Exemple #1
0
TupleList SimpleQueryLinker::make_tuples(
        const std::vector<std::string>& variables) 
{
    TupleList result;

    std::string first_qvar = *variables.begin();
    
    if(!is_initialized(first_qvar)) {
        throw QueryLinkerError();
    }

    for(ConditionSet::iterator cit = _qvar_table[first_qvar].begin();
        cit != _qvar_table[first_qvar].end(); ++cit)
    {
        TupleList tuples = make_tuples(first_qvar, *cit, 
                ++variables.begin(), variables.end());

        for(TupleList::iterator tit = tuples.begin();
            tit != tuples.end(); ++tit)
        {
            result.insert(*tit);
        }
    }

    return result;
}
Exemple #2
0
void SimpleQueryLinker::merge_tuples(const ConditionPtr& target_condition,
        const TupleList& tuples, TupleList& result)
{
    for(TupleList::const_iterator tit = tuples.begin();
        tit != tuples.end(); ++tit)
    {
        result.insert(ConditionTuplePtr(
                    new SimpleConditionTuple(target_condition, *tit)));
    }
}
Exemple #3
0
  //Simple quick  sort to real
  void ParallelMergeMesh::SortTuplesByReal(TupleList &tup,
					   double eps)
  {
    bool canWrite = tup.get_writeEnabled();
    if(!canWrite) tup.enableWriteAccess();

    uint mi, ml, mul, mr;
    tup.getTupleSize(mi,ml,mul,mr);
    PerformRealSort(tup, 0, tup.get_n(), eps, mr);

    if(!canWrite) tup.disableWriteAccess();
  }
Exemple #4
0
TupleList SimpleQueryLinker::make_tuples(
        const std::string& current_qvar,
        const ConditionPtr& current_condition,
        std::vector<std::string>::const_iterator next_qit,
        std::vector<std::string>::const_iterator end)
{
    if(!is_initialized(current_qvar)) {
        throw QueryLinkerError();
    }

    TupleList result;

    if(next_qit == end) {
        result.insert(ConditionTuplePtr(
                    new SimpleConditionTuple(current_condition)));
    } else {
        std::string next_qvar = *next_qit++;

        if(has_link(current_qvar, next_qvar)) {
            ConditionSet linked_conditions = get_linked_conditions(
                    current_qvar, next_qvar, current_condition);

            for(ConditionSet::iterator cit = linked_conditions.begin();
                    cit != linked_conditions.end(); ++cit)
            {
                merge_tuples(current_condition, 
                        make_tuples(next_qvar, *cit, next_qit, end), 
                        result);
            }
        } else if(has_indirect_links(current_qvar, next_qvar)) {
            ConditionSet linked_conditions = get_indirect_links(
                    current_qvar, next_qvar, current_condition);

            for(ConditionSet::iterator cit = linked_conditions.begin();
                    cit != linked_conditions.end(); ++cit)
            {
                merge_tuples(current_condition, 
                        make_tuples(next_qvar, *cit, next_qit, end), 
                        result);
            }
        } else {
            for(ConditionSet::iterator cit = _qvar_table[next_qvar].begin();
                cit != _qvar_table[next_qvar].end(); ++cit)
            {
                merge_tuples(current_condition, 
                        make_tuples(next_qvar, *cit, next_qit, end), 
                        result);
            }
        }
    }

    return result;
}
Exemple #5
0
/** Merge two DiscreteDBFs as if there we executed sequentially
 * @remarks This can also be achived on-the-fly using SequentialDBF
 */
DiscreteDBF DiscreteDBF::sequentialMerge(const DiscreteDBF& dbf1,
										 const DiscreteDBF& dbf2){
	DiscreteDBF retval;
	const TupleList& t1 = dbf1._tuples,
		  			 t2 = dbf2._tuples;
	TupleList& tr = retval._tuples;
	ConstTupleIterator i1 = t1.begin(),
					   i2 = t2.begin();

	int max = 0;

	// While we have stuff to merge from both t1 and t2
	while(i1 != t1.end() && i2 != t2.end()){
		int time = -1;
		if(i1->time() <= i2->time()){
			if(max < i1->wcet()){
				max = i1->wcet();
				time = i1->time();
				assert(time != -1);
			}
			i1++;
		}else if(i1->time() >= i2->time()){
			if(max < i2->wcet()){
				max = i2->wcet();
				time = i2->time();
				assert(time != -1);
			}
			i2++;
		}
		if(time != -1)
			tr.push_back(DemandTuple(max, time));
	}

