// Copyright 2023 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_island.h" #include #include #include #include #include #include // IWYU pragma: keep #include #include "engine/engine_core_constraint.h" #include "engine/engine_io.h" #include "engine/engine_support.h" #include "engine/engine_util_errmem.h" #include "engine/engine_util_misc.h" #include "engine/engine_util_sparse.h" #ifdef MEMORY_SANITIZER #include #endif //-------------------------- local utilities ------------------------------------------------------- // clear island-related arena pointers in mjData static void clearIsland(mjData* d, size_t parena) { #define X(type, name, nr, nc) d->name = NULL; MJDATA_ARENA_POINTERS_ISLAND #undef X d->nefc = 0; d->nisland = 0; d->nidof = 0; d->parena = parena; // poison remaining memory #ifdef ADDRESS_SANITIZER ASAN_POISON_MEMORY_REGION( (char*)d->arena + d->parena, d->narena - d->pstack - d->parena); #endif } // allocate island arrays on arena, return 1 on success, 0 on failure static int arenaAllocIsland(const mjModel* m, mjData* d) { #undef MJ_M #define MJ_M(n) m->n #undef MJ_D #define MJ_D(n) d->n size_t parena_old = d->parena; #define X(type, name, nr, nc) \ d->name = mj_arenaAllocByte(d, sizeof(type) * (nr) * (nc), _Alignof(type)); \ if (!d->name) { \ mj_warning(d, mjWARN_CNSTRFULL, d->narena); \ clearIsland(d, parena_old); \ return 0; \ } MJDATA_ARENA_POINTERS_ISLAND #undef X #undef MJ_M #define MJ_M(n) n #undef MJ_D #define MJ_D(n) n return 1; } //-------------------------- flood-fill and graph construction ------------------------------------ // find disjoint subgraphs ("islands") given sparse symmetric adjacency matrix // arguments: // island (nr) - island index assigned to vertex, -1 if vertex has no edges // nr - number of rows/columns of adjacency matrix // rownnz (nr) - matrix row nonzeros // rowadr (nr) - matrix row addresses // colind (nnz) - matrix column indices // stack (nnz) - stack space // returns number of islands // note: column indices are not required to be unique or sorted int mj_floodFill(int* island, int nr, const int* rownnz, const int* rowadr, const int* colind, int* stack) { // initialize island count, set ids to -1 int nisland = 0; for (int i=0; i < nr; i++) island[i] = -1; // iterate over vertices, discover islands for (int i=0; i < nr; i++) { // vertex already in island or singleton with no edges: skip if (island[i] != -1 || !rownnz[i]) { continue; } // push i onto stack int nstack = 0; stack[nstack++] = i; // DFS traversal of island while (nstack) { // pop v from stack int v = stack[--nstack]; // if v is already assigned, continue if (island[v] != -1) { continue; } // assign v to current island island[v] = nisland; // push adjacent vertices onto stack mju_copyInt(stack + nstack, colind + rowadr[v], rownnz[v]); nstack += rownnz[v]; } // island is filled: increment nisland nisland++; } return nisland; } // return id of next tree in Jacobian row i that is different from tree, -1 if not found // start search from *index // write the index of the found tree to *index // if J is (dense/sparse) *index is the (column/nonzero) index, respectively static int treeNext(const mjModel* m, const mjData* d, int tree, int i, int *index) { int tree_next = -1; int j; // local loop variable, saved to *index // sparse if (mj_isSparse(m)) { int rownnz = d->efc_J_rownnz[i]; int* colind = d->efc_J_colind + d->efc_J_rowadr[i]; // loop over remaining nonzeros, look for different tree for (j=(*index); j < rownnz; j++) { int tree_j = m->dof_treeid[colind[j]]; if (tree_j != tree) { // found different tree tree_next = tree_j; break; } } } // dense else { int nv = m->nv; // scan row, look for different tree for (j=(*index); j < nv; j++) { if (d->efc_J[nv*i + j]) { int tree_j = m->dof_treeid[j]; if (tree_j != tree) { // found