paulxstretch/deps/juce/modules/juce_box2d/box2d/Dynamics/b2Fixture.cpp

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/*
* Copyright (c) 2006-2009 Erin Catto http://www.box2d.org
*
* This software is provided 'as-is', without any express or implied
* warranty. In no event will the authors be held liable for any damages
* arising from the use of this software.
* Permission is granted to anyone to use this software for any purpose,
* including commercial applications, and to alter it and redistribute it
* freely, subject to the following restrictions:
* 1. The origin of this software must not be misrepresented; you must not
* claim that you wrote the original software. If you use this software
* in a product, an acknowledgment in the product documentation would be
* appreciated but is not required.
* 2. Altered source versions must be plainly marked as such, and must not be
* misrepresented as being the original software.
* 3. This notice may not be removed or altered from any source distribution.
*/
#include "b2Fixture.h"
#include "Contacts/b2Contact.h"
#include "b2World.h"
#include "../Collision/Shapes/b2CircleShape.h"
#include "../Collision/Shapes/b2EdgeShape.h"
#include "../Collision/Shapes/b2PolygonShape.h"
#include "../Collision/Shapes/b2ChainShape.h"
#include "../Collision/b2BroadPhase.h"
#include "../Collision/b2Collision.h"
#include "../Common/b2BlockAllocator.h"
b2Fixture::b2Fixture()
{
m_userData = NULL;
m_body = NULL;
m_next = NULL;
m_proxies = NULL;
m_proxyCount = 0;
m_shape = NULL;
m_density = 0.0f;
}
void b2Fixture::Create(b2BlockAllocator* allocator, b2Body* body, const b2FixtureDef* def)
{
m_userData = def->userData;
m_friction = def->friction;
m_restitution = def->restitution;
m_body = body;
m_next = NULL;
m_filter = def->filter;
m_isSensor = def->isSensor;
m_shape = def->shape->Clone(allocator);
// Reserve proxy space
int32 childCount = m_shape->GetChildCount();
m_proxies = (b2FixtureProxy*)allocator->Allocate(childCount * sizeof(b2FixtureProxy));
for (int32 i = 0; i < childCount; ++i)
{
m_proxies[i].fixture = NULL;
m_proxies[i].proxyId = b2BroadPhase::e_nullProxy;
}
m_proxyCount = 0;
m_density = def->density;
}
void b2Fixture::Destroy(b2BlockAllocator* allocator)
{
// The proxies must be destroyed before calling this.
b2Assert(m_proxyCount == 0);
// Free the proxy array.
int32 childCount = m_shape->GetChildCount();
allocator->Free(m_proxies, childCount * sizeof(b2FixtureProxy));
m_proxies = NULL;
// Free the child shape.
switch (m_shape->m_type)
{
case b2Shape::e_circle:
{
b2CircleShape* s = (b2CircleShape*)m_shape;
s->~b2CircleShape();
allocator->Free(s, sizeof(b2CircleShape));
}
break;
case b2Shape::e_edge:
{
b2EdgeShape* s = (b2EdgeShape*)m_shape;
s->~b2EdgeShape();
allocator->Free(s, sizeof(b2EdgeShape));
}
break;
case b2Shape::e_polygon:
{
b2PolygonShape* s = (b2PolygonShape*)m_shape;
s->~b2PolygonShape();
allocator->Free(s, sizeof(b2PolygonShape));
}
break;
case b2Shape::e_chain:
{
b2ChainShape* s = (b2ChainShape*)m_shape;
s->~b2ChainShape();
allocator->Free(s, sizeof(b2ChainShape));
}
break;
default:
b2Assert(false);
break;
}
m_shape = NULL;
}
void b2Fixture::CreateProxies(b2BroadPhase* broadPhase, const b2Transform& xf)
{
b2Assert(m_proxyCount == 0);
// Create proxies in the broad-phase.
m_proxyCount = m_shape->GetChildCount();
for (int32 i = 0; i < m_proxyCount; ++i)
{
b2FixtureProxy* proxy = m_proxies + i;
m_shape->ComputeAABB(&proxy->aabb, xf, i);
proxy->proxyId = broadPhase->CreateProxy(proxy->aabb, proxy);
proxy->fixture = this;
proxy->childIndex = i;
}
}
void b2Fixture::DestroyProxies(b2BroadPhase* broadPhase)
{
// Destroy proxies in the broad-phase.
for (int32 i = 0; i < m_proxyCount; ++i)
{
b2FixtureProxy* proxy = m_proxies + i;
broadPhase->DestroyProxy(proxy->proxyId);
proxy->proxyId = b2BroadPhase::e_nullProxy;
}
m_proxyCount = 0;
}
void b2Fixture::Synchronize(b2BroadPhase* broadPhase, const b2Transform& transform1, const b2Transform& transform2)
{
if (m_proxyCount == 0)
{
return;
}
for (int32 i = 0; i < m_proxyCount; ++i)
{
b2FixtureProxy* proxy = m_proxies + i;
// Compute an AABB that covers the swept shape (may miss some rotation effect).
