/* * Copyright (c) 2006-2011 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 #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include b2World::b2World(const b2Vec2& gravity) { m_destructionListener = NULL; g_debugDraw = NULL; m_bodyList = NULL; m_jointList = NULL; m_bodyCount = 0; m_jointCount = 0; m_warmStarting = true; m_continuousPhysics = true; m_subStepping = false; m_stepComplete = true; m_allowSleep = true; m_gravity = gravity; m_flags = e_clearForces; m_inv_dt0 = 0.0f; m_contactManager.m_allocator = &m_blockAllocator; memset(&m_profile, 0, sizeof(b2Profile)); } b2World::~b2World() { // Some shapes allocate using b2Alloc. b2Body* b = m_bodyList; while (b) { b2Body* bNext = b->m_next; b2Fixture* f = b->m_fixtureList; while (f) { b2Fixture* fNext = f->m_next; f->m_proxyCount = 0; f->Destroy(&m_blockAllocator); f = fNext; } b = bNext; } } void b2World::SetDestructionListener(b2DestructionListener* listener) { m_destructionListener = listener; } void b2World::SetContactFilter(b2ContactFilter* filter) { m_contactManager.m_contactFilter = filter; } void b2World::SetContactListener(b2ContactListener* listener) { m_contactManager.m_contactListener = listener; } void b2World::SetDebugDraw(b2Draw* debugDraw) { g_debugDraw = debugDraw; } b2Body* b2World::CreateBody(const b2BodyDef* def) { b2Assert(IsLocked() == false); if (IsLocked()) { return NULL; } void* mem = m_blockAllocator.Allocate(sizeof(b2Body)); b2Body* b = new (mem) b2Body(def, this); // Add to world doubly linked list. b->m_prev = NULL; b->m_next = m_bodyList; if (m_bodyList) { m_bodyList->m_prev = b; } m_bodyList = b; ++m_bodyCount; return b; } void b2World::DestroyBody(b2Body* b) { b2Assert(m_bodyCount > 0); b2Assert(IsLocked() == false); if (IsLocked()) { return; } // Delete the attached joints. b2JointEdge* je = b->m_jointList; while (je) { b2JointEdge* je0 = je; je = je->next; if (m_destructionListener) { m_destructionListener->SayGoodbye(je0->joint); } DestroyJoint(je0->joint); b->m_jointList = je; } b->m_jointList = NULL; // Delete the attached contacts. b2ContactEdge* ce = b->m_contactList; while (ce) { b2ContactEdge* ce0 = ce; ce = ce->next; m_contactManager.Destroy(ce0->contact); } b->m_contactList = NULL; // Delete the attached fixtures. This destroys broad-phase proxies. b2Fixture* f = b->m_fixtureList; while (f) { b2Fixture* f0 = f; f = f->m_next; if (m_destructionListener) { m_destructionListener->SayGoodbye(f0); } f0->DestroyProxies(&m_contactManager.m_broadPhase); f0->Destroy(&m_blockAllocator); f0->~b2Fixture(); m_blockAllocator.Free(f0, sizeof(b2Fixture)); b->m_fixtureList = f; b->m_fixtureCount -= 1; } b->m_fixtureList = NULL; b->m_fixtureCount = 0; // Remove world body list. if (b->m_prev) { b->m_prev->m_next = b->m_next; } if (b->m_next) { b->m_next->m_prev = b->m_prev; } if (b == m_bodyList) { m_bodyList = b->m_next; } --m_bodyCount; b->~b2Body(); m_blockAllocator.Free(b, sizeof(b2Body)); } b2Joint* b2World::CreateJoint(const b2JointDef* def) { b2Assert(IsLocked() == false); if (IsLocked()) { return NULL; } b2Joint* j = b2Joint::Create(def, &m_blockAllocator); // Connect to the world list. j->m_prev = NULL; j->m_next = m_jointList; if (m_jointList) { m_jointList->m_prev = j; } m_jointList = j; ++m_jointCount; // Connect to the bodies' doubly linked lists. j->m_edgeA.joint = j; j->m_edgeA.other = j->m_bodyB; j->m_edgeA.prev = NULL; j->m_edgeA.next = j->m_bodyA->m_jointList; if (j->m_bodyA->m_jointList) j->m_bodyA->m_jointList->prev = &j->m_edgeA; j->m_bodyA->m_jointList = &j->m_edgeA; j->m_edgeB.joint = j; j->m_edgeB.other = j->m_bodyA; j->m_edgeB.prev = NULL; j->m_edgeB.next = j->m_bodyB->m_jointList; if (j->m_bodyB->m_jointList) j->m_bodyB->m_jointList->prev = &j->m_edgeB; j->m_bodyB->m_jointList = &j->m_edgeB; b2Body* bodyA = def->bodyA; b2Body* bodyB = def->bodyB; // If the joint prevents collisions, then flag any contacts for filtering. if (def->collideConnected == false) { b2ContactEdge* edge = bodyB->GetContactList(); while (edge) { if (edge->other == bodyA) { // Flag the contact for filtering at the next time step (where either // body is awake). edge->contact->FlagForFiltering(); } edge = edge->next; } } // Note: creating a joint doesn't wake the bodies. return j; } void b2World::DestroyJoint(b2Joint* j) { b2Assert(IsLocked() == false); if (IsLocked()) { return; } bool collideConnected = j->m_collideConnected; // Remove from the doubly linked list. if (j->m_prev) { j->m_prev->m_next = j->m_next; } if (j->m_next) { j->m_next->m_prev = j->m_prev; } if (j == m_jointList) { m_jointList = j->m_next; } // Disconnect from island graph. b2Body* bodyA = j->m_bodyA; b2Body* bodyB = j->m_bodyB; // Wake up connected bodies. bodyA->SetAwake(true); bodyB->SetAwake(true); // Remove from body 1. if (j->m_edgeA.prev) { j->m_edgeA.prev->next = j->m_edgeA.next; } if (j->m_edgeA.next) { j->m_edgeA.next->prev = j->m_edgeA.prev; } if (&j->m_edgeA == bodyA->m_jointList) { bodyA->m_jointList = j->m_edgeA.next; } j->m_edgeA.prev = NULL; j->m_edgeA.next = NULL; // Remove from body 2 if (j->m_edgeB.prev) { j->m_edgeB.prev->next = j->m_edgeB.next; } if (j->m_edgeB.next) { j->m_edgeB.next->prev = j->m_edgeB.prev; } if (&j->m_edgeB == bodyB->m_jointList) { bodyB->m_jointList = j->m_edgeB.next; } j->m_edgeB.prev = NULL; j->m_edgeB.next = NULL; b2Joint::Destroy(j, &m_blockAllocator); b2Assert(m_jointCount > 0); --m_jointCount; // If the joint prevents collisions, then flag any contacts for filtering. if (collideConnected == false) { b2ContactEdge* edge = bodyB->GetContactList(); while (edge) { if (edge->other == bodyA) { // Flag the contact for filtering at the next time step (where either // body is awake). edge->contact->FlagForFiltering(); } edge = edge->next; } } } // void b2World::SetAllowSleeping(bool flag) { if (flag == m_allowSleep) { return; } m_allowSleep = flag; if (m_allowSleep == false) { for (b2Body* b = m_bodyList; b; b = b->m_next) { b->SetAwake(true); } } } // Find islands, integrate and solve constraints, solve position constraints void b2World::Solve(const b2TimeStep& step) { m_profile.solveInit = 0.0f; m_profile.solveVelocity = 0.0f; m_profile.solvePosition = 0.0f; // Size the island for the worst case. b2Island island(m_bodyCount, m_contactManager.m_contactCount, m_jointCount, &m_stackAllocator, m_contactManager.m_contactListener); // Clear all the island flags. for (b2Body* b = m_bodyList; b; b = b->m_next) { b->m_flags &= ~b2Body::e_islandFlag; } for (b2Contact* c = m_contactManager.m_contactList; c; c = c->m_next) { c->m_flags &= ~b2Contact::e_islandFlag; } for (b2Joint* j = m_jointList; j; j = j->m_next) { j->m_islandFlag = false; } // Build and simulate all awake islands. int32 stackSize = m_bodyCount; b2Body** stack = (b2Body**)m_stackAllocator.Allocate(stackSize * sizeof(b2Body*)); for (b2Body* seed = m_bodyList; seed; seed = seed->m_next) { if (seed->m_flags & b2Body::e_islandFlag) { continue; } if (seed->IsAwake() == false || seed->IsActive() == false) { continue; } // The seed can be dynamic or kinematic. if (seed->GetType() == b2_staticBody) { continue; } // Reset island and stack. island.Clear(); int32 stackCount = 0; stack[stackCount++] = seed; seed->m_flags |= b2Body::e_islandFlag; // Perform a depth first search (DFS) on the constraint graph. while (stackCount > 0) { // Grab the next body off the stack and add it to the island. b2Body* b = stack[--stackCount]; b2Assert(b->IsActive() == true); island.Add(b); // Make sure the body is awake. b->SetAwake(true); // To keep islands as small as possible, we don't // propagate islands across static bodies. if (b->GetType() == b2_staticBody) { continue; } // Search all contacts connected to this body. for (b2ContactEdge* ce = b->m_contactList; ce; ce = ce->next) { b2Contact* contact = ce->contact; // Has this contact already been added to an island? if (contact->m_flags & b2Contact::e_islandFlag) { continue; } // Is this contact solid and touching? if (contact->IsEnabled() == false || contact->IsTouching() == false) { continue; } // Skip sensors. bool sensorA = contact->m_fixtureA->m_isSensor; bool sensorB = contact->m_fixtureB->m_isSensor; if (sensorA || sensorB) { continue; } island.Add(contact); contact->m_flags |= b2Contact::e_islandFlag; b2Body* other = ce->other; // Was the other body already added to this island? if (other->m_flags & b2Body::e_islandFlag) { continue; } b2Assert(stackCount < stackSize); stack[stackCount++] = other; other->m_flags |= b2Body::e_islandFlag; } // Search all joints connect to this body. for (b2JointEdge* je = b->m_jointList; je; je = je->next) { if (je->joint->m_islandFlag == true) { continue; } b2Body* other = je->other; // Don't simulate joints connected to inactive bodies. if (other->IsActive() == false) { continue; } island.Add(je->joint); je->joint->m_islandFlag = true; if (other->m_flags & b2Body::e_islandFlag) { continue; } b2Assert(stackCount < stackSize); stack[stackCount++] = other; other->m_flags |= b2Body::e_islandFlag; } } b2Profile profile; island.Solve(&profile, step, m_gravity, m_allowSleep); m_profile.solveInit += profile.solveInit; m_profile.solveVelocity += profile.solveVelocity; m_profile.solvePosition += profile.solvePosition; // Post solve cleanup. for (int32 i = 0; i < island.m_bodyCount; ++i) { // Allow static bodies to participate in other islands. b2Body* b = island.m_bodies[i]; if (b->GetType() == b2_staticBody) { b->m_flags &= ~b2Body::e_islandFlag; } } } m_stackAllocator.Free(stack); { b2Timer timer; // Synchronize fixtures, check for out of range bodies. for (b2Body* b = m_bodyList; b; b = b->GetNext()) { // If