void
V3SVrfIPDR::startVerify2(const uint32_t& p) {
// Initialize Parameters
cerr << "Multi-Step PDR\n";
uint32_t proved = V3NtkUD, fired = V3NtkUD;
struct timeval inittime, curtime; gettimeofday(&inittime, NULL);
clearResult(p); if (profileON()) _totalStat->start(); assert (!_constr.size());
const string flushSpace = string(100, ' ');
setEndline(true);
_maxTime = 900;
// Clear Verification Results
if(_tem_decomp == false) _decompDepth = 1;
if (!reportUnsupportedInitialState()) return;
//printNetlist(_vrfNtk);
V3NtkExpand2* const pNtk = new V3NtkExpand2(_handler, _decompDepth+1, true); assert (pNtk);
_handler->_ntk = pNtk->getNtk();
_vrfNtk = pNtk->getNtk();
//_handler->_latchMap = V3NetTable(_cycle, V3NetVec(parentNets, V3NetUD));
_handler->_latchMap = &(pNtk->_latchMap);
if(_decompDepth >1) _handler->_decDep = _decompDepth;
v3Handler.pushAndSetCurHandler(_handler);
//printNetlist(pNtk->getNtk());
/*for (unsigned i = 0; i < 3; ++i){
for (unsigned j = 0; j < 6; ++j){
cout << _handler->_latchMap->at(i)[j].id << ":" << _handler->_latchMap->at(i)[j].cp << endl;
}
}*/
_pdrGen = new V3AlgAigGeneralize(_handler); assert (_pdrGen);
_pdrSim = dynamic_cast<V3AlgAigSimulate*>(_pdrGen); assert (_pdrSim);
V3NetVec simTargets(1, _vrfNtk->getOutput(p)); _pdrSim->reset2(simTargets);
// Initialize Pattern Input Size
assert (p < _result.size()); assert (p < _vrfNtk->getOutputSize());
const V3NetId& pId = _vrfNtk->getOutput(p); assert (V3NetUD != pId);
_pdrSize = _vrfNtk->getInputSize() + _vrfNtk->getInoutSize();
// Initialize Signal Priority List
if (_pdrPriority.size() != _vrfNtk->getLatchSize()) _pdrPriority.resize(_vrfNtk->getLatchSize());
// Initialize Bad Cube
_pdrBad = new V3SIPDRCube(0); assert (_pdrBad); _pdrBad->setState(V3NetVec(1, pId));
// Initialize Frame 0, Solver 0
_pdrFrame.push_back(new V3SIPDRFrame()); assert (_pdrFrame.size() == 1);
initializeSolver2(0);
assert (_pdrSvr.size() == 1); assert (_pdrSvr.back());
if (_vrfNtk->getLatchSize()) _pdrSvr.back()->assertInit(); // R0 = I0
// Start PDR Based Verification
V3SIPDRCube* badCube = 0;
while (true) {
// Check Time Bounds
gettimeofday(&curtime, NULL);
if (_maxTime < getTimeUsed(inittime, curtime)) break;
// Find a Bad Cube as Initial Proof Obligation
badCube = getInitialObligation(); // SAT(R ^ T ^ !p)
if(heavy_debug){
if(!badCube) cerr << "the Cube is NULL\n";
if(badCube){
cerr << "the Cube is NOT NULL\n";
printState(badCube->getState());
}
}
if (!badCube) {
if (!isIncKeepSilent() && intactON() && frame_info ) {
if (!endLineON()) Msg(MSG_IFO) << "\r" + flushSpace + "\r";
Msg(MSG_IFO) << setw(3) << left << getPDRDepth() << " :";
const uint32_t j = (_pdrFrame.size() > 25) ? _pdrFrame.size() - 25 : 0; if (j) Msg(MSG_IFO) << " ...";
for (uint32_t i = j; i < _pdrFrame.size(); ++i)
Msg(MSG_IFO) << " " << _pdrFrame[i]->getCubeList().size();
Msg(MSG_IFO) << endl; // Always Endline At the End of Each Frame
}
// Set p to the Last Frame
_pdrSvr.back()->assertProperty(pId, true, 0);
// Push New Frame
_pdrFrame.push_back(new V3SIPDRFrame());
initializeSolver2(getPDRDepth());
assert (_pdrSvr.back()); assert (_pdrSvr.size() == _pdrFrame.size());
if (propagateCubes()) {
