// 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_ray.h" #include #include #include #include #include // IWYU pragma: keep #include #include "engine/engine_collision_sdf.h" #include "engine/engine_io.h" #include "engine/engine_plugin.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" //---------------------------- utility functions --------------------------------------------------- // map ray to local geom frame static void ray_map(const mjtNum* pos, const mjtNum* mat, const mjtNum* pnt, const mjtNum* vec, mjtNum* lpnt, mjtNum* lvec) { const mjtNum dif[3] = {pnt[0]-pos[0], pnt[1]-pos[1], pnt[2]-pos[2]}; // lpnt = mat' * dif lpnt[0] = mat[0]*dif[0] + mat[3]*dif[1] + mat[6]*dif[2]; lpnt[1] = mat[1]*dif[0] + mat[4]*dif[1] + mat[7]*dif[2]; lpnt[2] = mat[2]*dif[0] + mat[5]*dif[1] + mat[8]*dif[2]; // lvec = mat' * vec lvec[0] = mat[0]*vec[0] + mat[3]*vec[1] + mat[6]*vec[2]; lvec[1] = mat[1]*vec[0] + mat[4]*vec[1] + mat[7]*vec[2]; lvec[2] = mat[2]*vec[0] + mat[5]*vec[1] + mat[8]*vec[2]; } // map to azimuth angle in spherical coordinates static mjtNum longitude(const mjtNum vec[3]) { return mju_atan2(vec[1], vec[0]); } // map to elevation angle in spherical coordinates static mjtNum latitude(const mjtNum vec[3]) { return mju_atan2(mju_sqrt(vec[0]*vec[0] + vec[1]*vec[1]), vec[2]); } // eliminate geom static int ray_eliminate(const mjModel* m, const mjData* d, int geomid, const mjtByte* geomgroup, mjtByte flg_static, int bodyexclude) { // body exclusion if (m->geom_bodyid[geomid] == bodyexclude) { return 1; } // invisible geom exclusion if (m->geom_matid[geomid] < 0 && m->geom_rgba[4*geomid+3] == 0) { return 1; } // invisible material exclusion if (m->geom_matid[geomid] >= 0 && m->mat_rgba[4*m->geom_matid[geomid]+3] == 0) { return 1; } // static exclusion if (!flg_static && m->body_weldid[m->geom_bodyid[geomid]] == 0) { return 1; } // no geomgroup inclusion if (!geomgroup) { return 0; } // group inclusion/exclusion int groupid = mjMIN(mjNGROUP-1, mjMAX(0, m->geom_group[geomid])); return (geomgroup[groupid] == 0); } // compute solution from quadratic: a*x^2 + 2*b*x + c = 0 static mjtNum ray_quad(mjtNum a, mjtNum b, mjtNum c, mjtNum* x) { // compute determinant and check mjtNum det = b*b - a*c; if (det < mjMINVAL) { x[0] = -1; x[1] = -1; return -1; } det = mju_sqrt(det); // compute the two solutions x[0] = (-b-det)/a; x[1] = (-b+det)/a; // finalize result if (x[0] >= 0) { return x[0]; } else if (x[1] >= 0) { return x[1]; } else { return -1; } } // intersect ray with triangle mjtNum ray_triangle(mjtNum v[][3], const mjtNum* lpnt, const mjtNum* lvec, const mjtNum* b0, const mjtNum* b1) { // dif = v[i] - lpnt mjtNum dif[3][3]; for (int i=0; i < 3; i++) { for (int j=0; j < 3; j++) { dif[i][j] = v[i][j] - lpnt[j]; } } // project difference vectors in normal plane mjtNum planar[3][2]; for (int i=0; i < 3; i++) { planar[i][0] = mju_dot3(b0, dif[i]); planar[i][1] = mju_dot3(b1, dif[i]); } // reject if on the same side of any coordinate axis if ((planar[0][0] > 0 && planar[1][0] > 0 && planar[2][0] > 0) || (planar[0][0] < 0 && planar[1][0] < 0 && planar[2][0] < 0) || (planar[0][1] > 0 && planar[1][1] > 0 && planar[2][1] > 0) || (planar[0][1] < 0 && planar[1][1] < 0 && planar[2][1] < 0)) { return -1; } // determine if origin is inside planar projection of triangle // A = (p0-p2, p1-p2), b = -p2, solve A*t = b mjtNum A[4] = {planar[0][0]-planar[2][0], planar[1][0]-planar[2][0], planar[0][1]-planar[2][1], planar[1][1]-planar[2][1]}; mjtNum b[2] = {-planar[2][0], -planar[2][1]}; mjtNum det = A[0]*A[3] - A[1]*A[2]; if (mju_abs(det) < mjMINVAL) { return -1; } mjtNum t0 = (A[3]*b[0] - A[1]*b[1]) / det; mjtNum t1 = (-A[2]*b[0] + A[0]*b[1]) / det; // check if outside if (t0 < 0 || t1 < 0|| t0+t1 > 1) { return -1; } // intersect ray with plane of triangle mju_sub3(dif[0], v[0], v[2]); // v0-v2 mju_sub3(dif[1], v[1], v[2]); // v1-v2 mju_sub3(dif[2], lpnt, v[2]); // lp-v2 mjtNum nrm[3]; mju_cross(nrm, dif[0], dif[1]); // normal to triangle plane mjtNum denom = mju_dot3(lvec, nrm); if (mju_abs(denom) < mjMINVAL) { return -1; } return (-mju_dot3(dif[2], nrm) / denom); } //---------------------------- geom-specific