Exemplo n.º 1
0
        public Physics()
        {
            // collision configuration contains default setup for memory, collision setup
            collisionConf = new DefaultCollisionConfiguration();
            dispatcher = new CollisionDispatcher(collisionConf);

            broadphase = new DbvtBroadphase();
            World = new DiscreteDynamicsWorld(dispatcher, broadphase, null, collisionConf);
            World.Gravity = new Vector3(0, -10, 0);

            // create the ground
            CollisionShape groundShape = new BoxShape(50, 50, 50);
            collisionShapes.Add(groundShape);
            CollisionObject ground = LocalCreateRigidBody(0, Matrix4.CreateTranslation(0, -50, 0), groundShape);
            ground.UserObject = "Ground";

            // create a few dynamic rigidbodies
            const float mass = 1.0f;

            CollisionShape colShape = new BoxShape(1);
            collisionShapes.Add(colShape);
            Vector3 localInertia = colShape.CalculateLocalInertia(mass);

            var rbInfo = new RigidBodyConstructionInfo(mass, null, colShape, localInertia);

            const float start_x = StartPosX - ArraySizeX / 2;
            const float start_y = StartPosY;
            const float start_z = StartPosZ - ArraySizeZ / 2;

            int k, i, j;
            for (k = 0; k < ArraySizeY; k++)
            {
                for (i = 0; i < ArraySizeX; i++)
                {
                    for (j = 0; j < ArraySizeZ; j++)
                    {
                        Matrix4 startTransform = Matrix4.CreateTranslation(
                            new Vector3(
                                2*i + start_x,
                                2*k + start_y,
                                2*j + start_z
                                )
                            );

                        // using motionstate is recommended, it provides interpolation capabilities
                        // and only synchronizes 'active' objects
                        rbInfo.MotionState = new DefaultMotionState(startTransform);

                        RigidBody body = new RigidBody(rbInfo);
                        
                        // make it drop from a height
                        body.Translate(new Vector3(0, 20, 0));

                        World.AddRigidBody(body);
                    }
                }
            }

            rbInfo.Dispose();
        }
Exemplo n.º 2
0
        static DefaultRigidBodyWorld()
        {
            // Broadphase algorithms are responsible for calculating bounding
            // boxes.  We should probably use an AABB Tree (DbvtBroadphase)
            // because they are generally good for worlds with lots of motion.
            // Sweep and Prune Broadphases are best when most of the world is
            // static.
            Broadphase = new DbvtBroadphase();
            CollisionConfiguration = new DefaultCollisionConfiguration();
            Dispatcher = new CollisionDispatcher(CollisionConfiguration);
            Solver = new SequentialImpulseConstraintSolver();

            DynamicsWorld = new DiscreteDynamicsWorld(Dispatcher, Broadphase, Solver, CollisionConfiguration);
            DynamicsWorld.Gravity = new Vector3(0F, 0F, -9.81F);

            Ground = PhysicsHelpers.MakePlane(new Vector3(0, 0, 1), 0);
            DynamicsWorld.AddRigidBody(Ground);
        }
Exemplo n.º 3
0
        protected override void OnInitializePhysics()
        {
            // collision configuration contains default setup for memory, collision setup
            CollisionConf = new DefaultCollisionConfiguration();

            // Use the default collision dispatcher. For parallel processing you can use a diffent dispatcher.
            Dispatcher = new CollisionDispatcher(CollisionConf);

            VoronoiSimplexSolver simplex = new VoronoiSimplexSolver();
            MinkowskiPenetrationDepthSolver pdSolver = new MinkowskiPenetrationDepthSolver();

            Convex2DConvex2DAlgorithm.CreateFunc convexAlgo2d = new Convex2DConvex2DAlgorithm.CreateFunc(simplex, pdSolver);

            Dispatcher.RegisterCollisionCreateFunc(BroadphaseNativeType.Convex2DShape, BroadphaseNativeType.Convex2DShape, convexAlgo2d);
            Dispatcher.RegisterCollisionCreateFunc(BroadphaseNativeType.Box2DShape, BroadphaseNativeType.Convex2DShape, convexAlgo2d);
            Dispatcher.RegisterCollisionCreateFunc(BroadphaseNativeType.Convex2DShape, BroadphaseNativeType.Box2DShape, convexAlgo2d);
            Dispatcher.RegisterCollisionCreateFunc(BroadphaseNativeType.Box2DShape, BroadphaseNativeType.Box2DShape, new Box2DBox2DCollisionAlgorithm.CreateFunc());

