GameAILab1/Boid.pde

/// In this file, you will have to implement seek and waypoint-following
/// The relevant locations are marked with "TODO"
import java.util.*;
class Crumb
{
  PVector position;
  Crumb(PVector position)
  {
    this.position = position;
  }
  void draw()
  {
    fill(255);
    noStroke();
    circle(this.position.x, this.position.y, CRUMB_SIZE);
  }
}

class Boid
{
  Crumb[] crumbs = {};
  int last_crumb;
  float acceleration;
  float rotational_acceleration;
  KinematicMovement kinematic;
  PVector target;

  Boid(PVector position, float heading, float max_speed, float max_rotational_speed, float acceleration, float rotational_acceleration)
  {
    this.kinematic = new KinematicMovement(position, heading, max_speed, max_rotational_speed);
    this.last_crumb = millis();
    this.acceleration = acceleration;
    this.rotational_acceleration = rotational_acceleration;
  }

  void update(float dt)
  {
    
    if (waypoints != null) {
      for (int i = 0; i<waypoints.size(); i++)
      {
        text(i, waypoints.get(i).x + 10, waypoints.get(i).y + 10);
      }
    }
    if (target != null)
    {
      // TODO: Implement seek here
      

      //This makes a vector with the direction our boid needs to go to
      PVector direction = PVector.sub(target, kinematic.position);

      //atan2(direction.y, direction.x) will return the direction we need to go in radians

      //print direction we need to go and the direction we are facing right now
      //println(atan2(direction.y, direction.x) + " " + normalize_angle_left_right(kinematic.getHeading()));

      float directionalThreshold = .1;
      float angleToTarget = normalize_angle_left_right(atan2(direction.y, direction.x) - normalize_angle_left_right(kinematic.getHeading()));
      float arrivalThreshold = 60.0;

      //This just draws a circle for visual debugging purposes
      circle(target.x, target.y, 3);

      //prints the angle to the target
      //println(angleToTarget);

      //if the angle is larger than the threshold in the positive direction, rotate counterclockwise
      if (angleToTarget >= .1) {
       //println("positive angle");
        kinematic.increaseSpeed(0.0, 2);


        //if the angle is smaller than the threshold in the negative direction, rotate clockwise
      } else if (angleToTarget < -.1) {
        kinematic.increaseSpeed(0.0, -1);

        //if the angle is within our threshold, stop our rotational velocity by rotating opposite
      } else if (directionalThreshold > angleToTarget) {

        if (kinematic.getRotationalVelocity() > 0) {
          kinematic.increaseSpeed(0.0, -1);
        } else if (kinematic.getRotationalVelocity() < 0) {
          kinematic.increaseSpeed(0.0, 1);

        }
      }


      //Sometimes our Boid just goes and does weird things and I don't know why

      //if the target is outside its arrival threshold, accelerate.
      //if the target is inside its arrival threshold, accelerate backwards until the speed is 0.
      if (direction.mag() > arrivalThreshold) {
        //println("main if");
        kinematic.increaseSpeed(.5, 0);
      } else if (direction.mag() < arrivalThreshold) {
        //Need more specific code here to handle arrivals correctly

        if (kinematic.getSpeed() < 40 && direction.mag() > 30) {
          //println("if 1");
          kinematic.increaseSpeed(1, 0);
        } else if (kinematic.getSpeed() < 20 && direction.mag() > 15) {
          //println("if .75");
          kinematic.increaseSpeed(.75, 0);
        } else if (kinematic.getSpeed() < 10 && direction.mag() > 5) {
          //println("if .5");
          kinematic.increaseSpeed(.5, 0);
        } else if (kinematic.getSpeed() < 5 && direction.mag() < 5) {
          //println("if -kin");
          //This should ensure that the boid's speed can be dropped to exactly 0 so we don't have stuttering

          kinematic.increaseSpeed(-kinematic.getSpeed(), 0);
        } else {
          //println("else");
          kinematic.increaseSpeed(-1, 0);
        }
      }


      //drawing a line for testing purposes
      //line(kinematic.position.x, kinematic.position.y, kinematic.position.x + direction.x, kinematic.position.y + direction.y);
    }

    // place crumbs, do not change
    if (LEAVE_CRUMBS && (millis() - this.last_crumb > CRUMB_INTERVAL))
    {
      this.last_crumb = millis();
      this.crumbs = (Crumb[])append(this.crumbs, new Crumb(this.kinematic.position));
      if (this.crumbs.length > MAX_CRUMBS)
        this.crumbs = (Crumb[])subset(this.crumbs, 1);
    }

