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#include "mpiSimulation.hpp" |
9 |
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#include "simError.h" |
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#include "fortranWrappers.hpp" |
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#include "randomSPRNG.hpp" |
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|
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|
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|
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|
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mpiSimulation* mpiSim; |
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|
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mpiSimulation::mpiSimulation(SimInfo* the_entryPlug) |
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|
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mpiPlug->numberProcessors = MPI::COMM_WORLD.Get_size(); |
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mpiPlug->myNode = worldRank; |
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|
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|
24 |
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MolToProcMap = new int[entryPlug->n_mol]; |
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MolComponentType = new int[entryPlug->n_mol]; |
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|
27 |
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AtomToProcMap = new int[entryPlug->n_atoms]; |
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|
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mpiSim = this; |
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wrapMeSimParallel( this ); |
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} |
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|
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} |
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|
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|
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|
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int* mpiSimulation::divideLabor( void ){ |
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|
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int* globalIndex; |
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|
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int nComponents; |
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MoleculeStamp** compStamps; |
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randomSPRNG myRandom; |
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int* componentsNmol; |
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int* AtomsPerProc; |
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|
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double numerator; |
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double denominator; |
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double precast; |
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double x, y, a; |
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int old_atoms, add_atoms, new_atoms; |
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|
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int nTarget; |
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int molIndex, atomIndex, compIndex, compStart; |
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nComponents = entryPlug->nComponents; |
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compStamps = entryPlug->compStamps; |
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componentsNmol = entryPlug->componentsNmol; |
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|
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AtomsPerProc = new int[mpiPlug->numberProcessors]; |
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|
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mpiPlug->nAtomsGlobal = entryPlug->n_atoms; |
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mpiPlug->nBondsGlobal = entryPlug->n_bonds; |
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mpiPlug->nBendsGlobal = entryPlug->n_bends; |
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mpiPlug->nSRIGlobal = entryPlug->n_SRI; |
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mpiPlug->nMolGlobal = entryPlug->n_mol; |
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|
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numerator = (double) entryPlug->n_atoms; |
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denominator = (double) mpiPlug->numberProcessors; |
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precast = numerator / denominator; |
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nTarget = (int)( precast + 0.5 ); |
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|
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molIndex = 0; |
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atomIndex = 0; |
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compIndex = 0; |
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compStart = 0; |
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for( i=0; i<(mpiPlug->numberProcessors-1); i++){ |
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|
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done = 0; |
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nLocal = 0; |
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molLocal = 0; |
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myRandom = new randomSPRNG(); |