            Broadphase = new DbvtBroadphase();

            // the default constraint solver.
            Solver = new SequentialImpulseConstraintSolver();

            World = new DiscreteDynamicsWorld(Dispatcher, Broadphase, Solver, CollisionConf);
            World.Gravity = new Vector3(0, -10, 0);

            // create a few basic rigid bodies
            CollisionShape groundShape = new BoxShape(150, 7, 150);
            CollisionShapes.Add(groundShape);
            RigidBody ground = LocalCreateRigidBody(0, Matrix.Identity, groundShape);
            ground.UserObject = "Ground";

            // create a few dynamic rigidbodies
            // Re-using the same collision is better for memory usage and performance
            float u = 0.96f;
            Vector3[] points = { new Vector3(0, u, 0), new Vector3(-u, -u, 0), new Vector3(u, -u, 0) };
            ConvexShape childShape0 = new BoxShape(1, 1, Depth);
            ConvexShape colShape = new Convex2DShape(childShape0);
            ConvexShape childShape1 = new ConvexHullShape(points);
            ConvexShape colShape2 = new Convex2DShape(childShape1);
            ConvexShape childShape2 = new CylinderShapeZ(1, 1, Depth);
            ConvexShape colShape3 = new Convex2DShape(childShape2);

            CollisionShapes.Add(colShape);
            CollisionShapes.Add(colShape2);
            CollisionShapes.Add(colShape3);

            CollisionShapes.Add(childShape0);
            CollisionShapes.Add(childShape1);
            CollisionShapes.Add(childShape2);

            colShape.Margin = 0.03f;

            float mass = 1.0f;
            Vector3 localInertia = colShape.CalculateLocalInertia(mass);

            Matrix startTransform;

            Vector3 x = new Vector3(-ArraySizeX, 8, -20);
            Vector3 y = Vector3.Zero;
            Vector3 deltaX = new Vector3(1, 2, 0);
            Vector3 deltaY = new Vector3(2, 0, 0);

            int i, j;
            for (i = 0; i < ArraySizeY; i++)
            {
                y = x;
                for (j = 0; j < ArraySizeX; j++)
                {
                    startTransform = Matrix.Translation(y - new Vector3(-10, 0, 0));

                    //using motionstate is recommended, it provides interpolation capabilities, and only synchronizes 'active' objects
                    DefaultMotionState myMotionState = new DefaultMotionState(startTransform);

                    RigidBodyConstructionInfo rbInfo;
                    switch (j % 3)
                    {
                        case 0:
                            rbInfo = new RigidBodyConstructionInfo(mass, myMotionState, colShape, localInertia);
                            break;
                        case 1:
                            rbInfo = new RigidBodyConstructionInfo(mass, myMotionState, colShape3, localInertia);
                            break;
                        default:
                            rbInfo = new RigidBodyConstructionInfo(mass, myMotionState, colShape2, localInertia);
                            break;
                    }
                    RigidBody body = new RigidBody(rbInfo);
                    rbInfo.Dispose();
                    //body.ActivationState = ActivationState.IslandSleeping;
                    body.LinearFactor = new Vector3(1, 1, 0);
                    body.AngularFactor = new Vector3(0, 0, 1);

                    World.AddRigidBody(body);

                    y += deltaY;
                }
                x += deltaX;
            }
        }
Exemplo n.º 4
0
        protected override void OnInitializePhysics()
        {
            // collision configuration contains default setup for memory, collision setup
            CollisionConf = new DefaultCollisionConfiguration();
            Dispatcher = new CollisionDispatcher(CollisionConf);

            Broadphase = new DbvtBroadphase();

            World = new DiscreteDynamicsWorld(Dispatcher, Broadphase, null, CollisionConf);
            World.Gravity = new Vector3(0, -10, 0);

