[physics.git] / src / collisionManager.cpp

/*
 *  Copyright (C) 2008 Patrik Gornicz, Gornicz_P (at) hotmail (dot) com.
 *
 *  This program is free software: you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation, either version 3 of the License, or
 *  (at your option) any later version.
 *
 *  This program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */

#include "collisionManager.h"
#include "debug.h"

#include "Vector2.h"

#include "Entities/Ball.h"
#include "Entities/Polygon.h"
#include "Entities/PhysicsEntity.h"

#include "CollisionInfo.h"

#include "mathw.h"

/// ***** Private Class Header *****

/// ***** Private Method Headers *****

void clearEntities();
void placeEntity(PhysicsEntity* p);
void updateEntities();

void applyCollision(PhysicsEntity* p1, PhysicsEntity* p2);
void applyCollision(Ball* b1, Ball* b2);
void applyCollision(Polygon* pPoly, Ball* pBall);

bool getInfo(const Ball* b1, const Ball* b2, CollisionInfo* cInfo);
bool getInfo(const Polygon* pPoly, const Ball* pBall, CollisionInfo* cInfo);

/// ***** Private Variables *****

const int xDivisions = 20;
const int yDivisions = 16;
const int screenX    = 800;
const int screenY    = 600;

setPhys divisions[xDivisions][yDivisions];

/// ***** Initializers/Cleaners *****

void collision::init()
{

}
void collision::clean()
{

}

/// ***** Public Methods *****

void collision::update(setPhys& sp)
{
    clearEntities();

    for( setPhys::iterator it = sp.begin();
         it != sp.end();
         it++ )
    {
        placeEntity(*it);
    }

    updateEntities();
}

/// ***** Private Methods *****

void clearEntities()
{
    for( int x = 0;
             x < xDivisions;
             x++ )
    {
        for( int y = 0;
                 y < yDivisions;
                 y++ )
        {
            divisions[x][y].clear();
        }
    }
}

void placeEntity(PhysicsEntity* p)
{
    Vector2 minP;
    Vector2 maxP;

    { // Ball case
        Ball* b = dynamic_cast<Ball*>(p);

        if( b != NULL )
        {
            const float& xb     = b->positionRaw().x;
            const float& yb     = b->positionRaw().y;
            const float& rad    = b->radius;

            minP.x = xb - rad;
            minP.y = yb - rad;
            maxP.x = xb + rad;
            maxP.y = yb + rad;

            goto start;
        }
    }

    { // Polygon case
        Polygon* pPoly = dynamic_cast<Polygon*>(p);

        if( pPoly != NULL )
        {
            minP = pPoly->minP;
            maxP = pPoly->maxP;

            goto start;
        }
    }

    DPF(0, "ENTITY TYPE NOT SUPPORTED BY placeEntity()!!");
    return;

start:
    for( int x =  static_cast<int>( minP.x / (screenX / xDivisions) );
             x <= static_cast<int>( maxP.x / (screenX / xDivisions) );
             x++ )
    {
        if(x < 0 || xDivisions <= x)
            break;

        for( int y =  static_cast<int>( minP.y / (screenY / yDivisions) );
                 y <= static_cast<int>( maxP.y / (screenY / yDivisions) );
                 y++ )
        {
            if(y < 0 || yDivisions <= y)
                break;

            divisions[x][y].insert(p);
        }
    }
}

void updateEntities()
{
    for( int x = 0;
             x < xDivisions;
             x++ )
    {
        for( int y = 0;
                 y < yDivisions;
                 y++ )
        {
            for( setPhys::iterator it1 = divisions[x][y].begin();
                 it1 != divisions[x][y].end();
                 it1++ )
            {
                for( setPhys::iterator it2 = divisions[x][y].begin();
                     it2 != divisions[x][y].end();
                     it2++ )
                {
                    if( *it1 == *it2 )
                        break;

                    applyCollision(*it1, *it2);
                }
            }
        }
    }
}

void applyCollision(PhysicsEntity* p1, PhysicsEntity* p2)
{
    {
        Ball* b1 = dynamic_cast<Ball*>(p1);
        Ball* b2 = dynamic_cast<Ball*>(p2);

        if( b1 != NULL && b2 != NULL )
        {
            applyCollision(b1, b2);
            return;
        }
    }

