IFD:PhysicalComp2011/code: Difference between revisions

/* SIMPLE SHAPES
 *
 * Get familiar with the coordinate system and the way
 * shapes are beeing drawn onto the screen.
 *
 * Frederic Gmeiner 2011
 */

// define the width and height of the display window:
// 400 x 400 px
size(400,400);

// draw the following shapes without outlines:
noStroke();
//set the fill color of the following shapes to pure red:
fill(255,0,0);
// draw a rectangle:
rect(230,230,50,100);
// set the fill color to pure green and draw a rectangle:
fill(0,255,0);
rect(200,200,50,100);
// set the outline color to pure blue:
stroke(0,0,255);
// draw the following shapes without any fill color:
noFill();
// draw a ellipse:
ellipse(100,100,20,20);

/* RELATIONS
 *
 * Instead of using fixed values, we use variables
 * to formulate relations. In this example a structure
 * based on two vertical parallel lines with a circle 
 * in between is formulated. 
 *
 * Frederic Gmeiner 2011
 */
 
// variable to store the radius of the circle:
int rad = 40;
// variables to store the x and y position of the structure:
int startPointX = 100;
int startPointY =100;

size(400,400);

// left line starts at the defined values and has a length of 80px:
line(startPointX, startPointY, startPointX, startPointY+80);

// the ellipse in between the two lines has a radius of "rad",
// so the width and hight is "2*rad". Since ellipses have their
// origin in the middle in processing, we need to add the radius
// to our "startPointX" value to have it centered in between the lines:
ellipse(startPointX+rad, startPointY+40, 2*rad, 2*rad);

// the right line is set in relation to the width of the circle: 
line(startPointX+(2*rad), startPointY, startPointX+(2*rad), startPointY+80);

/* FUNCTIONS
 * 
 * Here we define a custom function ("crossFunction()") which draws a 
 * cross onto the screen.
 * It takes the parameters: X value, Y value and the size.
 * Also the continuous mode is introduced, which 
 * uses the processing functions setup() and draw().
 * Via the pre-defined variables "mouseX" and "mouseY" we
 * can access the current mouse position.
 *
 * Frederic Gmeiner 2011
 */

// the setup() function is called everytime the program
// starts once.
void setup(){
  size(400,400);
}

// the draw() function is the main loop function of your program:
// after every operation in the draw function has been 
// called, the draw function is called again. this
// goes on until the program quits.
void draw(){
  background(255);
  crossFunction(mouseX,mouseY,10);
}

// this is the definition of the custom function "crossFunction()":
void crossFunction(int crossX, int crossY, int crossSize){
  line(crossX-crossSize/2, crossY-crossSize/2, crossX+crossSize/2, crossY+crossSize/2);
  line(crossX+crossSize/2, crossY-crossSize/2, crossX-crossSize/2, crossY+crossSize/2);
}

/* MOVEMENT & CONDITIONS
 * 
 * By changing a variable during the runtime, 
 * we can alter the condition of the program.
 * Here we increment an integer variable
 * each time draw() is called. This variable is
 * used for the x-position of a line, thus
 * creating the illusion of a continuous movement
 * from left to right. 
 * Via the "if" and "else" branches we can react
 * to different states of the program and alter it
 * accordingly.
 *
 * Frederic Gmeiner 2011
 */

// variable to store the x-position of the line:
int lineX = 0;

void setup(){
  size(500,300);
}

void draw(){
  // clear the background
  background(255);
  
  // if the x position of the line is larger than the middle of the screen:
  if(lineX > width/2){
     // change the stroke colour to pure red:
    stroke(255,0,0);
  // if the x position of the line is smaller than the middle of the screen:
  }else{
    // set the stroke coulour to black:
    stroke(0,0,0);
  }
  
  // draw a vertical line from the top (0) to the bottom ("height") at
  // the current x-position:
  line(lineX,0,lineX,height);
  
  // increment the lineX variable by 1 
  // (you could also simply write "lineX++")
  lineX = lineX+1;
  
  // use the "println()" function to show the value of variables 
  // in the console. this is helpful for debugging.
  println(lineX);
}

/* BOUNCING LINE
 * 
 * This is a modification of the previous sketch
 * so that the line will bounce off the left and
 * right borders of the window. Notice the introduction
 * of the variable "speed" to control the speed and 
 * direction of the moving line.
 *
 * Frederic Gmeiner 2011
 */
 
// variable to hold the currect x position of the line
int lineX = 0;
// variable that controls the speed and direction
int speed =1;

void setup(){
  size(500,300);
}

void draw(){
  background(204);
  
   // if the x position of the line exceeds the right border of the window:
   // change the direction by setting the speed to a negative value
  if(lineX > width){
    speed = -1; 
  }
  // accordingly set the speed to a positive value as soon as the line touches 
  // the left border.
  if(lineX < 0 ){
    speed = 1;
  }
  
  // here the new x position is calculated by adding the speed onto the 
  // current x position. if speed is -1, lineX decreases. if speed is 1, lineX 
  // increases.
  lineX = lineX + speed;
  
  // draw the line based on the calculated x position:
  line(lineX,0,lineX,height);
}

/* BOUNCING LINE ADVANCED
 * 
 * Notice the introduction of the variables 
 * "speed" and "direction to control the speed 
 * and direction of the moving line inependently.
 *
 * Frederic Gmeiner 2011
 */

// variable to hold the currect x position of the line
float lineX = 0;
// variable that controls the speed
float speed = 2.3f;
// variable that controls the direction
// (either 1 or -1)
int direction = 1;


void setup(){
  size(300,300);
}

void draw(){
  
  background(204);
  