intersection functions -------------------------------- // plane static mjtNum ray_plane(const mjtNum* pos, const mjtNum* mat, const mjtNum* size, const mjtNum* pnt, const mjtNum* vec) { // map to local frame mjtNum lpnt[3], lvec[3]; ray_map(pos, mat, pnt, vec, lpnt, lvec); // z-vec not pointing towards front face: reject if (lvec[2] > -mjMINVAL) { return -1; } // intersection with plane const mjtNum x = -lpnt[2]/lvec[2]; if (x < 0) { return -1; } mjtNum p0 = lpnt[0] + x*lvec[0]; mjtNum p1 = lpnt[1] + x*lvec[1]; // accept only within rendered rectangle if ((size[0] <= 0 || mju_abs(p0) <= size[0]) && (size[1] <= 0 || mju_abs(p1) <= size[1])) { return x; } else { return -1; } } // sphere static mjtNum ray_sphere(const mjtNum* pos, const mjtNum* mat, mjtNum dist_sqr, const mjtNum* pnt, const mjtNum* vec) { // (x*vec+pnt-pos)'*(x*vec+pnt-pos) = size[0]*size[0] mjtNum dif[3] = {pnt[0]-pos[0], pnt[1]-pos[1], pnt[2]-pos[2]}; mjtNum a = vec[0]*vec[0] + vec[1]*vec[1] + vec[2]*vec[2]; mjtNum b = vec[0]*dif[0] + vec[1]*dif[1] + vec[2]*dif[2]; mjtNum c = dif[0]*dif[0] + dif[1]*dif[1] + dif[2]*dif[2] - dist_sqr; // solve a*x^2 + 2*b*x + c = 0 mjtNum xx[2]; return ray_quad(a, b, c, xx); } // capsule static mjtNum ray_capsule(const mjtNum* pos, const mjtNum* mat, const mjtNum* size, const mjtNum* pnt, const mjtNum* vec) { // bounding sphere test mjtNum ssz = size[0] + size[1]; if (ray_sphere(pos, NULL, ssz*ssz, pnt, vec) < 0) { return -1; } // map to local frame mjtNum lpnt[3], lvec[3]; ray_map(pos, mat, pnt, vec, lpnt, lvec); // init solution mjtNum x = -1, sol, xx[2]; // cylinder round side: (x*lvec+lpnt)'*(x*lvec+lpnt) = size[0]*size[0] mjtNum a = lvec[0]*lvec[0] + lvec[1]*lvec[1]; mjtNum b = lvec[0]*lpnt[0] + lvec[1]*lpnt[1]; mjtNum c = lpnt[0]*lpnt[0] + lpnt[1]*lpnt[1] - size[0]*size[0]; // solve a*x^2 + 2*b*x + c = 0 sol = ray_quad(a, b, c, xx); // make sure round solution is between flat sides if (sol >= 0 && mju_abs(lpnt[2]+sol*lvec[2]) <= size[1]) { if (x < 0 || sol < x) { x = sol; } } // top cap mjtNum ldif[3] = {lpnt[0], lpnt[1], lpnt[2]-size[1]}; a = lvec[0]*lvec[0] + lvec[1]*lvec[1] + lvec[2]*lvec[2]; b = lvec[0]*ldif[0] + lvec[1]*ldif[1] + lvec[2]*ldif[2]; c = ldif[0]*ldif[0] + ldif[1]*ldif[1] + ldif[2]*ldif[2] - size[0]*size[0]; ray_quad(a, b, c, xx); // accept only top half of sphere for (int i=0; i < 2; i++) { if (xx[i] >= 0 && lpnt[2]+xx[i]*lvec[2] >= size[1]) { if (x < 0 || xx[i] < x) { x = xx[i]; } } } // bottom cap ldif[2] = lpnt[2]+size[1]; b = lvec[0]*ldif[0] + lvec[1]*ldif[1] + lvec[2]*ldif[2]; c = ldif[0]*ldif[0] + ldif[1]*ldif[1] + ldif[2]*ldif[2] - size[0]*size[0]; ray_quad(a, b, c, xx); // accept only bottom half of sphere for (int i=0; i < 2; i++) { if (xx[i] >= 0 && lpnt[2]+xx[i]*lvec[2] <= -size[1]) { if (x < 0 || xx[i] < x) { x = xx[i]; } } } return x; } // ellipsoid static mjtNum ray_ellipsoid(const mjtNum* pos, const mjtNum* mat, const mjtNum* size, const mjtNum* pnt, const mjtNum* vec) { // map to local frame mjtNum lpnt[3], lvec[3]; ray_map(pos, mat, pnt, vec, lpnt, lvec); // invert size^2 mjtNum s[3] = {1/(size[0]*size[0]), 1/(size[1]*size[1]), 1/(size[2]*size[2])}; // (x*lvec+lpnt)' * diag(1./size^2) * (x*lvec+lpnt) = 1 mjtNum a = s[0]*lvec[0]*lvec[0] + s[1]*lvec[1]*lvec[1] + s[2]*lvec[2]*lvec[2]; mjtNum b = s[0]*lvec[0]*lpnt[0] + s[1]*lvec[1]*lpnt[1] + s[2]*lvec[2]*lpnt[2]; mjtNum c = s[0]*lpnt[0]*lpnt[0] + s[1]*lpnt[1]*lpnt[1] + s[2]*lpnt[2]*lpnt[2] - 1; // solve a*x^2 + 2*b*x + c = 0 mjtNum xx[2]; return ray_quad(a, b, c, xx); } // cylinder static mjtNum ray_cylinder(const mjtNum* pos, const mjtNum* mat, const mjtNum* size, const mjtNum* pnt, const mjtNum* vec) { // bounding sphere test mjtNum ssz = size[0]*size[0] + size[1]*size[1]; if (ray_sphere(pos, NULL, ssz, pnt, vec) < 0) { return -1; } // map to local frame mjtNum lpnt[3], lvec[3]; ray_map(pos, mat, pnt, vec, lpnt, lvec); // init solution mjtNum x = -1, sol; // flat sides int side; if (mju_abs(lvec[2]) > mjMINVAL) { for (side=-1; side <= 1; side+=2) { // solution of: lpnt[2] + x*lvec[2] = side*height_size sol = (side*size[1]-lpnt[2])/lvec[2]; // process if non-negative if (sol >= 0) { // intersection