1 | /*
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2 | * Project: MoleCuilder
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3 | * Description: creates and alters molecular systems
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4 | * Copyright (C) 2010-2011 University of Bonn. All rights reserved.
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5 | * Please see the LICENSE file or "Copyright notice" in builder.cpp for details.
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6 | */
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7 |
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8 | /*
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9 | * MoleculeLeafClass.cpp
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10 | *
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11 | * Created on: Oct 20, 2011
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12 | * Author: heber
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13 | */
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14 |
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15 | // include config.h
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16 | #ifdef HAVE_CONFIG_H
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17 | #include <config.h>
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18 | #endif
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19 |
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20 | #include "CodePatterns/MemDebug.hpp"
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21 |
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22 | #include "MoleculeLeafClass.hpp"
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23 |
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24 | #include "CodePatterns/Log.hpp"
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25 |
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26 | #include "atom.hpp"
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27 | #include "Element/element.hpp"
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28 | #include "Fragmentation/Graph.hpp"
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29 | #include "Fragmentation/KeySet.hpp"
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30 | #include "molecule.hpp"
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31 |
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32 | /** Constructor for MoleculeLeafClass root leaf.
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33 | * \param *Up Leaf on upper level
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34 | * \param *PreviousLeaf NULL - We are the first leaf on this level, otherwise points to previous in list
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35 | */
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36 | //MoleculeLeafClass::MoleculeLeafClass(MoleculeLeafClass *Up = NULL, MoleculeLeafClass *Previous = NULL)
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37 | MoleculeLeafClass::MoleculeLeafClass(MoleculeLeafClass *PreviousLeaf = NULL) :
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38 | Leaf(NULL),
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39 | previous(PreviousLeaf)
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40 | {
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41 | // if (Up != NULL)
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42 | // if (Up->DownLeaf == NULL) // are we the first down leaf for the upper leaf?
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43 | // Up->DownLeaf = this;
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44 | // UpLeaf = Up;
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45 | // DownLeaf = NULL;
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46 | if (previous != NULL) {
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47 | MoleculeLeafClass *Walker = previous->next;
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48 | previous->next = this;
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49 | next = Walker;
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50 | } else {
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51 | next = NULL;
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52 | }
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53 | };
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54 |
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55 | /** Destructor for MoleculeLeafClass.
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56 | */
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57 | MoleculeLeafClass::~MoleculeLeafClass()
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58 | {
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59 | // if (DownLeaf != NULL) {// drop leaves further down
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60 | // MoleculeLeafClass *Walker = DownLeaf;
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61 | // MoleculeLeafClass *Next;
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62 | // do {
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63 | // Next = Walker->NextLeaf;
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64 | // delete(Walker);
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65 | // Walker = Next;
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66 | // } while (Walker != NULL);
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67 | // // Last Walker sets DownLeaf automatically to NULL
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68 | // }
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69 | // remove the leaf itself
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70 | if (Leaf != NULL) {
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71 | Leaf->removeAtomsinMolecule();
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72 | World::getInstance().destroyMolecule(Leaf);
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73 | Leaf = NULL;
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74 | }
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75 | // remove this Leaf from level list
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76 | if (previous != NULL)
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77 | previous->next = next;
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78 | // } else { // we are first in list (connects to UpLeaf->DownLeaf)
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79 | // if ((NextLeaf != NULL) && (NextLeaf->UpLeaf == NULL))
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80 | // NextLeaf->UpLeaf = UpLeaf; // either null as we are top level or the upleaf of the first node
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81 | // if (UpLeaf != NULL)
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82 | // UpLeaf->DownLeaf = NextLeaf; // either null as we are only leaf or NextLeaf if we are just the first
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83 | // }
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84 | // UpLeaf = NULL;
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85 | if (next != NULL) // are we last in list
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86 | next->previous = previous;
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87 | next = NULL;
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88 | previous = NULL;
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89 | };
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90 |
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91 | /** Adds \a molecule leaf to the tree.
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92 | * \param *ptr ptr to molecule to be added
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93 | * \param *Previous previous MoleculeLeafClass referencing level and which on the level
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94 | * \return true - success, false - something went wrong
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95 | */
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96 | bool MoleculeLeafClass::AddLeaf(molecule *ptr, MoleculeLeafClass *Previous)
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97 | {
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98 | return false;
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99 | };
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100 |
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101 | /** Fills the root stack for sites to be used as root in fragmentation depending on order or adaptivity criteria
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102 | * Again, as in \sa FillBondStructureFromReference steps recursively through each Leaf in this chain list of molecule's.
