// General Level Computation Functions for V3 Ntk
void dfsComputeLevel(V3Ntk* const ntk, V3NetVec& orderMap, V3UI32Vec& levelData) {
assert (ntk); assert (orderMap.size() <= ntk->getNetSize());
assert (levelData.size() == ntk->getNetSize());
// Set Net Levels According to the DFS Order
V3NetId id, id1; V3GateType type; uint32_t inSize;
for (uint32_t i = 0; i < orderMap.size(); ++i) {
id = orderMap[i]; assert (id.id < levelData.size());
if (V3NtkUD != levelData[id.id]) continue; levelData[id.id] = 0;
type = ntk->getGateType(id); assert (V3_XD > type); assert (V3_PI == type || V3_FF < type);
if (V3_MODULE == type) {
V3NtkModule* const moduleNtk = ntk->getModule(id); assert (moduleNtk);
const V3NetVec& inputs = moduleNtk->getInputList(); inSize = inputs.size();
while (inSize--) {
id1 = inputs[inSize]; assert (V3NtkUD != levelData[id1.id]);
if (levelData[id.id] < levelData[id1.id]) levelData[id.id] = levelData[id1.id];
}
}
else {
inSize = ntk->getInputNetSize(id); if (BV_SLICE == type || BV_CONST == type) --inSize;
while (inSize--) {
id1 = ntk->getInputNetId(id, inSize); assert (V3NtkUD != levelData[id1.id]);
if (levelData[id.id] < levelData[id1.id]) levelData[id.id] = levelData[id1.id];
}
}
++levelData[id.id];
}
}
void
V3SVrfIPDR::generalizeSimulation2(const uint32_t& d, V3SIPDRCube* const cube, const V3SIPDRCube* const nextCube) {
assert (d < _pdrSvr.size()); assert (cube); assert (nextCube);
assert (nextCube == cube->getNextCube()); assert (_pdrSim);
// Set Values for Simulator
for (uint32_t i = 0; i < _vrfNtk->getInputSize(); ++i) {
if (!_pdrSvr[d]->existVerifyData(_vrfNtk->getInput(i), 0)) _pdrSim->clearSource(_vrfNtk->getInput(i), true);
else _pdrSim->setSource(_vrfNtk->getInput(i), _pdrSvr[d]->getDataValue(_vrfNtk->getInput(i), 0));
}
for (uint32_t i = 0; i < _vrfNtk->getLatchSize(); ++i) {
if (!_pdrSvr[d]->existVerifyData(_vrfNtk->getLatch(i), 0)) _pdrSim->clearSource(_vrfNtk->getLatch(i), true);
else _pdrSim->setSource(_vrfNtk->getLatch(i), _pdrSvr[d]->getDataValue(_vrfNtk->getLatch(i), 0));
}
_pdrSim->simulate();
// Perform SAT Generalization
if (_pdrBad != nextCube) _pdrGen->setTargetNets2(V3NetVec(), nextCube->getState(), _decompDepth);
else {
V3NetVec constrCube(1, nextCube->getState()[0]);
assert (1 == nextCube->getState().size()); _pdrGen->setTargetNets(constrCube);
}
// Set Priority
V3UI32Vec prioNets; prioNets.clear(); prioNets.reserve(_pdrPriority.size());
for (uint32_t i = 0; i < _pdrPriority.size(); ++i) if (!_pdrPriority[i]) prioNets.push_back(i);
for (uint32_t i = 0; i < _pdrPriority.size(); ++i) if ( _pdrPriority[i]) prioNets.push_back(i);
//_pdrGen->_tem = true;
_pdrGen->performSetXForNotCOIVars(false); _pdrGen->performXPropForExtensibleVars(prioNets,false);
cube->setState(_pdrGen->getGeneralizationResult());
}
void
V3Handler::setLastHandler() {
assert (getHandlerCount()); if (_curHandlerId == _lastHandlerId) return;
const uint32_t curHandlerId = _curHandlerId; assert (getHandler(curHandlerId));
V3UI32Vec curRefIdVec = _curRefIdVec; assert (curRefIdVec.size());
_curHandlerId = _lastHandlerId; _curRefIdVec = _lastRefIdVec;
_lastHandlerId = curHandlerId; _lastRefIdVec = curRefIdVec;
}
void
V3NtkElaborate::elaborateFSMInvariants(V3FSM* const fsm, V3NetVec& constrList) {
// NOTE: We add constraints follow the reachability, and
// For FSM with Milestones, we also add constraints follows the milestones.
