Exemplo n.º 1
0
		private void SolveTOI(TimeStep step){
			Island island = new Island(m_contactManager.m_contactListener);

			if (m_stepComplete)
			{
			    foreach (Body b in m_bodyList)
			    {
			        b.m_flags &= ~Body.BodyFlags.e_islandFlag;
			        b.m_sweep.alpha0 = 0.0f;
			    }

			    foreach (Contact c in m_contactManager.m_contactList)
			    {
			        // Invalidate TOI
			        c.m_flags &= ~(ContactFlags.e_toiFlag | ContactFlags.e_islandFlag);
			        c.m_toiCount = 0;
			        c.m_toi = 1.0f;
			    }
			}

			Fixture fA = null;
			Fixture fB = null;
			Body bA = null;
			Body bB = null;

			// Find TOI events and solve them.
			for (;;)
			{
			    // Find the first TOI.
			    Contact minContact = null;
			    float minAlpha = 1.0f;

			    foreach (Contact c in m_contactManager.m_contactList)
			    {
			        // Is this contact disabled?
			        if (c.IsEnabled() == false)
			        {
			            continue;
			        }

			        // Prevent excessive sub-stepping.
			        if (c.m_toiCount > Settings._maxSubSteps)
			        {
			            continue;
			        }

					

			        float alpha = 1.0f;
			        if (c.m_flags.HasFlag(ContactFlags.e_toiFlag))
			        {
			            // This contact has a valid cached TOI.
			            alpha = c.m_toi;
			        }
			        else
			        {
			            fA = c.FixtureA;
			            fB = c.FixtureB;

			            // Is there a sensor?
			            if (fA.IsSensor || fB.IsSensor)
			            {
			                continue;
			            }

			            bA = fA.GetBody();
			            bB = fB.GetBody();

			            BodyType typeA = bA.m_type;
			            BodyType typeB = bB.m_type;
			            Utilities.Assert(typeA == BodyType._dynamicBody || typeB == BodyType._dynamicBody);

			            bool activeA = bA.IsAwake() && typeA != BodyType._staticBody;
			            bool activeB = bB.IsAwake() && typeB != BodyType._staticBody;

			            // Is at least one body active (awake and dynamic or kinematic)?
			            if (activeA == false && activeB == false)
			            {
			                continue;
			            }

			            bool collideA = bA.IsBullet() || typeA != BodyType._dynamicBody;
			            bool collideB = bB.IsBullet() || typeB != BodyType._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.
			            float 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);
			            }

			            Utilities.Assert(alpha0 < 1.0f);

			            int indexA = c.GetChildIndexA();
			            int indexB = c.GetChildIndexB();

			            // Compute the time of impact in interval [0, minTOI]
			            TOIInput input = new TOIInput();
			            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;

			            TOIOutput output;
			            Utilities.TimeOfImpact(out output, input);

			            // Beta is the fraction of the remaining portion of the .
			            float beta = output.t;
			            if (output.state == TOIOutput.State.e_touching)
			            {
			                alpha = Math.Min(alpha0 + (1.0f - alpha0) * beta, 1.0f);
			            }
			            else
			            {
			                alpha = 1.0f;
			            }

			            c.m_toi = alpha;
			            c.m_flags |= ContactFlags.e_toiFlag;
			        }

			        if (alpha < minAlpha)
			        {
			            // This is the minimum TOI found so far.
			            minContact = c;
			            minAlpha = alpha;
			        }
			    }

			    if (minContact == null || 1.0f - 10.0f * Single.Epsilon < minAlpha)
			    {
			        // No more TOI events. Done!
			        m_stepComplete = true;
			        break;
			    }

			    // Advance the bodies to the TOI.
			    fA = minContact.FixtureA;
			    fB = minContact.FixtureB;
			    bA = fA.GetBody();
			    bB = fB.GetBody();

			    Sweep backup1 = bA.m_sweep;
			    Sweep 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 &= ~ContactFlags.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 |= Body.BodyFlags.e_islandFlag;
			    bB.m_flags |= Body.BodyFlags.e_islandFlag;
			    minContact.m_flags |= ContactFlags.e_islandFlag;

			    // Get contacts on bodyA and bodyB.
			    Body[] bodies = {bA, bB};
			    for (int i = 0; i < 2; ++i)
			    {
			        Body body = bodies[i];
			        if (body.m_type == BodyType._dynamicBody)
			        {
						foreach (ContactEdge ce in body.m_contactList)
			            {
							throw new NotImplementedException();

							//if (island.m_bodies.Count() == island.m_bodyCapacity)
							//{
							//    break;
							//}

							//if (island.m_bodies.Count() == island.m_contactCapacity)
							//{
							//    break;
							//}

							//Contact* contact = ce.contact;

							//// Has this contact already been added to the island?
							//if (contact.m_flags & ContactFlags.e_islandFlag)
							//{
							//    continue;
							//}

							//// Only add static, kinematic, or bullet bodies.
							//Body* other = ce.other;
							//if (other.m_type == _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.
							//Sweep backup = other.m_sweep;
							//if ((other.m_flags & Body.BodyFlags.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 |= ContactFlags.e_islandFlag;
							//island.Add(contact);

							//// Has the other body already been added to the island?
							//if (other.m_flags & Body.BodyFlags.e_islandFlag)
							//{
							//    continue;
							//}
					
							//// Add the other body to the island.
							//other.m_flags |= Body.BodyFlags.e_islandFlag;

							//if (other.m_type != _staticBody)
							//{
							//    other.SetAwake(true);
							//}

							//island.Add(other);
			            }
			        }
			    }

			    TimeStep 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 (int i = 0; i < island.m_bodies.Count(); ++i)
			    {
					throw new NotImplementedException();
					//Body* body = island.m_bodies[i];
					//body.m_flags &= ~Body.BodyFlags.e_islandFlag;

					//if (body.m_type != _dynamicBody)
					//{
					//    continue;
					//}

					//body.SynchronizeFixtures();

					//// Invalidate all contact TOIs on this displaced body.
					//for (ContactEdge* ce = body.m_contactList; ce; ce = ce.next)
					//{
					//    ce.contact.m_flags &= ~(ContactFlags.e_toiFlag | ContactFlags.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;
			    }
			}
		}
Exemplo n.º 2
0
        void Solve(ref TimeStep step)
        {
            // Size the island for the worst case.
            _island.Reset(_bodyCount,
                          _contactManager._contactCount,
                          _jointCount,
                          _contactManager.ContactListener);