            GImpactCollisionAlgorithm.RegisterAlgorithm(Dispatcher);

            string bulletFile;
            string[] args = Environment.GetCommandLineArgs();
            if (args.Length == 1)
            {
                bulletFile = "testFile.bullet";
            }
            else
            {
                bulletFile = args[1];
            }

            fileLoader = new CustomBulletWorldImporter(World);
            if (!fileLoader.LoadFile(bulletFile))
            {
                CollisionShape groundShape = new BoxShape(50);
                CollisionShapes.Add(groundShape);
                RigidBody ground = LocalCreateRigidBody(0, Matrix.Translation(0, -50, 0), groundShape);
                ground.UserObject = "Ground";

                // create a few dynamic rigidbodies
                float mass = 1.0f;

                Vector3[] positions = new Vector3[2] { new Vector3(0.1f, 0.2f, 0.3f), new Vector3(0.4f, 0.5f, 0.6f) };
                float[] radi = new float[2] { 0.3f, 0.4f };

                CollisionShape colShape = new MultiSphereShape(positions, radi);

                //CollisionShape colShape = new CapsuleShapeZ(1, 1);
                //CollisionShape colShape = new CylinderShapeZ(1, 1, 1);
                //CollisionShape colShape = new BoxShape(1);
                //CollisionShape colShape = new SphereShape(1);
                CollisionShapes.Add(colShape);

                Vector3 localInertia = colShape.CalculateLocalInertia(mass);

                float start_x = StartPosX - ArraySizeX / 2;
                float start_y = StartPosY;
                float start_z = StartPosZ - ArraySizeZ / 2;

                int k, i, j;
                for (k = 0; k < ArraySizeY; k++)
                {
                    for (i = 0; i < ArraySizeX; i++)
                    {
                        for (j = 0; j < ArraySizeZ; j++)
                        {
                            Matrix startTransform = Matrix.Translation(
                                2 * i + start_x,
                                2 * k + start_y,
                                2 * j + start_z
                            );

                            // using motionstate is recommended, it provides interpolation capabilities
                            // and only synchronizes 'active' objects
                            DefaultMotionState myMotionState = new DefaultMotionState(startTransform);
                            RigidBodyConstructionInfo rbInfo =
                                new RigidBodyConstructionInfo(mass, myMotionState, colShape, localInertia);
                            RigidBody body = new RigidBody(rbInfo);
                            rbInfo.Dispose();

                            // make it drop from a height
                            body.Translate(new Vector3(0, 20, 0));

                            World.AddRigidBody(body);
                        }
                    }
                }

                DefaultSerializer serializer = new DefaultSerializer();

                serializer.RegisterNameForObject(ground, "GroundName");

                for (i = 0; i < CollisionShapes.Count; i++)
                    serializer.RegisterNameForObject(CollisionShapes[i], "name" + i.ToString());

                Point2PointConstraint p2p = new Point2PointConstraint((RigidBody)World.CollisionObjectArray[2], new Vector3(0, 1, 0));
                World.AddConstraint(p2p);

                serializer.RegisterNameForObject(p2p, "constraintje");

                World.Serialize(serializer);

                BulletSharp.DataStream data = serializer.LockBuffer();
                byte[] dataBytes = new byte[data.Length];
                data.Read(dataBytes, 0, dataBytes.Length);

                FileStream file = new FileStream("testFile.bullet", FileMode.Create);
                file.Write(dataBytes, 0, dataBytes.Length);
                file.Close();
            }
        }
        protected override void OnInitializePhysics()
        {
            // collision configuration contains default setup for memory, collision setup
            CollisionConf = new DefaultCollisionConfiguration();
            Dispatcher = new CollisionDispatcher(CollisionConf);

            Broadphase = new DbvtBroadphase();

            World = new DiscreteDynamicsWorld(Dispatcher, Broadphase, null, CollisionConf);
            World.Gravity = new Vector3(0, -10, 0);

            // create the ground
            CollisionShape groundShape = new BoxShape(20, 50, 10);
            CollisionShapes.Add(groundShape);
            CollisionObject ground = LocalCreateRigidBody(0,
                Matrix.RotationAxis(new Vector3(0, 0, 1), (float)Math.PI * 0.03f) * Matrix.Translation(0, -50, 0),
                groundShape);
            ground.Friction = 1;
            ground.RollingFriction = 1;
            ground.UserObject = "Ground";

            groundShape = new BoxShape(100, 50, 100);
            CollisionShapes.Add(groundShape);
            ground = LocalCreateRigidBody(0, Matrix.Translation(0, -54, 0), groundShape);
            ground.Friction = 1;
            ground.RollingFriction = 1;
            ground.UserObject = "Ground";

