prosperon/source/engine/thirdparty/Chipmunk2D/src/cpShape.c

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2022-01-19 16:43:21 -06:00
/* Copyright (c) 2013 Scott Lembcke and Howling Moon Software
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*/
#include "chipmunk/chipmunk_private.h"
#include "chipmunk/chipmunk_unsafe.h"
#define CP_DefineShapeGetter(struct, type, member, name) \
CP_DeclareShapeGetter(struct, type, name){ \
cpAssertHard(shape->klass == &struct##Class, "shape is not a "#struct); \
return ((struct *)shape)->member; \
}
cpShape *
cpShapeInit(cpShape *shape, const cpShapeClass *klass, cpBody *body, struct cpShapeMassInfo massInfo)
{
shape->klass = klass;
shape->body = body;
shape->massInfo = massInfo;
shape->sensor = 0;
shape->e = 0.0f;
shape->u = 0.0f;
shape->surfaceV = cpvzero;
shape->type = 0;
shape->filter.group = CP_NO_GROUP;
shape->filter.categories = CP_ALL_CATEGORIES;
shape->filter.mask = CP_ALL_CATEGORIES;
shape->userData = NULL;
shape->space = NULL;
shape->next = NULL;
shape->prev = NULL;
return shape;
}
void
cpShapeDestroy(cpShape *shape)
{
if(shape->klass && shape->klass->destroy) shape->klass->destroy(shape);
}
void
cpShapeFree(cpShape *shape)
{
if(shape){
cpShapeDestroy(shape);
cpfree(shape);
}
}
cpSpace *
cpShapeGetSpace(const cpShape *shape)
{
return shape->space;
}
cpBody *
cpShapeGetBody(const cpShape *shape)
{
return shape->body;
}
void
cpShapeSetBody(cpShape *shape, cpBody *body)
{
cpAssertHard(!cpShapeActive(shape), "You cannot change the body on an active shape. You must remove the shape from the space before changing the body.");
shape->body = body;
}
cpFloat cpShapeGetMass(cpShape *shape){ return shape->massInfo.m; }
void
cpShapeSetMass(cpShape *shape, cpFloat mass){
cpBody *body = shape->body;
cpBodyActivate(body);
shape->massInfo.m = mass;
cpBodyAccumulateMassFromShapes(body);
}
cpFloat cpShapeGetDensity(cpShape *shape){ return shape->massInfo.m/shape->massInfo.area; }
void cpShapeSetDensity(cpShape *shape, cpFloat density){ cpShapeSetMass(shape, density*shape->massInfo.area); }
cpFloat cpShapeGetMoment(cpShape *shape){ return shape->massInfo.m*shape->massInfo.i; }
cpFloat cpShapeGetArea(cpShape *shape){ return shape->massInfo.area; }
cpVect cpShapeGetCenterOfGravity(cpShape *shape) { return shape->massInfo.cog; }
cpBB
cpShapeGetBB(const cpShape *shape)
{
return shape->bb;
}
cpBool
cpShapeGetSensor(const cpShape *shape)
{
return shape->sensor;
}
void
cpShapeSetSensor(cpShape *shape, cpBool sensor)
{
cpBodyActivate(shape->body);
shape->sensor = sensor;
}
cpFloat
cpShapeGetElasticity(const cpShape *shape)
{
return shape->e;
}
void
cpShapeSetElasticity(cpShape *shape, cpFloat elasticity)
{
cpAssertHard(elasticity >= 0.0f, "Elasticity must be positive.");
cpBodyActivate(shape->body);
shape->e = elasticity;
}
cpFloat
cpShapeGetFriction(const cpShape *shape)
{
return shape->u;
}
void
cpShapeSetFriction(cpShape *shape, cpFloat friction)
{
cpAssertHard(friction >= 0.0f, "Friction must be postive.");
cpBodyActivate(shape->body);
shape->u = friction;
}
cpVect
cpShapeGetSurfaceVelocity(const cpShape *shape)
{
return shape->surfaceV;
}
void
