// Copyright 2021 DeepMind Technologies Limited // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include "engine/engine_collision_sdf.h" #include #include #include #include // IWYU pragma: keep #include #include "engine/engine_collision_primitive.h" #include "engine/engine_io.h" #include "engine/engine_plugin.h" #include "engine/engine_sort.h" #include "engine/engine_util_blas.h" #include "engine/engine_util_errmem.h" #include "engine/engine_util_misc.h" #include "engine/engine_util_spatial.h" #define MAXSDFFACE 1300 #define MAXMESHPNT 500 //---------------------------- interpolated sdf ------------------------------------------- mjtNum boxProjection(mjtNum point[3], const mjtNum box[6]) { mjtNum r[3] = {point[0] - box[0], point[1] - box[1], point[2] - box[2]}; mjtNum q[3] = {mju_abs(r[0]) - box[3], mju_abs(r[1]) - box[4], mju_abs(r[2]) - box[5]}; mjtNum dist_sqr = 0; mjtNum eps = 1e-6; // skip the projection if inside if (q[0] <= 0 && q[1] <= 0 && q[2] <= 0) { return mju_max(q[0], mju_max(q[1], q[2])); } // in-place projection inside the box if outside if ( q[0] >= 0 ) { dist_sqr += q[0] * q[0]; point[0] -= r[0] > 0 ? (q[0]+eps) : -(q[0]+eps); } if ( q[1] >= 0 ) { dist_sqr += q[1] * q[1]; point[1] -= r[1] > 0 ? (q[1]+eps) : -(q[1]+eps); } if ( q[2] >= 0 ) { dist_sqr += q[2] * q[2]; point[2] -= r[2] > 0 ? (q[2]+eps) : -(q[2]+eps); } return mju_sqrt(dist_sqr); } // find the octree leaf containing the point p, return the index of the leaf and // populate the weights of the interpolated function (if w is not null) and of // its gradient (if dw is not null) using the vertices as degrees of freedom for // trilinear interpolation. static int findOct(mjtNum w[8], mjtNum dw[8][3], const mjtNum* oct_aabb, const int* oct_child, const mjtNum p[3]) { int stack = 0; mjtNum eps = 1e-8; int niter = 100; while (niter-- > 0) { int node = stack; mjtNum vmin[3], vmax[3]; if (node == -1) { // SHOULD NOT OCCUR mju_error("Invalid node number"); return -1; } for (int j = 0; j < 3; j++) { vmin[j] = oct_aabb[6*node+j] - oct_aabb[6*node+3+j]; vmax[j] = oct_aabb[6*node+j] + oct_aabb[6*node+3+j]; } // check if the point is inside the aabb of the octree node if (p[0] + eps < vmin[0] || p[0] - eps > vmax[0] || p[1] + eps < vmin[1] || p[1] - eps > vmax[1] || p[2] + eps < vmin[2] || p[2] - eps > vmax[2]) { continue; } mjtNum coord[3] = {(p[0] - vmin[0]) / (vmax[0] - vmin[0]), (p[1] - vmin[1]) / (vmax[1] - vmin[1]), (p[2] - vmin[2]) / (vmax[2] - vmin[2])}; // check if the node is a leaf if (oct_child[8*node+0] == -1 && oct_child[8*node+1] == -1 && oct_child[8*node+2] == -1 && oct_child[8*node+3] == -1 && oct_child[8*node+4] == -1 && oct_child[8*node+5] == -1 && oct_child[8*node+6] == -1 && oct_child[8*node+7] == -1) { for (int j = 0; j < 8; j++) { if (w) { w[j] = (j & 1 ? coord[0] : 1 - coord[0]) * (j & 2 ? coord[1] : 1 - coord[1]) * (j & 4 ? coord[2] : 1 - coord[2]); } if (dw) { dw[j][0] = (j & 1 ? 1 : -1) * (j & 2 ? coord[1] : 1 - coord[1]) * (j & 4 ? coord[2] : 1 - coord[2]); dw[j][1] = (j & 1 ? coord[0] : 1 - coord[0]) * (j & 2 ? 1 : -1) * (j & 4 ? coord[2] : 1 - coord[2]); dw[j][2] = (j & 1 ? coord[0] : 1 - coord[0]) * (j & 2 ? coord[1] : 1 - coord[1]) * (j & 4 ? 1 : -1); } } return node; } // compute which of 8 children to visit next int x = coord[0] < .5 ? 1 : 0; int y = coord[1] < .5 ? 1 : 0; int z = coord[2] < .5 ? 