            // create a few dynamic rigidbodies
            CollisionShape[] colShapes = {
                new SphereShape(1),
                new CapsuleShape(0.5f,1),
                new CapsuleShapeX(0.5f,1),
                new CapsuleShapeZ(0.5f,1),
                new ConeShape(0.5f,1),
                new ConeShapeX(0.5f,1),
                new ConeShapeZ(0.5f,1),
                new CylinderShape(new Vector3(0.5f,1,0.5f)),
                new CylinderShapeX(new Vector3(1,0.5f,0.5f)),
                new CylinderShapeZ(new Vector3(0.5f,0.5f,1)),
            };
            foreach (var collisionShape in colShapes)
            {
                CollisionShapes.Add(collisionShape);
            }

            const float mass = 1.0f;

            CollisionShape colShape = new BoxShape(1);
            CollisionShapes.Add(colShape);
            Vector3 localInertia = colShape.CalculateLocalInertia(mass);

            var rbInfo = new RigidBodyConstructionInfo(mass, null, null, localInertia);

            const float startX = StartPosX - ArraySizeX / 2;
            const float startY = StartPosY;
            const float startZ = StartPosZ - ArraySizeZ / 2;

            int shapeIndex = 0;
            for (int k = 0; k < ArraySizeY; k++)
            {
                for (int i = 0; i < ArraySizeX; i++)
                {
                    for (int j = 0; j < ArraySizeZ; j++)
                    {
                        Matrix startTransform = Matrix.Translation(
                            2 * i + startX,
                            2 * k + startY + 20,
                            2 * j + startZ
                        );
                        shapeIndex++;

                        // using motionstate is recommended, it provides interpolation capabilities
                        // and only synchronizes 'active' objects
                        rbInfo.MotionState = new DefaultMotionState(startTransform);
                        rbInfo.CollisionShape = colShapes[shapeIndex % colShapes.Length];

                        RigidBody body = new RigidBody(rbInfo);
                        body.Friction = 1;
                        body.RollingFriction = 0.3f;
                        body.SetAnisotropicFriction(colShape.AnisotropicRollingFrictionDirection, AnisotropicFrictionFlags.RollingFriction);

                        World.AddRigidBody(body);
                    }
                }
            }

            rbInfo.Dispose();
        }
Exemplo n.º 6
0
        protected override void OnInitializePhysics()
        {
            // collision configuration contains default setup for memory, collision setup
            CollisionConf = new DefaultCollisionConfiguration();
            Dispatcher = new CollisionDispatcher(CollisionConf);

            Broadphase = new DbvtBroadphase();

            World = new DiscreteDynamicsWorld(Dispatcher, Broadphase, null, CollisionConf);
            World.Gravity = new Vector3(0, -10, 0);

            // create the ground
            BoxShape groundShape = new BoxShape(50, 1, 50);
            //groundShape.InitializePolyhedralFeatures();
            //CollisionShape groundShape = new StaticPlaneShape(new Vector3(0,1,0), 50);

            CollisionShapes.Add(groundShape);
            CollisionObject ground = LocalCreateRigidBody(0, Matrix.Identity, groundShape);
            ground.UserObject = "Ground";

            // create a few dynamic rigidbodies
            const float mass = 1.0f;

            BoxShape colShape = new BoxShape(1);
            CollisionShapes.Add(colShape);
            Vector3 localInertia = colShape.CalculateLocalInertia(mass);

            const float startX = StartPosX - ArraySizeX / 2;
            const float startY = StartPosY;
            const float startZ = StartPosZ - ArraySizeZ / 2;

            RigidBodyConstructionInfo rbInfo =
                new RigidBodyConstructionInfo(mass, null, colShape, localInertia);

            int k, i, j;
            for (k = 0; k < ArraySizeY; k++)
            {
                for (i = 0; i < ArraySizeX; i++)
                {
                    for (j = 0; j < ArraySizeZ; j++)
                    {
                        Matrix startTransform = Matrix.Translation(
                            2 * i + startX,
                            2 * k + startY,
                            2 * j + startZ
                        );