cpShapeSetSurfaceVelocity(cpShape *shape, cpVect surfaceVelocity)
{
cpBodyActivate(shape->body);
shape->surfaceV = surfaceVelocity;
}
cpDataPointer
cpShapeGetUserData(const cpShape *shape)
{
return shape->userData;
}
void
cpShapeSetUserData(cpShape *shape, cpDataPointer userData)
{
shape->userData = userData;
}
cpCollisionType
cpShapeGetCollisionType(const cpShape *shape)
{
return shape->type;
}
void
cpShapeSetCollisionType(cpShape *shape, cpCollisionType collisionType)
{
cpBodyActivate(shape->body);
shape->type = collisionType;
}
cpShapeFilter
cpShapeGetFilter(const cpShape *shape)
{
return shape->filter;
}
void
cpShapeSetFilter(cpShape *shape, cpShapeFilter filter)
{
cpBodyActivate(shape->body);
shape->filter = filter;
}
cpBB
cpShapeCacheBB(cpShape *shape)
{
return cpShapeUpdate(shape, shape->body->transform);
}
cpBB
cpShapeUpdate(cpShape *shape, cpTransform transform)
{
return (shape->bb = shape->klass->cacheData(shape, transform));
}
cpFloat
cpShapePointQuery(const cpShape *shape, cpVect p, cpPointQueryInfo *info)
{
cpPointQueryInfo blank = {NULL, cpvzero, INFINITY, cpvzero};
if(info){
(*info) = blank;
} else {
info = ␣
}
shape->klass->pointQuery(shape, p, info);
return info->distance;
}
cpBool
cpShapeSegmentQuery(const cpShape *shape, cpVect a, cpVect b, cpFloat radius, cpSegmentQueryInfo *info){
cpSegmentQueryInfo blank = {NULL, b, cpvzero, 1.0f};
if(info){
(*info) = blank;
} else {
info = ␣
}
cpPointQueryInfo nearest;
shape->klass->pointQuery(shape, a, &nearest);
if(nearest.distance <= radius){
info->shape = shape;
info->alpha = 0.0;
info->normal = cpvnormalize(cpvsub(a, nearest.point));
} else {
shape->klass->segmentQuery(shape, a, b, radius, info);
}
return (info->shape != NULL);
}
cpContactPointSet
cpShapesCollide(const cpShape *a, const cpShape *b)
{
struct cpContact contacts[CP_MAX_CONTACTS_PER_ARBITER];
struct cpCollisionInfo info = cpCollide(a, b, 0, contacts);
cpContactPointSet set;
set.count = info.count;
// cpCollideShapes() may have swapped the contact order. Flip the normal.
cpBool swapped = (a != info.a);
set.normal = (swapped ? cpvneg(info.n) : info.n);
for(int i=0; i<info.count; i++){
// cpCollideShapesInfo() returns contacts with absolute positions.
cpVect p1 = contacts[i].r1;
cpVect p2 = contacts[i].r2;
set.points[i].pointA = (swapped ? p2 : p1);
set.points[i].pointB = (swapped ? p1 : p2);
set.points[i].distance = cpvdot(cpvsub(p2, p1), set.normal);
}
return set;
}
cpCircleShape *
cpCircleShapeAlloc(void)
{
return (cpCircleShape *)cpcalloc(1, sizeof(cpCircleShape));
}
static cpBB
cpCircleShapeCacheData(cpCircleShape *circle, cpTransform transform)
{
cpVect c = circle->tc = cpTransformPoint(transform, circle->c);
return cpBBNewForCircle(c, circle->r);
}
static void
cpCircleShapePointQuery(cpCircleShape *circle, cpVect p, cpPointQueryInfo *info)
{
cpVect delta = cpvsub(p, circle->tc);
cpFloat d = cpvlength(delta);
cpFloat r = circle->r;
info->shape = (cpShape *)circle;
cpFloat r_over_d = d > 0.0f ? r/d : r;
info->point = cpvadd(circle->tc, cpvmult(delta, r_over_d)); // TODO: div/0
info->distance = d - r;
// Use up for the gradient if the distance is very small.