1 : 0; stack = oct_child[8 * node + 4*z + 2*y + x]; } mju_error("Node not found"); // SHOULD NOT OCCUR return -1; } // sdf mjtNum oct_distance(const mjModel* m, const mjtNum p[3], int meshid) { int octadr = m->mesh_octadr[meshid]; int* oct_child = m->oct_child + 8*octadr; mjtNum* oct_aabb = m->oct_aabb + 6*octadr; mjtNum* oct_coeff = m->oct_coeff + 8*octadr; mjtNum w[8]; mjtNum sdf = 0; mjtNum point[3] = {p[0], p[1], p[2]}; mjtNum boxDist = boxProjection(point, oct_aabb); if (boxDist > 0) { return boxDist; } int node = findOct(w, NULL, oct_aabb, oct_child, point); for (int i = 0; i < 8; ++i) { sdf += w[i] * oct_coeff[8*node + i]; } return sdf; } // gradient of sdf void oct_gradient(const mjModel* m, mjtNum grad[3], const mjtNum point[3], int meshid) { mju_zero3(grad); mjtNum p[3] = {point[0], point[1], point[2]}; int octadr = m->mesh_octadr[meshid]; int* oct_child = m->oct_child + 8*octadr; mjtNum* oct_aabb = m->oct_aabb + 6*octadr; mjtNum* oct_coeff = m->oct_coeff + 8*octadr; // analytic in the interior if (boxProjection(p, oct_aabb) <= 0) { mjtNum dw[8][3]; int node = findOct(NULL, dw, oct_aabb, oct_child, p); for (int i = 0; i < 8; ++i) { grad[0] += dw[i][0] * oct_coeff[8*node + i]; grad[1] += dw[i][1] * oct_coeff[8*node + i]; grad[2] += dw[i][2] * oct_coeff[8*node + i]; } return; } // finite difference in the exterior mjtNum eps = 1e-8; mjtNum dist0 = oct_distance(m, point, meshid); mjtNum pointX[3] = {point[0]+eps, point[1], point[2]}; mjtNum distX = oct_distance(m, pointX, meshid); mjtNum pointY[3] = {point[0], point[1]+eps, point[2]}; mjtNum distY = oct_distance(m, pointY, meshid); mjtNum pointZ[3] = {point[0], point[1], point[2]+eps}; mjtNum distZ = oct_distance(m, pointZ, meshid); grad[0] = (distX - dist0) / eps; grad[1] = (distY - dist0) / eps; grad[2] = (distZ - dist0) / eps; } //---------------------------- primitives sdf --------------------------------------------- static void radialField3d(mjtNum field[3], const mjtNum a[3], const mjtNum x[3], const mjtNum size[3]) { field[0] = -size[0] / a[0]; field[1] = -size[1] / a[1]; field[2] = -size[2] / a[2]; mju_normalize3(field); // flip sign if necessary if (x[0] < 0) field[0] = -field[0]; if (x[1] < 0) field[1] = -field[1]; if (x[2] < 0) field[2] = -field[2]; } static mjtNum geomDistance(const mjModel* m, const mjData* d, const mjpPlugin* p, int i, const mjtNum x[3], mjtGeom type) { mjtNum a[3], b[3]; const mjtNum* size = m->geom_size+3*i; // see https://iquilezles.org/articles/distfunctions/ switch (type) { case mjGEOM_PLANE: return x[2]; case mjGEOM_SPHERE: return mju_norm3(x) - size[0]; case mjGEOM_BOX: // compute shortest distance to box surface if outside, otherwise // intersect with a unit gradient that linearly rotates from radial to the face normals a[0] = mju_abs(x[0]) - size[0]; a[1] = mju_abs(x[1]) - size[1]; a[2] = mju_abs(x[2]) - size[2]; if (a[0] >= 0 || a[1] >= 0 || a[2] >= 0) { b[0] = mju_max(a[0], 0); b[1] = mju_max(a[1], 0); b[2] = mju_max(a[2], 0); return mju_norm3(b) + mju_min(mju_max(a[0], mju_max(a[1], a[2])), 0); } radialField3d(b, a, x, size); mjtNum t[3]; t[0] = -a[0] / mju_abs(b[0]); t[1] = -a[1] / mju_abs(b[1]); t[2] = -a[2] / mju_abs(b[2]); return -mju_min(t[0], mju_min(t[1], t[2])) * mju_norm3(b); case mjGEOM_CAPSULE: a[0] = x[0]; a[1] = x[1]; a[2] = x[2] - mju_clip(x[2], -size[1], size[1]); return mju_norm3(a) - size[0]; case mjGEOM_ELLIPSOID: a[0] = x[0] / size[0]; a[1] = x[1] / size[1]; a[2] = x[2] / size[2]; b[0] = a[0] / size[0]; b[1] = a[1] / size[1]; b[2] = a[2] / size[2]; mjtNum k0 = mju_norm3(a); mjtNum k1 = mju_norm3(b); return k0 * (k0 - 1.0) / k1; case mjGEOM_CYLINDER: a[0] = mju_sqrt(x[0]*x[0]+x[1]*x[1]) - size[0]; a[1] = mju_abs(x[2]) - size[1]; b[0] = mju_max(a[0], 0); b[1] = mju_max(a[1], 0); return mju_min(mju_max(a[0], a[1]), 0) + mju_norm(b, 2); case mjGEOM_SDF: if (p) { return p->sdf_distance(x, d, i); } else { return oct_distance(m, x, i); } default: mjERROR("sdf collisions not available for geom type %d", type); return 0; } } static void geomGradient(mjtNum gradient[3], const mjModel* m, const mjData* d, const mjpPlugin* p, int i, const mjtNum x[3], mjtGeom type) { mjtNum a[3], b[3], c, e; const mjtNum* size = m->geom_size+3*i; // see https://iquilezles.org/articles/distfunctions/ switch (type) { case mjGEOM_PLANE: mju_zero3(gradient); gradient[2] = 1; break; case mjGEOM_SPHERE: mju_copy3(gradient, x); c = mju_norm3(x); gradient[0] *= 1. / c; gradient[1] *= 1. / c; gradient[2] *= 1. / c; break; case mjGEOM_BOX: mju_zero3(gradient); a[0] = mju_abs(x[0]) - size[0]; a[1] = mju_abs(x[1]) - size[1]; a[2] = mju_abs(x[2]) - size[2]; int k = a[0] > a[1] ? 0 : 1; int l = a[2] > a[k] ? 2 : k; if (a[l] < 0) { radialField3d(gradient, a, x, size); } else { b[0] = mju_max(a[0], 0); b[1] = mju_max(a[1], 0); b[2] = mju_max(a[2], 0); c = mju_norm3(b); gradient[0] = a[0] > 0 ? b[0] / c * x[0] / mju_abs(x[0]) : 0; gradient[1] = a[1] > 0 ? b[1] / c * x[1] / mju_abs(x[1]) : 0; gradient[2] = a[2] > 0 ? b[2] / c * x[2] / mju_abs(x[2]) : 0; } break; case mjGEOM_CAPSULE: a[0] = x[0]; a[1] = x[1]; a[2] = x[2] - mju_clip(x[2], -size[1], size[1]); c = mju_norm3(a); gradient[0] = a[0] / c; gradient[1] = a[1] / c; gradient[2] = a[2] / c; break; case mjGEOM_ELLIPSOID: a[0] = x[0] / size[0]; a[1] = x[1] / size[1]; a[2] = x[2] / size[2]; b[0] = a[0] / size[0]; b[1] = a[1] / size[1]; b[2] = a[2] / size[2]; mjtNum k0 = mju_norm3(a); mjtNum k1 = mju_norm3(b); mjtNum invK0 = 1. / k0; mjtNum invK1 = 1. / k1; mjtNum gk0[3] = {b[0]*invK0, b[1]*invK0, b[2]*invK0}; mjtNum gk1[3] = {b[0]*invK1/(size[0]*size[0]), b[1]*invK1/(size[1]*size[1]), b[2]*invK1/(size[2]*size[2])}; mjtNum df_dk0 = (2.*k0 - 1.) * invK1; mjtNum df_dk1 = k0*(k0 - 1.) * invK1 * invK1; gradient[0] = gk0[0]*df_dk0 - gk1[0]*df_dk1; gradient[1] = gk0[1]*df_dk0 - gk1[1]*df_dk1; gradient[2] = gk0[2]*df_dk0 - gk1[2]*df_dk1; mju_normalize3(gradient); break; case mjGEOM_CYLINDER: c = mju_sqrt(x[0]*x[0]+x[1]*x[1]); e = mju_abs(x[2]); a[0] = c - size[0]; a[1] = e - size[1]; mjtNum grada[3] = {x[0] / mju_max(c, 1. / mjMAXVAL), x[1] / mju_max(c, 1. / mjMAXVAL), x[2] / mju_max(e, 1. / mjMAXVAL)}; int j = a[0] > a[1] ? 0 : 1; if (a[j] < 0) { gradient[0] = j == 0 ? grada[0] : 0; gradient[1] = j == 0 ? grada[1] : 0; gradient[2] = j == 1 ? grada[2] : 0; } else { b[0] = mju_max(a[0], 0); b[1] = mju_max(a[1], 0); mjtNum bnorm = mju_max(mju_norm(b, 2), 1./mjMAXVAL); gradient[0] = grada[0] * b[0] / bnorm; gradient[1] = grada[1] * b[0] / bnorm; gradient[2] = grada[2] * b[1] / bnorm; } break; case mjGEOM_SDF: if (p) { p->sdf_gradient(gradient, x, d, i); } else { oct_gradient(m, gradient, x, i); } break; default: mjERROR("sdf collisions not available for geom type %d", type); } } //---------------------------- helper functions ------------------------------------------- // signed distance function mjtNum mjc_distance(const