proved = getPDRDepth(); break;
}
}
else {
badCube = recursiveBlockCube2(badCube);
if (badCube) { fired = getPDRDepth(); break; }
// Interactively Show the Number of Bad Cubes in Frames
if (!isIncKeepSilent() && intactON() && frame_info) {
if (!endLineON()) Msg(MSG_IFO) << "\r" + flushSpace + "\r";
Msg(MSG_IFO) << setw(3) << left << getPDRDepth() << " :";
const uint32_t j = (_pdrFrame.size() > 25) ? _pdrFrame.size() - 25 : 0; if (j) Msg(MSG_IFO) << " ...";
for (uint32_t i = j; i < _pdrFrame.size(); ++i)
Msg(MSG_IFO) << " " << _pdrFrame[i]->getCubeList().size();
if (endLineON()) Msg(MSG_IFO) << endl; else Msg(MSG_IFO) << flush;
}
}
}
// Report Verification Result
if (!isIncKeepSilent() && reportON()) {
uint32_t c_size = 0;
for (uint32_t i = 0; i < _pdrFrame.size(); ++i)
c_size += _pdrFrame[i]->getCubeList().size();
cout << "CubeSize : " << c_size << endl;
if (intactON()) {
if (endLineON()) Msg(MSG_IFO) << endl;
else Msg(MSG_IFO) << "\r" << flushSpace << "\r";
}
if (V3NtkUD != proved) Msg(MSG_IFO) << "Inductive Invariant found at depth = " << ++proved;
else if (V3NtkUD != fired) Msg(MSG_IFO) << "Counter-example found at depth = " << ++fired;
else Msg(MSG_IFO) << "UNDECIDED at depth = " << _maxDepth;
if (usageON()) {
gettimeofday(&curtime, NULL);
Msg(MSG_IFO) << " (time = " << setprecision(5) << getTimeUsed(inittime, curtime) << " sec)" << endl;
}
if (profileON()) {
_totalStat->end();
Msg(MSG_IFO) << *_initSvrStat << endl;
Msg(MSG_IFO) << *_solveStat << endl;
Msg(MSG_IFO) << *_BMCStat << endl;
Msg(MSG_IFO) << *_generalStat << endl;
Msg(MSG_IFO) << *_propagateStat << endl;
Msg(MSG_IFO) << *_ternaryStat << endl;
Msg(MSG_IFO) << *_totalStat << endl;
}
}
// Record CounterExample Trace or Invariant
if (V3NtkUD != fired) { // Record Counter-Example
// Compute PatternCount
const V3SIPDRCube* traceCube = badCube; assert (traceCube);
uint32_t patternCount = 0; while (_pdrBad != traceCube) { traceCube = traceCube->getNextCube(); ++patternCount; }
V3CexTrace* const cex = new V3CexTrace(patternCount); assert (cex);
_result[p].setCexTrace(cex); assert (_result[p].isCex());
// Set Pattern Value
traceCube = badCube; assert (traceCube); assert (existInitial2(traceCube->getState()));
while (_pdrBad != traceCube) {
if (_pdrSize) cex->pushData(traceCube->getInputData());
traceCube = traceCube->getNextCube(); assert (traceCube);
}
const V3SIPDRCube* lastCube; traceCube = badCube;
while (_pdrBad != traceCube) { lastCube = traceCube->getNextCube(); delete traceCube; traceCube = lastCube; }
}
else if (V3NtkUD != proved) { // Record Inductive Invariant
_result[p].setIndInv(_vrfNtk); assert (_result[p].isInv());
// Put the Inductive Invariant to the Last Frame
uint32_t f = 1; for (; f < getPDRDepth(); ++f) if (!_pdrFrame[f]->getCubeList().size()) break;
assert (f < getPDRDepth());
for (uint32_t i = 1 + f; i < getPDRDepth(); ++i) {
const V3SIPDRCubeList& cubeList = _pdrFrame[i]->getCubeList(); V3SIPDRCubeList::const_iterator it;
for (it = cubeList.begin(); it != cubeList.end(); ++it) _pdrFrame.back()->pushCube(*it);
_pdrFrame[i]->clearCubeList(); delete _pdrFrame[i]; delete _pdrSvr[i];
}
// Remove Empty Frames
_pdrFrame[f] = _pdrFrame.back(); while ((1 + f) != _pdrFrame.size()) _pdrFrame.pop_back();
