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|
//===-- FastCexSolver.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/Constraints.h"
#include "klee/Expr.h"
#include "klee/IncompleteSolver.h"
#include "klee/util/ExprEvaluator.h"
#include "klee/util/ExprRangeEvaluator.h"
#include "klee/util/ExprVisitor.h"
// FIXME: Use APInt.
#include "klee/Internal/Support/IntEvaluation.h"
#include <iostream>
#include <sstream>
#include <cassert>
#include <map>
#include <vector>
using namespace klee;
/***/
//#define LOG
#ifdef LOG
std::ostream *theLog;
#endif
// Hacker's Delight, pgs 58-63
static uint64_t minOR(uint64_t a, uint64_t b,
uint64_t c, uint64_t d) {
uint64_t temp, m = ((uint64_t) 1)<<63;
while (m) {
if (~a & c & m) {
temp = (a | m) & -m;
if (temp <= b) { a = temp; break; }
} else if (a & ~c & m) {
temp = (c | m) & -m;
if (temp <= d) { c = temp; break; }
}
m >>= 1;
}
return a | c;
}
static uint64_t maxOR(uint64_t a, uint64_t b,
uint64_t c, uint64_t d) {
uint64_t temp, m = ((uint64_t) 1)<<63;
while (m) {
if (b & d & m) {
temp = (b - m) | (m - 1);
if (temp >= a) { b = temp; break; }
temp = (d - m) | (m -1);
if (temp >= c) { d = temp; break; }
}
m >>= 1;
}
return b | d;
}
static uint64_t minAND(uint64_t a, uint64_t b,
uint64_t c, uint64_t d) {
uint64_t temp, m = ((uint64_t) 1)<<63;
while (m) {
if (~a & ~c & m) {
temp = (a | m) & -m;
if (temp <= b) { a = temp; break; }
temp = (c | m) & -m;
if (temp <= d) { c = temp; break; }
}
m >>= 1;
}
return a & c;
}
static uint64_t maxAND(uint64_t a, uint64_t b,
uint64_t c, uint64_t d) {
uint64_t temp, m = ((uint64_t) 1)<<63;
while (m) {
if (b & ~d & m) {
temp = (b & ~m) | (m - 1);
if (temp >= a) { b = temp; break; }
} else if (~b & d & m) {
temp = (d & ~m) | (m - 1);
if (temp >= c) { d = temp; break; }
}
m >>= 1;
}
return b & d;
}
///
class ValueRange {
private:
uint64_t m_min, m_max;
public:
ValueRange() : m_min(1),m_max(0) {}
ValueRange(uint64_t value) : m_min(value), m_max(value) {}
ValueRange(uint64_t _min, uint64_t _max) : m_min(_min), m_max(_max) {}
ValueRange(const ValueRange &b) : m_min(b.m_min), m_max(b.m_max) {}
void print(std::ostream &os) const {
if (isFixed()) {
os << m_min;
} else {
os << "[" << m_min << "," << m_max << "]";
}
}
bool isEmpty() const {
return m_min>m_max;
}
bool contains(uint64_t value) const {
return this->intersects(ValueRange(value));
}
bool intersects(const ValueRange &b) const {
return !this->set_intersection(b).isEmpty();
}
bool isFullRange(unsigned bits) {
return m_min==0 && m_max==bits64::maxValueOfNBits(bits);
}
ValueRange set_intersection(const ValueRange &b) const {
return ValueRange(std::max(m_min,b.m_min), std::min(m_max,b.m_max));
}
ValueRange set_union(const ValueRange &b) const {
return ValueRange(std::min(m_min,b.m_min), std::max(m_max,b.m_max));
}
ValueRange set_difference(const ValueRange &b) const {
if (b.isEmpty() || b.m_min > m_max || b.m_max < m_min) { // no intersection
return *this;
} else if (b.m_min <= m_min && b.m_max >= m_max) { // empty
return ValueRange(1,0);
} else if (b.m_min <= m_min) { // one range out
// cannot overflow because b.m_max < m_max
return ValueRange(b.m_max+1, m_max);
} else if (b.m_max >= m_max) {
// cannot overflow because b.min > m_min
return ValueRange(m_min, b.m_min-1);
} else {
// two ranges, take bottom
return ValueRange(m_min, b.m_min-1);
}
}
ValueRange binaryAnd(const ValueRange &b) const {
// XXX
assert(!isEmpty() && !b.isEmpty() && "XXX");
if (isFixed() && b.isFixed()) {
return ValueRange(m_min & b.m_min);
} else {
return ValueRange(minAND(m_min, m_max, b.m_min, b.m_max),
maxAND(m_min, m_max, b.m_min, b.m_max));
}
}
ValueRange binaryAnd(uint64_t b) const { return binaryAnd(ValueRange(b)); }
ValueRange binaryOr(ValueRange b) const {
