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|
//===-- Solver.cpp --------------------------------------------------------===//
//
// The KLEE Symbolic Virtual Machine
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "klee/Solver.h"
#include "klee/SolverImpl.h"
#include "SolverStats.h"
#include "STPBuilder.h"
#include "klee/Constraints.h"
#include "klee/Expr.h"
#include "klee/TimerStatIncrementer.h"
#include "klee/util/Assignment.h"
#include "klee/util/ExprPPrinter.h"
#include "klee/util/ExprUtil.h"
#include "klee/Internal/Support/Timer.h"
#define vc_bvBoolExtract IAMTHESPAWNOFSATAN
#include <cassert>
#include <cstdio>
#include <map>
#include <vector>
#include <errno.h>
#include <signal.h>
#include <sys/wait.h>
#include <sys/ipc.h>
#include <sys/shm.h>
using namespace klee;
/***/
const char *Solver::validity_to_str(Validity v) {
switch (v) {
default: return "Unknown";
case True: return "True";
case False: return "False";
}
}
Solver::~Solver() {
delete impl;
}
SolverImpl::~SolverImpl() {
}
bool Solver::evaluate(const Query& query, Validity &result) {
assert(query.expr->getWidth() == Expr::Bool && "Invalid expression type!");
// Maintain invariants implementations expect.
if (ConstantExpr *CE = dyn_cast<ConstantExpr>(query.expr)) {
result = CE->isTrue() ? True : False;
return true;
}
return impl->computeValidity(query, result);
}
bool SolverImpl::computeValidity(const Query& query, Solver::Validity &result) {
bool isTrue, isFalse;
if (!computeTruth(query, isTrue))
return false;
if (isTrue) {
result = Solver::True;
} else {
if (!computeTruth(query.negateExpr(), isFalse))
return false;
result = isFalse ? Solver::False : Solver::Unknown;
}
return true;
}
bool Solver::mustBeTrue(const Query& query, bool &result) {
assert(query.expr->getWidth() == Expr::Bool && "Invalid expression type!");
// Maintain invariants implementations expect.
if (ConstantExpr *CE = dyn_cast<ConstantExpr>(query.expr)) {
result = CE->isTrue() ? true : false;
return true;
}
return impl->computeTruth(query, result);
}
bool Solver::mustBeFalse(const Query& query, bool &result) {
return mustBeTrue(query.negateExpr(), result);
}
bool Solver::mayBeTrue(const Query& query, bool &result) {
bool res;
if (!mustBeFalse(query, res))
return false;
result = !res;
return true;
}
bool Solver::mayBeFalse(const Query& query, bool &result) {
bool res;
if (!mustBeTrue(query, res))
return false;
result = !res;
return true;
}
bool Solver::getValue(const Query& query, ref<ConstantExpr> &result) {
// Maintain invariants implementation expect.
if (ConstantExpr *CE = dyn_cast<ConstantExpr>(query.expr)) {
result = CE;
return true;
}
// FIXME: Push ConstantExpr requirement down.
ref<Expr> tmp;
if (!impl->computeValue(query, tmp))
return false;
result = cast<ConstantExpr>(tmp);
return true;
}
bool
Solver::getInitialValues(const Query& query,
const std::vector<const Array*> &objects,
std::vector< std::vector<unsigned char> > &values) {
bool hasSolution;
bool success =
impl->computeInitialValues(query, objects, values, hasSolution);
// FIXME: Propogate this out.