_pdrFrame.back()->removeSelfSubsumed(); delete _pdrSvr.back(); while ((1 + f) != _pdrSvr.size()) _pdrSvr.pop_back();
}
}
// Verification Main Functions
void
V3VrfSIM::startVerify(const uint32_t& pIndex) {
// Initialize
V3Ntk* const ntk = _handler->getNtk(); assert (ntk);
V3AlgSimulate* simulator = 0;
if (dynamic_cast<V3BvNtk*>(ntk)) simulator = new V3AlgBvSimulate(_handler);
else simulator = new V3AlgAigSimulate(_handler); assert (simulator);
const V3NetId& pId = ntk->getOutput(pIndex); assert (V3NetUD != pId);
const uint32_t logMaxWidth = (uint32_t)(ceil(log10(_maxDepth)));
const string flushSpace = string(100, ' ');
uint32_t cycle = V3NtkUD, cycleReached = 0;
double runtime = clock(), timeBound = clock() + (CLOCKS_PER_SEC * _maxTime);
// Start SIM Based Verification
const uint32_t Cycle = 10000;
uint32_t i = 0, j = 0;
for (uint32_t k = 0, n = (uint32_t)(ceil(_maxDepth / Cycle)); k < n; ++k) {
j = Cycle + i; if (j > _maxDepth) j = _maxDepth;
for (i = Cycle * k; i < j; ++i) {
// Update FF Next State Values
simulator->updateNextStateValue();
// Purely Random Simulation
simulator->setSourceFree(V3_PI, true);
simulator->setSourceFree(V3_PIO, true);
// Simulate for One Cycle
simulator->simulate();
// Record Simulation Data
simulator->recordSimValue();
// Check if Property Asserted
if (simulator->getSimValue(pId).exist1()) { cycle = i; break; }
}
if (V3NtkUD != cycle) break;
// Report Verification Progress
if (intactON()) {
if (!endLineON()) Msg(MSG_IFO) << "\r" + flushSpace + "\r";
Msg(MSG_IFO) << "Simulation completed under cycle = " << setw(logMaxWidth) << i;
if (endLineON()) Msg(MSG_IFO) << endl; else Msg(MSG_IFO) << flush;
// Check if Time Bound Reached
if (clock() >= timeBound) { cycleReached = i; break; }
}
}
// Report Verification Result
if (reportON()) {
runtime = (clock()- runtime) / CLOCKS_PER_SEC;
if (intactON()) {
if (endLineON()) Msg(MSG_IFO) << endl;
else Msg(MSG_IFO) << "\r" << flushSpace << "\r";
}
if (V3NtkUD != cycle) Msg(MSG_IFO) << "Counter-example found at cycle = " << ++cycle;
else Msg(MSG_IFO) << "UNDECIDED at cycle = " << ((clock() >= timeBound) ? cycleReached : _maxDepth);
if (usageON()) Msg(MSG_IFO) << " (time = " << setprecision(5) << runtime << " sec)" << endl;
if (profileON()) { /* Report some profiling here ... */ }
}
// Record CounterExample Trace
if (V3NtkUD == cycle) return;
// Compute Pattern Size and Initialize Trace
V3CexTrace* const cex = new V3CexTrace(cycle); assert (cex);
_result[pIndex].setCexTrace(cex); assert (_result[pIndex].isCex());
uint32_t patternSize = 0;
for (uint32_t i = 0; i < ntk->getInputSize(); ++i) patternSize += ntk->getNetWidth(ntk->getInput(i));
for (uint32_t i = 0; i < ntk->getInoutSize(); ++i) patternSize += ntk->getNetWidth(ntk->getInout(i));
if (!patternSize) return;
// Record Counter-Example
V3SimTrace pattern(ntk->getInputSize()); V3BitVecX trace(patternSize);
if (dynamic_cast<V3BvNtk*>(ntk)) {
for (uint32_t i = 0; i < cycle; ++i) {
simulator->getSimRecordData(i, pattern);
uint32_t k = 0;
for (uint32_t j = 0; j < ntk->getInputSize(); ++j) {
assert (pattern[j].size() == ntk->getNetWidth(ntk->getInput(j)));
