aircord
test2017-1-13
Dependencies: AT24C1024 DMX-STM32 mbed
Diff: AccelStepper.cpp
- Revision:
- 0:d94213e24c2e
- Child:
- 4:c3f3fdde7eee
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/AccelStepper.cpp Fri Jan 13 03:28:16 2017 +0000
@@ -0,0 +1,612 @@
+// AccelStepper.cpp
+//
+// Copyright (C) 2009-2013 Mike McCauley
+// $Id: AccelStepper.cpp,v 1.19 2014/10/31 06:05:27 mikem Exp mikem $
+
+#include "AccelStepper.h"
+
+#if 0
+// Some debugging assistance
+void dump(uint8_t* p, int l)
+{
+ int i;
+
+ for (i = 0; i < l; i++) {
+ Serial.print(p[i], HEX);
+ Serial.print(" ");
+ }
+ Serial.println("");
+}
+#endif
+
+void AccelStepper::moveTo(long absolute)
+{
+ if (_targetPos != absolute) {
+ _targetPos = absolute;
+ computeNewSpeed();
+ // compute new n?
+ }
+}
+
+void AccelStepper::move(long relative)
+{
+ moveTo(_currentPos + relative);
+}
+
+// Implements steps according to the current step interval
+// You must call this at least once per step
+// returns true if a step occurred
+bool AccelStepper::runSpeed()
+{
+ extern Timer t;
+ // Dont do anything unless we actually have a step interval
+ if (!_stepInterval)
+ return false;
+
+ //unsigned long time = micros();
+ unsigned long time = t.read_us();
+ unsigned long nextStepTime = _lastStepTime + _stepInterval;
+ // Gymnastics to detect wrapping of either the nextStepTime and/or the current time
+ if ( ((nextStepTime >= _lastStepTime) && ((time >= nextStepTime) || (time < _lastStepTime)))
+ || ((nextStepTime < _lastStepTime) && ((time >= nextStepTime) && (time < _lastStepTime)))) {
+ if (_direction == DIRECTION_CW) {
+ // Clockwise
+ _currentPos += 1;
+ } else {
+ // Anticlockwise
+ _currentPos -= 1;
+ }
+ step(_currentPos);
+
+ _lastStepTime = time;
+ return true;
+ } else {
+ return false;
+ }
+}
+
+long AccelStepper::distanceToGo()
+{
+ return _targetPos - _currentPos;
+}
+
+long AccelStepper::targetPosition()
+{
+ return _targetPos;
+}
+
+long AccelStepper::currentPosition()
+{
+ return _currentPos;
+}
+
+// Useful during initialisations or after initial positioning
+// Sets speed to 0
+void AccelStepper::setCurrentPosition(long position)
+{
+ _targetPos = _currentPos = position;
+ _n = 0;
+ _stepInterval = 0;
+}
+
+void AccelStepper::computeNewSpeed()
+{
+ long distanceTo = distanceToGo(); // +ve is clockwise from curent location
+
+ long stepsToStop = (long)((_speed * _speed) / (2.0 * _acceleration)); // Equation 16
+
+ if (distanceTo == 0 && stepsToStop <= 1) {
+ // We are at the target and its time to stop
+ _stepInterval = 0;
+ _speed = 0.0;
+ _n = 0;
+ return;
+ }
+
+ if (distanceTo > 0) {
+ // We are anticlockwise from the target
+ // Need to go clockwise from here, maybe decelerate now
+ if (_n > 0) {
+ // Currently accelerating, need to decel now? Or maybe going the wrong way?
+ if ((stepsToStop >= distanceTo) || _direction == DIRECTION_CCW)
+ _n = -stepsToStop; // Start deceleration
+ } else if (_n < 0) {
+ // Currently decelerating, need to accel again?
+ if ((stepsToStop < distanceTo) && _direction == DIRECTION_CW)
+ _n = -_n; // Start accceleration
+ }
+ } else if (distanceTo < 0) {
+ // We are clockwise from the target
+ // Need to go anticlockwise from here, maybe decelerate
+ if (_n > 0) {
+ // Currently accelerating, need to decel now? Or maybe going the wrong way?
+ if ((stepsToStop >= -distanceTo) || _direction == DIRECTION_CW)
+ _n = -stepsToStop; // Start deceleration
+ } else if (_n < 0) {
+ // Currently decelerating, need to accel again?
+ if ((stepsToStop < -distanceTo) && _direction == DIRECTION_CCW)
+ _n = -_n; // Start accceleration
+ }
+ }
+
+ // Need to accelerate or decelerate
+ if (_n == 0) {
+ // First step from stopped
+ _cn = _c0;
+ _direction = (distanceTo > 0) ? DIRECTION_CW : DIRECTION_CCW;
+ } else {
+ // Subsequent step. Works for accel (n is +_ve) and decel (n is -ve).