	// Now one of them might contains something...
	while(i1 != t1.end()){
		if(max < i1->wcet()){
			max = i1->wcet();
			tr.push_back(DemandTuple(max, i1->time()));
		}
		i1++;
	}
	while(i2 != t2.end()){
		if(max < i2->wcet()){
			max = i2->wcet();
			tr.push_back(DemandTuple(max, i2->time()));
		}
		i2++;
	}

	return retval;
}
Exemple #6
0
void DomUtil::writeTupleListEntry(QDomDocument &doc, const QString &path, const QString &tag,
                                  const QStringList &attrList, const TupleList &value)
{
QDomElement el = createElementByPath(doc, path);

    TupleList::ConstIterator it;
    for (it = value.begin(); it != value.end(); ++it) {
        QDomElement subEl = doc.createElement(tag);
        int i=0;
        for(QValueListConstIterator<QString> iter = attrList.begin(); iter != attrList.end(); ++iter) {
            subEl.setAttribute(*iter,(*it)[i++]);
            }
        el.appendChild(subEl);
    }
}
Exemple #7
0
ErrorCode ReadCCMIO::make_faces(int *farray, 
                                TupleList &vert_map,
                                std::vector<EntityHandle> &new_faces, int num_faces) 
{
  std::vector<EntityHandle> verts;
  ErrorCode tmp_rval = MB_SUCCESS, rval = MB_SUCCESS;
  
  for (int i = 0; i < num_faces; i++) {
    int num_verts = *farray++;
    verts.resize(num_verts);

      // fill in connectivity by looking up by gid in vert tuple_list
    for (int j = 0; j < num_verts; j++) {
#ifdef TUPLE_LIST
      int tindex = vert_map.find(1, farray[j]);
      if (-1 == tindex) {
        tmp_rval = MB_FAILURE;
        break;
      }
      verts[j] = vert_map.get_ulong(tindex, 0);
#else
      verts[j] = (vert_map[farray[j]])[0];
#endif      
    }
    farray += num_verts;

    if (MB_SUCCESS == tmp_rval) {
    
        // make face
      EntityType ftype = (3 == num_verts ? MBTRI :
                            (4 == num_verts ? MBQUAD : MBPOLYGON));
      EntityHandle faceh;
      tmp_rval = mbImpl->create_element(ftype, &verts[0], num_verts, faceh);
      if (faceh) new_faces.push_back(faceh);
    }
    
    if (MB_SUCCESS != tmp_rval) rval = tmp_rval;
  }
  
  return rval;
}
Exemple #8
0
ErrorCode ReadCCMIO::read_all_faces(CCMIOID topologyID, TupleList &vert_map, 
                                      TupleList &face_map
#ifndef TUPLE_LIST
                                      ,SenseList &sense_map
#endif
                                      , Range *new_faces) 
{
  CCMIOSize_t index = CCMIOSIZEC(0);
  CCMIOID faceID;
  ErrorCode rval;

    // get total # internal/bdy faces, size the face map accordingly
  int nint_faces = 0, nbdy_faces = 0;
  CCMIOSize_t nf;
  CCMIOError error = kCCMIONoErr;
  while (kCCMIONoErr == CCMIONextEntity(NULL, topologyID, kCCMIOBoundaryFaces, &index, 
                                        &faceID))
  {
    CCMIOEntitySize(&error, faceID, &nf, NULL);
    nbdy_faces = nbdy_faces + nf;
  }
  CCMIOGetEntity(&error, topologyID, kCCMIOInternalFaces, 0, &faceID);
  CCMIOEntitySize(&error, faceID, &nf, NULL);
  nint_faces = nint_faces + nf;
#ifdef TUPLE_LIST
  face_map.resize(2*nint_faces + nbdy_faces);
#endif
  
    // get multiple blocks of bdy faces
  index = CCMIOSIZEC(0);
  while (kCCMIONoErr == CCMIONextEntity(NULL, topologyID, kCCMIOBoundaryFaces, &index, 
                                        &faceID))
  {
    rval = read_faces(faceID, kCCMIOBoundaryFaces, vert_map, face_map
#ifndef TUPLE_LIST
                      , sense_map
#endif
                      , new_faces);
    CHKERR(rval, "Trouble reading boundary faces.");
  }
  
