Mister-Green/Repetier-Firmware 1.0.3/Repetier/motion.cpp

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/*
This file is part of Repetier-Firmware.
Repetier-Firmware is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
Repetier-Firmware is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with Repetier-Firmware. If not, see <http://www.gnu.org/licenses/>.
This firmware is a nearly complete rewrite of the sprinter firmware
by kliment (https://github.com/kliment/Sprinter)
which based on Tonokip RepRap firmware rewrite based off of Hydra-mmm firmware.
Functions in this file are used to communicate using ascii or repetier protocol.
*/
#include "Repetier.h"
// ================ Sanity checks ================
#ifndef STEP_DOUBLER_FREQUENCY
#error Please add new parameter STEP_DOUBLER_FREQUENCY to your configuration.
#else
#if STEP_DOUBLER_FREQUENCY < 7000 || STEP_DOUBLER_FREQUENCY > 20000
#if CPU_ARCH==ARCH_AVR
#error STEP_DOUBLER_FREQUENCY should be in range 10000-16000.
#endif
#endif
#endif
#ifdef EXTRUDER_SPEED
#error EXTRUDER_SPEED is not used any more. Values are now taken from extruder definition.
#endif
#ifdef ENDSTOPPULLUPS
#error ENDSTOPPULLUPS is now replaced by individual pullup configuration!
#endif
#ifdef EXT0_PID_PGAIN
#error The PID system has changed. Please use the new float number options!
#endif
// ####################################################################################
// # No configuration below this line - just some error checking #
// ####################################################################################
#ifdef SUPPORT_MAX6675
#if !defined SCK_PIN || !defined MOSI_PIN || !defined MISO_PIN
#error For MAX6675 support, you need to define SCK_PIN, MISO_PIN and MOSI_PIN in pins.h
#endif
#endif
#if X_STEP_PIN < 0 || Y_STEP_PIN < 0 || Z_STEP_PIN < 0
#error One of the following pins is not assigned: X_STEP_PIN,Y_STEP_PIN,Z_STEP_PIN
#endif
#if EXT0_STEP_PIN < 0 && NUM_EXTRUDER > 0
#error EXT0_STEP_PIN not set to a pin number.
#endif
#if EXT0_DIR_PIN < 0 && NUM_EXTRUDER > 0
#error EXT0_DIR_PIN not set to a pin number.
#endif
#if PRINTLINE_CACHE_SIZE < 4
#error PRINTLINE_CACHE_SIZE must be at least 5
#endif
//Inactivity shutdown variables
millis_t previousMillisCmd = 0;
millis_t maxInactiveTime = MAX_INACTIVE_TIME * 1000L;
millis_t stepperInactiveTime = STEPPER_INACTIVE_TIME * 1000L;
long baudrate = BAUDRATE; ///< Communication speed rate.
#if USE_ADVANCE
#if ENABLE_QUADRATIC_ADVANCE
int maxadv = 0;
#endif
int maxadv2 = 0;
float maxadvspeed = 0;
#endif
uint8_t pwm_pos[NUM_PWM]; // 0-NUM_EXTRUDER = Heater 0-NUM_EXTRUDER of extruder, NUM_EXTRUDER = Heated bed, NUM_EXTRUDER+1 Board fan, NUM_EXTRUDER+2 = Fan
volatile int waitRelax = 0; // Delay filament relax at the end of print, could be a simple timeout
PrintLine PrintLine::lines[PRINTLINE_CACHE_SIZE]; ///< Cache for print moves.
PrintLine *PrintLine::cur = NULL; ///< Current printing line
#if CPU_ARCH == ARCH_ARM
volatile bool PrintLine::nlFlag = false;
#endif
ufast8_t PrintLine::linesWritePos = 0; ///< Position where we write the next cached line move.
volatile ufast8_t PrintLine::linesCount = 0; ///< Number of lines cached 0 = nothing to do.
ufast8_t PrintLine::linesPos = 0; ///< Position for executing line movement.
/**
Move printer the given number of steps. Puts the move into the queue. Used by e.g. homing commands.
Does not consider rotation but updates position correctly considering rotation. This can be used to
correct positions when changing tools.
\param x Distance in x direction in steps
\param y Distance in y direction in steps
\param z Distance in z direction in steps
\param e Distance in e direction in steps
\param feedrate Feed rate to be used in mm/s. Gets new active feedrate.
\param waitEnd If true will block until move is finished.
\param checkEndstop True if triggering endstop should stop move.
\param pathOptimize If false start and end speeds get fixed to minimum values.
*/
void PrintLine::moveRelativeDistanceInSteps(int32_t x, int32_t y, int32_t z, int32_t e, float feedrate, bool waitEnd, bool checkEndstop, bool pathOptimize) {
#if NUM_EXTRUDER > 0
if(Printer::debugDryrun() || (MIN_EXTRUDER_TEMP > 30 && Extruder::current->tempControl.currentTemperatureC < MIN_EXTRUDER_TEMP && !Printer::isColdExtrusionAllowed() && Extruder::current->tempControl.sensorType != 0))
e = 0; // should not be allowed for current temperature
#endif
#if MOVE_X_WHEN_HOMED == 1 || MOVE_Y_WHEN_HOMED == 1 || MOVE_Z_WHEN_HOMED == 1
if(!Printer::isHoming() && !Printer::isNoDestinationCheck()) {
#if MOVE_X_WHEN_HOMED
if(!Printer::isXHomed())
x = 0;
#endif
#if MOVE_Y_WHEN_HOMED
if(!Printer::isYHomed())
y = 0;
#endif
#if MOVE_Z_WHEN_HOMED
if(!Printer::isZHomed() && !Printer::isZProbingActive())
z = 0;
#endif
}
#endif // MOVE_X_WHEN_HOMED == 1 || MOVE_Y_WHEN_HOMED == 1 || MOVE_Z_WHEN_HOMED == 1
float savedFeedrate = Printer::feedrate;
Printer::destinationSteps[X_AXIS] = Printer::currentPositionSteps[X_AXIS] + x;
Printer::destinationSteps[Y_AXIS] = Printer::currentPositionSteps[Y_AXIS] + y;
Printer::destinationSteps[Z_AXIS] = Printer::currentPositionSteps[Z_AXIS] + z;
Printer::destinationSteps[E_AXIS] = Printer::currentPositionSteps[E_AXIS] + e;
Printer::feedrate = feedrate;
#if NONLINEAR_SYSTEM
if (!queueNonlinearMove(checkEndstop, pathOptimize, false)) {
Com::printWarningFLN(PSTR("moveRelativeDistanceInSteps / queueDeltaMove returns error"));
}
#else
#if DISTORTION_CORRECTION
Printer::destinationSteps[Z_AXIS] -= Printer::zCorrectionStepsIncluded; // correct as it will be added later in Cartesian move computation
#endif
queueCartesianMove(checkEndstop, pathOptimize);
#endif
Printer::feedrate = savedFeedrate;
Printer::updateCurrentPosition(false);
if(waitEnd)
Commands::waitUntilEndOfAllMoves();
previousMillisCmd = HAL::timeInMilliseconds();
}
/** Adds the steps converted to mm to the lastCmdPos position and moves to that position using Printer::moveToReal.
Will use Printer::isPositionAllowed to prevent illegal moves.
\param x Distance in x direction in steps
\param y Distance in y direction in steps
\param z Distance in z direction in steps
\param e Distance in e direction in steps
\param feedrate Feed rate to be used in mm/s. Gets new active feedrate.
\param waitEnd If true will block until move is finished.
\param pathOptimize If false start and end speeds get fixed to minimum values.
*/
void PrintLine::moveRelativeDistanceInStepsReal(int32_t x, int32_t y, int32_t z, int32_t e, float feedrate, bool waitEnd, bool pathOptimize) {
#if MOVE_X_WHEN_HOMED == 1 || MOVE_Y_WHEN_HOMED == 1 || MOVE_Z_WHEN_HOMED == 1
if(!Printer::isHoming() && !Printer::isNoDestinationCheck()) { // prevent movements when not homed
#if MOVE_X_WHEN_HOMED
if(!Printer::isXHomed())
x = 0;
#endif
#if MOVE_Y_WHEN_HOMED
if(!Printer::isYHomed())
y = 0;
#endif
#if MOVE_Z_WHEN_HOMED
if(!Printer::isZHomed() && !Printer::isZProbingActive())
z = 0;
#endif
}
#endif // MOVE_X_WHEN_HOMED == 1 || MOVE_Y_WHEN_HOMED == 1 || MOVE_Z_WHEN_HOMED == 1
Printer::lastCmdPos[X_AXIS] += x * Printer::invAxisStepsPerMM[X_AXIS];
Printer::lastCmdPos[Y_AXIS] += y * Printer::invAxisStepsPerMM[Y_AXIS];
Printer::lastCmdPos[Z_AXIS] += z * Printer::invAxisStepsPerMM[Z_AXIS];
#if LAZY_DUAL_X_AXIS
Printer::sledParked = false;
#endif
if(!Printer::isPositionAllowed( Printer::lastCmdPos[X_AXIS], Printer::lastCmdPos[Y_AXIS], Printer::lastCmdPos[Z_AXIS])) {
return; // ignore move
}
#if NUM_EXTRUDER > 0
if(Printer::debugDryrun() || (MIN_EXTRUDER_TEMP > 30 && Extruder::current->tempControl.currentTemperatureC < MIN_EXTRUDER_TEMP && !Printer::isColdExtrusionAllowed() && Extruder::current->tempControl.sensorType != 0))
e = 0; // should not be allowed for current temperature
#endif
Printer::moveToReal(Printer::lastCmdPos[X_AXIS], Printer::lastCmdPos[Y_AXIS], Printer::lastCmdPos[Z_AXIS],
(Printer::currentPositionSteps[E_AXIS] + e) * Printer::invAxisStepsPerMM[E_AXIS], feedrate, pathOptimize);
Printer::updateCurrentPosition();
if(waitEnd)
Commands::waitUntilEndOfAllMoves();
previousMillisCmd = HAL::timeInMilliseconds();
}
#if !NONLINEAR_SYSTEM
#if DISTORTION_CORRECTION
/* Special version which adds distortion correction to z. Gets called from queueCartesianMove if needed. */
void PrintLine::queueCartesianSegmentTo(uint8_t check_endstops, uint8_t pathOptimize) {
// Correct the bumps
Printer::zCorrectionStepsIncluded = Printer::distortion.correct(Printer::destinationSteps[X_AXIS], Printer::destinationSteps[Y_AXIS], Printer::destinationSteps[Z_AXIS]);
Printer::destinationSteps[Z_AXIS] += Printer::zCorrectionStepsIncluded;
#if DEBUG_DISTORTION
Com::printF(PSTR("zCorr:"), Printer::zCorrectionStepsIncluded * Printer::invAxisStepsPerMM[Z_AXIS], 3);
Com::printF(PSTR(" atX:"), Printer::destinationSteps[X_AXIS]*Printer::invAxisStepsPerMM[X_AXIS]);
Com::printFLN(PSTR(" atY:"), Printer::destinationSteps[Y_AXIS]*Printer::invAxisStepsPerMM[Y_AXIS]);
#endif
PrintLine::waitForXFreeLines(1);
uint8_t newPath = PrintLine::insertWaitMovesIfNeeded(pathOptimize, 0);
PrintLine *p = PrintLine::getNextWriteLine();
float axisDistanceMM[E_AXIS_ARRAY]; // Axis movement in mm
p->flags = (check_endstops ? FLAG_CHECK_ENDSTOPS : 0);
#if MIXING_EXTRUDER
if(Printer::isAllEMotors()) {
p->flags |= FLAG_ALL_E_MOTORS;
}
#endif
p->joinFlags = 0;
if(!pathOptimize) p->setEndSpeedFixed(true);
p->dir = 0;
//Find direction
//Printer::zCorrectionStepsIncluded = 0;
for(uint8_t axis = 0; axis < 4; axis++) {
p->delta[axis] = Printer::destinationSteps[axis] - Printer::currentPositionSteps[axis];
p->secondSpeed = Printer::fanSpeed;
if(axis == E_AXIS) {
if(Printer::mode == PRINTER_MODE_FFF) {
Printer::extrudeMultiplyError += (static_cast<float>(p->delta[E_AXIS]) * Printer::extrusionFactor);
p->delta[E_AXIS] = static_cast<int32_t>(Printer::extrudeMultiplyError);
Printer::extrudeMultiplyError -= p->delta[E_AXIS];
Printer::filamentPrinted += p->delta[E_AXIS] * Printer::invAxisStepsPerMM[axis];
}
#if defined(SUPPORT_LASER) && SUPPORT_LASER
else if(Printer::mode == PRINTER_MODE_LASER) {
p->secondSpeed = ((p->delta[X_AXIS] != 0 || p->delta[Y_AXIS] != 0) && (LaserDriver::laserOn || p->delta[E_AXIS] != 0) ? LaserDriver::intensity : 0);
p->delta[E_AXIS] = 0;
}
#endif
}
if(p->delta[axis] >= 0)
p->setPositiveDirectionForAxis(axis);
else
p->delta[axis] = -p->delta[axis];
axisDistanceMM[axis] = p->delta[axis] * Printer::invAxisStepsPerMM[axis];
if(p->delta[axis]) p->setMoveOfAxis(axis);
Printer::currentPositionSteps[axis] = Printer::destinationSteps[axis];
}
if(p->isNoMove()) {
if(newPath) // need to delete dummy elements, otherwise commands can get locked.
PrintLine::resetPathPlanner();
return; // No steps included
}
float xydist2;
#if ENABLE_BACKLASH_COMPENSATION
if((p->isXYZMove()) && ((p->dir & XYZ_DIRPOS) ^ (Printer::backlashDir & XYZ_DIRPOS)) & (Printer::backlashDir >> 3)) { // We need to compensate backlash, add a move
PrintLine::waitForXFreeLines(2);
uint8_t wpos2 = PrintLine::linesWritePos + 1;
if(wpos2 >= PRINTLINE_CACHE_SIZE) wpos2 = 0;
PrintLine *p2 = &PrintLine::lines[wpos2];
memcpy(p2, p, sizeof(PrintLine)); // Move current data to p2
uint8_t changed = (p->dir & XYZ_DIRPOS) ^ (Printer::backlashDir & XYZ_DIRPOS);
float back_diff[4]; // Axis movement in mm
back_diff[E_AXIS] = 0;
back_diff[X_AXIS] = (changed & 1 ? (p->isXPositiveMove() ? Printer::backlashX : -Printer::backlashX) : 0);
back_diff[Y_AXIS] = (changed & 2 ? (p->isYPositiveMove() ? Printer::backlashY : -Printer::backlashY) : 0);
back_diff[Z_AXIS] = (changed & 4 ? (p->isZPositiveMove() ? Printer::backlashZ : -Printer::backlashZ) : 0);
p->dir &= XYZ_DIRPOS; // x,y and z are already correct
for(uint8_t i = 0; i < 4; i++) {
float f = back_diff[i] * Printer::axisStepsPerMM[i];
p->delta[i] = abs((long)f);
if(p->delta[i]) p->dir |= XSTEP << i;
}
//Define variables that are needed for the Bresenham algorithm. Please note that Z is not currently included in the Bresenham algorithm.
if(p->delta[Y_AXIS] > p->delta[X_AXIS] && p->delta[Y_AXIS] > p->delta[Z_AXIS]) p->primaryAxis = Y_AXIS;
else if (p->delta[X_AXIS] > p->delta[Z_AXIS] ) p->primaryAxis = X_AXIS;
else p->primaryAxis = Z_AXIS;
p->stepsRemaining = p->delta[p->primaryAxis];
//Feedrate calc based on XYZ travel distance
xydist2 = back_diff[X_AXIS] * back_diff[X_AXIS] + back_diff[Y_AXIS] * back_diff[Y_AXIS];
if(p->isZMove())
p->distance = sqrt(xydist2 + back_diff[Z_AXIS] * back_diff[Z_AXIS]);
else
p->distance = sqrt(xydist2);
Printer::backlashDir = (Printer::backlashDir & 56) | (p2->dir & XYZ_DIRPOS);
p->calculateMove(back_diff, pathOptimize, p->primaryAxis);
p = p2; // use saved instance for the real move
}
#endif
//Define variables that are needed for the Bresenham algorithm. Please note that Z is not currently included in the Bresenham algorithm.
if(p->delta[Y_AXIS] > p->delta[X_AXIS] && p->delta[Y_AXIS] > p->delta[Z_AXIS] && p->delta[Y_AXIS] > p->delta[E_AXIS]) p->primaryAxis = Y_AXIS;
else if (p->delta[X_AXIS] > p->delta[Z_AXIS] && p->delta[X_AXIS] > p->delta[E_AXIS]) p->primaryAxis = X_AXIS;
else if (p->delta[Z_AXIS] > p->delta[E_AXIS]) p->primaryAxis = Z_AXIS;
else p->primaryAxis = E_AXIS;
p->stepsRemaining = p->delta[p->primaryAxis];
if(p->isXYZMove()) {
xydist2 = axisDistanceMM[X_AXIS] * axisDistanceMM[X_AXIS] + axisDistanceMM[Y_AXIS] * axisDistanceMM[Y_AXIS];
if(p->isZMove())
p->distance = RMath::max((float)sqrt(xydist2 + axisDistanceMM[Z_AXIS] * axisDistanceMM[Z_AXIS]), fabs(axisDistanceMM[E_AXIS]));
else
p->distance = RMath::max((float)sqrt(xydist2), fabs(axisDistanceMM[E_AXIS]));
} else
p->distance = fabs(axisDistanceMM[E_AXIS]);
p->calculateMove(axisDistanceMM, pathOptimize, p->primaryAxis);
}
#endif
/**
Put a move to the current destination coordinates into the movement cache.