+ _cn = _cn - ((2.0 * _cn) / ((4.0 * _n) + 1)); // Equation 13
+ _cn = max(_cn, _cmin);
+ }
+ _n++;
+ _stepInterval = _cn;
+ _speed = 1000000.0 / _cn;
+ if (_direction == DIRECTION_CCW)
+ _speed = -_speed;
+
+#if 0
+ Serial.println(_speed);
+ Serial.println(_acceleration);
+ Serial.println(_cn);
+ Serial.println(_c0);
+ Serial.println(_n);
+ Serial.println(_stepInterval);
+ Serial.println(distanceTo);
+ Serial.println(stepsToStop);
+ Serial.println("-----");
+#endif
+}
+
+// Run the motor to implement speed and acceleration in order to proceed to the target position
+// You must call this at least once per step, preferably in your main loop
+// If the motor is in the desired position, the cost is very small
+// returns true if the motor is still running to the target position.
+bool AccelStepper::run()
+{
+ if (runSpeed())
+ computeNewSpeed();
+ return _speed != 0.0 || distanceToGo() != 0;
+}
+
+AccelStepper::AccelStepper(uint8_t interface, PinName pin1, PinName pin2, PinName pin3, PinName pin4, bool enable)
+{
+ _interface = interface;
+ _currentPos = 0;
+ _targetPos = 0;
+ _speed = 0.0;
+ _maxSpeed = 1.0;
+ _acceleration = 0.0;
+ _sqrt_twoa = 1.0;
+ _stepInterval = 0;
+ _minPulseWidth = 1;
+ _lastStepTime = 0;
+ // _pin[0] = pin1;
+ // _pin[1] = pin2;
+ // _pin[2] = pin3;
+ // _pin[3] = pin4;
+ _pin0 = new DigitalOut(pin1);
+ _pin1 = new DigitalOut(pin2);
+ _pin2 = new DigitalOut(pin3);
+ _pin3 = new DigitalOut(pin4);
+
+ // NEW
+ _n = 0;
+ _c0 = 0.0;
+ _cn = 0.0;
+ _cmin = 1.0;
+ _direction = DIRECTION_CCW;
+
+ int i;
+ for (i = 0; i < 4; i++)
+ _pinInverted[i] = 0;
+ if (enable)
+ enableOutputs();
+ // Some reasonable default
+ setAcceleration(1);
+}
+
+AccelStepper::AccelStepper(void (*forward)(), void (*backward)())
+{
+ _interface = 0;
+ _currentPos = 0;
+ _targetPos = 0;
+ _speed = 0.0;
+ _maxSpeed = 1.0;
+ _acceleration = 0.0;
+ _sqrt_twoa = 1.0;
+ _stepInterval = 0;
+ _minPulseWidth = 1;
+ _lastStepTime = 0;
+ _forward = forward;
+ _backward = backward;
+
+ // NEW
+ _n = 0;
+ _c0 = 0.0;
+ _cn = 0.0;
+ _cmin = 1.0;
+ _direction = DIRECTION_CCW;
+
+ int i;
+ for (i = 0; i < 4; i++)
+ _pinInverted[i] = 0;
+ // Some reasonable default
+ setAcceleration(1);
+}
+
+void AccelStepper::setMaxSpeed(float speed)
+{
+ if (_maxSpeed != speed) {
+ _maxSpeed = speed;
+ _cmin = 1000000.0 / speed;
+ // Recompute _n from current speed and adjust speed if accelerating or cruising
+ if (_n > 0) {
+ _n = (long)((_speed * _speed) / (2.0 * _acceleration)); // Equation 16
+ computeNewSpeed();
+ }
+ }
+}
+
+void AccelStepper::setAcceleration(float acceleration)
+{
+ if (acceleration == 0.0)
+ return;
+ if (_acceleration != acceleration) {
+ // Recompute _n per Equation 17
+ _n = _n * (_acceleration / acceleration);
+ // New c0 per Equation 7, with correction per Equation 15
+ _c0 = 0.676 * sqrt(2.0 / acceleration) * 1000000.0; // Equation 15
+ _acceleration = acceleration;
+ computeNewSpeed();
+ }
+}
+
+void AccelStepper::setSpeed(float speed)
+{
+ if (speed == _speed)
+ return;
+ speed = constrain(speed, -_maxSpeed, _maxSpeed);
+ if (speed == 0.0)
+ _stepInterval = 0;
+ else {
+ _stepInterval = fabs(1000000.0 / speed);
+ _direction = (speed > 0.0) ? DIRECTION_CW : DIRECTION_CCW;
+ }
+ _speed = speed;
+}
+
+float AccelStepper::speed()
+{
+ return _speed;
+}
+
+// Subclasses can override
+void AccelStepper::step(long step)
+{
+ switch (_interface) {
+ case FUNCTION:
+ step0(step);
+ break;
+
+ case DRIVER:
+ step1(step);
+ break;
+
+ case FULL2WIRE:
+ step2(step);
+ break;
+
+ case FULL3WIRE:
+ step3(step);
+ break;
+
+ case FULL4WIRE:
+ step4(step);
+ break;
+
+ case HALF3WIRE:
+ step6(step);
+ break;
+
+ case HALF4WIRE:
+ step8(step);
+ break;
+ }
+}
+
+// You might want to override this to implement eg serial output
+// bit 0 of the mask corresponds to _pin[0]
+// bit 1 of the mask corresponds to _pin[1]
+// ....