if (!hasSolution)
return false;
return success;
}
std::pair< ref<Expr>, ref<Expr> > Solver::getRange(const Query& query) {
ref<Expr> e = query.expr;
Expr::Width width = e->getWidth();
uint64_t min, max;
if (width==1) {
Solver::Validity result;
if (!evaluate(query, result))
assert(0 && "computeValidity failed");
switch (result) {
case Solver::True:
min = max = 1; break;
case Solver::False:
min = max = 0; break;
default:
min = 0, max = 1; break;
}
} else if (ConstantExpr *CE = dyn_cast<ConstantExpr>(e)) {
min = max = CE->getZExtValue();
} else {
// binary search for # of useful bits
uint64_t lo=0, hi=width, mid, bits=0;
while (lo<hi) {
mid = lo + (hi - lo)/2;
bool res;
bool success =
mustBeTrue(query.withExpr(
EqExpr::create(LShrExpr::create(e,
ConstantExpr::create(mid,
width)),
ConstantExpr::create(0, width))),
res);
assert(success && "FIXME: Unhandled solver failure");
(void) success;
if (res) {
hi = mid;
} else {
lo = mid+1;
}
bits = lo;
}
// could binary search for training zeros and offset
// min max but unlikely to be very useful
// check common case
bool res = false;
bool success =
mayBeTrue(query.withExpr(EqExpr::create(e, ConstantExpr::create(0,
width))),
res);
assert(success && "FIXME: Unhandled solver failure");
(void) success;
if (res) {
min = 0;
} else {
// binary search for min
lo=0, hi=bits64::maxValueOfNBits(bits);
while (lo<hi) {
mid = lo + (hi - lo)/2;
bool res = false;
bool success =
mayBeTrue(query.withExpr(UleExpr::create(e,
ConstantExpr::create(mid,
width))),
res);
assert(success && "FIXME: Unhandled solver failure");
(void) success;
if (res) {
hi = mid;
} else {
lo = mid+1;
}
}
min = lo;
}
// binary search for max
lo=min, hi=bits64::maxValueOfNBits(bits);
while (lo<hi) {
mid = lo + (hi - lo)/2;
bool res;
bool success =
mustBeTrue(query.withExpr(UleExpr::create(e,
ConstantExpr::create(mid,
width))),
res);
assert(success && "FIXME: Unhandled solver failure");
(void) success;
if (res) {
hi = mid;
} else {
lo = mid+1;
}
}
max = lo;
}
return std::make_pair(ConstantExpr::create(min, width),
ConstantExpr::create(max, width));
}
/***/
class ValidatingSolver : public SolverImpl {
private:
Solver *solver, *oracle;
public:
ValidatingSolver(Solver *_solver, Solver *_oracle)
: solver(_solver), oracle(_oracle) {}
~ValidatingSolver() { delete solver; }
bool computeValidity(const Query&, Solver::Validity &result);
bool computeTruth(const Query&, bool &isValid);
bool computeValue(const Query&, ref<Expr> &result);
bool computeInitialValues(const Query&,
const std::vector<const Array*> &objects,
std::vector< std::vector<unsigned char> > &values,
bool &hasSolution);
};
bool ValidatingSolver::computeTruth(const Query& query,
bool &isValid) {
bool answer;
if (!solver->impl->computeTruth(query, isValid))
return false;
if (!oracle->impl->computeTruth(query, answer))
return false;
if (isValid != answer)
assert(0 && "invalid solver result (computeTruth)");
return true;
}
bool ValidatingSolver::computeValidity(const Query& query,
Solver::Validity &result) {
Solver::Validity answer;
if (!solver->impl->computeValidity(query, result))
return false;
if (!oracle->impl->computeValidity(query, answer))
return false;
if (result != answer)
assert(0 && "invalid solver result (computeValidity)");
return true;
}
bool ValidatingSolver::computeValue(const Query& query,
ref<Expr> &result) {
bool answer;
if (!solver->impl->computeValue(query, result))
return false;
// We don't want to compare, but just make sure this is a legal
// solution.
if (!oracle->impl->computeTruth(query.withExpr(NeExpr::create(query.expr,
result)),
answer))
return false;
if (answer)
assert(0 && "invalid solver result (computeValue)");
return true;
}
bool
ValidatingSolver::computeInitialValues(const Query& query,
const std::vector<const Array*>
&objects,
std::vector< std::vector<unsigned char> >
&values,
bool &hasSolution) {
bool answer;
if (!solver->impl->computeInitialValues(query, objects, values,
hasSolution))
return false;
if (hasSolution) {
// Assert the bindings as constraints, and verify that the
// conjunction of the actual constraints is satisfiable.
std::vector< ref<Expr> > bindings;
for (unsigned i = 0; i != values.size(); ++i) {
const Array *array = objects[i];
for (unsigned j=0; j<array->size; j++) {
unsigned char value = values[i][j];
bindings.push_back(EqExpr::create(ReadExpr::create(UpdateList(array, 0),
ConstantExpr::alloc(j, Expr::Int32)),
ConstantExpr::alloc(value, Expr::Int8)));
}
}
ConstraintManager tmp(bindings);
ref<Expr> constraints = Expr::createIsZero(query.expr);
for (ConstraintManager::const_iterator it = query.constraints.begin(),
ie = query.constraints.end(); it != ie; ++it)
constraints = AndExpr::create(constraints, *it);
if (!oracle->impl->computeTruth(Query(tmp, constraints), answer))
return false;
if (!answer)
assert(0 && "invalid solver result (computeInitialValues)");
} else {
if (!oracle->impl->computeTruth(query, answer))
return false;
if (!answer)
assert(0 && "invalid solver result (computeInitialValues)");
}
return true;
}
Solver *klee::createValidatingSolver(Solver *s, Solver *oracle) {
return new Solver(new ValidatingSolver(s, oracle));
}
/***/
class DummySolverImpl : public SolverImpl {
public:
DummySolverImpl() {}
bool computeValidity(const Query&, Solver::Validity &result) {
++stats::queries;
// FIXME: We should have stats::queriesFail;
return false;
}
bool computeTruth(const Query&, bool &isValid) {
++stats::queries;
// FIXME: We should have stats::queriesFail;
return false;
}
bool computeValue(const Query&, ref<Expr> &result) {
++stats::queries;
++stats::queryCounterexamples;
return false;
}
bool computeInitialValues(const Query&,
const std::vector<const Array*> &objects,
std::vector< std::vector<unsigned char> > &values,
bool &hasSolution) {
++stats::queries;
++stats::queryCounterexamples;
return false;
}
};
Solver *klee::createDummySolver() {
return new Solver(new DummySolverImpl());
}
/***/
class STPSolverImpl : public SolverImpl {
private:
/// The solver we are part of, for access to public information.
