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/******************************************************************************
* Top contributors (to current version):
* Ying Sheng, Aina Niemetz, Yoni Zohar
*
* This file is part of the cvc5 project.
*
* Copyright (c) 2009-2021 by the authors listed in the file AUTHORS
* in the top-level source directory and their institutional affiliations.
* All rights reserved. See the file COPYING in the top-level source
* directory for licensing information.
* ****************************************************************************
*
* Ackermannization preprocessing pass.
*
* This implements the Ackermannization preprocessing pass, which enables
* very limited theory combination support for eager bit-blasting via
* Ackermannization. It reduces constraints over the combination of the
* theories of fixed-size bit-vectors and uninterpreted functions as
* described in
* Liana Hadarean, An Efficient and Trustworthy Theory Solver for
* Bit-vectors in Satisfiability Modulo Theories.
* https://cs.nyu.edu/media/publications/hadarean_liana.pdf
*/
#include "cvc4_private.h"
#ifndef CVC5__PREPROCESSING__PASSES__ACKERMANN_H
#define CVC5__PREPROCESSING__PASSES__ACKERMANN_H
#include <unordered_map>
#include "expr/node.h"
#include "preprocessing/preprocessing_pass.h"
#include "theory/logic_info.h"
#include "theory/substitutions.h"
namespace cvc5 {
namespace preprocessing {
namespace passes {
using TNodeSet = std::unordered_set<TNode, TNodeHashFunction>;
using FunctionToArgsMap =
std::unordered_map<TNode, TNodeSet, TNodeHashFunction>;
using USortToBVSizeMap =
std::unordered_map<TypeNode, size_t, TypeNode::HashFunction>;
class Ackermann : public PreprocessingPass
{
public:
Ackermann(PreprocessingPassContext* preprocContext);
protected:
/**
* Apply Ackermannization as follows:
*
* - For each application f(X) where X = (x1, . . . , xn), introduce a fresh
* variable f_X and use it to replace all occurrences of f(X).
*
* - For each f(X) and f(Y) with X = (x1, . . . , xn) and Y = (y1, . . . , yn)
* occurring in the input formula, add the following lemma:
* (x_1 = y_1 /\ ... /\ x_n = y_n) => f_X = f_Y
*
* - For each uninterpreted sort S, suppose k is the number of variables with
* sort S, then for each such variable X, introduce a fresh variable BV_X
* with BV with size log_2(k)+1 and use it to replace all occurrences of X.
*/
PreprocessingPassResult applyInternal(
AssertionPipeline* assertionsToPreprocess) override;
private:
/* Map each function to a set of terms associated with it */
FunctionToArgsMap d_funcToArgs;
/* Map each function-application term to the new Skolem variable created by
* ackermannization */
theory::SubstitutionMap d_funcToSkolem;
/* Map each variable with uninterpreted sort to the new Skolem BV variable
* created by ackermannization */
theory::SubstitutionMap d_usVarsToBVVars;
/* Map each uninterpreted sort to the number of variables in this sort. */
USortToBVSizeMap d_usortCardinality;
LogicInfo d_logic;
};
} // namespace passes
} // namespace preprocessing
} // namespace cvc5
#endif /* CVC5__PREPROCESSING__PASSES__ACKERMANN_H */
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