+void AccelStepper::setOutputPins(uint8_t mask)
+{
+// uint8_t numpins = 2;
+// if (_interface == FULL4WIRE || _interface == HALF4WIRE)
+// numpins = 4;
+// else if (_interface == FULL3WIRE || _interface == HALF3WIRE)
+// numpins = 3;
+// uint8_t i;
+// for (i = 0; i < numpins; i++)
+// digitalWrite(_pin[i], (mask & (1 << i)) ? (HIGH ^ _pinInverted[i]) : (LOW ^ _pinInverted[i]));
+ *_pin0 = (mask & (1 << 0)) ? (HIGH ^ _pinInverted[0]) : (LOW ^ _pinInverted[0]);
+ *_pin1 = (mask & (1 << 1)) ? (HIGH ^ _pinInverted[1]) : (LOW ^ _pinInverted[1]);
+ if (_interface == FULL4WIRE || _interface == HALF4WIRE) {
+ *_pin2 = (mask & (1 << 2)) ? (HIGH ^ _pinInverted[2]) : (LOW ^ _pinInverted[2]);
+ *_pin3 = (mask & (1 << 3)) ? (HIGH ^ _pinInverted[3]) : (LOW ^ _pinInverted[3]);
+ } else if (_interface == FULL3WIRE || _interface == HALF3WIRE)
+ *_pin2 = (mask & (1 << 2)) ? (HIGH ^ _pinInverted[2]) : (LOW ^ _pinInverted[2]);
+}
+
+// 0 pin step function (ie for functional usage)
+void AccelStepper::step0(long step)
+{
+ if (_speed > 0)
+ _forward();
+ else
+ _backward();
+}
+
+// 1 pin step function (ie for stepper drivers)
+// This is passed the current step number (0 to 7)
+// Subclasses can override
+void AccelStepper::step1(long step)
+{
+ // _pin[0] is step, _pin[1] is direction
+ setOutputPins(_direction ? 0b10 : 0b00); // Set direction first else get rogue pulses
+ setOutputPins(_direction ? 0b11 : 0b01); // step HIGH
+ // Caution 200ns setup time
+ // Delay the minimum allowed pulse width
+ //delayMicroseconds(_minPulseWidth);
+ wait_us(_minPulseWidth);
+ setOutputPins(_direction ? 0b10 : 0b00); // step LOW
+
+}
+
+
+// 2 pin step function
+// This is passed the current step number (0 to 7)
+// Subclasses can override
+void AccelStepper::step2(long step)
+{
+ switch (step & 0x3) {
+ case 0: /* 01 */
+ setOutputPins(0b10);
+ break;
+
+ case 1: /* 11 */
+ setOutputPins(0b11);
+ break;
+
+ case 2: /* 10 */
+ setOutputPins(0b01);
+ break;
+
+ case 3: /* 00 */
+ setOutputPins(0b00);
+ break;
+ }
+}
+// 3 pin step function
+// This is passed the current step number (0 to 7)
+// Subclasses can override
+void AccelStepper::step3(long step)
+{
+ switch (step % 3) {
+ case 0: // 100
+ setOutputPins(0b100);
+ break;
+
+ case 1: // 001
+ setOutputPins(0b001);
+ break;
+
+ case 2: //010
+ setOutputPins(0b010);
+ break;
+
+ }
+}
+
+// 4 pin step function for half stepper
+// This is passed the current step number (0 to 7)
+// Subclasses can override
+void AccelStepper::step4(long step)
+{
+ switch (step & 0x3) {
+ case 0: // 1010
+ setOutputPins(0b0101);
+ break;
+
+ case 1: // 0110
+ setOutputPins(0b0110);
+ break;
+
+ case 2: //0101
+ setOutputPins(0b1010);
+ break;
+
+ case 3: //1001
+ setOutputPins(0b1001);
+ break;
+ }
+}
+
+// 3 pin half step function
+// This is passed the current step number (0 to 7)
+// Subclasses can override
+void AccelStepper::step6(long step)
+{
+ switch (step % 6) {
+ case 0: // 100
+ setOutputPins(0b100);
+ break;
+
+ case 1: // 101
+ setOutputPins(0b101);
+ break;
+
+ case 2: // 001
+ setOutputPins(0b001);
+ break;
+
+ case 3: // 011
+ setOutputPins(0b011);
+ break;
+
+ case 4: // 010
+ setOutputPins(0b010);
+ break;
+
+ case 5: // 011
+ setOutputPins(0b110);
+ break;
+
+ }