If the cache is full, the method will wait, until a place gets free. During
wait communication and temperature control is enabled.
destinationSteps must be excluding any z correction! We will add that if required here.
@param check_endstops Read end stop during move.
*/
void PrintLine::queueCartesianMove(uint8_t check_endstops, uint8_t pathOptimize) {
ENSURE_POWER
#if LAZY_DUAL_X_AXIS
if(Printer::sledParked && (Printer::currentPositionSteps[X_AXIS] != Printer::destinationSteps[X_AXIS] ||
Printer::currentPositionSteps[Y_AXIS] != Printer::destinationSteps[Y_AXIS] ||
Printer::currentPositionSteps[Z_AXIS] != Printer::destinationSteps[Z_AXIS]))
Printer::sledParked = false;
#endif
Printer::constrainDestinationCoords();
Printer::unsetAllSteppersDisabled();
#if DISTORTION_CORRECTION
if(Printer::distortion.isEnabled() && Printer::destinationSteps[Z_AXIS] < Printer::distortion.zMaxSteps() && Printer::isZProbingActive() == false && !Printer::isHoming()) {
// we are inside correction height so we split all moves in lines of max. 10 mm and add them
// including a z correction
int32_t deltas[E_AXIS_ARRAY], start[E_AXIS_ARRAY];
for(fast8_t i = 0; i < E_AXIS_ARRAY; i++) {
deltas[i] = Printer::destinationSteps[i] - Printer::currentPositionSteps[i];
start[i] = Printer::currentPositionSteps[i];
}
deltas[Z_AXIS] += Printer::zCorrectionStepsIncluded;
start[Z_AXIS] -= Printer::zCorrectionStepsIncluded;
float dx = Printer::invAxisStepsPerMM[X_AXIS] * deltas[X_AXIS];
float dy = Printer::invAxisStepsPerMM[Y_AXIS] * deltas[Y_AXIS];
float len = dx * dx + dy * dy;
if(len < 100) { // no splitting required
queueCartesianSegmentTo(check_endstops, pathOptimize);
return;
}
// we need to split longer lines to follow bed curvature
len = sqrt(len);
int segments = (static_cast<int>(len) + 9) / 10;
#if DEBUG_DISTORTION
Com::printF(PSTR("Split line len:"), len);
Com::printFLN(PSTR(" segments:"), segments);
#endif
for(int i = 1; i <= segments; i++) {
for(fast8_t j = 0; j < E_AXIS_ARRAY; j++) {
Printer::destinationSteps[j] = start[j] + (i * deltas[j]) / segments;
}
queueCartesianSegmentTo(check_endstops, pathOptimize);
}
return;
}
#endif
waitForXFreeLines(1);
uint8_t newPath = insertWaitMovesIfNeeded(pathOptimize, 0);
PrintLine *p = getNextWriteLine();
float axisDistanceMM[E_AXIS_ARRAY]; // Axis movement in mm
p->flags = (check_endstops ? FLAG_CHECK_ENDSTOPS : 0);
#if MIXING_EXTRUDER
if(Printer::isAllEMotors()) {
p->flags |= FLAG_ALL_E_MOTORS;
}
#endif
p->joinFlags = 0;
if(!pathOptimize) p->setEndSpeedFixed(true);
p->dir = 0;
//Find direction
Printer::zCorrectionStepsIncluded = 0;
for(uint8_t axis = 0; axis < 4; axis++) {
p->delta[axis] = Printer::destinationSteps[axis] - Printer::currentPositionSteps[axis];
p->secondSpeed = Printer::fanSpeed;
if(axis == E_AXIS) {
if(Printer::mode == PRINTER_MODE_FFF) {
Printer::extrudeMultiplyError += (static_cast<float>(p->delta[E_AXIS]) * Printer::extrusionFactor);
p->delta[E_AXIS] = static_cast<int32_t>(Printer::extrudeMultiplyError);
Printer::extrudeMultiplyError -= p->delta[E_AXIS];
Printer::filamentPrinted += p->delta[E_AXIS] * Printer::invAxisStepsPerMM[axis];
}
#if defined(SUPPORT_LASER) && SUPPORT_LASER
else if(Printer::mode == PRINTER_MODE_LASER) {
p->secondSpeed = ((p->delta[X_AXIS] != 0 || p->delta[Y_AXIS] != 0) && (LaserDriver::laserOn || p->delta[E_AXIS] != 0) ? LaserDriver::intensity : 0);
p->delta[E_AXIS] = 0;
}
#endif
}
if(p->delta[axis] >= 0)
p->setPositiveDirectionForAxis(axis);
else
p->delta[axis] = -p->delta[axis];
axisDistanceMM[axis] = p->delta[axis] * Printer::invAxisStepsPerMM[axis];
if(p->delta[axis]) p->setMoveOfAxis(axis);
Printer::currentPositionSteps[axis] = Printer::destinationSteps[axis];
}
if(p->isNoMove()) {
if(newPath) // need to delete dummy elements, otherwise commands can get locked.
resetPathPlanner();
return; // No steps included
}
float xydist2;
#if ENABLE_BACKLASH_COMPENSATION
if((p->isXYZMove()) && ((p->dir & XYZ_DIRPOS) ^ (Printer::backlashDir & XYZ_DIRPOS)) & (Printer::backlashDir >> 3)) { // We need to compensate backlash, add a move
waitForXFreeLines(2);
uint8_t wpos2 = linesWritePos + 1;
if(wpos2 >= PRINTLINE_CACHE_SIZE) wpos2 = 0;
PrintLine *p2 = &lines[wpos2];
memcpy(p2, p, sizeof(PrintLine)); // Move current data to p2
uint8_t changed = (p->dir & XYZ_DIRPOS) ^ (Printer::backlashDir & XYZ_DIRPOS);
float back_diff[4]; // Axis movement in mm
back_diff[E_AXIS] = 0;
back_diff[X_AXIS] = (changed & 1 ? (p->isXPositiveMove() ? Printer::backlashX : -Printer::backlashX) : 0);
back_diff[Y_AXIS] = (changed & 2 ? (p->isYPositiveMove() ? Printer::backlashY : -Printer::backlashY) : 0);
back_diff[Z_AXIS] = (changed & 4 ? (p->isZPositiveMove() ? Printer::backlashZ : -Printer::backlashZ) : 0);
p->dir &= XYZ_DIRPOS; // x,y and z are already correct
for(uint8_t i = 0; i < 4; i++) {
float f = back_diff[i] * Printer::axisStepsPerMM[i];
p->delta[i] = abs((long)f);
if(p->delta[i]) p->dir |= XSTEP << i;
}
//Define variables that are needed for the Bresenham algorithm. Please note that Z is not currently included in the Bresenham algorithm.
if(p->delta[Y_AXIS] > p->delta[X_AXIS] && p->delta[Y_AXIS] > p->delta[Z_AXIS]) p->primaryAxis = Y_AXIS;
else if (p->delta[X_AXIS] > p->delta[Z_AXIS] ) p->primaryAxis = X_AXIS;
else p->primaryAxis = Z_AXIS;
p->stepsRemaining = p->delta[p->primaryAxis];
//Feedrate calc based on XYZ travel distance
xydist2 = back_diff[X_AXIS] * back_diff[X_AXIS] + back_diff[Y_AXIS] * back_diff[Y_AXIS];
if(p->isZMove())
p->distance = sqrt(xydist2 + back_diff[Z_AXIS] * back_diff[Z_AXIS]);
else
p->distance = sqrt(xydist2);
// 56 seems to be xstep|ystep|e_posdir which just seems odd
Printer::backlashDir = (Printer::backlashDir & 56) | (p2->dir & XYZ_DIRPOS);
p->calculateMove(back_diff, pathOptimize, p->primaryAxis);
p = p2; // use saved instance for the real move
}
#endif
//Define variables that are needed for the Bresenham algorithm. Please note that Z is not currently included in the Bresenham algorithm.
if(p->delta[Y_AXIS] > p->delta[X_AXIS] && p->delta[Y_AXIS] > p->delta[Z_AXIS] && p->delta[Y_AXIS] > p->delta[E_AXIS]) p->primaryAxis = Y_AXIS;
else if (p->delta[X_AXIS] > p->delta[Z_AXIS] && p->delta[X_AXIS] > p->delta[E_AXIS]) p->primaryAxis = X_AXIS;
else if (p->delta[Z_AXIS] > p->delta[E_AXIS]) p->primaryAxis = Z_AXIS;
else p->primaryAxis = E_AXIS;
p->stepsRemaining = p->delta[p->primaryAxis];
if(p->isXYZMove()) {
xydist2 = axisDistanceMM[X_AXIS] * axisDistanceMM[X_AXIS] + axisDistanceMM[Y_AXIS] * axisDistanceMM[Y_AXIS];
if(p->isZMove())
p->distance = RMath::max((float)sqrt(xydist2 + axisDistanceMM[Z_AXIS] * axisDistanceMM[Z_AXIS]), fabs(axisDistanceMM[E_AXIS]));
else
p->distance = RMath::max((float)sqrt(xydist2), fabs(axisDistanceMM[E_AXIS]));
} else
p->distance = fabs(axisDistanceMM[E_AXIS]);
p->calculateMove(axisDistanceMM, pathOptimize, p->primaryAxis);
}
#endif
void PrintLine::calculateMove(float axisDistanceMM[], uint8_t pathOptimize, fast8_t drivingAxis) {
#if NONLINEAR_SYSTEM
long axisInterval[VIRTUAL_AXIS_ARRAY]; // shortest interval possible for that axis
#else
long axisInterval[E_AXIS_ARRAY];
#endif
//float timeForMove = (float)(F_CPU)*distance / (isXOrYMove() ? RMath::max(Printer::minimumSpeed, Printer::feedrate) : Printer::feedrate); // time is in ticks
float timeForMove = (float)(F_CPU) * distance / Printer::feedrate; // time is in ticks
//bool critical = Printer::isZProbingActive();
if(linesCount < MOVE_CACHE_LOW && timeForMove < LOW_TICKS_PER_MOVE) { // Limit speed to keep cache full.
//Com::printF(PSTR("L:"),(int)linesCount);
//Com::printF(PSTR(" Old "),timeForMove);
timeForMove += (3 * (LOW_TICKS_PER_MOVE - timeForMove)) / (linesCount + 1); // Increase time if queue gets empty. Add more time if queue gets smaller.
//Com::printFLN(PSTR("Slow "),timeForMove);
//critical = true;
}
timeInTicks = timeForMove;
UI_MEDIUM; // do check encoder
// Compute the slowest allowed interval (ticks/step), so maximum feedrate is not violated
int32_t limitInterval0;
int32_t limitInterval = limitInterval0 = timeForMove / stepsRemaining; // until not violated by other constraints it is your target speed
float toTicks = static_cast<float>(F_CPU) / stepsRemaining;
if(isXMove()) {
axisInterval[X_AXIS] = axisDistanceMM[X_AXIS] * toTicks / (Printer::maxFeedrate[X_AXIS]); // mm*ticks/s/(mm/s*steps) = ticks/step
#if !NONLINEAR_SYSTEM || defined(FAST_COREXYZ)
limitInterval = RMath::max(axisInterval[X_AXIS], limitInterval);
#endif
} else axisInterval[X_AXIS] = 0;
if(isYMove()) {
axisInterval[Y_AXIS] = axisDistanceMM[Y_AXIS] * toTicks / Printer::maxFeedrate[Y_AXIS];
#if !NONLINEAR_SYSTEM || defined(FAST_COREXYZ)
limitInterval = RMath::max(axisInterval[Y_AXIS], limitInterval);
#endif
} else axisInterval[Y_AXIS] = 0;
if(isZMove()) { // normally no move in z direction
axisInterval[Z_AXIS] = axisDistanceMM[Z_AXIS] * toTicks / Printer::maxFeedrate[Z_AXIS]; // must prevent overflow!
#if !NONLINEAR_SYSTEM || defined(FAST_COREXYZ)
limitInterval = RMath::max(axisInterval[Z_AXIS], limitInterval);
#endif
} else axisInterval[Z_AXIS] = 0;
if(isEMove()) {
axisInterval[E_AXIS] = axisDistanceMM[E_AXIS] * toTicks / Printer::maxFeedrate[E_AXIS];
limitInterval = RMath::max(axisInterval[E_AXIS], limitInterval);
} else axisInterval[E_AXIS] = 0;
#if DRIVE_SYSTEM == DELTA
if(axisDistanceMM[VIRTUAL_AXIS] >= 0) {// only for deltas all speeds in all directions have same limit
axisInterval[VIRTUAL_AXIS] = axisDistanceMM[VIRTUAL_AXIS] * toTicks / (Printer::maxFeedrate[Z_AXIS]);
limitInterval = RMath::max(axisInterval[VIRTUAL_AXIS], limitInterval);
}
#endif
fullInterval = limitInterval = limitInterval > LIMIT_INTERVAL ? limitInterval : LIMIT_INTERVAL; // This is our target speed
if(limitInterval != limitInterval0) {
// new time at full speed = limitInterval*p->stepsRemaining [ticks]
timeForMove = (float)limitInterval * (float)stepsRemaining; // for large z-distance this overflows with long computation
}
float inverseTimeS = (float)F_CPU / timeForMove;
if(isXMove()) {
axisInterval[X_AXIS] = timeForMove / delta[X_AXIS];
speedX = axisDistanceMM[X_AXIS] * inverseTimeS;
if(isXNegativeMove()) speedX = -speedX;
} else speedX = 0;
if(isYMove()) {
axisInterval[Y_AXIS] = timeForMove / delta[Y_AXIS];
speedY = axisDistanceMM[Y_AXIS] * inverseTimeS;
if(isYNegativeMove()) speedY = -speedY;
} else speedY = 0;
if(isZMove()) {
axisInterval[Z_AXIS] = timeForMove / delta[Z_AXIS];
speedZ = axisDistanceMM[Z_AXIS] * inverseTimeS;
if(isZNegativeMove()) speedZ = -speedZ;
} else speedZ = 0;
if(isEMove()) {
axisInterval[E_AXIS] = timeForMove / delta[E_AXIS];
speedE = axisDistanceMM[E_AXIS] * inverseTimeS;
if(isENegativeMove()) speedE = -speedE;
} else speedE = 0;
#if NONLINEAR_SYSTEM
axisInterval[VIRTUAL_AXIS] = limitInterval; //timeForMove/stepsRemaining;
#endif
fullSpeed = distance * inverseTimeS;
//long interval = axis_interval[primary_axis]; // time for every step in ticks with full speed
//If acceleration is enabled, do some Bresenham calculations depending on which axis will lead it.