for (uint32_t x = 0; x < pattern[j].size(); ++x, ++k)
if ('1' == pattern[j][x]) trace.set1(k);
else if ('0' == pattern[j][x]) trace.set0(k);
}
for (uint32_t j = 0; j < ntk->getInoutSize(); ++j) {
assert (pattern[j].size() == ntk->getNetWidth(ntk->getInout(j)));
for (uint32_t x = 0; x < pattern[j].size(); ++x, ++k)
if ('1' == pattern[j][x]) trace.set1(k);
else if ('0' == pattern[j][x]) trace.set0(k);
}
cex->pushData(trace); trace.clear();
}
}
else {
const uint32_t p = simulator->getSimValue(pId).first1(); assert (p < simulator->getSimValue(pId).size());
assert (pattern.size() == trace.size());
for (uint32_t i = 0; i < cycle; ++i) {
simulator->getSimRecordData(i, pattern);
for (uint32_t j = 0; j < pattern.size(); ++j)
if ('1' == pattern[j][p]) trace.set1(j);
else if ('0' == pattern[j][p]) trace.set0(j);
cex->pushData(trace); trace.clear();
}
}
}
/* ---------------------------------------------------------------------------------------------------- *\
isIncKeepLastReachability(): If the last result is unsat, put the inductive invariant into the last frame.
isIncContinueOnLastSolver(): Reset the solver.
\* ---------------------------------------------------------------------------------------------------- */
void
V3VrfMPDR::startVerify(const uint32_t& p) {
vrfRestart:
// Check Shared Results
if (_sharedBound && V3NtkUD == _sharedBound->getBound(p)) return;
// Clear Verification Results
clearResult(p); if (profileON()) _totalStat->start();
// Consistency Check
consistencyCheck(); assert (!_constr.size());
if (!reportUnsupportedInitialState()) return;
// Initialize Backup Frames
for (uint32_t i = 0; i < _pdrBackup.size(); ++i) delete _pdrBackup[i]; _pdrBackup.clear();
if (_pdrFrame.size()) {
if (isIncKeepLastReachability()) {
// Backup frames in the order: ..., 2, 1, INF
assert (_pdrFrame.size() > 1); _pdrBackup.reserve(_pdrFrame.size() - 1);
for (uint32_t i = _pdrFrame.size() - 2; i > 0; --i) _pdrBackup.push_back(_pdrFrame[i]);
_pdrBackup.push_back(_pdrFrame.back()); delete _pdrFrame[0];
}
else { for (uint32_t i = 0; i < _pdrFrame.size(); ++i) delete _pdrFrame[i]; } _pdrFrame.clear();
}
// Initialize Other Members
if (!isIncKeepLastReachability()) _pdrPriority.clear(); _pdrActCount = 0;
if (_pdrBad) delete _pdrBad; _pdrBad = 0; if (_pdrGen) delete _pdrGen; _pdrGen = 0;
if (dynamic_cast<V3BvNtk*>(_vrfNtk)) {
_pdrGen = new V3AlgBvGeneralize(_handler); assert (_pdrGen);
_pdrSim = dynamic_cast<V3AlgBvSimulate*>(_pdrGen); assert (_pdrSim);
}
else {
_pdrGen = new V3AlgAigGeneralize(_handler); assert (_pdrGen);
_pdrSim = dynamic_cast<V3AlgAigSimulate*>(_pdrGen); assert (_pdrSim);
}
V3NetVec simTargets(1, _vrfNtk->getOutput(p)); _pdrSim->reset(simTargets);
// Initialize Pattern Input Size
assert (p < _result.size()); assert (p < _vrfNtk->getOutputSize());
const V3NetId& pId = _vrfNtk->getOutput(p); assert (V3NetUD != pId);
_pdrSize = _vrfNtk->getInputSize() + _vrfNtk->getInoutSize();
// Initialize Parameters
const string flushSpace = string(100, ' ');
uint32_t proved = V3NtkUD, fired = V3NtkUD;
struct timeval inittime, curtime; gettimeofday(&inittime, NULL);
// Initialize Signal Priority List