    {
        Polygon*    pPoly   = dynamic_cast<Polygon*>(p1);
        Ball*       pBall   = dynamic_cast<Ball*>(p2);

        if( pPoly != NULL && pBall != NULL )
        {
            applyCollision(pPoly, pBall);
            return;
        }
    }

    {
        Polygon*    pPoly   = dynamic_cast<Polygon*>(p2);
        Ball*       pBall   = dynamic_cast<Ball*>(p1);

        if( pPoly != NULL && pBall != NULL )
        {
            applyCollision(pPoly, pBall);
            return;
        }
    }

    DPF(0, "ENTITY TYPE NOT SUPPORTED BY applyCollision()!!");
}

void applyCollision(Ball* b1, Ball* b2)
{
    CollisionInfo   cInfo;

    if(!getInfo(b1, b2, &cInfo))
        return;

    // a few values to simplify the equations
    const Vector2& normal = cInfo.normal;
    const Vector2& point  = cInfo.point;

    float m1 = b1->mass;
    float m2 = b2->mass;

    float e = (b1->CoR + b2->CoR) / 2;

    Vector2 v1 = b1->velocityRaw();
    Vector2 v2 = b2->velocityRaw();


    float iTop = -(e + 1) * (v1 - v2).dot(normal);

    // otherwise the collision happened and we do the math the below assumes
    // collisions have no friction

    float impulse = iTop / (normal.dot(normal) * (1 / m1 + 1 / m2));

    b1->applyImpulse(impulse / m1 * normal, point);
    b2->applyImpulse(-impulse / m2 * normal, point);
}

void applyCollision(Polygon* pPoly, Ball* pBall)
{
    CollisionInfo   cInfo;

    if(!getInfo(pPoly, pBall, &cInfo))
        return;

    float fCoR = pBall->CoR;
    Vector2 vecNorm = cInfo.normal;

    Vector2 vecVelo = pBall->velocityRaw();

    // impulse divided by mass
    float idm = (-(fCoR + 1) * vecVelo.dot(vecNorm))
              / (vecNorm.dot(vecNorm));

    pBall->applyImpulse(idm * vecNorm);

    // HACK
    // CoR penetration fix, adds the jitters

    // from center to point
    Vector2 vecCollP = vecNorm / vecNorm.length() * pBall->radius;
    pBall->applyNudge(cInfo.point + vecCollP - pBall->positionRaw());
}

bool getInfo(const Ball* b1, const Ball* b2, CollisionInfo* pcInfo)
{
    // a few values to simplify the equations
    float r1 = b1->radius;
    float r2 = b2->radius;

    Vector2 p1 = b1->positionRaw();
    Vector2 p2 = b2->positionRaw();
    Vector2 v1 = b1->velocityRaw();
    Vector2 v2 = b2->velocityRaw();

    // quick binding box check
    if (p1.x - r1 > p2.x + r2
     || p1.x + r1 < p2.x - r2
     || p1.y - r1 > p2.y + r2
     || p1.y + r1 < p2.y - r2)
        return false;

    // test if not touching
    if ((p1 - p2).sqrLength() >= (r1 + r2)*(r1 + r2))
        return false;

    // test if they are moving apart in some way if they aren't it's likely
    // that they collided last frame and are still overlapping

    if ((v1 - v2).dot(p1 - p2) >= 0)
        return false;

    pcInfo->point   = p1 - (p1 - p2) * r1 / (r1 + r2);
    pcInfo->normal  = p1 - p2;

    return true;
}

bool getInfo(const Polygon* pPoly, const Ball* pBall, CollisionInfo* pcInfo)
{
    // a few values to simplify the equations
    float   fRad    = pBall->radius;
    Vector2 vecPos  = pBall->positionRaw();
    Vector2 vecVelo = pBall->velocityRaw();

    float fMaxX = pPoly->maxP.x;
    float fMinX = pPoly->minP.x;
    float fMaxY = pPoly->maxP.y;
    float fMinY = pPoly->minP.y;

    // quick binding box check
    if (vecPos.x - fRad > fMaxX || vecPos.x + fRad < fMinX ||
        vecPos.y - fRad > fMaxY || vecPos.y + fRad < fMinY)
        return false;