assert (fsm); assert (_handler == fsm->getNtkHandler());
constrList.clear(); if (!_ntk || !_p2cMap.size()) return;
// Omit FSM Without Invariants: Every milestone is reachable from any states
if (!fsm->getStateSize()) return;
uint32_t comb = 0, seq = 0;
// Extract Combinational Invariants : G (state != some forward unreachable state)
V3NetId id1; V3NetVec stateNets; V3UI32Vec reachStates; V3InputVec inputs(2);
V3BvNtk* const bvNtk = dynamic_cast<V3BvNtk*>(_ntk);
for (uint32_t j = 0; j < fsm->getStateSize(); ++j) {
if (V3NtkUD != fsm->getStepFwdFromInit(j)) continue;
stateNets.clear(); fsm->getStateNetId(j, stateNets); assert (stateNets.size());
attachToNtk(_handler, _ntk, stateNets, _p2cMap, _c2pMap, _netHash); assert (_ntk);
id1 = elaborateFSMState(stateNets, false); assert (id1.id < _ntk->getNetSize());
constrList.push_back(~id1); ++comb;
}
// Elaborate Sequential Invariants : nextOpState -> (j -> Prev(OR (reachStates)))
const bool hasMileStone = fsm->getMileStoneSize();
if (hasMileStone) {
for (uint32_t j = 0; j < fsm->getStateSize(); ++j) {
if (!fsm->isMileStone(j)) continue;
assert (V3NtkUD != fsm->getStepBwdFromTerm(j));
fsm->getStateBwdReachable(j, reachStates, true);
if (fsm->getStateSize() == reachStates.size()) continue;
if (fsm->getStateSize() < (reachStates.size() << 2)) continue;
stateNets.clear(); fsm->getStateNetId(j, stateNets); assert (stateNets.size());
attachToNtk(_handler, _ntk, stateNets, _p2cMap, _c2pMap, _netHash); assert (_ntk);
id1 = elaborateFSMState(stateNets, false); assert (id1.id < _ntk->getNetSize());
inputs[0] = ~id1;
for (uint32_t k = 0; k < reachStates.size(); ++k) {
stateNets.clear(); fsm->getStateNetId(reachStates[k], stateNets); assert (stateNets.size());
attachToNtk(_handler, _ntk, stateNets, _p2cMap, _c2pMap, _netHash); assert (_ntk);
id1 = elaborateFSMState(stateNets, true); assert (id1.id < _ntk->getNetSize());
inputs[0] = ~(inputs[0].id); inputs[1] = ~id1; ++seq;
inputs[0] = bvNtk ? ~elaborateBvGate(bvNtk, BV_AND, inputs, _netHash)
: ~elaborateAigGate(_ntk, AIG_NODE, inputs, _netHash);
}
// Record Invariants
inputs[0] = ~(inputs[0].id); inputs[1] = _nextOpId; assert (V3NetUD != _nextOpId);
inputs[0] = bvNtk ? ~elaborateBvGate(bvNtk, BV_AND, inputs, _netHash)
: ~elaborateAigGate(_ntk, AIG_NODE, inputs, _netHash);
constrList.push_back(inputs[0].id);
}
}
}
void
V3VrfBase::checkCommonProof(const uint32_t& p, const V3NetTable& invList, const bool& checkInitial) {
assert (_result[p].isInv());
// Collect Unsolved Properties
V3UI32Vec unsolved; unsolved.clear(); unsolved.reserve(_result.size());
for (uint32_t i = 0; i < _result.size(); ++i)
if (!(_result[i].isCex() || _result[i].isInv())) unsolved.push_back(i);
// Check Same Property
const V3NetId pId = _vrfNtk->getOutput(p);
for (uint32_t i = 0; i < unsolved.size(); ++i) {
if (pId != _vrfNtk->getOutput(unsolved[i])) continue;
_result[unsolved[i]].setIndInv(_vrfNtk);
unsolved.erase(unsolved.begin() + i); --i;
}
if (!unsolved.size()) return; assert (!_constr.size());
// Create Solver
V3SvrBase* const solver = allocSolver(getSolver(), _vrfNtk); assert (solver);
V3SvrDataVec formula; formula.clear(); V3NetId id; uint32_t d = 0;
// Set Inductive Invariant
for (uint32_t i = 0; i < invList.size(); ++i) {
formula.clear(); formula.reserve(invList[i].size());
for (uint32_t j = 0; j < invList[i].size(); ++j) {