            // Clear all the island flags.
            for (Body b = _bodyList; b != null; b = b._next)
            {
                b._flags &= ~BodyFlags.Island;
            }
            for (Contact c = _contactManager._contactList; c != null; c = c._next)
            {
                c._flags &= ~ContactFlags.Island;
            }
            for (Joint j = _jointList; j != null; j = j._next)
            {
                j._islandFlag = false;
            }

            // Build and simulate all awake islands.
            int stackSize = _bodyCount;

            if (stackSize > stack.Length)
            {
                stack = new Body[Math.Max(stack.Length * 2, stackSize)];
            }

            for (Body seed = _bodyList; seed != null; seed = seed._next)
            {
                if ((seed._flags & (BodyFlags.Island)) != BodyFlags.None)
                {
                    continue;
                }

                if (seed.IsAwake() == false || seed.IsActive() == false)
                {
                    continue;
                }

                // The seed can be dynamic or kinematic.
                if (seed.GetType() == BodyType.Static)
                {
                    continue;
                }

                // Reset island and stack.
                _island.Clear();
                int stackCount = 0;
                stack[stackCount++] = seed;
                seed._flags        |= BodyFlags.Island;

                // Perform a depth first search (DFS) on the raint graph.
                while (stackCount > 0)
                {
                    // Grab the next body off the stack and add it to the island.
                    Body b = stack[--stackCount];
                    //Debug.Assert(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() == BodyType.Static)
                    {
                        continue;
                    }

                    // Search all contacts connected to this body.
                    for (ContactEdge ce = b._contactList; ce != null; ce = ce.Next)
                    {
                        Contact contact = ce.Contact;

                        // Has this contact already been added to an island?
                        if ((contact._flags & ContactFlags.Island) != ContactFlags.None)
                        {
                            continue;
                        }

                        // Is this contact solid and touching?
                        if (!ce.Contact.IsEnabled() || !ce.Contact.IsTouching())
                        {
                            continue;
                        }

                        // Skip sensors.
                        bool sensorA = contact._fixtureA._isSensor;
                        bool sensorB = contact._fixtureB._isSensor;
                        if (sensorA || sensorB)
                        {
                            continue;
                        }

                        _island.Add(contact);
                        contact._flags |= ContactFlags.Island;

                        Body other = ce.Other;

                        // Was the other body already added to this island?
                        if ((other._flags & BodyFlags.Island) != BodyFlags.None)
                        {
                            continue;
                        }

                        //Debug.Assert(stackCount < stackSize);
                        stack[stackCount++] = other;
                        other._flags       |= BodyFlags.Island;
                    }

                    // Search all joints connect to this body.
                    for (JointEdge je = b._jointList; je != null; je = je.Next)
                    {
                        if (je.Joint._islandFlag == true)
                        {
                            continue;
                        }

                        Body other = je.Other;

                        // Don't simulate joints connected to inactive bodies.
                        if (other.IsActive() == false)
                        {
                            continue;
                        }

                        _island.Add(je.Joint);
                        je.Joint._islandFlag = true;

                        if ((other._flags & BodyFlags.Island) != BodyFlags.None)
                        {
                            continue;
                        }

                        //Debug.Assert(stackCount < stackSize);
                        stack[stackCount++] = other;
                        other._flags       |= BodyFlags.Island;
                    }
                }

                _island.Solve(ref step, Gravity, _allowSleep);

                // Post solve cleanup.
                for (int i = 0; i < _island._bodyCount; ++i)
                {
                    // Allow static bodies to participate in other islands.
                    Body b = _island._bodies[i];
                    if (b.GetType() == BodyType.Static)
                    {
                        b._flags &= ~BodyFlags.Island;
                    }
                }
            }

            // Synchronize fixtures, check for out of range bodies.
            for (Body b = _bodyList; b != null; b = b.GetNext())
            {
                // If a body was not in an island then it did not move.
                if ((b._flags & BodyFlags.Island) != BodyFlags.Island)
                {
                    continue;
                }

                if (b.GetType() == BodyType.Static)
                {
                    continue;
                }

                // Update fixtures (for broad-phase).
                b.SynchronizeFixtures();
            }

            // Look for new contacts.
            _contactManager.FindNewContacts();
        }
Exemplo n.º 3
0
		private void Solve(TimeStep step){
			m_profile.solveInit = 0.0f;
			m_profile.solveVelocity = 0.0f;
			m_profile.solvePosition = 0.0f;

			// Size the island for the worst case.
			Island island = new Island(m_contactManager.m_contactListener);

			// Clear all the island flags.
			foreach (Body b in m_bodyList)
			{
			    b.m_flags &= ~Body.BodyFlags.e_islandFlag;
			}
			foreach (Contact c in m_contactManager.m_contactList)
			{
			    c.m_flags &= ~ContactFlags.e_islandFlag;
			}
			foreach (Joint j in m_jointList)
			{
			    j.m_islandFlag = false;
			}

			// Build and simulate all awake islands.
			List<Body> stack = new List<Body>(m_bodyList.Count());
			foreach (Body seed in m_bodyList)
			{
			    if (seed.m_flags.HasFlag(Body.BodyFlags.e_islandFlag))
			    {
			        continue;
			    }

			    if (seed.IsAwake() == false || seed.IsActive() == false)
			    {
			        continue;
			    }

			    // The seed can be dynamic or kinematic.
			    if (seed.GetBodyType() == BodyType._staticBody)
			    {
			        continue;
			    }

			    // Reset island and stack.
			    island.Clear();
			    int stackCount = 0;
				stack.Add(seed); stackCount++;
			    seed.m_flags |= Body.BodyFlags.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.
			        Body b = stack[--stackCount];
			        Utilities.Assert(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.GetBodyType() == BodyType._staticBody)
			        {
			            continue;
			        }

			        // Search all contacts connected to this body.
			        foreach (ContactEdge ce in b.m_contactList)
			        {
			            Contact contact = ce.contact;

			            // Has this contact already been added to an island?
			            if (contact.m_flags.HasFlag(ContactFlags.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 |= ContactFlags.e_islandFlag;

			            Body other = ce.other;

			            // Was the other body already added to this island?
			            if (other.m_flags.HasFlag(Body.BodyFlags.e_islandFlag))
			            {
			                continue;
			            }

