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//===-- ExecutionState.cpp ------------------------------------------------===//
//
// The KLEE Symbolic Virtual Machine
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "ExecutionState.h"
#include "Memory.h"
#include "klee/Expr/Expr.h"
#include "klee/Module/Cell.h"
#include "klee/Module/InstructionInfoTable.h"
#include "klee/Module/KInstruction.h"
#include "klee/Module/KModule.h"
#include "klee/Support/Casting.h"
#include "klee/Support/OptionCategories.h"
#include "llvm/IR/Function.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/raw_ostream.h"
#include <cassert>
#include <iomanip>
#include <map>
#include <set>
#include <sstream>
#include <stdarg.h>
using namespace llvm;
using namespace klee;
namespace {
cl::opt<bool> DebugLogStateMerge(
"debug-log-state-merge", cl::init(false),
cl::desc("Debug information for underlying state merging (default=false)"),
cl::cat(MergeCat));
}
namespace klee {
extern cl::opt<bool> SingleObjectResolution;
}
/***/
std::uint32_t ExecutionState::nextID = 1;
/***/
StackFrame::StackFrame(KInstIterator _caller, KFunction *_kf)
: caller(_caller), kf(_kf), callPathNode(0),
minDistToUncoveredOnReturn(0), varargs(0) {
locals = new Cell[kf->numRegisters];
}
StackFrame::StackFrame(const StackFrame &s)
: caller(s.caller),
kf(s.kf),
callPathNode(s.callPathNode),
allocas(s.allocas),
minDistToUncoveredOnReturn(s.minDistToUncoveredOnReturn),
varargs(s.varargs) {
locals = new Cell[s.kf->numRegisters];
for (unsigned i=0; i<s.kf->numRegisters; i++)
locals[i] = s.locals[i];
}
StackFrame::~StackFrame() {
delete[] locals;
}
/***/
ExecutionState::ExecutionState(KFunction *kf, MemoryManager *mm)
: pc(kf->instructions), prevPC(pc) {
pushFrame(nullptr, kf);
setID();
if (mm->stackFactory && mm->heapFactory) {
stackAllocator = mm->stackFactory.makeAllocator();
heapAllocator = mm->heapFactory.makeAllocator();
}
}
ExecutionState::~ExecutionState() {
for (const auto &cur_mergehandler: openMergeStack){
cur_mergehandler->removeOpenState(this);
}
while (!stack.empty()) popFrame();
}
ExecutionState::ExecutionState(const ExecutionState& state):
pc(state.pc),
prevPC(state.prevPC),
stack(state.stack),
incomingBBIndex(state.incomingBBIndex),
depth(state.depth),
addressSpace(state.addressSpace),
stackAllocator(state.stackAllocator),
heapAllocator(state.heapAllocator),
constraints(state.constraints),
pathOS(state.pathOS),
symPathOS(state.symPathOS),
coveredLines(state.coveredLines),
symbolics(state.symbolics),
cexPreferences(state.cexPreferences),
arrayNames(state.arrayNames),
openMergeStack(state.openMergeStack),
steppedInstructions(state.steppedInstructions),
instsSinceCovNew(state.instsSinceCovNew),
unwindingInformation(state.unwindingInformation
? state.unwindingInformation->clone()
: nullptr),
coveredNew(state.coveredNew),
forkDisabled(state.forkDisabled),
base_addrs(state.base_addrs),
base_mos(state.base_mos) {
for (const auto &cur_mergehandler: openMergeStack)
cur_mergehandler->addOpenState(this);
}
ExecutionState *ExecutionState::branch() {
depth++;
auto *falseState = new ExecutionState(*this);
falseState->setID();
falseState->coveredNew = false;
falseState->coveredLines.clear();
return falseState;
}
void ExecutionState::pushFrame(KInstIterator caller, KFunction *kf) {
stack.emplace_back(StackFrame(caller, kf));
}
void ExecutionState::popFrame() {
