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-rw-r--r--frontend/2d/_collisions/rectangle_rectangle.html1
-rw-r--r--frontend/2d/_collisions/rectangle_rectangle.html.content1
-rwxr-xr-xfrontend/2d/_collisions/rectangle_rectangle/dist/output.wasmbin51583 -> 55475 bytes
-rw-r--r--frontend/2d/_collisions/rectangle_rectangle/main.cpp68
4 files changed, 64 insertions, 6 deletions
diff --git a/frontend/2d/_collisions/rectangle_rectangle.html b/frontend/2d/_collisions/rectangle_rectangle.html
index 8b10ab6..51cac77 100644
--- a/frontend/2d/_collisions/rectangle_rectangle.html
+++ b/frontend/2d/_collisions/rectangle_rectangle.html
@@ -120,6 +120,7 @@ Vector2 getNormalToLineSegment(LineSegment* segment) {
<h2>References</h2>
<ul>
<li><a href="https://dyn4j.org/2010/01/sat/">Great SAT Explanation</a></li>
+ <li><a href="https://www.gamedev.net/forums/topic/588070-seperating-axis-theorem---how-to-resolve-contact-points/">SAT Finding Collision Points</a></li>
</ul>
</footer>
</section>
diff --git a/frontend/2d/_collisions/rectangle_rectangle.html.content b/frontend/2d/_collisions/rectangle_rectangle.html.content
index b994f45..2cc5847 100644
--- a/frontend/2d/_collisions/rectangle_rectangle.html.content
+++ b/frontend/2d/_collisions/rectangle_rectangle.html.content
@@ -70,6 +70,7 @@ Vector2 getNormalToLineSegment(LineSegment* segment) {
<h2>References</h2>
<ul>
<li><a href="https://dyn4j.org/2010/01/sat/">Great SAT Explanation</a></li>
+ <li><a href="https://www.gamedev.net/forums/topic/588070-seperating-axis-theorem---how-to-resolve-contact-points/">SAT Finding Collision Points</a></li>
</ul>
</footer>
</section>
diff --git a/frontend/2d/_collisions/rectangle_rectangle/dist/output.wasm b/frontend/2d/_collisions/rectangle_rectangle/dist/output.wasm
index c13cd15..66f6ab8 100755
--- a/frontend/2d/_collisions/rectangle_rectangle/dist/output.wasm
+++ b/frontend/2d/_collisions/rectangle_rectangle/dist/output.wasm
Binary files differ
diff --git a/frontend/2d/_collisions/rectangle_rectangle/main.cpp b/frontend/2d/_collisions/rectangle_rectangle/main.cpp
index 6b7b8dd..9f6db62 100644
--- a/frontend/2d/_collisions/rectangle_rectangle/main.cpp
+++ b/frontend/2d/_collisions/rectangle_rectangle/main.cpp
@@ -112,6 +112,19 @@ struct Rectangle {
body = previousBody;
}
+ Vector2 getPoint(int index) {
+ switch (index) {
+ case 0: return shape.model * Vector2 { -width / 2.f, -height / 2.f };
+ case 1: return shape.model * Vector2 { -width / 2.f, height / 2.f };
+ case 2: return shape.model * Vector2 { width / 2.f, height / 2.f };
+ case 3: return shape.model * Vector2 { width / 2.f, -height / 2.f };
+ default: {
+ printf("Unable to find point: index=%d", index);
+ return Vector2();
+ }
+ }
+ }
+
// Note that these getters are needlessly verbose for demonstration's sake
void getPoints(Vector2* pointList) {
Vector2 botLeft = shape.model * Vector2 { -width / 2.f, -height / 2.f };
@@ -148,7 +161,6 @@ struct Rectangle {
}
};
-
EM_BOOL onPlayClicked(int eventType, const EmscriptenMouseEvent* mouseEvent, void* userData);
EM_BOOL onStopClicked(int eventType, const EmscriptenMouseEvent* mouseEvent, void* userData);
@@ -236,6 +248,8 @@ IntersectionResult getIntersection(Rectangle* first, Rectangle* second) {
float32 minOverlap = FLT_MAX;
Vector2 minOverlapAxis;
+ bool minOverlapAxisIsFromFirstRectangle = true;
+
for (int i = 0; i < 4; i++) {
Vector2 normal = firstNormals[i];
@@ -251,6 +265,7 @@ IntersectionResult getIntersection(Rectangle* first, Rectangle* second) {
if (overlap < minOverlap) {
minOverlap = overlap;
minOverlapAxis = normal;
+ minOverlapAxisIsFromFirstRectangle = true;
}
}
@@ -268,6 +283,7 @@ IntersectionResult getIntersection(Rectangle* first, Rectangle* second) {
if (overlap < minOverlap) {
minOverlap = overlap;
minOverlapAxis = normal;
+ minOverlapAxisIsFromFirstRectangle = false;
}
}
@@ -275,6 +291,29 @@ IntersectionResult getIntersection(Rectangle* first, Rectangle* second) {
ir.relativeVelocity = first->body.velocity - second->body.velocity;
ir.collisionNormal = minOverlapAxis;
+ // Find the point of collision, this is kind of tricky, and it is just an approximation for now.
