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The JUCE cross-platform C++ framework, with DISTRHO/KXStudio specific changes
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JUCE/modules/juce_box2d/box2d/Dynamics/Joints/b2GearJoint.cpp

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  1. /*

  2. * Copyright (c) 2007-2011 Erin Catto http://www.box2d.org

  3. *

  4. * This software is provided 'as-is', without any express or implied

  5. * warranty.  In no event will the authors be held liable for any damages

  6. * arising from the use of this software.

  7. * Permission is granted to anyone to use this software for any purpose,

  8. * including commercial applications, and to alter it and redistribute it

  9. * freely, subject to the following restrictions:

  10. * 1. The origin of this software must not be misrepresented; you must not

  11. * claim that you wrote the original software. If you use this software

  12. * in a product, an acknowledgment in the product documentation would be

  13. * appreciated but is not required.

  14. * 2. Altered source versions must be plainly marked as such, and must not be

  15. * misrepresented as being the original software.

  16. * 3. This notice may not be removed or altered from any source distribution.

  17. */

  18. 

  19. #include "b2GearJoint.h"

  20. #include "b2RevoluteJoint.h"

  21. #include "b2PrismaticJoint.h"

  22. #include "../b2Body.h"

  23. #include "../b2TimeStep.h"

  24. 

  25. // Gear Joint:

  26. // C0 = (coordinate1 + ratio * coordinate2)_initial

  27. // C = (coordinate1 + ratio * coordinate2) - C0 = 0

  28. // J = [J1 ratio * J2]

  29. // K = J * invM * JT

  30. //   = J1 * invM1 * J1T + ratio * ratio * J2 * invM2 * J2T

  31. //

  32. // Revolute:

  33. // coordinate = rotation

  34. // Cdot = angularVelocity

  35. // J = [0 0 1]

  36. // K = J * invM * JT = invI

  37. //

  38. // Prismatic:

  39. // coordinate = dot(p - pg, ug)

  40. // Cdot = dot(v + cross(w, r), ug)

  41. // J = [ug cross(r, ug)]

  42. // K = J * invM * JT = invMass + invI * cross(r, ug)^2

  43. 

  44. b2GearJoint::b2GearJoint(const b2GearJointDef* def)

  45. : b2Joint(def)

  46. {

  47. 	m_joint1 = def->joint1;

  48. 	m_joint2 = def->joint2;

  49. 

  50. 	m_typeA = m_joint1->GetType();

  51. 	m_typeB = m_joint2->GetType();

  52. 

  53. 	b2Assert(m_typeA == e_revoluteJoint || m_typeA == e_prismaticJoint);

  54. 	b2Assert(m_typeB == e_revoluteJoint || m_typeB == e_prismaticJoint);

  55. 

  56. 	float32 coordinateA, coordinateB;

  57. 

  58. 	// TODO_ERIN there might be some problem with the joint edges in b2Joint.

  59. 

  60. 	m_bodyC = m_joint1->GetBodyA();

  61. 	m_bodyA = m_joint1->GetBodyB();

  62. 

  63. 	// Get geometry of joint1

  64. 	b2Transform xfA = m_bodyA->m_xf;

  65. 	float32 aA = m_bodyA->m_sweep.a;

  66. 	b2Transform xfC = m_bodyC->m_xf;

  67. 	float32 aC = m_bodyC->m_sweep.a;

  68. 

  69. 	if (m_typeA == e_revoluteJoint)

  70. 	{

  71. 		b2RevoluteJoint* revolute = (b2RevoluteJoint*)def->joint1;

  72. 		m_localAnchorC = revolute->m_localAnchorA;

  73. 		m_localAnchorA = revolute->m_localAnchorB;

  74. 		m_referenceAngleA = revolute->m_referenceAngle;

  75. 		m_localAxisC.SetZero();

  76. 

  77. 		coordinateA = aA - aC - m_referenceAngleA;

  78. 	}

  79. 	else

  80. 	{

  81. 		b2PrismaticJoint* prismatic = (b2PrismaticJoint*)def->joint1;

  82. 		m_localAnchorC = prismatic->m_localAnchorA;

  83. 		m_localAnchorA = prismatic->m_localAnchorB;

  84. 		m_referenceAngleA = prismatic->m_referenceAngle;

  85. 		m_localAxisC = prismatic->m_localXAxisA;

  86. 