id = invList[i][j]; assert (_vrfNtk->getLatchSize() > id.id); assert (!d);
if (!solver->existVerifyData(_vrfNtk->getLatch(id.id), d))
solver->addBoundedVerifyData(_vrfNtk->getLatch(id.id), d);
assert (solver->existVerifyData(_vrfNtk->getLatch(id.id), d));
formula.push_back(solver->getFormula(_vrfNtk->getLatch(id.id), 0, d));
if (!id.cp) formula.back() = solver->getNegFormula(formula.back());
}
solver->assertImplyUnion(formula);
}
if (checkInitial) {
solver->assumeRelease(); solver->assumeInit();
if (solver->assump_solve()) { delete solver; return; }
}
// Check if the bad State Signal is Inconsistent with the Inductive Invariant
for (uint32_t i = 0, j = 0; i < unsolved.size(); ++i) {
solver->assumeRelease(); assert (!d);
if (!solver->existVerifyData(_vrfNtk->getOutput(unsolved[i]), d))
solver->addBoundedVerifyData(_vrfNtk->getOutput(unsolved[i]), d);
assert (solver->existVerifyData(_vrfNtk->getOutput(unsolved[i]), d));
solver->assumeProperty(_vrfNtk->getOutput(unsolved[i]), false, d);
if (!solver->assump_solve()) { _result[unsolved[i]].setIndInv(_vrfNtk); j = 0; }
else if (++j > 100) break; // Avoid Spending Too Much Effort on the Check
}
delete solver;
}
V3Formula::V3Formula(V3NtkHandler* const handler, const uint32_t& constrSize, const uint32_t& maxCard, const V3GateType& gateType, const uint32_t& noPIorFF) : _handler(handler) {
assert (handler); assert (constrSize); assert (maxCard); assert (!(noPIorFF & ~3ul));
assert (BV_AND == gateType || BV_OR == gateType || BV_XOR == gateType || BV_XNOR == gateType);
// Collect Leaf Candidates
V3Ntk* const ntk = handler->getNtk(); assert (ntk);
V3NetVec leafId; leafId.clear(); leafId.reserve(ntk->getInputSize() + ntk->getInoutSize() + ntk->getLatchSize());
if (!(1ul & noPIorFF)) {
for (uint32_t i = 0; i < ntk->getInputSize(); ++i)
if (1 == ntk->getNetWidth(ntk->getInput(i))) leafId.push_back(ntk->getInput(i));
for (uint32_t i = 0; i < ntk->getInoutSize(); ++i)
if (1 == ntk->getNetWidth(ntk->getInout(i))) leafId.push_back(ntk->getInout(i));
}
if (!(2ul & noPIorFF)) {
for (uint32_t i = 0; i < ntk->getLatchSize(); ++i)
if (1 == ntk->getNetWidth(ntk->getLatch(i))) leafId.push_back(ntk->getLatch(i));
}
V3UI32Vec constrId; constrId.clear(); constrId.reserve(constrSize); _formula.clear();
// Create Constraints
for (uint32_t i = 0; i < constrSize; ++i) {
const uint32_t startId = _formula.size();
// Create Leaf Nodes
for (uint32_t j = 0; j < maxCard; ++j) {
if (j && !(rand() % maxCard)) break;
const V3NetId id = (rand() % 5) ? leafId[rand() % leafId.size()] : ~leafId[rand() % leafId.size()];
_formula.push_back(make_pair(V3_PI, V3InputVec())); _formula.back().second.push_back(V3NetType(id));
}
assert (startId < _formula.size());
// Link Leaf Nodes with the Specified GateType
for (uint32_t j = 0, k = _formula.size() - startId; j < k; ++j) {
if (!j) constrId.push_back(startId + j);
else {
_formula.push_back(make_pair(gateType, V3InputVec()));
_formula.back().second.push_back(constrId.back());
_formula.back().second.push_back(startId + j);
constrId.back() = _formula.size() - 1;
}
}
assert ((1 + i) == constrId.size());
}
// Combine Constraints
for (uint32_t i = 0; i < constrId.size(); ++i) {
if (!i) _rootId = constrId[i];
else {
_formula.push_back(make_pair(BV_AND, V3InputVec()));
_formula.back().second.push_back(_rootId);
_formula.back().second.push_back(constrId[i]);
_rootId = _formula.size() - 1;
}
