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rove.ino
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rove.ino
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/**
* Polargraph Server for ATMEGA1280+
* Written by Sandy Noble
* Released under GNU License version 3.
* http://www.polargraph.co.uk
* https://github.com/euphy/polargraph_server_polarshield
Specific features for Polarshield / arduino mega.
Rove.
Commands that will set and modify the rove area, and the features that use
the rove area heavily.
*/
#if MICROCONTROLLER == MC_MEGA
void rove_setRoveArea()
{
rove1x = stepsPerMM * atol(inParam1);
rove1y = stepsPerMM * atol(inParam2);
roveWidth = stepsPerMM * atol(inParam3);
roveHeight = stepsPerMM * atol(inParam4);
if (rove1x > pageWidth)
rove1x = pageWidth / 2;
else if (rove1x < 1)
rove1x = 1;
if (rove1y > pageHeight)
rove1y = pageHeight / 2;
else if (rove1y < 1)
rove1y = 1;
if (roveWidth+rove1x > pageWidth)
roveWidth = pageWidth - rove1x;
if (roveHeight+rove1y > pageHeight)
roveHeight = pageHeight - rove1y;
useRoveArea = true;
Serial.println("Set rove area (steps):");
Serial.print("X:");
Serial.print(rove1x);
Serial.print(",Y:");
Serial.print(rove1y);
Serial.print(",width:");
Serial.print(roveWidth);
Serial.print(",height:");
Serial.println(roveHeight);
Serial.println("Set rove area (mm):");
Serial.print("X:");
Serial.print(rove1x * mmPerStep);
Serial.print("mm, Y:");
Serial.print(rove1y * mmPerStep);
Serial.print("mm, width:");
Serial.print(roveWidth * mmPerStep);
Serial.print("mm, height:");
Serial.print(roveHeight * mmPerStep);
Serial.println("mm.");
}
void rove_startText()
{
if (useRoveArea)
{
long tA = multiplier(atol(inParam1));
long tB = multiplier(atol(inParam2));
inNoOfParams = 0;
if (rove_inRoveArea(tA, tB))
{
Serial.println("Target position is in rove area.");
penlift_penUp();
changeLength(tA, tB);
textRowSize = multiplier(atoi(inParam3));
textCharSize = textRowSize * 0.8;
globalDrawDirection = atoi(inParam4);
Serial.println("Text started.");
}
else
{
Serial.print("Target position (");
Serial.print(tA);
Serial.print(",");
Serial.print(tB);
Serial.println(") not in rove area.");
}
}
else
{
Serial.println("Rove area must be defined to start text.");
}
}
boolean rove_inRoveArea(float a, float b)
{
// work out cartesian position of pen
float cX = getCartesianXFP(a, b);
float cY = getCartesianYFP(cX, a);
// Serial.print("Input cX: ");
// Serial.println(cX);
// Serial.print("Input cY: ");
// Serial.println(cY);
//
// Serial.print("Rove origin: ");
// Serial.print(rove1x);
// Serial.print(", ");
// Serial.println(rove1y);
//
// Serial.print("Rove size: ");
// Serial.print(roveWidth);
// Serial.print(", ");
// Serial.println(roveHeight);
if (cX < rove1x || cX > rove1x+roveWidth || cY < rove1y || cY > rove1y+roveHeight)
return false;
else
return true;
}
/**
Method that works out where the next line should start, based on pen position, line
width and rove area
*/
boolean rove_moveToBeginningOfNextTextLine()
{
Serial.println("Move to beginning of next line.");
Serial.print("Global draw direction is ");
Serial.println(globalDrawDirection);
long xIntersection;
long yIntersection;
boolean result = false;
if (globalDrawDirection == DIR_SE) // 2
{
long nextLine = motorB.currentPosition() + textRowSize;
Serial.print("Next line:");
Serial.println(nextLine);
// greater than the far corner or less than the near corner
if (sq(nextLine) > sq(rove1y+roveHeight) + sq(pageWidth-rove1x)
|| sq(nextLine) < sq(rove1y) + sq(pageWidth-(rove1x+roveWidth)))
{
Serial.println("No space for lines!");
// no lines left!