#if RAMP_ACCELERATION
// slowest time to accelerate from v0 to limitInterval determines used acceleration
// t = (v_end-v_start)/a
float slowestAxisPlateauTimeRepro = 1e15; // 1/time to reduce division Unit: 1/s
uint32_t *accel = (isEPositiveMove() ? Printer::maxPrintAccelerationStepsPerSquareSecond : Printer::maxTravelAccelerationStepsPerSquareSecond);
#if defined(INTERPOLATE_ACCELERATION_WITH_Z) && INTERPOLATE_ACCELERATION_WITH_Z != 0
uint32_t newAccel[4];
float accelFac = (100.0 + (EEPROM::accelarationFactorTop() - 100.0) * Printer::currentPosition[Z_AXIS] / Printer::zLength) * 0.01;
#if INTERPOLATE_ACCELERATION_WITH_Z == 1 || INTERPOLATE_ACCELERATION_WITH_Z == 3
newAccel[X_AXIS] = static_cast<int32_t>(accel[X_AXIS] * accelFac);
newAccel[Y_AXIS] = static_cast<int32_t>(accel[Y_AXIS] * accelFac);
#else
newAccel[X_AXIS] = accel[X_AXIS];
newAccel[Y_AXIS] = accel[Y_AXIS];
#endif
#if INTERPOLATE_ACCELERATION_WITH_Z == 2 || INTERPOLATE_ACCELERATION_WITH_Z == 3
newAccel[Z_AXIS] = static_cast<int32_t>(accel[Z_AXIS] * accelFac);
#else
newAccel[Z_AXIS] = accel[Z_AXIS];
#endif
newAccel[E_AXIS] = accel[E_AXIS];
accel = newAccel;
#endif // INTERPOLATE_ACCELERATION_WITH_Z
for(fast8_t i = 0; i < E_AXIS_ARRAY ; i++) {
if(isMoveOfAxis(i))
// v = a * t => t = v/a = F_CPU/(c*a) => 1/t = c*a/F_CPU
slowestAxisPlateauTimeRepro = RMath::min(slowestAxisPlateauTimeRepro, (float)axisInterval[i] * (float)accel[i]); // steps/s^2 * step/tick Ticks/s^2
}
// Errors for delta move are initialized in timer (except extruder)
#if !NONLINEAR_SYSTEM
error[X_AXIS] = error[Y_AXIS] = error[Z_AXIS] = error[E_AXIS] = delta[primaryAxis] >> 1;
#endif
#if NONLINEAR_SYSTEM
error[E_AXIS] = stepsRemaining >> 1;
#endif
invFullSpeed = 1.0 / fullSpeed;
accelerationPrim = slowestAxisPlateauTimeRepro / axisInterval[primaryAxis]; // a = v/t = F_CPU/(c*t): Steps/s^2
//Now we can calculate the new primary axis acceleration, so that the slowest axis max acceleration is not violated
fAcceleration = 262144.0 * (float)accelerationPrim / F_CPU; // will overflow without float!
accelerationDistance2 = 2.0 * distance * slowestAxisPlateauTimeRepro * fullSpeed / ((float)F_CPU); // mm^2/s^2
startSpeed = endSpeed = minSpeed = safeSpeed(drivingAxis);
if(startSpeed > Printer::feedrate)
startSpeed = endSpeed = minSpeed = Printer::feedrate;
// Can accelerate to full speed within the line
if (startSpeed * startSpeed + accelerationDistance2 >= fullSpeed * fullSpeed)
setNominalMove();
vMax = F_CPU / fullInterval; // maximum steps per second, we can reach
// if(p->vMax>46000) // gets overflow in N computation
// p->vMax = 46000;
//p->plateauN = (p->vMax*p->vMax/p->accelerationPrim)>>1;
#if USE_ADVANCE
if(!isXYZMove() || !isEPositiveMove()) {
#if ENABLE_QUADRATIC_ADVANCE
advanceRate = 0; // No head move or E move only or sucking filament back
advanceFull = 0;
#endif
advanceL = 0;
} else {
float advlin = fabs(speedE) * Extruder::current->advanceL * 0.001 * Printer::axisStepsPerMM[E_AXIS];
advanceL = (uint16_t)((65536L * advlin) / vMax); //advanceLscaled = (65536*vE*k2)/vMax
#if ENABLE_QUADRATIC_ADVANCE
advanceFull = 65536 * Extruder::current->advanceK * speedE * speedE; // Steps*65536 at full speed
long steps = (HAL::U16SquaredToU32(vMax)) / (accelerationPrim << 1); // v^2/(2*a) = steps needed to accelerate from 0-vMax
advanceRate = advanceFull / steps;
if((advanceFull >> 16) > maxadv) {
maxadv = (advanceFull >> 16);
maxadvspeed = fabs(speedE);
}
#endif
if(advlin > maxadv2) {
maxadv2 = advlin;
maxadvspeed = fabs(speedE);
}
}
#endif
UI_MEDIUM; // do check encoder
updateTrapezoids();
// how much steps on primary axis do we need to reach target feedrate
//p->plateauSteps = (long) (((float)p->acceleration *0.5f / slowest_axis_plateau_time_repro + p->vMin) *1.01f/slowest_axis_plateau_time_repro);
#else
#if USE_ADVANCE
#if ENABLE_QUADRATIC_ADVANCE
advanceRate = 0; // No advance for constant speeds
advanceFull = 0;
#endif
#endif
#endif
#ifdef DEBUG_STEPCOUNT
// Set in delta move calculation
#if !NONLINEAR_SYSTEM
totalStepsRemaining = delta[X_AXIS] + delta[Y_AXIS] + delta[Z_AXIS];
#endif
#endif
#ifdef DEBUG_QUEUE_MOVE
if(Printer::debugEcho()) {
logLine();
Com::printFLN(Com::tDBGLimitInterval, limitInterval);
Com::printFLN(Com::tDBGMoveDistance, distance);
Com::printFLN(Com::tDBGCommandedFeedrate, Printer::feedrate);
Com::printFLN(Com::tDBGConstFullSpeedMoveTime, timeForMove);
}
#endif
// Make result permanent
if (pathOptimize) waitRelax = 70;
pushLine();
DEBUG_MEMORY;
}
/**
This is the path planner.
It goes from the last entry and tries to increase the end speed of previous moves in a fashion that the maximum jerk
is never exceeded. If a segment with reached maximum speed is met, the planner stops. Everything left from this
is already optimal from previous updates.
The first 2 entries in the queue are not checked. The first is the one that is already in print and the following will likely to become active.
The method is called before lines_count is increased!
*/
void PrintLine::updateTrapezoids() {
ufast8_t first = linesWritePos;
PrintLine *firstLine;
PrintLine *act = &lines[linesWritePos];
InterruptProtectedBlock noInts;
// First we find out how far back we could go with optimization.
ufast8_t maxfirst = linesPos; // first non fixed segment we might change
if(maxfirst != linesWritePos)
nextPlannerIndex(maxfirst); // don't touch the line printing
// Now ignore enough segments to gain enough time for path planning
millis_t timeleft = 0;
// Skip as many stored moves as needed to gain enough time for computation
#if PRINTLINE_CACHE_SIZE < 10
#define minTime 4500L * PRINTLINE_CACHE_SIZE
#else
#define minTime 45000L
#endif
while(timeleft < minTime && maxfirst != linesWritePos) {
timeleft += lines[maxfirst].timeInTicks;
nextPlannerIndex(maxfirst);
}
// Search last fixed element
while(first != maxfirst && !lines[first].isEndSpeedFixed())
previousPlannerIndex(first);
if(first != linesWritePos && lines[first].isEndSpeedFixed())
nextPlannerIndex(first);
// now first points to last segment before the end speed is fixed
// so start speed is also fixed.
if(first == linesWritePos) { // Nothing to plan, only new element present
act->block(); // Prevent stepper interrupt from using this
noInts.unprotect();
act->setStartSpeedFixed(true);
act->updateStepsParameter();
act->unblock();
return;
}
// now we have at least one additional move for optimization
// that is not a wait move
// First is now the new element or the first element with non fixed end speed.
// anyhow, the start speed of first is fixed
firstLine = &lines[first];
firstLine->block(); // don't let printer touch this or following segments during update
noInts.unprotect();
ufast8_t previousIndex = linesWritePos;
previousPlannerIndex(previousIndex);
PrintLine *previous = &lines[previousIndex]; // segment before the one we are inserting
#if DRIVE_SYSTEM != DELTA
// filters z-move<->not z-move
/* if((previous->primaryAxis == Z_AXIS && act->primaryAxis != Z_AXIS) || (previous->primaryAxis != Z_AXIS && act->primaryAxis == Z_AXIS))
{
previous->setEndSpeedFixed(true);
act->setStartSpeedFixed(true);
act->updateStepsParameter();
firstLine->unblock();
return;
}*/
#endif // DRIVE_SYSTEM
if(previous->isEOnlyMove() != act->isEOnlyMove()) {
previous->maxJunctionSpeed = previous->endSpeed; // act->startSpeed; // maybe remove this. Previous should be at minimum and systems have nothing in common
previous->setEndSpeedFixed(true);
act->setStartSpeedFixed(true);
act->updateStepsParameter();
firstLine->unblock();
return;
} else {
computeMaxJunctionSpeed(previous, act); // Set maximum junction speed if we have a real move before
}
// Increase speed if possible neglecting current speed
backwardPlanner(linesWritePos, first);
// Reduce speed to reachable speeds
forwardPlanner(first);
#ifdef DEBUG_PLANNER
if(Printer::debugEcho()) {
Com::printF(PSTR("Planner: "), (int)linesCount);
previousPlannerIndex(first);
Com::printF(PSTR(" F "), lines[first].startSpeed, 1);
Com::printF(PSTR(" - "), lines[first].endSpeed, 1);
Com::printF(PSTR("("), lines[first].maxJunctionSpeed, 1);
Com::printF(PSTR(","), (int)lines[first].joinFlags);
nextPlannerIndex(first);
}
#endif
// Update precomputed data
do {
lines[first].updateStepsParameter();
#ifdef DEBUG_PLANNER
if(Printer::debugEcho()) {
Com::printF(PSTR(" / "), lines[first].startSpeed, 1);
Com::printF(PSTR(" - "), lines[first].endSpeed, 1);
Com::printF(PSTR("("), lines[first].maxJunctionSpeed, 1);
Com::printF(PSTR(","), (int)lines[first].joinFlags);
#ifdef DEBUG_QUEUE_MOVE
Com::println();
#endif
}
#endif
//noInts.protect();
lines[first].unblock(); // start with first block to release next used segment as early as possible
nextPlannerIndex(first);
lines[first].block();
//noInts.unprotect();
} while(first != linesWritePos);
act->updateStepsParameter();
act->unblock();
#ifdef DEBUG_PLANNER
if(Printer::debugEcho()) {
Com::printF(PSTR(" / "), lines[first].startSpeed, 1);
Com::printF(PSTR(" - "), lines[first].endSpeed, 1);
Com::printF(PSTR("("), lines[first].maxJunctionSpeed, 1);
Com::printFLN(PSTR(","), (int)lines[first].joinFlags);
}
#endif
}
/* Computes the maximum junction speed of the newly added segment under
optimal conditions. There is no guarantee that the previous move will be able to reach the
speed at all, but if it could exceed it will never exceed this theoretical limit.
if you define ALTERNATIVE_JERK the new jerk computations are used. These
use the cosine of the angle and the maximum speed
Jerk = (1-cos(alpha))*min(v1,v2)
This sets jerk to 0 on zero angle change.
Old New
0°: 0 0
30°: 51,8 13.4
45°: 76.53 29.3
90°: 141 100
180°: 200 200
Speed from 100 to 200
Old New(min) New(max)
0°: 100 0 0
30°: 123,9 13.4 26.8
45°: 147.3 29.3 58.6
90°: 223 100 200
180°: 300 200 400
*/
inline void PrintLine::computeMaxJunctionSpeed(PrintLine *previous, PrintLine *current) {
#if NONLINEAR_SYSTEM
/* if (previous->moveID == current->moveID) // Avoid computing junction speed for split nonlinear lines
{
if(previous->fullSpeed > current->fullSpeed)
previous->maxJunctionSpeed = current->fullSpeed;
else
previous->maxJunctionSpeed = previous->fullSpeed;
return;
}*/
#endif
#if USE_ADVANCE
if(Printer::isAdvanceActivated()) {
// if we start/stop extrusion we need to do so with lowest possible end speed
// or advance would leave a drolling extruder and can not adjust fast enough.
if(previous->isEMove() != current->isEMove()) {
previous->setEndSpeedFixed(true);
current->setStartSpeedFixed(true);
previous->endSpeed = current->startSpeed = previous->maxJunctionSpeed = RMath::min(previous->endSpeed, current->startSpeed);
previous->invalidateParameter();
current->invalidateParameter();
return;
}
}
#endif // USE_ADVANCE
// if we are here we have to identical move types
// either pure extrusion -> pure extrusion or
// move -> move (with or without extrusion)
// First we compute the normalized jerk for speed 1
float factor = 1.0;
float lengthFactor = 1.0;
#ifdef REDUCE_ON_SMALL_SEGMENTS
if(previous->distance < MAX_JERK_DISTANCE)
lengthFactor = static_cast<float>(MAX_JERK_DISTANCE * MAX_JERK_DISTANCE) / (previous->distance * previous->distance);
#endif
float maxJoinSpeed = RMath::min(current->fullSpeed, previous->fullSpeed);
#if (DRIVE_SYSTEM == DELTA) // No point computing Z Jerk separately for delta moves
#ifdef ALTERNATIVE_JERK
float jerk = maxJoinSpeed * lengthFactor * (1.0 - (current->speedX * previous->speedX + current->speedY * previous->speedY + current->speedZ * previous->speedZ) / (current->fullSpeed * previous->fullSpeed));
#else
float dx = current->speedX - previous->speedX;
float dy = current->speedY - previous->speedY;
float dz = current->speedZ - previous->speedZ;
float jerk = sqrt(dx * dx + dy * dy + dz * dz) * lengthFactor;
#endif // ALTERNATIVE_JERK
#else // DELTA
#ifdef ALTERNATIVE_JERK
float jerk = maxJoinSpeed * lengthFactor * (1.0 - (current->speedX * previous->speedX + current->speedY * previous->speedY + current->speedZ * previous->speedZ) / (current->fullSpeed * previous->fullSpeed));
#else
float dx = current->speedX - previous->speedX;
float dy = current->speedY - previous->speedY;
float jerk = sqrt(dx * dx + dy * dy) * lengthFactor;
#endif // ALTERNATIVE_JERK
#endif // DELTA
if(jerk > Printer::maxJerk) {
factor = Printer::maxJerk / jerk; // always < 1.0!
if(factor * maxJoinSpeed * 2.0 < Printer::maxJerk)
factor = Printer::maxJerk / (2.0 * maxJoinSpeed);
}
#if DRIVE_SYSTEM != DELTA
if((previous->dir | current->dir) & ZSTEP) {
float dz = fabs(current->speedZ - previous->speedZ);
if(dz > Printer::maxZJerk)
factor = RMath::min(factor, Printer::maxZJerk / dz);
}
#endif
float eJerk = fabs(current->speedE - previous->speedE);
if(eJerk > Extruder::current->maxStartFeedrate) {
factor = RMath::min(factor, Extruder::current->maxStartFeedrate / eJerk);
}
previous->maxJunctionSpeed = maxJoinSpeed * factor; // set speed limit
#ifdef DEBUG_QUEUE_MOVE
if(Printer::debugEcho()) {
Com::printF(PSTR("ID:"), (int)previous);
Com::printFLN(PSTR(" MJ:"), previous->maxJunctionSpeed);
}
#endif // DEBUG_QUEUE_MOVE
}
/** Update parameter used by updateTrapezoids
Computes the acceleration/deceleration steps and advanced parameter associated.
*/
void PrintLine::updateStepsParameter() {
if(areParameterUpToDate() || isWarmUp()) return;
float startFactor = startSpeed * invFullSpeed;
float endFactor = endSpeed * invFullSpeed;
vStart = vMax * startFactor; //starting speed
vEnd = vMax * endFactor;
#if CPU_ARCH == ARCH_AVR
uint32_t vmax2 = HAL::U16SquaredToU32(vMax);
accelSteps = ((vmax2 - HAL::U16SquaredToU32(vStart)) / (accelerationPrim << 1)) + 1; // Always add 1 for missing precision
decelSteps = ((vmax2 - HAL::U16SquaredToU32(vEnd)) / (accelerationPrim << 1)) + 1;
#else
uint64_t vmax2 = static_cast<uint64_t>(vMax) * static_cast<uint64_t>(vMax);
accelSteps = ((vmax2 - static_cast<uint64_t>(vStart) * static_cast<uint64_t>(vStart)) / (accelerationPrim << 1)) + 1; // Always add 1 for missing precision
decelSteps = ((vmax2 - static_cast<uint64_t>(vEnd) * static_cast<uint64_t>(vEnd)) / (accelerationPrim << 1)) + 1;
#endif
#if USE_ADVANCE
#if ENABLE_QUADRATIC_ADVANCE
advanceStart = (float)advanceFull * startFactor * startFactor;
advanceEnd = (float)advanceFull * endFactor * endFactor;
#endif
#endif
if(static_cast<int32_t>(accelSteps + decelSteps) >= stepsRemaining) { // can't reach limit speed
uint32_t red = (accelSteps + decelSteps - stepsRemaining) >> 1;
accelSteps = accelSteps - RMath::min(static_cast<int32_t>(accelSteps), static_cast<int32_t>(red));
decelSteps = decelSteps - RMath::min(static_cast<int32_t>(decelSteps), static_cast<int32_t>(red));
}
setParameterUpToDate();
#ifdef DEBUG_QUEUE_MOVE
if(Printer::debugEcho()) {
Com::printFLN(Com::tDBGId, (int)this);
Com::printF(Com::tDBGVStartEnd, (long)vStart);
Com::printFLN(Com::tSlash, (long)vEnd);
Com::printF(Com::tDBAccelSteps, (long)accelSteps);
Com::printF(Com::tSlash, (long)decelSteps);
Com::printFLN(Com::tSlash, (long)stepsRemaining);
Com::printF(Com::tDBGStartEndSpeed, startSpeed, 1);
Com::printFLN(Com::tSlash, endSpeed, 1);
Com::printFLN(Com::tDBGFlags, (uint32_t)flags);
Com::printFLN(Com::tDBGJoinFlags, (uint32_t)joinFlags);
}
#endif
}
/**
Compute the maximum speed from the last entered move.
