISR)); // Thread t_comm_in(osPriorityAboveNormal, 1024); // Thread t_comm_out(osPriorityAboveNormal, 1024); // Thread t_motor_ctrl(osPriorityAboveNormal, 1024); motorPower = 300; targetVel = 45.0; targetRot = 459.0; /*MsgChar = {'m', 'R', 'V', 'r', 'v', 'h', 'K', 'n', 'T', 'r', 'e'};*/ } void putMessage(msgType type, uint32_t message){ msg *p_msg = mailStack.alloc(); p_msg->type = type; p_msg->message = message; mailStack.put(p_msg); } void start_comm(){ _RUN = true; // reset buffer // MbedOS prints 'Embedded Systems are fun and do awesome things!' // if you print a null terminator pc.putc('>'); for (int i = 0; i < MAXCMDLENGTH; ++i) { inCharQ[i] = '.'; pc.putc('.'); } pc.putc('<'); pc.putc('\r'); inCharQ[MAXCMDLENGTH] = '\0'; strncpy(newCmd, inCharQ, MAXCMDLENGTH); // returnCursor(); // t_comm_in.start(callback(this, &Comm::commInFn)); // this::thread::wait() // wait(1.0); t_comm_out.start(callback(this, &Comm::commOutFn)); } char newCmd[]; // because unallocated must be defined at the bottom of the class char inCharQ[]; }; class Motor { protected: int8_t orState; //Rotor offset at motor state 0, motor specific volatile int8_t currentState; //Current Rotor State volatile int8_t stateList[6]; //All possible rotor states stored //Phase lead to make motor spin int8_t lead; Comm* p_comm; //Run the motor synchronisation float dutyC; // 1 = 100% float mtrPeriod; // motor period uint8_t stateCount[3]; // State Counter uint8_t theStates[3]; // The Key states Thread t_motor_ctrl; // Thread for motor Control public: Motor() : t_motor_ctrl(osPriorityAboveNormal, 1024) { // Set Power to maximum to drive motorHome() dutyC = 1; mtrPeriod = 2e-3; // motor period pwmCtrl.period(mtrPeriod); pwmCtrl.pulsewidth(mtrPeriod*dutyC); orState = motorHome(); //Rotot offset at motor state 0 currentState = readRotorState(); //Current Rotor State // stateList[6] = {0,0,0, 0,0,0}; //All possible rotor states stored theStates[0] = orState; theStates[1] = (orState + lead) % 6; theStates[2] = (orState + (lead*2)) % 6; lead = 2; //2 for forwards, -2 for backwards stateCount[0] = 0; stateCount[1] = 0; stateCount[2] = 0; theStates[0] = 0; theStates[1] = 0; theStates[2] = 0; p_comm = NULL; // null pointer for now } void motorStart(Comm *comm) { // Establish Photointerrupter Service Routines (auto choose next state) I1.fall(callback(this, &Motor::stateUpdate)); I2.fall(callback(this, &Motor::stateUpdate)); I3.fall(callback(this, &Motor::stateUpdate)); I1.rise(callback(this, &Motor::stateUpdate)); I2.rise(callback(this, &Motor::stateUpdate)); I3.rise(callback(this, &Motor::stateUpdate)); // push digitally so if motor is static it will start moving motorOut((currentState-orState+lead+6)%6); // We push it digitally // Default a lower duty cylce dutyC = 0.8; pwmCtrl.period(mtrPeriod); pwmCtrl.pulsewidth(mtrPeriod*dutyC); // Start motor control thread t_motor_ctrl.start(callback(this, &Motor::motorCtrlFn)); p_comm = comm; } //Set a given drive state void motorOut(int8_t driveState) { //Lookup the output byte from the drive state. int8_t driveOut = driveTable[driveState & 0x07]; //Turn off first if (~driveOut & 0x01) L1L = 0; if (~driveOut & 0x02) L1H = 1; if (~driveOut & 0x04) L2L = 0; if (~driveOut & 0x08) L2H = 1; if (~driveOut & 0x10) L3L = 0; if (~driveOut & 0x20) L3H = 1; //Then turn on if (driveOut & 0x01) L1L = 1; if (driveOut & 0x02) L1H = 0; if (driveOut & 0x04) L2L = 1; if (driveOut & 0x08) L2H = 0; if (driveOut & 0x10) L3L = 1; if (driveOut & 0x20) L3H = 0; } //Convert photointerrupter inputs to a rotor state inline int8_t readRotorState() { return stateMap[I1 + 2*I2 + 4*I3]; } //Basic synchronisation routine int8_t motorHome() { //Put the motor in drive state 0 and wait for it to stabilise motorOut(0); wait(2.0); //Get the rotor state return readRotorState(); } void stateUpdate() { // () { // **params currentState = readRotorState(); // Store into state counter if (currentState == theStates[0]) stateCount[0]++; else if (currentState == theStates[1]) stateCount[1]++; else if (currentState == theStates[2]) stateCount[2]++; // (Current - Offset + lead + 6) %6 motorOut((currentState - orState + lead + 6) % 6); } // attach_us -> runs funtion every 100ms void motorCtrlFn() { Ticker motorCtrlTicker; motorCtrlTicker.attach_us(callback(this,&Motor::motorCtrlTick), 1e5); while (1) { t_motor_ctrl.signal_wait((int32_t)0x1); p_comm->pc.printf("B4115"); } } void motorCtrlTick(){ t_motor_ctrl.signal_set(0x1); } }; //Main int main() { // std::ios::sync_with_stdio(false); Comm comm_plz; // comm_plz.pc.printf("%s\n", "do i work bruh" ); // using printf of class is calm SHA256 Miner; Motor motor; uint8_t sequence[] = {0x45,0x6D,0x62,0x65,0x64,0x64,0x65,0x64, 0x20,0x53,0x79,0x73,0x74,0x65,0x6D,0x73, 0x20,0x61,0x72,0x65,0x20,0x66,0x75,0x6E, 0x20,0x61,0x6E,0x64,0x20,0x64,0x6F,0x20, 0x61,0x77,0x65,0x73,0x6F,0x6D,0x65,0x20, 0x74,0x68,0x69,0x6E,0x67,0x73,0x21,0x20, 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00}; uint64_t* key = (uint64_t*)((int)sequence + 48); uint64_t* nonce = (uint64_t*)((int)sequence + 56); uint8_t hash[32]; uint32_t length64 = 64; uint32_t hashCounter = 0; Timer timer; motor.motorStart(&comm_plz); comm_plz.start_comm(); // Motor States // pc.printf("Rotor origin: %x\n\r",orState); // orState is subtracted from future rotor state inputs to align rotor and motor states // intState = readRotorState(); //if (intState != intStateOld) { // pc.printf("old:%d \t new:%d \t next:%d \n\r",intStateOld, intState, (intState-orState+lead+6)%6); // intStateOld = intState; // motorOut((intState-orState+lead+6)%6); //+6 to make sure the remainder is positive // } // Keep the program running indefinitely timer.start(); // start timer while (1) { // pc.printf("Current:%d \t Next:%d \n\r", currentState, (currentState-orState+lead+6)%6); comm_plz.newKey_mutex.lock(); *key = comm_plz.newKey; comm_plz.newKey_mutex.unlock(); Miner.computeHash(hash, sequence, length64); hashCounter++; if ((hash[0]==0) && (hash[1]==0)){ comm_plz.putMessage((Comm::msgType)7, *nonce); } // Try a new nonce (*nonce)++; // Per Second i.e. when greater or equal to 1 if (timer.read() >= 1){ comm_plz.putMessage((Comm::msgType)5, hashCounter); //pc.printf("HashRate = %02u \n\r",hashCounter); hashCounter=0; timer.reset(); } } }