			            Utilities.Assert(stackCount < m_bodyList.Count());
						stack.Add(other); stackCount++;
			            other.m_flags |= Body.BodyFlags.e_islandFlag;
			        }

					// Search all joints connect to this body.
					foreach (JointEdge je in b.m_jointList){
						if (je.joint.m_islandFlag == true) {
							continue;
						}

						Body 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.HasFlag(Body.BodyFlags.e_islandFlag)) {
							continue;
						}

						stack.Add(other); stackCount++;
						other.m_flags |= Body.BodyFlags.e_islandFlag;
					}
			    }

			    Profile profile = new 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 (int i = 0; i < island.m_bodies.Count(); ++i) {
					// Allow static bodies to participate in other islands.
					Body b = island.m_bodies[i];
					if (b.GetBodyType() == BodyType._staticBody) {
						b.m_flags &= ~Body.BodyFlags.e_islandFlag;
					}
				}
			}

			{
			    Timer timer = new Timer();
			    // Synchronize fixtures, check for out of range bodies.
			    foreach (Body b in m_bodyList)
			    {
			        // If a body was not in an island then it did not move.
			        if ((b.m_flags & Body.BodyFlags.e_islandFlag) == 0)
			        {
			            continue;
			        }

			        if (b.GetBodyType() == BodyType._staticBody)
			        {
			            continue;
			        }

			        // Update fixtures (for broad-phase).
			        b.SynchronizeFixtures();
			    }

			    // Look for new contacts.
			    m_contactManager.FindNewContacts();
			    m_profile.broadphase = timer.GetMilliseconds();
			}
		}
Exemplo n.º 4
0
        internal override void SolveVelocityConstraints(ref TimeStep step)
        {
            Body b1 = _bodyA;
            Body b2 = _bodyB;

            Vector2 v1 = b1._linearVelocity;
            float   w1 = b1._angularVelocity;
            Vector2 v2 = b2._linearVelocity;
            float   w2 = b2._angularVelocity;

            // Solve linear motor constraint.
            if (_enableMotor && _limitState != LimitState.Equal)
            {
                float Cdot       = Vector2.Dot(_axis, v2 - v1) + _a2 * w2 - _a1 * w1;
                float impulse    = _motorMass * (_motorSpeed - Cdot);
                float oldImpulse = _motorImpulse;
                float maxImpulse = step.dt * _maxMotorForce;
                _motorImpulse = MathUtils.Clamp(_motorImpulse + impulse, -maxImpulse, maxImpulse);
                impulse       = _motorImpulse - oldImpulse;

                Vector2 P  = impulse * _axis;
                float   L1 = impulse * _a1;
                float   L2 = impulse * _a2;

                v1 -= _invMassA * P;
                w1 -= _invIA * L1;

                v2 += _invMassB * P;
                w2 += _invIB * L2;
            }

            float Cdot1 = Vector2.Dot(_perp, v2 - v1) + _s2 * w2 - _s1 * w1;

            if (_enableLimit && _limitState != LimitState.Inactive)
            {
                // Solve prismatic and limit constraint in block form.
                float   Cdot2 = Vector2.Dot(_axis, v2 - v1) + _a2 * w2 - _a1 * w1;
                Vector2 Cdot  = new Vector2(Cdot1, Cdot2);

                Vector2 f1 = _impulse;
                Vector2 df = _K.Solve(-Cdot);
                _impulse += df;

                if (_limitState == LimitState.AtLower)
                {
                    _impulse.y = Math.Max(_impulse.y, 0.0f);
                }
                else if (_limitState == LimitState.AtUpper)
                {
                    _impulse.y = Math.Min(_impulse.y, 0.0f);
                }

                // f2(1) = invK(1,1) * (-Cdot(1) - K(1,2) * (f2(2) - f1(2))) + f1(1)
                float b = -Cdot1 - (_impulse.y - f1.y) * _K.col2.x;

                float f2r;
                if (_K.col1.x != 0.0f)
                {
                    f2r = b / _K.col1.x + f1.x;
                }
                else
                {
                    f2r = f1.x;
                }

                _impulse.x = f2r;

                df = _impulse - f1;

                Vector2 P  = df.x * _perp + df.y * _axis;
                float   L1 = df.x * _s1 + df.y * _a1;
                float   L2 = df.x * _s2 + df.y * _a2;

                v1 -= _invMassA * P;
                w1 -= _invIA * L1;

                v2 += _invMassB * P;
                w2 += _invIB * L2;
            }
            else
            {
                // Limit is inactive, just solve the prismatic constraint in block form.

                float df;
                if (_K.col1.x != 0.0f)
                {
                    df = -Cdot1 / _K.col1.x;
                }
                else
                {
                    df = 0.0f;
                }

                _impulse.x += df;

                Vector2 P  = df * _perp;
                float   L1 = df * _s1;
                float   L2 = df * _s2;

                v1 -= _invMassA * P;
                w1 -= _invIA * L1;

                v2 += _invMassB * P;
                w2 += _invIB * L2;
            }

            b1._linearVelocity  = v1;
            b1._angularVelocity = w1;
            b2._linearVelocity  = v2;
            b2._angularVelocity = w2;
        }
Exemplo n.º 5
0
        internal override void InitVelocityConstraints(ref TimeStep step)
        {
            Body b1 = _bodyA;
            Body b2 = _bodyB;

            Transform xf1, xf2;

            b1.GetTransform(out xf1);
            b2.GetTransform(out xf2);

            // Compute the effective mass matrix.
            Vector2 r1 = MathUtils.Multiply(ref xf1.R, _localAnchor1 - b1.GetLocalCenter());
            Vector2 r2 = MathUtils.Multiply(ref xf2.R, _localAnchor2 - b2.GetLocalCenter());

            _u = b2._sweep.c + r2 - b1._sweep.c - r1;

            // Handle singularity.
            float length = _u.magnitude;

            if (length < _length)
            {
                return;
            }

            if (length > Settings.b2_linearSlop)
            {
                _u *= 1.0f / length;
            }
            else
            {
                _u = new Vector2(0.0f, 0.0f);
            }

            float cr1u    = MathUtils.Cross(r1, _u);
            float cr2u    = MathUtils.Cross(r2, _u);
            float invMass = b1._invMass + b1._invI * cr1u * cr1u + b2._invMass + b2._invI * cr2u * cr2u;

