/* * Copyright (c) 2007-2009 Erin Catto http://www.box2d.org * * This software is provided 'as-is', without any express or implied * warranty. In no event will the authors be held liable for any damages * arising from the use of this software. * Permission is granted to anyone to use this software for any purpose, * including commercial applications, and to alter it and redistribute it * freely, subject to the following restrictions: * 1. The origin of this software must not be misrepresented; you must not * claim that you wrote the original software. If you use this software * in a product, an acknowledgment in the product documentation would be * appreciated but is not required. * 2. Altered source versions must be plainly marked as such, and must not be * misrepresented as being the original software. * 3. This notice may not be removed or altered from any source distribution. */ #include #include #include #include #include #include using namespace std; int32 b2_toiCalls, b2_toiIters, b2_toiMaxIters; int32 b2_toiRootIters, b2_toiMaxRootIters; struct b2SeparationFunction { enum Type { e_points, e_faceA, e_faceB }; // TODO_ERIN might not need to return the separation float32 Initialize(const b2SimplexCache* cache, const b2DistanceProxy* proxyA, const b2Sweep& sweepA, const b2DistanceProxy* proxyB, const b2Sweep& sweepB, float32 t1) { m_proxyA = proxyA; m_proxyB = proxyB; int32 count = cache->count; b2Assert(0 < count && count < 3); m_sweepA = sweepA; m_sweepB = sweepB; b2Transform xfA, xfB; m_sweepA.GetTransform(&xfA, t1); m_sweepB.GetTransform(&xfB, t1); if (count == 1) { m_type = e_points; b2Vec2 localPointA = m_proxyA->GetVertex(cache->indexA[0]); b2Vec2 localPointB = m_proxyB->GetVertex(cache->indexB[0]); b2Vec2 pointA = b2Mul(xfA, localPointA); b2Vec2 pointB = b2Mul(xfB, localPointB); m_axis = pointB - pointA; float32 s = m_axis.Normalize(); return s; } else if (cache->indexA[0] == cache->indexA[1]) { // Two points on B and one on A. m_type = e_faceB; b2Vec2 localPointB1 = proxyB->GetVertex(cache->indexB[0]); b2Vec2 localPointB2 = proxyB->GetVertex(cache->indexB[1]); m_axis = b2Cross(localPointB2 - localPointB1, 1.0f); m_axis.Normalize(); b2Vec2 normal = b2Mul(xfB.q, m_axis); m_localPoint = 0.5f * (localPointB1 + localPointB2); b2Vec2 pointB = b2Mul(xfB, m_localPoint); b2Vec2 localPointA = proxyA->GetVertex(cache->indexA[0]); b2Vec2 pointA = b2Mul(xfA, localPointA); float32 s = b2Dot(pointA - pointB, normal); if (s < 0.0f) { m_axis = -m_axis; s = -s; } return s; } else { // Two points on A and one or two points on B. m_type = e_faceA; b2Vec2 localPointA1 = m_proxyA->GetVertex(cache->indexA[0]); b2Vec2 localPointA2 = m_proxyA->GetVertex(cache->indexA[1]); m_axis = b2Cross(localPointA2 - localPointA1, 1.0f); m_axis.Normalize(); b2Vec2 normal = b2Mul(xfA.q, m_axis); m_localPoint = 0.5f * (localPointA1 + localPointA2); b2Vec2 pointA = b2Mul(xfA, m_localPoint); b2Vec2 localPointB = m_proxyB->GetVertex(cache->indexB[0]); b2Vec2 pointB = b2Mul(xfB, localPointB); float32 s = b2Dot(pointB - pointA, normal); if (s < 0.0f) { m_axis = -m_axis; s = -s; } return s; } } float32 FindMinSeparation(int32* indexA, int32* indexB, float32 t) const { b2Transform xfA, xfB; m_sweepA.GetTransform(&xfA, t); m_sweepB.GetTransform(&xfB, t); switch (m_type) { case e_points: { b2Vec2 axisA = b2MulT(xfA.q, m_axis); b2Vec2 axisB = b2MulT(xfB.q, -m_axis); *indexA = m_proxyA->GetSupport(axisA); *indexB = m_proxyB->GetSupport(axisB); b2Vec2 localPointA = m_proxyA->GetVertex(*indexA); b2Vec2 localPointB = m_proxyB->GetVertex(*indexB); b2Vec2 pointA = b2Mul(xfA, localPointA); b2Vec2 pointB = b2Mul(xfB, localPointB); float32 separation = b2Dot(pointB - pointA, m_axis); return separation; } case e_faceA: { b2Vec2 normal = b2Mul(xfA.q, m_axis); b2Vec2 pointA = b2Mul(xfA, m_localPoint); b2Vec2 axisB = b2MulT(xfB.q, -normal); *indexA = -1; *indexB = m_proxyB->GetSupport(axisB); b2Vec2 localPointB = m_proxyB->GetVertex(*indexB); b2Vec2 pointB = b2Mul(xfB, localPointB); float32 separation = b2Dot(pointB - pointA, normal); return separation; } case e_faceB: { b2Vec2 normal = b2Mul(xfB.q, m_axis); b2Vec2 pointB = b2Mul(xfB, m_localPoint); b2Vec2 axisA = b2MulT(xfA.q, -normal); *indexB = -1; *indexA = m_proxyA->GetSupport(axisA); b2Vec2 localPointA = m_proxyA->GetVertex(*indexA); b2Vec2 pointA = b2Mul(xfA, localPointA); float32 separation = b2Dot(pointA - pointB, normal); return separation; } default: b2Assert(false); *indexA = -1; *indexB = -1; return 0.0f; } } float32 Evaluate(int32 indexA, int32 indexB, float32 t) const { b2Transform xfA, xfB; m_sweepA.GetTransform(&xfA, t); m_sweepB.GetTransform(&xfB, t); switch (m_type) { case e_points: { b2Vec2 axisA = b2MulT(xfA.q, m_axis); b2Vec2 axisB = b2MulT(xfB.q, -m_axis); b2Vec2 localPointA = m_proxyA->GetVertex(indexA); b2Vec2 localPointB = m_proxyB->GetVertex(indexB); b2Vec2 pointA = b2Mul(xfA, localPointA); b2Vec2 pointB = b2Mul(xfB, localPointB); float32 separation = b2Dot(pointB - pointA, m_axis); return separation; } case e_faceA: { b2Vec2 normal = b2Mul(xfA.q, m_axis); b2Vec2 pointA = b2Mul(xfA, m_localPoint); b2Vec2 axisB = b2MulT(xfB.q, -normal); b2Vec2 localPointB = m_proxyB->GetVertex(indexB); b2Vec2 pointB = b2Mul(xfB, localPointB); float32 separation = b2Dot(pointB - pointA, normal); return separation; } case e_faceB: { b2Vec2 normal = b2Mul(xfB.q, m_axis); b2Vec2 pointB = b2Mul(xfB, m_localPoint); b2Vec2 axisA = b2MulT(xfA.q, -normal); b2Vec2 localPointA = m_proxyA->GetVertex(indexA); b2Vec2 pointA = b2Mul(xfA, localPointA); float32 separation = b2Dot(pointA - pointB, normal); return separation; } default: b2Assert(false); return 0.0f; } } const b2DistanceProxy* m_proxyA; const b2DistanceProxy* m_proxyB; b2Sweep m_sweepA, m_sweepB; Type m_type; b2Vec2 m_localPoint; b2Vec2 m_axis; }; // CCD via the local separating axis method. This seeks progression // by computing the largest time at which separation is maintained. void b2TimeOfImpact(b2TOIOutput* output, const b2TOIInput* input) { ++b2_toiCalls; output->state = b2TOIOutput::e_unknown; output->t = input->tMax; const b2DistanceProxy* proxyA = &input->proxyA; const b2DistanceProxy* proxyB = &input->proxyB; b2Sweep sweepA = input->sweepA; b2Sweep sweepB = input->sweepB; // Large rotations can make the root finder fail, so we normalize the // sweep angles. sweepA.Normalize(); sweepB.Normalize(); float32 tMax = input->tMax; float32 totalRadius = proxyA->m_radius + proxyB->m_radius; float32 target = b2Max(b2_linearSlop, totalRadius - 3.0f * b2_linearSlop); float32 tolerance = 0.25f * b2_linearSlop; b2Assert(target > tolerance); float32 t1 = 0.0f; const int32 k_maxIterations = 20; // TODO_ERIN b2Settings int32 iter = 0; // Prepare input for distance query. b2SimplexCache cache; cache.count = 0; b2DistanceInput distanceInput; distanceInput.proxyA = input->proxyA; distanceInput.proxyB = input->proxyB; distanceInput.useRadii = false; // The outer loop progressively attempts to compute new separating axes. // This loop terminates when an axis is repeated (no progress is made). for(;;) { b2Transform xfA, xfB; sweepA.GetTransform(&xfA, t1); sweepB.GetTransform(&xfB, t1); // Get the distance between shapes. We can also use the results // to get a separating axis. distanceInput.transformA = xfA; distanceInput.transformB = xfB; b2DistanceOutput distanceOutput; b2Distance(&distanceOutput, &cache, &distanceInput); // If the shapes are overlapped, we give up on continuous collision. if (distanceOutput.distance <= 0.0f) { // Failure! output->state = b2TOIOutput::e_overlapped; output->t = 0.0f; break; } if (distanceOutput.distance < target + tolerance) { // Victory! output->state = b2TOIOutput::e_touching; output->t = t1; break; } // Initialize the separating axis. b2SeparationFunction fcn; fcn.Initialize(&cache, proxyA, sweepA, proxyB, sweepB, t1); #if 0 // Dump the curve seen by the root finder { const int32 N = 100; float32 dx = 1.0f / N; float32 xs[N+1]; float32 fs[N+1]; float32 x = 0.0f; for (int32 i = 0; i <= N; ++i) { sweepA.GetTransform(&xfA, x); sweepB.GetTransform(&xfB, x); float32 f = fcn.Evaluate(xfA, xfB) - target; printf("%g %g\n", x, f); xs[i] = x; fs[i] = f; x += dx; } } #endif // Compute the TOI on the separating axis. We do this by successively // resolving the deepest point. This loop is bounded by the number of vertices. bool done = false; float32 t2 = tMax; int32 pushBackIter = 0; for (;;) { // Find the deepest point at t2. Store the witness point indices. int32 indexA, indexB; float32 s2 = fcn.FindMinSeparation(&indexA, &indexB, t2); // Is the final configuration separated? if (s2 > target + tolerance) { // Victory! output->state = b2TOIOutput::e_separated; output->t = tMax; done = true; break; } // Has the separation reached tolerance? if (s2 > target - tolerance) { // Advance the sweeps t1 = t2; break; } // Compute the initial separation of the witness points. float32 s1 = fcn.Evaluate(indexA, indexB, t1); // Check for initial overlap. This might happen if the root finder // runs out of iterations. if (s1 < target - tolerance) { output->state = b2TOIOutput::e_failed; output->t = t1; done = true; break; } // Check for touching if (s1 <= target + tolerance) { // Victory! t1 should hold the TOI (could be 0.0). output->state = b2TOIOutput::e_touching; output->t = t1; done = true; break; } // Compute 1D root of: f(x) - target = 0 int32 rootIterCount = 0; float32 a1 = t1, a2 = t2; for (;;) { // Use a mix of the secant rule and bisection. float32 t; if (rootIterCount & 1) { // Secant rule to improve convergence. t = a1 + (target - s1) * (a2 - a1) / (s2 - s1); } else { // Bisection to guarantee progress. t = 0.5f * (a1 + a2); } float32 s = fcn.Evaluate(indexA, indexB, t); if (b2Abs(s - target) < tolerance) { // t2 holds a tentative value for t1 t2 = t; break; } // Ensure we continue to bracket the root. if (s > target) { a1 = t; s1 = s; } else { a2 = t; s2 = s; } ++rootIterCount; ++b2_toiRootIters; if (rootIterCount == 50) { break; } } b2_toiMaxRootIters = b2Max(b2_toiMaxRootIters, rootIterCount); ++pushBackIter; if (pushBackIter == b2_maxPolygonVertices) { break; } } ++iter; ++b2_toiIters; if (done) { break; } if (iter == k_maxIterations) { // Root finder got stuck. Semi-victory. output->state = b2TOIOutput::e_failed; output->t = t1; break; } } b2_toiMaxIters = b2Max(b2_toiMaxIters, iter); }