a body was not in an island then it did not move. if ((b->m_flags & b2Body::e_islandFlag) == 0) { continue; } if (b->GetType() == b2_staticBody) { continue; } // Update fixtures (for broad-phase). b->SynchronizeFixtures(); } // Look for new contacts. m_contactManager.FindNewContacts(); m_profile.broadphase = timer.GetMilliseconds(); } } // Find TOI contacts and solve them. void b2World::SolveTOI(const b2TimeStep& step) { b2Island island(2 * b2_maxTOIContacts, b2_maxTOIContacts, 0, &m_stackAllocator, m_contactManager.m_contactListener); if (m_stepComplete) { for (b2Body* b = m_bodyList; b; b = b->m_next) { b->m_flags &= ~b2Body::e_islandFlag; b->m_sweep.alpha0 = 0.0f; } for (b2Contact* c = m_contactManager.m_contactList; c; c = c->m_next) { // Invalidate TOI c->m_flags &= ~(b2Contact::e_toiFlag | b2Contact::e_islandFlag); c->m_toiCount = 0; c->m_toi = 1.0f; } } // Find TOI events and solve them. for (;;) { // Find the first TOI. b2Contact* minContact = NULL; float32 minAlpha = 1.0f; for (b2Contact* c = m_contactManager.m_contactList; c; c = c->m_next) { // Is this contact disabled? if (c->IsEnabled() == false) { continue; } // Prevent excessive sub-stepping. if (c->m_toiCount > b2_maxSubSteps) { continue; } float32 alpha = 1.0f; if (c->m_flags & b2Contact::e_toiFlag) { // This contact has a valid cached TOI. alpha = c->m_toi; } else { b2Fixture* fA = c->GetFixtureA(); b2Fixture* fB = c->GetFixtureB(); // Is there a sensor? if (fA->IsSensor() || fB->IsSensor()) { continue; } b2Body* bA = fA->GetBody(); b2Body* bB = fB->GetBody(); b2BodyType typeA = bA->m_type; b2BodyType typeB = bB->m_type; b2Assert(typeA == b2_dynamicBody || typeB == b2_dynamicBody); bool activeA = bA->IsAwake() && typeA != b2_staticBody; bool activeB = bB->IsAwake() && typeB != b2_staticBody; // Is at least one body active (awake and dynamic or kinematic)? if (activeA == false && activeB == false) { continue; } bool collideA = bA->IsBullet() || typeA != b2_dynamicBody; bool collideB = bB->IsBullet() || typeB != b2_dynamicBody; // Are these two non-bullet dynamic bodies? if (collideA == false && collideB == false) { continue; } // Compute the TOI for this contact. // Put the sweeps onto the same time interval. float32 alpha0 = bA->m_sweep.alpha0; if (bA->m_sweep.alpha0 < bB->m_sweep.alpha0) { alpha0 = bB->m_sweep.alpha0; bA->m_sweep.Advance(alpha0); } else if (bB->m_sweep.alpha0 < bA->m_sweep.alpha0) { alpha0 = bA->m_sweep.alpha0; bB->m_sweep.Advance(alpha0); } b2Assert(alpha0 < 1.0f); int32 indexA = c->GetChildIndexA(); int32 indexB = c->GetChildIndexB(); // Compute the time of impact in interval [0, minTOI] b2TOIInput input; input.proxyA.Set(fA->GetShape(), indexA); input.proxyB.Set(fB->GetShape(), indexB); input.sweepA = bA->m_sweep; input.sweepB = bB->m_sweep; input.tMax = 1.0f; b2TOIOutput output; b2TimeOfImpact(&output, &input); // Beta is the fraction of the remaining portion of the . float32 beta = output.t; if (output.state == b2TOIOutput::e_touching) { alpha = b2Min(alpha0 + (1.0f - alpha0) * beta, 1.0f); } else { alpha = 1.0f; } c->m_toi = alpha; c->m_flags |= b2Contact::e_toiFlag; } if (alpha < minAlpha) { // This is the minimum TOI found so far. minContact = c; minAlpha = alpha; } } if (minContact == NULL || 1.0f - 10.0f * b2_epsilon < minAlpha) { // No more TOI events. Done! m_stepComplete = true; break; } // Advance the bodies to the TOI. b2Fixture* fA = minContact->GetFixtureA(); b2Fixture* fB = minContact->GetFixtureB(); b2Body* bA = fA->GetBody(); b2Body* bB = fB->GetBody(); b2Sweep backup1 = bA->m_sweep; b2Sweep backup2 = bB->m_sweep; bA->Advance(minAlpha); bB->Advance(minAlpha); // The TOI contact likely has some new contact points. minContact->Update(m_contactManager.m_contactListener); minContact->m_flags &= ~b2Contact::e_toiFlag; ++minContact->m_toiCount; // Is the contact solid? if (minContact->IsEnabled() == false || minContact->IsTouching() == false) { // Restore the sweeps. minContact->SetEnabled(false); bA->m_sweep = backup1; bB->m_sweep = backup2; bA->SynchronizeTransform(); bB->SynchronizeTransform(); continue; } bA->SetAwake(true); bB->SetAwake(true); // Build the island island.Clear(); island.Add(bA); island.Add(bB); island.Add(minContact); bA->m_flags |= b2Body::e_islandFlag; bB->m_flags |= b2Body::e_islandFlag; minContact->m_flags |= b2Contact::e_islandFlag; // Get contacts on bodyA and bodyB. b2Body* bodies[2] = {bA, bB}; for (int32 i = 0; i < 2; ++i) { b2Body* body = bodies[i]; if (body->m_type == b2_dynamicBody) { for (b2ContactEdge* ce = body->m_contactList; ce; ce = ce->next) { if (island.m_bodyCount == island.m_bodyCapacity) { break; } if (island.m_contactCount == island.m_contactCapacity) { break; } b2Contact* contact = ce->contact; // Has this contact already been added to the island? if (contact->m_flags & b2Contact::e_islandFlag) { continue; } // Only add static, kinematic, or bullet bodies. b2Body* other = ce->other; if (other->m_type == b2_dynamicBody && body->IsBullet() == false && other->IsBullet() == false) { continue; } // Skip sensors. bool sensorA = contact->m_fixtureA->m_isSensor; bool sensorB = contact->m_fixtureB->m_isSensor; if (sensorA || sensorB) { continue; } // Tentatively advance the body to the TOI. b2Sweep backup = other->m_sweep; if ((other->m_flags & b2Body::e_islandFlag) == 0) { other->Advance(minAlpha); } // Update the contact points contact->Update(m_contactManager.m_contactListener); // Was the contact disabled by the user? if (contact->IsEnabled() == false) { other->m_sweep = backup; other->SynchronizeTransform(); continue; } // Are there contact points? if (contact->IsTouching() == false) { other->m_sweep = backup; other->SynchronizeTransform(); continue; } // Add the contact to the island contact->m_flags |= b2Contact::e_islandFlag; island.Add(contact); // Has the other body already been added to the island? if (other->m_flags & b2Body::e_islandFlag) { continue; } // Add the other body to the island. other->m_flags |= b2Body::e_islandFlag; if (other->m_type != b2_staticBody) { other->SetAwake(true); } island.Add(other); } } } b2TimeStep subStep; subStep.dt = (1.0f - minAlpha) * step.dt; subStep.inv_dt = 1.0f / subStep.dt; subStep.dtRatio = 1.0f; subStep.positionIterations = 20; subStep.velocityIterations = step.velocityIterations; subStep.warmStarting = false; island.SolveTOI(subStep, bA->m_islandIndex, bB->m_islandIndex); // Reset island flags