The backwards planner traverses the moves from last to first looking at deceleration. The RHS of the accelerate/decelerate ramp.
start = last line inserted
last = last element until we check
*/
inline void PrintLine::backwardPlanner(ufast8_t start, ufast8_t last) {
PrintLine *act = &lines[start], *previous;
float lastJunctionSpeed = act->endSpeed; // Start always with safe speed
//PREVIOUS_PLANNER_INDEX(last); // Last element is already fixed in start speed
while(start != last) {
previousPlannerIndex(start);
previous = &lines[start];
previous->block();
// Avoid speed calculation once cruising in split delta move
#if NONLINEAR_SYSTEM
/*if (previous->moveID == act->moveID && lastJunctionSpeed == previous->maxJunctionSpeed)
{
act->startSpeed = RMath::max(act->minSpeed, previous->endSpeed = lastJunctionSpeed);
previous->invalidateParameter();
act->invalidateParameter();
}*/
#endif
/* if(prev->isEndSpeedFixed()) // Nothing to update from here on, happens when path optimize disabled
{
act->setStartSpeedFixed(true);
return;
}*/
// Avoid speed calculations if we know we can accelerate within the line
lastJunctionSpeed = (act->isNominalMove() ? act->fullSpeed : sqrt(lastJunctionSpeed * lastJunctionSpeed + act->accelerationDistance2)); // acceleration is acceleration*distance*2! What can be reached if we try?
// If that speed is more that the maximum junction speed allowed then ...
if(lastJunctionSpeed >= previous->maxJunctionSpeed) { // Limit is reached
// If the previous line's end speed has not been updated to maximum speed then do it now
if(previous->endSpeed != previous->maxJunctionSpeed) {
previous->invalidateParameter(); // Needs recomputation
previous->endSpeed = RMath::max(previous->minSpeed, previous->maxJunctionSpeed); // possibly unneeded???
}
// If actual line start speed has not been updated to maximum speed then do it now
if(act->startSpeed != previous->maxJunctionSpeed) {
act->startSpeed = RMath::max(act->minSpeed, previous->maxJunctionSpeed); // possibly unneeded???
act->invalidateParameter();
}
lastJunctionSpeed = previous->endSpeed;
} else {
// Block previous end and act start as calculated speed and recalculate plateau speeds (which could move the speed higher again)
act->startSpeed = RMath::max(act->minSpeed, lastJunctionSpeed);
lastJunctionSpeed = previous->endSpeed = RMath::max(lastJunctionSpeed, previous->minSpeed);
previous->invalidateParameter();
act->invalidateParameter();
}
act = previous;
} // while loop
}
void PrintLine::forwardPlanner(ufast8_t first) {
PrintLine *act;
PrintLine *next = &lines[first];
float vmaxRight;
float leftSpeed = next->startSpeed;
while(first != linesWritePos) { // All except last segment, which has fixed end speed
act = next;
nextPlannerIndex(first);
next = &lines[first];
/* if(act->isEndSpeedFixed())
{
leftSpeed = act->endSpeed;
continue; // Nothing to do here
}*/
// Avoid speed calculate once cruising in split delta move
#if NONLINEAR_SYSTEM
/* if (act->moveID == next->moveID && act->endSpeed == act->maxJunctionSpeed)
{
act->startSpeed = leftSpeed;
leftSpeed = act->endSpeed;
act->setEndSpeedFixed(true);
next->setStartSpeedFixed(true);
continue;
}*/
#endif
// Avoid speed calculates if we know we can accelerate within the line.
vmaxRight = (act->isNominalMove() ? act->fullSpeed : sqrt(leftSpeed * leftSpeed + act->accelerationDistance2));
if(vmaxRight > act->endSpeed) { // Could be higher next run?
if(leftSpeed < act->minSpeed) {
leftSpeed = act->minSpeed;
act->endSpeed = sqrt(leftSpeed * leftSpeed + act->accelerationDistance2);
}
act->startSpeed = leftSpeed;
next->startSpeed = leftSpeed = RMath::max(RMath::min(act->endSpeed, act->maxJunctionSpeed), next->minSpeed);
if(act->endSpeed == act->maxJunctionSpeed) { // Full speed reached, don't compute again!
act->setEndSpeedFixed(true);
next->setStartSpeedFixed(true);
}
act->invalidateParameter();
} else { // We can accelerate full speed without reaching limit, which is as fast as possible. Fix it!
act->fixStartAndEndSpeed();
act->invalidateParameter();
if(act->minSpeed > leftSpeed) {
leftSpeed = act->minSpeed;
vmaxRight = sqrt(leftSpeed * leftSpeed + act->accelerationDistance2);
}
act->startSpeed = leftSpeed;
act->endSpeed = RMath::max(act->minSpeed, vmaxRight);
next->startSpeed = leftSpeed = RMath::max(RMath::min(act->endSpeed, act->maxJunctionSpeed), next->minSpeed);
next->setStartSpeedFixed(true);
}
} // While
next->startSpeed = RMath::max(next->minSpeed, leftSpeed); // This is the new segment, which is updated anyway, no extra flag needed.
}
inline float PrintLine::safeSpeed(fast8_t drivingAxis) {
float xyMin = Printer::maxJerk * 0.5;
float mz = 0;
float safe(xyMin);
#if DRIVE_SYSTEM != DELTA
if(isZMove()) {
mz = Printer::maxZJerk * 0.5;
if(isXOrYMove()) {
if(fabs(speedZ) > mz)
safe = RMath::min(safe, mz * fullSpeed / fabs(speedZ));
} else {
safe = mz;
}
}
#endif
if(isEMove()) {
if(isXYZMove())
safe = RMath::min(safe, 0.5 * Extruder::current->maxStartFeedrate * fullSpeed / fabs(speedE));
else
safe = 0.5 * Extruder::current->maxStartFeedrate; // This is a retraction move
}
// Check for minimum speeds needed for numerical robustness
#if DRIVE_SYSTEM == DELTA
if(drivingAxis == X_AXIS || drivingAxis == Y_AXIS || drivingAxis == Z_AXIS) // enforce minimum speed for numerical stability of explicit speed integration
safe = RMath::max(xyMin, safe);
#else
if(drivingAxis == X_AXIS || drivingAxis == Y_AXIS) // enforce minimum speed for numerical stability of explicit speed integration
safe = RMath::max(xyMin, safe);
else if(drivingAxis == Z_AXIS)
{
safe = RMath::max(mz, safe);
}
#endif
return RMath::min(safe, fullSpeed);
}
/** Check if move is new. If it is insert some dummy moves to allow the path optimizer to work since it does
not act on the first two moves in the queue. The stepper timer will spot these moves and leave some time for
processing.
*/
uint8_t PrintLine::insertWaitMovesIfNeeded(uint8_t pathOptimize, uint8_t waitExtraLines) {
if(linesCount == 0 && waitRelax == 0 && pathOptimize) { // First line after some time - warm up needed
//return 0;
#if NONLINEAR_SYSTEM
uint8_t w = 3;
#else
uint8_t w = 4;
#endif
while(w--) {
PrintLine *p = getNextWriteLine();
p->flags = FLAG_WARMUP;
p->joinFlags = FLAG_JOIN_STEPPARAMS_COMPUTED | FLAG_JOIN_END_FIXED | FLAG_JOIN_START_FIXED;
p->dir = 0;
p->setWaitForXLinesFilled(w + waitExtraLines);
#if NONLINEAR_SYSTEM
p->setWaitTicks(300000);
p->moveID = lastMoveID++;
#else
p->setWaitTicks(100000);
#endif // NONLINEAR_SYSTEM
pushLine();
}
//Com::printFLN(PSTR("InsertWait"));
return 1;
}
return 0;
}
void PrintLine::LaserWarmUp( uint32_t wait) {
PrintLine *p = getNextWriteLine();
p->flags = FLAG_WARMUP;
p->joinFlags = FLAG_JOIN_STEPPARAMS_COMPUTED | FLAG_JOIN_END_FIXED | FLAG_JOIN_START_FIXED;
p->dir = 1;
p->setWaitForXLinesFilled(1);
p->setWaitTicks(long(wait * (F_CPU / 1000))); //in ms
pushLine();
Com::printFLN(PSTR("Laser Warmup"));
}
void PrintLine::logLine() {
#ifdef DEBUG_QUEUE_MOVE
Com::printFLN(Com::tDBGId, (int)this);
Com::printArrayFLN(Com::tDBGDelta, delta);
Com::printFLN(Com::tDBGDir, (uint32_t)dir);
Com::printFLN(Com::tDBGFlags, (uint32_t)flags);
Com::printFLN(Com::tDBGFullSpeed, fullSpeed);
Com::printFLN(Com::tDBGVMax, (int32_t)vMax);
Com::printFLN(Com::tDBGAcceleration, accelerationDistance2);
Com::printFLN(Com::tDBGAccelerationPrim, (int32_t)accelerationPrim);
Com::printFLN(Com::tDBGRemainingSteps, stepsRemaining);
#if USE_ADVANCE
#if ENABLE_QUADRATIC_ADVANCE
Com::printFLN(Com::tDBGAdvanceFull, advanceFull >> 16);
Com::printFLN(Com::tDBGAdvanceRate, advanceRate);
#endif
#endif
#endif // DEBUG_QUEUE_MOVE
}
void PrintLine::waitForXFreeLines(uint8_t b, bool allowMoves) {
while(getLinesCount() + b > PRINTLINE_CACHE_SIZE) { // wait for a free entry in movement cache
//GCode::readFromSerial();
Commands::checkForPeriodicalActions(allowMoves);
}
}
#ifdef FAST_COREXYZ
uint8_t transformCartesianStepsToDeltaSteps(int32_t cartesianPosSteps[], int32_t corePosSteps[]) {
#if DRIVE_SYSTEM == XY_GANTRY
//1 = z axis + xy H-gantry (x_motor = x+y, y_motor = x-y)
corePosSteps[A_TOWER] = cartesianPosSteps[X_AXIS] + cartesianPosSteps[Y_AXIS];
corePosSteps[B_TOWER] = cartesianPosSteps[X_AXIS] - cartesianPosSteps[Y_AXIS];
corePosSteps[C_TOWER] = cartesianPosSteps[Z_AXIS];
#elif DRIVE_SYSTEM == YX_GANTRY
// 2 = z axis + xy H-gantry (x_motor = x+y, y_motor = y-x)
corePosSteps[A_TOWER] = cartesianPosSteps[X_AXIS] + cartesianPosSteps[Y_AXIS];
corePosSteps[B_TOWER] = cartesianPosSteps[Y_AXIS] - cartesianPosSteps[X_AXIS];
corePosSteps[C_TOWER] = cartesianPosSteps[Z_AXIS];
#elif DRIVE_SYSTEM == XZ_GANTRY
// 8 = y axis + xz H-gantry (x_motor = x+z, z_motor = x-z)
corePosSteps[A_TOWER] = cartesianPosSteps[X_AXIS] + cartesianPosSteps[Z_AXIS];
corePosSteps[C_TOWER] = cartesianPosSteps[X_AXIS] - cartesianPosSteps[Z_AXIS];
corePosSteps[B_TOWER] = cartesianPosSteps[Y_AXIS];
#elif DRIVE_SYSTEM == ZX_GANTRY
//9 = y axis + xz H-gantry (x_motor = x+z, z_motor = z-x)
corePosSteps[A_TOWER] = cartesianPosSteps[X_AXIS] + cartesianPosSteps[Z_AXIS];
corePosSteps[C_TOWER] = cartesianPosSteps[Z_AXIS] - cartesianPosSteps[X_AXIS];
corePosSteps[B_TOWER] = cartesianPosSteps[Y_AXIS];
#elif DRIVE_SYSTEM == GANTRY_FAKE
corePosSteps[A_TOWER] = cartesianPosSteps[X_AXIS];
corePosSteps[B_TOWER] = cartesianPosSteps[Y_AXIS];
corePosSteps[C_TOWER] = cartesianPosSteps[Z_AXIS];
#endif
return 1;
}
#endif
#if DRIVE_SYSTEM == DELTA
// pick one for verbose the other silent
#define RETURN_0(s) { Com::printErrorFLN(PSTR(s)); return 0; }
/*#define RETURN_0(s) { Com::print(s " "); SHOWS(temp); SHOWS(opt);\
SHOWS(cartesianPosSteps[Z_AXIS]);\
SHOWS(towerAMinSteps); ;\
SHOWS(deltaPosSteps[A_TOWER]); \
SHOWS(Printer::deltaAPosYSteps);\
SHOWS(cartesianPosSteps[Y_AXIS]); \
SHOW(Printer::deltaDiagonalStepsSquaredA.l); return 0; }
*/
/**
Calculate the delta tower position from a Cartesian position
@param cartesianPosSteps Array containing Cartesian coordinates.
@param deltaPosSteps Result array with tower coordinates.
@returns 1 if Cartesian coordinates have a valid delta tower position 0 if not.
*/
uint8_t transformCartesianStepsToDeltaSteps(int32_t cartesianPosSteps[], int32_t deltaPosSteps[]) {
int32_t zSteps = cartesianPosSteps[Z_AXIS];
#if DISTORTION_CORRECTION
static int cnt = 0;
static int32_t lastZSteps = 9999999;
static int32_t lastZCorrection = 0;
cnt++;
if(cnt >= DISTORTION_UPDATE_FREQUENCY || lastZSteps != zSteps) {
cnt = 0;
lastZSteps = zSteps;
lastZCorrection = Printer::distortion.correct(cartesianPosSteps[X_AXIS], cartesianPosSteps[Y_AXIS], cartesianPosSteps[Z_AXIS]);
}
zSteps += lastZCorrection;
#endif
if(Printer::isLargeMachine()) {
#ifdef SUPPORT_64_BIT_MATH
// 64 bit is better for precision, so we use that if available.