            //Debug.Assert(invMass > Settings.b2_epsilon);
            _mass = invMass != 0.0f ? 1.0f / invMass : 0.0f;

            if (_frequencyHz > 0.0f)
            {
                float C = length - _length;

                // Frequency
                float omega = 2.0f * Settings.b2_pi * _frequencyHz;

                // Damping coefficient
                float d = 2.0f * _mass * _dampingRatio * omega;

                // Spring stiffness
                float k = _mass * omega * omega;

                // magic formulas
                _gamma = step.dt * (d + step.dt * k);
                _gamma = _gamma != 0.0f ? 1.0f / _gamma : 0.0f;
                _bias  = C * step.dt * k * _gamma;

                _mass = invMass + _gamma;
                _mass = _mass != 0.0f ? 1.0f / _mass : 0.0f;
            }

            if (step.warmStarting)
            {
                // Scale the impulse to support a variable time step.
                _impulse *= step.dtRatio;

                Vector2 P = _impulse * _u;
                b1._linearVelocity  -= b1._invMass * P;
                b1._angularVelocity -= b1._invI * MathUtils.Cross(r1, P);
                b2._linearVelocity  += b2._invMass * P;
                b2._angularVelocity += b2._invI * MathUtils.Cross(r2, P);
            }
            else
            {
                _impulse = 0.0f;
            }
        }
Exemplo n.º 6
0
        private void Solve(TimeStep step)
        {
            m_profile.solveInit     = 0.0f;
            m_profile.solveVelocity = 0.0f;
            m_profile.solvePosition = 0.0f;

            // Size the island for the worst case.
            Island island = new Island(m_contactManager.m_contactListener);

            // Clear all the island flags.
            foreach (Body b in m_bodyList)
            {
                b.m_flags &= ~Body.BodyFlags.e_islandFlag;
            }
            foreach (Contact c in m_contactManager.m_contactList)
            {
                c.m_flags &= ~ContactFlags.e_islandFlag;
            }
            foreach (Joint j in m_jointList)
            {
                j.m_islandFlag = false;
            }

            // Build and simulate all awake islands.
            List <Body> stack = new List <Body>(m_bodyList.Count());

            foreach (Body seed in m_bodyList)
            {
                if (seed.m_flags.HasFlag(Body.BodyFlags.e_islandFlag))
                {
                    continue;
                }

                if (seed.IsAwake() == false || seed.IsActive() == false)
                {
                    continue;
                }

                // The seed can be dynamic or kinematic.
                if (seed.GetBodyType() == BodyType._staticBody)
                {
                    continue;
                }

                // Reset island and stack.
                island.Clear();
                int stackCount = 0;
                stack.Add(seed); stackCount++;
                seed.m_flags |= Body.BodyFlags.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.
                    Body b = stack[--stackCount];
                    Utilities.Assert(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.GetBodyType() == BodyType._staticBody)
                    {
                        continue;
                    }

                    // Search all contacts connected to this body.
                    foreach (ContactEdge ce in b.m_contactList)
                    {
                        Contact contact = ce.contact;

                        // Has this contact already been added to an island?
                        if (contact.m_flags.HasFlag(ContactFlags.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 |= ContactFlags.e_islandFlag;

                        Body other = ce.other;

                        // Was the other body already added to this island?
                        if (other.m_flags.HasFlag(Body.BodyFlags.e_islandFlag))
                        {
                            continue;
                        }

                        Utilities.Assert(stackCount < m_bodyList.Count());
                        stack.Add(other); stackCount++;
                        other.m_flags |= Body.BodyFlags.e_islandFlag;
                    }

                    // Search all joints connect to this body.
                    foreach (JointEdge je in b.m_jointList)
                    {
                        if (je.joint.m_islandFlag == true)
                        {
                            continue;
                        }

                        Body 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.HasFlag(Body.BodyFlags.e_islandFlag))
                        {
                            continue;
                        }

                        stack.Add(other); stackCount++;
                        other.m_flags |= Body.BodyFlags.e_islandFlag;
                    }
                }

                Profile profile = new 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 (int i = 0; i < island.m_bodies.Count(); ++i)
                {
                    // Allow static bodies to participate in other islands.
                    Body b = island.m_bodies[i];
                    if (b.GetBodyType() == BodyType._staticBody)
                    {
                        b.m_flags &= ~Body.BodyFlags.e_islandFlag;
                    }
                }
            }

            {
                Timer timer = new Timer();
                // Synchronize fixtures, check for out of range bodies.
                foreach (Body b in m_bodyList)
                {
                    // If a body was not in an island then it did not move.
                    if ((b.m_flags & Body.BodyFlags.e_islandFlag) == 0)
                    {
                        continue;
                    }

                    if (b.GetBodyType() == BodyType._staticBody)
                    {
                        continue;
                    }

                    // Update fixtures (for broad-phase).
                    b.SynchronizeFixtures();
                }

                // Look for new contacts.
                m_contactManager.FindNewContacts();
                m_profile.broadphase = timer.GetMilliseconds();
            }
        }
Exemplo n.º 7
0
        internal override void InitVelocityConstraints(ref TimeStep step)
        {
            Body b1 = _bodyA;
            Body b2 = _bodyB;

            _localCenterA = b1.GetLocalCenter();
            _localCenterB = b2.GetLocalCenter();

            Transform xf1, xf2;

            b1.GetTransform(out xf1);
            b2.GetTransform(out xf2);

            // Compute the effective masses.
            Vector2 r1 = MathUtils.Multiply(ref xf1.R, _localAnchor1 - _localCenterA);
            Vector2 r2 = MathUtils.Multiply(ref xf2.R, _localAnchor2 - _localCenterB);
            Vector2 d  = b2._sweep.c + r2 - b1._sweep.c - r1;

            _invMassA = b1._invMass;
            _invIA    = b1._invI;
            _invMassB = b2._invMass;
            _invIB    = b2._invI;

            // Compute motor Jacobian and effective mass.
            {
                _axis = MathUtils.Multiply(ref xf1.R, _localxAxis1);
                _a1   = MathUtils.Cross(d + r1, _axis);
                _a2   = MathUtils.Cross(r2, _axis);

                _motorMass = _invMassA + _invMassB + _invIA * _a1 * _a1 + _invIB * _a2 * _a2;
                if (_motorMass > Settings.b2_epsilon)
                {
                    _motorMass = 1.0f / _motorMass;
                }
                else
                {
                    _motorMass = 0.0f;
                }
            }