if (_pdrPriority.size() != _vrfNtk->getLatchSize()) _pdrPriority.resize(_vrfNtk->getLatchSize(), 0);
// Initialize Solver
if (_pdrSvr && !isIncContinueOnLastSolver()) { delete _pdrSvr; _pdrSvr = 0; } initializeSolver();
// Initialize Bad Cube
_pdrBad = new V3MPDRCube(0); assert (_pdrBad); _pdrBad->setState(V3NetVec(1, pId));
// Initialize Frame 0
if (_vrfNtk->getLatchSize()) _pdrFrame.push_back(new V3MPDRFrame(_pdrSvr->setImplyInit())); // R0 = I0
else _pdrFrame.push_back(new V3MPDRFrame(_pdrSvr->reserveFormula()));
assert (_pdrFrame.back()->getActivator()); assert (_pdrFrame.size() == 1);
// Initialize Frame INF
if (_pdrBackup.size()) { _pdrFrame.push_back(_pdrBackup.back()); _pdrBackup.pop_back(); addFrameInfoToSolver(1); }
else _pdrFrame.push_back(new V3MPDRFrame(_pdrSvr->reserveFormula()));
assert (_pdrFrame.back()->getActivator()); assert (_pdrFrame.size() == 2);
// Check Shared Invariants
if (_sharedInv) {
V3NetTable sharedInv; _sharedInv->getInv(sharedInv);
for (uint32_t i = 0; i < sharedInv.size(); ++i) {
V3MPDRCube* const inv = new V3MPDRCube(0); assert (inv);
inv->setState(sharedInv[i]); addBlockedCube(make_pair(getPDRFrame(), inv));
}
}
// Continue on the Last Depth
while (_pdrBackup.size() && (getIncLastDepthToKeepGoing() > getPDRFrame())) {
_pdrFrame.push_back(_pdrFrame.back()); // Keep frame INF the last frame
_pdrFrame[_pdrFrame.size() - 2] = _pdrBackup.back(); _pdrBackup.pop_back();
addFrameInfoToSolver(_pdrFrame.size() - 2);
}
// Start PDR Based Verification
V3MPDRCube* badCube = 0;
while (true) {
// Check Time Bounds
gettimeofday(&curtime, NULL);
if (_maxTime < getTimeUsed(inittime, curtime)) break;
// Check Shared Results
if (_sharedBound && (V3NtkUD == _sharedBound->getBound(p))) break;
// Check Shared Networks
if (_sharedNtk) {
V3NtkHandler* const sharedNtk = _sharedNtk->getNtk(_handler);
if (sharedNtk) {
setIncKeepLastReachability(true); setIncContinueOnLastSolver(false); setIncLastDepthToKeepGoing(getPDRDepth());
_handler = sharedNtk; _vrfNtk = sharedNtk->getNtk(); goto vrfRestart;
}
}
// Find a Bad Cube as Initial Proof Obligation
badCube = getInitialObligation(); // SAT(R ^ T ^ !p)
if (!badCube) {
if (!isIncKeepSilent() && intactON()) {
if (!endLineON()) Msg(MSG_IFO) << "\r" + flushSpace + "\r";
Msg(MSG_IFO) << setw(3) << left << getPDRDepth() << " :";
const uint32_t j = (_pdrFrame.size() > 25) ? _pdrFrame.size() - 25 : 0; if (j) Msg(MSG_IFO) << " ...";
for (uint32_t i = j; i < _pdrFrame.size(); ++i)
Msg(MSG_IFO) << " " << _pdrFrame[i]->getCubeList().size();
if (svrInfoON()) { Msg(MSG_IFO) << " ("; _pdrSvr->printInfo(); Msg(MSG_IFO) << ")"; }
Msg(MSG_IFO) << endl; // Always Endline At the End of Each Frame
}
if (_sharedBound) _sharedBound->updateBound(p, getPDRFrame());
// Push New Frame
_pdrFrame.push_back(_pdrFrame.back()); // Renders F Infinity to be the last in _pdrFrame
if (_pdrBackup.size()) {
_pdrFrame[_pdrFrame.size() - 2] = _pdrBackup.back(); _pdrBackup.pop_back();
addFrameInfoToSolver(_pdrFrame.size() - 2);
}
else _pdrFrame[_pdrFrame.size() - 2] = new V3MPDRFrame(_pdrSvr->reserveFormula()); // New Frame
if (propagateCubes()) { proved = getPDRDepth(); break; }
if (_maxDepth <= (getPDRFrame() - 1)) break;
}
else {