  87. 		b2Vec2 pC = m_localAnchorC;

  88. 		b2Vec2 pA = b2MulT(xfC.q, b2Mul(xfA.q, m_localAnchorA) + (xfA.p - xfC.p));

  89. 		coordinateA = b2Dot(pA - pC, m_localAxisC);

  90. 	}

  91. 

  92. 	m_bodyD = m_joint2->GetBodyA();

  93. 	m_bodyB = m_joint2->GetBodyB();

  94. 

  95. 	// Get geometry of joint2

  96. 	b2Transform xfB = m_bodyB->m_xf;

  97. 	float32 aB = m_bodyB->m_sweep.a;

  98. 	b2Transform xfD = m_bodyD->m_xf;

  99. 	float32 aD = m_bodyD->m_sweep.a;

  100. 

  101. 	if (m_typeB == e_revoluteJoint)

  102. 	{

  103. 		b2RevoluteJoint* revolute = (b2RevoluteJoint*)def->joint2;

  104. 		m_localAnchorD = revolute->m_localAnchorA;

  105. 		m_localAnchorB = revolute->m_localAnchorB;

  106. 		m_referenceAngleB = revolute->m_referenceAngle;

  107. 		m_localAxisD.SetZero();

  108. 

  109. 		coordinateB = aB - aD - m_referenceAngleB;

  110. 	}

  111. 	else

  112. 	{

  113. 		b2PrismaticJoint* prismatic = (b2PrismaticJoint*)def->joint2;

  114. 		m_localAnchorD = prismatic->m_localAnchorA;

  115. 		m_localAnchorB = prismatic->m_localAnchorB;

  116. 		m_referenceAngleB = prismatic->m_referenceAngle;

  117. 		m_localAxisD = prismatic->m_localXAxisA;

  118. 

  119. 		b2Vec2 pD = m_localAnchorD;

  120. 		b2Vec2 pB = b2MulT(xfD.q, b2Mul(xfB.q, m_localAnchorB) + (xfB.p - xfD.p));

  121. 		coordinateB = b2Dot(pB - pD, m_localAxisD);

  122. 	}

  123. 

  124. 	m_ratio = def->ratio;

  125. 

  126. 	m_constant = coordinateA + m_ratio * coordinateB;

  127. 

  128. 	m_impulse = 0.0f;

  129. }

  130. 

  131. void b2GearJoint::InitVelocityConstraints(const b2SolverData& data)

  132. {

  133. 	m_indexA = m_bodyA->m_islandIndex;

  134. 	m_indexB = m_bodyB->m_islandIndex;

  135. 	m_indexC = m_bodyC->m_islandIndex;

  136. 	m_indexD = m_bodyD->m_islandIndex;

  137. 	m_lcA = m_bodyA->m_sweep.localCenter;

  138. 	m_lcB = m_bodyB->m_sweep.localCenter;

  139. 	m_lcC = m_bodyC->m_sweep.localCenter;

  140. 	m_lcD = m_bodyD->m_sweep.localCenter;

  141. 	m_mA = m_bodyA->m_invMass;

  142. 	m_mB = m_bodyB->m_invMass;

  143. 	m_mC = m_bodyC->m_invMass;

  144. 	m_mD = m_bodyD->m_invMass;

  145. 	m_iA = m_bodyA->m_invI;

  146. 	m_iB = m_bodyB->m_invI;

  147. 	m_iC = m_bodyC->m_invI;

  148. 	m_iD = m_bodyD->m_invI;

  149. 

  150. 	float32 aA = data.positions[m_indexA].a;

  151. 	b2Vec2 vA = data.velocities[m_indexA].v;

  152. 	float32 wA = data.velocities[m_indexA].w;

  153. 

  154. 	float32 aB = data.positions[m_indexB].a;

  155. 	b2Vec2 vB = data.velocities[m_indexB].v;

  156. 	float32 wB = data.velocities[m_indexB].w;

  157. 

  158. 	float32 aC = data.positions[m_indexC].a;

  159. 	b2Vec2 vC = data.velocities[m_indexC].v;

  160. 	float32 wC = data.velocities[m_indexC].w;

  161. 

