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2 Commits
v0.1.8 ... v0.1.7-rc.

Author SHA1 Message Date
Patrick Lühne
fc4edc670a Version bump for release 0.1.7 RC 3 2018-04-07 02:16:15 +02:00
Patrick Lühne
bf6bf7f9c3 Support placeholders with #external declarations 
This adds support for declaring predicates as placeholders through the
“#external” directive in the input language of clingo.

Placeholders are not subject to completion. This prevents predicates
that represent instance-specific facts from being assumed as universally
false by default negation when translating an encoding.

This stretches clingo’s usual syntax a bit in order to make the
implementation lightweight. In order to declare a predicate with a
specific arity as a placeholder, the following statement needs to be
added to the input program:
 2018-04-07 02:12:53 +02:00
26 changed files with 180 additions and 1368 deletions
Expand all files Collapse all files

2
.ci/Dockerfile-ubuntu-18.04
View File

@@ -3,7 +3,7 @@ FROM ubuntu:18.04
ARG toolchain
RUN apt-get update
RUN apt-get install -y bison cmake git ninja-build re2c
RUN apt-get install -y cmake git ninja-build re2c
RUN if [ "${toolchain}" = "gcc" ]; then apt-get install -y g++; fi
RUN if [ "${toolchain}" = "clang" ]; then apt-get install -y clang; fi

10
CHANGELOG.md
View File

@@ -1,14 +1,6 @@
# Change Log
## 0.1.8 (2018-04-20)
### Features
* more and advanced simplification rules
* adds support for exponentiation (power) and modulus (absolute value)
* new examples: prime numbers, permutation generator, and graph coloring (extended)
## 0.1.7 (2018-04-08)
## 0.1.7 RC 3 (2018-04-07)
### Features

2
LICENSE.md
View File

@@ -1,6 +1,6 @@
# The MIT License (MIT)
Copyright © 20162018 Patrick Lühne
Copyright © 20162017 Patrick Lühne
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal

5
README.md
View File

@@ -9,11 +9,10 @@
## Usage
```bash
$ anthem [--complete] [--simplify] file...
$ anthem [--simplify] file...
```
`--complete` instructs `anthem` to perform Clarks completion on the translated formulas.
With the option `--simplify`, the output formulas are simplified by applying several basic transformation rules.
With the option `--simplify`, output formulas are simplified by applying several basic transformation rules.
## Building

2
app/main.cpp
View File

@@ -70,7 +70,7 @@ int main(int argc, char **argv)
if (version)
{
std::cout << "anthem version 0.1.8" << std::endl;
std::cout << "anthem version 0.1.7-rc.3" << std::endl;
return EXIT_SUCCESS;
}

20
examples/graph-coloring.lp
View File

@@ -1,10 +1,12 @@
#external color(1).
#external edge(2).
#external vertex(1).
#show color/2.
colored(V, red) :- vertex(V), not colored(V, green), not colored(V, blue).
colored(V, green) :- vertex(V), not colored(V, red), not colored(V, blue).
colored(V, blue) :- vertex(V), not colored(V, red), not colored(V, green).
{color(V, C)} :- vertex(V), color(C).
covered(V) :- color(V, _).
:- vertex(V), not covered(V).
:- color(V1, C), color(V2, C), edge(V1, V2).
:- color(V, C1), color(V, C2), C1 != C2.
:- edge(V1, V2), colored(V1, C), colored(V2, C).
vertex(a).
vertex(b).
vertex(c).
edge(a, b).
edge(a, c).

12
examples/permutations.lp
View File

@@ -1,12 +0,0 @@
{p(1..n, 1..n)}.
:- p(X, Y1), p(X, Y2), Y1 != Y2.
:- p(X1, Y), p(X2, Y), X1 != X2.
q1(X) :- p(X, _).
q2(Y) :- p(_, Y).
:- not q1(X), X = 1..n.
:- not q2(Y), Y = 1..n.
#show p/2.