// XXX
assert(!isEmpty() && !b.isEmpty() && "XXX");
if (isFixed() && b.isFixed()) {
return ValueRange(m_min | b.m_min);
} else {
return ValueRange(minOR(m_min, m_max, b.m_min, b.m_max),
maxOR(m_min, m_max, b.m_min, b.m_max));
}
}
ValueRange binaryOr(uint64_t b) const { return binaryOr(ValueRange(b)); }
ValueRange binaryXor(ValueRange b) const {
if (isFixed() && b.isFixed()) {
return ValueRange(m_min ^ b.m_min);
} else {
uint64_t t = m_max | b.m_max;
while (!bits64::isPowerOfTwo(t))
t = bits64::withoutRightmostBit(t);
return ValueRange(0, (t<<1)-1);
}
}
ValueRange binaryShiftLeft(unsigned bits) const {
return ValueRange(m_min<<bits, m_max<<bits);
}
ValueRange binaryShiftRight(unsigned bits) const {
return ValueRange(m_min>>bits, m_max>>bits);
}
ValueRange concat(const ValueRange &b, unsigned bits) const {
return binaryShiftLeft(bits).binaryOr(b);
}
ValueRange extract(uint64_t lowBit, uint64_t maxBit) const {
return binaryShiftRight(lowBit).binaryAnd(bits64::maxValueOfNBits(maxBit-lowBit));
}
ValueRange add(const ValueRange &b, unsigned width) const {
return ValueRange(0, bits64::maxValueOfNBits(width));
}
ValueRange sub(const ValueRange &b, unsigned width) const {
return ValueRange(0, bits64::maxValueOfNBits(width));
}
ValueRange mul(const ValueRange &b, unsigned width) const {
return ValueRange(0, bits64::maxValueOfNBits(width));
}
ValueRange udiv(const ValueRange &b, unsigned width) const {
return ValueRange(0, bits64::maxValueOfNBits(width));
}
ValueRange sdiv(const ValueRange &b, unsigned width) const {
return ValueRange(0, bits64::maxValueOfNBits(width));
}
ValueRange urem(const ValueRange &b, unsigned width) const {
return ValueRange(0, bits64::maxValueOfNBits(width));
}
ValueRange srem(const ValueRange &b, unsigned width) const {
return ValueRange(0, bits64::maxValueOfNBits(width));
}
// use min() to get value if true (XXX should we add a method to
// make code clearer?)
bool isFixed() const { return m_min==m_max; }
bool operator==(const ValueRange &b) const { return m_min==b.m_min && m_max==b.m_max; }
bool operator!=(const ValueRange &b) const { return !(*this==b); }
bool mustEqual(const uint64_t b) const { return m_min==m_max && m_min==b; }
bool mayEqual(const uint64_t b) const { return m_min<=b && m_max>=b; }
bool mustEqual(const ValueRange &b) const { return isFixed() && b.isFixed() && m_min==b.m_min; }
bool mayEqual(const ValueRange &b) const { return this->intersects(b); }
uint64_t min() const {
assert(!isEmpty() && "cannot get minimum of empty range");
return m_min;
}
uint64_t max() const {
assert(!isEmpty() && "cannot get maximum of empty range");
return m_max;
}
int64_t minSigned(unsigned bits) const {
assert((m_min>>bits)==0 && (m_max>>bits)==0 &&
"range is outside given number of bits");
// if max allows sign bit to be set then it can be smallest value,
// otherwise since the range is not empty, min cannot have a sign
// bit
uint64_t smallest = ((uint64_t) 1 << (bits-1));
if (m_max >= smallest) {
return ints::sext(smallest, 64, bits);
} else {
return m_min;
}
}
int64_t maxSigned(unsigned bits) const {
assert((m_min>>bits)==0 && (m_max>>bits)==0 &&
"range is outside given number of bits");
uint64_t smallest = ((uint64_t) 1 << (bits-1));
// if max and min have sign bit then max is max, otherwise if only
// max has sign bit then max is largest signed integer, otherwise
// max is max
if (m_min < smallest && m_max >= smallest) {
return smallest - 1;
} else {
return ints::sext(m_max, 64, bits);
}
}
};
inline std::ostream &operator<<(std::ostream &os, const ValueRange &vr) {
vr.print(os);
return os;
}
// used to find all memory object ids and the maximum size of any
// object state that references them (for symbolic size).