   // if the x position of the line exceeds the right border of the window
   // OR (||) the x position of the line exceeds the left border 
   // of the window:
  if(lineX > width || lineX < 0){
    direction = direction * -1; // change the direction 
  }
  
  // here the new x-position is calculated by adding the speed and direction onto the 
  // current x-position. if direction is -1, lineX decreases. if direction is 1, lineX 
  // increases:
  lineX = lineX + (speed * direction);
  
  // draw the line based on the calculated x-position:
  line(lineX,0,lineX,height);
}

/* A FRIGHTENED SQUARE
 * 
 * A little sketch to illustrate the random() function
 * and a more complex boolean equation to check whether
 * the mouse pointer is inside a rectangular shape.
 *
 * Frederic Gmeiner 2011
 */

// the x an y positions of the square:
float xPos = 200f;
float yPos = 200f;
// the width and height of the square:
int s = 20;

void setup(){
   size(400,400);
}

void draw(){
  background(204);
  
  // Here we check if the position of the mouse is somewhere inside of the
  // square. To know this, all these four contitions must be true ( && ):
  if( mouseX > xPos && mouseX < xPos + s && mouseY > yPos && mouseY < yPos + s){
      xPos += random(-2,3); // add a random value between -2 and 3 to the xPos
      yPos += random(-2,3);
      fill(40);
  }else{
    fill(255);
  }
  
  // finally draw the square: 
  rect(xPos, yPos, s, s);

}

/* DYNAMIC DISTRIBUTION
 * 
 * This sketch demonstrates the usage of
 * a for-loop for calculating and drawing
 * a certain number of ellipses according
 * to the changing mouseX position.
 *
 * Frederic Gmeiner 2011
 */


// the number of circles:
int numCircles = 15;

void setup(){
  size(500,200);
  stroke(255);
  fill(150);
  smooth();
}

void draw(){
  background(255);
  
  // calculate the distance between the circles
  // so that in total it results in the mouseX position:
  float distance = mouseX / (numCircles-1);
  
  // for every circle (numCircles) calculate the xPos
  // and draw it onto the screen:
  for(int i=0; i < numCircles; i++){
    float xPos = i*distance;
    ellipse(xPos,100,10,10); 
  }
}

/* Random points in an array
 * 
 * This demonstrates how to store values in 
 * an array. This is useful when working with
 * many things which share the same parameters.
 * Here we use two arrays to store the coordinates
 * of circles.
 *
 * Frederic Gmeiner 2011
 */

// total number of circles:
int numCircles = 40;

// the radius of the circles 
float rad = 20f;

// initializing two arrays for storing the x and y positions
// of the circles:
float[] xPositions = new float[numCircles];
float[] yPositions = new float[numCircles];


void setup(){
  
  size(500,500);
  smooth();
  noStroke();
  fill(150);
  
  // iterating over the arrays to set each position with 
  // a random value based on the window size:
  for(int i=0; i< numCircles; i++){
    xPositions[i] = random(0,width);
    yPositions[i] = random(0,height);
  }
}


void draw(){

  background(204);
  
  // again iterating over the arrays. but this time we only 
  // get the x and y coordinates to draw the circles:
  for(int i=0; i< numCircles; i++){
    ellipse(xPositions[i], yPositions[i], rad, rad);
  }

}

/* PULSING CIRCLES
 * 
 * Mofification of the example above so that
 * the circles will shrink and grow by using
 * a sinewave.
 *
 * Frederic Gmeiner 2011
 */

int numCircles = 40;
float rad = 20f;

// initial angle of 0. this will increase during the
// runtime of the programm and will be used to calculate
// the sine based on this value in order so modify the size of
// circles.
float angle = 0.0f;
// how fast the angle will increase is defined by the speed variable:
float speed = 0.01;

float[] xPositions = new float[numCircles];
float[] yPositions = new float[numCircles];


void setup(){
  size(500,500);
  smooth();
  noStroke();
  fill(150);
  
  for(int i=0; i< numCircles; i++){
    xPositions[i] = random(0,width);
    yPositions[i] = random(0,height);
  }
}


void draw(){

  background(204);
  // add the speed value to the angle:
  angle += speed;
  
  // calculate the diamater by calculating the sine value of the
  // angle and scaling it up by the value of 30. This is necessary since
  // the sin() funtion returns only values between -1 and 1.
  float diameter = sin(angle)*30;

  for(int i=0; i< numCircles; i++){
    // draw the circles:
    ellipse(xPositions[i], yPositions[i], diameter, diameter);
  }
}

/* ELLIPTICAL MOTION
 * 
 * A little demonstration of the sine and 
 * cosine relation.
 *
 * Frederic Gmeiner 2011
 */

float speed = 0.1f;  // frequency
float angle = 0.0f; // you might also call it theta


void draw(){
  
  background(200);
  angle += speed;
  
  point(50,50);
  point(50+ (cos(angle)/2*50), 50+ (sin(angle)*50));

}

int degr= 0;

println("0° Degrees:");
println("PI:" + radians(degr) / PI);
println("sine:" + round(sin(radians(degr))) + "\n");

degr= 90;
println("90° Degrees:");
println("PI:" + radians(degr) / PI);
println("sine:" + round(sin(radians(degr))) + "\n");

degr= 180;
println("180° Degrees:");
println("PI:" + radians(degr) / PI);
println("sine:" + round(sin(radians(degr))) + "\n");

degr= 270;
println("270° Degrees:");
println("PI:" + radians(degr) / PI);
println("sine:" + round(sin(radians(degr))) + "\n");

degr= 360;
println("360° Degrees:");
println("PI:" + radians(degr) / PI);
println("sine:" + round(sin(radians(degr))) + "\n");