mjModel* m, const mjData* d, const mjSDF* s, const mjtNum x[3]) { mjtNum y[3]; switch (s->type) { case mjSDFTYPE_SINGLE: return geomDistance(m, d, s->plugin[0], s->id[0], x, s->geomtype[0]); case mjSDFTYPE_INTERSECTION: mju_mulMatVec3(y, s->relmat, x); mju_addTo3(y, s->relpos); return mju_max(geomDistance(m, d, s->plugin[0], s->id[0], x, s->geomtype[0]), geomDistance(m, d, s->plugin[1], s->id[1], y, s->geomtype[1])); case mjSDFTYPE_MIDSURFACE: mju_mulMatVec3(y, s->relmat, x); mju_addTo3(y, s->relpos); return geomDistance(m, d, s->plugin[0], s->id[0], x, s->geomtype[0]) - geomDistance(m, d, s->plugin[1], s->id[1], y, s->geomtype[1]); case mjSDFTYPE_COLLISION: mju_mulMatVec3(y, s->relmat, x); mju_addTo3(y, s->relpos); mjtNum A = geomDistance(m, d, s->plugin[0], s->id[0], x, s->geomtype[0]); mjtNum B = geomDistance(m, d, s->plugin[1], s->id[1], y, s->geomtype[1]); return A + B + mju_abs(mju_max(A, B)); default: mjERROR("SDF type not available"); return 0; } } // gradient of sdf void mjc_gradient(const mjModel* m, const mjData* d, const mjSDF* s, mjtNum gradient[3], const mjtNum x[3]) { mjtNum y[3]; const mjtNum* point[2] = {x, y}; mjtNum grad1[3], grad2[3]; switch (s->type) { case mjSDFTYPE_INTERSECTION: mju_mulMatVec3(y, s->relmat, x); mju_addTo3(y, s->relpos); int i = geomDistance(m, d, s->plugin[0], s->id[0], x, s->geomtype[0]) > geomDistance(m, d, s->plugin[1], s->id[1], y, s->geomtype[1]) ? 0 : 1; geomGradient(gradient, m, d, s->plugin[i], s->id[i], point[i], s->geomtype[i]); if (i == 1) { mju_mulMatTVec3(gradient, s->relmat, gradient); } break; case mjSDFTYPE_MIDSURFACE: mju_mulMatVec3(y, s->relmat, x); mju_addTo3(y, s->relpos); geomGradient(grad1, m, d, s->plugin[0], s->id[0], x, s->geomtype[0]); mju_normalize3(grad1); geomGradient(grad2, m, d, s->plugin[1], s->id[1], y, s->geomtype[1]); mju_mulMatTVec3(grad2, s->relmat, grad2); mju_normalize3(grad2); mju_sub3(gradient, grad1, grad2); mju_normalize3(gradient); break; case mjSDFTYPE_COLLISION: mju_mulMatVec3(y, s->relmat, x); mju_addTo3(y, s->relpos); mjtNum A = geomDistance(m, d, s->plugin[0], s->id[0], x, s->geomtype[0]); mjtNum B = geomDistance(m, d, s->plugin[1], s->id[1], y, s->geomtype[1]); geomGradient(grad1, m, d, s->plugin[0], s->id[0], x, s->geomtype[0]); geomGradient(grad2, m, d, s->plugin[1], s->id[1], y, s->geomtype[1]); mju_mulMatTVec3(grad2, s->relmat, grad2); gradient[0] = grad1[0] + grad2[0]; gradient[1] = grad1[1] + grad2[1]; gradient[2] = grad1[2] + grad2[2]; mju_addToScl3(gradient, A > B ? grad1 : grad2, mju_max(A, B) > 0 ? 1 : -1); break; case mjSDFTYPE_SINGLE: geomGradient(gradient, m, d, s->plugin[0], s->id[0], point[0], s->geomtype[0]); break; default: mjERROR("SDF type not available"); } } // get sdf from geom id const mjpPlugin* mjc_getSDF(const mjModel* m, int id) { int instance = m->geom_plugin[id]; const int nslot = mjp_pluginCount(); const int slot = m->plugin[instance]; const mjpPlugin* sdf = mjp_getPluginAtSlotUnsafe(slot, nslot); if (!sdf) mjERROR("invalid plugin slot: %d", slot); if (!