so this is my first post ever on asking a question about programming, so please be patient :)

For a little project in school I made a little physics class, handling collision. Although it worked out fine I still have a bug I couldn't figure out after some hours of searching and I still don't really know where the problem lies in. For the implementation we used the on Java based language Processing which is used for an introduction to programming and prototyping.

With the a left mouseclick I can spawn some balls which collide pixel-wise with a certain color on the screen. When colliding with a 90 degree corner they just fall through the obstacle. Sadly I can't post a screenshot because of my lack in reputation.

So my question is about what the problem is. Someone I asked said it could be a problem with the dot product I use for calculating the new mirrored velocity, but I couldn't find anything in that direction. I suspect the error lies somewhere in the part where the new velocity is calculated, in the update method of the PhysicsEntity class.

So thanks to everyone who is answering, I am grateful for every useful hint :)

Here is my code, it consists of three classes. I am going to post everything so you can run the code yourself. If you don't have processing you'll need to download it from http://processing.org/ in order to run the code sample below.

**Main.pde NOTE: This part is only an example for using my physics class.**

```
ArrayList<PhysicsEntity> entities = new ArrayList<PhysicsEntity>();
boolean mouseClicked = false;
boolean paused = false;
void setup()
{
size(800, 600);
background(0);
frameRate(60);
}
void draw()
{
if (!paused)
{
clear();
float gameTime = 1 / frameRate;
loadPixels();
for (int x = 0; x < width; ++x)
{
for (int y = height - 100; y < height; ++y)
{
pixels[x + y * width] = color(0, 200, 0, 128);
}
}
for (int x = 0; x < width; ++x)
{
for (int y = 0; y < 20; ++y)
{
pixels[x + y * width] = color(0, 200, 0, 128);
}
}
for (int x = 0; x < 100; ++x)
{
for (int y = 0; y < height; ++y)
{
pixels[x + y * width] = color(0, 200, 0, 128);
}
}
for (int x = width - 100; x < width; ++x)
{
for (int y = 0; y < height; ++y)
{
pixels[x + y * width] = color(0, 200, 0, 128);
}
}
updatePixels();
if (mousePressed)
{
entities.add(new PhysicsEntity(new Vector2(width / 2, height / 2), new Vector2(random(-100, 100), random(-100, 100)), new Vector2(0.0f, 250.0f)));
}
for (int i = 0; i < entities.size(); ++i)
{
entities.get(i).update(gameTime);
entities.get(i).show();
}
}
}
```

**Vector2.pde NOTE: This class is just necessary for calculting things in the physics class.**

```
class Vector2
{
float a;
float b;
Vector2()
{
a = 0.0f;
b = 0.0f;
}
Vector2(float _a, float _b)
{
a = _a;
b = _b;
}
/* Return exact copy of the vector */
Vector2 Copy()
{
return new Vector2(a, b);
}
Vector2 Add(Vector2 vecB)
{
return new Vector2(a + vecB.a, b + vecB.b);
}
Vector2 Substract(Vector2 vecB)
{
return new Vector2(a - vecB.a, b - vecB.b);
}
/* Scale the vector by a scalar x */
Vector2 Scale(float x)
{
return new Vector2(a * x, b * x);
}
Vector2 Divide(float x)
{
return new Vector2(a / x, b / x);
}
float Dot(Vector2 vecB)
{
return (a * vecB.a + b * vecB.b);
}
float SqrLength()
{
return (pow(a, 2) + pow(b, 2));
}
float Length()
{
return sqrt(SqrLength());
}
boolean Equals(Vector2 vecB)
{
return (a != vecB.a || b != vecB.b) ? false : true;
}
}
Vector2 ZeroVector()
{
return new Vector2(0.0f, 0.0f);
}
```