badCube = recursiveBlockCube(badCube);
if (badCube) { fired = getPDRDepth(); break; }
// Interactively Show the Number of Bad Cubes in Frames
if (!isIncKeepSilent() && intactON()) {
if (!endLineON()) Msg(MSG_IFO) << "\r" + flushSpace + "\r";
Msg(MSG_IFO) << setw(3) << left << getPDRDepth() << " :";
const uint32_t j = (_pdrFrame.size() > 25) ? _pdrFrame.size() - 25 : 0; if (j) Msg(MSG_IFO) << " ...";
for (uint32_t i = j; i < _pdrFrame.size(); ++i)
Msg(MSG_IFO) << " " << _pdrFrame[i]->getCubeList().size();
if (svrInfoON()) { Msg(MSG_IFO) << " ("; _pdrSvr->printInfo(); Msg(MSG_IFO) << ")"; }
if (endLineON()) Msg(MSG_IFO) << endl; else Msg(MSG_IFO) << flush;
}
}
}
// Report Verification Result
if (!isIncKeepSilent() && reportON()) {
if (intactON()) {
if (endLineON()) Msg(MSG_IFO) << endl;
else Msg(MSG_IFO) << "\r" << flushSpace << "\r";
}
if (V3NtkUD != proved) Msg(MSG_IFO) << "Inductive Invariant found at depth = " << ++proved;
else if (V3NtkUD != fired) Msg(MSG_IFO) << "Counter-example found at depth = " << ++fired;
else Msg(MSG_IFO) << "UNDECIDED at depth = " << _maxDepth;
if (usageON()) {
gettimeofday(&curtime, NULL);
Msg(MSG_IFO) << " (time = " << setprecision(5) << getTimeUsed(inittime, curtime) << " sec)" << endl;
}
if (profileON()) {
_totalStat->end();
Msg(MSG_IFO) << *_initSvrStat << endl;
Msg(MSG_IFO) << *_solveStat << endl;
Msg(MSG_IFO) << *_generalStat << endl;
Msg(MSG_IFO) << *_propagateStat << endl;
Msg(MSG_IFO) << *_ternaryStat << endl;
Msg(MSG_IFO) << *_totalStat << endl;
}
}
// Record CounterExample Trace or Invariant
if (V3NtkUD != fired) { // Record Counter-Example
// Compute PatternCount
const V3MPDRCube* traceCube = badCube; assert (traceCube); assert (existInitial(traceCube->getState()));
uint32_t patternCount = 0; while (_pdrBad != traceCube) { traceCube = traceCube->getNextCube(); ++patternCount; }
V3CexTrace* const cex = new V3CexTrace(patternCount); assert (cex);
_result[p].setCexTrace(cex); assert (_result[p].isCex());
// Set Pattern Value
traceCube = badCube; assert (traceCube); assert (existInitial(traceCube->getState()));
while (_pdrBad != traceCube) {
if (_pdrSize) cex->pushData(traceCube->getInputData());
traceCube = traceCube->getNextCube(); assert (traceCube);
}
// Set Initial State Value
if (_pdrInitValue.size()) {
V3BitVecX initValue(_pdrInitValue.size());
for (uint32_t i = 0; i < badCube->getState().size(); ++i) {
assert (initValue.size() > badCube->getState()[i].id);
if (badCube->getState()[i].cp) initValue.set0(badCube->getState()[i].id);
else initValue.set1(badCube->getState()[i].id);
}
for (uint32_t i = 0; i < _pdrInitValue.size(); ++i)
if (_pdrInitConst[i]) { if (_pdrInitValue[i]) initValue.set0(i); else initValue.set1(i); }
cex->setInit(initValue);
}
// Delete Cubes on the Trace
const V3MPDRCube* lastCube; traceCube = badCube;
while (_pdrBad != traceCube) { lastCube = traceCube->getNextCube(); delete traceCube; traceCube = lastCube; }
// Check Common Results
if (isIncVerifyUsingCurResult()) checkCommonCounterexample(p, *cex);
}
else if (V3NtkUD != proved) { // Record Inductive Invariant
_result[p].setIndInv(_vrfNtk); assert (_result[p].isInv());
// Put the Inductive Invariant to Frame INF