                        // using motionstate is recommended, it provides interpolation capabilities
                        // and only synchronizes 'active' objects
                        rbInfo.MotionState = new DefaultMotionState(startTransform);
                        RigidBody body = new RigidBody(rbInfo);

                        // make it drop from a height
                        body.Translate(new Vector3(0, 20, 0));

                        World.AddRigidBody(body);
                    }
                }
            }
            rbInfo.Dispose();
        }
    void Start()
    {
        //Create a World
        Debug.Log("Initialize physics");
        List<CollisionShape> CollisionShapes = new List<CollisionShape>();

        DefaultCollisionConfiguration CollisionConf = new DefaultCollisionConfiguration();
        CollisionDispatcher Dispatcher = new CollisionDispatcher(CollisionConf);

        DbvtBroadphase Broadphase = new DbvtBroadphase();

        DiscreteDynamicsWorld World = new DiscreteDynamicsWorld(Dispatcher, Broadphase, null, CollisionConf);
        World.Gravity = new BulletSharp.Math.Vector3(0, -10, 0);

        // create a few dynamic rigidbodies
        const float mass = 1.0f;
        //Add a single cube
        RigidBody fallRigidBody;
        BoxShape shape = new BoxShape(1f, 1f, 1f);
        BulletSharp.Math.Vector3 localInertia = BulletSharp.Math.Vector3.Zero;
        shape.CalculateLocalInertia(mass, out localInertia);
        RigidBodyConstructionInfo rbInfo = new RigidBodyConstructionInfo(mass, null, shape, localInertia);
        fallRigidBody = new RigidBody(rbInfo);
        rbInfo.Dispose();
        Matrix st = Matrix.Translation(new BulletSharp.Math.Vector3(0f, 10f, 0f));
        fallRigidBody.WorldTransform = st;
        World.AddRigidBody(fallRigidBody);

        //Step the simulation 300 steps
        for (int i = 0; i < 300; i++)
        {
            World.StepSimulation(1f / 60f, 10);

            Matrix trans;
            fallRigidBody.GetWorldTransform(out trans);

            Debug.Log("box height: " + trans.Origin);
        }

        //Clean up.
        World.RemoveRigidBody(fallRigidBody);
        fallRigidBody.Dispose();

        UnityEngine.Debug.Log("ExitPhysics");
        if (World != null)
        {
            //remove/dispose constraints
            int i;
            for (i = World.NumConstraints - 1; i >= 0; i--)
            {
                TypedConstraint constraint = World.GetConstraint(i);
                World.RemoveConstraint(constraint);
                constraint.Dispose();
            }

            //remove the rigidbodies from the dynamics world and delete them
            for (i = World.NumCollisionObjects - 1; i >= 0; i--)
            {
                CollisionObject obj = World.CollisionObjectArray[i];
                RigidBody body = obj as RigidBody;
                if (body != null && body.MotionState != null)
                {
                    body.MotionState.Dispose();
                }
                World.RemoveCollisionObject(obj);
                obj.Dispose();
            }

            //delete collision shapes
            foreach (CollisionShape ss in CollisionShapes)
                ss.Dispose();
            CollisionShapes.Clear();

            World.Dispose();
            Broadphase.Dispose();
            Dispatcher.Dispose();
            CollisionConf.Dispose();
        }

        if (Broadphase != null)
        {
            Broadphase.Dispose();
        }
        if (Dispatcher != null)
        {
            Dispatcher.Dispose();
        }
        if (CollisionConf != null)
        {
            CollisionConf.Dispose();
        }
    }
    //IMPORTANT Time.fixedTime must match the timestep being used here.
    public static List<UnityEngine.Vector3> SimulateBall(BRigidBody ballRb, UnityEngine.Vector3 ballThrowForce, int numberOfSimulationSteps, bool reverseOrder)
    {
        var ballPositions = new List<UnityEngine.Vector3>(numberOfSimulationSteps);

        //Create a World
        Debug.Log("Initialize physics");