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|
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if( i == mpiPlug->myNode ){ |
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mpiPlug->myMolStart = molIndex; |
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mpiPlug->myAtomStart = atomIndex; |
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} |
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|
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while( !done ){ |
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|
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if( (molIndex-compStart) >= componentsNmol[compIndex] ){ |
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compStart = molIndex; |
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compIndex++; |
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continue; |
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} |
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a = (double)mpiPlug->nMolGlobal / (double)mpiPlug->nAtomsGlobal; |
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|
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nLocal += compStamps[compIndex]->getNAtoms(); |
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atomIndex += compStamps[compIndex]->getNAtoms(); |
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molIndex++; |
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molLocal++; |
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|
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if ( nLocal == nTarget ) done = 1; |
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|
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else if( nLocal < nTarget ){ |
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smallDiff = nTarget - nLocal; |
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} |
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else if( nLocal > nTarget ){ |
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bigDiff = nLocal - nTarget; |
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|
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if( bigDiff < smallDiff ) done = 1; |
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else{ |
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molIndex--; |
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molLocal--; |
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atomIndex -= compStamps[compIndex]->getNAtoms(); |
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nLocal -= compStamps[compIndex]->getNAtoms(); |
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done = 1; |
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} |
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} |
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} |
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// Initialize things that we'll send out later: |
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for (i = 0; i < mpiPlug->numberProcessors; i++ ) { |
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AtomsPerProc[i] = 0; |
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} |
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for (i = 0; i < mpiPlug->nMolGlobal; i++ ) { |
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// default to an error condition: |
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MolToProcMap[i] = -1; |
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MolComponentType[i] = -1; |
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} |
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for (i = 0; i < mpiPlug->nAtomsGlobal; i++ ) { |
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// default to an error condition: |
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AtomToProcMap[i] = -1; |
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} |
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|
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if( i == mpiPlug->myNode ){ |
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mpiPlug->myMolEnd = (molIndex - 1); |
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mpiPlug->myAtomEnd = (atomIndex - 1); |
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mpiPlug->myNlocal = nLocal; |
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mpiPlug->myMol = molLocal; |
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} |
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|
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numerator = (double)( entryPlug->n_atoms - atomIndex ); |
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denominator = (double)( mpiPlug->numberProcessors - (i+1) ); |
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if (mpiPlug->myNode == 0) { |
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numerator = (double) entryPlug->n_atoms; |
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denominator = (double) mpiPlug->numberProcessors; |
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precast = numerator / denominator; |
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nTarget = (int)( precast + 0.5 ); |
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} |
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|
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if( mpiPlug->myNode == mpiPlug->numberProcessors-1 ){ |
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mpiPlug->myMolStart = molIndex; |