info->gradient = (d > MAGIC_EPSILON ? cpvmult(delta, 1.0f/d) : cpv(0.0f, 1.0f));
}
static void
cpCircleShapeSegmentQuery(cpCircleShape *circle, cpVect a, cpVect b, cpFloat radius, cpSegmentQueryInfo *info)
{
CircleSegmentQuery((cpShape *)circle, circle->tc, circle->r, a, b, radius, info);
}
static struct cpShapeMassInfo
cpCircleShapeMassInfo(cpFloat mass, cpFloat radius, cpVect center)
{
struct cpShapeMassInfo info = {
mass, cpMomentForCircle(1.0f, 0.0f, radius, cpvzero),
center,
cpAreaForCircle(0.0f, radius),
};
return info;
}
static const cpShapeClass cpCircleShapeClass = {
CP_CIRCLE_SHAPE,
(cpShapeCacheDataImpl)cpCircleShapeCacheData,
NULL,
(cpShapePointQueryImpl)cpCircleShapePointQuery,
(cpShapeSegmentQueryImpl)cpCircleShapeSegmentQuery,
};
cpCircleShape *
cpCircleShapeInit(cpCircleShape *circle, cpBody *body, cpFloat radius, cpVect offset)
{
circle->c = offset;
circle->r = radius;
cpShapeInit((cpShape *)circle, &cpCircleShapeClass, body, cpCircleShapeMassInfo(0.0f, radius, offset));
return circle;
}
cpShape *
cpCircleShapeNew(cpBody *body, cpFloat radius, cpVect offset)
{
return (cpShape *)cpCircleShapeInit(cpCircleShapeAlloc(), body, radius, offset);
}
cpVect
cpCircleShapeGetOffset(const cpShape *shape)
{
cpAssertHard(shape->klass == &cpCircleShapeClass, "Shape is not a circle shape.");
return ((cpCircleShape *)shape)->c;
}
cpFloat
cpCircleShapeGetRadius(const cpShape *shape)
{
cpAssertHard(shape->klass == &cpCircleShapeClass, "Shape is not a circle shape.");
return ((cpCircleShape *)shape)->r;
}
cpSegmentShape *
cpSegmentShapeAlloc(void)
{
return (cpSegmentShape *)cpcalloc(1, sizeof(cpSegmentShape));
}
static cpBB
cpSegmentShapeCacheData(cpSegmentShape *seg, cpTransform transform)
{
seg->ta = cpTransformPoint(transform, seg->a);
seg->tb = cpTransformPoint(transform, seg->b);
seg->tn = cpTransformVect(transform, seg->n);
cpFloat l,r,b,t;
if(seg->ta.x < seg->tb.x){
l = seg->ta.x;
r = seg->tb.x;
} else {
l = seg->tb.x;
r = seg->ta.x;
}
if(seg->ta.y < seg->tb.y){
b = seg->ta.y;
t = seg->tb.y;
} else {
b = seg->tb.y;
t = seg->ta.y;
}
cpFloat rad = seg->r;
return cpBBNew(l - rad, b - rad, r + rad, t + rad);
}
static void
cpSegmentShapePointQuery(cpSegmentShape *seg, cpVect p, cpPointQueryInfo *info)
{
cpVect closest = cpClosetPointOnSegment(p, seg->ta, seg->tb);
cpVect delta = cpvsub(p, closest);
cpFloat d = cpvlength(delta);
cpFloat r = seg->r;
cpVect g = cpvmult(delta, 1.0f/d);
info->shape = (cpShape *)seg;
info->point = (d ? cpvadd(closest, cpvmult(g, r)) : closest);
info->distance = d - r;
// Use the segment's normal if the distance is very small.
info->gradient = (d > MAGIC_EPSILON ? g : seg->n);
}
static void
cpSegmentShapeSegmentQuery(cpSegmentShape *seg, cpVect a, cpVect b, cpFloat r2, cpSegmentQueryInfo *info)
{
cpVect n = seg->tn;
cpFloat d = cpvdot(cpvsub(seg->ta, a), n);
cpFloat r = seg->r + r2;
cpVect flipped_n = (d > 0.0f ? cpvneg(n) : n);
cpVect seg_offset = cpvsub(cpvmult(flipped_n, r), a);
// Make the endpoints relative to 'a' and move them by the thickness of the segment.
cpVect seg_a = cpvadd(seg->ta, seg_offset);
cpVect seg_b = cpvadd(seg->tb, seg_offset);
cpVect delta = cpvsub(b, a);
if(cpvcross(delta, seg_a)*cpvcross(delta, seg_b) <= 0.0f){
cpFloat d_offset = d + (d > 0.0f ? -r : r);
cpFloat ad = -d_offset;
cpFloat bd = cpvdot(delta, n) - d_offset;
if(ad*bd < 0.0f){
cpFloat t = ad/(ad - bd);
info->shape = (cpShape *)seg;
info->point = cpvsub(cpvlerp(a, b, t), cpvmult(flipped_n, r2));
info->normal = flipped_n;
info->alpha = t;
}
} else if(r != 0.0f){
cpSegmentQueryInfo info1 = {NULL, b, cpvzero, 1.0f};
cpSegmentQueryInfo info2 = {NULL, b, cpvzero, 1.0f};
CircleSegmentQuery((cpShape *)seg, seg->ta, seg->r, a, b, r2, &info1);
CircleSegmentQuery((cpShape *)seg, seg->tb, seg->r, a, b, r2, &info2);
if(info1.alpha < info2.alpha){
(*info) = info1;
} else {
(*info) = info2;
}
}
}
static struct cpShapeMassInfo
cpSegmentShapeMassInfo(cpFloat mass, cpVect a, cpVect b, cpFloat r)
{
struct cpShapeMassInfo info = {
mass, cpMomentForBox(1.0f, cpvdist(a, b) + 2.0f*r, 2.0f*r), // TODO is an approximation.