// A TOWER height
uint64_t temp = RMath::absLong(Printer::deltaAPosYSteps - cartesianPosSteps[Y_AXIS]);
uint64_t opt = Printer::deltaDiagonalStepsSquaredA.L;
temp *= temp;
if (opt < temp)
RETURN_0("Apos y square ");
opt -= temp;
temp = RMath::absLong(Printer::deltaAPosXSteps - cartesianPosSteps[X_AXIS]);
temp *= temp;
if (opt < temp)
RETURN_0("Apos x square ");
deltaPosSteps[A_TOWER] = HAL::integer64Sqrt(opt - temp) + zSteps;
if (deltaPosSteps[A_TOWER] < Printer::deltaFloorSafetyMarginSteps && !Printer::isZProbingActive())
RETURN_0("A hit floor");
// B TOWER height
temp = RMath::absLong(Printer::deltaBPosYSteps - cartesianPosSteps[Y_AXIS]);
opt = Printer::deltaDiagonalStepsSquaredB.L;
temp *= temp;
if (opt < temp)
RETURN_0("Bpos y square ");
opt -= temp;
temp = RMath::absLong(Printer::deltaBPosXSteps - cartesianPosSteps[X_AXIS]);
temp *= temp;
if (opt < temp)
RETURN_0("Bpos x square ");
deltaPosSteps[B_TOWER] = HAL::integer64Sqrt(opt - temp) + zSteps ;
if (deltaPosSteps[B_TOWER] < Printer::deltaFloorSafetyMarginSteps && !Printer::isZProbingActive())
RETURN_0("B hit floor");
// C TOWER height
temp = RMath::absLong(Printer::deltaCPosYSteps - cartesianPosSteps[Y_AXIS]);
opt = Printer::deltaDiagonalStepsSquaredC.L ;
temp = temp * temp;
if ( opt < temp )
RETURN_0("Cpos y square ");
opt -= temp;
temp = RMath::absLong(Printer::deltaCPosXSteps - cartesianPosSteps[X_AXIS]);
temp = temp * temp;
if ( opt < temp )
RETURN_0("Cpos x square ");
deltaPosSteps[C_TOWER] = HAL::integer64Sqrt(opt - temp) + zSteps;
if (deltaPosSteps[C_TOWER] < Printer::deltaFloorSafetyMarginSteps && !Printer::isZProbingActive())
RETURN_0("C hit floor");
#else
float temp = Printer::deltaAPosYSteps - cartesianPosSteps[Y_AXIS];
float opt = Printer::deltaDiagonalStepsSquaredA.f - temp * temp;
float temp2 = Printer::deltaAPosXSteps - cartesianPosSteps[X_AXIS];
if ((temp = opt - temp2 * temp2) >= 0)
deltaPosSteps[A_TOWER] = floor(0.5 + sqrt(temp)
+ zSteps);
else
return 0;
if (deltaPosSteps[A_TOWER] < Printer::deltaFloorSafetyMarginSteps && !Printer::isZProbingActive()) return 0;
temp = Printer::deltaBPosYSteps - cartesianPosSteps[Y_AXIS];
opt = Printer::deltaDiagonalStepsSquaredB.f - temp * temp;
temp2 = Printer::deltaBPosXSteps - cartesianPosSteps[X_AXIS];
if ((temp = opt - temp2 * temp2) >= 0)
deltaPosSteps[B_TOWER] = floor(0.5 + sqrt(temp)
+ zSteps);
else
return 0;
if (deltaPosSteps[B_TOWER] < Printer::deltaFloorSafetyMarginSteps && !Printer::isZProbingActive()) return 0;
temp = Printer::deltaCPosYSteps - cartesianPosSteps[Y_AXIS];
opt = Printer::deltaDiagonalStepsSquaredC.f - temp * temp;
temp2 = Printer::deltaCPosXSteps - cartesianPosSteps[X_AXIS];
if ((temp = opt - temp2 * temp2) >= 0)
deltaPosSteps[C_TOWER] = floor(0.5 + sqrt(temp)
+ zSteps);
else
return 0;
if (deltaPosSteps[C_TOWER] < Printer::deltaFloorSafetyMarginSteps && !Printer::isZProbingActive()) return 0;
return 1;
#endif
} else {
// As we are right on the edge of many printers arm lengths, this is rewritten to use unsigned long
// This allows 52% longer arms to be used without performance penalty
// the code is a bit longer, because we cannot use negative to test for invalid conditions
// Also, previous code did not check for overflow of squared result
// Overflow is also detected as a fault condition
const uint32_t LIMIT = 65534; // Largest squarable int without overflow;
// A TOWER height
uint32_t temp = RMath::absLong(Printer::deltaAPosYSteps - cartesianPosSteps[Y_AXIS]);
uint32_t opt = Printer::deltaDiagonalStepsSquaredA.l;
if (temp > LIMIT)
RETURN_0("Apos y steps ");
temp *= temp;
if (opt < temp)
RETURN_0("Apos y square ");
opt -= temp;
temp = RMath::absLong(Printer::deltaAPosXSteps - cartesianPosSteps[X_AXIS]);
if (temp > LIMIT)
RETURN_0("Apos x steps ");
temp *= temp;
if (opt < temp)
RETURN_0("Apos x square ");
deltaPosSteps[A_TOWER] = SQRT(opt - temp) + zSteps;
if (deltaPosSteps[A_TOWER] < Printer::deltaFloorSafetyMarginSteps && !Printer::isZProbingActive())
RETURN_0("A hit floor");
// B TOWER height
temp = RMath::absLong(Printer::deltaBPosYSteps - cartesianPosSteps[Y_AXIS]);
opt = Printer::deltaDiagonalStepsSquaredB.l;
if (temp > LIMIT)
RETURN_0("Bpos y steps ");
temp *= temp;
if (opt < temp)
RETURN_0("Bpos y square ");
opt -= temp;
temp = RMath::absLong(Printer::deltaBPosXSteps - cartesianPosSteps[X_AXIS]);
if (temp > LIMIT )
RETURN_0("Bpos x steps ");
temp *= temp;
if (opt < temp)
RETURN_0("Bpos x square ");
deltaPosSteps[B_TOWER] = SQRT(opt - temp) + zSteps ;
if (deltaPosSteps[B_TOWER] < Printer::deltaFloorSafetyMarginSteps && !Printer::isZProbingActive())
RETURN_0("B hit floor");
// C TOWER height
temp = RMath::absLong(Printer::deltaCPosYSteps - cartesianPosSteps[Y_AXIS]);
opt = Printer::deltaDiagonalStepsSquaredC.l ;
if (temp > LIMIT)
RETURN_0("Cpos y steps ");
temp = temp * temp;
if ( opt < temp )
RETURN_0("Cpos y square ");
opt -= temp;
temp = RMath::absLong(Printer::deltaCPosXSteps - cartesianPosSteps[X_AXIS]);
if (temp > LIMIT)
RETURN_0("Cpos x steps ");
temp = temp * temp;
if ( opt < temp )
RETURN_0("Cpos x square ");
deltaPosSteps[C_TOWER] = SQRT(opt - temp) + zSteps;
if (deltaPosSteps[C_TOWER] < Printer::deltaFloorSafetyMarginSteps && !Printer::isZProbingActive())
RETURN_0("C hit floor");
/*
long temp = Printer::deltaAPosYSteps - cartesianPosSteps[Y_AXIS];
long opt = Printer::deltaDiagonalStepsSquaredA.l - temp * temp;
long temp2 = Printer::deltaAPosXSteps - cartesianPosSteps[X_AXIS];
if ((temp = opt - temp2 * temp2) >= 0)
#ifdef FAST_INTEGER_SQRT
deltaPosSteps[A_TOWER] = HAL::integerSqrt(temp) + cartesianPosSteps[Z_AXIS];
#else
deltaPosSteps[A_TOWER] = sqrt(temp) + cartesianPosSteps[Z_AXIS];
#endif
else
return 0;
temp = Printer::deltaBPosYSteps - cartesianPosSteps[Y_AXIS];
opt = Printer::deltaDiagonalStepsSquaredB.l - temp * temp;
temp2 = Printer::deltaBPosXSteps - cartesianPosSteps[X_AXIS];
if ((temp = opt - temp2*temp2) >= 0)
#ifdef FAST_INTEGER_SQRT
deltaPosSteps[B_TOWER] = HAL::integerSqrt(temp) + cartesianPosSteps[Z_AXIS];
#else
deltaPosSteps[B_TOWER] = sqrt(temp) + cartesianPosSteps[Z_AXIS];
#endif
else
return 0;
temp = Printer::deltaCPosYSteps - cartesianPosSteps[Y_AXIS];
opt = Printer::deltaDiagonalStepsSquaredC.l - temp * temp;
temp2 = Printer::deltaCPosXSteps - cartesianPosSteps[X_AXIS];
if ((temp = opt - temp2*temp2) >= 0)
#ifdef FAST_INTEGER_SQRT
deltaPosSteps[C_TOWER] = HAL::integerSqrt(temp) + cartesianPosSteps[Z_AXIS];
#else
deltaPosSteps[C_TOWER] = sqrt(temp) + cartesianPosSteps[Z_AXIS];
#endif
else
return 0;*/
}
return 1;
}
#endif
#if DRIVE_SYSTEM==TUGA
/**
Calculate the delta tower position from a Cartesian position
@param cartesianPosSteps Array containing Cartesian coordinates.
@param deltaPosSteps Result array with tower coordinates.
@returns 1 if Cartesian coordinates have a valid delta tower position 0 if not.
X Y
* *
\ /
\ /
\ /
\/
/
/
/
/
* Extruder
*/
uint8_t transformCartesianStepsToDeltaSteps(int32_t cartesianPosSteps[], int32_t tugaPosSteps[]) {
tugaPosSteps[0] = cartesianPosSteps[0];
tugaPosSteps[2] = cartesianPosSteps[2];
int32_t y2 = Printer::deltaBPosXSteps - cartesianPosSteps[1];
if(Printer::isLargeMachine()) {
float y2f = (float)y2 * (float)y2;
float temp = Printer::deltaDiagonalStepsSquaredF - y2f;
if(temp < 0) return 0;
tugaPosSteps[1] = tugaPosSteps[0] + sqrt(temp);
} else {
y2 = y2 * y2;
int32_t temp = Printer::deltaDiagonalStepsSquared - y2;
if(temp < 0) return 0;
tugaPosSteps[1] = tugaPosSteps[0] + HAL::integerSqrt(temp);
}
return 1;
}
#endif
#if NONLINEAR_SYSTEM
bool NonlinearSegment::checkEndstops(PrintLine *cur, bool checkall) {
fast8_t r = 0;
if(Printer::isZProbingActive()) {
Endstops::update();
#if FEATURE_Z_PROBE
if(isZNegativeMove() && Endstops::zProbe()) {
#if DRIVE_SYSTEM == DELTA
cur->setXMoveFinished();
cur->setYMoveFinished();
#endif
cur->setZMoveFinished();
//dir = 0;
Printer::stepsRemainingAtZHit = cur->stepsRemaining;
cur->stepsRemaining = 0;
return true;
}
#endif
#if DRIVE_SYSTEM == DELTA
if(isZPositiveMove() && isXPositiveMove() && isYPositiveMove() && Endstops::anyXYZMax())
#else
if(isZPositiveMove() && Endstops::zMax())
#endif
{
#if DRIVE_SYSTEM == DELTA
cur->setXMoveFinished();
cur->setYMoveFinished();
#endif
cur->setZMoveFinished();
//dir = 0;
Printer::stepsRemainingAtZHit = cur->stepsRemaining;
return true;
}
} else if(checkall) {
Endstops::update(); // do not test twice
if(!Endstops::anyXYZ()) // very quick check for the normal case
return false;
}
if(checkall) {
#if GANTRY
// Test axis endstops based on global direction
if(cur->isXPositiveMove() && Endstops::xMax()) {
setXMoveFinished();
cur->setXMoveFinished();
r = 1;
}
if(cur->isYPositiveMove() && Endstops::yMax()) {
setYMoveFinished();
cur->setYMoveFinished();
r = 1;
}
if(cur->isXNegativeMove() && Endstops::xMin()) {
setXMoveFinished();
cur->setXMoveFinished();
r = 1;
}
if(cur->isYNegativeMove() && Endstops::yMin()) {
setYMoveFinished();
cur->setYMoveFinished();
r = 1;
}
#if MULTI_ZENDSTOP_HOMING
{
if(Printer::isHoming()) {
if(isZNegativeMove()) {
if(Endstops::zMin())
Printer::multiZHomeFlags &= ~1;
if(Endstops::z2MinMax())
Printer::multiZHomeFlags &= ~2;
if(Printer::multiZHomeFlags == 0)
setZMoveFinished();
} else if(isZPositiveMove()) {
if(Endstops::zMax())
Printer::multiZHomeFlags &= ~1;
if(Endstops::z2MinMax())
Printer::multiZHomeFlags &= ~2;
if(Printer::multiZHomeFlags == 0) {
setZMoveFinished();
cur->setZMoveFinished();
r = 1;
}
}
} else {
#if !(Z_MIN_PIN == Z_PROBE_PIN && FEATURE_Z_PROBE)
if(isZNegativeMove() && Endstops::zMin()) {
setZMoveFinished();
cur->setZMoveFinished();
r = 1;
} else
#endif
if(isZPositiveMove() && Endstops::zMax()) {
setZMoveFinished();
cur->setZMoveFinished();
r = 1;
}
}
}
#else
if(cur->isZPositiveMove() && Endstops::zMax()) {
setZMoveFinished();
cur->setZMoveFinished();
r = 1;
}
if(cur->isZNegativeMove() && Endstops::zMin()
#if Z_MIN_PIN == Z_PROBE_PIN && FEATURE_Z_PROBE
&& Printer::isHoming()
#endif
) {
setZMoveFinished();
cur->setZMoveFinished();
r = 1;
}
#endif
#else
// endstops are per motor and do not depend on global axis movement
if(isXPositiveMove() && Endstops::xMax()) {
#if DRIVE_SYSTEM == DELTA
if(Printer::stepsRemainingAtXHit < 0)
Printer::stepsRemainingAtXHit = cur->stepsRemaining;
#endif
setXMoveFinished();
cur->setXMoveFinished();
r++;
}
if(isYPositiveMove() && Endstops::yMax()) {
#if DRIVE_SYSTEM == DELTA
if(Printer::stepsRemainingAtYHit < 0)
Printer::stepsRemainingAtYHit = cur->stepsRemaining;
#endif
setYMoveFinished();
cur->setYMoveFinished();
r++;
}
#if DRIVE_SYSTEM != DELTA
if(isXNegativeMove() && Endstops::xMin()) {
setXMoveFinished();
cur->setXMoveFinished();
r++;
}
if(isYNegativeMove() && Endstops::yMin()) {
setYMoveFinished();
cur->setYMoveFinished();
r++;
}
#endif
if(isZPositiveMove() && Endstops::zMax()) {
#if MAX_HARDWARE_ENDSTOP_Z
if(Printer::stepsRemainingAtZHit)
Printer::stepsRemainingAtZHit = cur->stepsRemaining;
#endif
setZMoveFinished();
cur->setZMoveFinished();
r++;
}
if(isZNegativeMove() && Endstops::zMin()) {
setZMoveFinished();
cur->setZMoveFinished();
r++;
}
#if DRIVE_SYSTEM == DELTA
if(Printer::isHoming())
return r == 3;
#endif
#endif // Not gantry
}
return r != 0;
}
void PrintLine::calculateDirectionAndDelta(int32_t difference[], ufast8_t *dir, int32_t delta[]) {
*dir = 0;
//Find direction
if(difference[X_AXIS] != 0) {
if(difference[X_AXIS] < 0) {
delta[X_AXIS] = -difference[X_AXIS];
*dir |= XSTEP;
} else {
delta[X_AXIS] = difference[X_AXIS];
*dir |= X_DIRPOS + XSTEP;
}
} else {
delta[X_AXIS] = 0;
}
if(difference[Y_AXIS] != 0) {
if(difference[Y_AXIS] < 0) {
delta[Y_AXIS] = -difference[Y_AXIS];
*dir |= YSTEP;
} else {
delta[Y_AXIS] = difference[Y_AXIS];
*dir |= Y_DIRPOS + YSTEP;
}
} else {
delta[Y_AXIS] = 0;
}
if(difference[Z_AXIS] != 0) {
if(difference[Z_AXIS] < 0) {
delta[Z_AXIS] = -difference[Z_AXIS];
*dir |= ZSTEP;
} else {
delta[Z_AXIS] = difference[Z_AXIS];
*dir |= Z_DIRPOS + ZSTEP;
}
} else {
delta[Z_AXIS] = 0;
}
if(difference[E_AXIS] != 0) {
if(difference[E_AXIS] < 0) {
delta[E_AXIS] = -difference[E_AXIS];
*dir |= ESTEP;
} else {
delta[E_AXIS] = difference[E_AXIS];
*dir |= E_DIRPOS + ESTEP;
}
} else {
delta[E_AXIS] = 0;
}
}
/**
Calculate and cache the delta robot positions of the Cartesian move in a line.
@return The largest delta axis move in a single segment
@param p The line to examine.
*/
inline uint16_t PrintLine::calculateNonlinearSubSegments(uint8_t softEndstop) {
fast8_t i;
int32_t delta, diff;
int32_t destinationSteps[Z_AXIS_ARRAY], destinationDeltaSteps[TOWER_ARRAY];
// Save current position
#if (CPU_ARCH == ARCH_AVR) && !EXACT_DELTA_MOVES
for(uint8_t i = 0; i < Z_AXIS_ARRAY; i++)
destinationSteps[i] = Printer::currentPositionSteps[i];
#else
float dx[Z_AXIS_ARRAY];
for(int i = 0; i < Z_AXIS_ARRAY; i++)
dx[i] = static_cast<float>(Printer::destinationSteps[i] - Printer::currentPositionSteps[i]) / static_cast<float>(numNonlinearSegments);
#endif
// out.println_byte_P(PSTR("Calculate delta segments:"), p->numDeltaSegments);
#ifdef DEBUG_STEPCOUNT
totalStepsRemaining = 0;
#endif
uint16_t maxAxisSteps = 0;
for (int s = numNonlinearSegments; s > 0; s--) {
NonlinearSegment *d = &segments[s - 1];
#if (CPU_ARCH == ARCH_AVR) && !EXACT_DELTA_MOVES
for(i = 0; i < Z_AXIS_ARRAY; i++) {
// End of segment in Cartesian steps
// This method generates small waves which get larger with increasing number of delta segments. smaller?