and synchronize broad-phase proxies. for (int32 i = 0; i < island.m_bodyCount; ++i) { b2Body* body = island.m_bodies[i]; body->m_flags &= ~b2Body::e_islandFlag; if (body->m_type != b2_dynamicBody) { continue; } body->SynchronizeFixtures(); // Invalidate all contact TOIs on this displaced body. for (b2ContactEdge* ce = body->m_contactList; ce; ce = ce->next) { ce->contact->m_flags &= ~(b2Contact::e_toiFlag | b2Contact::e_islandFlag); } } // Commit fixture proxy movements to the broad-phase so that new contacts are created. // Also, some contacts can be destroyed. m_contactManager.FindNewContacts(); if (m_subStepping) { m_stepComplete = false; break; } } } void b2World::Step(float32 dt, int32 velocityIterations, int32 positionIterations) { b2Timer stepTimer; // If new fixtures were added, we need to find the new contacts. if (m_flags & e_newFixture) { m_contactManager.FindNewContacts(); m_flags &= ~e_newFixture; } m_flags |= e_locked; b2TimeStep step; step.dt = dt; step.velocityIterations = velocityIterations; step.positionIterations = positionIterations; if (dt > 0.0f) { step.inv_dt = 1.0f / dt; } else { step.inv_dt = 0.0f; } step.dtRatio = m_inv_dt0 * dt; step.warmStarting = m_warmStarting; // Update contacts. This is where some contacts are destroyed. { b2Timer timer; m_contactManager.Collide(); m_profile.collide = timer.GetMilliseconds(); } // Integrate velocities, solve velocity constraints, and integrate positions. if (m_stepComplete && step.dt > 0.0f) { b2Timer timer; Solve(step); m_profile.solve = timer.GetMilliseconds(); } // Handle TOI events. if (m_continuousPhysics && step.dt > 0.0f) { b2Timer timer; SolveTOI(step); m_profile.solveTOI = timer.GetMilliseconds(); } if (step.dt > 0.0f) { m_inv_dt0 = step.inv_dt; } if (m_flags & e_clearForces) { ClearForces(); } m_flags &= ~e_locked; m_profile.step = stepTimer.GetMilliseconds(); } void b2World::ClearForces() { for (b2Body* body = m_bodyList; body; body = body->GetNext()) { body->m_force.SetZero(); body->m_torque = 0.0f; } } struct b2WorldQueryWrapper { bool QueryCallback(int32 proxyId) { b2FixtureProxy* proxy = (b2FixtureProxy*)broadPhase->GetUserData(proxyId); return callback->ReportFixture(proxy->fixture); } const b2BroadPhase* broadPhase; b2QueryCallback* callback; }; void b2World::QueryAABB(b2QueryCallback* callback, const b2AABB& aabb) const { b2WorldQueryWrapper wrapper; wrapper.broadPhase = &m_contactManager.m_broadPhase; wrapper.callback = callback; m_contactManager.m_broadPhase.Query(&wrapper, aabb); } struct b2WorldRayCastWrapper { float32 RayCastCallback(const b2RayCastInput& input, int32 proxyId) { void* userData = broadPhase->GetUserData(proxyId); b2FixtureProxy* proxy = (b2FixtureProxy*)userData; b2Fixture* fixture = proxy->fixture; int32 index = proxy->childIndex; b2RayCastOutput output; bool hit = fixture->RayCast(&output, input, index); if (hit) { float32 fraction = output.fraction; b2Vec2 point = (1.0f - fraction) * input.p1 + fraction * input.p2; return callback->ReportFixture(fixture, point, output.normal, fraction); } return input.maxFraction; } const b2BroadPhase* broadPhase; b2RayCastCallback* callback; }; void b2World::RayCast(b2RayCastCallback* callback, const