uint32_t f = 1; for (; f < getPDRDepth(); ++f) if (!_pdrFrame[f]->getCubeList().size()) break;
assert (f < getPDRDepth());
for (uint32_t i = 1 + f; i < getPDRFrame(); ++i) {
const V3MPDRCubeList& cubeList = _pdrFrame[i]->getCubeList(); V3MPDRCubeList::const_iterator it;
for (it = cubeList.begin(); it != cubeList.end(); ++it) addBlockedCube(make_pair(getPDRFrame(), *it));
_pdrFrame[i]->clearCubeList(); delete _pdrFrame[i];
}
// Remove Empty Frames
_pdrFrame.back()->removeSelfSubsumed();
_pdrFrame[f] = _pdrFrame.back(); while ((1 + f) != _pdrFrame.size()) _pdrFrame.pop_back();
// Check Common Results
if (isIncVerifyUsingCurResult()) {
const V3MPDRCubeList& invCubeList = _pdrFrame.back()->getCubeList();
V3NetTable invList; invList.clear(); invList.reserve(invCubeList.size());
for (V3MPDRCubeList::const_iterator it = invCubeList.begin(); it != invCubeList.end(); ++it)
invList.push_back((*it)->getState()); checkCommonProof(p, invList, false);
}
}
}
// Private Verification Main Functions
void
V3VrfUMC::startVerify(const uint32_t& pIndex) {
// Consistency Check
if (_preDepth > _maxDepth) _maxDepth = _preDepth; assert (_maxDepth >= _preDepth);
if (_incDepth && ((_maxDepth - _preDepth) % _incDepth)) _maxDepth -= (_maxDepth - _preDepth) % _incDepth;
assert (!_incDepth || !((_maxDepth - _preDepth) % _incDepth)); assert (_maxDepth >= _preDepth);
if ((_maxDepth > _preDepth) && !_incDepth) _maxDepth = _preDepth;
// Initialize
V3Ntk* const ntk = _handler->getNtk(); assert (ntk);
if (_solver) delete _solver; _solver = allocSolver(getSolver(), ntk);
assert (_solver); assert (_solver->totalSolves() == 0);
assert (pIndex < _result.size()); assert (pIndex < ntk->getOutputSize());
const V3NetId& pId = ntk->getOutput(pIndex); assert (V3NetUD != pId);
const uint32_t logMaxWidth = (uint32_t)(ceil(log10(_maxDepth)));
const string flushSpace = string(100, ' ');
uint32_t proved = V3NtkUD, fired = V3NtkUD;
double runtime = clock();
uint32_t boundDepth = _preDepth ? _preDepth : _incDepth;
// Solver Data
V3SvrData pFormulaData; V3PtrVec pFormula;
pFormula.reserve((_preDepth > _incDepth) ? _preDepth : _incDepth);
// Start UMC Based Verification
for (uint32_t i = 0, j = _maxDepth; i < j; ++i) {
// Add time frame expanded circuit to SAT Solver
_solver->addBoundedVerifyData(pId, i); pFormula.push_back(_solver->getFormula(pId, i));
// Check if the bound is achieved
if ((1 + i) < boundDepth) continue; assert ((1 + i) == boundDepth);
assert ((1 + i) >= pFormula.size()); boundDepth += _incDepth;
// Add assume for assumption solve only
_solver->assumeRelease();
if (1 == pFormula.size()) _solver->assumeProperty(pId, false, i);
else {
pFormulaData = _solver->setImplyUnion(pFormula);
assert (pFormulaData); _solver->assumeProperty(pFormulaData);
}
_solver->simplify();
// Report Verification Progress
if (intactON()) {
if (!endLineON()) Msg(MSG_IFO) << "\r" + flushSpace + "\r";
Msg(MSG_IFO) << "Verification completed under depth = " << setw(logMaxWidth) << (i + 1);
if (svrInfoON()) { Msg(MSG_IFO) << " ("; _solver->printInfo(); Msg(MSG_IFO) << ")"; }
if (endLineON()) Msg(MSG_IFO) << endl; else Msg(MSG_IFO) << flush;
}
// Assumption Solve : If UNSAT, proved!