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mpiPlug->myAtomStart = atomIndex; |
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|
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nLocal = 0; |
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molLocal = 0; |
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while( compIndex < nComponents ){ |
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|
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if( (molIndex-compStart) >= componentsNmol[compIndex] ){ |
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compStart = molIndex; |
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compIndex++; |
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continue; |
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} |
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|
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nLocal += compStamps[compIndex]->getNAtoms(); |
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atomIndex += compStamps[compIndex]->getNAtoms(); |
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molIndex++; |
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molLocal++; |
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// Build the array of molecule component types first |
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molIndex = 0; |
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for (i=0; i < nComponents; i++) { |
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for (j=0; j < componentsNmol[i]; j++) { |
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MolComponentType[molIndex] = i; |
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molIndex++; |
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} |
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|
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mpiPlug->myMolEnd = (molIndex - 1); |
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mpiPlug->myAtomEnd = (atomIndex - 1); |
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mpiPlug->myNlocal = nLocal; |
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mpiPlug->myMol = molLocal; |
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} |
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} |
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|
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atomIndex = 0; |
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|
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MPI_Allreduce( &nLocal, &testSum, 1, MPI_INT, MPI_SUM, MPI_COMM_WORLD ); |
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< |
|
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< |
if( mpiPlug->myNode == 0 ){ |
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if( testSum != entryPlug->n_atoms ){ |
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< |
sprintf( painCave.errMsg, |
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< |
"The summ of all nLocals, %d, did not equal the total number of atoms, %d.\n", |
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< |
testSum, entryPlug->n_atoms ); |
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< |
painCave.isFatal = 1; |
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simError(); |
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> |
for (i = 0; i < molIndex; i++ ) { |
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|
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done = 0; |
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> |
loops = 0; |
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> |
|
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> |
while( !done ){ |
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> |
loops++; |
120 |
> |
|
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> |
// Pick a processor at random |
122 |
> |
|
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which_proc = (int) (myRandom.getRandom() * mpiPlug->numberProcessors); |
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> |
|
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> |
// How many atoms does this processor have? |
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|
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> |
old_atoms = AtomsPerProc[which_proc]; |
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> |
|
129 |
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// If the processor already had too many atoms, just skip this |
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// processor and try again. |
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|
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> |
if (old_atoms >= nTarget) continue; |
133 |
> |
|
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add_atoms = compStamps[MolComponentType[i]]->getNatoms(); |
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new_atoms = old_atoms + add_atoms; |
136 |
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|
137 |
> |
// If we can add this molecule to this processor without sending |
138 |
> |
// it above nTarget, then go ahead and do it: |
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> |
|
140 |
> |
if (new_atoms <= nTarget) { |
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> |
MolToProcMap[i] = which_proc; |
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> |
AtomsPerProc[which_proc] += add_atoms; |
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> |
for (j = 0 ; j < add_atoms; j++ ) { |