const StackFrame &sf = stack.back();
for (const auto *memoryObject : sf.allocas) {
deallocate(memoryObject);
addressSpace.unbindObject(memoryObject);
}
stack.pop_back();
}
void ExecutionState::deallocate(const MemoryObject *mo) {
if (SingleObjectResolution) {
auto mos_it = base_mos.find(mo->address);
if (mos_it != base_mos.end()) {
for (auto it = mos_it->second.begin(); it != mos_it->second.end(); ++it) {
base_addrs.erase(*it);
}
base_mos.erase(mos_it->first);
}
}
if (!stackAllocator || !heapAllocator)
return;
auto address = reinterpret_cast<void *>(mo->address);
if (mo->isLocal) {
stackAllocator.free(address, std::max(mo->size, mo->alignment));
} else {
heapAllocator.free(address, std::max(mo->size, mo->alignment));
}
}
void ExecutionState::addSymbolic(const MemoryObject *mo, const Array *array) {
symbolics.emplace_back(ref<const MemoryObject>(mo), array);
}
/**/
llvm::raw_ostream &klee::operator<<(llvm::raw_ostream &os, const MemoryMap &mm) {
os << "{";
MemoryMap::iterator it = mm.begin();
MemoryMap::iterator ie = mm.end();
if (it!=ie) {
os << "MO" << it->first->id << ":" << it->second.get();
for (++it; it!=ie; ++it)
os << ", MO" << it->first->id << ":" << it->second.get();
}
os << "}";
return os;
}
bool ExecutionState::merge(const ExecutionState &b) {
if (DebugLogStateMerge)
llvm::errs() << "-- attempting merge of A:" << this << " with B:" << &b
<< "--\n";
if (pc != b.pc)
return false;
// XXX is it even possible for these to differ? does it matter? probably
// implies difference in object states?
if (symbolics != b.symbolics)
return false;
{
std::vector<StackFrame>::const_iterator itA = stack.begin();
std::vector<StackFrame>::const_iterator itB = b.stack.begin();
while (itA!=stack.end() && itB!=b.stack.end()) {
// XXX vaargs?
if (itA->caller!=itB->caller || itA->kf!=itB->kf)
return false;
++itA;
++itB;
}
if (itA!=stack.end() || itB!=b.stack.end())
return false;
}
std::set< ref<Expr> > aConstraints(constraints.begin(), constraints.end());
std::set< ref<Expr> > bConstraints(b.constraints.begin(),
b.constraints.end());
std::set< ref<Expr> > commonConstraints, aSuffix, bSuffix;
std::set_intersection(aConstraints.begin(), aConstraints.end(),
bConstraints.begin(), bConstraints.end(),
std::inserter(commonConstraints, commonConstraints.begin()));
std::set_difference(aConstraints.begin(), aConstraints.end(),
commonConstraints.begin(), commonConstraints.end(),
std::inserter(aSuffix, aSuffix.end()));
std::set_difference(bConstraints.begin(), bConstraints.end(),
commonConstraints.begin(), commonConstraints.end(),
std::inserter(bSuffix, bSuffix.end()));
if (DebugLogStateMerge) {
llvm::errs() << "\tconstraint prefix: [";
for (std::set<ref<Expr> >::iterator it = commonConstraints.begin(),
ie = commonConstraints.end();
it != ie; ++it)
llvm::errs() << *it << ", ";
llvm::errs() << "]\n";
llvm::errs() << "\tA suffix: [";
for (std::set<ref<Expr> >::iterator it = aSuffix.begin(),
ie = aSuffix.end();
it != ie; ++it)
llvm::errs() << *it << ", ";
llvm::errs() << "]\n";
llvm::errs() << "\tB suffix: [";
for (std::set<ref<Expr> >::iterator it = bSuffix.begin(),
ie = bSuffix.end();
it != ie; ++it)
llvm::errs() << *it << ", ";
llvm::errs() << "]\n";
}
// We cannot merge if addresses would resolve differently in the
// states. This means:
//
// 1. Any objects created since the branch in either object must
// have been free'd.