with horizontal face mjtNum p0 = lpnt[0] + sol*lvec[0]; mjtNum p1 = lpnt[1] + sol*lvec[1]; // accept within radius if (p0*p0 + p1*p1 <= size[0]*size[0]) { if (x < 0 || sol < x) { x = sol; } } } } } // (x*lvec+lpnt)'*(x*lvec+lpnt) = size[0]*size[0] mjtNum a = lvec[0]*lvec[0] + lvec[1]*lvec[1]; mjtNum b = lvec[0]*lpnt[0] + lvec[1]*lpnt[1]; mjtNum c = lpnt[0]*lpnt[0] + lpnt[1]*lpnt[1] - size[0]*size[0]; // solve a*x^2 + 2*b*x + c = 0 mjtNum xx[2]; sol = ray_quad(a, b, c, xx); // make sure round solution is between flat sides if (sol >= 0 && mju_abs(lpnt[2]+sol*lvec[2]) <= size[1]) { if (x < 0 || sol < x) { x = sol; } } return x; } // box static mjtNum ray_box(const mjtNum* pos, const mjtNum* mat, const mjtNum* size, const mjtNum* pnt, const mjtNum* vec, mjtNum* all) { // clear all if (all) { for (int i=0; i < 6; i++) { all[i] = -1; } } // bounding sphere test mjtNum ssz = size[0]*size[0] + size[1]*size[1] + size[2]*size[2]; if (ray_sphere(pos, NULL, ssz, pnt, vec) < 0) { return -1; } // faces const int iface[3][2] = { {1, 2}, {0, 2}, {0, 1} }; // map to local frame mjtNum lpnt[3], lvec[3]; ray_map(pos, mat, pnt, vec, lpnt, lvec); // init solution mjtNum x = -1, sol; // loop over axes with non-zero vec for (int i=0; i < 3; i++) { if (mju_abs(lvec[i]) > mjMINVAL) { for (int side=-1; side <= 1; side+=2) { // solution of: lpnt[i] + x*lvec[i] = side*size[i] sol = (side*size[i]-lpnt[i])/lvec[i]; // process if non-negative if (sol >= 0) { // intersection with face mjtNum p0 = lpnt[iface[i][0]] + sol*lvec[iface[i][0]]; mjtNum p1 = lpnt[iface[i][1]] + sol*lvec[iface[i][1]]; // accept within rectangle if (mju_abs(p0) <= size[iface[i][0]] && mju_abs(p1) <= size[iface[i][1]]) { // update if (x < 0 || sol < x) { x = sol; } // save in all if (all) { all[2*i+(side+1)/2] = sol; } } } } } } return x; } // intersect ray with hfield mjtNum mj_rayHfield(const mjModel* m, const mjData* d, int id, const mjtNum* pnt, const mjtNum* vec) { // check geom type if (m->geom_type[id] != mjGEOM_HFIELD) { mjERROR("geom with hfield type expected"); } // hfield id and dimensions int hid = m->geom_dataid[id]; int nrow = m->hfield_nrow[hid]; int ncol = m->hfield_ncol[hid]; const mjtNum* size = m->hfield_size + 4*hid; const float* data = m->hfield_data + m->hfield_adr[hid]; // compute size and pos of base box mjtNum base_size[3] = {size[0], size[1], size[3]*0.5}; mjtNum base_pos[3] = { d->geom_xpos[3*id] - d->geom_xmat[9*id+2]*size[3]*0.5, d->geom_xpos[3*id+1] - d->geom_xmat[9*id+5]*size[3]*0.5, d->geom_xpos[3*id+2] - d->geom_xmat[9*id+8]*size[3]*0.5 }; // compute size and pos of top box mjtNum top_size[3] = {size[0], size[1], size[2]*0.5}; mjtNum top_pos[3] = { d->geom_xpos[3*id] + d->geom_xmat[9*id+2]*size[2]*0.5, d->geom_xpos[3*id+1] + d->geom_xmat[9*id+5]*size[2]*0.5, d->geom_xpos[3*id+2] + d->geom_xmat[9*id+8]*size[2]*0.5 }; // init: intersection with base box mjtNum x = ray_box(base_pos, d->geom_xmat+9*id, base_size, pnt, vec, NULL); // check top box: done if no intersection mjtNum all[6]; mjtNum top_intersect = ray_box(top_pos, d->geom_xmat+9*id, top_size, pnt, vec, all); if (top_intersect < 0) { return x; } // map to local frame mjtNum lpnt[3], lvec[3]; ray_map(d->geom_xpos+3*id, d->geom_xmat+9*id, pnt, vec, lpnt, lvec); // construct basis vectors of normal plane mjtNum b0[3] = {1, 1, 1}, b1[3]; if (mju_abs(lvec[0]) >= mju_abs(lvec[1]) && mju_abs(lvec[0]) >= mju_abs(lvec[2])) { b0[0] = 0; } else if (mju_abs(lvec[1]) >= mju_abs(lvec[2])) { b0[1] = 0; } else { b0[2] = 0; } mju_addScl3(b1, b0, lvec, -mju_dot3(lvec, b0)/mju_dot3(lvec, lvec)); mju_normalize3(b1); mju_cross(b0, b1, lvec); mju_normalize3(b0); // find ray segment intersecting top box mjtNum seg[2] = {0, top_intersect}; for (int i=0; i < 6; i++) { if (all[i] > seg[1]) { seg[0] = top_intersect; seg[1] = all[i]; } } // project segment endpoints in horizontal plane, discretize mjtNum dx = (2.0*size[0]) / (ncol-1); mjtNum dy = (2.0*size[1]) / (nrow-1); mjtNum SX[2], SY[2]; for (int i=0; i < 2; i++) { SX[i] = (lpnt[0] + seg[i]*lvec[0] + size[0]) / dx; SY[i] = (lpnt[1] + seg[i]*lvec[1] + size[1]) / dy; } // compute ranges, with +1 padding int cmin = mjMAX(0, (int)mju_floor(mjMIN(SX[0], SX[1]))-1); int cmax = mjMIN(ncol-1, (int)mju_ceil(mjMAX(SX[0], SX[1]))+1); int rmin = mjMAX(0, (int)mju_floor(mjMIN(SY[0], SY[1]))-1); int rmax = mjMIN(nrow-1, (int)mju_ceil(mjMAX(SY[0], SY[1]))+1); // check triangles within bounds for (int r=rmin; r < rmax; r++) { for (int c=cmin; c < cmax; c++) { // first triangle mjtNum va[3][3] = { {dx*c-size[0], dy*r-size[1], data[r*ncol+c]*size[2]}, {dx*(c+1)-size[0], dy*(r+1)-size[1], data[(r+1)*ncol+(c+1)]*size[2]}, {dx*(c+1)-size[0], dy*r-size[1], data[r*ncol+(c+1)]*size[2]} }; mjtNum sol = ray_triangle(va, lpnt, lvec, b0, b1); if (sol >= 0 && (x < 0 || sol < x)) { x = sol; } // second triangle mjtNum vb[3][3] = { {dx*c-size[0], dy*r-size[1], data[r*ncol+c]*size[2]}, {dx*(c+1)-size[0], dy*(r+1)-size[1], data[(r+1)*ncol+(c+1)]*size[2]}, {dx*c-size[0], dy*(r+1)-size[1], data[(r+1)*ncol+c]*size[2]} }; sol = ray_triangle(vb, lpnt, lvec, b0, b1); if (sol >= 0 && (x < 0 || sol < x)) { x = sol; } } } // check viable sides of top box for (int i=0; i < 4; i++) { if (all[i] >= 0 && (all[i] < x || x < 0)) { // normalized height of intersection point mjtNum z = (lpnt[2] + all[i]*lvec[2]) / size[2]; // rectangle points mjtNum y, y0, z0, z1; // side normal to x-axis if (i < 2) { y = (lpnt[1] + all[i]*lvec[1] + size[1]) / dy; y0 = mjMAX(0, mjMIN(nrow-2, mju_floor(y))); z0 = (mjtNum)data[mju_round(y0)*nrow + (i == 1 ? ncol-1 : 0)]; z1 = (mjtNum)data[mju_round(y0+1)*nrow + (i == 1 ? ncol-1 : 0)]; } // side normal to y-axis else { y = (lpnt[0] + all[i]*lvec[0] + size[0]) / dx; y0 = mjMAX(0, mjMIN(ncol-2, mju_floor(y))); z0 = (mjtNum)data[mju_round(y0) + (i == 3 ? (nrow-1)*ncol : 0)]; z1 = (mjtNum)data[mju_round(y0+1) + (i == 3 ? (nrow-1)*ncol : 0)]; } // check if point is below line segment if (z < z0*(y0+1-y) + z1*(y-y0)) { x = all[i]; } } } return x; } // ray vs axis-aligned bounding box using slab method // see Ericson, Real-time Collision Detection section 5.3.3. int mju_raySlab(const mjtNum aabb[6], const mjtNum xpos[3], const mjtNum xmat[9], const mjtNum* pnt, const mjtNum* vec) { mjtNum tmin = 0.0, tmax = INFINITY; // compute min and max mjtNum min[3] = {aabb[0]-aabb[3], aabb[1]-aabb[4], aabb[2]-aabb[5]}; mjtNum max[3] = {aabb[0]+aabb[3], aabb[1]+aabb[4], aabb[2]+aabb[5]}; // compute ray in local coordinates mjtNum src[3], dir[3]; ray_map(xpos, xmat, pnt, vec, src, dir); // check intersections mjtNum invdir[3] = { 1.0 / dir[0], 1.0 / dir[1], 1.0 / dir[2] }; for (int d = 0; d < 3; ++d) { mjtNum t1 = (min[d] - src[d]) * invdir[d]; mjtNum t2 = (max[d] - src[d]) * invdir[d]; mjtNum minval = t1 < t2 ? t1 : t2; mjtNum maxval = t1 < t2 ? t2 : t1; tmin = tmin > minval ? tmin : minval; tmax = tmax < maxval ? tmax : maxval; } return tmin < tmax; } // ray vs tree intersection mjtNum mju_rayTree(const mjModel* m, const mjData* d, int id, const mjtNum* pnt, const mjtNum* vec) { int mark_active = m->vis.global.bvactive; const int meshid = m->geom_dataid[id]; const int bvhadr = m->mesh_bvhadr[meshid]; const int* faceid = m->bvh_nodeid + bvhadr; const mjtNum* bvh = m->bvh_aabb + 6*bvhadr; const int* child = m->bvh_child + 2*bvhadr; if (meshid == -1) { mjERROR("mesh id of geom %d is -1", meshid); // SHOULD NOT OCCUR } // initialize stack int stack[mjMAXTREEDEPTH]; int nstack = 0; stack[nstack] = 0; nstack++; // map to local frame mjtNum lpnt[3], lvec[3]; ray_map(d->geom_xpos+3*id, d->geom_xmat+9*id, pnt, vec, lpnt, lvec); // construct basis vectors of normal plane mjtNum b0[3] = {1, 1, 1}, b1[3]; if (mju_abs(lvec[0]) >= mju_abs(lvec[1]) && mju_abs(lvec[0]) >= mju_abs(lvec[2])) { b0[0] = 0; } else if (mju_abs(lvec[1]) >= mju_abs(lvec[2])) { b0[1] = 0; } else { b0[2] = 0; } mju_addScl3(b1, b0, lvec, -mju_dot3(lvec, b0)/mju_dot3(lvec, lvec)); mju_normalize3(b1); mju_cross(b0, b1, lvec); mju_normalize3(b0); // init solution mjtNum x = -1, sol; while (nstack) { // pop from stack nstack--; int node = stack[nstack]; // intersection test int intersect = mju_raySlab(bvh+6*node, d->geom_xpos+3*id, d->geom_xmat+9*id, pnt, vec); // if no intersection, skip if (!intersect) { continue; } // node1 is a leaf if (faceid[node] != -1) { int face = faceid[node] + m->mesh_faceadr[meshid]; // get float vertices float* vf[3]; vf[0] = m->mesh_vert + 3*(m->mesh_face[3*face+0] + m->mesh_vertadr[meshid]); vf[1] = m->mesh_vert + 3*(m->mesh_face[3*face+1] + m->mesh_vertadr[meshid]); vf[2] = m->mesh_vert + 3*(m->mesh_face[3*face+2] + m->mesh_vertadr[meshid]); // convert to mjtNum mjtNum v[3][3]; for (int i=0; i < 3; i++) { for (int j=0; j < 3; j++) { v[i][j] = (mjtNum)vf[i][j]; } } // solve sol = ray_triangle(v, lpnt, lvec, b0, b1); // update if (sol >= 0 && (x < 0 || sol < x)) { x = sol; if (mark_active) { d->bvh_active[node + bvhadr] = 1; } } continue; } // used for rendering if (mark_active) { d->bvh_active[node + bvhadr] = 1; } // add children to the stack for (int i=0; i < 2; i++) { if (child[2*node+i] != -1) { if (nstack >= mjMAXTREEDEPTH) { mjERROR("BVH stack depth exceeded in geom %d.", id); } stack[nstack] = child[2*node+i]; nstack++; } } } return x; } // intersect ray with signed distance field mjtNum ray_sdf(const mjModel* m, const mjData* d, int g, const mjtNum* pnt, const mjtNum* vec) { mjtNum distance_total = 0; mjtNum p[3]; mjtNum kMinDist = 1e-7; // exclude using bounding box if (ray_box(d->geom_xpos+3*g, d->geom_xmat+9*g, m->geom_size+3*g, pnt, vec, NULL) < 0) { return -1; } // get sdf plugin int instance = m->geom_plugin[g]; const mjpPlugin* sdf_ptr = instance == -1 ? NULL : mjc_getSDF(m, g); instance = instance == -1 ? m->geom_dataid[g] : instance; mjtGeom geomtype = mjGEOM_SDF; // construct sdf struct mjSDF sdf; sdf.id = &instance; sdf.type = mjSDFTYPE_SINGLE; sdf.plugin = &sdf_ptr; sdf.geomtype = &geomtype; // reset counter if (sdf_ptr) { sdf_ptr->reset(m, NULL, (void*)(d->plugin_data[instance]), instance); } // map to local frame mjtNum lpnt[3], lvec[3]; ray_map(d->geom_xpos + 3*g, d->geom_xmat + 9*g, pnt, vec, lpnt, lvec); // unit direction mju_normalize3(lvec); // ray marching, see e.g. https://en.wikipedia.org/wiki/Ray_marching for (int i=0; i < 40; i++) { mju_addScl3(p, lpnt, lvec, distance_total); mjtNum distance = mjc_distance(m, d, &sdf, p); distance_total += distance; if (mju_abs(distance) < kMinDist) { return distance_total; } if (distance > 1e6) { // no intersection break; } } // reset counter if (sdf_ptr) { sdf_ptr->reset(m, NULL, (void*)(d->plugin_data[instance]), instance); } return -1; } // intersect ray with mesh mjtNum mj_rayMesh(const mjModel* m, const mjData* d, int id, const mjtNum* pnt, const mjtNum* vec) { // check geom type if (m->geom_type[id] != mjGEOM_MESH) { mjERROR("geom with mesh type expected"); } // bounding box test if (ray_box(d->geom_xpos+3*id, d->geom_xmat+9*id, m->geom_size+3*id, pnt, vec, NULL) < 0) { return -1; } return mju_rayTree(m, d, id, pnt, vec); } // intersect ray with pure geom, no meshes or hfields mjtNum mju_rayGeom(const mjtNum* pos, const mjtNum* mat, const mjtNum* size, const mjtNum* pnt, const mjtNum* vec, int geomtype) { switch ((mjtGeom) geomtype) { case mjGEOM_PLANE: return ray_plane(pos, mat, size, pnt, vec); case mjGEOM_SPHERE: return ray_sphere(pos, mat, size[0]*size[0], pnt, vec); case mjGEOM_CAPSULE: return ray_capsule(pos, mat, size, pnt, vec); case mjGEOM_ELLIPSOID: return ray_ellipsoid(pos, mat, size, pnt, vec); case mjGEOM_CYLINDER: return ray_cylinder(pos, mat, size, pnt, vec); case mjGEOM_BOX: return ray_box(pos, mat, size, pnt, vec, NULL); default: mjERROR("unexpected geom type %d", geomtype); return -1; } } // intersect ray with flex, return nearest vertex id mjtNum mju_rayFlex(const mjModel* m, const mjData* d, int flex_layer, mjtByte flg_vert, mjtByte flg_edge, mjtByte flg_face, mjtByte flg_skin, int flexid, const mjtNum* pnt, const mjtNum* vec, int vertid[1]) { int dim = m->flex_dim[flexid]; // compute bounding box mjtNum box[3][2] = {{0, 0}, {0, 0}, {0, 0}}; mjtNum* vert = d->flexvert_xpos + 3*m->flex_vertadr[flexid]; for (int i=0; i < m->flex_vertnum[flexid]; i++) { for (int j=0; j < 3; j++) { // update minimum along side j if (box[j][0] > vert[3*i+j] || i == 0) { box[j][0] = vert[3*i+j]; } // update maximum along side j if (box[j][1] < vert[3*i+j] || i == 0) { box[j][1] = vert[3*i+j]; } } } // adjust box for radius mjtNum radius = m->flex_radius[flexid]; for (int j=0; j < 3; j++) { box[j][0] -= radius; box[j][1] += radius; } // construct box geom mjtNum pos[3], size[3], mat[9] = {1, 0, 0, 0, 1, 0, 0, 0, 1}; for (int j=0; j < 3; j++) { pos[j] = 0.5*(box[j][0]+box[j][1]); size[j] = 0.5*(box[j][1]-box[j][0]); } // apply bounding-box filter if (ray_box(pos, mat, size, pnt, vec, NULL) < 0) { return -1; } // construct basis vectors of normal plane mjtNum b0[3] = {1, 1, 1}, b1[3]; if (mju_abs(vec[0]) >= mju_abs(vec[1]) && mju_abs(vec[0]) >= mju_abs(vec[2])) { b0[0] = 0; } else if (mju_abs(vec[1]) >= mju_abs(vec[2])) { b0[1] = 0; } else { b0[2] = 0; } mju_addScl3(b1, b0, vec, -mju_dot3(vec, b0)/mju_dot3(vec, vec)); mju_normalize3(b1); mju_cross(b0, b1, vec); mju_normalize3(b0); // init solution mjtNum x = -1; // check edges if rendered, or if skin if (flg_edge || (dim > 1 && flg_skin)) { int edge_end = m->flex_edgeadr[flexid]+m->flex_edgenum[flexid]; for (int e=m->flex_edgeadr[flexid]; e < edge_end; e++) { // get vertices for this edge mjtNum* v1 = d->flexvert_xpos + 3*(m->flex_vertadr[flexid]+m->flex_edge[2*e]); mjtNum* v2 = d->flexvert_xpos + 3*(m->flex_vertadr[flexid]+m->flex_edge[2*e+1]); // construct capsule geom mju_add3(pos, v1, v2); mju_scl3(pos, pos, 0.5); mjtNum dif[3] = {v2[0]-v1[0], v2[1]-v1[1], v2[2]-v1[2]}; size[0] = radius; size[1] = 0.5*mju_normalize3(dif); mjtNum quat[4]; mju_quatZ2Vec(quat, dif); mju_quat2Mat(mat, quat); // intersect ray with capsule mjtNum sol = mju_rayGeom(pos, mat, size, pnt, vec, mjGEOM_CAPSULE); // update if (sol >= 0 && (x < 0 || sol < x)) { x = sol; // construct intersection point mjtNum intersect[3]; mju_addScl3(intersect, pnt, vec, sol); // find nearest vertex if (mju_dist3(v1, intersect) < mju_dist3(v2, intersect)) { *vertid = m->flex_edge[2*e]; } else { *vertid = m->flex_edge[2*e+1]; } } } } // check vertices if rendered (and edges not checked) else if (flg_vert && !(dim > 1 && flg_skin)) { for (int v=0; v < m->flex_vertnum[flexid]; v++) { // get vertex mjtNum* vpos = d->flexvert_xpos + 3*(m->flex_vertadr[flexid] + v); // construct sphere geom size[0] = radius; // intersect ray with sphere mjtNum sol = mju_rayGeom(vpos, NULL, size, pnt, vec, mjGEOM_SPHERE); // update if (sol >= 0 && (x < 0 || sol < x)) { x = sol; *vertid = v; } } } // check faces if rendered if (dim > 1 && (flg_face || flg_skin)) { for (int e=0; e < m->flex_elemnum[flexid]; e++) { // skip if 3D element is not visible int elayer = m->flex_elemlayer[m->flex_elemadr[flexid]+e]; if (dim == 3 && ((flg_skin && elayer > 0) || (!flg_skin && elayer != flex_layer))) { continue; } // get element data const int* edata = m->flex_elem + m->flex_elemdataadr[flexid] + e*(dim+1); mjtNum* v1 = d->flexvert_xpos + 3*(m->flex_vertadr[flexid] + edata[0]); mjtNum* v2 = d->flexvert_xpos + 3*(m->flex_vertadr[flexid] + edata[1]); mjtNum* v3 = d->flexvert_xpos + 3*(m->flex_vertadr[flexid] + edata[2]); mjtNum* v4 = dim == 2 ? NULL : d->flexvert_xpos + 3*(m->flex_vertadr[flexid] + edata[3]); mjtNum* vptr[4][3] = {{v1, v2, v3}, {v1, v2, v4}, {v1, v3, v4}, {v2, v3, v4}}; int vid[4][3] = {{0, 1, 2}, {0, 1, 3}, {0, 2, 3}, {1, 2, 3}}; // process triangles of this element for (int i=0; i < (dim == 2?1:4); i++) { // copy vertices into triangle representation mjtNum v[3][3]; for (int j=0; j < 3; j++) mju_copy3(v[j], vptr[i][j]); // intersect ray with triangle mjtNum sol = ray_triangle(v, pnt, vec, b0, b1); // update if (sol >= 0 && (x < 0 || sol < x)) { x = sol; // construct intersection point mjtNum intersect[3]; mju_addScl3(intersect, pnt, vec, sol); // find nearest vertex mjtNum dist[3] = { mju_dist3(v[0], intersect), mju_dist3(v[1], intersect), mju_dist3(v[2], intersect) }; if (dist[0] <= dist[1] && dist[0] <= dist[2]) { *vertid = edata[vid[i][0]]; } else if (dist[1] <= dist[2]){ *vertid = edata[vid[i][1]]; } else { *vertid = edata[vid[i][2]]; } } } } } return x; } // intersect ray with skin, return nearest vertex id mjtNum mju_raySkin(int nface, int nvert, const int* face, const float* vert, const mjtNum* pnt, const mjtNum* vec, int vertid[1]) { // compute bounding box mjtNum box[3][2] = {{0, 0}, {0, 0}, {0, 0}}; for (int i=0; i < nvert; i++) { for (int j=0; j < 