}
else if (sq(nextLine) <= sq(rove1y) + sq(pageWidth-rove1x))
{
Serial.println("On the top edge.");
// measure on the top edge of the rove area
xIntersection = pageWidth-sqrt(sq(nextLine) - sq(rove1y));
yIntersection = rove1y;
Serial.print("nextline:");
Serial.print(nextLine * mmPerStep);
Serial.print(",rove1x:");
Serial.print(rove1x * mmPerStep);
Serial.print(",rove1y:");
Serial.println(rove1y * mmPerStep);
result = true;
}
else
{
Serial.println("On the left edge.");
// measure on the left edge of the rove area
xIntersection = rove1x;
yIntersection = sqrt(sq(nextLine) - sq(pageWidth - rove1x));
result = true;
}
}
else if (globalDrawDirection == DIR_NW) // 4
{
}
else if (globalDrawDirection == DIR_SW) //3
{
}
else //(drawDirection == DIR_NE) // default //1
{
}
if (result)
{
long pA = getMachineA(xIntersection, yIntersection);
long pB = getMachineB(xIntersection, yIntersection);
changeLength(pA, pB);
}
return result;
}
/**
* This is a good one - hoping to draw something like the
* Norwegian Creations machine. This uses a very short wavelength
* and a relatively wide amplitude. Using a wavelength this short
* isn't practical for interactive use (too many commands)
* so this first attempt will do it on-board. In addition this
* should cut out an awful lot of the complexity involved in
* creating lists of commands, but will probably result in some
* fairly dirty code. Apologies in advance.
*/
void rove_drawNorwegianFromFile()
{
if (useRoveArea)
{
// get parameters
String filename = inParam1;
int maxAmplitude = multiplier(atoi(inParam2));
int wavelength = multiplier(atoi(inParam3));
inNoOfParams = 0;
// Look up file and open it
if (!sd_openPbm(filename))
{
Serial.print("Couldn't open that file - ");
Serial.println(filename);
return;
}
else
{
Serial.print("image size ");
Serial.print(pbmWidth, DEC);
Serial.print(", ");
Serial.println(pbmHeight, DEC);
Serial.print("(roveWidth:");
Serial.print(roveWidth);
Serial.println(")");
pbmScaling = float(roveWidth) / float(pbmWidth);
Serial.print("Scaling factor:");
Serial.println(pbmScaling);
Serial.print("Rove width:");
Serial.println(roveWidth);
Serial.print("Image offset:");
Serial.println(pbmImageoffset);
}
// Pen up and move to start corner (top-right)
penlift_penUp();
// Move to top of first row:
// x2 - amplitude
// set roveHeight so that it is the same shape as the image.
roveHeight = roveWidth * pbmAspectRatio;
long rove2x = rove1x + roveWidth;
long rove2y = rove1y + roveHeight;
// work out the distance from motor B to the closest corner of the rove area
float row = getMachineB(rove2x,rove1y);
// so the first row will be that value plus half of maxAmplitude
row += (maxAmplitude / 2);
changeLength(getMachineA(rove2x, rove1y), row);
penlift_penDown();
// and figure out where the arc with this radius intersects the top edge
long xIntersection;
long yIntersection;
boolean finished = false;
float tA = motorA.currentPosition();
float tB = motorB.currentPosition();
// tA = getMachineA(rove2x, rove2y);
// tB = row;
int pixels = 0;
while (!finished)
{
if (!rove_inRoveArea(tA, tB))
{
Serial.println("Outside rove area. Making new line.");
penlift_penUp();
// increment row
row += maxAmplitude;
tB = row;
// greater than the far corner or less than the near corner
if (sq(row) > sq(rove2y) + sq(pageWidth-rove1x)
|| sq(row) < sq(rove1y) + sq(pageWidth-(rove2x)))
{
Serial.println("No space for rows!");
// no lines left!