    Vector2 vecTotVec;
    int iTot = 0;

    {
        const vector<Vector2>& pts = pPoly->points;
        unsigned int num = pts.size();

        for (unsigned int i = 0; i < num; i++)
        {
            Vector2 vec = vectorToLine(vecPos,
                                       pts[i].x,
                                       pts[i].y,
                                       pts[(i + 1) % num].x,
                                       pts[(i + 1) % num].y);

            if (vec.sqrLength() <= fRad*fRad && 0 < vec.dot(vecVelo))
            {
                vecTotVec += vec;
                iTot += 1;
            }
        }
    }

    if (iTot <= 0)
        return false;


    pcInfo->point   = vecTotVec / iTot + vecPos;
    pcInfo->normal  = vecPos - pcInfo->point;

    return true;
}
Commit	Line	Data
	1	/*
	2	* Copyright (C) 2008 Patrik Gornicz, Gornicz_P (at) hotmail (dot) com.
	3	*
	4	* This program is free software: you can redistribute it and/or modify
	5	* it under the terms of the GNU General Public License as published by
	6	* the Free Software Foundation, either version 3 of the License, or
	7	* (at your option) any later version.
	8	*
	9	* This program is distributed in the hope that it will be useful,
	10	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	11	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	12	* GNU General Public License for more details.
	13	*
	14	* You should have received a copy of the GNU General Public License
	15	* along with this program. If not, see <http://www.gnu.org/licenses/>.
	16	*/
	17
	18	#include "collisionManager.h"
	19	#include "debug.h"
	20
	21	#include "Vector2.h"
	22
	23	#include "Entities/Ball.h"
	24	#include "Entities/Polygon.h"
	25	#include "Entities/PhysicsEntity.h"
	26
	27	#include "CollisionInfo.h"
	28
	29	#include "mathw.h"
	30
	31	/// *** Private Class Header ***
	32
	33	/// *** Private Method Headers ***
	34
	35	void clearEntities();
	36	void placeEntity(PhysicsEntity* p);
	37	void updateEntities();
	38
	39	void applyCollision(PhysicsEntity* p1, PhysicsEntity* p2);
	40	void applyCollision(Ball* b1, Ball* b2);
	41	void applyCollision(Polygon* pPoly, Ball* pBall);
	42
	43	bool getInfo(const Ball* b1, const Ball* b2, CollisionInfo* cInfo);
	44	bool getInfo(const Polygon* pPoly, const Ball* pBall, CollisionInfo* cInfo);
	45
	46	/// *** Private Variables ***
	47
	48	const int xDivisions = 20;
	49	const int yDivisions = 16;
	50	const int screenX = 800;
	51	const int screenY = 600;
	52
	53	setPhys divisions[xDivisions][yDivisions];
	54
	55	/// *** Initializers/Cleaners ***
	56
	57	void collision::init()
	58	{
	59
	60	}
	61	void collision::clean()
	62	{
	63
	64	}
	65
	66	/// *** Public Methods ***
	67
	68	void collision::update(setPhys& sp)
	69	{
	70	clearEntities();
	71
	72	for( setPhys::iterator it = sp.begin();
	73	it != sp.end();
	74	it++ )
	75	{
	76	placeEntity(*it);
	77	}
	78
	79	updateEntities();
	80	}
	81
	82	/// *** Private Methods ***
	83
	84	void clearEntities()
	85	{
	86	for( int x = 0;
	87	x < xDivisions;
	88	x++ )
	89	{
	90	for( int y = 0;
	91	y < yDivisions;
	92	y++ )
	93	{