  162. 	float32 aD = data.positions[m_indexD].a;

  163. 	b2Vec2 vD = data.velocities[m_indexD].v;

  164. 	float32 wD = data.velocities[m_indexD].w;

  165. 

  166. 	b2Rot qA(aA), qB(aB), qC(aC), qD(aD);

  167. 

  168. 	m_mass = 0.0f;

  169. 

  170. 	if (m_typeA == e_revoluteJoint)

  171. 	{

  172. 		m_JvAC.SetZero();

  173. 		m_JwA = 1.0f;

  174. 		m_JwC = 1.0f;

  175. 		m_mass += m_iA + m_iC;

  176. 	}

  177. 	else

  178. 	{

  179. 		b2Vec2 u = b2Mul(qC, m_localAxisC);

  180. 		b2Vec2 rC = b2Mul(qC, m_localAnchorC - m_lcC);

  181. 		b2Vec2 rA = b2Mul(qA, m_localAnchorA - m_lcA);

  182. 		m_JvAC = u;

  183. 		m_JwC = b2Cross(rC, u);

  184. 		m_JwA = b2Cross(rA, u);

  185. 		m_mass += m_mC + m_mA + m_iC * m_JwC * m_JwC + m_iA * m_JwA * m_JwA;

  186. 	}

  187. 

  188. 	if (m_typeB == e_revoluteJoint)

  189. 	{

  190. 		m_JvBD.SetZero();

  191. 		m_JwB = m_ratio;

  192. 		m_JwD = m_ratio;

  193. 		m_mass += m_ratio * m_ratio * (m_iB + m_iD);

  194. 	}

  195. 	else

  196. 	{

  197. 		b2Vec2 u = b2Mul(qD, m_localAxisD);

  198. 		b2Vec2 rD = b2Mul(qD, m_localAnchorD - m_lcD);

  199. 		b2Vec2 rB = b2Mul(qB, m_localAnchorB - m_lcB);

  200. 		m_JvBD = m_ratio * u;

  201. 		m_JwD = m_ratio * b2Cross(rD, u);

  202. 		m_JwB = m_ratio * b2Cross(rB, u);

  203. 		m_mass += m_ratio * m_ratio * (m_mD + m_mB) + m_iD * m_JwD * m_JwD + m_iB * m_JwB * m_JwB;

  204. 	}

  205. 

  206. 	// Compute effective mass.

  207. 	m_mass = m_mass > 0.0f ? 1.0f / m_mass : 0.0f;

  208. 

  209. 	if (data.step.warmStarting)

  210. 	{

  211. 		vA += (m_mA * m_impulse) * m_JvAC;

  212. 		wA += m_iA * m_impulse * m_JwA;

  213. 		vB += (m_mB * m_impulse) * m_JvBD;

  214. 		wB += m_iB * m_impulse * m_JwB;

  215. 		vC -= (m_mC * m_impulse) * m_JvAC;

  216. 		wC -= m_iC * m_impulse * m_JwC;

  217. 		vD -= (m_mD * m_impulse) * m_JvBD;

  218. 		wD -= m_iD * m_impulse * m_JwD;

  219. 	}

  220. 	else

  221. 	{

  222. 		m_impulse = 0.0f;

  223. 	}

  224. 

  225. 	data.velocities[m_indexA].v = vA;

  226. 	data.velocities[m_indexA].w = wA;

  227. 	data.velocities[m_indexB].v = vB;

  228. 	data.velocities[m_indexB].w = wB;

  229. 	data.velocities[m_indexC].v = vC;

  230. 	data.velocities[m_indexC].w = wC;

  231. 	data.velocities[m_indexD].v = vD;

  232. 	data.velocities[m_indexD].w = wD;

  233. }

  234. 

  235. void b2GearJoint::SolveVelocityConstraints(const b2SolverData& data)

  236. {

  237. 	b2Vec2 vA = data.velocities[m_indexA].v;

  238. 	float32 wA = data.velocities[m_indexA].w;

  239. 	b2Vec2 vB = data.velocities[m_indexB].v;

  240. 	float32 wB = data.velocities[m_indexB].w;

  241. 	b2Vec2 vC = data.velocities[m_indexC].v;

  242. 	float32 wC = data.velocities[m_indexC].w;

  243. 	b2Vec2 vD = data.velocities[m_indexD].v;

  244. 	float32 wD = data.velocities[m_indexD].w;

  245. 