}
}
// Constructor for Random Formula
V3Formula::V3Formula(V3NtkHandler* const handler, const V3SimTraceVec& cexTrace, const double& strength) : _handler(handler) {
assert (handler); assert (cexTrace.size()); assert (strength > 0 && strength <= 1.00);
V3UI32Vec constrId; constrId.clear(); constrId.reserve(cexTrace.size()); _formula.clear();
// Create Constraints
V3Ntk* const ntk = handler->getNtk(); assert (ntk);
for (uint32_t i = 0; i < cexTrace.size(); ++i) {
const uint32_t startId = _formula.size(), end = 1 + (uint32_t)(strength * ntk->getLatchSize());
assert (cexTrace[i].size()); assert (ntk->getLatchSize() == cexTrace[i].size());
for (uint32_t j = 0; j < end; ++j) {
const uint32_t index = rand() % cexTrace[i].size(); assert (1 == ntk->getNetWidth(ntk->getLatch(index)));
const V3NetId id = ('0' == cexTrace[i][index][0]) ? ~(ntk->getLatch(index)) : ntk->getLatch(index);
_formula.push_back(make_pair(V3_PI, V3InputVec())); _formula.back().second.push_back(V3NetType(id));
}
assert (startId <= _formula.size());
// Conjunction of Leaf Nodes
for (uint32_t j = 0, k = _formula.size() - startId; j < k; ++j) {
if (!j) constrId.push_back(startId + j);
else {
_formula.push_back(make_pair(BV_AND, V3InputVec()));
_formula.back().second.push_back(constrId.back());
_formula.back().second.push_back(startId + j);
constrId.back() = _formula.size() - 1;
}
}
}
// Disjunction of Constraints
for (uint32_t i = 0; i < constrId.size(); ++i) {
if (!i) _rootId = constrId[i];
else {
_formula.push_back(make_pair(BV_OR, V3InputVec()));
_formula.back().second.push_back(_rootId);
_formula.back().second.push_back(constrId[i]);
_rootId = _formula.size() - 1;
}
}
}
//----------------------------------------------------------------------
// MITer NTk <(unsigned ntkId1)> <(unsigned ntkId2)>
// [-Name <(string miterNtkName)>] [| -SEC | -CEC] [-Merge]
//----------------------------------------------------------------------
V3CmdExecStatus
V3MiterNtkCmd::exec(const string& option) {
vector<string> options;
V3CmdExec::lexOptions(option, options);
uint32_t id1 = V3NtkUD, id2 = V3NtkUD;
bool miterName = false, miterNameON = false;
bool sec = false, cec = false, merge = false;
string miterNtkName = ""; int temp;
size_t n = options.size();
for (size_t i = 0; i < n; ++i) {
const string& token = options[i];
if (v3StrNCmp("-Name", token, 2) == 0) {
if (miterName) return V3CmdExec::errorOption(CMD_OPT_EXTRA, token);
else miterName = miterNameON = true;
}
else if (v3StrNCmp("-SEC", token, 4) == 0) {
if (sec || cec) return V3CmdExec::errorOption(CMD_OPT_EXTRA, token);
else sec = true;
}
else if (v3StrNCmp("-CEC", token, 4) == 0) {
if (sec || cec) return V3CmdExec::errorOption(CMD_OPT_EXTRA, token);
else cec = true;
}
else if (v3StrNCmp("-Merge", token, 2) == 0) {
if (merge) return V3CmdExec::errorOption(CMD_OPT_EXTRA, token);
else merge = true;
}
else if (miterNameON) { miterNameON = false; miterNtkName = token; }
else if (V3NtkUD == id1) {
if (!v3Str2Int(token, temp)) return V3CmdExec::errorOption(CMD_OPT_ILLEGAL, "(unsigned ntkId1)");
else if (temp < 0) return V3CmdExec::errorOption(CMD_OPT_ILLEGAL, "(unsigned ntkId1)");
id1 = (uint32_t)temp;
}
else if (V3NtkUD == id2) {
if (!v3Str2Int(token, temp)) return V3CmdExec::errorOption(CMD_OPT_ILLEGAL, "(unsigned ntkId2)");
else if (temp < 0) return V3CmdExec::errorOption(CMD_OPT_ILLEGAL, "(unsigned ntkId2)");
