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/******************************************************************************
* Top contributors (to current version):
* Andrew Reynolds
*
* 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.
* ****************************************************************************
*
* Function definition processor for finite model finding.
*/
#ifndef CVC5__PREPROCESSING__PASSES__FUN_DEF_FMF_H
#define CVC5__PREPROCESSING__PASSES__FUN_DEF_FMF_H
#include <map>
#include <vector>
#include "context/cdlist.h"
#include "expr/node.h"
#include "preprocessing/preprocessing_pass.h"
namespace cvc5 {
namespace preprocessing {
namespace passes {
/**
* Preprocessing pass to allow finite model finding for admissible recursive
* function definitions. For details, see Reynolds et al "Model Finding for
* Recursive Functions" IJCAR 2016.
*/
class FunDefFmf : public PreprocessingPass
{
/** The types for the recursive function definitions */
typedef context::CDList<Node> NodeList;
public:
FunDefFmf(PreprocessingPassContext* preprocContext);
~FunDefFmf();
protected:
/**
* Run the preprocessing pass on the pipeline, taking into account the
* previous definitions.
*/
PreprocessingPassResult applyInternal(
AssertionPipeline* assertionsToPreprocess) override;
private:
/** Run the preprocessing pass on the pipeline. */
void process(AssertionPipeline* assertionsToPreprocess);
/** simplify formula
* This is A_0 in Figure 1 of Reynolds et al "Model Finding for Recursive
* Functions". The input of A_0 in that paper is a pair ( term t, polarity p )
* The return value of A_0 in that paper is a pair ( term t', set of formulas
* X ).
*
* This function implements this such that :
* n is t
* pol/hasPol is p
* the return value is t'
* the set of formulas X are stored in "constraints"
*
* Additionally, is_fun_def is whether we are currently processing the top of
* a function defintion, since this affects whether we process the head of the
* definition.
*/
Node simplifyFormula(Node n,
bool pol,
bool hasPol,
std::vector<Node>& constraints,
Node hd,
bool is_fun_def,
std::map<int, std::map<Node, Node>>& visited,
std::map<int, std::map<Node, Node>>& visited_cons);
/** get constraints
*
* This computes constraints for the final else branch of A_0 in Figure 1
* of Reynolds et al "Model Finding for Recursive Functions". The range of
* the cache visited stores the constraint (if any) for each node.
*/
void getConstraints(Node n,
std::vector<Node>& constraints,
std::map<Node, Node>& visited);
/** recursive function definition abstractions for fmf-fun */
std::map<Node, TypeNode> d_fmfRecFunctionsAbs;
/** map to concrete definitions for fmf-fun */
std::map<Node, std::vector<Node>> d_fmfRecFunctionsConcrete;
/** List of defined recursive functions processed by fmf-fun */
NodeList* d_fmfRecFunctionsDefined;
// defined functions to input sort (alpha)
std::map<Node, TypeNode> d_sorts;
// defined functions to injections input -> argument elements (gamma)
std::map<Node, std::vector<Node>> d_input_arg_inj;
// (newly) defined functions
std::vector<Node> d_funcs;
};
} // namespace passes
} // namespace preprocessing
} // namespace cvc5
#endif /* CVC5__PREPROCESSING__PASSES__SYGUS_INFERENCE_H_ */
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