  246. 	float32 Cdot = b2Dot(m_JvAC, vA - vC) + b2Dot(m_JvBD, vB - vD);

  247. 	Cdot += (m_JwA * wA - m_JwC * wC) + (m_JwB * wB - m_JwD * wD);

  248. 

  249. 	float32 impulse = -m_mass * Cdot;

  250. 	m_impulse += impulse;

  251. 

  252. 	vA += (m_mA * impulse) * m_JvAC;

  253. 	wA += m_iA * impulse * m_JwA;

  254. 	vB += (m_mB * impulse) * m_JvBD;

  255. 	wB += m_iB * impulse * m_JwB;

  256. 	vC -= (m_mC * impulse) * m_JvAC;

  257. 	wC -= m_iC * impulse * m_JwC;

  258. 	vD -= (m_mD * impulse) * m_JvBD;

  259. 	wD -= m_iD * impulse * m_JwD;

  260. 

  261. 	data.velocities[m_indexA].v = vA;

  262. 	data.velocities[m_indexA].w = wA;

  263. 	data.velocities[m_indexB].v = vB;

  264. 	data.velocities[m_indexB].w = wB;

  265. 	data.velocities[m_indexC].v = vC;

  266. 	data.velocities[m_indexC].w = wC;

  267. 	data.velocities[m_indexD].v = vD;

  268. 	data.velocities[m_indexD].w = wD;

  269. }

  270. 

  271. bool b2GearJoint::SolvePositionConstraints(const b2SolverData& data)

  272. {

  273. 	b2Vec2 cA = data.positions[m_indexA].c;

  274. 	float32 aA = data.positions[m_indexA].a;

  275. 	b2Vec2 cB = data.positions[m_indexB].c;

  276. 	float32 aB = data.positions[m_indexB].a;

  277. 	b2Vec2 cC = data.positions[m_indexC].c;

  278. 	float32 aC = data.positions[m_indexC].a;

  279. 	b2Vec2 cD = data.positions[m_indexD].c;

  280. 	float32 aD = data.positions[m_indexD].a;

  281. 

  282. 	b2Rot qA(aA), qB(aB), qC(aC), qD(aD);

  283. 

  284. 	float32 linearError = 0.0f;

  285. 

  286. 	float32 coordinateA, coordinateB;

  287. 

  288. 	b2Vec2 JvAC, JvBD;

  289. 	float32 JwA, JwB, JwC, JwD;

  290. 	float32 mass = 0.0f;

  291. 

  292. 	if (m_typeA == e_revoluteJoint)

  293. 	{

  294. 		JvAC.SetZero();

  295. 		JwA = 1.0f;

  296. 		JwC = 1.0f;

  297. 		mass += m_iA + m_iC;

  298. 

  299. 		coordinateA = aA - aC - m_referenceAngleA;

  300. 	}

  301. 	else

  302. 	{

  303. 		b2Vec2 u = b2Mul(qC, m_localAxisC);

  304. 		b2Vec2 rC = b2Mul(qC, m_localAnchorC - m_lcC);

  305. 		b2Vec2 rA = b2Mul(qA, m_localAnchorA - m_lcA);

  306. 		JvAC = u;

  307. 		JwC = b2Cross(rC, u);

  308. 		JwA = b2Cross(rA, u);

  309. 		mass += m_mC + m_mA + m_iC * JwC * JwC + m_iA * JwA * JwA;

  310. 

  311. 		b2Vec2 pC = m_localAnchorC - m_lcC;

  312. 		b2Vec2 pA = b2MulT(qC, rA + (cA - cC));

  313. 		coordinateA = b2Dot(pA - pC, m_localAxisC);

  314. 	}

  315. 

  316. 	if (m_typeB == e_revoluteJoint)

  317. 	{

  318. 		JvBD.SetZero();

  319. 		JwB = m_ratio;

  320. 		JwD = m_ratio;

  321. 		mass += m_ratio * m_ratio * (m_iB + m_iD);

  322. 