class ObjectFinder : public ExprVisitor {
protected:
Action visitRead(const ReadExpr &re) {
addUpdates(re.updates);
return Action::doChildren();
}
// XXX nice if this information was cached somewhere, used by
// independence as well right?
void addUpdates(const UpdateList &ul) {
for (const UpdateNode *un=ul.head; un; un=un->next) {
visit(un->index);
visit(un->value);
}
addObject(*ul.root);
}
public:
void addObject(const Array& array) {
unsigned id = array.id;
std::map<unsigned,unsigned>::iterator it = results.find(id);
// FIXME: Not 64-bit size clean.
if (it == results.end()) {
results[id] = (unsigned) array.size;
} else {
it->second = std::max(it->second, (unsigned) array.size);
}
}
public:
std::map<unsigned, unsigned> results;
};
// XXX waste of space, rather have ByteValueRange
typedef ValueRange CexValueData;
class CexObjectData {
public:
unsigned size;
CexValueData *values;
public:
CexObjectData(unsigned _size) : size(_size), values(new CexValueData[size]) {
for (unsigned i=0; i<size; i++)
values[i] = ValueRange(0, 255);
}
};
class CexRangeEvaluator : public ExprRangeEvaluator<ValueRange> {
public:
std::map<unsigned, CexObjectData> &objectValues;
CexRangeEvaluator(std::map<unsigned, CexObjectData> &_objectValues)
: objectValues(_objectValues) {}
ValueRange getInitialReadRange(const Array &os, ValueRange index) {
return ValueRange(0, 255);
}
};
class CexConstifier : public ExprEvaluator {
protected:
ref<Expr> getInitialValue(const Array& array, unsigned index) {
std::map<unsigned, CexObjectData>::iterator it =
objectValues.find(array.id);
assert(it != objectValues.end() && "missing object?");
CexObjectData &cod = it->second;
if (index >= cod.size) {
return ReadExpr::create(UpdateList(&array, true, 0),
ConstantExpr::alloc(index, Expr::Int32));
} else {
CexValueData &cvd = cod.values[index];
assert(cvd.min() == cvd.max() && "value is not fixed");
return ConstantExpr::alloc(cvd.min(), Expr::Int8);
}
}
public:
std::map<unsigned, CexObjectData> &objectValues;
CexConstifier(std::map<unsigned, CexObjectData> &_objectValues)
: objectValues(_objectValues) {}
};
class CexData {
public:
std::map<unsigned, CexObjectData> objectValues;
public:
CexData(ObjectFinder &finder) {
for (std::map<unsigned,unsigned>::iterator it = finder.results.begin(),
ie = finder.results.end(); it != ie; ++it) {
objectValues.insert(std::pair<unsigned, CexObjectData>(it->first,
CexObjectData(it->second)));
}
}
~CexData() {
for (std::map<unsigned, CexObjectData>::iterator it = objectValues.begin(),
ie = objectValues.end(); it != ie; ++it)
delete[] it->second.values;
}
void forceExprToValue(ref<Expr> e, uint64_t value) {
forceExprToRange(e, CexValueData(value,value));
}
void forceExprToRange(ref<Expr> e, CexValueData range) {
#ifdef LOG
// *theLog << "force: " << e << " to " << range << "\n";
#endif
switch (e->getKind()) {
case Expr::Constant: {
// rather a pity if the constant isn't in the range, but how can
// we use this?