**PhysicsEntity.pde NOTE: That's the class where actually failed.**

```
class PhysicsEntity
{
Vector2 m_Pos;
Vector2 m_PrevPos;
Vector2 m_Vel;
Vector2 m_Acc;
/* bouncyness in case of collision; gets multiplied with the velocity */
float m_fBouncyness = 1.0f;
color collisionKey = color(0, 200, 0, 128);
public PhysicsEntity(Vector2 _pos, Vector2 _vel, Vector2 _acc)
{
if (_vel == null)
_vel = new Vector2(0.0f, 0.0f);
m_Pos = new Vector2(_pos.a, _pos.b);
m_PrevPos = m_Pos;
m_Vel = _vel;
m_Acc = _acc;
}
public void update(float dt)
{
/* Euler Integration more accurate Version */
/* x = x + vt + 0.5*at^2 */
m_Pos = m_Pos.Add(m_Vel.Scale(dt)).Add(m_Acc.Scale(pow(dt, 2)).Scale(0.5));
/* v = v + at */
m_Vel = m_Vel.Add(m_Acc.Scale(dt));
/* Collision based on color key */
if (isCollidable(m_Pos.a, m_Pos.b, collisionKey))
{
float speed = m_Vel.Length();
if (speed > 0.0f)
{
/* normalized vector of velocity */
Vector2 velNorm = m_Vel.Divide(speed);
/* getting the floor normal */
Vector2 floorNorm = interp(m_Pos, m_PrevPos);
if (!floorNorm.Equals(ZeroVector()))
{
/* mirror velocity on floor normal vector */
/* C = A - (2 * B * (A dot B)) where A is original vector, B the mirror, C result. */
Vector2 mirVel = velNorm.Substract(floorNorm.Scale(2.0f).Scale(velNorm.Dot(floorNorm)));
/* caculate new velocity */
m_Vel = mirVel.Scale(speed).Scale(m_fBouncyness);
/* add to position to move out of collision */
m_Pos = m_Pos.Add(m_Vel.Scale(dt));
}
}
}
m_PrevPos = m_Pos;
}
public void show()
{
ellipse(m_Pos.a, m_Pos.b, 10, 10);
}
public Vector2 interp(Vector2 pos, Vector2 PrevPos)
{
/* Vector from previous position to current position */
Vector2 line = pos.Substract(PrevPos);
float iLength = line.Length();
Vector2 lineFraction = ZeroVector();
/* checks if there the is vectorlength greater zero that connects the current and the previous position */
if (iLength > 0.0f)
lineFraction = line.Divide(iLength);
/* loop from through positions between previous position and current position */
for (int i = 0; i <= iLength; ++i)
{
Vector2 normVec = getNormal(PrevPos.Add(lineFraction.Scale(i)), collisionKey);
if (!normVec.Equals(ZeroVector()))
return normVec;
}
return ZeroVector();
}
}
/* returns normal vector of a 2d landscape in a certain area */
public Vector2 getNormal(Vector2 pos, color col)
{
int area = 10;
/* prevent coordinates from being out of the window */
if (pos.a <= area || pos.a >= width - area || pos.b <= area || pos.b >= height - area)
return ZeroVector();
Vector2 avg = new Vector2();
float loops = 0;
/* loop through an area of pixels */
for (int x = -area; x <= area; ++x)
{
for (int y = -area; y <= area; ++y)
{
if (x*x + y*y <= area*area)
{
float sumX = pos.a + float(x);
float sumY = pos.b + float(y);
/* count collidable pixels in area */
if (isCollidable(sumX, sumY, col))
{
/* add up positions of these pixels */
avg.a += sumX;
avg.b += sumY;
++loops;
}
}
}
}
if (loops == 0)
return ZeroVector();
/* calculate average position */
avg = avg.Divide(loops);
/* calculate length of the vector from initial position to average position */
float avgLength = dist(avg.a, avg.b, pos.a, pos.b);
/* check if avgLenth is zero or in other words: if avg is equals to pos */
if (avgLength == 0.0f)
return ZeroVector();
/* calculate vector(connection vector) from initial position to average position */
Vector2 conVec = pos.Substract(avg);
/* return normalized connection vector */
return conVec.Divide(avgLength);
}
/* method to check if pixel on a certain position is collidable */
public boolean isCollidable(float pixelX, float pixelY, color col)
{
if (pixelX >= width || pixelX < 0 || pixelY >= height || pixelY < 0)
return false;
return pixels[int(pixelX) + int(pixelY) * width] == col;
}
```

**Edit1:**
So thanks to the friendly first replay I stripped my code by a few lines :) If there is still a problem with my post let me know!

lotof code for what should be a very simple task. I strongly recommend that you learn to prepare a minimal complete example, the shortest and simplest code that will reproduce the problem. It's a valuable skill that will make you a better programmer, and it makes our job of helping you much easier. – Beta Jan 19 '14 at 7:42