cpvlerp(a, b, 0.5f),
cpAreaForSegment(a, b, r),
};
return info;
}
static const cpShapeClass cpSegmentShapeClass = {
CP_SEGMENT_SHAPE,
(cpShapeCacheDataImpl)cpSegmentShapeCacheData,
NULL,
(cpShapePointQueryImpl)cpSegmentShapePointQuery,
(cpShapeSegmentQueryImpl)cpSegmentShapeSegmentQuery,
};
cpSegmentShape *
cpSegmentShapeInit(cpSegmentShape *seg, cpBody *body, cpVect a, cpVect b, cpFloat r)
{
seg->a = a;
seg->b = b;
seg->n = cpvrperp(cpvnormalize(cpvsub(b, a)));
seg->r = r;
seg->a_tangent = cpvzero;
seg->b_tangent = cpvzero;
cpShapeInit((cpShape *)seg, &cpSegmentShapeClass, body, cpSegmentShapeMassInfo(0.0f, a, b, r));
return seg;
}
cpShape*
cpSegmentShapeNew(cpBody *body, cpVect a, cpVect b, cpFloat r)
{
return (cpShape *)cpSegmentShapeInit(cpSegmentShapeAlloc(), body, a, b, r);
}
cpVect
cpSegmentShapeGetA(const cpShape *shape)
{
cpAssertHard(shape->klass == &cpSegmentShapeClass, "Shape is not a segment shape.");
return ((cpSegmentShape *)shape)->a;
}
cpVect
cpSegmentShapeGetB(const cpShape *shape)
{
cpAssertHard(shape->klass == &cpSegmentShapeClass, "Shape is not a segment shape.");
return ((cpSegmentShape *)shape)->b;
}
cpVect
cpSegmentShapeGetNormal(const cpShape *shape)
{
cpAssertHard(shape->klass == &cpSegmentShapeClass, "Shape is not a segment shape.");
return ((cpSegmentShape *)shape)->n;
}
cpFloat
cpSegmentShapeGetRadius(const cpShape *shape)
{
cpAssertHard(shape->klass == &cpSegmentShapeClass, "Shape is not a segment shape.");
return ((cpSegmentShape *)shape)->r;
}
void
cpSegmentShapeSetNeighbors(cpShape *shape, cpVect prev, cpVect next)
{
cpAssertHard(shape->klass == &cpSegmentShapeClass, "Shape is not a segment shape.");
cpSegmentShape *seg = (cpSegmentShape *)shape;
seg->a_tangent = cpvsub(prev, seg->a);
seg->b_tangent = cpvsub(next, seg->b);
}
// Unsafe API (chipmunk_unsafe.h)
// TODO setters should wake the shape up?
void
cpCircleShapeSetRadius(cpShape *shape, cpFloat radius)
{
cpAssertHard(shape->klass == &cpCircleShapeClass, "Shape is not a circle shape.");
cpCircleShape *circle = (cpCircleShape *)shape;
circle->r = radius;
cpFloat mass = shape->massInfo.m;
shape->massInfo = cpCircleShapeMassInfo(mass, circle->r, circle->c);
if(mass > 0.0f) cpBodyAccumulateMassFromShapes(shape->body);
}
void
cpCircleShapeSetOffset(cpShape *shape, cpVect offset)
{
cpAssertHard(shape->klass == &cpCircleShapeClass, "Shape is not a circle shape.");
cpCircleShape *circle = (cpCircleShape *)shape;
circle->c = offset;
cpFloat mass = shape->massInfo.m;
shape->massInfo = cpCircleShapeMassInfo(shape->massInfo.m, circle->r, circle->c);
if(mass > 0.0f) cpBodyAccumulateMassFromShapes(shape->body);
}
void
cpSegmentShapeSetEndpoints(cpShape *shape, cpVect a, cpVect b)
{
cpAssertHard(shape->klass == &cpSegmentShapeClass, "Shape is not a segment shape.");
cpSegmentShape *seg = (cpSegmentShape *)shape;
seg->a = a;
seg->b = b;
seg->n = cpvperp(cpvnormalize(cpvsub(b, a)));
cpFloat mass = shape->massInfo.m;
shape->massInfo = cpSegmentShapeMassInfo(shape->massInfo.m, seg->a, seg->b, seg->r);
if(mass > 0.0f) cpBodyAccumulateMassFromShapes(shape->body);
}
void
cpSegmentShapeSetRadius(cpShape *shape, cpFloat radius)
{
cpAssertHard(shape->klass == &cpSegmentShapeClass, "Shape is not a segment shape.");
cpSegmentShape *seg = (cpSegmentShape *)shape;
seg->r = radius;
cpFloat mass = shape->massInfo.m;
shape->massInfo = cpSegmentShapeMassInfo(shape->massInfo.m, seg->a, seg->b, seg->r);
if(mass > 0.0f) cpBodyAccumulateMassFromShapes(shape->body);
}