STPSolver *solver;
VC vc;
STPBuilder *builder;
double timeout;
bool useForkedSTP;
public:
STPSolverImpl(STPSolver *_solver, bool _useForkedSTP, bool _optimizeDivides = true);
~STPSolverImpl();
char *getConstraintLog(const Query&);
void setTimeout(double _timeout) { timeout = _timeout; }
bool computeTruth(const Query&, bool &isValid);
bool computeValue(const Query&, ref<Expr> &result);
bool computeInitialValues(const Query&,
const std::vector<const Array*> &objects,
std::vector< std::vector<unsigned char> > &values,
bool &hasSolution);
};
static unsigned char *shared_memory_ptr;
static const unsigned shared_memory_size = 1<<20;
static int shared_memory_id;
static void stp_error_handler(const char* err_msg) {
fprintf(stderr, "error: STP Error: %s\n", err_msg);
abort();
}
STPSolverImpl::STPSolverImpl(STPSolver *_solver, bool _useForkedSTP, bool _optimizeDivides)
: solver(_solver),
vc(vc_createValidityChecker()),
builder(new STPBuilder(vc, _optimizeDivides)),
timeout(0.0),
useForkedSTP(_useForkedSTP)
{
assert(vc && "unable to create validity checker");
assert(builder && "unable to create STPBuilder");
#ifdef HAVE_EXT_STP
// In newer versions of STP, a memory management mechanism has been
// introduced that automatically invalidates certain C interface
// pointers at vc_Destroy time. This caused double-free errors
// due to the ExprHandle destructor also attempting to invalidate
// the pointers using vc_DeleteExpr. By setting EXPRDELETE to 0
// we restore the old behaviour.
vc_setInterfaceFlags(vc, EXPRDELETE, 0);
#endif
vc_registerErrorHandler(::stp_error_handler);
if (useForkedSTP) {
shared_memory_id = shmget(IPC_PRIVATE, shared_memory_size, IPC_CREAT | 0700);
assert(shared_memory_id>=0 && "shmget failed");
shared_memory_ptr = (unsigned char*) shmat(shared_memory_id, NULL, 0);
assert(shared_memory_ptr!=(void*)-1 && "shmat failed");
shmctl(shared_memory_id, IPC_RMID, NULL);
}
}
STPSolverImpl::~STPSolverImpl() {
delete builder;
vc_Destroy(vc);
}
/***/
STPSolver::STPSolver(bool useForkedSTP, bool optimizeDivides)
: Solver(new STPSolverImpl(this, useForkedSTP, optimizeDivides))
{
}
char *STPSolver::getConstraintLog(const Query &query) {
return static_cast<STPSolverImpl*>(impl)->getConstraintLog(query);
}
void STPSolver::setTimeout(double timeout) {
static_cast<STPSolverImpl*>(impl)->setTimeout(timeout);
}
/***/
char *STPSolverImpl::getConstraintLog(const Query &query) {
vc_push(vc);
for (std::vector< ref<Expr> >::const_iterator it = query.constraints.begin(),
ie = query.constraints.end(); it != ie; ++it)
vc_assertFormula(vc, builder->construct(*it));
assert(query.expr == ConstantExpr::alloc(0, Expr::Bool) &&
"Unexpected expression in query!");
char *buffer;
unsigned long length;
vc_printQueryStateToBuffer(vc, builder->getFalse(),
&buffer, &length, false);
vc_pop(vc);
return buffer;
}
bool STPSolverImpl::computeTruth(const Query& query,
bool &isValid) {
std::vector<const Array*> objects;
std::vector< std::vector<unsigned char> > values;
bool hasSolution;
if (!computeInitialValues(query, objects, values, hasSolution))
return false;
isValid = !hasSolution;
return true;
}
bool STPSolverImpl::computeValue(const Query& query,
ref<Expr> &result) {
std::vector<const Array*> objects;
std::vector< std::vector<unsigned char> > values;
bool hasSolution;
// Find the object used in the expression, and compute an assignment
// for them.
findSymbolicObjects(query.expr, objects);
if (!computeInitialValues(query.withFalse(), objects, values, hasSolution))
return false;
assert(hasSolution && "state has invalid constraint set");
// Evaluate the expression with the computed assignment.