id2 = (uint32_t)temp;
}
else return V3CmdExec::errorOption(CMD_OPT_ILLEGAL, token);
}
if (V3NtkUD == id1) return V3CmdExec::errorOption(CMD_OPT_MISSING, "(unsigned ntkId1)");
if (V3NtkUD == id2) return V3CmdExec::errorOption(CMD_OPT_MISSING, "(unsigned ntkId2)");
if (miterNameON) return V3CmdExec::errorOption(CMD_OPT_MISSING, "(string miterNtkName)");
V3NtkHandler* const handler = v3Handler.getCurHandler();
if (handler) {
if (id1 >= v3Handler.getHandlerCount())
Msg(MSG_ERR) << "Network with id = " << id1 << " Does NOT Exist !!" << endl;
else if (id2 >= v3Handler.getHandlerCount())
Msg(MSG_ERR) << "Network with id = " << id2 << " Does NOT Exist !!" << endl;
else {
V3NtkHandler* const handler1 = v3Handler.getHandler(id1); assert (handler);
V3NtkHandler* const handler2 = v3Handler.getHandler(id2); assert (handler);
if (!(reportIncompatibleModule(handler1, handler2) || reportIncompatibleModule(handler1, handler2))) {
if (!cec) {
V3NtkMiter* const miterHandler = new V3NtkMiter(handler1, handler2, merge, miterNtkName);
assert (miterHandler); v3Handler.pushAndSetCurHandler(miterHandler);
}
else {
// Compute Name Mapping for Latches Between Two Networks
if (handler1->getNtk()->getLatchSize() == handler2->getNtk()->getLatchSize()) {
V3Map<string, uint32_t>::Map nameMap; nameMap.clear();
for (uint32_t i = 0; i < handler2->getNtk()->getLatchSize(); ++i)
nameMap.insert(make_pair(handler2->getNetName(handler2->getNtk()->getLatch(i)), i));
if (handler2->getNtk()->getLatchSize() == nameMap.size()) {
V3Map<string, uint32_t>::Map::const_iterator it; V3UI32Vec latchMap;
latchMap.clear(); latchMap.reserve(handler1->getNtk()->getLatchSize());
for (uint32_t i = 0; i < nameMap.size(); ++i) {
it = nameMap.find(handler1->getNetName(handler1->getNtk()->getLatch(i)));
if ((nameMap.end() == it) ||
(handler1->getNtk()->getNetWidth(handler1->getNtk()->getLatch(i)) !=
handler2->getNtk()->getNetWidth(handler2->getNtk()->getLatch(it->second)))) break;
else latchMap.push_back(it->second);
}
if (handler1->getNtk()->getLatchSize() == latchMap.size()) {
V3NtkMiter* const miterHandler =
new V3NtkMiter(handler1, handler2, latchMap, merge, miterNtkName);
assert (miterHandler); v3Handler.pushAndSetCurHandler(miterHandler);
}
else Msg(MSG_ERR) << "Unmapped Latch " << latchMap.size()
<< " Found in Network " << id1 << " !!" << endl;
}
else Msg(MSG_ERR) << "Repeated or Missing Latch Names Exist !!" << endl;
}
else Msg(MSG_ERR) << "Number of Latches in Networks NOT Matched : " << id1 << "("
<< handler1->getNtk()->getLatchSize() << ") != " << id2 << "("
<< handler2->getNtk()->getLatchSize() << ") !!" << endl;
}
}
}
}
else Msg(MSG_ERR) << "Empty Ntk !!" << endl;
return CMD_EXEC_DONE;
}
// Functions for Checking Common Results
void
V3VrfBase::checkCommonCounterexample(const uint32_t& p, const V3CexTrace& cex) {
assert (_result[p].isCex()); assert (cex.getTraceSize());
// Collect Unsolved Properties
V3UI32Vec unsolved; unsolved.clear(); unsolved.reserve(_result.size());
for (uint32_t i = 0; i < _result.size(); ++i)
if (!(_result[i].isCex() || _result[i].isInv())) unsolved.push_back(i);
if (!unsolved.size()) return; assert (!_constr.size());
V3UI32Vec firedIndex, firedDepth; firedIndex.clear(); firedDepth.clear();
// Check Same Property
const V3NetId pId = _vrfNtk->getOutput(p);
for (uint32_t i = 0; i < unsolved.size(); ++i) {