different tree tree_next = tree_j; break; } } } } // save last index *index = j; return tree_next; } // find first and possibly second nonegative tree ids in Jacobian row i // if row i is special-cased (no more trees), return -1 // otherwise call treeNext, starting scan at index 0, return index static int treeFirst(const mjModel* m, const mjData* d, int tree[2], int i) { int efc_type = d->efc_type[i]; int efc_id = d->efc_id[i]; // clear outputs tree[0] = -1; tree[1] = -1; // ==== fast handling of special cases // joint friction if (efc_type == mjCNSTR_FRICTION_DOF) { tree[0] = m->dof_treeid[efc_id]; return -1; } // joint limit if (efc_type == mjCNSTR_LIMIT_JOINT) { tree[0] = m->dof_treeid[m->jnt_dofadr[efc_id]]; return -1; } // contact if (efc_type == mjCNSTR_CONTACT_FRICTIONLESS || efc_type == mjCNSTR_CONTACT_PYRAMIDAL || efc_type == mjCNSTR_CONTACT_ELLIPTIC) { int g1 = d->contact[efc_id].geom[0]; int g2 = d->contact[efc_id].geom[1]; // no shortcut for flex contacts (handled in the generic case) if (g1 >=0 && g2 >= 0) { tree[0] = m->body_treeid[m->geom_bodyid[g1]]; tree[1] = m->body_treeid[m->geom_bodyid[g2]]; // handle static bodies if (tree[0] < 0) { if (tree[1] < 0) { mjERROR("contact %d is between two static bodies", efc_id); // SHOULD NOT OCCUR } else { int tmp = tree[0]; tree[0] = tree[1]; tree[1] = tmp; } } return -1; } } // connect or weld constraints if (efc_type == mjCNSTR_EQUALITY) { mjtEq eq_type = m->eq_type[efc_id]; if (eq_type == mjEQ_CONNECT || eq_type == mjEQ_WELD) { int b1 = m->eq_obj1id[efc_id]; int b2 = m->eq_obj2id[efc_id]; // get body ids if using site semantics if (m->eq_objtype[efc_id] == mjOBJ_SITE) { b1 = m->site_bodyid[b1]; b2 = m->site_bodyid[b2]; } tree[0] = m->body_treeid[b1]; tree[1] = m->body_treeid[b2]; // handle static bodies if (tree[0] < 0) { if (tree[1] < 0) { mjERROR("equality %d is between two static bodies", efc_id); // SHOULD NOT OCCUR } else { int tmp = tree[0]; tree[0] = tree[1]; tree[1] = tmp; } } return -1; } } // ==== generic case: scan Jacobian int index = 0; tree[0] = treeNext(m, d, -1, i, &index); if (tree[0] < 0) { mjERROR("no tree found for constraint %d", i); // SHOULD NOT OCCUR } return index; } // add 0 edges, 1 self-edge or 2 flipped edges to array, increment treenedge // return current number of edges static int addEdge(int* treenedge, int* edge, int nedge, int tree1, int tree2, int nedge_max) { // handle the static tree if (tree1 == -1 && tree2 == -1) { mjERROR("self-edge of the static tree"); // SHOULD NOT OCCUR return 0; } if (tree1 == -1) tree1 = tree2; if (tree2 == -1) tree2 = tree1; // previous edge int p1 = nedge ? edge[2*nedge - 2] : -1; int p2 = nedge ? edge[2*nedge - 1] : -1; // === self edge if (tree1 == tree2) { // same as previous edge, return if (nedge && tree1 == p1 && tree1 == p2) { return nedge; } // check size if (nedge >= nedge_max) { mjERROR("edge array too small"); return 0; } // add tree1-tree1 self-edge edge[2*nedge + 0] = tree1; edge[2*nedge + 1] = tree1; treenedge[tree1]++; return nedge + 1; } // === non-self edge if (nedge && ((tree1 == p1 && tree2 == p2) || (tree1 == p2 && tree2 == p1))) { // same as previous edge, return return nedge; } // check size if (nedge + 2 > nedge_max) { mjERROR("edge array too small"); return 0; } // add tree1-tree2 and tree2-tree1 edge[2*nedge + 0] = tree1; edge[2*nedge + 1] = tree2; edge[2*nedge + 2] = tree2; edge[2*nedge + 3] = tree1; treenedge[tree1]++; treenedge[tree2]++; return nedge + 2; } // find tree-tree edges, increment treenedge counters, return total number of edges static int findEdges(const mjModel* m, const mjData* d, int* treenedge, int* edge, int nedge_max) { int nefc = d->nefc; int efc_type = -1; int efc_id = -1; // clear treenedge mju_zeroInt(treenedge, m->ntree); int nedge = 0; for (int i=0; i < nefc; i++) { // row i is still in the same constraint: skip it, if (efc_type == d->efc_type[i] && efc_id == d->efc_id[i]) { // unless it is a flex equality, where the tree pattern changes per dof if (!