diff = Printer::destinationSteps[i] - destinationSteps[i];
if(s == 1)
destinationSteps[i] += diff;
else if(s == 2)
destinationSteps[i] += (diff >> 1);
else if(s == 4)
destinationSteps[i] += (diff >> 2);
else if(diff < 0)
destinationSteps[i] -= HAL::Div4U2U(-diff, s);
else
destinationSteps[i] += HAL::Div4U2U(diff, s);
}
#else
float segment = static_cast<float>(numNonlinearSegments - s + 1);
for(i = 0; i < Z_AXIS_ARRAY; i++) // End of segment in Cartesian steps
// Perfect approximation, but slower, so we limit it to faster processors like arm
destinationSteps[i] = static_cast<int32_t>(floor(0.5 + dx[i] * segment)) + Printer::currentPositionSteps[i];
#endif
// Verify that delta calculation has a solution
if (transformCartesianStepsToDeltaSteps(destinationSteps, destinationDeltaSteps)) {
d->dir = 0;
#if DRIVE_SYSTEM == DELTA
if (softEndstop) {
destinationDeltaSteps[A_TOWER] = RMath::min(destinationDeltaSteps[A_TOWER], Printer::maxDeltaPositionSteps);
destinationDeltaSteps[B_TOWER] = RMath::min(destinationDeltaSteps[B_TOWER], Printer::maxDeltaPositionSteps);
destinationDeltaSteps[C_TOWER] = RMath::min(destinationDeltaSteps[C_TOWER], Printer::maxDeltaPositionSteps);
}
#endif
for(i = 0; i < TOWER_ARRAY; i++) {
delta = destinationDeltaSteps[i] - Printer::currentNonlinearPositionSteps[i];
if (delta > 0) {
d->setPositiveMoveOfAxis(i);
#ifdef DEBUG_DELTA_OVERFLOW
if (delta > 65535)
Com::printFLN(Com::tDBGDeltaOverflow, delta);
#endif
d->deltaSteps[i] = static_cast<uint16_t>(delta);
} else {
d->setMoveOfAxis(i);
#ifdef DEBUG_DELTA_OVERFLOW
if (-delta > 65535)
Com::printFLN(Com::tDBGDeltaOverflow, delta);
#endif
d->deltaSteps[i] = static_cast<uint16_t>(-delta);
}
#ifdef DEBUG_STEPCOUNT
totalStepsRemaining += d->deltaSteps[i];
#endif
if(d->deltaSteps[i] > maxAxisSteps)
maxAxisSteps = d->deltaSteps[i];
Printer::currentNonlinearPositionSteps[i] = destinationDeltaSteps[i];
}
} else {
// Illegal position - ignore move
Com::printWarningF(Com::tInvalidDeltaCoordinate);
Com::printF(PSTR(" x:"), destinationSteps[X_AXIS]);
Com::printF(PSTR(" y:"), destinationSteps[Y_AXIS]);
Com::printFLN(PSTR(" z:"), destinationSteps[Z_AXIS]);
d->dir = 0;
d->deltaSteps[A_TOWER] = d->deltaSteps[B_TOWER] = d->deltaSteps[C_TOWER] = 0;
return 65535; // flag error
}
}
#ifdef DEBUG_STEPCOUNT
// out.println_long_P(PSTR("initial StepsRemaining:"), p->totalStepsRemaining);
#endif
return maxAxisSteps;
}
uint8_t PrintLine::calculateDistance(float axisDistanceMM[], uint8_t dir, float *distance) {
// Calculate distance depending on direction
if(dir & XYZ_STEP) {
if(dir & XSTEP)
*distance = axisDistanceMM[X_AXIS] * axisDistanceMM[X_AXIS];
else
*distance = 0;
if(dir & YSTEP)
*distance += axisDistanceMM[Y_AXIS] * axisDistanceMM[Y_AXIS];
if(dir & ZSTEP)
*distance += axisDistanceMM[Z_AXIS] * axisDistanceMM[Z_AXIS];
*distance = RMath::max((float)sqrt(*distance), axisDistanceMM[E_AXIS]);
return 1;
} else {
if(dir & ESTEP) {
*distance = axisDistanceMM[E_AXIS];
return 1;
}
*distance = 0;
return 0;
}
}
#if SOFTWARE_LEVELING
void PrintLine::calculatePlane(int32_t factors[], int32_t p1[], int32_t p2[], int32_t p3[]) {
factors[0] = p1[1] * (p2[2] - p3[2]) + p2[1] * (p3[2] - p1[2]) + p3[1] * (p1[2] - p2[2]);
factors[1] = p1[2] * (p2[0] - p3[0]) + p2[2] * (p3[0] - p1[0]) + p3[2] * (p1[0] - p2[0]);
factors[2] = p1[0] * (p2[1] - p3[1]) + p2[0] * (p3[1] - p1[1]) + p3[0] * (p1[1] - p2[1]);
factors[3] = p1[0] * ((p2[1] * p3[2]) - (p3[1] * p2[2])) + p2[0] * ((p3[1] * p1[2]) - (p1[1] * p3[2])) + p3[0] * ((p1[1] * p2[2]) - (p2[1] * p1[2]));
}
float PrintLine::calcZOffset(int32_t factors[], int32_t pointX, int32_t pointY) {
return (factors[3] - factors[X_AXIS] * pointX - factors[Y_AXIS] * pointY) / (float) factors[2];
}
#endif
inline void PrintLine::queueEMove(int32_t extrudeDiff, uint8_t check_endstops, uint8_t pathOptimize) {
Printer::unsetAllSteppersDisabled();
waitForXFreeLines(1);
uint8_t newPath = insertWaitMovesIfNeeded(pathOptimize, 1);
PrintLine *p = getNextWriteLine();
float axisDistanceMM[VIRTUAL_AXIS_ARRAY]; // Axis movement in mm
if(check_endstops) p->flags = FLAG_CHECK_ENDSTOPS;
else p->flags = 0;
#if MIXING_EXTRUDER
if(Printer::isAllEMotors()) {
p->flags |= FLAG_ALL_E_MOTORS;
}
#endif
p->joinFlags = 0;
if(!pathOptimize) p->setEndSpeedFixed(true);
//Find direction
for(uint8_t i = 0; i < Z_AXIS_ARRAY; i++) {
p->delta[i] = 0;
axisDistanceMM[i] = 0;
}
if (extrudeDiff >= 0) {
p->delta[E_AXIS] = extrudeDiff;
p->dir = E_STEP_DIRPOS;
} else {
p->delta[E_AXIS] = -extrudeDiff;
p->dir = ESTEP;
}
Printer::currentPositionSteps[E_AXIS] = Printer::destinationSteps[E_AXIS];
p->numNonlinearSegments = 0;
//Define variables that are needed for the Bresenham algorithm. Please note that Z is not currently included in the Bresenham algorithm.
p->primaryAxis = E_AXIS;
p->stepsRemaining = p->delta[E_AXIS];
axisDistanceMM[E_AXIS] = p->distance = p->delta[E_AXIS] * Printer::invAxisStepsPerMM[E_AXIS];
axisDistanceMM[VIRTUAL_AXIS] = -p->distance;
p->moveID = lastMoveID++;
p->calculateMove(axisDistanceMM, pathOptimize, E_AXIS);
}
/**
Split a line up into a series of lines with at most DELTASEGMENTS_PER_PRINTLINE delta segments.
@param check_endstops Check endstops during the move.
@param pathOptimize Run the path optimizer.
@param softEndstop check if we go out of bounds.
*/
uint8_t PrintLine::queueNonlinearMove(uint8_t check_endstops, uint8_t pathOptimize, uint8_t softEndstop) {
ENSURE_POWER
//if (softEndstop && Printer::destinationSteps[Z_AXIS] < 0) Printer::destinationSteps[Z_AXIS] = 0; // now constrained at entry level including cylinder test
EVENT_CONTRAIN_DESTINATION_COORDINATES
int32_t difference[E_AXIS_ARRAY];
float axisDistanceMM[VIRTUAL_AXIS_ARRAY]; // Real cartesian axis movement in mm. Virtual axis in 4;
secondspeed_t secondSpeed = Printer::fanSpeed;
for(fast8_t axis = 0; axis < E_AXIS_ARRAY; axis++) {
difference[axis] = Printer::destinationSteps[axis] - Printer::currentPositionSteps[axis];
if(axis == E_AXIS) {
if(Printer::mode == PRINTER_MODE_FFF) {
Printer::extrudeMultiplyError += (static_cast<float>(difference[E_AXIS]) * Printer::extrusionFactor);
difference[E_AXIS] = static_cast<int32_t>(Printer::extrudeMultiplyError);
Printer::extrudeMultiplyError -= difference[E_AXIS];
axisDistanceMM[E_AXIS] = difference[E_AXIS] * Printer::invAxisStepsPerMM[E_AXIS];
Printer::filamentPrinted += axisDistanceMM[E_AXIS];
axisDistanceMM[E_AXIS] = fabs(axisDistanceMM[E_AXIS]);
}
#if defined(SUPPORT_LASER) && SUPPORT_LASER
else if(Printer::mode == PRINTER_MODE_LASER) {
secondSpeed = ((axisDistanceMM[X_AXIS] != 0 || axisDistanceMM[Y_AXIS] != 0) && (LaserDriver::laserOn || axisDistanceMM[E_AXIS] != 0) ? LaserDriver::intensity : 0);
axisDistanceMM[E_AXIS] = 0;
}
#endif
} else
axisDistanceMM[axis] = fabs(difference[axis] * Printer::invAxisStepsPerMM[axis]);
}
float cartesianDistance;
ufast8_t cartesianDir;
int32_t cartesianDeltaSteps[E_AXIS_ARRAY];
calculateDirectionAndDelta(difference, &cartesianDir, cartesianDeltaSteps);
if (!calculateDistance(axisDistanceMM, cartesianDir, &cartesianDistance)) {
// Appears the intent is to do nothing if no distance is detected.
// This apparently is not an error condition, just early exit.
return true;
}
if (!(cartesianDir & XYZ_STEP)) {
queueEMove(difference[E_AXIS], check_endstops, pathOptimize);
return true;
}
int16_t segmentCount;
#if DRIVE_SYSTEM == DELTA
float feedrate = RMath::min(Printer::feedrate, Printer::maxFeedrate[Z_AXIS]);
#else
float feedrate = Printer::feedrate; // each motor has own max. feedrate here resulting in total feedrate
#endif
if (cartesianDir & XY_STEP) {
// Compute number of seconds for move and hence number of segments needed
//float seconds = 100 * cartesianDistance / (Printer::feedrate * Printer::feedrateMultiply); multiply in feedrate included
float seconds = cartesianDistance / feedrate;
#ifdef DEBUG_SPLIT
Com::printFLN(Com::tDBGDeltaSeconds, seconds);
#endif
float sps = static_cast<float>((cartesianDir & ESTEP) == ESTEP ? Printer::printMovesPerSecond : Printer::travelMovesPerSecond);
segmentCount = RMath::max(1, static_cast<int16_t>(sps * seconds));
#ifdef DEBUG_SEGMENT_LENGTH
float segDist = cartesianDistance / (float)segmentCount;
if(segDist > Printer::maxRealSegmentLength) {
Printer::maxRealSegmentLength = segDist;
Com::printFLN(PSTR("SegmentsPerSecond:"), sps);
Com::printFLN(PSTR("New max. segment length:"), segDist);
}
#endif
//Com::printFLN(PSTR("Segments:"),segmentCount);
} else {
// Optimize pure Z axis move. Since a pure Z axis move is linear all we have to watch out for is unsigned integer overruns in
// the queued moves;
#ifdef DEBUG_SPLIT
Com::printFLN(Com::tDBGDeltaZDelta, cartesianDeltaSteps[Z_AXIS]);
#endif
segmentCount = (cartesianDeltaSteps[Z_AXIS] + (uint32_t)43680) / (uint32_t)43679; // can not go to 65535 for rounding issues causing overflow later in some cases!
}
// Now compute the number of lines needed
int numLines = (segmentCount + DELTASEGMENTS_PER_PRINTLINE - 1) / DELTASEGMENTS_PER_PRINTLINE;
// There could be some error here but it doesn't matter since the number of segments will just be reduced slightly
int segmentsPerLine = segmentCount / numLines;
int32_t startPosition[E_AXIS_ARRAY], fractionalSteps[E_AXIS_ARRAY];
if(numLines > 1) {
for (fast8_t i = 0; i < Z_AXIS_ARRAY; i++)
startPosition[i] = Printer::currentPositionSteps[i];
startPosition[E_AXIS] = 0;
cartesianDistance /= static_cast<float>(numLines);
}
#ifdef DEBUG_SPLIT
Com::printFLN(Com::tDBGDeltaSegments, segmentCount);
Com::printFLN(Com::tDBGDeltaNumLines, numLines);
Com::printFLN(Com::tDBGDeltaSegmentsPerLine, segmentsPerLine);
#endif
Printer::unsetAllSteppersDisabled(); // Motor is enabled now
waitForXFreeLines(1);
// Insert dummy moves if necessary
// Need to leave at least one slot open for the first split move
insertWaitMovesIfNeeded(pathOptimize, RMath::min(PRINTLINE_CACHE_SIZE - 4, numLines));
uint32_t oldEDestination = Printer::destinationSteps[E_AXIS]; // flow and volumetric extrusion changed virtual target
Printer::currentPositionSteps[E_AXIS] = 0;
for (int lineNumber = 1; lineNumber <= numLines; lineNumber++) {
waitForXFreeLines(1);
PrintLine *p = getNextWriteLine();
// Downside a comparison per loop. Upside one less distance calculation and simpler code.
if (numLines == 1) {
// p->numDeltaSegments = segmentCount; // not neede, gets overwritten further down
p->dir = cartesianDir;
for (fast8_t i = 0; i < E_AXIS_ARRAY; i++) {
p->delta[i] = cartesianDeltaSteps[i];
fractionalSteps[i] = difference[i];
}
p->distance = cartesianDistance;
} else {
for (fast8_t i = 0; i < E_AXIS_ARRAY; i++) {
Printer::destinationSteps[i] = startPosition[i] + (difference[i] * lineNumber) / numLines;
fractionalSteps[i] = Printer::destinationSteps[i] - Printer::currentPositionSteps[i];
axisDistanceMM[i] = fabs(fractionalSteps[i] * Printer::invAxisStepsPerMM[i]);
}
calculateDirectionAndDelta(fractionalSteps, &p->dir, p->delta);
p->distance = cartesianDistance;
}
p->joinFlags = 0;
p->secondSpeed = secondSpeed;
p->moveID = lastMoveID;
// Only set fixed on last segment
if (lineNumber == numLines && !pathOptimize)
p->setEndSpeedFixed(true);
p->flags = (check_endstops ? FLAG_CHECK_ENDSTOPS : 0);
#if MIXING_EXTRUDER
if(Printer::isAllEMotors()) {
p->flags |= FLAG_ALL_E_MOTORS;
}
#endif
p->numNonlinearSegments = segmentsPerLine;
uint16_t maxStepsPerSegment = p->calculateNonlinearSubSegments(softEndstop);
if (maxStepsPerSegment == 65535) {
Com::printWarningFLN(PSTR("in queueDeltaMove to calculateDeltaSubSegments returns error."));
return false;
}
#ifdef DEBUG_SPLIT
Com::printFLN(Com::tDBGDeltaMaxDS, (int32_t)maxStepsPerSegment);
#endif
int32_t virtualAxisSteps = static_cast<int32_t>(maxStepsPerSegment) * segmentsPerLine;
if (virtualAxisSteps == 0 && p->delta[E_AXIS] == 0) {
if (numLines != 1) {
Com::printErrorFLN(Com::tDBGDeltaNoMoveinDSegment);
return false; // Line too short in low precision area
}
break;
}
fast8_t drivingAxis = X_AXIS;
p->primaryAxis = VIRTUAL_AXIS; // Virtual axis will lead Bresenham step either way
if (virtualAxisSteps > p->delta[E_AXIS]) { // Is delta move or E axis leading
p->stepsRemaining = virtualAxisSteps;
axisDistanceMM[VIRTUAL_AXIS] = p->distance; //virtual_axis_move * Printer::invAxisStepsPerMM[Z_AXIS]; // Steps/unit same as all the towers
// Virtual axis steps per segment
p->numPrimaryStepPerSegment = maxStepsPerSegment;
#if DRIVE_SYSTEM != DELTA
if(cartesianDeltaSteps[Z_AXIS] > cartesianDeltaSteps[X_AXIS] && cartesianDeltaSteps[Z_AXIS] > cartesianDeltaSteps[Y_AXIS])
drivingAxis = Z_AXIS;
#endif
} else {
// Round up the E move to get something divisible by segment count which is greater than E move
p->numPrimaryStepPerSegment = (p->delta[E_AXIS] + segmentsPerLine - 1) / segmentsPerLine;
p->stepsRemaining = p->numPrimaryStepPerSegment * segmentsPerLine;
axisDistanceMM[VIRTUAL_AXIS] = -p->distance; //p->stepsRemaining * Printer::invAxisStepsPerMM[Z_AXIS];
drivingAxis = E_AXIS;
}
#ifdef DEBUG_SPLIT
Com::printFLN(Com::tDBGDeltaStepsPerSegment, p->numPrimaryStepPerSegment);
Com::printFLN(Com::tDBGDeltaVirtualAxisSteps, p->stepsRemaining);
#endif
p->calculateMove(axisDistanceMM, pathOptimize, drivingAxis);
for (fast8_t i = 0; i < E_AXIS_ARRAY; i++) {
Printer::currentPositionSteps[i] += fractionalSteps[i];
}
}
Printer::currentPositionSteps[E_AXIS] = Printer::destinationSteps[E_AXIS] = oldEDestination;
lastMoveID++; // Will wrap at 255
return true; // flag success
}
#endif
#if ARC_SUPPORT
// Arc function taken from grbl
// The arc is approximated by generating a huge number of tiny, linear segments. The length of each
// segment is configured in settings.mm_per_arc_segment.
