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yap-6.3/packages/bee/cryptominisat-2.5.1/Solver/MatrixFinder.cpp

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/***********************************************************************************
CryptoMiniSat -- Copyright (c) 2009 Mate Soos
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
**************************************************************************************************/
#include "constants.h"
#ifdef USE_GAUSS
#include "MatrixFinder.h"
#include "Solver.h"
#include "Gaussian.h"
#include "GaussianConfig.h"
#include "ClauseCleaner.h"
#include "time_mem.h"
#include <set>
#include <map>
#include <iomanip>
#include <math.h>
using std::set;
using std::map;
//#define VERBOSE_DEBUG
using std::cout;
using std::endl;
//#define PART_FINDING
MatrixFinder::MatrixFinder(Solver& _solver) :
solver(_solver)
{
}
inline const Var MatrixFinder::fingerprint(const XorClause& c) const
{
Var fingerprint = 0;
for (const Lit* a = &c[0], *end = a + c.size(); a != end; a++)
fingerprint |= a->var();
return fingerprint;
}
inline const bool MatrixFinder::firstPartOfSecond(const XorClause& c1, const XorClause& c2) const
{
uint i1, i2;
for (i1 = 0, i2 = 0; i1 < c1.size() && i2 < c2.size();) {
if (c1[i1].var() != c2[i2].var())
i2++;
else {
i1++;
i2++;
}
}
return (i1 == c1.size());
}
const bool MatrixFinder::findMatrixes()
{
table.clear();
table.resize(solver.nVars(), var_Undef);
reverseTable.clear();
matrix_no = 0;
double myTime = cpuTime();
if (solver.xorclauses.size() < MIN_GAUSS_XOR_CLAUSES ||
solver.gaussconfig.decision_until <= 0 ||
solver.xorclauses.size() > MAX_GAUSS_XOR_CLAUSES
)
return true;
solver.clauseCleaner->cleanClauses(solver.xorclauses, ClauseCleaner::xorclauses);
if (!solver.ok) return false;
if (solver.gaussconfig.noMatrixFind) {
if (solver.verbosity >=1)
cout << "c | Matrix finding disabled through switch. Putting all xors into matrix." << endl;
vector<XorClause*> xorclauses;
xorclauses.reserve(solver.xorclauses.size());
for (uint32_t i = 0; i < solver.xorclauses.size(); i++)
xorclauses.push_back(solver.xorclauses[i]);
solver.gauss_matrixes.push_back(new Gaussian(solver, solver.gaussconfig, 0, xorclauses));
return true;
}
for (XorClause** c = solver.xorclauses.getData(), **end = c + solver.xorclauses.size(); c != end; c++) {
set<uint> tomerge;
vector<Var> newSet;
for (Lit *l = &(**c)[0], *end2 = l + (**c).size(); l != end2; l++) {
if (table[l->var()] != var_Undef)
tomerge.insert(table[l->var()]);
else
newSet.push_back(l->var());
}
if (tomerge.size() == 1) {
const uint into = *tomerge.begin();
map<uint, vector<Var> >::iterator intoReverse = reverseTable.find(into);
for (uint i = 0; i < newSet.size(); i++) {
intoReverse->second.push_back(newSet[i]);
table[newSet[i]] = into;
}
continue;
}
for (set<uint>::iterator it = tomerge.begin(); it != tomerge.end(); it++) {
newSet.insert(newSet.end(), reverseTable[*it].begin(), reverseTable[*it].end());
reverseTable.erase(*it);
}
for (uint i = 0; i < newSet.size(); i++)
table[newSet[i]] = matrix_no;
reverseTable[matrix_no] = newSet;
matrix_no++;
}
#ifdef VERBOSE_DEBUG
for (map<uint, vector<Var> >::iterator it = reverseTable.begin(), end = reverseTable.end(); it != end; it++) {
cout << "-- set begin --" << endl;
for (vector<Var>::iterator it2 = it->second.begin(), end2 = it->second.end(); it2 != end2; it2++) {
cout << *it2 << ", ";
}
cout << "-------" << endl;
}
#endif
uint32_t numMatrixes = setMatrixes();
if (solver.verbosity >=1)