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> |
atomIndex++; |
145 |
> |
AtomToProcMap[atomIndex] = which_proc; |
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> |
} |
147 |
> |
done = 1; |
148 |
> |
continue; |
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> |
} |
150 |
> |
|
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> |
// If we've been through this loop too many times, we need |
152 |
> |
// to just give up and assign the molecule to this processor |
153 |
> |
// and be done with it. |
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> |
|
155 |
> |
if (loops > 100) { |
156 |
> |
sprintf( painCave.errMsg, |
157 |
> |
"I've tried 100 times to assign molecule %d to a " |
158 |
> |
" processor, but can't find a good spot.\n" |
159 |
> |
"I'm assigning it at random to processor %d.\n", |
160 |
> |
i, which_proc); |
161 |
> |
painCave.isFatal = 0; |
162 |
> |
simError(); |
163 |
> |
|
164 |
> |
MolToProcMap[i] = which_proc; |
165 |
> |
AtomsPerProc[which_proc] += add_atoms; |
166 |
> |
for (j = 0 ; j < add_atoms; j++ ) { |
167 |
> |
atomIndex++; |
168 |
> |
AtomToProcMap[atomIndex] = which_proc; |
169 |
> |
} |
170 |
> |
done = 1; |
171 |
> |
continue; |
172 |
> |
} |
173 |
> |
|
174 |
> |
// The only situation left is where old_atoms < nTarget, but |
175 |
> |
// new_atoms > nTarget. We want to accept this with some |
176 |
> |
// probability that dies off the farther we are from nTarget |
177 |
> |
|
178 |
> |
// roughly: x = new_atoms - nTarget |
179 |
> |
// Pacc(x) = exp(- a * x) |
180 |
> |
// where a = 1 / (average atoms per molecule) |
181 |
> |
|
182 |
> |
x = (double) (new_atoms - nTarget); |
183 |
> |
y = myRandom.getRandom(); |
184 |
> |
|
185 |
> |
if (exp(- a * x) > y) { |
186 |
> |
MolToProcMap[i] = which_proc; |
187 |
> |
AtomsPerProc[which_proc] += add_atoms; |
188 |
> |
for (j = 0 ; j < add_atoms; j++ ) { |
189 |
> |
atomIndex++; |
190 |
> |
AtomToProcMap[atomIndex] = which_proc; |
191 |
> |
} |
192 |
> |
done = 1; |
193 |
> |
continue; |
194 |
> |
} else { |
195 |
> |
continue; |
196 |
> |
} |
197 |
> |
|
198 |
> |
} |
199 |
|
} |
200 |
+ |
|
201 |
+ |
// Spray out this nonsense to all other processors: |
202 |
+ |
|
203 |
+ |
MPI::COMM_WORLD.Bcast(&MolToProcMap, mpiPlug->nMolGlobal, |
204 |
+ |
MPI_INT, 0); |
205 |
+ |
|
206 |
+ |
MPI::COMM_WORLD.Bcast(&AtomToProcMap, mpiPlug->nAtomsGlobal, |
207 |
+ |
MPI_INT, 0); |
208 |
+ |
|
209 |
+ |
MPI::COMM_WORLD.Bcast(&MolComponentType, mpiPlug->nMolGlobal, |
210 |
+ |
MPI_INT, 0); |
211 |
+ |
|
212 |
+ |
MPI::COMM_WORLD.Bcast(&AtomsPerProc, mpiPlug->numberProcessors, |
213 |
+ |
MPI_INT, 0); |
214 |
+ |
} else { |
215 |
+ |
|
216 |
+ |
// Listen to your marching orders from processor 0: |
217 |
+ |
|
218 |
+ |
MPI::COMM_WORLD.Bcast(&MolToProcMap, mpiPlug->nMolGlobal, |
219 |
+ |
MPI_INT, 0); |
220 |
+ |
|
221 |
+ |
MPI::COMM_WORLD.Bcast(&AtomToProcMap, mpiPlug->nAtomsGlobal, |
222 |
+ |
MPI_INT, 0); |
223 |
+ |
|
224 |
+ |
MPI::COMM_WORLD.Bcast(&MolComponentType, mpiPlug->nMolGlobal, |
225 |
+ |
MPI_INT, 0); |
226 |
+ |
|
227 |
+ |
MPI::COMM_WORLD.Bcast(&AtomsPerProc, mpiPlug->numberProcessors, |
228 |
+ |
MPI_INT, 0); |
229 |
|
} |
230 |
|
|
231 |
+ |
|
232 |
+ |
// Let's all check for sanity: |
233 |
+ |
|
234 |
+ |
nmol_local = 0; |
235 |
+ |
for (i = 0 ; i < mpiPlug->nMolGlobal; i++ ) { |
236 |
+ |
if (MolToProcMap[i] == mpiPlug->myNode) { |
237 |
+ |
nmol_local++; |
238 |
+ |
} |
239 |
+ |
} |
240 |
+ |
|
241 |
+ |
natoms_local = 0; |
242 |
+ |
for (i = 0; i < mpiPlug->nAtomsGlobal; i++) { |
243 |
+ |
if (AtomToProcMap[i] == mpiPlug->myNode) { |
244 |
+ |
natoms_local++; |
245 |
+ |
} |
246 |
+ |
} |
247 |
+ |
|
248 |
+ |
MPI::COMM_WORLD.Allreduce(&nmol_local,&nmol_global,1,MPI_INT,MPI_SUM); |
249 |
+ |
MPI::COMM_WORLD.Allreduce(&natoms_local,&natoms_global,1,MPI_INT,MPI_SUM); |
250 |
+ |
|
251 |
+ |
if( nmol_global != entryPlug->n_mol ){ |
252 |
+ |
sprintf( painCave.errMsg, |
253 |
+ |
"The sum of all nmol_local, %d, did not equal the " |
254 |
+ |
"total number of molecules, %d.\n", |
255 |
+ |
nmol_global, entryPlug->n_mol ); |
256 |
+ |
painCave.isFatal = 1; |
257 |
+ |
simError(); |
258 |
+ |
} |
259 |
+ |
|
260 |
+ |
if( natoms_global != entryPlug->n_atoms ){ |
261 |
+ |
sprintf( painCave.errMsg, |
262 |
+ |
"The sum of all natoms_local, %d, did not equal the " |
263 |
+ |
"total number of atoms, %d.\n", |
264 |
+ |
natoms_global, entryPlug->n_atoms ); |
265 |
+ |
painCave.isFatal = 1; |
266 |
+ |
simError(); |
267 |
+ |
} |
268 |
+ |
|
269 |
|
sprintf( checkPointMsg, |
270 |
|
"Successfully divided the molecules among the processors.\n" ); |
271 |
|
MPIcheckPoint(); |
272 |
|
|
273 |
< |
// lets create the identity array |
273 |
> |
mpiPlug->myNMol = nmol_local; |
274 |
> |
mpiPlug->myNlocal = natoms_local; |
275 |
|
|
276 |
|
globalIndex = new int[mpiPlug->myNlocal]; |
277 |
< |
index = mpiPlug->myAtomStart; |
278 |
< |
for( i=0; i<mpiPlug->myNlocal; i++){ |
279 |
< |
globalIndex[i] = index; |
280 |
< |
index++; |
277 |
> |
local_index = 0; |
278 |
> |
for (i = 0; i < mpiPlug->nAtomsGlobal; i++) { |
279 |
> |
if (AtomToProcMap[i] == mpiPlug->myNode) { |
280 |
> |
globalIndex[local_index] = |
281 |
> |
} |
282 |
|
} |
283 |
+ |
|
284 |
|
|
285 |
< |
return globalIndex; |
285 |
> |
|
286 |
> |
|
287 |
> |
index = mpiPlug->myAtomStart; |
288 |
> |
// for( i=0; i<mpiPlug->myNlocal; i++){ |
289 |
> |
// globalIndex[i] = index; |
290 |
> |
// index++; |
291 |
> |
// } |
292 |
> |
|
293 |
> |
// return globalIndex; |
294 |
|
} |
295 |
|
|
296 |
|
|