if (!isFireOnly() && !_solver->assump_solve()) {
if (!isProveOnly()) {
proved = i; break;
}
}
// Assumption Solve : If SAT, disproved!
if (!isProveOnly()) {
_solver->assumeInit(); // Conjunction with initial condition
if (_solver->assump_solve()) {
for (uint32_t k = 0; k < pFormula.size(); ++k)
if ('0' != _solver->getDataValue(pFormula[k])) {
fired = (1 + i + k - pFormula.size()); break;
}
assert (V3NtkUD != fired); break;
}
}
// Add assert back to the property
if (1 < pFormula.size()) { assert (pFormulaData); _solver->assertProperty(pFormulaData, true); }
for (uint32_t k = i - pFormula.size(); k < i; ++k) _solver->assertProperty(pId, true, k);
pFormula.clear(); pFormulaData = 0;
}
// Report Verification Result
if (reportON()) {
runtime = (clock() - runtime) / CLOCKS_PER_SEC;
if (intactON()) {
if (endLineON()) Msg(MSG_IFO) << endl;
else Msg(MSG_IFO) << "\r" << flushSpace << "\r";
}
if (V3NtkUD != proved) Msg(MSG_IFO) << "Inductive Invariant found at depth = " << ++proved;
else if (V3NtkUD != fired) Msg(MSG_IFO) << "Counter-example found at depth = " << ++fired;
else Msg(MSG_IFO) << "UNDECIDED at depth = " << _maxDepth;
if (usageON()) Msg(MSG_IFO) << " (time = " << setprecision(5) << runtime << " sec)" << endl;
if (profileON()) { /* Report some profiling here ... */ }
}
else {
if (V3NtkUD != proved) ++proved;
else if (V3NtkUD != fired) ++fired;
}
// Record CounterExample Trace or Invariant
if (V3NtkUD != fired) { // Record Counter-Example
V3CexTrace* const cex = new V3CexTrace(fired); assert (cex);
_result[pIndex].setCexTrace(cex); assert (_result[pIndex].isCex());
// Compute Pattern Size (PI + PIO)
uint32_t patternSize = 0;
for (uint32_t i = 0; i < ntk->getInputSize(); ++i) patternSize += ntk->getNetWidth(ntk->getInput(i));
for (uint32_t i = 0; i < ntk->getInoutSize(); ++i) patternSize += ntk->getNetWidth(ntk->getInout(i));
// Set Pattern Value (PI + PIO)
V3BitVecX dataValue, patternValue(patternSize ? patternSize : 1);
for (uint32_t i = 0; i < fired; ++i) {
patternSize = 0; patternValue.clear();
for (uint32_t j = 0; j < ntk->getInputSize(); ++j) {
if (_solver->existVerifyData(ntk->getInput(j), i)) {
dataValue = _solver->getDataValue(ntk->getInput(j), i);
assert (dataValue.size() == ntk->getNetWidth(ntk->getInput(j)));
for (uint32_t k = 0; k < dataValue.size(); ++k, ++patternSize) {
if ('0' == dataValue[k]) patternValue.set0(patternSize);
else if ('1' == dataValue[k]) patternValue.set1(patternSize);
}
}
else patternSize += ntk->getNetWidth(ntk->getInput(j));
}
for (uint32_t j = 0; j < ntk->getInoutSize(); ++j) {
if (_solver->existVerifyData(ntk->getInout(j), i)) {
dataValue = _solver->getDataValue(ntk->getInout(j), i);
assert (dataValue.size() == ntk->getNetWidth(ntk->getInout(j)));
for (uint32_t k = 0; k < dataValue.size(); ++k, ++patternSize) {
if ('0' == dataValue[k]) patternValue.set0(patternSize);
else if ('1' == dataValue[k]) patternValue.set1(patternSize);
}
}
else patternSize += ntk->getNetWidth(ntk->getInout(j));
}
assert (_solver->existVerifyData(pId, i));
assert (!patternSize || patternSize == patternValue.size()); cex->pushData(patternValue);
}
}
else if (V3NtkUD != proved) { // Record Inductive Invariant
_result[pIndex].setIndInv(ntk); assert (_result[pIndex].isInv());
}
}