(sdf->capabilityflags & mjPLUGIN_SDF)) { mjERROR("Plugin is not a signed distance field at slot %d", slot); } return sdf; } // map (pos12, mat12) as (xpos2, xmat2)^-1 \circ (xpos1, xmat1) static void mapPose(const mjtNum xpos1[3], const mjtNum xquat1[4], const mjtNum xpos2[3], const mjtNum xquat2[4], mjtNum pos12[3], mjtNum mat12[9]) { mjtNum negpos[3], negquat[4], quat12[4]; mju_negPose(negpos, negquat, xpos2, xquat2); mju_mulPose(pos12, quat12, negpos, negquat, xpos1, xquat1); mju_quat2Mat(mat12, quat12); } //---------------------------- narrow phase ----------------------------------------------- // comparison function for contact sorting static inline int distcmp(int* i, int* j, void* context) { mjtNum d1 = ((mjtNum*)context)[*i]; mjtNum d2 = ((mjtNum*)context)[*j]; if (d1 < d2) { return -1; } else if (d1 == d2) { return 0; } else { return 1; } } // define distSort function for contact sorting mjSORT(distSort, int, distcmp) // check if the collision point already exists static int isknown(const mjtNum* points, const mjtNum x[3], int cnt) { for (int i = 0; i < cnt; i++) { if (mju_dist3(x, points + 3*i) < mjMINVAL) { return 1; } } return 0; } // adds candidate point to result static int addContact(mjtNum* points, mjContact* con, const mjtNum x[3], const mjtNum pos2[3], const mjtNum quat2[4], mjtNum dist, int cnt, const mjModel* m, const mjSDF* s, mjData* d) { // check if there is a collision if (dist > 0 || isknown(points, x, cnt)) { return cnt; } else { mju_copy3(points+3*cnt, x); } // compute normal in local coordinates mjtNum norm[3], vec[3]; mjc_gradient(m, d, s, norm, x); mju_scl3(norm, norm, -1); // construct contact con[cnt].dist = dist; mju_rotVecQuat(con[cnt].frame, norm, quat2); mju_zero3(con[cnt].frame+3); mju_makeFrame(con[cnt].frame); mju_scl3(vec, con[cnt].frame, -con[cnt].dist/2); mju_rotVecQuat(con[cnt].pos, x, quat2); mju_addTo3(con[cnt].pos, pos2); mju_addTo3(con[cnt].pos, vec); return cnt+1; } // finds minimum of Frank-Wolfe objective static mjtNum stepFrankWolfe(mjtNum x[3], const mjtNum* corners, int ncorners, const mjModel* m, const mjSDF* sdf, mjData* d) { for (int step=0; step < m->opt.sdf_iterations; step++) { mjtNum best = 1e10, fun, s[3], grad[3]; // evaluate gradient mjc_gradient(m, d, sdf, grad, x); // evaluate all corners for (int i=0; i < ncorners; i++) { // compute sdf fun = mju_dot3(corners + 3*i, grad); // save argmin if (fun < best) { best = fun; mju_copy3(s, corners + 3*i); } } // update collision point mju_subFrom3(s, x); mju_addToScl3(x, s, 2. / (step+2.)); } // compute distance return mjc_distance(m, d, sdf, x); } // finds minimum using gradient descent static mjtNum stepGradient(mjtNum x[3], const mjModel* m, const mjSDF* s, mjData* d, int niter) { const mjtNum c = .1; // reduction factor for the target decrease in the objective function const mjtNum rho = .5; // reduction factor for the gradient scaling (alpha) const mjtNum amin = 1e-4; // minimum value for alpha mjtNum dist = mjMAXVAL; for (int step=0; step < niter; step++) { mjtNum grad[3]; mjtNum alpha = 2.; // initial line search factor scaling the gradient // the units of the gradient depend on s->type // evaluate gradient mjc_gradient(m, d, s, grad, x); // sanity check if (isnan(grad[0]) || grad[0] > mjMAXVAL || grad[0] < -mjMAXVAL || isnan(grad[1]) || grad[1] > mjMAXVAL || grad[1] < -mjMAXVAL || isnan(grad[2]) || grad[2] > mjMAXVAL || grad[2] < -mjMAXVAL) { return mjMAXVAL; } // save current solution mjtNum x0[] = {x[0], x[1], x[2]}; // evaluate distance mjtNum dist0 = mjc_distance(m, d, s, x0); mjtNum wolfe = - c * alpha * mju_dot3(grad, grad); // backtracking line search do { alpha *= rho; wolfe *= rho; mju_addScl3(x, x0, grad, -alpha); dist = mjc_distance(m, d, s, x); } while (alpha > amin && dist - dist0 > wolfe); // if no