	94	divisions[x][y].clear();
	95	}
	96	}
	97	}
	98
	99	void placeEntity(PhysicsEntity* p)
	100	{
	101	Vector2 minP;
	102	Vector2 maxP;
	103
	104	{ // Ball case
	105	Ball* b = dynamic_cast<Ball*>(p);
	106
	107	if( b != NULL )
	108	{
	109	const float& xb = b->positionRaw().x;
	110	const float& yb = b->positionRaw().y;
	111	const float& rad = b->radius;
	112
	113	minP.x = xb - rad;
	114	minP.y = yb - rad;
	115	maxP.x = xb + rad;
	116	maxP.y = yb + rad;
	117
	118	goto start;
	119	}
	120	}
	121
	122	{ // Polygon case
	123	Polygon* pPoly = dynamic_cast<Polygon*>(p);
	124
	125	if( pPoly != NULL )
	126	{
	127	minP = pPoly->minP;
	128	maxP = pPoly->maxP;
	129
	130	goto start;
	131	}
	132	}
	133
	134	DPF(0, "ENTITY TYPE NOT SUPPORTED BY placeEntity()!!");
	135	return;
	136
	137	start:
	138	for( int x = static_cast<int>( minP.x / (screenX / xDivisions) );
	139	x <= static_cast<int>( maxP.x / (screenX / xDivisions) );
	140	x++ )
	141	{
	142	if(x < 0 \|\| xDivisions <= x)
	143	break;
	144
	145	for( int y = static_cast<int>( minP.y / (screenY / yDivisions) );
	146	y <= static_cast<int>( maxP.y / (screenY / yDivisions) );
	147	y++ )
	148	{
	149	if(y < 0 \|\| yDivisions <= y)
	150	break;
	151
	152	divisions[x][y].insert(p);
	153	}
	154	}
	155	}
	156
	157	void updateEntities()
	158	{
	159	for( int x = 0;
	160	x < xDivisions;
	161	x++ )
	162	{
	163	for( int y = 0;
	164	y < yDivisions;
	165	y++ )
	166	{
	167	for( setPhys::iterator it1 = divisions[x][y].begin();
	168	it1 != divisions[x][y].end();
	169	it1++ )
	170	{
	171	for( setPhys::iterator it2 = divisions[x][y].begin();
	172	it2 != divisions[x][y].end();
	173	it2++ )
	174	{
	175	if( it1 == it2 )
	176	break;
	177
	178	applyCollision(it1, it2);
	179	}
	180	}
	181	}
	182	}
	183	}
	184
	185	void applyCollision(PhysicsEntity* p1, PhysicsEntity* p2)
	186	{
	187	{
	188	Ball* b1 = dynamic_cast<Ball*>(p1);
	189	Ball* b2 = dynamic_cast<Ball*>(p2);
	190
	191	if( b1 != NULL && b2 != NULL )
	192	{
	193	applyCollision(b1, b2);
	194	return;
	195	}
	196	}
	197
	198	{
	199	Polygon* pPoly = dynamic_cast<Polygon*>(p1);
	200	Ball* pBall = dynamic_cast<Ball*>(p2);
	201
	202	if( pPoly != NULL && pBall != NULL )
	203	{
	204	applyCollision(pPoly, pBall);
	205	return;
	206	}
	207	}
	208
	209	{
	210	Polygon* pPoly = dynamic_cast<Polygon*>(p2);
	211	Ball* pBall = dynamic_cast<Ball*>(p1);
	212
	213	if( pPoly != NULL && pBall != NULL )
	214	{
	215	applyCollision(pPoly, pBall);
	216	return;
	217	}
	218	}
	219
	220	DPF(0, "ENTITY TYPE NOT SUPPORTED BY applyCollision()!!");
	221	}
	222
	223	void applyCollision(Ball* b1, Ball* b2)
	224	{
	225	CollisionInfo cInfo;
	226
	227	if(!getInfo(b1, b2, &cInfo))
	228	return;
	229
	230	// a few values to simplify the equations
	231	const Vector2& normal = cInfo.normal;
	232	const Vector2& point = cInfo.point;
	233
	234	float m1 = b1->mass;
	235	float m2 = b2->mass;
	236
	237	float e = (b1->CoR + b2->CoR) / 2;
	238
	239	Vector2 v1 = b1->velocityRaw();
	240	Vector2 v2 = b2->velocityRaw();
	241
	242
	243	float iTop = -(e + 1) * (v1 - v2).dot(normal);
	244
	245	// otherwise the collision happened and we do the math the below assumes