b2AABB aabb1, aabb2;
m_shape->ComputeAABB(&aabb1, transform1, proxy->childIndex);
m_shape->ComputeAABB(&aabb2, transform2, proxy->childIndex);
proxy->aabb.Combine(aabb1, aabb2);
b2Vec2 displacement = transform2.p - transform1.p;
broadPhase->MoveProxy(proxy->proxyId, proxy->aabb, displacement);
}
}
void b2Fixture::SetFilterData(const b2Filter& filter)
{
m_filter = filter;
Refilter();
}
void b2Fixture::Refilter()
{
if (m_body == NULL)
{
return;
}
// Flag associated contacts for filtering.
b2ContactEdge* edge = m_body->GetContactList();
while (edge)
{
b2Contact* contact = edge->contact;
b2Fixture* fixtureA = contact->GetFixtureA();
b2Fixture* fixtureB = contact->GetFixtureB();
if (fixtureA == this || fixtureB == this)
{
contact->FlagForFiltering();
}
edge = edge->next;
}
b2World* world = m_body->GetWorld();
if (world == NULL)
{
return;
}
// Touch each proxy so that new pairs may be created
b2BroadPhase* broadPhase = &world->m_contactManager.m_broadPhase;
for (int32 i = 0; i < m_proxyCount; ++i)
{
broadPhase->TouchProxy(m_proxies[i].proxyId);
}
}
void b2Fixture::SetSensor(bool sensor)
{
if (sensor != m_isSensor)
{
m_body->SetAwake(true);
m_isSensor = sensor;
}
}
void b2Fixture::Dump(int32 bodyIndex)
{
b2Log(" b2FixtureDef fd;\n");
b2Log(" fd.friction = %.15lef;\n", m_friction);
b2Log(" fd.restitution = %.15lef;\n", m_restitution);
b2Log(" fd.density = %.15lef;\n", m_density);
b2Log(" fd.isSensor = bool(%d);\n", m_isSensor);
b2Log(" fd.filter.categoryBits = uint16(%d);\n", m_filter.categoryBits);
b2Log(" fd.filter.maskBits = uint16(%d);\n", m_filter.maskBits);
b2Log(" fd.filter.groupIndex = int16(%d);\n", m_filter.groupIndex);
switch (m_shape->m_type)
{
case b2Shape::e_circle:
{
b2CircleShape* s = (b2CircleShape*)m_shape;
b2Log(" b2CircleShape shape;\n");
b2Log(" shape.m_radius = %.15lef;\n", s->m_radius);
b2Log(" shape.m_p.Set(%.15lef, %.15lef);\n", s->m_p.x, s->m_p.y);
}
break;
case b2Shape::e_edge:
{
b2EdgeShape* s = (b2EdgeShape*)m_shape;
b2Log(" b2EdgeShape shape;\n");
b2Log(" shape.m_radius = %.15lef;\n", s->m_radius);
b2Log(" shape.m_vertex0.Set(%.15lef, %.15lef);\n", s->m_vertex0.x, s->m_vertex0.y);
b2Log(" shape.m_vertex1.Set(%.15lef, %.15lef);\n", s->m_vertex1.x, s->m_vertex1.y);
b2Log(" shape.m_vertex2.Set(%.15lef, %.15lef);\n", s->m_vertex2.x, s->m_vertex2.y);
b2Log(" shape.m_vertex3.Set(%.15lef, %.15lef);\n", s->m_vertex3.x, s->m_vertex3.y);
b2Log(" shape.m_hasVertex0 = bool(%d);\n", s->m_hasVertex0);
b2Log(" shape.m_hasVertex3 = bool(%d);\n", s->m_hasVertex3);
}
break;
case b2Shape::e_polygon:
{
b2PolygonShape* s = (b2PolygonShape*)m_shape;
b2Log(" b2PolygonShape shape;\n");
b2Log(" b2Vec2 vs[%d];\n", b2_maxPolygonVertices);
for (int32 i = 0; i < s->m_vertexCount; ++i)
{
b2Log(" vs[%d].Set(%.15lef, %.15lef);\n", i, s->m_vertices[i].x, s->m_vertices[i].y);
}
b2Log(" shape.Set(vs, %d);\n", s->m_vertexCount);
}
break;
case b2Shape::e_chain:
{
b2ChainShape* s = (b2ChainShape*)m_shape;
b2Log(" b2ChainShape shape;\n");
b2Log(" b2Vec2 vs[%d];\n", s->m_count);
for (int32 i = 0; i < s->m_count; ++i)
{
b2Log(" vs[%d].Set(%.15lef, %.15lef);\n", i, s->m_vertices[i].x, s->m_vertices[i].y);
}
b2Log(" shape.CreateChain(vs, %d);\n", s->m_count);
b2Log(" shape.m_prevVertex.Set(%.15lef, %.15lef);\n", s->m_prevVertex.x, s->m_prevVertex.y);
b2Log(" shape.m_nextVertex.Set(%.15lef, %.15lef);\n", s->m_nextVertex.x, s->m_nextVertex.y);
b2Log(" shape.m_hasPrevVertex = bool(%d);\n", s->m_hasPrevVertex);
b2Log(" shape.m_hasNextVertex = bool(%d);\n", s->m_hasNextVertex);
}
break;
default:
return;
}
b2Log("\n");
b2Log(" fd.shape = &shape;\n");
b2Log("\n");
b2Log(" bodies[%d]->CreateFixture(&fd);\n", bodyIndex);
}