    // now get internal faces
  CCMIOGetEntity(&error, topologyID, kCCMIOInternalFaces, 0, &faceID);

  rval = read_faces(faceID, kCCMIOInternalFaces, vert_map,face_map
#ifndef TUPLE_LIST
                    , sense_map
#endif
                    , new_faces);
  CHKERR(rval, "Trouble reading internal faces.");

  return rval;
}
Exemple #9
0
TupleList MBConnection::getBigramCount(const std::string& word1, const std::string& word2)
{
  MYSQL_BIND param[2];
  memset(param, 0, 2 * sizeof(MYSQL_BIND));
  setBindValue<0>(param, word1);  
  setBindValue<1>(param, word2);
  
  long nameId;
  long lineCount;
  MYSQL_BIND result[2];
  memset(result, 0, 2 * sizeof(MYSQL_BIND));
  setBindValue<0>(result, nameId);
  setBindValue<1>(result, lineCount);

  if (mysql_stmt_bind_param(this->_getBigramCountStatement, param))
  {
    std::cout << "Binding parameters to prepared statement failed" << std::endl;
    throw 0;
  }

  if (mysql_stmt_bind_result(this->_getBigramCountStatement, result))
  {
    std::cout << "Binding result to prepared statement failed" << std::endl;
    throw 0;
  }

  if (mysql_stmt_execute(this->_getBigramCountStatement))
  {
    std::cout << "Executing select from bigram count failed" << mysql_stmt_error(this->_getBigramCountStatement) << std::endl;
    throw 0;
  }

  mysql_stmt_store_result(this->_getBigramCountStatement);
  TupleList resultSet;

  while (!mysql_stmt_fetch(this->_getBigramCountStatement)) 
    resultSet.push_back(make_tuple(static_cast<int>(nameId), static_cast<int>(lineCount)));

  return resultSet;
}
Exemple #10
0
  //Swap around tuples
  void ParallelMergeMesh::SwapTuples(TupleList &tup,
				     unsigned long a, unsigned long b)
  {
    if(a==b) return;

    uint mi, ml, mul, mr;
    tup.getTupleSize(mi, ml, mul, mr);

    //Swap mi
    unsigned long a_val = a*mi, b_val=b*mi;
    for(unsigned long i=0; i< mi;i++){
      sint t =tup.vi_rd[a_val];
      tup.vi_wr[a_val] = tup.vi_rd[b_val];
      tup.vi_wr[b_val] = t; 
      a_val++;
      b_val++;
    }
    //Swap ml
    a_val = a*ml;
    b_val = b*ml;
    for(unsigned long i=0; i< ml;i++){
      slong t =tup.vl_rd[a_val];
      tup.vl_wr[a_val] = tup.vl_rd[b_val];
      tup.vl_wr[b_val] = t;
      a_val++;
      b_val++;
    }
    //Swap mul
    a_val = a*mul;
    b_val = b*mul;
    for(unsigned long i=0; i< mul;i++){
      Ulong t =tup.vul_rd[a_val];
      tup.vul_wr[a_val] = tup.vul_rd[b_val];
      tup.vul_wr[b_val] = t; 
      a_val++;
      b_val++;
    }
    //Swap mr
    a_val = a*mr;
    b_val = b*mr;
    for(unsigned long i=0; i< mr;i++){
      realType t =tup.vr_rd[a_val];
      tup.vr_wr[a_val] = tup.vr_rd[b_val];
      tup.vr_wr[b_val] = t; 
      a_val++;
      b_val++;
    }
  }
Exemple #11
0
      void
      sendStaticFile(TCPSocket* sock, TupleList& headers, const Path& file)
      {
        int64_t beg = -1;
        int64_t end = -1;

        std::string range = headers.get("range");
        if (range.compare(0, 6, "bytes=") == 0)
        {
          std::vector<std::string> parts;
          String::split(range.substr(6), "-", parts);

          std::istringstream p0(parts[0]);
          p0 >> beg;

          std::istringstream p1(parts[1]);
          p1 >> end;
        }
Exemple #12
0
void TupleCache::add_emit_tuple(sp_int32 _task_id, const proto::system::AckTuple& _tuple) {
  if (total_size_ >= drain_threshold_bytes_) drain_impl();
  TupleList* l = get(_task_id);
  return l->add_emit_tuple(_tuple, &total_size_);
}
Exemple #13
0
sp_int64 TupleCache::add_data_tuple(sp_int32 _task_id, const proto::api::StreamId& _streamid,
                                    proto::system::HeronDataTuple* _tuple) {
  if (total_size_ >= drain_threshold_bytes_) drain_impl();
  TupleList* l = get(_task_id);
  return l->add_data_tuple(_streamid, _tuple, &total_size_, &tuples_cache_max_tuple_size_);
}
Exemple #14
0
ErrorCode ReadCCMIO::read_vertices(CCMIOSize_t /* proc */, CCMIOID /* processorID */, CCMIOID verticesID,
                                   CCMIOID /* topologyID */, 
                                   Range *verts, TupleList &vert_map) 
{
  CCMIOError error = kCCMIONoErr;
  