  323. 		coordinateB = aB - aD - m_referenceAngleB;

  324. 	}

  325. 	else

  326. 	{

  327. 		b2Vec2 u = b2Mul(qD, m_localAxisD);

  328. 		b2Vec2 rD = b2Mul(qD, m_localAnchorD - m_lcD);

  329. 		b2Vec2 rB = b2Mul(qB, m_localAnchorB - m_lcB);

  330. 		JvBD = m_ratio * u;

  331. 		JwD = m_ratio * b2Cross(rD, u);

  332. 		JwB = m_ratio * b2Cross(rB, u);

  333. 		mass += m_ratio * m_ratio * (m_mD + m_mB) + m_iD * JwD * JwD + m_iB * JwB * JwB;

  334. 

  335. 		b2Vec2 pD = m_localAnchorD - m_lcD;

  336. 		b2Vec2 pB = b2MulT(qD, rB + (cB - cD));

  337. 		coordinateB = b2Dot(pB - pD, m_localAxisD);

  338. 	}

  339. 

  340. 	float32 C = (coordinateA + m_ratio * coordinateB) - m_constant;

  341. 

  342. 	float32 impulse = 0.0f;

  343. 	if (mass > 0.0f)

  344. 	{

  345. 		impulse = -C / mass;

  346. 	}

  347. 

  348. 	cA += m_mA * impulse * JvAC;

  349. 	aA += m_iA * impulse * JwA;

  350. 	cB += m_mB * impulse * JvBD;

  351. 	aB += m_iB * impulse * JwB;

  352. 	cC -= m_mC * impulse * JvAC;

  353. 	aC -= m_iC * impulse * JwC;

  354. 	cD -= m_mD * impulse * JvBD;

  355. 	aD -= m_iD * impulse * JwD;

  356. 

  357. 	data.positions[m_indexA].c = cA;

  358. 	data.positions[m_indexA].a = aA;

  359. 	data.positions[m_indexB].c = cB;

  360. 	data.positions[m_indexB].a = aB;

  361. 	data.positions[m_indexC].c = cC;

  362. 	data.positions[m_indexC].a = aC;

  363. 	data.positions[m_indexD].c = cD;

  364. 	data.positions[m_indexD].a = aD;

  365. 

  366. 	// TODO_ERIN not implemented

  367. 	return linearError < b2_linearSlop;

  368. }

  369. 

  370. b2Vec2 b2GearJoint::GetAnchorA() const

  371. {

  372. 	return m_bodyA->GetWorldPoint(m_localAnchorA);

  373. }

  374. 

  375. b2Vec2 b2GearJoint::GetAnchorB() const

  376. {

  377. 	return m_bodyB->GetWorldPoint(m_localAnchorB);

  378. }

  379. 

  380. b2Vec2 b2GearJoint::GetReactionForce(float32 inv_dt) const

  381. {

  382. 	b2Vec2 P = m_impulse * m_JvAC;

  383. 	return inv_dt * P;

  384. }

  385. 

  386. float32 b2GearJoint::GetReactionTorque(float32 inv_dt) const

  387. {

  388. 	float32 L = m_impulse * m_JwA;

  389. 	return inv_dt * L;

  390. }

  391. 

  392. void b2GearJoint::SetRatio(float32 ratio)

  393. {

  394. 	b2Assert(b2IsValid(ratio));

  395. 	m_ratio = ratio;

  396. }

  397. 

  398. float32 b2GearJoint::GetRatio() const

  399. {

  400. 	return m_ratio;

  401. }

  402. 

  403. void b2GearJoint::Dump()

  404. {

  405. 	int32 indexA = m_bodyA->m_islandIndex;

  406. 	int32 indexB = m_bodyB->m_islandIndex;

  407. 

  408. 	int32 index1 = m_joint1->m_index;

  409. 	int32 index2 = m_joint2->m_index;

  410. 

  411. 	b2Log("  b2GearJointDef jd;\n");

  412. 	b2Log("  jd.bodyA = bodies[%d];\n", indexA);

  413. 	b2Log("  jd.bodyB = bodies[%d];\n", indexB);

  414. 	b2Log("  jd.collideConnected = bool(%d);\n", m_collideConnected);

  415. 	b2Log("  jd.joint1 = joints[%d];\n", index1);

  416. 	b2Log("  jd.joint2 = joints[%d];\n", index2);

  417. 	b2Log("  jd.ratio = %.15lef;\n", m_ratio);

  418. 	b2Log("  joints[%d] = m_world->CreateJoint(&jd);\n", m_index);

  419. }