+ // At this point, we know that we intersected along the minOverlapAxis, but we do not know where
+ // that exactly happened. To remedy this will, we create two parallel lines: one at the top of the
+ // normal area, and one at the bottom. For point on both of the Rectangles, we will check:
+ // (1) if it is between these two planes
+ // (2) if, for that rectangle, it is the closest point to the original normal vector
+ // (3) or if it is equally distant from normal vector as another point (then this is a "flat" collision)
+ //
+ // The collision point MUST be between these two planes. We can then say the corner/face of the non-monoverlapAxis
+ // Rectangle is the collision point. This enables us to then solve for their respective points of application fairly
+ // easily. If the collision "point" is an entire face, we make the collision point be the center point.
+ //
+ Vector2 topPlane;
+ Vector2 bottomPlane;
+
+ for (int p = 0; p < 4; p++) {
+ Vector2 point = minOverlapAxisIsFromFirstRectangle ? first->getPoint(p) : second->getPoint(p);
+
+ }
+
+ ir.firstPointOfApplication = Vector2();
+ ir.secondPointOfApplication = Vector2();
+
return ir;
}
@@ -289,14 +328,14 @@ void resolveCollision(Rigidbody* first, Rigidbody* second, IntersectionResult* i
float32 cofOfRestition = (first->cofOfRestition + second->cofOfRestition) / 2.f;
float32 numerator = (relativeVelocity * (-1 * (1.f + cofOfRestition))).dot(collisionNormal);
float32 linearDenomPart = collisionNormal.dot(collisionNormal * (1.f / first->mass + 1.f / second->mass));
- //float32 rotationalDenomPart = (firstPerpNorm * firstPerpNorm) / first->momentOfInertia + (sndPerpNorm * sndPerpNorm) / second->momentOfInertia;
+ float32 rotationalDenomPart = (firstPerpNorm * firstPerpNorm) / first->momentOfInertia + (sndPerpNorm * sndPerpNorm) / second->momentOfInertia;
- float32 impulseMagnitude = numerator / (linearDenomPart);// + rotationalDenomPart);
+ float32 impulseMagnitude = numerator / (linearDenomPart + rotationalDenomPart);
first->velocity = first->velocity + (collisionNormal * (impulseMagnitude / first->mass));
second->velocity = second->velocity - (collisionNormal * (impulseMagnitude / second->mass));
- //first->rotationalVelocity = first->rotationalVelocity + firstPerp.dot(collisionNormal * impulseMagnitude) / first->momentOfInertia;
- //second->rotationalVelocity = second->rotationalVelocity - secondPerp.dot(collisionNormal * impulseMagnitude) / second->momentOfInertia;
+ first->rotationalVelocity = first->rotationalVelocity + firstPerp.dot(collisionNormal * impulseMagnitude) / first->momentOfInertia;
+ second->rotationalVelocity = second->rotationalVelocity - secondPerp.dot(collisionNormal * impulseMagnitude) / second->momentOfInertia;
}
void update(float32 deltaTimeSeconds, void* userData) {
@@ -305,7 +344,7 @@ void update(float32 deltaTimeSeconds, void* userData) {
rectangleList[r].update(deltaTimeSeconds);
}
- // Check collisions
+ // Check collisions with other rectangles
for (int i = 0; i < 4; i++) {
Rectangle* first = &rectangleList[i];
for (int j = i + 1; j < 4; j++) {
@@ -348,6 +387,23 @@ void update(float32 deltaTimeSeconds, void* userData) {
second->update(frameTimeRemaining);
}
}
+
+ // Check collisions with walls
+ for (int r = 0; r < 4; r++) {
+ Rectangle* rect = &rectangleList[r];
+ if (rect->body.position.x <= 0.f) {
+ rect->body.velocity = rect->body.velocity - Vector2 { 1.f, 0.f } * (2 * (rect->body.velocity.dot(Vector2 { 1.f, 0.f })));
+ }
+ if (rect->body.position.y <= 0.f) {
+ rect->body.velocity = rect->body.velocity - Vector2 { 0.f, 1.f } * (2 * (rect->body.velocity.dot(Vector2 { 0.f, 1.f })));
+ }
+ if (rect->body.position.x >= 640.f) {
+ rect->body.velocity = rect->body.velocity - Vector2 { -1.f, 0.f } * (2 * (rect->body.velocity.dot(Vector2{ -1.f, 0.f })));
+ }
+ if (rect->body.position.y >= 480.f) {
+ rect->body.velocity = rect->body.velocity - Vector2 { 0.f, -1.f } * (2 * (rect->body.velocity.dot(Vector2 { 0.f, -1.f }))) ;
+ }
+ }
// Renderer
renderer.render();