    // pre-read the number of vertices, so we can pre-allocate & read directly in
  CCMIOSize_t nverts = CCMIOSIZEC(0);
  CCMIOEntitySize(&error, verticesID, &nverts, NULL);
  CHKCCMERR(error, "Couldn't get number of vertices.");

    // get # dimensions
  CCMIOSize_t dims;
  float scale;
  CCMIOReadVerticesf(&error, verticesID, &dims, NULL, NULL, NULL, CCMIOINDEXC(0), CCMIOINDEXC(1));
  CHKCCMERR(error, "Couldn't get number of dimensions.");

    // allocate vertex space
  EntityHandle node_handle = 0;
  std::vector<double*> arrays;
  readMeshIface->get_node_coords(3, GETINT32(nverts), MB_START_ID, node_handle, arrays);

    // read vertex coords
  CCMIOID mapID;
  std::vector<double> tmp_coords(GETINT32(dims)*GETINT32(nverts));
  CCMIOReadVerticesd(&error, verticesID, &dims, &scale, &mapID, &tmp_coords[0], 
                     CCMIOINDEXC(0), CCMIOINDEXC(0+nverts));
  CHKCCMERR(error, "Trouble reading vertex coordinates.");

    // copy interleaved coords into moab blocked coordinate space
  int i = 0, threei = 0;
  for (; i < nverts; i++) {
    arrays[0][i] = tmp_coords[threei++];
    arrays[1][i] = tmp_coords[threei++];
    if (3 == GETINT32(dims)) arrays[2][i] = tmp_coords[threei++];
    else arrays[2][i] = 0.0;
  }

    // scale, if necessary
  if (1.0 != scale) {
    for(i = 0; i < nverts; i++) {
      arrays[0][i] *= scale;
      arrays[1][i] *= scale;
      if (3 == GETINT32(dims)) arrays[2][i] *= scale;
    }
  }

    // read gids for vertices
  std::vector<int> gids(GETINT32(nverts));
  CCMIOReadMap(&error, mapID, &gids[0], CCMIOINDEXC(kCCMIOStart), CCMIOINDEXC(kCCMIOEnd));
  CHKCCMERR(error, "Trouble reading vertex global ids.");

    // put new vertex handles into range, and set gids for them
  Range new_verts(node_handle, node_handle+nverts-1);
  ErrorCode rval = mbImpl->tag_set_data(mGlobalIdTag, new_verts, &gids[0]);
  CHKERR(rval, "Couldn't set gids on vertices.");
  
    // pack vert_map with global ids and handles for these vertices
#ifdef TUPLE_LIST
  vert_map.resize(GETINT32(nverts));
  for (i = 0; i < GETINT32(nverts); i++) {
    vert_map.push_back(NULL, &gids[i], &node_handle, NULL);
#else
  for (i = 0; i < GETINT32(nverts); i++) {
    (vert_map[gids[i]]).push_back(node_handle);
#endif
    node_handle += 1;
  }
  
  if (verts) verts->merge(new_verts);

  return MB_SUCCESS;
}
  
ErrorCode ReadCCMIO::get_processors(CCMIOID stateID, 
                                    CCMIOID &processorID, CCMIOID &verticesID,
                                    CCMIOID &topologyID, CCMIOID &solutionID,
                                    std::vector<CCMIOSize_t> &procs,
                                    bool & /* has_solution */) 
{
  CCMIOSize_t proc = CCMIOSIZEC(0);
  CCMIOError error = kCCMIONoErr;
  
  CCMIONextEntity(&error, stateID, kCCMIOProcessor, &proc, &processorID);
  CHKCCMERR(error, NULL);
  if (CCMIOReadProcessor(NULL, processorID, &verticesID, 
                         &topologyID, NULL, &solutionID) != kCCMIONoErr) {
      // Maybe no solution;  try again
    CCMIOReadProcessor(&error, processorID, &verticesID, 
                       &topologyID, NULL, NULL);
    hasSolution = false;
  }
  CHKCCMERR(error, NULL);
  
  procs.push_back(proc);
  