4
examples/prime.lp
View File

@@ -1,4 +0,0 @@
#show prime/1.
composite(I * J) :- I = 2..n, J = 2..n.
prime(N) :- N = 2..n, not composite(N).

2
examples/schur-numbers.lp
View File

@@ -3,5 +3,3 @@ covered(I) :- in(I, S).
:- I = 1..n, not covered(I).
:- in(I, S), in(J, S), in(I + J, S).
#show in/2.

27
include/anthem/AST.h
View File

@@ -32,8 +32,7 @@ struct BinaryOperation
Minus,
Multiplication,
Division,
Modulo,
Power
Modulo
};
explicit BinaryOperation(Operator operator_, Term &&left, Term &&right)
@@ -293,30 +292,6 @@ struct String
////////////////////////////////////////////////////////////////////////////////////////////////////
struct UnaryOperation
{
enum class Operator
{
Absolute
};
explicit UnaryOperation(Operator operator_, Term &&argument)
: operator_{operator_},
argument{std::move(argument)}
{
}
UnaryOperation(const UnaryOperation &other) = delete;
UnaryOperation &operator=(const UnaryOperation &other) = delete;
UnaryOperation(UnaryOperation &&other) noexcept = default;
UnaryOperation &operator=(UnaryOperation &&other) noexcept = default;
Operator operator_;
Term argument;
};
////////////////////////////////////////////////////////////////////////////////////////////////////
struct Variable
{
explicit Variable(VariableDeclaration *declaration)

2
include/anthem/ASTForward.h
View File

@@ -37,7 +37,6 @@ struct Or;
struct Predicate;
struct SpecialInteger;
struct String;
struct UnaryOperation;
struct Variable;
struct VariableDeclaration;
using VariableDeclarationPointer = std::unique_ptr<VariableDeclaration>;
@@ -69,7 +68,6 @@ using Term = Clingo::Variant<
Interval,
SpecialInteger,
String,
UnaryOperation,
Variable>;
////////////////////////////////////////////////////////////////////////////////////////////////////

8
include/anthem/ASTVisitors.h
View File

@@ -165,14 +165,6 @@ struct RecursiveTermVisitor
return T::accept(string, term, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
ReturnType visit(UnaryOperation &unaryOperation, Term &term, Arguments &&... arguments)
{
unaryOperation.argument.accept(*this, unaryOperation.argument, std::forward<Arguments>(arguments)...);
return T::accept(unaryOperation, term, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
ReturnType visit(Variable &variable, Term &term, Arguments &&... arguments)
{