b2Vec2& point1, const b2Vec2& point2) const { b2WorldRayCastWrapper wrapper; wrapper.broadPhase = &m_contactManager.m_broadPhase; wrapper.callback = callback; b2RayCastInput input; input.maxFraction = 1.0f; input.p1 = point1; input.p2 = point2; m_contactManager.m_broadPhase.RayCast(&wrapper, input); } void b2World::DrawShape(b2Fixture* fixture, const b2Transform& xf, const b2Color& color) { switch (fixture->GetType()) { case b2Shape::e_circle: { b2CircleShape* circle = (b2CircleShape*)fixture->GetShape(); b2Vec2 center = b2Mul(xf, circle->m_p); float32 radius = circle->m_radius; b2Vec2 axis = b2Mul(xf.q, b2Vec2(1.0f, 0.0f)); g_debugDraw->DrawSolidCircle(center, radius, axis, color); } break; case b2Shape::e_edge: { b2EdgeShape* edge = (b2EdgeShape*)fixture->GetShape(); b2Vec2 v1 = b2Mul(xf, edge->m_vertex1); b2Vec2 v2 = b2Mul(xf, edge->m_vertex2); g_debugDraw->DrawSegment(v1, v2, color); } break; case b2Shape::e_chain: { b2ChainShape* chain = (b2ChainShape*)fixture->GetShape(); int32 count = chain->m_count; const b2Vec2* vertices = chain->m_vertices; b2Vec2 v1 = b2Mul(xf, vertices[0]); for (int32 i = 1; i < count; ++i) { b2Vec2 v2 = b2Mul(xf, vertices[i]); g_debugDraw->DrawSegment(v1, v2, color); g_debugDraw->DrawCircle(v1, 0.05f, color); v1 = v2; } } break; case b2Shape::e_polygon: { b2PolygonShape* poly = (b2PolygonShape*)fixture->GetShape(); int32 vertexCount = poly->m_count; b2Assert(vertexCount <= b2_maxPolygonVertices); b2Vec2 vertices[b2_maxPolygonVertices]; for (int32 i = 0; i < vertexCount; ++i) { vertices[i] = b2Mul(xf, poly->m_vertices[i]); } g_debugDraw->DrawSolidPolygon(vertices, vertexCount, color); } break; default: break; } } void b2World::DrawJoint(b2Joint* joint) { b2Body* bodyA = joint->GetBodyA(); b2Body* bodyB = joint->GetBodyB(); const b2Transform& xf1 = bodyA->GetTransform(); const b2Transform& xf2 = bodyB->GetTransform(); b2Vec2 x1 = xf1.p; b2Vec2 x2 = xf2.p; b2Vec2 p1 = joint->GetAnchorA(); b2Vec2 p2 = joint->GetAnchorB(); b2Color color(0.5f, 0.8f, 0.8f); switch (joint->GetType()) { case e_distanceJoint: g_debugDraw->DrawSegment(p1, p2, color); break; case e_pulleyJoint: { b2PulleyJoint* pulley = (b2PulleyJoint*)joint; b2Vec2 s1 = pulley->GetGroundAnchorA(); b2Vec2 s2 = pulley->GetGroundAnchorB(); g_debugDraw->DrawSegment(s1, p1, color); g_debugDraw->DrawSegment(s2, p2, color); g_debugDraw->DrawSegment(s1, s2, color); } break; case e_mouseJoint: // don't draw this break; default: g_debugDraw->DrawSegment(x1, p1, color); g_debugDraw->DrawSegment(p1, p2, color); g_debugDraw->DrawSegment(x2, p2, color); } } void b2World::DrawDebugData() { if (g_debugDraw == NULL) { return; } uint32 flags = g_debugDraw->GetFlags(); if (flags & b2Draw::e_shapeBit) { for (b2Body* b = m_bodyList; b; b = b->GetNext()) { const b2Transform& xf = b->GetTransform(); for (b2Fixture* f = b->GetFixtureList(); f; f = f->GetNext()) { if (b->IsActive() == false) { DrawShape(f, xf, b2Color(0.5f, 0.5f, 0.3f)); } else if (b->GetType() == b2_staticBody) { DrawShape(f, xf, b2Color(0.5f, 0.9f, 0.5f)); } else if (b->GetType() == b2_kinematicBody) { DrawShape(f, xf, b2Color(0.5f, 0.5f, 0.9f)); } else if (b->IsAwake() == false) { DrawShape(f, xf, b2Color(0.6f, 