  return MB_SUCCESS;
}
Exemple #15
0
/** Create DiscreteStepIterator */
DiscreteDBF::DiscreteStepIterator::DiscreteStepIterator(const TupleList& tuples){
	_next = tuples.begin();
	_end = tuples.end();
}
Exemple #16
0
ErrorCode ReadCCMIO::construct_cells(TupleList &face_map, 
#ifndef TUPLE_LIST
                                     SenseList &sense_map, 
#endif
                                     TupleList & /* vert_map */,
                                     std::map<int,int> &cell_topo_types,
                                     std::vector<EntityHandle> &new_cells) 
{
  std::vector<EntityHandle> facehs;
  std::vector<int> senses;
  EntityHandle cell;
  ErrorCode tmp_rval, rval = MB_SUCCESS;
  EntityType this_type = MBMAXTYPE;
  bool has_mid_nodes = false;
#ifdef TUPLE_LIST
  unsigned int i = 0;
  while (i < face_map.n) {
      // pull out face handles bounding the same cell
    facehs.clear();
    int this_id = face_map.get_int(i);
    unsigned int inext = i;
    while (face_map.get_int(inext) == this_id && inext <= face_map.n) {
      inext++;
      EntityHandle face = face_map.get_ulong(inext);
      facehs.push_back(face);
      senses.push_back(face_map.get_short(inext));
    }
    this_type = MBMAXTYPE;
    has_mid_nodes = false;
#else
      
  std::map<int,std::vector<EntityHandle> >::iterator fmit;
  std::map<int,std::vector<int> >::iterator smit;
  std::map<int,int>::iterator typeit;
  for (fmit = face_map.begin(), smit = sense_map.begin();
       fmit != face_map.end(); fmit++, smit++) {
      // pull out face handles bounding the same cell
    facehs.clear();
    int this_id = (*fmit).first;
    facehs = (*fmit).second;
    senses.clear();
    senses = (*smit).second;
    typeit = cell_topo_types.find(this_id);
    if (typeit != cell_topo_types.end()) {
      rval = ccmio_to_moab_type(typeit->second, this_type, has_mid_nodes);
    }
    else {
      this_type = MBMAXTYPE;
      has_mid_nodes = false;
    }
#endif
    tmp_rval = create_cell_from_faces(facehs, senses, this_type, has_mid_nodes, cell);
    if (MB_SUCCESS != tmp_rval) rval = tmp_rval;
    else {
      new_cells.push_back(cell);
        // tag cell with global id
      tmp_rval = mbImpl->tag_set_data(mGlobalIdTag, &cell, 1, &this_id);
      if (MB_SUCCESS != tmp_rval) rval = tmp_rval;
    }
  }
    
  return rval;
}

ErrorCode ReadCCMIO::ccmio_to_moab_type(int ccm_type, EntityType &moab_type, bool &has_mid_nodes) 
{
  switch (ccm_type) {
    case 1:
        moab_type = MBVERTEX;
        break;
    case 2:
    case 28:
        moab_type = MBEDGE;
        break;
    case 29:
        moab_type = MBMAXTYPE;
        break;
    case 3:
    case 4:
        moab_type = MBQUAD;
        break;
    case 11:
    case 21:
        moab_type = MBHEX;
        break;
    case 12:
    case 22:
        moab_type = MBPRISM;
        break;
    case 13:
    case 23:
        moab_type = MBTET;
        break;
    case 14:
    case 24:
        moab_type = MBPYRAMID;
        break;
    case 255:
        moab_type = MBPOLYHEDRON;
        break;
    default:
        moab_type = MBMAXTYPE;
  }
  
  switch (ccm_type) {
    case 28:
    case 4:
    case 21:
    case 22:
    case 23:
    case 24:
        has_mid_nodes = true;
        break;
    default:
        break;
  }
  
  return MB_SUCCESS;
}

ErrorCode ReadCCMIO::create_cell_from_faces(std::vector<EntityHandle> &facehs,
                                            std::vector<int> &senses,
                                            EntityType this_type,
                                            bool /* has_mid_nodes */,
                                            EntityHandle &cell) 
{
  ErrorCode rval;

    // test up front to see if they're one type
  EntityType face_type = mbImpl->type_from_handle(facehs[0]);
  bool same_type = true;
  for (std::vector<EntityHandle>::iterator vit = facehs.begin(); vit != facehs.end(); vit++) {
    if (face_type != mbImpl->type_from_handle(*vit)) {
      same_type = false;
      break;
    }
  }

  std::vector<EntityHandle> verts;
  EntityType input_type = this_type;
  std::vector<EntityHandle> storage;
  MeshTopoUtil mtu(mbImpl);
  
    // preset this to maxtype, so we get an affirmative choice in loop
  this_type = MBMAXTYPE;
  
  if ((MBTET == input_type || MBMAXTYPE == input_type) && same_type &&
      face_type == MBTRI && facehs.size() == 4) {
      // try to get proper connectivity for tet