break;
}
// Special
case Expr::NotOptimized: break;
case Expr::Read: {
ReadExpr *re = cast<ReadExpr>(e);
const Array *array = re->updates.root;
CexObjectData &cod = objectValues.find(array->id)->second;
// XXX we need to respect the version here and object state chain
if (re->index->isConstant() &&
re->index->getConstantValue() < array->size) {
CexValueData &cvd = cod.values[re->index->getConstantValue()];
CexValueData tmp = cvd.set_intersection(range);
if (tmp.isEmpty()) {
if (range.isFixed()) // ranges conflict, if new one is fixed use that
cvd = range;
} else {
cvd = tmp;
}
} else {
// XXX fatal("XXX not implemented");
}
break;
}
case Expr::Select: {
SelectExpr *se = cast<SelectExpr>(e);
ValueRange cond = evalRangeForExpr(se->cond);
if (cond.isFixed()) {
if (cond.min()) {
forceExprToRange(se->trueExpr, range);
} else {
forceExprToRange(se->falseExpr, range);
}
} else {
// XXX imprecise... we have a choice here. One method is to
// simply force both sides into the specified range (since the
// condition is indetermined). This may lose in two ways, the
// first is that the condition chosen may limit further
// restrict the range in each of the children, however this is
// less of a problem as the range will be a superset of legal
// values. The other is if the condition ends up being forced
// by some other constraints, then we needlessly forced one
// side into the given range.
//
// The other method would be to force the condition to one
// side and force that side into the given range. This loses
// when we force the condition to an unsatisfiable value
// (either because the condition cannot be that, or the
// resulting range given that condition is not in the required
// range).
//
// Currently we just force both into the range. A hybrid would
// be to evaluate the ranges for each of the children... if
// one of the ranges happens to already be a subset of the
// required range then it may be preferable to force the
// condition to that side.
forceExprToRange(se->trueExpr, range);
forceExprToRange(se->falseExpr, range);
}
break;
}
// XXX imprecise... the problem here is that extracting bits
// loses information about what bits are connected across the
// bytes. if a value can be 1 or 256 then either the top or
// lower byte is 0, but just extraction loses this information
// and will allow neither,one,or both to be 1.
//
// we can protect against this in a limited fashion by writing
// the extraction a byte at a time, then checking the evaluated
// value, isolating for that range, and continuing.
case Expr::Concat: {
ConcatExpr *ce = cast<ConcatExpr>(e);
if (ce->is2ByteConcat()) {
forceExprToRange(ce->getKid(0), range.extract( 8, 16));
forceExprToRange(ce->getKid(1), range.extract( 0, 8));
}
else if (ce->is4ByteConcat()) {
forceExprToRange(ce->getKid(0), range.extract(24, 32));
forceExprToRange(ce->getKid(1), range.extract(16, 24));
forceExprToRange(ce->getKid(2), range.extract( 8, 16));
forceExprToRange(ce->getKid(3), range.extract( 0, 8));
}
else if (ce->is8ByteConcat()) {
forceExprToRange(ce->getKid(0), range.extract(56, 64));
forceExprToRange(ce->getKid(1), range.extract(48, 56));
forceExprToRange(ce->getKid(2), range.extract(40, 48));
forceExprToRange(ce->getKid(3), range.extract(32, 40));
forceExprToRange(ce->getKid(4), range.extract(24, 32));
forceExprToRange(ce->getKid(5), range.extract(16, 24));
forceExprToRange(ce->getKid(6), range.extract( 8, 16));
forceExprToRange(ce->getKid(7), range.extract( 0, 8));
}
break;
}
case Expr::Extract: {
// XXX
break;
}
// Casting
// Simply intersect the output range with the range of all
// possible outputs and then truncate to the desired number of
// bits.