430
include/anthem/Equality.h
View File

@@ -1,430 +0,0 @@
#ifndef __ANTHEM__EQUALITY_H
#define __ANTHEM__EQUALITY_H
#include <anthem/AST.h>
#include <anthem/ASTUtils.h>
namespace anthem
{
namespace ast
{
////////////////////////////////////////////////////////////////////////////////////////////////////
//
// Equality
//
////////////////////////////////////////////////////////////////////////////////////////////////////
// TODO: move to separate class
enum class Tristate
{
True,
False,
Unknown,
};
////////////////////////////////////////////////////////////////////////////////////////////////////
Tristate equal(const Formula &lhs, const Formula &rhs);
Tristate equal(const Term &lhs, const Term &rhs);
////////////////////////////////////////////////////////////////////////////////////////////////////
struct FormulaEqualityVisitor
{
Tristate visit(const And &and_, const Formula &otherFormula)
{
if (!otherFormula.is<And>())
return Tristate::Unknown;
const auto &otherAnd = otherFormula.get<And>();
for (const auto &argument : and_.arguments)
{
const auto match = std::find_if(
otherAnd.arguments.cbegin(), otherAnd.arguments.cend(),
[&](const auto &otherArgument)
{
return equal(argument, otherArgument) == Tristate::True;
});
if (match == otherAnd.arguments.cend())
return Tristate::Unknown;
}
for (const auto &otherArgument : otherAnd.arguments)
{
const auto match = std::find_if(
and_.arguments.cbegin(), and_.arguments.cend(),
[&](const auto &argument)
{
return equal(otherArgument, argument) == Tristate::True;
});
if (match == and_.arguments.cend())
return Tristate::Unknown;
}
return Tristate::True;
}
Tristate visit(const Biconditional &biconditional, const Formula &otherFormula)
{
if (!otherFormula.is<Biconditional>())
return Tristate::Unknown;
const auto &otherBiconditional = otherFormula.get<Biconditional>();
if (equal(biconditional.left, otherBiconditional.left) == Tristate::True
&& equal(biconditional.right, otherBiconditional.right) == Tristate::True)
{
return Tristate::True;
}
if (equal(biconditional.left, otherBiconditional.right) == Tristate::True
&& equal(biconditional.right, otherBiconditional.left) == Tristate::True)
{
return Tristate::True;
}
return Tristate::Unknown;
}
Tristate visit(const Boolean &boolean, const Formula &otherFormula)
{
if (!otherFormula.is<Boolean>())
return Tristate::Unknown;
const auto &otherBoolean = otherFormula.get<Boolean>();
return (boolean.value == otherBoolean.value)
? Tristate::True
: Tristate::False;
}
Tristate visit(const Comparison &comparison, const Formula &otherFormula)
{
if (!otherFormula.is<Comparison>())
return Tristate::Unknown;
const auto &otherComparison = otherFormula.get<Comparison>();
if (comparison.operator_ != otherComparison.operator_)
return Tristate::Unknown;
if (equal(comparison.left, otherComparison.left) == Tristate::True
&& equal(comparison.right, otherComparison.right) == Tristate::True)
{
return Tristate::True;
}
// Only = and != are commutative operators, all others dont need to be checked with exchanged arguments
if (comparison.operator_ != Comparison::Operator::Equal
&& comparison.operator_ != Comparison::Operator::NotEqual)
{
return Tristate::Unknown;
}
if (equal(comparison.left, otherComparison.right) == Tristate::True
&& equal(comparison.right, otherComparison.left) == Tristate::True)
{
return Tristate::True;
}
return Tristate::Unknown;
}
Tristate visit(const Exists &, const Formula &otherFormula)
{
if (!otherFormula.is<Exists>())
return Tristate::Unknown;
// TODO: implement stronger check
return Tristate::Unknown;
}
Tristate visit(const ForAll &, const Formula &otherFormula)
{
if (!otherFormula.is<ForAll>())
return Tristate::Unknown;
// TODO: implement stronger check
return Tristate::Unknown;
}
Tristate visit(const Implies &implies, const Formula &otherFormula)
{
if (!otherFormula.is<Implies>())
return Tristate::Unknown;
const auto &otherImplies = otherFormula.get<Implies>();
if (equal(implies.antecedent, otherImplies.antecedent) == Tristate::True
&& equal(implies.consequent, otherImplies.consequent) == Tristate::True)
{
return Tristate::True;
}
return Tristate::Unknown;
}
Tristate visit(const In &in, const Formula &otherFormula)
{
if (!otherFormula.is<In>())
return Tristate::Unknown;