      // get connectivity of first face, and reverse it if sense is forward, since 
      // base face always points into entity
    rval = mbImpl->get_connectivity(&facehs[0], 1, verts);
    CHKERR(rval, "Couldn't get connectivity.");
    if (senses[0] > 0) std::reverse(verts.begin(), verts.end());

      // get the 4th vertex through the next tri
    const EntityHandle *conn; int conn_size;
    rval = mbImpl->get_connectivity(facehs[1], conn, conn_size, true, &storage);
    CHKERR(rval, "Couldn't get connectivity.");
    int i = 0;
    while (std::find(verts.begin(), verts.end(), conn[i]) != verts.end() && i < conn_size) i++;

      // if i is not at the end of the verts, found the apex; otherwise fall back to polyhedron
    if (conn_size != i) {
      this_type = MBTET;
      verts.push_back(conn[i]);
    }
  }
  else if ((MBHEX == input_type || MBMAXTYPE == input_type) && same_type &&
           MBQUAD == face_type && facehs.size() == 6) {
      // build hex from quads
      // algorithm:
      // - verts = vertices from 1st quad
      // - find quad q1 sharing verts[0] and verts[1]
      // - find quad q2 sharing other 2 verts in q1
      // - find v1 = opposite vert from verts[1] in q1 , v2 = opposite from verts[0]
      // - get i = offset of v1 in verts2 of q2, rotate verts2 by i
      // - if verts2[i+1%4] != v2, flip verts2 by switching verts2[1] and verts2[3]
      // - append verts2 to verts


      // get the other vertices for this hex; need to find the quad with no common vertices
    Range tmp_faces, tmp_verts;
      // get connectivity of first face, and reverse it if sense is forward, since 
      // base face always points into entity
    rval = mbImpl->get_connectivity(&facehs[0], 1, verts);
    CHKERR(rval, "Couldn't get connectivity.");
    if (senses[0] > 0) std::reverse(verts.begin(), verts.end());


      // get q1, which shares 2 vertices with q0
    std::copy(facehs.begin(), facehs.end(), range_inserter(tmp_faces));
    rval = mbImpl->get_adjacencies(&verts[0], 2, 2, false, tmp_faces);
    if (MB_SUCCESS != rval || tmp_faces.size() != 2)
      CHKERR(MB_FAILURE, "Couldn't get adj face.");
    tmp_faces.erase(facehs[0]);
    EntityHandle q1 = *tmp_faces.begin();
      // get other 2 verts of q1
    rval = mbImpl->get_connectivity(&q1, 1, tmp_verts);
    CHKERR(rval, "Couldn't get adj verts.");
    tmp_verts.erase(verts[0]); tmp_verts.erase(verts[1]);
      // get q2
    std::copy(facehs.begin(), facehs.end(), range_inserter(tmp_faces));
    rval = mbImpl->get_adjacencies(tmp_verts, 2, false, tmp_faces);
    if (MB_SUCCESS != rval || tmp_faces.size() != 2)
      CHKERR(MB_FAILURE, "Couldn't get adj face.");
    tmp_faces.erase(q1);
    EntityHandle q2 = *tmp_faces.begin();
      // get verts in q2
    rval = mbImpl->get_connectivity(&q2, 1, storage);
    CHKERR(rval, "Couldn't get adj vertices.");

      // get verts in q1 opposite from v[1] and v[0] in q0
    EntityHandle v0 = 0, v1 = 0;
    rval = mtu.opposite_entity(q1, verts[1], v0);
    rval = mtu.opposite_entity(q1, verts[0], v1);
    if (v0 && v1) {

        // offset of v0 in q2, then rotate and flip
      unsigned int ioff = std::find(storage.begin(), storage.end(), v0) - storage.begin();
      if (4 == ioff)
        CHKERR(MB_FAILURE, "Trouble finding offset.");

      if (storage[(ioff+1)%4] != v1) {
        std::reverse(storage.begin(), storage.end());
        ioff = std::find(storage.begin(), storage.end(), v0) - storage.begin();
      }
      if (0 != ioff)
        std::rotate(storage.begin(), storage.begin()+ioff, storage.end());

        // copy into verts, and make hex
      std::copy(storage.begin(), storage.end(), std::back_inserter(verts));
      this_type = MBHEX;
    }
  }

  if (MBMAXTYPE == this_type && facehs.size() == 5) {
      // some preliminaries
    std::vector<EntityHandle> tris, quads;
    for (unsigned int i = 0; i < 5; i++) {
      if (MBTRI == mbImpl->type_from_handle(facehs[i])) tris.push_back(facehs[i]);
      else if (MBQUAD == mbImpl->type_from_handle(facehs[i])) quads.push_back(facehs[i]);
    }