0.6f, 0.6f)); } else { DrawShape(f, xf, b2Color(0.9f, 0.7f, 0.7f)); } } } } if (flags & b2Draw::e_jointBit) { for (b2Joint* j = m_jointList; j; j = j->GetNext()) { DrawJoint(j); } } if (flags & b2Draw::e_pairBit) { b2Color color(0.3f, 0.9f, 0.9f); for (b2Contact* c = m_contactManager.m_contactList; c; c = c->GetNext()) { //b2Fixture* fixtureA = c->GetFixtureA(); //b2Fixture* fixtureB = c->GetFixtureB(); //b2Vec2 cA = fixtureA->GetAABB().GetCenter(); //b2Vec2 cB = fixtureB->GetAABB().GetCenter(); //g_debugDraw->DrawSegment(cA, cB, color); } } if (flags & b2Draw::e_aabbBit) { b2Color color(0.9f, 0.3f, 0.9f); b2BroadPhase* bp = &m_contactManager.m_broadPhase; for (b2Body* b = m_bodyList; b; b = b->GetNext()) { if (b->IsActive() == false) { continue; } for (b2Fixture* f = b->GetFixtureList(); f; f = f->GetNext()) { for (int32 i = 0; i < f->m_proxyCount; ++i) { b2FixtureProxy* proxy = f->m_proxies + i; b2AABB aabb = bp->GetFatAABB(proxy->proxyId); b2Vec2 vs[4]; vs[0].Set(aabb.lowerBound.x, aabb.lowerBound.y); vs[1].Set(aabb.upperBound.x, aabb.lowerBound.y); vs[2].Set(aabb.upperBound.x, aabb.upperBound.y); vs[3].Set(aabb.lowerBound.x, aabb.upperBound.y); g_debugDraw->DrawPolygon(vs, 4, color); } } } } if (flags & b2Draw::e_centerOfMassBit) { for (b2Body* b = m_bodyList; b; b = b->GetNext()) { b2Transform xf = b->GetTransform(); xf.p = b->GetWorldCenter(); g_debugDraw->DrawTransform(xf); } } } int32 b2World::GetProxyCount() const { return m_contactManager.m_broadPhase.GetProxyCount(); } int32 b2World::GetTreeHeight() const { return m_contactManager.m_broadPhase.GetTreeHeight(); } int32 b2World::GetTreeBalance() const { return m_contactManager.m_broadPhase.GetTreeBalance(); } float32 b2World::GetTreeQuality() const { return m_contactManager.m_broadPhase.GetTreeQuality(); } void b2World::ShiftOrigin(const b2Vec2& newOrigin) { b2Assert((m_flags & e_locked) == 0); if ((m_flags & e_locked) == e_locked) { return; } for (b2Body* b = m_bodyList; b; b = b->m_next) { b->m_xf.p -= newOrigin; b->m_sweep.c0 -= newOrigin; b->m_sweep.c -= newOrigin; } for (b2Joint* j = m_jointList; j; j = j->m_next) { j->ShiftOrigin(newOrigin); } m_contactManager.m_broadPhase.ShiftOrigin(newOrigin); } void b2World::Dump() { if ((m_flags & e_locked) == e_locked) { return; } b2Log("b2Vec2 g(%.15lef, %.15lef);\n", m_gravity.x, m_gravity.y); b2Log("m_world->SetGravity(g);\n"); b2Log("b2Body** bodies = (b2Body**)b2Alloc(%d * sizeof(b2Body*));\n", m_bodyCount); b2Log("b2Joint** joints = (b2Joint**)b2Alloc(%d * sizeof(b2Joint*));\n", m_jointCount); int32 i = 0; for (b2Body* b = m_bodyList; b; b = b->m_next) { b->m_islandIndex = i; b->Dump(); ++i; } i = 0; for (b2Joint* j = m_jointList; j; j = j->m_next) { j->m_index = i; ++i; } // First pass on joints, skip gear joints. for (b2Joint* j = m_jointList; j; j = j->m_next) { if (j->m_type == e_gearJoint) { continue; } b2Log("{\n"); j->Dump(); b2Log("}\n"); } // Second pass on joints, only gear joints. for (b2Joint* j = m_jointList; j; j = j->m_next) { if (j->m_type != e_gearJoint) { continue; } b2Log("{\n"); j->Dump(); b2Log("}\n"); } b2Log("b2Free(joints);\n"); b2Log("b2Free(bodies);\n"); b2Log("joints = NULL;\n"); b2Log("bodies = NULL;\n"); }