3; j++) { // update minimum along side j if (box[j][0] > vert[3*i+j] || i == 0) { box[j][0] = vert[3*i+j]; } // update maximum along side j if (box[j][1] < vert[3*i+j] || i == 0) { box[j][1] = vert[3*i+j]; } } } // construct box geom mjtNum pos[3], size[3], mat[9] = {1, 0, 0, 0, 1, 0, 0, 0, 1}; for (int j=0; j < 3; j++) { pos[j] = 0.5*(box[j][0]+box[j][1]); size[j] = 0.5*(box[j][1]-box[j][0]); } // apply bounding-box filter if (ray_box(pos, mat, size, pnt, vec, NULL) < 0) { return -1; } // construct basis vectors of normal plane mjtNum b0[3] = {1, 1, 1}, b1[3]; if (mju_abs(vec[0]) >= mju_abs(vec[1]) && mju_abs(vec[0]) >= mju_abs(vec[2])) { b0[0] = 0; } else if (mju_abs(vec[1]) >= mju_abs(vec[2])) { b0[1] = 0; } else { b0[2] = 0; } mju_addScl3(b1, b0, vec, -mju_dot3(vec, b0)/mju_dot3(vec, vec)); mju_normalize3(b1); mju_cross(b0, b1, vec); mju_normalize3(b0); // init solution mjtNum x = -1; // process all faces for (int i=0; i < nface; i++) { // get float vertices const float* vf[3]; vf[0] = vert + 3*(face[3*i]); vf[1] = vert + 3*(face[3*i+1]); vf[2] = vert + 3*(face[3*i+2]); // convert to mjtNum mjtNum v[3][3]; for (int j=0; j < 3; j++) { for (int k=0; k < 3; k++) { v[j][k] = (mjtNum)vf[j][k]; } } // solve mjtNum sol = ray_triangle(v, pnt, vec, b0, b1); // update if (sol >= 0 && (x < 0 || sol < x)) { x = sol; // construct intersection point mjtNum intersect[3]; mju_addScl3(intersect, pnt, vec, sol); // find nearest vertex mjtNum dist = mju_dist3(intersect, v[0]); *vertid = face[3*i]; for (int j=1; j < 3; j++) { mjtNum newdist = mju_dist3(intersect, v[j]); if (newdist < dist) { dist = newdist; *vertid = face[3*i+j]; } } } } return x; } // return 1 if point is inside object-aligned bounding box, 0 otherwise static int point_in_box(const mjtNum aabb[6], const mjtNum xpos[3], const mjtNum xmat[9], const mjtNum pnt[3]) { mjtNum point[3]; // compute point in local coordinates of the box mju_sub3(point, pnt, xpos); mju_mulMatTVec3(point, xmat, point); mju_subFrom3(point, aabb); // check intersections for (int j=0; j < 3; j++) { // directions if (mju_abs(point[j]) > aabb[3+j]) { return 0; } } return 1; } //---------------------------- main entry point ---------------------------------------------------- // intersect ray (pnt+x*vec, x>=0) with visible geoms, except geoms on bodyexclude // return geomid and distance (x) to nearest surface, or -1 if no intersection // geomgroup, flg_static are as in mjvOption; geomgroup==NULL skips group exclusion mjtNum mj_ray(const mjModel* m, const mjData* d, const mjtNum* pnt, const mjtNum* vec, const mjtByte* geomgroup, mjtByte flg_static, int bodyexclude, int geomid[1]) { mjtNum dist, newdist; // check vector length if (mju_norm3(vec) < mjMINVAL) { mjERROR("vector length is too small"); } // clear result dist = -1; if (geomid) *geomid = -1; // loop over geoms not eliminated by mask and bodyexclude for (int i=0; i < m->ngeom; i++) { if (!ray_eliminate(m, d, i, geomgroup, flg_static, bodyexclude)) { // handle mesh and hfield separately if (m->geom_type[i] == mjGEOM_MESH) { newdist = mj_rayMesh(m, d, i, pnt, vec); } else if (m->geom_type[i] == mjGEOM_HFIELD) { newdist = mj_rayHfield(m, d, i, pnt, vec); } else if (m->geom_type[i] == mjGEOM_SDF) { newdist = ray_sdf(m, d, i, pnt, vec); } // otherwise general dispatch else { newdist = mju_rayGeom(d->geom_xpos+3*i, d->geom_xmat+9*i, m->geom_size+3*i, pnt, vec, m->geom_type[i]); } // update if closer intersection found if (newdist >= 0 && (newdist < dist || dist < 0)) { dist = newdist; if (geomid) *geomid = i; } } } return dist; } // Initializes spherical bounding angles (geom_ba) and flag vector for a given source void mju_multiRayPrepare(const mjModel* m, const mjData* d, const mjtNum pnt[3], const mjtNum* ray_xmat, const mjtByte* geomgroup, mjtByte flg_static, int bodyexclude, mjtNum cutoff, mjtNum* geom_ba, int* geom_eliminate) { if (ray_xmat) { mjERROR("ray_xmat is currently unused, should be NULL"); } // compute eliminate flag for all geoms for (int geomid=0; geomid < m->ngeom; geomid++) geom_eliminate[geomid] = ray_eliminate(m, d, geomid, geomgroup, flg_static, bodyexclude); for (int b=0; b < m->nbody; b++) { // skip