@Override public boolean solvePositionConstraints(final org.jbox2d.dynamics.SolverData data) { final Rot qA = pool.popRot(); final Rot qB = pool.popRot(); Vec2 cA = data.positions[m_indexA].c; float aA = data.positions[m_indexA].a; Vec2 cB = data.positions[m_indexB].c; float aB = data.positions[m_indexB].a; qA.set(aA); qB.set(aB); float angularError = 0.0f; float positionError = 0.0f; boolean fixedRotation = (m_invIA + m_invIB == 0.0f); // Solve angular limit constraint. if (m_enableLimit && m_limitState != LimitState.INACTIVE && fixedRotation == false) { float angle = aB - aA - m_referenceAngle; float limitImpulse = 0.0f; if (m_limitState == LimitState.EQUAL) { // Prevent large angular corrections float C = MathUtils.clamp( angle - m_lowerAngle, -Settings.maxAngularCorrection, Settings.maxAngularCorrection); limitImpulse = -m_motorMass * C; angularError = MathUtils.abs(C); } else if (m_limitState == LimitState.AT_LOWER) { float C = angle - m_lowerAngle; angularError = -C; // Prevent large angular corrections and allow some slop. C = MathUtils.clamp(C + Settings.angularSlop, -Settings.maxAngularCorrection, 0.0f); limitImpulse = -m_motorMass * C; } else if (m_limitState == LimitState.AT_UPPER) { float C = angle - m_upperAngle; angularError = C; // Prevent large angular corrections and allow some slop. C = MathUtils.clamp(C - Settings.angularSlop, 0.0f, Settings.maxAngularCorrection); limitImpulse = -m_motorMass * C; } aA -= m_invIA * limitImpulse; aB += m_invIB * limitImpulse; } // Solve point-to-point constraint. { qA.set(aA); qB.set(aB); final Vec2 rA = pool.popVec2(); final Vec2 rB = pool.popVec2(); final Vec2 C = pool.popVec2(); final Vec2 impulse = pool.popVec2(); Rot.mulToOutUnsafe(qA, C.set(m_localAnchorA).subLocal(m_localCenterA), rA); Rot.mulToOutUnsafe(qB, C.set(m_localAnchorB).subLocal(m_localCenterB), rB); C.set(cB).addLocal(rB).subLocal(cA).subLocal(rA); positionError = C.length(); float mA = m_invMassA, mB = m_invMassB; float iA = m_invIA, iB = m_invIB; final org.jbox2d.common.Mat22 K = pool.popMat22(); K.ex.x = mA + mB + iA * rA.y * rA.y + iB * rB.y * rB.y; K.ex.y = -iA * rA.x * rA.y - iB * rB.x * rB.y; K.ey.x = K.ex.y; K.ey.y = mA + mB + iA * rA.x * rA.x + iB * rB.x * rB.x; K.solveToOut(C, impulse); impulse.negateLocal(); cA.x -= mA * impulse.x; cA.y -= mA * impulse.y; aA -= iA * Vec2.cross(rA, impulse); cB.x += mB * impulse.x; cB.y += mB * impulse.y; aB += iB * Vec2.cross(rB, impulse); pool.pushVec2(4); pool.pushMat22(1); } // data.positions[m_indexA].c.set(cA); data.positions[m_indexA].a = aA; // data.positions[m_indexB].c.set(cB); data.positions[m_indexB].a = aB; pool.pushRot(2); return positionError <= Settings.linearSlop && angularError <= Settings.angularSlop; }
@Override public final boolean raycast( RayCastOutput output, RayCastInput input, Transform xf, int childIndex) { final Vec2 p1 = pool1; final Vec2 p2 = pool2; final Vec2 d = pool3; final Vec2 temp = pool4; p1.set(input.p1).subLocal(xf.p); Rot.mulTrans(xf.q, p1, p1); p2.set(input.p2).subLocal(xf.p); Rot.mulTrans(xf.q, p2, p2); d.set(p2).subLocal(p1); // if (count == 2) { // } else { float lower = 0, upper = input.maxFraction; int index = -1; for (int i = 0; i < m_count; ++i) { // p = p1 + a * d // dot(normal, p - v) = 0 // dot(normal, p1 - v) + a * dot(normal, d) = 0 temp.set(m_vertices[i]).subLocal(p1); final float numerator = Vec2.dot(m_normals[i], temp); final float denominator = Vec2.dot(m_normals[i], d); if (denominator == 0.0f) { if (numerator < 0.0f) { return false; } } else { // Note: we want this predicate without division: // lower < numerator / denominator, where denominator < 0 // Since denominator < 0, we have to flip the inequality: // lower < numerator / denominator <==> denominator * lower > // numerator. if (denominator < 0.0f && numerator < lower * denominator) { // Increase lower. // The segment enters this half-space. lower = numerator / denominator; index = i; } else if (denominator > 0.0f && numerator < upper * denominator) { // Decrease upper. // The segment exits this half-space. upper = numerator / denominator; } } if (upper < lower) { return false; } } assert (0.0f <= lower && lower <= input.maxFraction); if (index >= 0) { output.fraction = lower; Rot.mulToOutUnsafe(xf.q, m_normals[index], output.normal); // normal = Mul(xf.R, m_normals[index]); return true; } return false; }
@Override public void initVelocityConstraints(final org.jbox2d.dynamics.SolverData data) { m_indexA = m_bodyA.m_islandIndex; m_indexB = m_bodyB.m_islandIndex; m_localCenterA.set(m_bodyA.m_sweep.localCenter); m_localCenterB.set(m_bodyB.m_sweep.localCenter); m_invMassA = m_bodyA.m_invMass; m_invMassB = m_bodyB.m_invMass; m_invIA = m_bodyA.m_invI; m_invIB = m_bodyB.m_invI; // Vec2 cA = data.positions[m_indexA].c; float aA = data.positions[m_indexA].a; Vec2 vA = data.velocities[m_indexA].v; float wA = data.velocities[m_indexA].w; // Vec2 cB = data.positions[m_indexB].c; float aB = data.positions[m_indexB].a; Vec2 vB = data.velocities[m_indexB].v; float wB = data.velocities[m_indexB].w; final Rot qA = pool.popRot(); final Rot qB = pool.popRot(); final Vec2 temp = pool.popVec2(); qA.set(aA); qB.set(aB); // Compute the effective masses. Rot.mulToOutUnsafe(qA, temp.set(m_localAnchorA).subLocal(m_localCenterA), m_rA); Rot.mulToOutUnsafe(qB, temp.set(m_localAnchorB).subLocal(m_localCenterB), m_rB); // 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 = m_invMassA, mB = m_invMassB; float iA = m_invIA, iB = m_invIB; boolean fixedRotation = (iA + iB == 0.0f); m_mass.ex.x = mA + mB + m_rA.y * m_rA.y * iA + m_rB.y * m_rB.y * iB; m_mass.ey.x = -m_rA.y * m_rA.x * iA - m_rB.y * m_rB.x * iB; m_mass.ez.x = -m_rA.y * iA - m_rB.y * iB; m_mass.ex.y = m_mass.ey.x; m_mass.ey.y = mA + mB + m_rA.x * m_rA.x * iA + m_rB.x * m_rB.x * iB; m_mass.ez.y = m_rA.x * iA + m_rB.x * iB; m_mass.ex.z = m_mass.ez.x; m_mass.ey.z = m_mass.ez.y; m_mass.ez.z = iA + iB; m_motorMass = iA + iB; if (m_motorMass > 0.0f) { m_motorMass = 1.0f / m_motorMass; } if (m_enableMotor == false || fixedRotation) { m_motorImpulse = 0.0f; } if (m_enableLimit && fixedRotation == false) { float jointAngle = aB - aA - m_referenceAngle; if (MathUtils.abs(m_upperAngle - m_lowerAngle) < 2.0f * Settings.angularSlop) { m_limitState = LimitState.EQUAL; } else if (jointAngle <= m_lowerAngle) { if (m_limitState != LimitState.AT_LOWER) { m_impulse.z = 0.0f; } m_limitState = LimitState.AT_LOWER; } else if (jointAngle >= m_upperAngle) { if (m_limitState != LimitState.AT_UPPER) { m_impulse.z = 0.0f; } m_limitState = LimitState.AT_UPPER; } else { m_limitState = LimitState.INACTIVE; m_impulse.z = 0.0f; } } else { m_limitState = LimitState.INACTIVE; } if (data.step.warmStarting) { final Vec2 P = pool.popVec2(); // Scale impulses to support a variable time step. m_impulse.x *= data.step.dtRatio; m_impulse.y *= data.step.dtRatio; m_motorImpulse *= data.step.dtRatio; P.x = m_impulse.x; P.y = m_impulse.y; vA.x -= mA * P.x; vA.y -= mA * P.y; wA -= iA * (Vec2.cross(m_rA, P) + m_motorImpulse + m_impulse.z); vB.x += mB * P.x; vB.y += mB * P.y; wB += iB * (Vec2.cross(m_rB, P) + m_motorImpulse + m_impulse.z); pool.pushVec2(1); } else { m_impulse.setZero(); m_motorImpulse = 0.0f; } // data.velocities[m_indexA].v.set(vA); data.velocities[m_indexA].w = wA; // data.velocities[m_indexB].v.set(vB); data.velocities[m_indexB].w = wB; pool.pushVec2(1); pool.pushRot(2); }