(efc_type == mjCNSTR_EQUALITY && m->eq_type[efc_id] == mjEQ_FLEX)) { continue; } } efc_type = d->efc_type[i]; efc_id = d->efc_id[i]; int tree[2]; int index = treeFirst(m, d, tree, i); int tree1 = tree[0]; int tree2 = tree[1]; // no more edges to find, add and continue if (index == -1) { nedge = addEdge(treenedge, edge, nedge, tree1, tree2 == -1 ? tree1 : tree2, nedge_max); continue; } // possibly more edges, scan Jacobian row else { tree2 = treeNext(m, d, tree1, i, &index); if (tree2 == -1) { // 1 tree found: add self-edge nedge = addEdge(treenedge, edge, nedge, tree1, tree1, nedge_max); } else { // 2 trees found: add edge, keep scanning and adding until no more trees nedge = addEdge(treenedge, edge, nedge, tree1, tree2, nedge_max); int tree3 = treeNext(m, d, tree2, i, &index); while (tree3 > -1 && tree3 != tree2) { tree1 = tree2; tree2 = tree3; nedge = addEdge(treenedge, edge, nedge, tree1, tree2, nedge_max); tree3 = treeNext(m, d, tree2, i, &index); } } } } return nedge; } //-------------------------- main entry-point ----------------------------------------------------- // discover islands: // nisland, island_idofadr, dof_island, dof_islandnext, island_efcadr, efc_island, efc_islandnext void mj_island(const mjModel* m, mjData* d) { int nv = m->nv, nefc = d->nefc, ntree=m->ntree; // no constraints: quick return if (!mjENABLED(mjENBL_ISLAND) || !nefc) { d->nisland = d->nidof = 0; return; } mj_markStack(d); // allocate edge array, nJ is an upper bound int* edge = mjSTACKALLOC(d, 2*d->nJ, int); // get tree-tree edges and rownnz counts from efc arrays int* rownnz = mjSTACKALLOC(d, ntree, int); // number of edges per tree int nedge = findEdges(m, d, rownnz, edge, d->nJ); // compute starting address of tree's column indices while resetting rownnz int* rowadr = mjSTACKALLOC(d, ntree, int); rowadr[0] = 0; for (int r=1; r < ntree; r++) { rowadr[r] = rowadr[r-1] + rownnz[r-1]; rownnz[r-1] = 0; } rownnz[ntree-1] = 0; // copy column indices: list each tree's neighbors int* colind = mjSTACKALLOC(d, nedge, int); for (int e=0; e < nedge; e++) { int row = edge[2*e]; int col = edge[2*e + 1]; colind[rowadr[row] + rownnz[row]++] = col; } // discover islands int* tree_island = mjSTACKALLOC(d, ntree, int); // id of island assigned to tree int* stack = mjSTACKALLOC(d, nedge, int); d->nisland = mj_floodFill(tree_island, ntree, rownnz, rowadr, colind, stack); // no islands found: quick return if (!d->nisland) { d->nidof = 0; mj_freeStack(d); return; } // count ni: total number of dofs in islands int nidof = 0; for (int i=0; i < nv; i++) { nidof += (tree_island[m->dof_treeid[i]] >= 0); } d->nidof = nidof; // allocate island arrays on arena if (!arenaAllocIsland(m, d)) { mj_freeStack(d); return; } // local copy int nisland = d->nisland; // ------------------------------------- degrees of freedom -------------------------------------- // compute dof_island, island_nv mju_zeroInt(d->island_nv, nisland); for (int i=0; i < nv; i++) { // assign dofs to islands int island = tree_island[m->dof_treeid[i]]; // -1 if unconstrained d->dof_island[i] = island; // increment island_nv if (island >= 0) { d->island_nv[island]++; } } // compute island_idofadr (cumsum of island_nv) d->island_idofadr[0] = 0; for (int i=1; i < nisland; i++) { d->island_idofadr[i] = d->island_idofadr[i-1] + d->island_nv[i-1]; } // compute dof <-> idof maps int* island_nv2 = mjSTACKALLOC(d, nisland + 1, int); // last element counts unconstrained dofs mju_zeroInt(island_nv2, nisland + 1); for (int dof=0; dof < nv; dof++) { int island = d->dof_island[dof]; int idof; if (island >= 0) { // constrained dof idof = d->island_idofadr[island] + island_nv2[island]++; } else { // unconstrained dof idof = nidof + island_nv2[nisland]++; } d->map_dof2idof[dof] = idof; d->map_idof2dof[idof] = dof; // only the first ni elements of map_idof2dof are in some island } // SHOULD NOT OCCUR if (!mju_compare(island_nv2, d->island_nv, nisland)) mjERROR("island_nv miscount"); if (nidof + island_nv2[nisland] != nv) mjERROR("miscount of unconstrained dofs"); // compute island_dofadr (used for visualization) for (int i=0; i < nisland; i++) { d->island_dofadr[i] = d->map_idof2dof[d->island_idofadr[i]]; } // inertia: block-diagonalize both iLD <- qLD and iM <- qM mju_blockDiagSparse(d->iLD, d->iM_rownnz, d->iM_rowadr, d->iM_colind, d->qLD, d->M_rownnz, d->M_rowadr, d->M_colind, nidof, nisland, d->map_idof2dof, d->map_dof2idof, d->island_idofadr, d->island_idofadr, d->iM, d->M); mju_gather(d->iLDiagInv, d->qLDiagInv, d->map_idof2dof, nidof); // ------------------------------------- constraints --------------------------------------------- // compute efc_island, island_{ne,nf,nefc} mju_zeroInt(d->island_ne, nisland); mju_zeroInt(d->island_nf, nisland); mju_zeroInt(d->island_nefc, nisland); for (int i=0; i < nefc; i++) { int tree[2]; treeFirst(m, d, tree, i); int island = tree_island[tree[0]]; d->efc_island[i] = island; d->island_nefc[island]++; switch (d->efc_type[i]) { case mjCNSTR_EQUALITY: d->island_ne[island]++; break; case mjCNSTR_FRICTION_DOF: case mjCNSTR_FRICTION_TENDON: d->island_nf[island]++; break; default: break; } } // compute island_iefcadr (cumsum of island_nefc) d->island_iefcadr[0] = 0; for (int i=1; i < nisland; i++) { d->island_iefcadr[i] = d->island_iefcadr[i-1] + d->island_nefc[i-1]; } // compute efc <-> iefc maps int* island_nefc2 = island_nv2; // reuse island_nv2 mju_zeroInt(island_nefc2, nisland); for (int c=0; c < nefc; c++) { int island = d->efc_island[c]; int ic = d->island_iefcadr[island] + island_nefc2[island]++; d->map_efc2iefc[c] = ic; d->map_iefc2efc[ic] = c; } // SHOULD NOT OCCUR if (!mju_compare(island_nefc2, d->island_nefc, nisland)) mjERROR("island_nefc miscount"); // dense: block-diagonalize Jacobian if (!mj_isSparse(m)) { mju_blockDiag(d->iefc_J, d->efc_J, nv, nidof, nisland, d->map_iefc2efc, d->map_idof2dof, d->island_nefc, d->island_nv, d->island_iefcadr, d->island_idofadr); } // sparse else { // block-diagonalize Jacobian mju_blockDiagSparse(d->iefc_J, d->iefc_J_rownnz, d->iefc_J_rowadr, d->iefc_J_colind, d->efc_J, d->efc_J_rownnz, d->efc_J_rowadr, d->efc_J_colind, nefc, nisland, d->map_iefc2efc, d->map_dof2idof, d->island_iefcadr, d->island_idofadr, NULL, NULL); // recompute rowsuper per island for (int island=0; island < nisland; island++) { int adr = d->island_iefcadr[island]; mju_superSparse(d->island_nefc[island], d->iefc_J_rowsuper + adr, d->iefc_J_rownnz + adr, d->iefc_J_rowadr + adr, d->iefc_J_colind); } // block-diagonalize Jacobian-transpose mju_blockDiagSparse(d->iefc_JT, d->iefc_JT_rownnz, d->iefc_JT_rowadr, d->iefc_JT_colind, d->efc_JT, d->efc_JT_rownnz, d->efc_JT_rowadr, d->efc_JT_colind, nidof, nisland, d->map_idof2dof, d->map_efc2iefc, d->island_idofadr, d->island_iefcadr, NULL, NULL); // recompute rowsuper per island for (int island=0; island < nisland; island++) { int adr = d->island_idofadr[island]; mju_superSparse(d->island_nv[island], d->iefc_JT_rowsuper + adr, d->iefc_JT_rownnz + adr, d->iefc_JT_rowadr + adr, d->iefc_JT_colind); } } // copy position-dependent efc vectors required by solver mju_gatherInt(d->iefc_type, d->efc_type, d->map_iefc2efc, nefc); mju_gatherInt(d->iefc_id, d->efc_id, d->map_iefc2efc, nefc); mju_gather(d->iefc_frictionloss, d->efc_frictionloss, d->map_iefc2efc, nefc); mju_gather(d->iefc_D, d->efc_D, d->map_iefc2efc, nefc); mju_gather(d->iefc_R, d->efc_R, d->map_iefc2efc, nefc); mj_freeStack(d); }