//
// 2. We cannot have free'd any pre-existing object in one state
// and not the other
if (DebugLogStateMerge) {
llvm::errs() << "\tchecking object states\n";
llvm::errs() << "A: " << addressSpace.objects << "\n";
llvm::errs() << "B: " << b.addressSpace.objects << "\n";
}
std::set<const MemoryObject*> mutated;
MemoryMap::iterator ai = addressSpace.objects.begin();
MemoryMap::iterator bi = b.addressSpace.objects.begin();
MemoryMap::iterator ae = addressSpace.objects.end();
MemoryMap::iterator be = b.addressSpace.objects.end();
for (; ai!=ae && bi!=be; ++ai, ++bi) {
if (ai->first != bi->first) {
if (DebugLogStateMerge) {
if (ai->first < bi->first) {
llvm::errs() << "\t\tB misses binding for: " << ai->first->id << "\n";
} else {
llvm::errs() << "\t\tA misses binding for: " << bi->first->id << "\n";
}
}
return false;
}
if (ai->second.get() != bi->second.get()) {
if (DebugLogStateMerge)
llvm::errs() << "\t\tmutated: " << ai->first->id << "\n";
mutated.insert(ai->first);
}
}
if (ai!=ae || bi!=be) {
if (DebugLogStateMerge)
llvm::errs() << "\t\tmappings differ\n";
return false;
}
// merge stack
ref<Expr> inA = ConstantExpr::alloc(1, Expr::Bool);
ref<Expr> inB = ConstantExpr::alloc(1, Expr::Bool);
for (std::set< ref<Expr> >::iterator it = aSuffix.begin(),
ie = aSuffix.end(); it != ie; ++it)
inA = AndExpr::create(inA, *it);
for (std::set< ref<Expr> >::iterator it = bSuffix.begin(),
ie = bSuffix.end(); it != ie; ++it)
inB = AndExpr::create(inB, *it);
// XXX should we have a preference as to which predicate to use?
// it seems like it can make a difference, even though logically
// they must contradict each other and so inA => !inB
std::vector<StackFrame>::iterator itA = stack.begin();
std::vector<StackFrame>::const_iterator itB = b.stack.begin();
for (; itA!=stack.end(); ++itA, ++itB) {
StackFrame &af = *itA;
const StackFrame &bf = *itB;
for (unsigned i=0; i<af.kf->numRegisters; i++) {
ref<Expr> &av = af.locals[i].value;
const ref<Expr> &bv = bf.locals[i].value;
if (!av || !bv) {
// if one is null then by implication (we are at same pc)
// we cannot reuse this local, so just ignore
} else {
av = SelectExpr::create(inA, av, bv);
}
}
}
for (std::set<const MemoryObject*>::iterator it = mutated.begin(),
ie = mutated.end(); it != ie; ++it) {
const MemoryObject *mo = *it;
const ObjectState *os = addressSpace.findObject(mo);
const ObjectState *otherOS = b.addressSpace.findObject(mo);
assert(os && !os->readOnly &&
"objects mutated but not writable in merging state");
assert(otherOS);
ObjectState *wos = addressSpace.getWriteable(mo, os);
for (unsigned i=0; i<mo->size; i++) {
ref<Expr> av = wos->read8(i);
ref<Expr> bv = otherOS->read8(i);
wos->write(i, SelectExpr::create(inA, av, bv));
}
}
constraints = ConstraintSet();
ConstraintManager m(constraints);
for (const auto &constraint : commonConstraints)
m.addConstraint(constraint);
m.addConstraint(OrExpr::create(inA, inB));
return true;
}
void ExecutionState::dumpStack(llvm::raw_ostream &out) const {
unsigned idx = 0;
const KInstruction *target = prevPC;
for (ExecutionState::stack_ty::const_reverse_iterator
it = stack.rbegin(), ie = stack.rend();
it != ie; ++it) {
const StackFrame &sf = *it;
Function *f = sf.kf->function;
const InstructionInfo &ii = *target->info;
out << "\t#" << idx++;
std::stringstream AssStream;
AssStream << std::setw(8) << std::setfill('0') << ii.assemblyLine;
out << AssStream.str();
out << " in " << f->getName().str() << "(";
// Yawn, we could go up and print varargs if we wanted to.
unsigned index = 0;
for (Function::arg_iterator ai = f->arg_begin(), ae = f->arg_end();
ai != ae; ++ai) {
if (ai!=f->arg_begin()) out << ", ";
if (ai->hasName())
out << ai->getName().str() << "=";
ref<Expr> value = sf.locals[sf.kf->getArgRegister(index++)].value;
if (isa_and_nonnull<ConstantExpr>(value)) {
out << value;
} else {
out << "symbolic";
}
}
out << ")";
if (ii.file != "")
out << " at " << ii.file << ":" << ii.line;
out << "\n";
target = sf.caller;
}
}
void ExecutionState::addConstraint(ref<Expr> e) {
ConstraintManager c(constraints);
c.addConstraint(e);
}
void ExecutionState::addCexPreference(const ref<Expr> &cond) {
cexPreferences = cexPreferences.insert(cond);
}
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