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103 | * \param *out output stream for debugging
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104 | * \param *&RootStack stack to be filled
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105 | * \param *AtomMask defines true/false per global Atom::Nr to mask in/out each nuclear site
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106 | * \param &FragmentCounter counts through the fragments in this MoleculeLeafClass
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107 | * \param saturation whether to treat hydrogen special or not
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108 | * \return true - stack is non-empty, fragmentation necessary, false - stack is empty, no more sites to update
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109 | */
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110 | bool MoleculeLeafClass::FillRootStackForSubgraphs(KeyStack *&RootStack, bool *AtomMask, int &FragmentCounter, const enum HydrogenSaturation saturation)
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111 | {
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112 | atom *Father = NULL;
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113 |
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114 | if (RootStack != NULL) {
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115 | // find first root candidates
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116 | if (&(RootStack[FragmentCounter]) != NULL) {
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117 | RootStack[FragmentCounter].clear();
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118 | for(molecule::const_iterator iter = Leaf->begin(); iter != Leaf->end(); ++iter) {
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119 | Father = (*iter)->GetTrueFather();
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120 | if (AtomMask[Father->getNr()]) // apply mask
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121 | if ((saturation == DontSaturate) || ((*iter)->getType()->getAtomicNumber() != 1)) // skip hydrogen
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122 | RootStack[FragmentCounter].push_front((*iter)->getNr());
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123 | }
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124 | if (next != NULL)
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125 | next->FillRootStackForSubgraphs(RootStack, AtomMask, ++FragmentCounter, saturation);
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126 | } else {
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127 | LOG(1, "Rootstack[" << FragmentCounter << "] is NULL.");
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128 | return false;
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129 | }
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130 | FragmentCounter--;
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131 | return true;
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132 | } else {
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133 | LOG(1, "Rootstack is NULL.");
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134 | return false;
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135 | }
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136 | };
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137 |
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138 | /** The indices per keyset are compared to the respective father's Atom::Nr in each subgraph and thus put into \a **&FragmentList.
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139 | * \param *out output stream fro debugging
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140 | * \param *reference reference molecule with the bond structure to be copied
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141 | * \param *KeySetList list with all keysets
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142 | * \param ***ListOfLocalAtoms Lookup table for each subgraph and index of each atom in global molecule, may be NULL on start, then it is filled
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143 | * \param **&FragmentList list to be allocated and returned
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144 | * \param &FragmentCounter counts the fragments as we move along the list
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145 | * \param FreeList true - ***ListOfLocalAtoms is free'd before return, false - it is not
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146 | * \retuen true - success, false - failure
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147 | */
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148 | bool MoleculeLeafClass::AssignKeySetsToFragment(molecule *reference, Graph *KeySetList, atom ***&ListOfLocalAtoms, Graph **&FragmentList, int &FragmentCounter, bool FreeList)
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149 | {
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150 | bool status = true;
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151 | int KeySetCounter = 0;
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152 |
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153 | LOG(1, "Begin of AssignKeySetsToFragment.");
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154 | // fill ListOfLocalAtoms if NULL was given
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155 | if (!Leaf->FillListOfLocalAtoms(ListOfLocalAtoms[FragmentCounter], reference->getAtomCount())) {
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156 | LOG(1, "Filling of ListOfLocalAtoms failed.");
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157 | return false;
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158 | }
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159 |
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160 | // allocate fragment list
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161 | if (FragmentList == NULL) {
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162 | KeySetCounter = Count();
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163 | FragmentList = new Graph*[KeySetCounter];
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164 | for (int i=0;i<KeySetCounter;i++)
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165 | FragmentList[i] = NULL;
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166 | KeySetCounter = 0;
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167 | }
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168 |
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169 | if ((KeySetList != NULL) && (KeySetList->size() != 0)) { // if there are some scanned keysets at all
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170 | // assign scanned keysets
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171 | if (FragmentList[FragmentCounter] == NULL)
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172 | FragmentList[FragmentCounter] = new Graph;
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173 | KeySet *TempSet = new KeySet;
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174 | for (Graph::iterator runner = KeySetList->begin(); runner != KeySetList->end(); runner++) { // key sets contain global numbers!