Assignment a(objects, values);
result = a.evaluate(query.expr);
return true;
}
static void runAndGetCex(::VC vc, STPBuilder *builder, ::VCExpr q,
const std::vector<const Array*> &objects,
std::vector< std::vector<unsigned char> > &values,
bool &hasSolution) {
// XXX I want to be able to timeout here, safely
hasSolution = !vc_query(vc, q);
if (hasSolution) {
values.reserve(objects.size());
for (std::vector<const Array*>::const_iterator
it = objects.begin(), ie = objects.end(); it != ie; ++it) {
const Array *array = *it;
std::vector<unsigned char> data;
data.reserve(array->size);
for (unsigned offset = 0; offset < array->size; offset++) {
ExprHandle counter =
vc_getCounterExample(vc, builder->getInitialRead(array, offset));
unsigned char val = getBVUnsigned(counter);
data.push_back(val);
}
values.push_back(data);
}
}
}
static void stpTimeoutHandler(int x) {
_exit(52);
}
static bool runAndGetCexForked(::VC vc,
STPBuilder *builder,
::VCExpr q,
const std::vector<const Array*> &objects,
std::vector< std::vector<unsigned char> >
&values,
bool &hasSolution,
double timeout) {
unsigned char *pos = shared_memory_ptr;
unsigned sum = 0;
for (std::vector<const Array*>::const_iterator
it = objects.begin(), ie = objects.end(); it != ie; ++it)
sum += (*it)->size;
assert(sum<shared_memory_size && "not enough shared memory for counterexample");
fflush(stdout);
fflush(stderr);
int pid = fork();
if (pid==-1) {
fprintf(stderr, "error: fork failed (for STP)");
return false;
}
if (pid == 0) {
if (timeout) {
::alarm(0); /* Turn off alarm so we can safely set signal handler */
::signal(SIGALRM, stpTimeoutHandler);
::alarm(std::max(1, (int)timeout));
}
unsigned res = vc_query(vc, q);
if (!res) {
for (std::vector<const Array*>::const_iterator
it = objects.begin(), ie = objects.end(); it != ie; ++it) {
const Array *array = *it;
for (unsigned offset = 0; offset < array->size; offset++) {
ExprHandle counter =
vc_getCounterExample(vc, builder->getInitialRead(array, offset));
*pos++ = getBVUnsigned(counter);
}
}
}
_exit(res);
} else {
int status;
pid_t res;
do {
res = waitpid(pid, &status, 0);
} while (res < 0 && errno == EINTR);
if (res < 0) {
fprintf(stderr, "error: waitpid() for STP failed");
return false;
}
// From timed_run.py: It appears that linux at least will on
// "occasion" return a status when the process was terminated by a
// signal, so test signal first.
if (WIFSIGNALED(status) || !WIFEXITED(status)) {
fprintf(stderr, "error: STP did not return successfully");
return false;
}
int exitcode = WEXITSTATUS(status);
if (exitcode==0) {
hasSolution = true;
} else if (exitcode==1) {
hasSolution = false;
} else if (exitcode==52) {
fprintf(stderr, "error: STP timed out");
return false;
} else {
fprintf(stderr, "error: STP did not return a recognized code");
return false;
}
if (hasSolution) {
values = std::vector< std::vector<unsigned char> >(objects.size());
unsigned i=0;
for (std::vector<const Array*>::const_iterator
it = objects.begin(), ie = objects.end(); it != ie; ++it) {
const Array *array = *it;
std::vector<unsigned char> &data = values[i++];
data.insert(data.begin(), pos, pos + array->size);
pos += array->size;
}
}
return true;
}
}
bool
STPSolverImpl::computeInitialValues(const Query &query,
const std::vector<const Array*>
&objects,
std::vector< std::vector<unsigned char> >
&values,
bool &hasSolution) {
TimerStatIncrementer t(stats::queryTime);
vc_push(vc);
for (ConstraintManager::const_iterator it = query.constraints.begin(),
ie = query.constraints.end(); it != ie; ++it)
vc_assertFormula(vc, builder->construct(*it));
++stats::queries;
++stats::queryCounterexamples;
ExprHandle stp_e = builder->construct(query.expr);
if (0) {
char *buf;
unsigned long len;
vc_printQueryStateToBuffer(vc, stp_e, &buf, &len, false);
fprintf(stderr, "note: STP query: %.*s\n", (unsigned) len, buf);
}
bool success;
if (useForkedSTP) {
success = runAndGetCexForked(vc, builder, stp_e, objects, values,
hasSolution, timeout);
} else {
runAndGetCex(vc, builder, stp_e, objects, values, hasSolution);
success = true;
}
if (success) {
if (hasSolution)
++stats::queriesInvalid;
else
++stats::queriesValid;
}
vc_pop(vc);
return success;
}
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