improvement, early stop if (dist0 < dist) { return dist; } } // the distance will be used for the contact creation return dist; } //---------------------------- bounding box vs sdf ------------------------------------------------- // stricter triangle collision static int triangleIntersect(const mjtNum triangle[9], const mjModel* m, const mjSDF* sdf, mjData* d) { mjtNum edges[6]; mjtNum normal[3], center[3]; mjtNum v[9], cross[9], p[3]; mjtNum kDistanceScl = 10.; // triangle normal mju_sub3(edges+0, triangle+3, triangle); mju_sub3(edges+3, triangle+6, triangle); mju_cross(normal, edges, edges+3); mju_normalize3(normal); // fourth point mju_scl3(p, triangle, 1./3.); mju_addToScl3(p, triangle+3, 1./3.); mju_addToScl3(p, triangle+6, 1./3.); mjtNum h = -mjc_distance(m, d, sdf, p)/kDistanceScl; mju_addToScl3(p, normal, -h); // circumsphere center mju_sub3(v+0, triangle+0, p); mju_sub3(v+3, triangle+3, p); mju_sub3(v+6, triangle+6, p); mju_cross(cross+0, v+3, v+6); mju_cross(cross+3, v+6, v+0); mju_cross(cross+6, v+0, v+3); mju_scl3(center, cross, mju_dot3(v, v)); mju_addToScl3(center, cross+3, mju_dot3(v+3, v+3)); mju_addToScl3(center, cross+6, mju_dot3(v+6, v+6)); mju_scl3(center, center, 1./(2.*mju_dot3(v, cross))); // circumsphere radius mjtNum r = mju_sqrt(mju_dot3(center, center)); // coordinate change mju_addTo3(center, p); return mjc_distance(m, d, sdf, center) < r; } // intersect with circumsphere of bounding box static int boxIntersect(const mjtNum bvh[6], const mjtNum offset[3], const mjtNum rotation[9], const mjModel* m, const mjSDF* s, mjData* d) { mjtNum candidate[3]; mjtNum r = mju_norm3(bvh+3); mju_mulMatVec3(candidate, rotation, bvh); mju_addTo3(candidate, offset); // check if inside the bounding box return mjc_distance(m, d, s, candidate) < r; } //---------------------------- mesh vs sdf broad phase -------------------------------------------- // tree vs sdf binary search static void collideBVH(const mjModel* m, mjData* d, int g, const mjtNum offset[3], const mjtNum rotation[9], int* faces, int* npoints, int* n0, const mjSDF* sdf) { const int bvhadr = m->mesh_bvhadr[m->geom_dataid[g]]; const int* faceid = m->bvh_nodeid + bvhadr; const mjtNum* bvh = m->bvh_aabb + 6*bvhadr; const int* child = m->bvh_child + 2*bvhadr; mjtByte* bvh_active = m->vis.global.bvactive ? d->bvh_active + bvhadr : NULL; mj_markStack(d); // TODO(quaglino): Store bvh max depths to make this bound tighter. int max_stack = m->mesh_bvhnum[m->geom_dataid[g]]; struct CollideTreeArgs_ { int node; }; typedef struct CollideTreeArgs_ CollideTreeArgs; CollideTreeArgs* stack = mjSTACKALLOC(d, max_stack, CollideTreeArgs); int nstack = 0; stack[nstack].node = 0; nstack++; while (nstack) { (*n0)++; // pop from stack nstack--; int node = stack[nstack].node; // node1 is a leaf if (faceid[node] != -1) { if (boxIntersect(bvh+6*node, offset, rotation, m, sdf, d)) { faces[*npoints] = faceid[node]; if (++(*npoints) == MAXSDFFACE) { mju_warning("mjc_MeshSDF: too many bounding volumes, some contacts may be missed"); mj_freeStack(d); return; } if (bvh_active) bvh_active[node] = 1; } continue; } // if no intersection at intermediate levels, stop if (!boxIntersect(bvh+6*node, offset, rotation, m, sdf, d)) { continue; } if (bvh_active) bvh_active[node] = 1; // recursive call for (int i=0; i < 2; i++) { if (child[2*node+i] != -1) { if (nstack >= max_stack) mjERROR("BVH stack depth exceeded."); stack[nstack].node = child[2*node+i]; nstack++; } } } mj_freeStack(d); } //------------------------------ collision functions ----------------------------------------------- // collision between a height field and a signed distance field int mjc_HFieldSDF(const mjModel* m, const mjData* d, mjContact* con, int g1, int g2, mjtNum margin) { mju_warning("HField vs SDF collision not yet supported!"); return 0; } // collision between a mesh and a signed distance field int mjc_MeshSDF(const mjModel* m, const mjData* d, mjContact* con, int g1, int g2, mjtNum margin) { mjGETINFO; mjtNum offset[3], rotation[9], corners[9], x[3], depth; mjtNum points[3*MAXSDFFACE], dist[MAXMESHPNT], candidate[3*MAXMESHPNT]; int vertadr = m->mesh_vertadr[m->geom_dataid[g1]]; int faceadr = m->mesh_faceadr[m->geom_dataid[g1]]; int cnt=0, npoints=0, ncandidate=0, n0=0, faces[MAXSDFFACE]={-1}, index[MAXMESHPNT]; // get sdf plugin int instance = m->geom_plugin[g2]; const mjpPlugin* sdf_ptr = instance == -1 ? NULL : mjc_getSDF(m, g2); instance = instance == -1 ? m->geom_dataid[g2] : instance; mjtGeom geomtype = mjGEOM_SDF; // copy into data mjSDF sdf; sdf.id = &instance; sdf.type = mjSDFTYPE_SINGLE; sdf.plugin = &sdf_ptr; sdf.geomtype = &geomtype; // compute transformation from g1 to g2 mjtNum sdf_quat[4], quat1[4]; mju_mat2Quat(quat1, mat1); mju_mat2Quat(sdf_quat, mat2); mapPose(pos1, quat1, pos2, sdf_quat, offset, rotation); // binary tree search collideBVH(m, (mjData*)d, g1, offset, rotation, faces, &npoints, &n0, &sdf); // Frank-Wolfe algorithm for (int i=0; i < npoints; i++) { int face = faceadr + faces[i]; for (int v=0; v < 3; v++) { mjtNum vec[3] = { m->mesh_vert[3*(vertadr+m->mesh_face[3*face+v])+0], m->mesh_vert[3*(vertadr+m->mesh_face[3*face+v])+1], m->mesh_vert[3*(vertadr+m->mesh_face[3*face+v])+2], }; // transform local 1 (mesh) to local 2 (sdf) mju_mulMatVec3(corners+3*v, rotation, vec); mju_addTo3(corners+3*v, offset); } // stricter culling if (!triangleIntersect(corners, m, &sdf, (mjData*)d)) { continue; } // starting point x[0] = (corners[0]+corners[3]+corners[6])/3; x[1] = (corners[1]+corners[4]+corners[7])/3; x[2] = (corners[2]+corners[5]+corners[8])/3; // SHOULD NOT OCCUR if (ncandidate == MAXMESHPNT)mjERROR("too many contact points"); // Frank-Wolfe depth = stepFrankWolfe(x, corners, 3, m, &sdf, (mjData*)d); // store candidate if there is penetration if (depth < 0) { mju_copy3(candidate + 3*ncandidate, x); index[ncandidate] = ncandidate; dist[ncandidate++] = depth; } } // sort contacts using depth if (ncandidate > 1) { int buf[MAXMESHPNT]; distSort(index, buf, ncandidate, dist); } // add only the first mjMAXCONPAIR pairs for (int i=0; i < mju_min(ncandidate, mjMAXCONPAIR); i++) { cnt = addContact(points, con, candidate + 3*index[i], pos2, sdf_quat, dist[index[i]], cnt, m, &sdf, (mjData*)d); } return cnt; } // collision between two SDFs int mjc_SDF(const mjModel* m, const mjData* d, mjContact* con, int g1, int g2, mjtNum margin) { mjGETINFO; size1 = m->geom_aabb + 6*g1; size2 = m->geom_aabb + 6*g2; int cnt = 0; mjtNum x[3], y[3], dist, vec1[3], vec2[3]; mjtNum aabb1[6] = {mjMAXVAL, mjMAXVAL, mjMAXVAL, -mjMAXVAL, -mjMAXVAL, -mjMAXVAL}; mjtNum aabb2[6] = {mjMAXVAL, mjMAXVAL, mjMAXVAL, -mjMAXVAL, -mjMAXVAL, -mjMAXVAL}; mjtNum aabb[6] = {mjMAXVAL, mjMAXVAL, mjMAXVAL, -mjMAXVAL, -mjMAXVAL, -mjMAXVAL}; // second geom must be an SDF if (m->geom_type[g2] != mjGEOM_SDF) { mjERROR("geom