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175 | if (ListOfLocalAtoms[FragmentCounter][reference->FindAtom(*((*runner).first.begin()))->getNr()] != NULL) {// as we may assume that that bond structure is unchanged, we only test the first key in each set
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176 | // translate keyset to local numbers
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177 | for (KeySet::iterator sprinter = (*runner).first.begin(); sprinter != (*runner).first.end(); sprinter++)
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178 | TempSet->insert(ListOfLocalAtoms[FragmentCounter][reference->FindAtom(*sprinter)->getNr()]->getNr());
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179 | // insert into FragmentList
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180 | FragmentList[FragmentCounter]->insert(GraphPair(*TempSet, pair<int, double> (KeySetCounter++, (*runner).second.second)));
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181 | }
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182 | TempSet->clear();
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183 | }
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184 | delete (TempSet);
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185 | if (KeySetCounter == 0) {// if there are no keysets, delete the list
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186 | LOG(1, "KeySetCounter is zero, deleting FragmentList.");
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187 | delete (FragmentList[FragmentCounter]);
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188 | } else
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189 | LOG(1, KeySetCounter << " keysets were assigned to subgraph " << FragmentCounter << ".");
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190 | FragmentCounter++;
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191 | if (next != NULL)
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192 | next->AssignKeySetsToFragment(reference, KeySetList, ListOfLocalAtoms, FragmentList, FragmentCounter, FreeList);
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193 | FragmentCounter--;
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194 | } else
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195 | LOG(1, "KeySetList is NULL or empty.");
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196 |
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197 | if ((FreeList) && (ListOfLocalAtoms != NULL)) {
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198 | // free the index lookup list
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199 | delete[](ListOfLocalAtoms[FragmentCounter]);
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200 | }
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201 | LOG(1, "End of AssignKeySetsToFragment.");
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202 | return status;
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203 | };
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204 |
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205 | /** Translate list into global numbers (i.e. ones that are valid in "this" molecule, not in MolecularWalker->Leaf)
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206 | * \param *out output stream for debugging
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207 | * \param **FragmentList Graph with local numbers per fragment
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208 | * \param &FragmentCounter counts the fragments as we move along the list
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209 | * \param &TotalNumberOfKeySets global key set counter
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210 | * \param &TotalGraph Graph to be filled with global numbers
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211 | */
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212 | void MoleculeLeafClass::TranslateIndicesToGlobalIDs(Graph **FragmentList, int &FragmentCounter, int &TotalNumberOfKeySets, Graph &TotalGraph)
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213 | {
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214 | LOG(1, "Begin of TranslateIndicesToGlobalIDs.");
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215 | KeySet *TempSet = new KeySet;
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216 | if (FragmentList[FragmentCounter] != NULL) {
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217 | for (Graph::iterator runner = FragmentList[FragmentCounter]->begin(); runner != FragmentList[FragmentCounter]->end(); runner++) {
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218 | for (KeySet::iterator sprinter = (*runner).first.begin(); sprinter != (*runner).first.end(); sprinter++)
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219 | TempSet->insert((Leaf->FindAtom(*sprinter))->GetTrueFather()->getNr());
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220 | TotalGraph.insert(GraphPair(*TempSet, pair<int, double> (TotalNumberOfKeySets++, (*runner).second.second)));
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221 | TempSet->clear();
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222 | }
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223 | delete (TempSet);
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224 | } else {
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225 | LOG(1, "FragmentList is NULL.");
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226 | }
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227 | if (next != NULL)
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228 | next->TranslateIndicesToGlobalIDs(FragmentList, ++FragmentCounter, TotalNumberOfKeySets, TotalGraph);
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229 | FragmentCounter--;
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230 | LOG(1, "End of TranslateIndicesToGlobalIDs.");
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231 | };
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232 |
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233 | /** Simply counts the number of items in the list, from given MoleculeLeafClass.
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234 | * \return number of items
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235 | */
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236 | int MoleculeLeafClass::Count() const
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237 | {
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238 | if (next != NULL)
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239 | return next->Count() + 1;
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240 | else
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241 | return 1;
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242 | };
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243 |
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