            // Prismatic constraint.
            {
                _perp = MathUtils.Multiply(ref xf1.R, _localyAxis1);

                _s1 = MathUtils.Cross(d + r1, _perp);
                _s2 = MathUtils.Cross(r2, _perp);

                float m1 = _invMassA, m2 = _invMassB;
                float i1 = _invIA, i2 = _invIB;

                float k11 = m1 + m2 + i1 * _s1 * _s1 + i2 * _s2 * _s2;
                float k12 = i1 * _s1 * _a1 + i2 * _s2 * _a2;
                float k22 = m1 + m2 + i1 * _a1 * _a1 + i2 * _a2 * _a2;

                _K.col1 = new Vector2(k11, k12);
                _K.col2 = new Vector2(k12, k22);
            }

            // Compute motor and limit terms.
            if (_enableLimit)
            {
                float jointTranslation = Vector2.Dot(_axis, d);
                if (Math.Abs(_upperTranslation - _lowerTranslation) < 2.0f * Settings.b2_linearSlop)
                {
                    _limitState = LimitState.Equal;
                }
                else if (jointTranslation <= _lowerTranslation)
                {
                    if (_limitState != LimitState.AtLower)
                    {
                        _limitState = LimitState.AtLower;
                        _impulse.y  = 0.0f;
                    }
                }
                else if (jointTranslation >= _upperTranslation)
                {
                    if (_limitState != LimitState.AtUpper)
                    {
                        _limitState = LimitState.AtUpper;
                        _impulse.y  = 0.0f;
                    }
                }
                else
                {
                    _limitState = LimitState.Inactive;
                    _impulse.y  = 0.0f;
                }
            }
            else
            {
                _limitState = LimitState.Inactive;
            }

            if (_enableMotor == false)
            {
                _motorImpulse = 0.0f;
            }

            if (step.warmStarting)
            {
                // Account for variable time step.
                _impulse      *= step.dtRatio;
                _motorImpulse *= step.dtRatio;

                Vector2 P  = _impulse.x * _perp + (_motorImpulse + _impulse.y) * _axis;
                float   L1 = _impulse.x * _s1 + (_motorImpulse + _impulse.y) * _a1;
                float   L2 = _impulse.x * _s2 + (_motorImpulse + _impulse.y) * _a2;

                b1._linearVelocity  -= _invMassA * P;
                b1._angularVelocity -= _invIA * L1;

                b2._linearVelocity  += _invMassB * P;
                b2._angularVelocity += _invIB * L2;
            }
            else
            {
                _impulse      = Vector2.zero;
                _motorImpulse = 0.0f;
            }
        }
Exemplo n.º 8
0
        private void SolveTOI(TimeStep step)
        {
            Island island = new Island(m_contactManager.m_contactListener);

            if (m_stepComplete)
            {
                foreach (Body b in m_bodyList)
                {
                    b.m_flags       &= ~Body.BodyFlags.e_islandFlag;
                    b.m_sweep.alpha0 = 0.0f;
                }

                foreach (Contact c in m_contactManager.m_contactList)
                {
                    // Invalidate TOI
                    c.m_flags   &= ~(ContactFlags.e_toiFlag | ContactFlags.e_islandFlag);
                    c.m_toiCount = 0;
                    c.m_toi      = 1.0f;
                }
            }

            Fixture fA = null;
            Fixture fB = null;
            Body    bA = null;
            Body    bB = null;

            // Find TOI events and solve them.
            for (;;)
            {
                // Find the first TOI.
                Contact minContact = null;
                float   minAlpha   = 1.0f;

                foreach (Contact c in m_contactManager.m_contactList)
                {
                    // Is this contact disabled?
                    if (c.IsEnabled() == false)
                    {
                        continue;
                    }

                    // Prevent excessive sub-stepping.
                    if (c.m_toiCount > Settings._maxSubSteps)
                    {
                        continue;
                    }



                    float alpha = 1.0f;
                    if (c.m_flags.HasFlag(ContactFlags.e_toiFlag))
                    {
                        // This contact has a valid cached TOI.
                        alpha = c.m_toi;
                    }
                    else
                    {
                        fA = c.FixtureA;
                        fB = c.FixtureB;

                        // Is there a sensor?
                        if (fA.IsSensor || fB.IsSensor)
                        {
                            continue;
                        }

                        bA = fA.GetBody();
                        bB = fB.GetBody();

                        BodyType typeA = bA.m_type;
                        BodyType typeB = bB.m_type;
                        Utilities.Assert(typeA == BodyType._dynamicBody || typeB == BodyType._dynamicBody);

                        bool activeA = bA.IsAwake() && typeA != BodyType._staticBody;
                        bool activeB = bB.IsAwake() && typeB != BodyType._staticBody;

                        // Is at least one body active (awake and dynamic or kinematic)?
                        if (activeA == false && activeB == false)
                        {
                            continue;
                        }

                        bool collideA = bA.IsBullet() || typeA != BodyType._dynamicBody;
                        bool collideB = bB.IsBullet() || typeB != BodyType._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.
                        float 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);
                        }

                        Utilities.Assert(alpha0 < 1.0f);

                        int indexA = c.GetChildIndexA();
                        int indexB = c.GetChildIndexB();

                        // Compute the time of impact in interval [0, minTOI]
                        TOIInput input = new TOIInput();
                        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;

                        TOIOutput output;
                        Utilities.TimeOfImpact(out output, input);

                        // Beta is the fraction of the remaining portion of the .
                        float beta = output.t;
                        if (output.state == TOIOutput.State.e_touching)
                        {
                            alpha = Math.Min(alpha0 + (1.0f - alpha0) * beta, 1.0f);
                        }
                        else
                        {
                            alpha = 1.0f;
                        }

                        c.m_toi    = alpha;
                        c.m_flags |= ContactFlags.e_toiFlag;
                    }

                    if (alpha < minAlpha)
                    {
                        // This is the minimum TOI found so far.
                        minContact = c;
                        minAlpha   = alpha;
                    }
                }

                if (minContact == null || 1.0f - 10.0f * Single.Epsilon < minAlpha)
                {
                    // No more TOI events. Done!
                    m_stepComplete = true;
                    break;
                }

                // Advance the bodies to the TOI.
                fA = minContact.FixtureA;
                fB = minContact.FixtureB;
                bA = fA.GetBody();
                bB = fB.GetBody();