if (pId != _vrfNtk->getOutput(unsolved[i])) continue;
firedIndex.push_back(unsolved[i]); firedDepth.push_back(cex.getTraceSize());
unsolved.erase(unsolved.begin() + i); --i;
}
// Create Simulator
V3AlgSimulate* simulator = 0; V3BitVecX pattern;
if (dynamic_cast<V3BvNtk*>(_vrfNtk)) simulator = new V3AlgBvSimulate(_handler);
else simulator = new V3AlgAigSimulate(_handler); assert (simulator);
// For each time-frame, set pattern from counter-example
for (uint32_t i = 0, k; i < cex.getTraceSize(); ++i) {
if (!unsolved.size()) break;
// Update FF Next State Values
simulator->updateNextStateValue();
// Set Initial State Values
if (!i && cex.getInit()) {
V3BitVecX* const initValue = cex.getInit(); k = 0;
for (uint32_t j = 0; j < _vrfNtk->getLatchSize(); ++j, ++k)
simulator->setSource(_vrfNtk->getLatch(j), initValue->bv_slice(k, k));
}
// Set PI Values
if (cex.getTraceDataSize()) pattern = cex.getData(i); k = 0;
for (uint32_t j = 0; j < _vrfNtk->getInputSize(); ++j, ++k)
simulator->setSource(_vrfNtk->getInput(j), pattern.bv_slice(k, k));
for (uint32_t j = 0; j < _vrfNtk->getInoutSize(); ++j, ++k)
simulator->setSource(_vrfNtk->getInout(j), pattern.bv_slice(k, k));
// Simulate Ntk for a Cycle
simulator->simulate();
// Check Property Assertion
for (uint32_t j = 0; j < unsolved.size(); ++j) {
if ('1' == simulator->getSimValue(_vrfNtk->getOutput(unsolved[j])).bv_slice(0, 0)[0]) {
firedIndex.push_back(unsolved[j]); firedDepth.push_back(1 + i);
unsolved.erase(unsolved.begin() + j); --j;
}
}
}
delete simulator; simulator = 0; assert (firedIndex.size() == firedDepth.size());
// Set Sub-Traces for Cex to Fired Properties
for (uint32_t i = 0; i < firedIndex.size(); ++i) {
V3CexTrace* const subTrace = new V3CexTrace(firedDepth[i]); assert (subTrace);
if (cex.getTraceDataSize()) for (uint32_t j = 0; j < firedDepth[i]; ++j) subTrace->pushData(cex.getData(j));
if (cex.getInit()) subTrace->setInit(*(cex.getInit())); _result[firedIndex[i]].setCexTrace(subTrace);
}
}
void
V3Handler::setCurHandlerFromPath(const string& path) {
assert (path.size());
string curPath = path;
uint32_t i;
// Split Path by '/'
V3Vec<string>::Vec idStr; idStr.clear();
while (curPath.size()) {
for (i = 0; i < curPath.size(); ++i) if ('/' == curPath[i]) break;
if (!i) idStr.push_back("");
else idStr.push_back(curPath.substr(0, i));
if ((i + 1) >= curPath.size()) break;
else curPath = curPath.substr(i + 1);
}
// Copy Current Handler and RefId
const uint32_t curHandlerId = _curHandlerId; assert (getHandler(curHandlerId));
V3UI32Vec curRefIdVec = _curRefIdVec; assert (curRefIdVec.size());
V3NtkHandler* handler = 0;
bool isRoot = false; int temp;
for (i = 0; i < idStr.size(); ++i) {
if (handler) { // Expecting Sub-Module Index
if (!idStr[i].size()) continue;
if (v3Str2Int(idStr[i], temp)) {
const uint32_t id = (uint32_t)temp;
if (id < handler->getNtk()->getModuleSize()) {
handler = handler->getNtk()->getModule(id)->getNtkRef();
uint32_t j = 0; for (; j < _ntkHandlerList.size(); ++j) if (handler == _ntkHandlerList[j]) break;
_curHandlerId = j; _curRefIdVec.push_back(id);
}
else {
string recoverPath = "";
for (uint32_t j = 0; j < _curRefIdVec.size(); ++j) recoverPath += ("/" + v3Int2Str(_curRefIdVec[j]));
Msg(MSG_ERR) << "Sub-Module of " << recoverPath << " with Index = "
<< idStr[i] << " Does NOT Exist !!" << endl; return;
}
}
}
else { // Expecting NtkID or Location Symbols (/, ./, ~/, .)