finished = true;
}
else if (sq(row) <= sq(rove1y) + sq(pageWidth-rove1x))
{
Serial.println("On the top edge.");
// measure on the top edge of the rove area
xIntersection = pageWidth-sqrt(sq(row) - sq(rove1y));
yIntersection = rove1y;
Serial.print("New row starts at (mm) x:");
Serial.print(rove1x * mmPerStep);
Serial.print(",Y:");
Serial.print(rove1y * mmPerStep);
// move
tA = getMachineA(xIntersection, yIntersection);
tB = getMachineB(xIntersection, yIntersection);
finished = false;
}
else
{
Serial.println("On the left edge.");
// measure on the left edge of the rove area
xIntersection = rove1x;
yIntersection = sqrt(sq(row) - sq(pageWidth - rove1x));
Serial.print("New row starts at (mm) x:");
Serial.print(rove1x * mmPerStep);
Serial.print(",Y:");
Serial.print(rove1y * mmPerStep);
// move
tA = getMachineA(xIntersection, yIntersection);
tB = getMachineB(xIntersection, yIntersection);
finished = false;
}
delay(1000);
}
else
{
Serial.println("In area.");
}
if (!finished)
{
changeLength(tA,tB);
penlift_penDown();
pixels++;
Serial.print("Pixel ");
Serial.println(pixels);
// draw pixel
// Measure cartesian position at that point.
float cX = getCartesianXFP(tA, tB);
float cY = getCartesianYFP(cX, tA);
cX -= rove1x;
cY -= rove1y;
Serial.print("Drawing pixel on page at x:");
Serial.print(cX); //* mmPerStep);
Serial.print(", y:");
Serial.println(cY);// * mmPerStep);
// Scale down to cartesian position in bitmap
cX = cX / pbmScaling;
cY = cY / pbmScaling;
Serial.print("Drawing pixel from file at pixel x:");
Serial.print(cX);
Serial.print(", y:");
Serial.println(cY);
if (int(cY) > pbmHeight || int(cX) > pbmWidth)
{
Serial.println("Out of pixels. Cancelling");
finished = true;
}
else
{
// Get pixel brightness at that position
byte brightness = sd_getBrightnessAtPixel(cX, cY);
if (brightness < 0)
{
Serial.println("No brightness value found. Cancelling.");
finished = true;
}
else
{
// Scale pixel amplitude to be in range 0 to <maxAmplitude>,
// where brightest = 0 and darkest = <maxAmplitude>
byte amplitude = brightness;
amplitude = pixel_scaleDensity(amplitude, pbmDepth, maxAmplitude);
// Draw the wave:
float halfWavelength = float(wavelength) / 2.0;
float halfAmplitude = float(amplitude) / 2.0;
changeLength(tA+halfWavelength, tB-halfAmplitude);
changeLength(tA+halfWavelength, tB+halfAmplitude);
changeLength(tA+wavelength, tB);
tA += wavelength;
// changeLength(tA, tB);
}
}
}
else
{
Serial.println("Finished!!");
// finished
}
}
penlift_penUp();
}
else
{
Serial.println("Rove area must be chosen for this operation.");
}
}
void rove_drawRoveAreaFittedToImage()
{
if (useRoveArea)
{
// get parameters
String filename = inParam1;
// Look up file and open it
if (!sd_openPbm(filename))
{
Serial.print("Couldn't open that file - ");
Serial.println(filename);
return;
}
else
{
Serial.print("image size ");
Serial.print(pbmWidth, DEC);
Serial.print(", ");
Serial.println(pbmHeight, DEC);
Serial.print("(roveWidth:");
Serial.print(roveWidth);
Serial.println(")");
pbmScaling = roveWidth / pbmWidth;
Serial.print("Scaling factor:");
Serial.println(pbmScaling);
Serial.print("Rove width:");
Serial.println(roveWidth);
Serial.print("Image offset:");
Serial.println(pbmImageoffset);
}
// set roveHeight so that it is the same shape as the image.