// For ZExt this simplifies to just intersection with the
// possible input range.
case Expr::ZExt: {
CastExpr *ce = cast<CastExpr>(e);
unsigned inBits = ce->src->getWidth();
ValueRange input = range.set_intersection(ValueRange(0, bits64::maxValueOfNBits(inBits)));
forceExprToRange(ce->src, input);
break;
}
// For SExt instead of doing the intersection we just take the output range
// minus the impossible values. This is nicer since it is a single interval.
case Expr::SExt: {
CastExpr *ce = cast<CastExpr>(e);
unsigned inBits = ce->src->getWidth();
unsigned outBits = ce->width;
ValueRange output = range.set_difference(ValueRange(1<<(inBits-1),
(bits64::maxValueOfNBits(outBits)-
bits64::maxValueOfNBits(inBits-1)-1)));
ValueRange input = output.binaryAnd(bits64::maxValueOfNBits(inBits));
forceExprToRange(ce->src, input);
break;
}
// Binary
case Expr::And: {
BinaryExpr *be = cast<BinaryExpr>(e);
if (be->getWidth()==Expr::Bool) {
if (range.isFixed()) {
ValueRange left = evalRangeForExpr(be->left);
ValueRange right = evalRangeForExpr(be->right);
if (!range.min()) {
if (left.mustEqual(0) || right.mustEqual(0)) {
// all is well
} else {
// XXX heuristic, which order
forceExprToValue(be->left, 0);
left = evalRangeForExpr(be->left);
// see if that worked
if (!left.mustEqual(1))
forceExprToValue(be->right, 0);
}
} else {
if (!left.mustEqual(1)) forceExprToValue(be->left, 1);
if (!right.mustEqual(1)) forceExprToValue(be->right, 1);
}
}
} else {
// XXX
}
break;
}
case Expr::Or: {
BinaryExpr *be = cast<BinaryExpr>(e);
if (be->getWidth()==Expr::Bool) {
if (range.isFixed()) {
ValueRange left = evalRangeForExpr(be->left);
ValueRange right = evalRangeForExpr(be->right);
if (range.min()) {
if (left.mustEqual(1) || right.mustEqual(1)) {
// all is well
} else {
// XXX heuristic, which order?
// force left to value we need
forceExprToValue(be->left, 1);
left = evalRangeForExpr(be->left);
// see if that worked
if (!left.mustEqual(1))
forceExprToValue(be->right, 1);
}
} else {
if (!left.mustEqual(0)) forceExprToValue(be->left, 0);
if (!right.mustEqual(0)) forceExprToValue(be->right, 0);
}
}
} else {
// XXX
}
break;
}
case Expr::Xor: break;
// Comparison
case Expr::Eq: {
BinaryExpr *be = cast<BinaryExpr>(e);
if (range.isFixed()) {
if (be->left->isConstant()) {
uint64_t value = be->left->getConstantValue();
if (range.min()) {
forceExprToValue(be->right, value);
} else {
if (value==0) {
forceExprToRange(be->right,
CexValueData(1,
ints::sext(1,
be->right->getWidth(),
1)));
} else {
// XXX heuristic / lossy, could be better to pick larger range?
forceExprToRange(be->right, CexValueData(0, value-1));
}
}
} else {
// XXX what now
}
}
break;
}
case Expr::Ult: {
BinaryExpr *be = cast<BinaryExpr>(e);
// XXX heuristic / lossy, what order if conflict
if (range.isFixed()) {
ValueRange left = evalRangeForExpr(be->left);
ValueRange right = evalRangeForExpr(be->right);
uint64_t maxValue = bits64::maxValueOfNBits(be->right->getWidth());
// XXX should deal with overflow (can lead to empty range)
if (left.isFixed()) {
if (range.min()) {
forceExprToRange(be->right, CexValueData(left.min()+1, maxValue));
} else {
forceExprToRange(be->right, CexValueData(0, left.min()));
}
} else if (right.isFixed()) {
if (range.min()) {
forceExprToRange(be->left, CexValueData(0, right.min()-1));
} else {
forceExprToRange(be->left, CexValueData(right.min(), maxValue));
}
} else {
// XXX ???