    // do not change
    this.kinematic.update(dt);

    draw();
  }

  void draw()
  {
    for (Crumb c : this.crumbs)
    {
      c.draw();
    }

    fill(255);
    noStroke();
    float x = kinematic.position.x;
    float y = kinematic.position.y;
    float r = kinematic.heading;
    circle(x, y, BOID_SIZE);
    // front
    float xp = x + BOID_SIZE*cos(r);
    float yp = y + BOID_SIZE*sin(r);

    // left
    float x1p = x - (BOID_SIZE/2)*sin(r);
    float y1p = y + (BOID_SIZE/2)*cos(r);

    // right
    float x2p = x + (BOID_SIZE/2)*sin(r);
    float y2p = y - (BOID_SIZE/2)*cos(r);
    triangle(xp, yp, x1p, y1p, x2p, y2p);
  }

  void seek(PVector target)
  {
    this.target = target;
  }
int count = 0;
 
  //void follow(ArrayList<PVector> waypoints)
  //{
     
  //  //println("func count " + count);
  //  if(count > waypoints.size() - 1){
  //  this.target = waypoints.get(0);
  //  return;
  //  }
  //  else {
  //  // TODO: change to follow *all* waypoints
  //  println("count " + count);
  //  this.target = waypoints.get(count);
  //  PVector temp = waypoints.remove(count);
  //  count++;
  //  //count--;
    
  //  follow(waypoints);
  //  }
    
  //}
  void follow(ArrayList<PVector> waypoints)
  {
    if(waypoints.size() == 0) return;
    println("vector " + waypoints);   
    println("reverse vector " + waypoints);
    int count = 0;
    PVector stop = waypoints.get(0);
    this.seek(stop);
    
    
    PVector temp = waypoints.remove(0);
    println("temp vector " + waypoints);
    //follow(waypoints);
   
    //this.target = waypoints.get(0);
     //do{
       
       
     // println("in while " + count);
     ////this.target = waypoints.get(count);
     //this.target = waypoints.get(count);
     //if(PVector.sub(this.target,this.kinematic.position).mag() < 40){
     //   count++;
     //}
    
  
     //}while(count < waypoints.size());
    //count++;
    //for(int i = 1; i < waypoints.size(); i++){
    //    println("dist " + PVector.sub(this.target,this.kinematic.position).mag());
    //    if(PVector.sub(this.target,this.kinematic.position).mag() < 40){
    //    this.seek(waypoints.get(i));
    //    this.target = waypoints.get(i);
    //    }
    
    }

}
Provided framework, no changes 2022-09-17 02:45:09 -07:00			`/// In this file, you will have to implement seek and waypoint-following`
			`/// The relevant locations are marked with "TODO"`
navmesh 2022-10-30 18:27:14 -07:00			`import java.util.*;`
Provided framework, no changes 2022-09-17 02:45:09 -07:00			`class Crumb`
			`{`
			`PVector position;`
			`Crumb(PVector position)`
			`{`
add waypoints code 2022-09-26 22:03:24 -07:00			`this.position = position;`
Provided framework, no changes 2022-09-17 02:45:09 -07:00			`}`
			`void draw()`
			`{`
add waypoints code 2022-09-26 22:03:24 -07:00			`fill(255);`
			`noStroke();`
			`circle(this.position.x, this.position.y, CRUMB_SIZE);`
Provided framework, no changes 2022-09-17 02:45:09 -07:00			`}`
			`}`

			`class Boid`
			`{`
add waypoints code 2022-09-26 22:03:24 -07:00			`Crumb[] crumbs = {};`
			`int last_crumb;`
			`float acceleration;`
			`float rotational_acceleration;`
			`KinematicMovement kinematic;`
			`PVector target;`

			`Boid(PVector position, float heading, float max_speed, float max_rotational_speed, float acceleration, float rotational_acceleration)`
			`{`
			`this.kinematic = new KinematicMovement(position, heading, max_speed, max_rotational_speed);`
			`this.last_crumb = millis();`
			`this.acceleration = acceleration;`
			`this.rotational_acceleration = rotational_acceleration;`
			`}`