if (!idStr[i].size()) isRoot = true;
else {
// Lex if current token is a SubModule Index
if (v3Str2Int(idStr[i], temp)) {
const uint32_t id = (uint32_t)temp;
if (isRoot) {
if (id < getHandlerCount()) {
handler = getHandler(id); _curHandlerId = id;
_curRefIdVec.clear(); _curRefIdVec.push_back(id);
}
else {
Msg(MSG_ERR) << "Ntk with ID = " << idStr[i] << " Does NOT Exist !!" << endl; return;
}
}
else {
if (id < getCurHandler()->getNtk()->getModuleSize()) {
handler = getCurHandler()->getNtk()->getModule(id)->getNtkRef();
uint32_t j = 0; for (; j < _ntkHandlerList.size(); ++j) if (handler == _ntkHandlerList[j]) break;
_curHandlerId = j; _curRefIdVec.push_back(id);
}
else {
string recoverPath = "";
for (uint32_t j = 0; j < _curRefIdVec.size(); ++j) recoverPath += ("/" + v3Int2Str(_curRefIdVec[j]));
Msg(MSG_ERR) << "Sub-Module of " << recoverPath << " with Index = "
<< idStr[i] << " Does NOT Exist !!" << endl; return;
}
}
}
else if (idStr[i].size() > 1) {
Msg(MSG_ERR) << "Unexpected Symbol \"" << idStr[i] << "\" in the Path !!" << endl; return;
}
else if ('~' == idStr[i][0]) {
const uint32_t baseId = _curHandlerId = _curRefIdVec[0]; handler = getHandler(baseId);
_curRefIdVec.clear(); _curRefIdVec.push_back(baseId);
}
else if ('.' == idStr[i][0]) handler = getCurHandler(); assert (handler);
}
}
}
// Copy Data for Last if Valid, Or Resume Data for Current
if (_curHandlerId < _ntkHandlerList.size()) {
_lastHandlerId = curHandlerId; _lastRefIdVec = curRefIdVec;
}
else {
_curHandlerId = curHandlerId; _curRefIdVec = curRefIdVec;
Msg(MSG_ERR) << "Network " << path << " was Implicitly Created and it is Currently Untraceable !!" << endl;
}
}
const V3NetId
V3NtkElaborate::elaborateL2S(const V3NetId& id) {
assert (_ntk); assert (_p2cMap.size()); assert (id.id < _ntk->getNetSize());
assert (isMutable()); assert (_shadow.size() == _handler->getNtk()->getLatchSize());
// Create L2S Data Members if NOT Exist
V3BvNtk* const bvNtk = dynamic_cast<V3BvNtk*>(_ntk);
V3InputVec inputs; inputs.clear(); inputs.reserve(4);
if (V3NetUD == _saved || V3NetUD == _1stSave || V3NetUD == _inLoop) {
assert (V3NetUD == _saved && V3NetUD == _1stSave && V3NetUD == _inLoop);
_saved = _ntk->createNet(1); // Create Latch (_saved) for "In the Loop"
const V3NetId oracle = _ntk->createNet(1), inSaved = _ntk->createNet(1);
inputs.push_back(~_saved); inputs.push_back(~oracle); _ntk->setInput(inSaved, inputs);
_ntk->createGate((bvNtk ? BV_AND : AIG_NODE), inSaved); inputs.clear();
inputs.push_back(~inSaved); inputs.push_back(0); _ntk->setInput(_saved, inputs);
_ntk->createLatch(_saved); inputs.clear(); _ntk->createInput(oracle);
_1stSave = _ntk->createNet(1); // Create Net (_1stSave) for "Loop Start"
inputs.push_back(oracle); inputs.push_back(~_saved); _ntk->setInput(_1stSave, inputs);
_ntk->createGate((bvNtk ? BV_AND : AIG_NODE), _1stSave); inputs.clear();
_inLoop = _ntk->createNet(1); // Create Net (_inLoop) for "_1stSave || _saved"
inputs.push_back(~_1stSave); inputs.push_back(~_saved); _ntk->setInput(_inLoop, inputs);
_ntk->createGate((bvNtk ? BV_AND : AIG_NODE), _inLoop); inputs.clear(); _inLoop = ~_inLoop;
}