                Sweep backup1 = bA.m_sweep;
                Sweep 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 &= ~ContactFlags.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         |= Body.BodyFlags.e_islandFlag;
                bB.m_flags         |= Body.BodyFlags.e_islandFlag;
                minContact.m_flags |= ContactFlags.e_islandFlag;

                // Get contacts on bodyA and bodyB.
                Body[] bodies = { bA, bB };
                for (int i = 0; i < 2; ++i)
                {
                    Body body = bodies[i];
                    if (body.m_type == BodyType._dynamicBody)
                    {
                        foreach (ContactEdge ce in body.m_contactList)
                        {
                            throw new NotImplementedException();

                            //if (island.m_bodies.Count() == island.m_bodyCapacity)
                            //{
                            //    break;
                            //}

                            //if (island.m_bodies.Count() == island.m_contactCapacity)
                            //{
                            //    break;
                            //}

                            //Contact* contact = ce.contact;

                            //// Has this contact already been added to the island?
                            //if (contact.m_flags & ContactFlags.e_islandFlag)
                            //{
                            //    continue;
                            //}

                            //// Only add static, kinematic, or bullet bodies.
                            //Body* other = ce.other;
                            //if (other.m_type == _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.
                            //Sweep backup = other.m_sweep;
                            //if ((other.m_flags & Body.BodyFlags.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 |= ContactFlags.e_islandFlag;
                            //island.Add(contact);

                            //// Has the other body already been added to the island?
                            //if (other.m_flags & Body.BodyFlags.e_islandFlag)
                            //{
                            //    continue;
                            //}

                            //// Add the other body to the island.
                            //other.m_flags |= Body.BodyFlags.e_islandFlag;

                            //if (other.m_type != _staticBody)
                            //{
                            //    other.SetAwake(true);
                            //}

                            //island.Add(other);
                        }
                    }
                }

                TimeStep 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 (int i = 0; i < island.m_bodies.Count(); ++i)
                {
                    throw new NotImplementedException();
                    //Body* body = island.m_bodies[i];
                    //body.m_flags &= ~Body.BodyFlags.e_islandFlag;

                    //if (body.m_type != _dynamicBody)
                    //{
                    //    continue;
                    //}

                    //body.SynchronizeFixtures();

                    //// Invalidate all contact TOIs on this displaced body.
                    //for (ContactEdge* ce = body.m_contactList; ce; ce = ce.next)
                    //{
                    //    ce.contact.m_flags &= ~(ContactFlags.e_toiFlag | ContactFlags.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;
                }
            }
        }
Exemplo n.º 9
0
		public void SolveTOI(TimeStep subStep, int toiIndexA, int toiIndexB) {
			throw new NotImplementedException();
		//    Utilities.Assert(toiIndexA < m_bodies.Count());
		//    Utilities.Assert(toiIndexB < m_bodies.Count());

		//    // Initialize the body state.
		//    for (int i = 0; i < m_bodies.Count(); ++i)
		//    {
		//        Body* b = m_bodies[i];
		//        m_positions[i].c = b.m_sweep.c;
		//        m_positions[i].a = b.m_sweep.a;
		//        m_velocities[i].v = b.m_linearVelocity;
		//        m_velocities[i].w = b.m_angularVelocity;
		//    }

		//    ContactSolverDef contactSolverDef;
		//    contactSolverDef.contacts = m_contacts;
		//    contactSolverDef.count = m_contactCount;
		//    contactSolverDef.allocator = m_allocator;
		//    contactSolverDef.step = subStep;
		//    contactSolverDef.positions = m_positions;
		//    contactSolverDef.velocities = m_velocities;
		//    ContactSolver contactSolver(&contactSolverDef);

		//    // Solve position constraints.
		//    for (int i = 0; i < subStep.positionIterations; ++i)
		//    {
		//        bool contactsOkay = contactSolver.SolveTOIPositionConstraints(toiIndexA, toiIndexB);
		//        if (contactsOkay)
		//        {
		//            break;
		//        }
		//    }

		//#if ZERO
		//    // Is the new position really safe?
		//    for (int i = 0; i < m_contactCount; ++i)
		//    {
		//        Contact* c = m_contacts[i];
		//        Fixture fA = c.FixtureA;
		//        Fixture fB = c.FixtureB;

		//        Body* bA = fA.GetBody();
		//        Body* bB = fB.GetBody();

		//        int indexA = c.GetChildIndexA();
		//        int indexB = c.GetChildIndexB();

		//        DistanceInput input;
		//        input.proxyA.Set(fA.GetShape(), indexA);
		//        input.proxyB.Set(fB.GetShape(), indexB);
		//        input.transformA = bA.GetTransform();
		//        input.transformB = bB.GetTransform();
		//        input.useRadii = false;

		//        DistanceOutput output;
		//        SimplexCache cache;
		//        cache.count = 0;
		//        Utilities.Distance(out output, cache, input);

		//        if (output.distance == 0 || cache.count == 3)
		//        {
		//            cache.count += 0;
		//        }
		//    }
		//#endif

		//    // Leap of faith to new safe state.
		//    m_bodies[toiIndexA].m_sweep.c0 = m_positions[toiIndexA].c;
		//    m_bodies[toiIndexA].m_sweep.a0 = m_positions[toiIndexA].a;
		//    m_bodies[toiIndexB].m_sweep.c0 = m_positions[toiIndexB].c;
		//    m_bodies[toiIndexB].m_sweep.a0 = m_positions[toiIndexB].a;

		//    // No warm starting is needed for TOI events because warm
		//    // starting impulses were applied in the discrete solver.
		//    contactSolver.InitializeVelocityConstraints();

		//    // Solve velocity constraints.
		//    for (int i = 0; i < subStep.velocityIterations; ++i)
		//    {
		//        contactSolver.SolveVelocityConstraints();
		//    }

		//    // Don't store the TOI contact forces for warm starting
		//    // because they can be quite large.