roveHeight = roveWidth * pbmAspectRatio;
long rove2x = rove1x + roveWidth;
long rove2y = rove1y + roveHeight;
Serial.print("rove2x:");
Serial.print(rove2x);
Serial.print("rove2y:");
Serial.println(rove2y);
// go to first point, top-left
// Serial.println("Point 1.");
float mA = motorA.currentPosition();
float mB = motorB.currentPosition();
float tA = getMachineA(rove1x, rove1y);
float tB = getMachineB(rove1x, rove1y);
// Serial.print("now a:");
// Serial.print(mA);
// Serial.print(",b:");
// Serial.print(mB);
// Serial.print(", target a:");
// Serial.print(tA);
// Serial.print(", b:");
// Serial.print(tB);
exec_drawBetweenPoints(mA, mB, tA, tB, 20);
// Serial.println("Point 2.");
mA = motorA.currentPosition();
mB = motorB.currentPosition();
tA = getMachineA(rove2x, rove1y);
tB = getMachineB(rove2x, rove1y);
// Serial.print("now a:");
// Serial.print(mA);
// Serial.print(",b:");
// Serial.print(mB);
// Serial.print(", target a:");
// Serial.print(tA);
// Serial.print(", b:");
// Serial.println(tB);
exec_drawBetweenPoints(mA, mB, tA, tB, 20);
// Serial.println("Point 3.");
mA = motorA.currentPosition();
mB = motorB.currentPosition();
tA = getMachineA(rove2x, rove2y);
tB = getMachineB(rove2x, rove2y);
// Serial.print("now a:");
// Serial.print(mA);
// Serial.print(",b:");
// Serial.print(mB);
// Serial.print(", target a:");
// Serial.print(tA);
// Serial.print(", b:");
// Serial.println(tB);
exec_drawBetweenPoints(mA, mB, tA, tB, 20);
// Serial.println("Point 4.");
mA = motorA.currentPosition();
mB = motorB.currentPosition();
tA = getMachineA(rove1x, rove2y);
tB = getMachineB(rove1x, rove2y);
// Serial.print("now a:");
// Serial.print(mA);
// Serial.print(",b:");
// Serial.print(mB);
// Serial.print(", target a:");
// Serial.print(tA);
// Serial.print(", b:");
// Serial.println(tB);
exec_drawBetweenPoints(mA, mB, tA, tB, 20);
// Serial.println("Point 5.");
mA = motorA.currentPosition();
mB = motorB.currentPosition();
tA = getMachineA(rove1x, rove1y);
tB = getMachineB(rove1x, rove1y);
// Serial.print("now a:");
// Serial.print(mA);
// Serial.print(",b:");
// Serial.print(mB);
// Serial.print(", target a:");
// Serial.print(tA);
// Serial.print(", b:");
// Serial.println(tB);
exec_drawBetweenPoints(mA, mB, tA, tB, 20);
exec_drawBetweenPoints(float(motorA.currentPosition()), float(motorB.currentPosition()), getMachineA(rove1x, rove1y), getMachineB(rove1x, rove1y), 20);
// Serial.println("Done.");
}
else
{
Serial.println("Rove area must be chosen for this operation.");
}
}
/**
* This moves to a random positions inside the rove area.
*/
void rove_moveToRandomPositionInRoveArea()
{
long x = random(rove1x, rove1x+roveWidth);
long y = random(rove1y, rove1y+roveHeight);
float a = getMachineA(x,y);
float b = getMachineB(x,y);
penlift_penUp();
changeLength(a,b);
}
void rove_swirl()
{
motorA.run();
motorB.run();
if (motorA.distanceToGo() == 0)
{
long x = random(rove1x, rove1x+roveWidth);
long y = random(rove1y, rove1y+roveHeight);
float a = getMachineA(x,y);
motorA.moveTo(a);
}
if (motorB.distanceToGo() == 0)
{
long x = random(rove1x, rove1x+roveWidth);
long y = random(rove1y, rove1y+roveHeight);
float b = getMachineB(x,y);
motorB.moveTo(b);
}
}
void rove_controlSwirling()
{
if (atoi(inParam1) == 0)
{
swirling = false;
}
else
{
if (useRoveArea)
{
swirling = true;
}
else
{
Serial.println("Rove area must be defined to swirl.");
}
}
}
#endif