        CollisionConfiguration CollisionConf;
        CollisionDispatcher Dispatcher;
        BroadphaseInterface Broadphase;
        CollisionWorld cw;
        SequentialImpulseConstraintSolver Solver;
        BulletSharp.SoftBody.SoftBodyWorldInfo softBodyWorldInfo;

        //This should create a copy of the BPhysicsWorld with the same settings
        BPhysicsWorld bw = BPhysicsWorld.Get();
        bw.CreatePhysicsWorld(out cw, out CollisionConf, out Dispatcher, out Broadphase, out Solver, out softBodyWorldInfo);
        World = (DiscreteDynamicsWorld) cw;

        //Copy all existing rigidbodies in scene
        // IMPORTANT rigidbodies must be added to the offline world in the same order that they are in the source world
        // this is because collisions must be resolved in the same order for the sim to be deterministic
        DiscreteDynamicsWorld sourceWorld = (DiscreteDynamicsWorld) bw.world;
        BulletSharp.RigidBody bulletBallRb = null;
        BulletSharp.Math.Matrix mm = BulletSharp.Math.Matrix.Identity;
        for(int i = 0; i < sourceWorld.NumCollisionObjects; i++)
        {
            CollisionObject co = sourceWorld.CollisionObjectArray[i];
            if (co != null && co.UserObject is BRigidBody)
            {
                BRigidBody rb = (BRigidBody) co.UserObject;
                float mass = rb.isDynamic() ? rb.mass : 0f;
                BCollisionShape existingShape = rb.GetComponent<BCollisionShape>();
                CollisionShape shape = null;
                if (existingShape is BSphereShape)
                {
                    shape = ((BSphereShape)existingShape).CopyCollisionShape();
                }
                else if (existingShape is BBoxShape)
                {
                    shape = ((BBoxShape)existingShape).CopyCollisionShape();
                }

                RigidBody bulletRB = null;
                BulletSharp.Math.Vector3 localInertia = new BulletSharp.Math.Vector3();
                rb.CreateOrConfigureRigidBody(ref bulletRB, ref localInertia, shape, null);
                BulletSharp.Math.Vector3 pos = rb.GetCollisionObject().WorldTransform.Origin;
                BulletSharp.Math.Quaternion rot = rb.GetCollisionObject().WorldTransform.GetOrientation();
                BulletSharp.Math.Matrix.AffineTransformation(1f, ref rot, ref pos, out mm);
                bulletRB.WorldTransform = mm;
                World.AddRigidBody(bulletRB, rb.groupsIBelongTo, rb.collisionMask);
                if (rb == ballRb)
                {
                    bulletBallRb = bulletRB;
                    bulletRB.ApplyCentralImpulse(ballThrowForce.ToBullet());
                }
            }
        }

        //Step the simulation numberOfSimulationSteps times
        for (int i = 0; i < numberOfSimulationSteps; i++)
        {
            int numSteps = World.StepSimulation(1f / 60f, 10, 1f / 60f);
            ballPositions.Add(bulletBallRb.WorldTransform.Origin.ToUnity());
        }

        UnityEngine.Debug.Log("ExitPhysics");
        if (World != null)
        {
            //remove/dispose constraints
            int i;
            for (i = World.NumConstraints - 1; i >= 0; i--)
            {
                TypedConstraint constraint = World.GetConstraint(i);
                World.RemoveConstraint(constraint);
                constraint.Dispose();
            }

            //remove the rigidbodies from the dynamics world and delete them
            for (i = World.NumCollisionObjects - 1; i >= 0; i--)
            {
                CollisionObject obj = World.CollisionObjectArray[i];
                RigidBody body = obj as RigidBody;
                if (body != null && body.MotionState != null)
                {
                    body.MotionState.Dispose();
                }
                World.RemoveCollisionObject(obj);
                obj.Dispose();
            }

            World.Dispose();
            Broadphase.Dispose();
            Dispatcher.Dispose();
            CollisionConf.Dispose();
        }

        if (Broadphase != null)
        {
            Broadphase.Dispose();
        }
        if (Dispatcher != null)
        {
            Dispatcher.Dispose();
        }
        if (CollisionConf != null)
        {
            CollisionConf.Dispose();
        }

        return ballPositions;
    }