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path: root/lib/Solver/CexCachingSolver.cpp
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//===-- CexCachingSolver.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/SolverImpl.h"
#include "klee/TimerStatIncrementer.h"
#include "klee/util/Assignment.h"
#include "klee/util/ExprUtil.h"
#include "klee/util/ExprVisitor.h"
#include "klee/Internal/ADT/MapOfSets.h"

#include "SolverStats.h"

#include "llvm/Support/CommandLine.h"

using namespace klee;
using namespace llvm;

namespace {
  cl::opt<bool>
  DebugCexCacheCheckBinding("debug-cex-cache-check-binding");

  cl::opt<bool>
  CexCacheTryAll("cex-cache-try-all",
                 cl::desc("try substituting all counterexamples before asking STP"),
                 cl::init(false));

  cl::opt<bool>
  CexCacheExperimental("cex-cache-exp", cl::init(false));

}

///

typedef std::set< ref<Expr> > KeyType;

struct AssignmentLessThan {
  bool operator()(const Assignment *a, const Assignment *b) {
    return a->bindings < b->bindings;
  }
};


class CexCachingSolver : public SolverImpl {
  typedef std::set<Assignment*, AssignmentLessThan> assignmentsTable_ty;

  Solver *solver;
  
  MapOfSets<ref<Expr>, Assignment*> cache;
  // memo table
  assignmentsTable_ty assignmentsTable;

  bool searchForAssignment(KeyType &key, 
                           Assignment *&result);
  
  bool lookupAssignment(const Query& query, Assignment *&result);

  bool getAssignment(const Query& query, Assignment *&result);
  
public:
  CexCachingSolver(Solver *_solver) : solver(_solver) {}
  ~CexCachingSolver();
  
  bool computeTruth(const Query&, bool &isValid);
  bool computeValidity(const Query&, Solver::Validity &result);
  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);
};

///

struct NullAssignment {
  bool operator()(Assignment *a) const { return !a; }
};

struct NonNullAssignment {
  bool operator()(Assignment *a) const { return a!=0; }
};

struct NullOrSatisfyingAssignment {
  KeyType &key;
  
  NullOrSatisfyingAssignment(KeyType &_key) : key(_key) {}

  bool operator()(Assignment *a) const { 
    return !a || a->satisfies(key.begin(), key.end()); 
  }
};

bool CexCachingSolver::searchForAssignment(KeyType &key, Assignment *&result) {
  Assignment * const *lookup = cache.lookup(key);
  if (lookup) {
    result = *lookup;
    return true;
  }

  if (CexCacheTryAll) {
    Assignment **lookup = cache.findSuperset(key, NonNullAssignment());
    if (!lookup) lookup = cache.findSubset(key, NullAssignment());
    if (lookup) {
      result = *lookup;
      return true;
    }
    for (assignmentsTable_ty::iterator it = assignmentsTable.begin(), 
           ie = assignmentsTable.end(); it != ie; ++it) {
      Assignment *a = *it;
      if (a->satisfies(key.begin(), key.end())) {
        result = a;
        return true;
      }
    }
  } else {
    // XXX which order? one is sure to be better
    Assignment **lookup = cache.findSuperset(key, NonNullAssignment());
    if (!lookup) lookup = cache.findSubset(key, NullOrSatisfyingAssignment(key));
    if (lookup) {
      result = *lookup;
      return true;
    }
  }
  
  return false;
}

bool CexCachingSolver::lookupAssignment(const Query &query, 
                                        Assignment *&result) {
  KeyType key(query.constraints.begin(), query.constraints.end());
  ref<Expr> neg = Expr::createNot(query.expr);
  if (neg.isConstant()) {
    if (!neg->getConstantValue()) {
      result = (Assignment*) 0;
      return true;
    }
  } else {
    key.insert(neg);
  }

  return searchForAssignment(key, result);
}

bool CexCachingSolver::getAssignment(const Query& query, Assignment *&result) {
  KeyType key(query.constraints.begin(), query.constraints.end());
  ref<Expr> neg = Expr::createNot(query.expr);
  if (neg.isConstant()) {
    if (!neg->getConstantValue()) {
      result = (Assignment*) 0;
      return true;
    }
  } else {
    key.insert(neg);
  }

  if (!searchForAssignment(key, result)) {
    // need to solve
    
    std::vector<const Array*> objects;
    findSymbolicObjects(key.begin(), key.end(), objects);

    std::vector< std::vector<unsigned char> > values;
    bool hasSolution;
    if (!solver->impl->computeInitialValues(query, objects, values, 
                                            hasSolution))
      return false;
    