void PrintLine::arc(float *position, float *target, float *offset, float radius, uint8_t isclockwise) {
// int acceleration_manager_was_enabled = plan_is_acceleration_manager_enabled();
// plan_set_acceleration_manager_enabled(false); // disable acceleration management for the duration of the arc
float center_axis0 = position[X_AXIS] + offset[X_AXIS];
float center_axis1 = position[Y_AXIS] + offset[Y_AXIS];
//float linear_travel = 0; //target[axis_linear] - position[axis_linear];
float extruder_travel = (Printer::destinationSteps[E_AXIS] - Printer::currentPositionSteps[E_AXIS]) * Printer::invAxisStepsPerMM[E_AXIS];
float r_axis0 = -offset[0]; // Radius vector from center to current location
float r_axis1 = -offset[1];
float rt_axis0 = target[0] - center_axis0;
float rt_axis1 = target[1] - center_axis1;
/*long xtarget = Printer::destinationSteps[X_AXIS];
long ytarget = Printer::destinationSteps[Y_AXIS];
long ztarget = Printer::destinationSteps[Z_AXIS];
long etarget = Printer::destinationSteps[E_AXIS];
*/
// CCW angle between position and target from circle center. Only one atan2() trig computation required.
float angular_travel = atan2(r_axis0 * rt_axis1 - r_axis1 * rt_axis0, r_axis0 * rt_axis0 + r_axis1 * rt_axis1);
if ((!isclockwise && angular_travel <= 0.00001) || (isclockwise && angular_travel < -0.000001)) {
angular_travel += 2.0f * M_PI;
}
if (isclockwise) {
angular_travel -= 2.0f * M_PI;
}
float millimeters_of_travel = fabs(angular_travel) * radius; //hypot(angular_travel*radius, fabs(linear_travel));
if (millimeters_of_travel < 0.001f) {
return;// treat as succes because there is nothing to do;
}
//uint16_t segments = (radius>=BIG_ARC_RADIUS ? floor(millimeters_of_travel/MM_PER_ARC_SEGMENT_BIG) : floor(millimeters_of_travel/MM_PER_ARC_SEGMENT));
// Increase segment size if printing faster then computation speed allows
uint16_t segments = (Printer::feedrate > 60.0f ? floor(millimeters_of_travel / RMath::min(static_cast<float>(MM_PER_ARC_SEGMENT_BIG), Printer::feedrate * 0.01666f * static_cast<float>(MM_PER_ARC_SEGMENT))) : floor(millimeters_of_travel / static_cast<float>(MM_PER_ARC_SEGMENT)));
if(segments == 0) segments = 1;
/*
// Multiply inverse feed_rate to compensate for the fact that this movement is approximated
// by a number of discrete segments. The inverse feed_rate should be correct for the sum of
// all segments.
if (invert_feed_rate) { feed_rate *= segments; }
*/
float theta_per_segment = angular_travel / segments;
//float linear_per_segment = linear_travel/segments;
float extruder_per_segment = extruder_travel / segments;
/* Vector rotation by transformation matrix: r is the original vector, r_T is the rotated vector,
and phi is the angle of rotation. Based on the solution approach by Jens Geisler.
r_T = [cos(phi) -sin(phi);
sin(phi) cos(phi] * r ;
For arc generation, the center of the circle is the axis of rotation and the radius vector is
defined from the circle center to the initial position. Each line segment is formed by successive
vector rotations. This requires only two cos() and sin() computations to form the rotation
matrix for the duration of the entire arc. Error may accumulate from numerical round-off, since
all double numbers are single precision on the Arduino. (True double precision will not have
round off issues for CNC applications.) Single precision error can accumulate to be greater than
tool precision in some cases. Therefore, arc path correction is implemented.
Small angle approximation may be used to reduce computation overhead further. This approximation
holds for everything, but very small circles and large mm_per_arc_segment values. In other words,
theta_per_segment would need to be greater than 0.1 rad and N_ARC_CORRECTION would need to be large
to cause an appreciable drift error. N_ARC_CORRECTION~=25 is more than small enough to correct for
numerical drift error. N_ARC_CORRECTION may be on the order a hundred(s) before error becomes an
issue for CNC machines with the single precision Arduino calculations.
This approximation also allows mc_arc to immediately insert a line segment into the planner
without the initial overhead of computing cos() or sin(). By the time the arc needs to be applied
a correction, the planner should have caught up to the lag caused by the initial mc_arc overhead.
This is important when there are successive arc motions.
*/
// Vector rotation matrix values
float cos_T = 1 - 0.5 * theta_per_segment * theta_per_segment; // Small angle approximation
float sin_T = theta_per_segment;
float arc_target[4];
float sin_Ti;
float cos_Ti;
float r_axisi;
uint16_t i;
int8_t count = 0;
// Initialize the linear axis
//arc_target[axis_linear] = position[axis_linear];
// Initialize the extruder axis
arc_target[E_AXIS] = Printer::currentPositionSteps[E_AXIS] * Printer::invAxisStepsPerMM[E_AXIS];
for (i = 1; i < segments; i++) {
// Increment (segments-1)
if((count & 3) == 0) {
//GCode::readFromSerial();
Commands::checkForPeriodicalActions(false);
UI_MEDIUM; // do check encoder
}
if (count < N_ARC_CORRECTION) { //25 pieces
// Apply vector rotation matrix
r_axisi = r_axis0 * sin_T + r_axis1 * cos_T;
r_axis0 = r_axis0 * cos_T - r_axis1 * sin_T;
r_axis1 = r_axisi;
count++;
} else {
// Arc correction to radius vector. Computed only every N_ARC_CORRECTION increments.
// Compute exact location by applying transformation matrix from initial radius vector(=-offset).
cos_Ti = cos(i * theta_per_segment);
sin_Ti = sin(i * theta_per_segment);
r_axis0 = -offset[0] * cos_Ti + offset[1] * sin_Ti;
r_axis1 = -offset[0] * sin_Ti - offset[1] * cos_Ti;
count = 0;
}
// Update arc_target location
arc_target[X_AXIS] = center_axis0 + r_axis0;
arc_target[Y_AXIS] = center_axis1 + r_axis1;
//arc_target[axis_linear] += linear_per_segment;
arc_target[E_AXIS] += extruder_per_segment;
Printer::moveToReal(arc_target[X_AXIS], arc_target[Y_AXIS], IGNORE_COORDINATE, arc_target[E_AXIS], IGNORE_COORDINATE);
}
// Ensure last segment arrives at target location.
Printer::moveToReal(target[X_AXIS], target[Y_AXIS], IGNORE_COORDINATE, target[E_AXIS], IGNORE_COORDINATE);
}
#endif
/**
Moves the stepper motors one step. If the last step is reached, the next movement is started.
The function must be called from a timer loop. It returns the time for the next call.
This is a modified version that implements a Bresenham 'multi-step' algorithm where the dominant
Cartesian axis steps may be less than the changing dominant delta axis.
*/
#if NONLINEAR_SYSTEM
int lastblk = - 1;
int32_t cur_errupd;
// Current nonlinear segment
NonlinearSegment *curd;
// Current nonlinear segment primary error increment
int32_t curd_errupd, stepsPerSegRemaining;
int32_t PrintLine::bresenhamStep() { // Version for delta printer
#if CPU_ARCH == ARCH_ARM
if(!PrintLine::nlFlag)
#else
if(cur == NULL)
#endif
{
setCurrentLine();
if(cur->isBlocked()) { // This step is in computation - shouldn't happen
if(lastblk != (int)cur) {
HAL::allowInterrupts();
lastblk = (int)cur;
Com::printFLN(Com::tBLK, (int32_t)linesCount);
}
cur = NULL;
#if CPU_ARCH == ARCH_ARM
PrintLine::nlFlag = false;
#endif
return 2000;
}
HAL::allowInterrupts();
lastblk = -1;
#if INCLUDE_DEBUG_NO_MOVE
if(Printer::debugNoMoves()) { // simulate a move, but do nothing in reality
removeCurrentLineForbidInterrupt();
if(linesCount == 0) UI_STATUS_F(Com::translatedF(UI_TEXT_IDLE_ID));
return 1000;
}
#endif
if(cur->isWarmUp()) {
// This is a warm up move to initialize the path planner correctly. Just waste
// a bit of time to get the planning up to date.
if(linesCount <= cur->getWaitForXLinesFilled()) {
cur = NULL;
#if CPU_ARCH==ARCH_ARM
PrintLine::nlFlag = false;
#endif
return 2000;
}
#if LASER_WARMUP_TIME > 0 && SUPPORT_LASER
if(cur->dir) {
LaserDriver::changeIntensity(LASER_PWM_MAX);
}
#endif
long wait = cur->getWaitTicks();
removeCurrentLineForbidInterrupt();
return(wait); // waste some time for path optimization to fill up
} // End if WARMUP
#if FEATURE_Z_PROBE
// z move may consist of more then 1 z line segment, so we better ignore them
// if the probe was already hit.
if(Printer::isZProbingActive() && Printer::stepsRemainingAtZHit >= 0) {
removeCurrentLineForbidInterrupt();
if(linesCount == 0) UI_STATUS_F(Com::translatedF(UI_TEXT_IDLE_ID));
return 1000;
}
#endif
if(cur->isEMove()) {
Extruder::enable();
}
cur->fixStartAndEndSpeed();
// Set up delta segments
if (cur->numNonlinearSegments) {
// If there are delta segments point to them here
curd = &cur->segments[--cur->numNonlinearSegments];
// Enable axis - All axis are enabled since they will most probably all be involved in a move
// Since segments could involve different axis this reduces load when switching segments and
// makes disabling easier.
Printer::enableXStepper();
Printer::enableYStepper();
Printer::enableZStepper();
Printer::setXDirection(curd->isXPositiveMove());
Printer::setYDirection(curd->isYPositiveMove());
Printer::setZDirection(curd->isZPositiveMove());
// Copy across movement into main direction flags so that endstops function correctly
#if DRIVE_SYSTEM == DELTA
cur->dir |= curd->dir; // deltas need this for homing!
#endif
// Initialize Bresenham for the first segment
cur->error[X_AXIS] = cur->error[Y_AXIS] = cur->error[Z_AXIS] = cur->numPrimaryStepPerSegment >> 1;
curd_errupd = cur->numPrimaryStepPerSegment;
stepsPerSegRemaining = cur->numPrimaryStepPerSegment;
} else curd = NULL;
cur_errupd = cur->stepsRemaining;
if(!cur->areParameterUpToDate()) { // should never happen, but with bad timings???
cur->updateStepsParameter();
}
Printer::vMaxReached = cur->vStart;
Printer::stepNumber = 0;
Printer::timer = 0;
HAL::forbidInterrupts();
#if USE_ADVANCE
if(!Printer::isAdvanceActivated()) // Set direction if no advance/OPS enabled
#endif
Extruder::setDirection(cur->isEPositiveMove());
#if defined(DIRECTION_DELAY) && DIRECTION_DELAY > 0
// HAL::delayMicroseconds(DIRECTION_DELAY); // We leave interrupt without step so no delay needed here
#endif
#if USE_ADVANCE
#if ENABLE_QUADRATIC_ADVANCE
Printer::advanceExecuted = cur->advanceStart;
#endif
cur->updateAdvanceSteps(cur->vStart, 0, false);
#endif
if(Printer::mode == PRINTER_MODE_FFF) {
Printer::setFanSpeedDirectly(cur->secondSpeed);
}
#if defined(SUPPORT_LASER) && SUPPORT_LASER
else if(Printer::mode == PRINTER_MODE_LASER) {
LaserDriver::changeIntensity(cur->secondSpeed);
}
#endif
#if MULTI_XENDSTOP_HOMING
Printer::multiXHomeFlags = MULTI_XENDSTOP_ALL; // move all x motors until endstop says differently
#endif
#if MULTI_YENDSTOP_HOMING
Printer::multiYHomeFlags = MULTI_YENDSTOP_ALL; // move all y motors until endstop says differently
#endif
#if MULTI_ZENDSTOP_HOMING
Printer::multiZHomeFlags = MULTI_ZENDSTOP_ALL; // move all z motors until endstop says differently
#endif
return Printer::interval; // Wait an other 50% from last step to make the 100% full
} // End cur=0
HAL::allowInterrupts();
if(curd != NULL) {
if(curd->checkEndstops(cur, (cur->isCheckEndstops()))) { // should stop move
cur->stepsRemaining = 0;
curd = NULL;
// eat up all following segments with moveID
uint8_t delId = cur->moveID;
removeCurrentLineForbidInterrupt();
while(linesCount > 0) {
setCurrentLine();
if(cur->isBlocked() || cur->moveID != delId) {
break;
}
removeCurrentLineForbidInterrupt();
}
cur = NULL;
#if CPU_ARCH == ARCH_ARM
nlFlag = false;
#endif
Printer::disableAllowedStepper();
if(Printer::mode == PRINTER_MODE_FFF) {
Printer::setFanSpeedDirectly(Printer::fanSpeed);
}
#if defined(SUPPORT_LASER) && SUPPORT_LASER
else if(Printer::mode == PRINTER_MODE_LASER) { // Last move disables laser for safety!
LaserDriver::changeIntensity(0);
}
#endif
return Printer::interval;
}
}
int maxLoops = (Printer::stepsPerTimerCall <= cur->stepsRemaining ? Printer::stepsPerTimerCall : cur->stepsRemaining);
HAL::forbidInterrupts();
for(int loop = 0; loop < maxLoops; loop++) {
#if STEPPER_HIGH_DELAY + DOUBLE_STEP_DELAY
if(loop > 0)
HAL::delayMicroseconds(STEPPER_HIGH_DELAY + DOUBLE_STEP_DELAY);
#endif
if((cur->error[E_AXIS] -= cur->delta[E_AXIS]) < 0) {
#if USE_ADVANCE
if(Printer::isAdvanceActivated()) { // Use interrupt for movement
if(cur->isEPositiveMove())
Printer::extruderStepsNeeded++;
else
Printer::extruderStepsNeeded--;
} else
#endif
Extruder::step();
cur->error[E_AXIS] += cur_errupd;
}
if (curd) {
// Take delta steps
if(curd->isXMove())
if((cur->error[X_AXIS] -= curd->deltaSteps[A_TOWER]) < 0) {
cur->startXStep();
cur->error[X_AXIS] += curd_errupd;
#ifdef DEBUG_REAL_POSITION
Printer::realDeltaPositionSteps[A_TOWER] += curd->isXPositiveMove() ? 1 : -1;
#endif
#ifdef DEBUG_STEPCOUNT
cur->totalStepsRemaining--;
#endif
}
if(curd->isYMove())
if((cur->error[Y_AXIS] -= curd->deltaSteps[B_TOWER]) < 0) {
cur->startYStep();
cur->error[Y_AXIS] += curd_errupd;
#ifdef DEBUG_REAL_POSITION
Printer::realDeltaPositionSteps[B_TOWER] += curd->isYPositiveMove() ? 1 : -1;
#endif
#ifdef DEBUG_STEPCOUNT
cur->totalStepsRemaining--;
#endif
}
if(curd->isZMove())
if((cur->error[Z_AXIS] -= curd->deltaSteps[C_TOWER]) < 0) {
cur->startZStep();
cur->error[Z_AXIS] += curd_errupd;
Printer::realDeltaPositionSteps[C_TOWER] += curd->isZPositiveMove() ? 1 : -1;
#ifdef DEBUG_STEPCOUNT
cur->totalStepsRemaining--;
#endif
}
stepsPerSegRemaining--;
}
#if CPU_ARCH != ARCH_AVR
if(loop < maxLoops - 1) {
#endif
Printer::insertStepperHighDelay();
Printer::endXYZSteps();
#if USE_ADVANCE
if(!Printer::isAdvanceActivated()) // Use interrupt for movement
#endif
Extruder::unstep();
#if CPU_ARCH != ARCH_AVR
}
#endif
if (!stepsPerSegRemaining) { // start new nonlinear segment
if (cur->numNonlinearSegments && curd != NULL) {
#if FEATURE_BABYSTEPPING
if(Printer::zBabystepsMissing/* && curd
&& (curd->dir & XYZ_STEP) == XYZ_STEP*/) {
// execute a extra baby step
Printer::zBabystep();
}
#endif
// Get the next delta segment
curd = &cur->segments[--cur->numNonlinearSegments];
// Initialize Bresenham for this segment (numPrimaryStepPerSegment is already correct for the half step setting)
cur->error[X_AXIS] = cur->error[Y_AXIS] = cur->error[Z_AXIS] = cur->numPrimaryStepPerSegment >> 1;
// Reset the counter of the primary steps. This is initialized in the line
// generation so don't have to do this the first time.