precomputation if no bounding volume is available if (m->body_bvhadr[b] == -1) { continue; } // loop over child geoms, compute bounding angles for (int i=0; i < m->body_geomnum[b]; i++) { int g = i + m->body_geomadr[b]; mjtNum AABB[4] = {mjMAXVAL, mjMAXVAL, -mjMAXVAL, -mjMAXVAL}; mjtNum* aabb = m->geom_aabb + 6*g; mjtNum* xpos = d->geom_xpos + 3*g; mjtNum* xmat = d->geom_xmat + 9*g; // skip if eliminated by flags if (geom_eliminate[g]) { continue; } // add to geom_eliminate if distance of bounding sphere is above cutoff if (mju_dist3(d->geom_xpos+3*g, pnt) > cutoff+m->geom_rbound[g]) { geom_eliminate[g] = 1; continue; } if (point_in_box(aabb, xpos, xmat, pnt)) { (geom_ba+4*g)[0] = -mjPI; (geom_ba+4*g)[1] = 0; (geom_ba+4*g)[2] = mjPI; (geom_ba+4*g)[3] = mjPI; continue; } // loop over box vertices, compute spherical aperture for (int v=0; v < 8; v++) { mjtNum vert[3], box[3]; vert[0] = (v&1 ? aabb[0]+aabb[3] : aabb[0]-aabb[3]); vert[1] = (v&2 ? aabb[1]+aabb[4] : aabb[1]-aabb[4]); vert[2] = (v&4 ? aabb[2]+aabb[5] : aabb[2]-aabb[5]); // rotate to the world frame mju_mulMatVec3(box, xmat, vert); mju_addTo3(box, xpos); // spherical coordinates mju_sub3(vert, box, pnt); mjtNum azimuth = longitude(vert); mjtNum elevation = latitude(vert); // update bounds AABB[0] = mju_min(AABB[0], azimuth); AABB[1] = mju_min(AABB[1], elevation); AABB[2] = mju_max(AABB[2], azimuth); AABB[3] = mju_max(AABB[3], elevation); } if (AABB[2]-AABB[0] > mjPI) { AABB[0] = -mjPI; AABB[1] = 0; AABB[2] = mjPI; AABB[3] = mjPI; } if (AABB[3]-AABB[1] > mjPI) { // SHOULD NOT OCCUR mjERROR("discontinuity in azimuth angle"); } mju_copy(geom_ba+4*g, AABB, 4); } } } // Performs single ray intersection static mjtNum mju_singleRay(const mjModel* m, mjData* d, const mjtNum pnt[3], const mjtNum vec[3], int* ray_eliminate, mjtNum* geom_ba, int geomid[1]) { mjtNum dist, newdist; // check vector length if (mju_norm3(vec) < mjMINVAL) { mjERROR("vector length is too small"); } // clear result dist = -1; *geomid = -1; // get ray spherical coordinates mjtNum azimuth = longitude(vec); mjtNum elevation = latitude(vec); // loop over bodies not eliminated by bodyexclude for (int b=0; b < m->nbody; b++) { // exclude body using bounding sphere test if (m->body_bvhadr[b] != -1) { mjtNum* pos = m->bvh_aabb + 6*m->body_bvhadr[b]; mjtNum center[3]; mjtNum* size = pos + 3; mjtNum ssz = size[0]*size[0] + size[1]*size[1] + size[2]*size[2]; mju_add3(center, pos, d->xipos+3*b); if (ray_sphere(center, NULL, ssz, pnt, vec) < 0) { continue; } } // loop over geoms if bounding sphere test fails for (int g=0; g < m->body_geomnum[b]; g++) { int i = m->body_geomadr[b] + g; if (ray_eliminate[i]) { continue; } // exclude geom using bounding angles if (m->body_bvhadr[b] != -1) { if (azimuth < (geom_ba+4*i)[0] || elevation < (geom_ba+4*i)[1] || azimuth > (geom_ba+4*i)[2] || elevation > (geom_ba+4*i)[3]) { continue; } } // handle mesh and hfield separately if (m->geom_type[i] == mjGEOM_MESH) { newdist = mj_rayMesh(m, d, i, pnt, vec); } else if (m->geom_type[i] == mjGEOM_HFIELD) { newdist = mj_rayHfield(m, d, i, pnt, vec); } else if (m->geom_type[i] == mjGEOM_SDF) { newdist = ray_sdf(m, d, i, pnt, vec); } // otherwise general dispatch else { newdist = mju_rayGeom(d->geom_xpos+3*i, d->geom_xmat+9*i, m->geom_size+3*i, pnt, vec, m->geom_type[i]); } // update if closer intersection found if (newdist >= 0 && (newdist < dist || dist < 0)) { dist = newdist; *geomid = i; } } } return dist; } // Performs multiple ray intersections with the precomputes bv and flags void mj_multiRay(const mjModel* m, mjData* d, const mjtNum pnt[3], const mjtNum* vec, const mjtByte* geomgroup, mjtByte flg_static, int bodyexclude, int* geomid, mjtNum* dist, int nray, mjtNum cutoff) { mj_markStack(d); // allocate source mjtNum* geom_ba = mjSTACKALLOC(d, 4*m->ngeom, mjtNum); int* geom_eliminate = mjSTACKALLOC(d, m->ngeom, int); // initialize source mju_multiRayPrepare(m, d, pnt, NULL, geomgroup, flg_static, bodyexclude, cutoff, geom_ba, geom_eliminate); // loop over rays for (int i=0; i < nray; i++) { dist[i] = mju_singleRay(m, d, pnt, vec+3*i, geom_eliminate, geom_ba, geomid+i); } mj_freeStack(d); }