	246	// collisions have no friction
	247
	248	float impulse = iTop / (normal.dot(normal) * (1 / m1 + 1 / m2));
	249
	250	b1->applyImpulse(impulse / m1 * normal, point);
	251	b2->applyImpulse(-impulse / m2 * normal, point);
	252	}
	253
	254	void applyCollision(Polygon* pPoly, Ball* pBall)
	255	{
	256	CollisionInfo cInfo;
	257
	258	if(!getInfo(pPoly, pBall, &cInfo))
	259	return;
	260
	261	float fCoR = pBall->CoR;
	262	Vector2 vecNorm = cInfo.normal;
	263
	264	Vector2 vecVelo = pBall->velocityRaw();
	265
	266	// impulse divided by mass
	267	float idm = (-(fCoR + 1) * vecVelo.dot(vecNorm))
	268	/ (vecNorm.dot(vecNorm));
	269
	270	pBall->applyImpulse(idm * vecNorm);
	271
	272	// HACK
	273	// CoR penetration fix, adds the jitters
	274
	275	// from center to point
	276	Vector2 vecCollP = vecNorm / vecNorm.length() * pBall->radius;
	277	pBall->applyNudge(cInfo.point + vecCollP - pBall->positionRaw());
	278	}
	279
	280	bool getInfo(const Ball* b1, const Ball* b2, CollisionInfo* pcInfo)
	281	{
	282	// a few values to simplify the equations
	283	float r1 = b1->radius;
	284	float r2 = b2->radius;
	285
	286	Vector2 p1 = b1->positionRaw();
	287	Vector2 p2 = b2->positionRaw();
	288	Vector2 v1 = b1->velocityRaw();
	289	Vector2 v2 = b2->velocityRaw();
	290
	291	// quick binding box check
	292	if (p1.x - r1 > p2.x + r2
	293	\|\| p1.x + r1 < p2.x - r2
	294	\|\| p1.y - r1 > p2.y + r2
	295	\|\| p1.y + r1 < p2.y - r2)
	296	return false;
	297
	298	// test if not touching
	299	if ((p1 - p2).sqrLength() >= (r1 + r2)*(r1 + r2))
	300	return false;
	301
	302	// test if they are moving apart in some way if they aren't it's likely
	303	// that they collided last frame and are still overlapping
	304
	305	if ((v1 - v2).dot(p1 - p2) >= 0)
	306	return false;
	307
	308	pcInfo->point = p1 - (p1 - p2) * r1 / (r1 + r2);
	309	pcInfo->normal = p1 - p2;
	310
	311	return true;
	312	}
	313
	314	bool getInfo(const Polygon* pPoly, const Ball* pBall, CollisionInfo* pcInfo)
	315	{
	316	// a few values to simplify the equations
	317	float fRad = pBall->radius;
	318	Vector2 vecPos = pBall->positionRaw();
	319	Vector2 vecVelo = pBall->velocityRaw();
	320
	321	float fMaxX = pPoly->maxP.x;
	322	float fMinX = pPoly->minP.x;
	323	float fMaxY = pPoly->maxP.y;
	324	float fMinY = pPoly->minP.y;
	325
	326	// quick binding box check
	327	if (vecPos.x - fRad > fMaxX \|\| vecPos.x + fRad < fMinX \|\|
	328	vecPos.y - fRad > fMaxY \|\| vecPos.y + fRad < fMinY)
	329	return false;
	330
	331
	332	Vector2 vecTotVec;
	333	int iTot = 0;
	334
	335	{
	336	const vector<Vector2>& pts = pPoly->points;
	337	unsigned int num = pts.size();
	338
	339	for (unsigned int i = 0; i < num; i++)
	340	{
	341	Vector2 vec = vectorToLine(vecPos,
	342	pts[i].x,
	343	pts[i].y,
	344	pts[(i + 1) % num].x,
	345	pts[(i + 1) % num].y);
	346
	347	if (vec.sqrLength() <= fRad*fRad && 0 < vec.dot(vecVelo))
	348	{
	349	vecTotVec += vec;
	350	iTot += 1;
	351	}
	352	}
	353	}
	354
	355	if (iTot <= 0)
	356	return false;
	357
	358
	359	pcInfo->point = vecTotVec / iTot + vecPos;
	360	pcInfo->normal = vecPos - pcInfo->point;
	361
	362	return true;
	363	}