    Assignment *binding;
    if (hasSolution) {
      binding = new Assignment(objects, values);

      // memoization
      std::pair<assignmentsTable_ty::iterator, bool>
        res = assignmentsTable.insert(binding);
      if (!res.second) {
        delete binding;
        binding = *res.first;
      }

      if (DebugCexCacheCheckBinding)
        assert(binding->satisfies(key.begin(), key.end()));
    } else {
      binding = (Assignment*) 0;
    }

    result = binding;
    cache.insert(key, binding);
  }

  return true;
}

///

CexCachingSolver::~CexCachingSolver() {
  cache.clear();
  delete solver;
  for (assignmentsTable_ty::iterator it = assignmentsTable.begin(), 
         ie = assignmentsTable.end(); it != ie; ++it)
    delete *it;
}

bool CexCachingSolver::computeValidity(const Query& query,
                                       Solver::Validity &result) {
  TimerStatIncrementer t(stats::cexCacheTime);
  Assignment *a;
  if (!getAssignment(query.withFalse(), a))
    return false;
  assert(a && "computeValidity() must have assignment");
  ref<Expr> q = a->evaluate(query.expr);
  assert(q.isConstant() && "assignment evaluation did not result in constant");

  if (q->getConstantValue()) {
    if (!getAssignment(query, a))
      return false;
    result = !a ? Solver::True : Solver::Unknown;
  } else {
    if (!getAssignment(query.negateExpr(), a))
      return false;
    result = !a ? Solver::False : Solver::Unknown;
  }
  
  return true;
}

bool CexCachingSolver::computeTruth(const Query& query,
                                    bool &isValid) {
  TimerStatIncrementer t(stats::cexCacheTime);

  // There is a small amount of redundancy here. We only need to know
  // truth and do not really need to compute an assignment. This means
  // that we could check the cache to see if we already know that
  // state ^ query has no assignment. In that case, by the validity of
  // state, we know that state ^ !query must have an assignment, and
  // so query cannot be true (valid). This does get hits, but doesn't
  // really seem to be worth the overhead.

  if (CexCacheExperimental) {
    Assignment *a;
    if (lookupAssignment(query.negateExpr(), a) && !a)
      return false;
  }

  Assignment *a;
  if (!getAssignment(query, a))
    return false;

  isValid = !a;

  return true;
}

bool CexCachingSolver::computeValue(const Query& query,
                                    ref<Expr> &result) {
  TimerStatIncrementer t(stats::cexCacheTime);

  Assignment *a;
  if (!getAssignment(query.withFalse(), a))
    return false;
  assert(a && "computeValue() must have assignment");
  result = a->evaluate(query.expr);  
  assert(result.isConstant() && 
         "assignment evaluation did not result in constant");
  return true;
}

bool 
CexCachingSolver::computeInitialValues(const Query& query,
                                       const std::vector<const Array*> 
                                         &objects,
                                       std::vector< std::vector<unsigned char> >
                                         &values,
                                       bool &hasSolution) {
  TimerStatIncrementer t(stats::cexCacheTime);
  Assignment *a;
  if (!getAssignment(query, a))
    return false;
  hasSolution = !!a;
  
  if (!a)
    return true;

  // FIXME: We should use smarter assignment for result so we don't
  // need redundant copy.
  values = std::vector< std::vector<unsigned char> >(objects.size());
  for (unsigned i=0; i < objects.size(); ++i) {
    const Array *os = objects[i];
    Assignment::bindings_ty::iterator it = a->bindings.find(os);
    
    if (it == a->bindings.end()) {
      values[i] = std::vector<unsigned char>(os->size, 0);
    } else {
      values[i] = it->second;
    }
  }
  
  return true;
}

///

Solver *klee::createCexCachingSolver(Solver *_solver) {
  return new Solver(new CexCachingSolver(_solver));
}