is not an SDF"); } // compute transformations from/to g1 to/from g2 mjtNum quat1[4], quat2[4]; mjtNum offset21[3], rotation21[9], rotation12[9]; mjtNum offset12[3], offset2[3], rotation2[9]; mju_mat2Quat(quat1, mat1); mju_mat2Quat(quat2, mat2); mapPose(pos1, quat1, pos1, quat1, offset2, rotation2); mapPose(pos2, quat2, pos1, quat1, offset21, rotation21); mapPose(pos1, quat1, pos2, quat2, offset12, rotation12); // axis-aligned bounding boxes in g1 frame for (int i=0; i < 8; i++) { vec1[0] = (i&1 ? size1[0]+size1[3] : size1[0]-size1[3]); vec1[1] = (i&2 ? size1[1]+size1[4] : size1[1]-size1[4]); vec1[2] = (i&4 ? size1[2]+size1[5] : size1[2]-size1[5]); vec2[0] = (i&1 ? size2[0]+size2[3] : size2[0]-size2[3]); vec2[1] = (i&2 ? size2[1]+size2[4] : size2[1]-size2[4]); vec2[2] = (i&4 ? size2[2]+size2[5] : size2[2]-size2[5]); mju_mulMatVec3(vec2, rotation21, vec2); mju_addTo3(vec2, offset21); for (int k=0; k < 3; k++) { aabb1[0+k] = mju_min(aabb1[0+k], vec1[k]); aabb1[3+k] = mju_max(aabb1[3+k], vec1[k]); aabb2[0+k] = mju_min(aabb2[0+k], vec2[k]); aabb2[3+k] = mju_max(aabb2[3+k], vec2[k]); } } // intersection of aabbs for (int k=0; k < 3; k++) { aabb[0+k] = mju_max(aabb1[0+k], aabb2[0+k]); aabb[3+k] = mju_min(aabb1[3+k], aabb2[3+k]); } // no intersection if max < min if (aabb[3] < aabb[0] || aabb[4] < aabb[1] || aabb[5] < aabb[2]) { return cnt; } // create sdf pointers int instance[2]; const mjpPlugin* sdf_ptr[2]; mjtGeom geomtypes[2] = {m->geom_type[g2], m->geom_type[g1]}; instance[0] = m->geom_plugin[g2]; sdf_ptr[0] = instance[0] == -1 ? NULL : mjc_getSDF(m, g2); // get sdf plugins if (m->geom_type[g1] == mjGEOM_SDF) { instance[1] = m->geom_plugin[g1]; sdf_ptr[1] = instance[1] == -1 ? NULL : mjc_getSDF(m, g1); } else { instance[1] = g1; sdf_ptr[1] = NULL; } // reset visualization count if (sdf_ptr[0]) { sdf_ptr[0]->reset(m, NULL, (void*)(d->plugin_data[instance[0]]), instance[0]); } // copy into sdf mjSDF sdf; instance[0] = instance[0] == -1 ? m->geom_dataid[g2] : instance[0]; instance[1] = instance[1] == -1 ? m->geom_dataid[g1] : instance[1]; sdf.id = instance; sdf.relpos = offset21; sdf.relmat = rotation21; sdf.plugin = sdf_ptr; sdf.geomtype = geomtypes; // minimize sdf intersection mjtNum contacts[3*mjMAXCONPAIR]; int i = 0, j = 0; while (i < m->opt.sdf_initpoints) { x[0] = aabb[0] + (aabb[3]-aabb[0]) * mju_Halton(j, 2); x[1] = aabb[1] + (aabb[4]-aabb[1]) * mju_Halton(j, 3); x[2] = aabb[2] + (aabb[5]-aabb[2]) * mju_Halton(j, 5); mju_mulMatVec3(y, rotation2, x); mju_addTo3(y, offset2); mju_mulMatVec3(x, rotation12, y); mju_addTo3(x, offset12); j++; // here a criterion for rejecting points could be inserted i++; // start counters if (sdf_ptr[0]) { sdf_ptr[0]->compute(m, (mjData*)d, instance[0], mjPLUGIN_SDF); } // gradient descent - we use a special function of the two SDF as objective sdf.type = mjSDFTYPE_COLLISION; dist = stepGradient(x, m, &sdf, (mjData*)d, m->opt.sdf_iterations); // inexact SDFs can yield spurious collisions, filter them by projecting on the midsurface sdf.type = mjSDFTYPE_INTERSECTION; dist = stepGradient(x, m, &sdf, (mjData*)d, 1); // contact point and normal - we use the midsurface where SDF1=SDF2 as zero level set sdf.type = mjSDFTYPE_MIDSURFACE; cnt = addContact(contacts, con, x, pos2, quat2, dist, cnt, m, &sdf, (mjData*)d); // SHOULD NOT OCCUR if (cnt > mjMAXCONPAIR) { mjERROR("too many contact points"); } } return cnt; }