stepsPerSegRemaining = cur->numPrimaryStepPerSegment;
// Change direction if necessary
Printer::setXDirection(curd->dir & X_DIRPOS);
Printer::setYDirection(curd->dir & Y_DIRPOS);
Printer::setZDirection(curd->dir & Z_DIRPOS);
#if defined(DIRECTION_DELAY) && DIRECTION_DELAY > 0
#if CPU_ARCH != ARCH_AVR
if(loop < maxLoops - 1)
#endif
HAL::delayMicroseconds(DIRECTION_DELAY);
#endif
} else
curd = 0;// Release the last segment
//deltaSegmentCount--;
}
} // for loop
HAL::allowInterrupts(); // Allow interrupts for other types, timer1 is still disabled
#if RAMP_ACCELERATION
//If acceleration is enabled on this move and we are in the acceleration segment, calculate the current interval
if (cur->moveAccelerating()) {
Printer::vMaxReached = HAL::ComputeV(Printer::timer, cur->fAcceleration) + cur->vStart;
if(Printer::vMaxReached > cur->vMax) Printer::vMaxReached = cur->vMax;
speed_t v = Printer::updateStepsPerTimerCall(Printer::vMaxReached);
Printer::interval = HAL::CPUDivU2(v);
// if(Printer::maxInterval < Printer::interval) // fix timing for very slow speeds
// Printer::interval = Printer::maxInterval;
Printer::timer += Printer::interval;
cur->updateAdvanceSteps(Printer::vMaxReached, maxLoops, true);
Printer::stepNumber += maxLoops; // is only used by moveAccelerating
} else if (cur->moveDecelerating()) { // time to slow down
speed_t v = HAL::ComputeV(Printer::timer, cur->fAcceleration);
if (v > Printer::vMaxReached) // if deceleration goes too far it can become too large
v = cur->vEnd;
else {
v = Printer::vMaxReached - v;
if (v < cur->vEnd) v = cur->vEnd; // extra steps at the end of deceleration due to rounding errors
}
cur->updateAdvanceSteps(v, maxLoops, false);
v = Printer::updateStepsPerTimerCall(v);
Printer::interval = HAL::CPUDivU2(v);
// if(Printer::maxInterval < Printer::interval) // fix timing for very slow speeds
// Printer::interval = Printer::maxInterval;
Printer::timer += Printer::interval;
} else {
// If we had acceleration, we need to use the latest vMaxReached and interval
// If we started full speed, we need to use cur->fullInterval and vMax
cur->updateAdvanceSteps((!cur->accelSteps ? cur->vMax : Printer::vMaxReached), 0, true);
if(!cur->accelSteps) {
if(cur->vMax > STEP_DOUBLER_FREQUENCY) {
#if ALLOW_QUADSTEPPING
if(cur->vMax > STEP_DOUBLER_FREQUENCY * 2) {
Printer::stepsPerTimerCall = 4;
Printer::interval = cur->fullInterval << 2;
} else {
Printer::stepsPerTimerCall = 2;
Printer::interval = cur->fullInterval << 1;
}
#else
Printer::stepsPerTimerCall = 2;
Printer::interval = cur->fullInterval << 1;
#endif
} else {
Printer::stepsPerTimerCall = 1;
Printer::interval = cur->fullInterval;
}
}
}
#else
Printer::interval = cur->fullInterval; // without RAMPS always use full speed
#endif
PrintLine::cur->stepsRemaining -= maxLoops;
if(cur->stepsRemaining <= 0 || cur->isNoMove()) { // line finished
// Release remaining delta segments
#ifdef DEBUG_STEPCOUNT
if(cur->totalStepsRemaining || cur->numNonlinearSegments) {
Com::printFLN(PSTR("Missed steps:"), cur->totalStepsRemaining);
Com::printFLN(PSTR("Step/seg r:"), stepsPerSegRemaining);
Com::printFLN(PSTR("NDS:"), (int) cur->numNonlinearSegments);
}
#endif
removeCurrentLineForbidInterrupt();
Printer::disableAllowedStepper();
if(linesCount == 0) {
if(!Printer::isPrinting()) {
UI_STATUS_F(Com::translatedF(UI_TEXT_IDLE_ID));
}
if(Printer::mode == PRINTER_MODE_FFF) {
Printer::setFanSpeedDirectly(Printer::fanSpeed);
}
#if defined(SUPPORT_LASER) && SUPPORT_LASER
else if(Printer::mode == PRINTER_MODE_LASER) { // Last move disables laser for safety!
LaserDriver::changeIntensity(0);
}
#endif
}
Printer::interval >>= 1; // 50% of time to next call to do cur=0
DEBUG_MEMORY;
} // Do even
#if CPU_ARCH != ARCH_AVR
Printer::insertStepperHighDelay();
Printer::endXYZSteps();
#if USE_ADVANCE
if(!Printer::isAdvanceActivated()) // Use interrupt for movement
#endif
Extruder::unstep();
#endif
return Printer::interval;
}
#else
/**
Moves the stepper motors one step. If the last step is reached, the next movement is started.
The function must be called from a timer loop. It returns the time for the next call.
Normal linear algorithm
*/
int lastblk = -1;
int32_t cur_errupd;
int32_t PrintLine::bresenhamStep() { // version for Cartesian printer
#if CPU_ARCH == ARCH_ARM
if(!PrintLine::nlFlag)
#else
if(cur == NULL)
#endif
{
setCurrentLine();
if(cur->isBlocked()) { // This step is in computation - shouldn't happen
/*if(lastblk!=(int)cur) // can cause output errors!
{
HAL::allowInterrupts();
lastblk = (int)cur;
Com::printFLN(Com::tBLK,lines_count);
}*/
cur = NULL;
#if CPU_ARCH==ARCH_ARM
PrintLine::nlFlag = false;
#endif
return 2000;
}
HAL::allowInterrupts();
lastblk = -1;
#if INCLUDE_DEBUG_NO_MOVE
if(Printer::debugNoMoves()) { // simulate a move, but do nothing in reality
removeCurrentLineForbidInterrupt();
return 1000;
}
#endif
ANALYZER_OFF(ANALYZER_CH0);
if(cur->isWarmUp()) {
// This is a warm up move to initialize the path planner correctly. Just waste
// a bit of time to get the planning up to date.
if(linesCount <= cur->getWaitForXLinesFilled()) {
cur = NULL;
#if CPU_ARCH == ARCH_ARM
PrintLine::nlFlag = false;
#endif
return 2000;
}
#if LASER_WARMUP_TIME > 0 && SUPPORT_LASER
if(cur->dir) {
LaserDriver::changeIntensity(LASER_PWM_MAX);
}
#endif
long wait = cur->getWaitTicks();
removeCurrentLineForbidInterrupt();
return(wait); // waste some time for path optimization to fill up
} // End if WARMUP
//Only enable axis that are moving. If the axis doesn't need to move then it can stay disabled depending on configuration.
#if GANTRY
#if DRIVE_SYSTEM == XY_GANTRY || DRIVE_SYSTEM == YX_GANTRY
if(cur->isXOrYMove()) {
Printer::enableXStepper();
Printer::enableYStepper();
}
if(cur->isZMove()) Printer::enableZStepper();
#else // XZ / ZX Gantry
if(cur->isXOrZMove()) {
Printer::enableXStepper();
Printer::enableZStepper();
}
if(cur->isYMove()) Printer::enableYStepper();
#endif
#else
if(cur->isXMove()) Printer::enableXStepper();
if(cur->isYMove()) Printer::enableYStepper();
if(cur->isZMove()) Printer::enableZStepper();
#endif
if(cur->isEMove()) Extruder::enable();
cur->fixStartAndEndSpeed();
HAL::allowInterrupts();
cur_errupd = cur->delta[cur->primaryAxis];
if(!cur->areParameterUpToDate()) { // should never happen, but with bad timings???
cur->updateStepsParameter();
}
Printer::vMaxReached = cur->vStart;
Printer::stepNumber = 0;
Printer::timer = 0;
HAL::forbidInterrupts();
//Determine direction of movement,check if endstop was hit
#if !(GANTRY)
Printer::setXDirection(cur->isXPositiveMove());
Printer::setYDirection(cur->isYPositiveMove());
Printer::setZDirection(cur->isZPositiveMove());
#else // Any gantry type
long gdx = (cur->dir & X_DIRPOS ? cur->delta[X_AXIS] : -cur->delta[X_AXIS]); // Compute signed difference in steps
#if DRIVE_SYSTEM == XY_GANTRY || DRIVE_SYSTEM == YX_GANTRY
Printer::setZDirection(cur->isZPositiveMove());
long gdy = (cur->dir & Y_DIRPOS ? cur->delta[Y_AXIS] : -cur->delta[Y_AXIS]);
Printer::setXDirection(gdx + gdy >= 0);
#if DRIVE_SYSTEM == XY_GANTRY
Printer::setYDirection(gdx > gdy);
#else
Printer::setYDirection(gdx <= gdy);
#endif
#else // XZ or ZX core
Printer::setYDirection(cur->isYPositiveMove());
long gdz = (cur->dir & Z_DIRPOS ? cur->delta[Z_AXIS] : -cur->delta[Z_AXIS]);
Printer::setXDirection(gdx + gdz >= 0);
#if DRIVE_SYSTEM == XZ_GANTRY
Printer::setZDirection(gdx > gdz);
#else
Printer::setZDirection(gdx <= gdz);
#endif
#endif // YZ or ZY Gantry
#endif // GANTRY
#if USE_ADVANCE
if(!Printer::isAdvanceActivated()) // Set direction if no advance/OPS enabled
#endif
Extruder::setDirection(cur->isEPositiveMove());
#if defined(DIRECTION_DELAY) && DIRECTION_DELAY > 0
// HAL::delayMicroseconds(DIRECTION_DELAY); // We leave interrupt without step so no delay needed here
#endif
#if USE_ADVANCE
#if ENABLE_QUADRATIC_ADVANCE
Printer::advanceExecuted = cur->advanceStart;
#endif
cur->updateAdvanceSteps(cur->vStart, 0, false);
#endif
if(Printer::mode == PRINTER_MODE_FFF) {
Printer::setFanSpeedDirectly(static_cast<uint8_t>(cur->secondSpeed));
}
#if defined(SUPPORT_LASER) && SUPPORT_LASER
else if(Printer::mode == PRINTER_MODE_LASER) {
LaserDriver::changeIntensity(cur->secondSpeed);
}
#endif
#if MULTI_XENDSTOP_HOMING
Printer::multiXHomeFlags = MULTI_XENDSTOP_ALL; // move all x motors until endstop says differently
#endif
#if MULTI_YENDSTOP_HOMING
Printer::multiYHomeFlags = MULTI_YENDSTOP_ALL; // move all y motors until endstop says differently
#endif
#if MULTI_ZENDSTOP_HOMING
Printer::multiZHomeFlags = MULTI_ZENDSTOP_ALL; // move all z motors until endstop says differently
#endif
return Printer::interval; // Wait an other 50% from last step to make the 100% full
} // End cur=0
cur->checkEndstops();
fast8_t max_loops = Printer::stepsPerTimerCall;
if(cur->stepsRemaining < max_loops)
max_loops = cur->stepsRemaining;
for(fast8_t loop = 0; loop < max_loops; loop++) {
#if STEPPER_HIGH_DELAY + DOUBLE_STEP_DELAY > 0
if(loop)
HAL::delayMicroseconds(STEPPER_HIGH_DELAY + DOUBLE_STEP_DELAY);
#endif
if((cur->error[E_AXIS] -= cur->delta[E_AXIS]) < 0) {
#if USE_ADVANCE
if(Printer::isAdvanceActivated()) { // Use interrupt for movement
if(cur->isEPositiveMove())
Printer::extruderStepsNeeded++;
else
Printer::extruderStepsNeeded--;
} else
#endif
Extruder::step();
cur->error[E_AXIS] += cur_errupd;
}
#if CPU_ARCH == ARCH_AVR
if(cur->isXMove())
#endif
if((cur->error[X_AXIS] -= cur->delta[X_AXIS]) < 0) {
cur->startXStep();
cur->error[X_AXIS] += cur_errupd;
}
#if CPU_ARCH == ARCH_AVR
if(cur->isYMove())
#endif
if((cur->error[Y_AXIS] -= cur->delta[Y_AXIS]) < 0) {
cur->startYStep();
cur->error[Y_AXIS] += cur_errupd;
}
#if CPU_ARCH == ARCH_AVR
if(cur->isZMove())
#endif
if((cur->error[Z_AXIS] -= cur->delta[Z_AXIS]) < 0) {
cur->startZStep();
cur->error[Z_AXIS] += cur_errupd;
#ifdef DEBUG_STEPCOUNT
cur->totalStepsRemaining--;
#endif
}
#if (GANTRY)
#if DRIVE_SYSTEM == XY_GANTRY || DRIVE_SYSTEM == YX_GANTRY
Printer::executeXYGantrySteps();
#else
Printer::executeXZGantrySteps();
#endif
#endif
Printer::insertStepperHighDelay();
#if USE_ADVANCE
if(!Printer::isAdvanceActivated()) // Use interrupt for movement
#endif
Extruder::unstep();
cur->stepsRemaining--;
Printer::endXYZSteps();
} // for loop
HAL::allowInterrupts(); // Allow interrupts for other types, timer1 is still disabled
#if RAMP_ACCELERATION
//If acceleration is enabled on this move and we are in the acceleration segment, calculate the current interval
if (cur->moveAccelerating()) { // we are accelerating
Printer::vMaxReached = HAL::ComputeV(Printer::timer, cur->fAcceleration) + cur->vStart; // v = v0 + a * t
if(Printer::vMaxReached > cur->vMax) Printer::vMaxReached = cur->vMax;
unsigned int v = Printer::updateStepsPerTimerCall(Printer::vMaxReached);
Printer::interval = HAL::CPUDivU2(v);
// if(Printer::maxInterval < Printer::interval) // fix timing for very slow speeds
// Printer::interval = Printer::maxInterval;
Printer::timer += Printer::interval;
cur->updateAdvanceSteps(Printer::vMaxReached, max_loops, true);
Printer::stepNumber += max_loops; // only used for moveAccelerating
} else if (cur->moveDecelerating()) { // time to slow down
unsigned int v = HAL::ComputeV(Printer::timer, cur->fAcceleration);
if (v > Printer::vMaxReached) // if deceleration goes too far it can become too large
v = cur->vEnd;
else {
v = Printer::vMaxReached - v;
if (v < cur->vEnd) v = cur->vEnd; // extra steps at the end of deceleration due to rounding errors
}
cur->updateAdvanceSteps(v, max_loops, false); // needs original v
v = Printer::updateStepsPerTimerCall(v);
Printer::interval = HAL::CPUDivU2(v);
// if(Printer::maxInterval < Printer::interval) // fix timing for very slow speeds
// Printer::interval = Printer::maxInterval;
Printer::timer += Printer::interval;
} else { // full speed reached
cur->updateAdvanceSteps((!cur->accelSteps ? cur->vMax : Printer::vMaxReached), 0, true);
// constant speed reached
if(cur->vMax > STEP_DOUBLER_FREQUENCY) {
#if ALLOW_QUADSTEPPING
if(cur->vMax > STEP_DOUBLER_FREQUENCY * 2) {
Printer::stepsPerTimerCall = 4;
Printer::interval = cur->fullInterval << 2;
} else {
Printer::stepsPerTimerCall = 2;
Printer::interval = cur->fullInterval << 1;
}
#else
Printer::stepsPerTimerCall = 2;
Printer::interval = cur->fullInterval << 1;
#endif
} else {
Printer::stepsPerTimerCall = 1;
Printer::interval = cur->fullInterval;
}
}
#else
Printer::stepsPerTimerCall = 1;
Printer::interval = cur->fullInterval; // without RAMPS always use full speed
#endif // RAMP_ACCELERATION
long interval = Printer::interval;
if(cur->stepsRemaining <= 0 || cur->isNoMove()) { // line finished
#ifdef DEBUG_STEPCOUNT
if(cur->totalStepsRemaining) {
Com::printF(Com::tDBGMissedSteps, cur->totalStepsRemaining);
Com::printFLN(Com::tComma, cur->stepsRemaining);
}
#endif
removeCurrentLineForbidInterrupt();
Printer::disableAllowedStepper();
if(linesCount == 0) {
if(!Printer::isPrinting()) {
UI_STATUS_F(Com::translatedF(UI_TEXT_IDLE_ID));
}
if(Printer::mode == PRINTER_MODE_FFF) {
Printer::setFanSpeedDirectly(Printer::fanSpeed);
}
#if defined(SUPPORT_LASER) && SUPPORT_LASER
else if(Printer::mode == PRINTER_MODE_LASER) { // Last move disables laser for safety!
LaserDriver::changeIntensity(0);
}
#endif
}
interval = Printer::interval = interval >> 1; // 50% of time to next call to do cur=0
DEBUG_MEMORY;
} // Do even
#if FEATURE_BABYSTEPPING
if(Printer::zBabystepsMissing) {
HAL::forbidInterrupts();
Printer::zBabystep();
}
#endif
return interval;
}
#endif