axmol/Box2D/Dynamics/b2WorldCallbacks.h

218 lines
7.7 KiB
C++

/*
* Copyright (c) 2006-2009 Erin Catto http://www.gphysics.com
*
* 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.
*/
#ifndef B2_WORLD_CALLBACKS_H
#define B2_WORLD_CALLBACKS_H
#include <Box2D/Common/b2Settings.h>
struct b2Vec2;
struct b2Transform;
class b2Fixture;
class b2Body;
class b2Joint;
class b2Contact;
struct b2ContactPoint;
struct b2ContactResult;
struct b2Manifold;
/// Joints and fixtures are destroyed when their associated
/// body is destroyed. Implement this listener so that you
/// may nullify references to these joints and shapes.
class b2DestructionListener
{
public:
virtual ~b2DestructionListener() {}
/// Called when any joint is about to be destroyed due
/// to the destruction of one of its attached bodies.
virtual void SayGoodbye(b2Joint* joint) = 0;
/// Called when any fixture is about to be destroyed due
/// to the destruction of its parent body.
virtual void SayGoodbye(b2Fixture* fixture) = 0;
};
/// Implement this class to provide collision filtering. In other words, you can implement
/// this class if you want finer control over contact creation.
class b2ContactFilter
{
public:
virtual ~b2ContactFilter() {}
/// Return true if contact calculations should be performed between these two shapes.
/// @warning for performance reasons this is only called when the AABBs begin to overlap.
virtual bool ShouldCollide(b2Fixture* fixtureA, b2Fixture* fixtureB);
};
/// Contact impulses for reporting. Impulses are used instead of forces because
/// sub-step forces may approach infinity for rigid body collisions. These
/// match up one-to-one with the contact points in b2Manifold.
struct b2ContactImpulse
{
float32 normalImpulses[b2_maxManifoldPoints];
float32 tangentImpulses[b2_maxManifoldPoints];
};
/// Implement this class to get contact information. You can use these results for
/// things like sounds and game logic. You can also get contact results by
/// traversing the contact lists after the time step. However, you might miss
/// some contacts because continuous physics leads to sub-stepping.
/// Additionally you may receive multiple callbacks for the same contact in a
/// single time step.
/// You should strive to make your callbacks efficient because there may be
/// many callbacks per time step.
/// @warning You cannot create/destroy Box2D entities inside these callbacks.
class b2ContactListener
{
public:
virtual ~b2ContactListener() {}
/// Called when two fixtures begin to touch.
virtual void BeginContact(b2Contact* contact) { B2_NOT_USED(contact); }
/// Called when two fixtures cease to touch.
virtual void EndContact(b2Contact* contact) { B2_NOT_USED(contact); }
/// This is called after a contact is updated. This allows you to inspect a
/// contact before it goes to the solver. If you are careful, you can modify the
/// contact manifold (e.g. disable contact).
/// A copy of the old manifold is provided so that you can detect changes.
/// Note: this is called only for awake bodies.
/// Note: this is called even when the number of contact points is zero.
/// Note: this is not called for sensors.
/// Note: if you set the number of contact points to zero, you will not
/// get an EndContact callback. However, you may get a BeginContact callback
/// the next step.
virtual void PreSolve(b2Contact* contact, const b2Manifold* oldManifold)
{
B2_NOT_USED(contact);
B2_NOT_USED(oldManifold);
}
/// This lets you inspect a contact after the solver is finished. This is useful
/// for inspecting impulses.
/// Note: the contact manifold does not include time of impact impulses, which can be
/// arbitrarily large if the sub-step is small. Hence the impulse is provided explicitly
/// in a separate data structure.
/// Note: this is only called for contacts that are touching, solid, and awake.
virtual void PostSolve(b2Contact* contact, const b2ContactImpulse* impulse)
{
B2_NOT_USED(contact);
B2_NOT_USED(impulse);
}
};
/// Callback class for AABB queries.
/// See b2World::Query
class b2QueryCallback
{
public:
virtual ~b2QueryCallback() {}
/// Called for each fixture found in the query AABB.
/// @return false to terminate the query.
virtual bool ReportFixture(b2Fixture* fixture) = 0;
};
/// Callback class for ray casts.
/// See b2World::RayCast
class b2RayCastCallback
{
public:
virtual ~b2RayCastCallback() {}
/// Called for each fixture found in the query. You control how the ray cast
/// proceeds by returning a float:
/// return -1: ignore this fixture and continue
/// return 0: terminate the ray cast
/// return fraction: clip the ray to this point
/// return 1: don't clip the ray and continue
/// @param fixture the fixture hit by the ray
/// @param point the point of initial intersection
/// @param normal the normal vector at the point of intersection
/// @return -1 to filter, 0 to terminate, fraction to clip the ray for
/// closest hit, 1 to continue
virtual float32 ReportFixture( b2Fixture* fixture, const b2Vec2& point,
const b2Vec2& normal, float32 fraction) = 0;
};
/// Color for debug drawing. Each value has the range [0,1].
struct b2Color
{
b2Color() {}
b2Color(float32 r, float32 g, float32 b) : r(r), g(g), b(b) {}
void Set(float32 ri, float32 gi, float32 bi) { r = ri; g = gi; b = bi; }
float32 r, g, b;
};
/// Implement and register this class with a b2World to provide debug drawing of physics
/// entities in your game.
class b2DebugDraw
{
public:
b2DebugDraw();
virtual ~b2DebugDraw() {}
enum
{
e_shapeBit = 0x0001, ///< draw shapes
e_jointBit = 0x0002, ///< draw joint connections
e_aabbBit = 0x0004, ///< draw axis aligned bounding boxes
e_pairBit = 0x0008, ///< draw broad-phase pairs
e_centerOfMassBit = 0x0010, ///< draw center of mass frame
};
/// Set the drawing flags.
void SetFlags(uint32 flags);
/// Get the drawing flags.
uint32 GetFlags() const;
/// Append flags to the current flags.
void AppendFlags(uint32 flags);
/// Clear flags from the current flags.
void ClearFlags(uint32 flags);
/// Draw a closed polygon provided in CCW order.
virtual void DrawPolygon(const b2Vec2* vertices, int32 vertexCount, const b2Color& color) = 0;
/// Draw a solid closed polygon provided in CCW order.
virtual void DrawSolidPolygon(const b2Vec2* vertices, int32 vertexCount, const b2Color& color) = 0;
/// Draw a circle.
virtual void DrawCircle(const b2Vec2& center, float32 radius, const b2Color& color) = 0;
/// Draw a solid circle.
virtual void DrawSolidCircle(const b2Vec2& center, float32 radius, const b2Vec2& axis, const b2Color& color) = 0;
/// Draw a line segment.
virtual void DrawSegment(const b2Vec2& p1, const b2Vec2& p2, const b2Color& color) = 0;
/// Draw a transform. Choose your own length scale.
/// @param xf a transform.
virtual void DrawTransform(const b2Transform& xf) = 0;
protected:
uint32 m_drawFlags;
};
#endif