		//    float h = subStep.dt;

		//    // Integrate positions
		//    for (int i = 0; i < m_bodies.Count(); ++i)
		//    {
		//        Vec2 c = m_positions[i].c;
		//        float a = m_positions[i].a;
		//        Vec2 v = m_velocities[i].v;
		//        float w = m_velocities[i].w;

		//        // Check for large velocities
		//        Vec2 translation = h * v;
		//        if (Utilities.Dot(translation, translation) > _maxTranslationSquared)
		//        {
		//            float ratio = _maxTranslation / translation.Length();
		//            v *= ratio;
		//        }

		//        float rotation = h * w;
		//        if (rotation * rotation > _maxRotationSquared)
		//        {
		//            float ratio = _maxRotation / Math.Abs(rotation);
		//            w *= ratio;
		//        }

		//        // Integrate
		//        c += h * v;
		//        a += h * w;

		//        m_positions[i].c = c;
		//        m_positions[i].a = a;
		//        m_velocities[i].v = v;
		//        m_velocities[i].w = w;

		//        // Sync bodies
		//        Body* body = m_bodies[i];
		//        body.m_sweep.c = c;
		//        body.m_sweep.a = a;
		//        body.m_linearVelocity = v;
		//        body.m_angularVelocity = w;
		//        body.SynchronizeTransform();
		//    }

		//    Report(contactSolver.m_velocityConstraints);
		}
Exemplo n.º 10
0
		public void Solve(Profile profile, TimeStep step, Vec2 gravity, bool allowSleep) {
			Timer timer = new Timer();

			float h = step.dt;

			// Integrate velocities and apply damping. Initialize the body state.
			for (int i = 0; i < m_bodies.Count(); i++)
			{
				Body b = m_bodies[i];
			    Vec2 c = b.m_sweep.c;
			    float a = b.m_sweep.a;
			    Vec2 v = b.m_linearVelocity;
			    float w = b.m_angularVelocity;

			    // Store positions for continuous collision.
			    b.m_sweep.c0 = b.m_sweep.c;
			    b.m_sweep.a0 = b.m_sweep.a;

			    if (b.m_type == BodyType._dynamicBody)
			    {
			        // Integrate velocities.
			        v += h * (b.m_gravityScale * gravity + b.m_invMass * b.m_force);
			        w += h * b.m_invI * b.m_torque;

			        // Apply damping.
			        // ODE: dv/dt + c * v = 0
			        // Solution: v(t) = v0 * exp(-c * t)
			        // Time step: v(t + dt) = v0 * exp(-c * (t + dt)) = v0 * exp(-c * t) * exp(-c * dt) = v * exp(-c * dt)
			        // v2 = exp(-c * dt) * v1
			        // Taylor expansion:
			        // v2 = (1.0f - c * dt) * v1
			        v *= Utilities.Clamp(1.0f - h * b.m_linearDamping, 0.0f, 1.0f);
					w *= Utilities.Clamp(1.0f - h * b.m_angularDamping, 0.0f, 1.0f);
			    }

				Position pos = new Position();
				pos.c = c;
				pos.a = a;
				m_positions.Add(pos);

				Velocity vel = new Velocity();
				vel.v = v;
				vel.w = w;
				m_velocities.Add(vel);
			}

			timer.Reset();

			// Solver data
			SolverData solverData;
			solverData.step = step;
			solverData.positions = m_positions;
			solverData.velocities = m_velocities;

			// Initialize velocity constraints.
			ContactSolverDef contactSolverDef;
			contactSolverDef.step = step;
			contactSolverDef.contacts = m_contacts;
			contactSolverDef.positions = m_positions;
			contactSolverDef.velocities = m_velocities;

			ContactSolver contactSolver = new ContactSolver(contactSolverDef);
			contactSolver.InitializeVelocityConstraints();

			if (step.warmStarting)
			{
			    contactSolver.WarmStart();
			}
	
			for (int i = 0; i < m_joints.Count(); ++i)
			{
			    m_joints[i].InitVelocityConstraints(solverData);
			}

			profile.solveInit = timer.GetMilliseconds();

			// Solve velocity constraints
			timer.Reset();
			for (int i = 0; i < step.velocityIterations; ++i)
			{
			    for (int j = 0; j < m_joints.Count(); ++j)
			    {
			        m_joints[j].SolveVelocityConstraints(solverData);
			    }

			    contactSolver.SolveVelocityConstraints();
			}

			// Store impulses for warm starting
			contactSolver.StoreImpulses();
			profile.solveVelocity = timer.GetMilliseconds();

			// Integrate positions
			for (int i = 0; i < m_bodies.Count(); ++i)
			{
			    Vec2 c = m_positions[i].c;
			    float a = m_positions[i].a;
			    Vec2 v = m_velocities[i].v;
			    float w = m_velocities[i].w;

			    // Check for large velocities
			    Vec2 translation = h * v;
			    if (Utilities.Dot(translation, translation) > Settings._maxTranslationSquared)
			    {
					float ratio = Settings._maxTranslation / translation.Length();
			        v *= ratio;
			    }

			    float rotation = h * w;
				if (rotation * rotation > Settings._maxRotationSquared)
			    {
					float ratio = Settings._maxRotation / Math.Abs(rotation);
			        w *= ratio;
			    }

			    // Integrate
			    c += h * v;
			    a += h * w;

				m_positions[i].c = c;
				m_positions[i].a = a;
				m_velocities[i].v = v;
				m_velocities[i].w = w;
			}

			// Solve position constraints
			timer.Reset();
			bool positionSolved = false;
			for (int i = 0; i < step.positionIterations; ++i)
			{
			    bool contactsOkay = contactSolver.SolvePositionConstraints();

			    bool jointsOkay = true;
			    for (int j = 0; j < m_joints.Count; ++j)
			    {
			        bool jointOkay = m_joints[j].SolvePositionConstraints(solverData);
			        jointsOkay = jointsOkay && jointOkay;
			    }

			    if (contactsOkay && jointsOkay)
			    {
			        // Exit early if the position errors are small.
			        positionSolved = true;
			        break;
			    }
			}

			// Copy state buffers back to the bodies
			for (int i = 0; i < m_bodies.Count(); ++i)
			{
			    Body body = m_bodies[i];
			    body.m_sweep.c = m_positions[i].c;
			    body.m_sweep.a = m_positions[i].a;
			    body.m_linearVelocity = m_velocities[i].v;
			    body.m_angularVelocity = m_velocities[i].w;
			    body.SynchronizeTransform();
			}

			profile.solvePosition = timer.GetMilliseconds();