			`void update(float dt)`
			`{`
navmesh 2022-10-30 18:27:14 -07:00
			`if (waypoints != null) {`
			`for (int i = 0; i<waypoints.size(); i++)`
			`{`
			`text(i, waypoints.get(i).x + 10, waypoints.get(i).y + 10);`
			`}`
			`}`
add waypoints code 2022-09-26 22:03:24 -07:00			`if (target != null)`
			`{`
			`// TODO: Implement seek here`
navmesh 2022-10-30 18:27:14 -07:00
add waypoints code 2022-09-26 22:03:24 -07:00

			`//This makes a vector with the direction our boid needs to go to`
			`PVector direction = PVector.sub(target, kinematic.position);`

			`//atan2(direction.y, direction.x) will return the direction we need to go in radians`

			`//print direction we need to go and the direction we are facing right now`
			`//println(atan2(direction.y, direction.x) + " " + normalize_angle_left_right(kinematic.getHeading()));`

			`float directionalThreshold = .1;`
			`float angleToTarget = normalize_angle_left_right(atan2(direction.y, direction.x) - normalize_angle_left_right(kinematic.getHeading()));`
			`float arrivalThreshold = 60.0;`

			`//This just draws a circle for visual debugging purposes`
			`circle(target.x, target.y, 3);`

			`//prints the angle to the target`
			`//println(angleToTarget);`

			`//if the angle is larger than the threshold in the positive direction, rotate counterclockwise`
			`if (angleToTarget >= .1) {`
navmesh 2022-10-30 18:27:14 -07:00			`//println("positive angle");`
add waypoints code 2022-09-26 22:03:24 -07:00			`kinematic.increaseSpeed(0.0, 2);`

add do-while waypoints 2022-09-26 22:29:18 -07:00
add boid pathfinding 2022-09-21 02:04:57 -07:00			`//if the angle is smaller than the threshold in the negative direction, rotate clockwise`
add waypoints code 2022-09-26 22:03:24 -07:00			`} else if (angleToTarget < -.1) {`
			`kinematic.increaseSpeed(0.0, -1);`

add boid pathfinding 2022-09-21 02:04:57 -07:00			`//if the angle is within our threshold, stop our rotational velocity by rotating opposite`
add waypoints code 2022-09-26 22:03:24 -07:00			`} else if (directionalThreshold > angleToTarget) {`

			`if (kinematic.getRotationalVelocity() > 0) {`
			`kinematic.increaseSpeed(0.0, -1);`
			`} else if (kinematic.getRotationalVelocity() < 0) {`
			`kinematic.increaseSpeed(0.0, 1);`
add do-while waypoints 2022-09-26 22:29:18 -07:00
add boid pathfinding 2022-09-21 02:04:57 -07:00			`}`
add waypoints code 2022-09-26 22:03:24 -07:00			`}`



			`//Sometimes our Boid just goes and does weird things and I don't know why`

			`//if the target is outside its arrival threshold, accelerate.`
			`//if the target is inside its arrival threshold, accelerate backwards until the speed is 0.`
			`if (direction.mag() > arrivalThreshold) {`
			`//println("main if");`
			`kinematic.increaseSpeed(.5, 0);`
			`} else if (direction.mag() < arrivalThreshold) {`
			`//Need more specific code here to handle arrivals correctly`

			`if (kinematic.getSpeed() < 40 && direction.mag() > 30) {`
			`//println("if 1");`
			`kinematic.increaseSpeed(1, 0);`
			`} else if (kinematic.getSpeed() < 20 && direction.mag() > 15) {`
			`//println("if .75");`
			`kinematic.increaseSpeed(.75, 0);`
			`} else if (kinematic.getSpeed() < 10 && direction.mag() > 5) {`
			`//println("if .5");`
			`kinematic.increaseSpeed(.5, 0);`
			`} else if (kinematic.getSpeed() < 5 && direction.mag() < 5) {`
			`//println("if -kin");`
			`//This should ensure that the boid's speed can be dropped to exactly 0 so we don't have stuttering`

			`kinematic.increaseSpeed(-kinematic.getSpeed(), 0);`
			`} else {`
navmesh 2022-10-30 18:27:14 -07:00			`//println("else");`
add waypoints code 2022-09-26 22:03:24 -07:00			`kinematic.increaseSpeed(-1, 0);`
add boid pathfinding 2022-09-21 02:04:57 -07:00			`}`
add waypoints code 2022-09-26 22:03:24 -07:00			`}`