// Create Equivalence Logic and Shadow FF if NOT Exist
V3NetId ffId; V3GateType type; V3UI32Vec newShadow; newShadow.clear();
for (uint32_t i = 0; i < _shadow.size(); ++i) {
ffId = _p2cMap[_handler->getNtk()->getLatch(i).id]; assert (V3_FF == _ntk->getGateType(ffId));
if (V3NetUD == ffId || V3NetUD != _shadow[i]) continue; newShadow.push_back(i);
// Create Net for Shadow FF
_shadow[i] = _ntk->createNet(_ntk->getNetWidth(ffId)); assert (V3NetUD != _shadow[i]);
V3NetId shadowMux = V3NetUD; // Create Input MUX of Shadow FF
if (bvNtk) {
inputs.push_back(_shadow[i]); inputs.push_back(ffId); inputs.push_back(_1stSave);
type = BV_MUX; shadowMux = elaborateBvGate(bvNtk, type, inputs, _netHash);
}
else {
inputs.push_back(_1stSave); inputs.push_back(ffId);
inputs.push_back(~_1stSave); inputs.push_back(_shadow[i]);
type = AIG_NODE; shadowMux = elaborateAigAndOrAndGate(_ntk, inputs, _netHash);
}
// Create Shadow FF
assert (V3NetUD != shadowMux); inputs.clear(); inputs.push_back(shadowMux);
if (_ntk->getNetWidth(ffId) == 1) inputs.push_back(0);
else {
V3InputVec constInputs(1, bvNtk->hashV3ConstBitVec(v3Int2Str(_ntk->getNetWidth(ffId)) + "'d0"));
type = BV_CONST; inputs.push_back(elaborateBvGate(bvNtk, type, constInputs, _netHash));
}
_ntk->setInput(_shadow[i], inputs); _ntk->createLatch(_shadow[i]); inputs.clear();
// Create Equivalence Gate and Update _shadow
if (bvNtk) {
inputs.push_back(ffId); inputs.push_back(_shadow[i]); type = BV_EQUALITY;
_shadow[i] = elaborateBvGate(bvNtk, type, inputs, _netHash);
}
else {
inputs.push_back(ffId); inputs.push_back(_shadow[i]);
inputs.push_back(~ffId); inputs.push_back(~_shadow[i]);
_shadow[i] = elaborateAigAndOrAndGate(_ntk, inputs, _netHash);
}
assert (V3NetUD != _shadow[i]); assert (1 == _ntk->getNetWidth(_shadow[i])); inputs.clear();
}
// Create or Update Net (_looped) for "Loop Found" if NOT Exist
if (V3NetUD == _looped) _looped = _saved;
for (uint32_t i = 0; i < newShadow.size(); ++i) {
assert (V3NetUD != _p2cMap[_handler->getNtk()->getLatch(i).id]); assert (V3NetUD != _shadow[i]);
inputs.push_back(_looped); inputs.push_back(_shadow[i]);
if (bvNtk) { type = BV_AND; _looped = elaborateBvGate(bvNtk, type, inputs, _netHash); }
else { type = AIG_NODE; _looped = elaborateAigGate(_ntk, type, inputs, _netHash); }
assert (V3NetUD != _looped); inputs.clear();
}
if (V3NetId::makeNetId(0) == ~id) return _looped;
// Create Latch (pLatch) for Recording Existence of Violation to id
const V3NetId pLatch = _ntk->createNet(1), in_pLatch = _ntk->createNet(1);
inputs.push_back(~pLatch); inputs.push_back(id); _ntk->setInput(in_pLatch, inputs);
_ntk->createGate((bvNtk ? BV_AND : AIG_NODE), in_pLatch); inputs.clear();
inputs.push_back(~in_pLatch); inputs.push_back(0); _ntk->setInput(pLatch, inputs);
_ntk->createLatch(pLatch); inputs.clear();
// Create L2S Property Output (to Witness "_looped && in_pLatch")
V3NetId pId = V3NetUD; inputs.push_back(_looped); inputs.push_back(in_pLatch);
if (bvNtk) { type = BV_AND; pId = elaborateBvGate(bvNtk, type, inputs, _netHash); }
else { type = AIG_NODE; pId = elaborateAigGate(_ntk, type, inputs, _netHash); }
assert (V3NetUD != pId); inputs.clear(); return pId;
}