std::cout << "c | Finding matrixes : " << cpuTime() - myTime << " s (found " << numMatrixes << ") |" << endl;
for (vector<Gaussian*>::iterator gauss = solver.gauss_matrixes.begin(), end = solver.gauss_matrixes.end(); gauss != end; gauss++) {
if (!(*gauss)->full_init()) return false;
}
return true;
}
const uint MatrixFinder::setMatrixes()
{
vector<pair<uint, uint> > numXorInMatrix;
for (uint i = 0; i < matrix_no; i++)
numXorInMatrix.push_back(std::make_pair(i, 0));
vector<uint> sumXorSizeInMatrix(matrix_no, 0);
vector<vector<uint> > xorSizesInMatrix(matrix_no);
vector<vector<XorClause*> > xorsInMatrix(matrix_no);
#ifdef PART_FINDING
vector<vector<Var> > xorFingerprintInMatrix(matrix_no);
#endif
for (XorClause** c = solver.xorclauses.getData(), **end = c + solver.xorclauses.size(); c != end; c++) {
XorClause& x = **c;
const uint matrix = table[x[0].var()];
assert(matrix < matrix_no);
//for stats
numXorInMatrix[matrix].second++;
sumXorSizeInMatrix[matrix] += x.size();
xorSizesInMatrix[matrix].push_back(x.size());
xorsInMatrix[matrix].push_back(&x);
#ifdef PART_FINDING
xorFingerprintInMatrix[matrix].push_back(fingerprint(x));
#endif //PART_FINDING
}
std::sort(numXorInMatrix.begin(), numXorInMatrix.end(), mysorter());
#ifdef PART_FINDING
for (uint i = 0; i < matrix_no; i++)
findParts(xorFingerprintInMatrix[i], xorsInMatrix[i]);
#endif //PART_FINDING
uint realMatrixNum = 0;
for (int a = matrix_no-1; a != -1; a--) {
uint i = numXorInMatrix[a].first;
if (numXorInMatrix[a].second < 3)
continue;
const uint totalSize = reverseTable[i].size()*numXorInMatrix[a].second;
const double density = (double)sumXorSizeInMatrix[i]/(double)totalSize*100.0;
double avg = (double)sumXorSizeInMatrix[i]/(double)numXorInMatrix[a].second;
double variance = 0.0;
for (uint i2 = 0; i2 < xorSizesInMatrix[i].size(); i2++)
variance += pow((double)xorSizesInMatrix[i][i2]-avg, 2);
variance /= (double)xorSizesInMatrix.size();
const double stdDeviation = sqrt(variance);
if (numXorInMatrix[a].second >= solver.gaussconfig.minMatrixRows
&& numXorInMatrix[a].second <= solver.gaussconfig.maxMatrixRows
&& realMatrixNum < 3)
{
if (solver.verbosity >=1)
cout << "c | Matrix no " << std::setw(2) << realMatrixNum;
solver.gauss_matrixes.push_back(new Gaussian(solver, solver.gaussconfig, realMatrixNum, xorsInMatrix[i]));
realMatrixNum++;
} else {
if (solver.verbosity >=1 /*&& numXorInMatrix[a].second >= 20*/)
cout << "c | Unused Matrix ";
}
if (solver.verbosity >=1 /*&& numXorInMatrix[a].second >= 20*/) {
cout << std::setw(7) << numXorInMatrix[a].second << " x" << std::setw(5) << reverseTable[i].size();
cout << " density:" << std::setw(5) << std::fixed << std::setprecision(1) << density << "%";
cout << " xorlen avg:" << std::setw(5) << std::fixed << std::setprecision(2) << avg;
cout << " stdev:" << std::setw(6) << std::fixed << std::setprecision(2) << stdDeviation << " |" << endl;
}
}
return realMatrixNum;
}
void MatrixFinder::findParts(vector<Var>& xorFingerprintInMatrix, vector<XorClause*>& xorsInMatrix)
{
uint ai = 0;
for (XorClause **a = &xorsInMatrix[0], **end = a + xorsInMatrix.size(); a != end; a++, ai++) {
const Var fingerprint = xorFingerprintInMatrix[ai];
uint ai2 = 0;
for (XorClause **a2 = &xorsInMatrix[0]; a2 != end; a2++, ai2++) {
if (ai == ai2) continue;
const Var fingerprint2 = xorFingerprintInMatrix[ai2];
if (((fingerprint & fingerprint2) == fingerprint) && firstPartOfSecond(**a, **a2)) {
cout << "First part of second:" << endl;
(*a)->plainPrint();
(*a2)->plainPrint();
cout << "END" << endl;
}
}
}
}
#endif //USE_GAUSS
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