      // check for prisms
    if (2 == tris.size() && 3 == quads.size()) {
        // ok, we have the right number of tris and quads; try to find the proper verts

        // get connectivity of first tri, and reverse if necessary
      int index = std::find(facehs.begin(), facehs.end(), tris[0]) - facehs.begin();
      rval = mbImpl->get_connectivity(&tris[0], 1, verts);
      CHKERR(rval, "Couldn't get connectivity.");
      if (senses[index] > 0) std::reverse(verts.begin(), verts.end());

        // now align vertices of other tri, through a quad, similar to how we did hexes
        // get q1, which shares 2 vertices with t0
      Range tmp_faces, tmp_verts;
      std::copy(facehs.begin(), facehs.end(), range_inserter(tmp_faces));
      rval = mbImpl->get_adjacencies(&verts[0], 2, 2, false, tmp_faces);
      if (MB_SUCCESS != rval || tmp_faces.size() != 2)
      CHKERR(MB_FAILURE, "Couldn't get adj face.");
      tmp_faces.erase(tris[0]);
      EntityHandle q1 = *tmp_faces.begin();
        // get verts in q1
      rval = mbImpl->get_connectivity(&q1, 1, storage);
      CHKERR(rval, "Couldn't get adj vertices.");

        // get verts in q1 opposite from v[1] and v[0] in q0
      EntityHandle v0 = 0, v1 = 0;
      rval = mtu.opposite_entity(q1, verts[1], v0);
      rval = mtu.opposite_entity(q1, verts[0], v1);
      if (v0 && v1) {
          // offset of v0 in t2, then rotate and flip
        storage.clear();
        rval = mbImpl->get_connectivity(&tris[1], 1, storage);
        CHKERR(rval, "Couldn't get connectivity.");
    
        index = std::find(facehs.begin(), facehs.end(), tris[1]) - facehs.begin();
        if (senses[index] < 0) std::reverse(storage.begin(), storage.end());
        unsigned int ioff = std::find(storage.begin(), storage.end(), v0) - storage.begin();
        if (3 == ioff) CHKERR(MB_FAILURE, "Trouble finding offset.");
        for (unsigned int i = 0; i < 3; i++)
          verts.push_back(storage[(ioff+i)%3]);

        this_type = MBPRISM;
      }
    }
    else if (tris.size() == 4 && quads.size() == 1) {
        // check for pyramid
        // get connectivity of first tri, and reverse if necessary
      int index = std::find(facehs.begin(), facehs.end(), quads[0]) - facehs.begin();
      rval = mbImpl->get_connectivity(&quads[0], 1, verts);
      CHKERR(rval, "Couldn't get connectivity.");
      if (senses[index] > 0) std::reverse(verts.begin(), verts.end());

        // get apex node
      rval = mbImpl->get_connectivity(&tris[0], 1, storage);
      CHKERR(rval, "Couldn't get connectivity.");
      for (unsigned int i = 0; i < 3; i++) {
        if (std::find(verts.begin(), verts.end(), storage[i]) == verts.end()) {
          verts.push_back(storage[i]);
          break;
        }
      }

      if (5 == verts.size()) this_type = MBPYRAMID;
    }
    else {
        // dummy else clause to stop in debugger
      this_type = MBMAXTYPE;
    }
  }

  if (MBMAXTYPE != input_type && input_type != this_type && this_type != MBMAXTYPE)
    std::cerr << "Warning: types disagree (cell_topo_type = " << CN::EntityTypeName(input_type)
              << ", faces indicate type " << CN::EntityTypeName(this_type) << std::endl;

  if (MBMAXTYPE != input_type && this_type == MBMAXTYPE && input_type != MBPOLYHEDRON)
    std::cerr << "Warning: couldn't find proper connectivity for specified topo_type = " 
              << CN::EntityTypeName(input_type) << std::endl;

    // now make the element; if we fell back to polyhedron, use faces, otherwise use verts
  if (MBPOLYHEDRON == this_type || MBMAXTYPE == this_type) 
    rval = mbImpl->create_element(MBPOLYHEDRON, &facehs[0], facehs.size(), cell);
  else
    rval = mbImpl->create_element(this_type, &verts[0], verts.size(), cell);
  CHKERR(rval, "create_element failed.");
  
  return MB_SUCCESS;
}
Exemple #17
0
ErrorCode ReadCCMIO::read_faces(CCMIOID faceID, 
                                CCMIOEntity bdy_or_int,
                                TupleList &vert_map,
                                TupleList &face_map
#ifndef TUPLE_LIST
                                  ,SenseList &sense_map
#endif
                                  , Range *new_faces)
{
  if (kCCMIOInternalFaces != bdy_or_int && kCCMIOBoundaryFaces != bdy_or_int)
    CHKERR(MB_FAILURE, "Face type isn't boundary or internal.");