+}
+
+// 4 pin half step function
+// This is passed the current step number (0 to 7)
+// Subclasses can override
+void AccelStepper::step8(long step)
+{
+ switch (step & 0x7) {
+ case 0: // 1000
+ setOutputPins(0b0001);
+ break;
+
+ case 1: // 1010
+ setOutputPins(0b0101);
+ break;
+
+ case 2: // 0010
+ setOutputPins(0b0100);
+ break;
+
+ case 3: // 0110
+ setOutputPins(0b0110);
+ break;
+
+ case 4: // 0100
+ setOutputPins(0b0010);
+ break;
+
+ case 5: //0101
+ setOutputPins(0b1010);
+ break;
+
+ case 6: // 0001
+ setOutputPins(0b1000);
+ break;
+
+ case 7: //1001
+ setOutputPins(0b1001);
+ break;
+ }
+}
+
+// Prevents power consumption on the outputs
+void AccelStepper::disableOutputs()
+{
+ if (! _interface) return;
+
+ setOutputPins(0); // Handles inversion automatically
+ // if (_enablePin != 0xff)
+ if (_enablePin)
+ // digitalWrite(_enablePin, LOW ^ _enableInverted);
+ *_enablePin = LOW ^ _enableInverted;
+}
+
+void AccelStepper::enableOutputs()
+{
+ if (! _interface)
+ return;
+
+ //pinMode(_pin[0], OUTPUT);
+ //pinMode(_pin[1], OUTPUT);
+ if (_interface == FULL4WIRE || _interface == HALF4WIRE) {
+ //pinMode(_pin[2], OUTPUT);
+ //pinMode(_pin[3], OUTPUT);
+ } else if (_interface == FULL3WIRE || _interface == HALF3WIRE) {
+ //pinMode(_pin[2], OUTPUT);
+ }
+
+ // if (_enablePin != 0xff)
+ if (_enablePin) {
+ //pinMode(_enablePin, OUTPUT);
+ //digitalWrite(_enablePin, HIGH ^ _enableInverted);
+ *_enablePin = HIGH ^ _enableInverted;
+ }
+}
+
+void AccelStepper::setMinPulseWidth(unsigned int minWidth)
+{
+ _minPulseWidth = minWidth;
+}
+
+// void AccelStepper::setEnablePin(uint8_t enablePin)
+void AccelStepper::setEnablePin(PinName enablePin)
+{
+ // _enablePin = enablePin;
+ _enablePin = new DigitalOut(enablePin);
+
+ // This happens after construction, so init pin now.
+ // if (_enablePin != 0xff)
+ if (*_enablePin) {
+ //pinMode(_enablePin, OUTPUT);
+ //digitalWrite(_enablePin, HIGH ^ _enableInverted);
+ *_enablePin = HIGH ^ _enableInverted;
+ }
+}
+
+void AccelStepper::setPinsInverted(bool directionInvert, bool stepInvert, bool enableInvert)
+{
+ _pinInverted[0] = stepInvert;
+ _pinInverted[1] = directionInvert;
+ _enableInverted = enableInvert;
+}
+
+void AccelStepper::setPinsInverted(bool pin1Invert, bool pin2Invert, bool pin3Invert, bool pin4Invert, bool enableInvert)
+{
+ _pinInverted[0] = pin1Invert;
+ _pinInverted[1] = pin2Invert;
+ _pinInverted[2] = pin3Invert;
+ _pinInverted[3] = pin4Invert;
+ _enableInverted = enableInvert;
+}
+
+// Blocks until the target position is reached and stopped
+void AccelStepper::runToPosition()
+{
+ while (run())
+ ;
+}
+
+bool AccelStepper::runSpeedToPosition()
+{
+ if (_targetPos == _currentPos)
+ return false;
+ if (_targetPos >_currentPos)
+ _direction = DIRECTION_CW;
+ else
+ _direction = DIRECTION_CCW;
+ return runSpeed();
+}
+
+// Blocks until the new target position is reached
+void AccelStepper::runToNewPosition(long position)
+{
+ moveTo(position);
+ runToPosition();
+}
+
+void AccelStepper::stop()
+{
+ if (_speed != 0.0) {
+ long stepsToStop = (long)((_speed * _speed) / (2.0 * _acceleration)) + 1; // Equation 16 (+integer rounding)
+ if (_speed > 0)
+ move(stepsToStop);
+ else
+ move(-stepsToStop);
+ }
+}
\ No newline at end of file