}
}
break;
}
case Expr::Ule: {
BinaryExpr *be = cast<BinaryExpr>(e);
// XXX heuristic / lossy, what order if conflict
if (range.isFixed()) {
ValueRange left = evalRangeForExpr(be->left);
ValueRange right = evalRangeForExpr(be->right);
// XXX should deal with overflow (can lead to empty range)
uint64_t maxValue = bits64::maxValueOfNBits(be->right->getWidth());
if (left.isFixed()) {
if (range.min()) {
forceExprToRange(be->right, CexValueData(left.min(), maxValue));
} else {
forceExprToRange(be->right, CexValueData(0, left.min()-1));
}
} else if (right.isFixed()) {
if (range.min()) {
forceExprToRange(be->left, CexValueData(0, right.min()));
} else {
forceExprToRange(be->left, CexValueData(right.min()+1, maxValue));
}
} else {
// XXX ???
}
}
break;
}
case Expr::Ne:
case Expr::Ugt:
case Expr::Uge:
case Expr::Sgt:
case Expr::Sge:
assert(0 && "invalid expressions (uncanonicalized");
default:
break;
}
}
void fixValues() {
for (std::map<unsigned, CexObjectData>::iterator it = objectValues.begin(),
ie = objectValues.end(); it != ie; ++it) {
CexObjectData &cod = it->second;
for (unsigned i=0; i<cod.size; i++) {
CexValueData &cvd = cod.values[i];
cvd = CexValueData(cvd.min() + (cvd.max()-cvd.min())/2);
}
}
}
ValueRange evalRangeForExpr(ref<Expr> &e) {
CexRangeEvaluator ce(objectValues);
return ce.evaluate(e);
}
bool exprMustBeValue(ref<Expr> e, uint64_t value) {
CexConstifier cc(objectValues);
ref<Expr> v = cc.visit(e);
if (!v->isConstant()) return false;
// XXX reenable once all reads and vars are fixed
// assert(v.isConstant() && "not all values have been fixed");
return v->getConstantValue() == value;
}
};
/* *** */
class FastCexSolver : public IncompleteSolver {
public:
FastCexSolver();
~FastCexSolver();
IncompleteSolver::PartialValidity computeTruth(const Query&);
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);
};
FastCexSolver::FastCexSolver() { }
FastCexSolver::~FastCexSolver() { }
IncompleteSolver::PartialValidity
FastCexSolver::computeTruth(const Query& query) {
#ifdef LOG
std::ostringstream log;
theLog = &log;
// log << "------ start FastCexSolver::mustBeTrue ------\n";
log << "-- QUERY --\n";
unsigned i=0;
for (ConstraintManager::const_iterator it = query.constraints.begin(),
ie = query.constraints.end(); it != ie; ++it)
log << " C" << i++ << ": " << *it << ", \n";
log << " Q : " << query.expr << "\n";
#endif
ObjectFinder of;
for (ConstraintManager::const_iterator it = query.constraints.begin(),
ie = query.constraints.end(); it != ie; ++it)
of.visit(*it);
of.visit(query.expr);
CexData cd(of);
for (ConstraintManager::const_iterator it = query.constraints.begin(),
ie = query.constraints.end(); it != ie; ++it)
cd.forceExprToValue(*it, 1);
cd.forceExprToValue(query.expr, 0);
#ifdef LOG
log << " -- ranges --\n";
for (std::map<unsigned, CexObjectData>::iterator it = objectValues.begin(),
ie = objectValues.end(); it != ie; ++it) {
CexObjectData &cod = it->second;
log << " arr" << it->first << "[" << cod.size << "] = [";
unsigned continueFrom=cod.size-1;
for (; continueFrom>0; continueFrom--)
if (cod.values[continueFrom-1]!=cod.values[continueFrom])
break;
for (unsigned i=0; i<cod.size; i++) {
log << cod.values[i];
if (i<cod.size-1) {
log << ", ";
if (i==continueFrom) {
log << "...";
break;
}
}
}
log << "]\n";
}
#endif
// this could be done lazily of course
cd.fixValues();
#ifdef LOG
log << " -- fixed values --\n";
for (std::map<unsigned, CexObjectData>::iterator it = objectValues.begin(),
ie = objectValues.end(); it != ie; ++it) {