  CCMIOSize_t dum_faces;
  CCMIOError error = kCCMIONoErr;
  CCMIOEntitySize(&error, faceID, &dum_faces, NULL);
  int num_faces = GETINT32(dum_faces);
  
    // get the size of the face connectivity array (not really a straight connect
    // array, has n, connect(n), ...)
  CCMIOSize_t farray_size = CCMIOSIZEC(0);
  CCMIOReadFaces(&error, faceID, bdy_or_int, NULL, &farray_size, NULL,
                 CCMIOINDEXC(kCCMIOStart), CCMIOINDEXC(kCCMIOEnd));
  CHKCCMERR(error, "Trouble reading face connectivity length.");
    

    // allocate vectors for holding farray and cells for each face; use new for finer
    // control of de-allocation
  int num_sides = (kCCMIOInternalFaces == bdy_or_int ? 2 : 1);
  int *farray = new int[GETINT32(farray_size)];

    // read farray and make the faces
  CCMIOID mapID;
  CCMIOReadFaces(&error, faceID, bdy_or_int, &mapID, NULL,
                 farray, CCMIOINDEXC(kCCMIOStart), CCMIOINDEXC(kCCMIOEnd));
  CHKCCMERR(error, "Trouble reading face connectivity.");

  std::vector<EntityHandle> face_handles;
  ErrorCode rval = make_faces(farray, vert_map, face_handles, num_faces);
  CHKERR(rval, NULL);

    // read face cells and make tuples
  int *face_cells;
  if (num_sides*num_faces < farray_size) face_cells = new int[num_sides*num_faces];
  else face_cells = farray;
  CCMIOReadFaceCells(&error, faceID, bdy_or_int, face_cells,
                     CCMIOINDEXC(kCCMIOStart), CCMIOINDEXC(kCCMIOEnd));
  CHKCCMERR(error, "Trouble reading face cells.");

  int *tmp_ptr = face_cells;
  for (unsigned int i = 0; i < face_handles.size(); i++) {
#ifdef TUPLE_LIST
    short forward = 1, reverse = -1;
    face_map.push_back(&forward, tmp_ptr++, &face_handles[i], NULL);
    if (2 == num_sides)
      face_map.push_back(&reverse, tmp_ptr++, &face_handles[i], NULL);
#else
    face_map[*tmp_ptr].push_back(face_handles[i]);
    sense_map[*tmp_ptr++].push_back(1);
    if (2 == num_sides) {
      face_map[*tmp_ptr].push_back(face_handles[i]);
      sense_map[*tmp_ptr++].push_back(-1);
    }
#endif
  }

    // now read & set face gids, reuse face_cells 'cuz we know it's big enough
  CCMIOReadMap(&error, mapID, face_cells, CCMIOINDEXC(kCCMIOStart), CCMIOINDEXC(kCCMIOEnd));
  CHKCCMERR(error, "Trouble reading face gids.");

  rval = mbImpl->tag_set_data(mGlobalIdTag, &face_handles[0], face_handles.size(), face_cells);
  CHKERR(rval, "Couldn't set face global ids.");

    // make a neumann set for these faces if they're all in a boundary face set
  if (kCCMIOBoundaryFaces == bdy_or_int) {
    EntityHandle neuset;
    rval = mbImpl->create_meshset(MESHSET_SET, neuset);
    CHKERR(rval, "Failed to create neumann set.");

      // don't trust entity index passed in
    int index;
    CCMIOGetEntityIndex(&error, faceID, &index);
    newNeusets[index] = neuset;

    rval = mbImpl->add_entities(neuset, &face_handles[0], face_handles.size());
    CHKERR(rval, "Failed to add faces to neumann set.");

      // now tag as neumann set; will add id later
    int dum_val = 0;
    rval = mbImpl->tag_set_data(mNeumannSetTag, &neuset, 1, &dum_val);
    CHKERR(rval, "Failed to tag neumann set.");
  }

  if (new_faces) {
    std::sort(face_handles.begin(), face_handles.end());
    std::copy(face_handles.rbegin(), face_handles.rend(), range_inserter(*new_faces));
  }
  
  return MB_SUCCESS;
}