			Report(contactSolver.m_velocityConstraints);

			if (allowSleep)
			{
			    float minSleepTime = Single.MaxValue;

				const float linTolSqr = Settings._linearSleepTolerance * Settings._linearSleepTolerance;
				const float angTolSqr = Settings._angularSleepTolerance * Settings._angularSleepTolerance;

			    for (int i = 0; i < m_bodies.Count(); ++i)
			    {
			        Body b = m_bodies[i];
			        if (b.GetBodyType() == BodyType._staticBody)
			        {
			            continue;
			        }

			        if ((b.m_flags & Body.BodyFlags.e_autoSleepFlag) == 0 ||
			            b.m_angularVelocity * b.m_angularVelocity > angTolSqr ||
			            Utilities.Dot(b.m_linearVelocity, b.m_linearVelocity) > linTolSqr)
			        {
			            b.m_sleepTime = 0.0f;
			            minSleepTime = 0.0f;
			        }
			        else
			        {
			            b.m_sleepTime += h;
			            minSleepTime = Math.Min(minSleepTime, b.m_sleepTime);
			        }
			    }

				if (minSleepTime >= Settings._timeToSleep && positionSolved)
			    {
			        for (int i = 0; i < m_bodies.Count(); ++i)
			        {
			            Body b = m_bodies[i];
			            b.SetAwake(false);
			        }
			    }
			}
		}
Exemplo n.º 11
0
        internal override void SolveVelocityConstraints(ref TimeStep step)
        {
            Body bA = _bodyA;
            Body bB = _bodyB;

            Vector2 vA = bA._linearVelocity;
            float   wA = bA._angularVelocity;
            Vector2 vB = bB._linearVelocity;
            float   wB = bB._angularVelocity;

            float mA = bA._invMass, mB = bB._invMass;
            float iA = bA._invI, iB = bB._invI;

            Transform xfA, xfB;

            bA.GetTransform(out xfA);
            bB.GetTransform(out xfB);

            Vector2 rA = MathUtils.Multiply(ref xfA.R, _localAnchor1 - bA.GetLocalCenter());
            Vector2 rB = MathUtils.Multiply(ref xfB.R, _localAnchor2 - bB.GetLocalCenter());

            // Solve angular friction
            {
                float Cdot    = wB - wA;
                float impulse = -_angularMass * Cdot;

                float oldImpulse = _angularImpulse;
                float maxImpulse = step.dt * _maxTorque;
                _angularImpulse = MathUtils.Clamp(_angularImpulse + impulse, -maxImpulse, maxImpulse);
                impulse         = _angularImpulse - oldImpulse;

                wA -= iA * impulse;
                wB += iB * impulse;
            }

            // Solve linear friction
            {
                Vector2 Cdot = vB + MathUtils.Cross(wB, rB) - vA - MathUtils.Cross(wA, rA);

                Vector2 impulse    = -MathUtils.Multiply(ref _linearMass, Cdot);
                Vector2 oldImpulse = _linearImpulse;
                _linearImpulse += impulse;

                float maxImpulse = step.dt * _maxForce;

                if (_linearImpulse.sqrMagnitude > maxImpulse * maxImpulse)
                {
                    _linearImpulse.Normalize();
                    _linearImpulse *= maxImpulse;
                }

                impulse = _linearImpulse - oldImpulse;

                vA -= mA * impulse;
                wA -= iA * MathUtils.Cross(rA, impulse);

                vB += mB * impulse;
                wB += iB * MathUtils.Cross(rB, impulse);
            }

            bA._linearVelocity  = vA;
            bA._angularVelocity = wA;
            bB._linearVelocity  = vB;
            bB._angularVelocity = wB;
        }
Exemplo n.º 12
0
        internal override void InitVelocityConstraints(ref TimeStep step)
        {
            Body bA = _bodyA;
            Body bB = _bodyB;

            Transform xfA, xfB;

            bA.GetTransform(out xfA);
            bB.GetTransform(out xfB);

            // Compute the effective mass matrix.
            Vector2 rA = MathUtils.Multiply(ref xfA.R, _localAnchor1 - bA.GetLocalCenter());
            Vector2 rB = MathUtils.Multiply(ref xfB.R, _localAnchor2 - bB.GetLocalCenter());

            // J = [-I -r1_skew I r2_skew]
            //     [ 0       -1 0       1]
            // r_skew = [-ry; rx]

            // Matlab
            // K = [ mA+r1y^2*iA+mB+r2y^2*iB,  -r1y*iA*r1x-r2y*iB*r2x,          -r1y*iA-r2y*iB]
            //     [  -r1y*iA*r1x-r2y*iB*r2x, mA+r1x^2*iA+mB+r2x^2*iB,           r1x*iA+r2x*iB]
            //     [          -r1y*iA-r2y*iB,           r1x*iA+r2x*iB,                   iA+iB]

            float mA = bA._invMass, mB = bB._invMass;
            float iA = bA._invI, iB = bB._invI;

            Mat22 K1 = new Mat22();

            K1.col1.x = mA + mB;    K1.col2.x = 0.0f;
            K1.col1.y = 0.0f;               K1.col2.y = mA + mB;

            Mat22 K2 = new Mat22();

            K2.col1.x = iA * rA.y * rA.y;  K2.col2.x = -iA * rA.x * rA.y;
            K2.col1.y = -iA * rA.x * rA.y;  K2.col2.y = iA * rA.x * rA.x;

            Mat22 K3 = new Mat22();

            K3.col1.x = iB * rB.y * rB.y;  K3.col2.x = -iB * rB.x * rB.y;
            K3.col1.y = -iB * rB.x * rB.y;  K3.col2.y = iB * rB.x * rB.x;

            Mat22 K12;

            Mat22.Add(ref K1, ref K2, out K12);
            Mat22 K;

            Mat22.Add(ref K12, ref K3, out K);
            _linearMass = K.GetInverse();

            _angularMass = iA + iB;
            if (_angularMass > 0.0f)
            {
                _angularMass = 1.0f / _angularMass;
            }

            if (step.warmStarting)
            {
                // Scale impulses to support a variable time step.
                _linearImpulse  *= step.dtRatio;
                _angularImpulse *= step.dtRatio;

                Vector2 P = new Vector2(_linearImpulse.x, _linearImpulse.y);

                bA._linearVelocity  -= mA * P;
                bA._angularVelocity -= iA * (MathUtils.Cross(rA, P) + _angularImpulse);

                bB._linearVelocity  += mB * P;
                bB._angularVelocity += iB * (MathUtils.Cross(rB, P) + _angularImpulse);
            }
            else
            {
                _linearImpulse  = Vector2.zero;
                _angularImpulse = 0.0f;
            }
        }