			`//drawing a line for testing purposes`
			`//line(kinematic.position.x, kinematic.position.y, kinematic.position.x + direction.x, kinematic.position.y + direction.y);`
			`}`

			`// place crumbs, do not change`
			`if (LEAVE_CRUMBS && (millis() - this.last_crumb > CRUMB_INTERVAL))`
			`{`
			`this.last_crumb = millis();`
			`this.crumbs = (Crumb[])append(this.crumbs, new Crumb(this.kinematic.position));`
			`if (this.crumbs.length > MAX_CRUMBS)`
			`this.crumbs = (Crumb[])subset(this.crumbs, 1);`
			`}`

			`// do not change`
			`this.kinematic.update(dt);`

			`draw();`
			`}`

			`void draw()`
			`{`
			`for (Crumb c : this.crumbs)`
			`{`
			`c.draw();`
			`}`

			`fill(255);`
			`noStroke();`
			`float x = kinematic.position.x;`
			`float y = kinematic.position.y;`
			`float r = kinematic.heading;`
			`circle(x, y, BOID_SIZE);`
			`// front`
			`float xp = x + BOID_SIZE*cos(r);`
			`float yp = y + BOID_SIZE*sin(r);`

			`// left`
			`float x1p = x - (BOID_SIZE/2)*sin(r);`
			`float y1p = y + (BOID_SIZE/2)*cos(r);`

			`// right`
			`float x2p = x + (BOID_SIZE/2)*sin(r);`
			`float y2p = y - (BOID_SIZE/2)*cos(r);`
			`triangle(xp, yp, x1p, y1p, x2p, y2p);`
			`}`

			`void seek(PVector target)`
			`{`
			`this.target = target;`
			`}`
			`int count = 0;`

			`//void follow(ArrayList<PVector> waypoints)`
			`//{`
Provided framework, no changes 2022-09-17 02:45:09 -07:00
add waypoints code 2022-09-26 22:03:24 -07:00			`// //println("func count " + count);`
			`// if(count > waypoints.size() - 1){`
			`// this.target = waypoints.get(0);`
			`// return;`
			`// }`
			`// else {`
			`// // TODO: change to follow all waypoints`
			`// println("count " + count);`
			`// this.target = waypoints.get(count);`
			`// PVector temp = waypoints.remove(count);`
			`// count++;`
			`// //count--;`

			`// follow(waypoints);`
			`// }`

			`//}`
			`void follow(ArrayList<PVector> waypoints)`
			`{`
navmesh 2022-10-30 18:27:14 -07:00			`if(waypoints.size() == 0) return;`
			`println("vector " + waypoints);`
			`println("reverse vector " + waypoints);`
add do-while waypoints 2022-09-26 22:29:18 -07:00			`int count = 0;`
navmesh 2022-10-30 18:27:14 -07:00			`PVector stop = waypoints.get(0);`
			`this.seek(stop);`




			`PVector temp = waypoints.remove(0);`
			`println("temp vector " + waypoints);`
			`//follow(waypoints);`

add do-while waypoints 2022-09-26 22:29:18 -07:00			`//this.target = waypoints.get(0);`
navmesh 2022-10-30 18:27:14 -07:00			`//do{`
add do-while waypoints 2022-09-26 22:29:18 -07:00

navmesh 2022-10-30 18:27:14 -07:00			`// println("in while " + count);`
			`////this.target = waypoints.get(count);`
			`//this.target = waypoints.get(count);`
			`//if(PVector.sub(this.target,this.kinematic.position).mag() < 40){`
			`// count++;`
			`//}`
add do-while waypoints 2022-09-26 22:29:18 -07:00
navmesh 2022-10-30 18:27:14 -07:00
			`//}while(count < waypoints.size());`
			`//count++;`
			`//for(int i = 1; i < waypoints.size(); i++){`
			`// println("dist " + PVector.sub(this.target,this.kinematic.position).mag());`
			`// if(PVector.sub(this.target,this.kinematic.position).mag() < 40){`
			`// this.seek(waypoints.get(i));`
			`// this.target = waypoints.get(i);`
			`// }`
add do-while waypoints 2022-09-26 22:29:18 -07:00
navmesh 2022-10-30 18:27:14 -07:00			`}`

Provided framework, no changes 2022-09-17 02:45:09 -07:00			`}`