CexObjectData &cod = it->second;
log << " arr" << it->first << "[" << cod.size << "] = [";
unsigned continueFrom=cod.size-1;
for (; continueFrom>0; continueFrom--)
if (cod.values[continueFrom-1]!=cod.values[continueFrom])
break;
for (unsigned i=0; i<cod.size; i++) {
log << cod.values[i];
if (i<cod.size-1) {
log << ", ";
if (i==continueFrom) {
log << "...";
break;
}
}
}
log << "]\n";
}
#endif
// check the result
bool isGood = true;
if (!cd.exprMustBeValue(query.expr, 0)) isGood = false;
for (ConstraintManager::const_iterator it = query.constraints.begin(),
ie = query.constraints.end(); it != ie; ++it)
if (!cd.exprMustBeValue(*it, 1))
isGood = false;
#ifdef LOG
log << " -- evaluating result --\n";
i=0;
for (ConstraintManager::const_iterator it = query.constraints.begin(),
ie = query.constraints.end(); it != ie; ++it) {
bool res = cd.exprMustBeValue(*it, 1);
log << " C" << i++ << ": " << (res?"true":"false") << "\n";
}
log << " Q : "
<< (cd.exprMustBeValue(query.expr, 0)?"true":"false") << "\n";
log << "\n\n";
#endif
return isGood ? IncompleteSolver::MayBeFalse : IncompleteSolver::None;
}
bool FastCexSolver::computeValue(const Query& query, ref<Expr> &result) {
ObjectFinder of;
for (ConstraintManager::const_iterator it = query.constraints.begin(),
ie = query.constraints.end(); it != ie; ++it)
of.visit(*it);
of.visit(query.expr);
CexData cd(of);
for (ConstraintManager::const_iterator it = query.constraints.begin(),
ie = query.constraints.end(); it != ie; ++it)
cd.forceExprToValue(*it, 1);
// this could be done lazily of course
cd.fixValues();
// check the result
for (ConstraintManager::const_iterator it = query.constraints.begin(),
ie = query.constraints.end(); it != ie; ++it)
if (!cd.exprMustBeValue(*it, 1))
return false;
CexConstifier cc(cd.objectValues);
ref<Expr> value = cc.visit(query.expr);
if (value->isConstant()) {
result = value;
return true;
} else {
return false;
}
}
bool
FastCexSolver::computeInitialValues(const Query& query,
const std::vector<const Array*>
&objects,
std::vector< std::vector<unsigned char> >
&values,
bool &hasSolution) {
ObjectFinder of;
for (ConstraintManager::const_iterator it = query.constraints.begin(),
ie = query.constraints.end(); it != ie; ++it)
of.visit(*it);
of.visit(query.expr);
for (unsigned i = 0; i != objects.size(); ++i)
of.addObject(*objects[i]);
CexData cd(of);
for (ConstraintManager::const_iterator it = query.constraints.begin(),
ie = query.constraints.end(); it != ie; ++it)
cd.forceExprToValue(*it, 1);
cd.forceExprToValue(query.expr, 0);
// this could be done lazily of course
cd.fixValues();
// check the result
for (ConstraintManager::const_iterator it = query.constraints.begin(),
ie = query.constraints.end(); it != ie; ++it)
if (!cd.exprMustBeValue(*it, 1))
return false;
if (!cd.exprMustBeValue(query.expr, 0))
return false;
hasSolution = true;
CexConstifier cc(cd.objectValues);
for (unsigned i = 0; i != objects.size(); ++i) {
const Array *array = objects[i];
std::vector<unsigned char> data;
data.reserve(array->size);
for (unsigned i=0; i < array->size; i++) {
ref<Expr> value =
cc.visit(ReadExpr::create(UpdateList(array, true, 0),
ConstantExpr::create(i,
kMachinePointerType)));
if (value->isConstant()) {
data.push_back(value->getConstantValue());
} else {
// FIXME: When does this happen?
return false;
}
}
values.push_back(data);
}
return true;
}
Solver *klee::createFastCexSolver(Solver *s) {
return new Solver(new StagedSolverImpl(new FastCexSolver(), s));
}
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