const auto &otherIn = otherFormula.get<In>();
if (equal(in.element, otherIn.element) == Tristate::True
&& equal(in.set, otherIn.set) == Tristate::True)
{
return Tristate::True;
}
return Tristate::Unknown;
}
Tristate visit(const Not &not_, const Formula &otherFormula)
{
if (!otherFormula.is<Not>())
return Tristate::Unknown;
const auto &otherNot = otherFormula.get<Not>();
return equal(not_.argument, otherNot.argument);
}
Tristate visit(const Or &or_, const Formula &otherFormula)
{
if (!otherFormula.is<Or>())
return Tristate::Unknown;
const auto &otherOr = otherFormula.get<Or>();
for (const auto &argument : or_.arguments)
{
const auto match = std::find_if(
otherOr.arguments.cbegin(), otherOr.arguments.cend(),
[&](const auto &otherArgument)
{
return equal(argument, otherArgument) == Tristate::True;
});
if (match == otherOr.arguments.cend())
return Tristate::Unknown;
}
for (const auto &otherArgument : otherOr.arguments)
{
const auto match = std::find_if(
or_.arguments.cbegin(), or_.arguments.cend(),
[&](const auto &argument)
{
return equal(otherArgument, argument) == Tristate::True;
});
if (match == or_.arguments.cend())
return Tristate::Unknown;
}
return Tristate::True;
}
Tristate visit(const Predicate &predicate, const Formula &otherFormula)
{
if (!otherFormula.is<Predicate>())
return Tristate::Unknown;
const auto &otherPredicate = otherFormula.get<Predicate>();
if (!matches(predicate, otherPredicate))
return Tristate::False;
assert(predicate.arguments.size() == otherPredicate.arguments.size());
for (size_t i = 0; i < predicate.arguments.size(); i++)
if (equal(predicate.arguments[i], otherPredicate.arguments[i]) != Tristate::True)
return Tristate::Unknown;
return Tristate::True;
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
struct TermEqualityVisitor
{
Tristate visit(const BinaryOperation &binaryOperation, const Term &otherTerm)
{
if (!otherTerm.is<BinaryOperation>())
return Tristate::Unknown;
const auto &otherBinaryOperation = otherTerm.get<BinaryOperation>();
if (binaryOperation.operator_ != otherBinaryOperation.operator_)
return Tristate::Unknown;
if (equal(binaryOperation.left, otherBinaryOperation.left) == Tristate::True
&& equal(binaryOperation.right, otherBinaryOperation.right) == Tristate::True)
{
return Tristate::True;
}
// Only + and * are commutative operators, all others dont need to be checked with exchanged arguments
if (binaryOperation.operator_ != BinaryOperation::Operator::Plus
&& binaryOperation.operator_ != BinaryOperation::Operator::Multiplication)
{
return Tristate::Unknown;
}
if (equal(binaryOperation.left, binaryOperation.right) == Tristate::True
&& equal(binaryOperation.right, binaryOperation.left) == Tristate::True)
{
return Tristate::True;
}
return Tristate::Unknown;
}
Tristate visit(const Boolean &boolean, const Term &otherTerm)
{
if (!otherTerm.is<Boolean>())
return Tristate::Unknown;
const auto &otherBoolean = otherTerm.get<Boolean>();
return (boolean.value == otherBoolean.value)
? Tristate::True
: Tristate::False;
}
Tristate visit(const Constant &constant, const Term &otherTerm)
{
if (!otherTerm.is<Constant>())
return Tristate::Unknown;
const auto &otherConstant = otherTerm.get<Constant>();
return (constant.name == otherConstant.name)
? Tristate::True
: Tristate::False;
}
Tristate visit(const Function &function, const Term &otherTerm)
{
if (!otherTerm.is<Function>())
return Tristate::Unknown;
const auto &otherFunction = otherTerm.get<Function>();
if (function.name != otherFunction.name)
return Tristate::False;
if (function.arguments.size() != otherFunction.arguments.size())
return Tristate::False;
for (size_t i = 0; i < function.arguments.size(); i++)
if (equal(function.arguments[i], otherFunction.arguments[i]) != Tristate::True)
return Tristate::Unknown;
return Tristate::True;
}
Tristate visit(const Integer &integer, const Term &otherTerm)
{
if (!otherTerm.is<Integer>())
return Tristate::Unknown;
const auto &otherInteger = otherTerm.get<Integer>();
return (integer.value == otherInteger.value)
? Tristate::True
: Tristate::False;
}
Tristate visit(const Interval &interval, const Term &otherTerm)
{
if (!otherTerm.is<Interval>())
return Tristate::Unknown;
const auto &otherInterval = otherTerm.get<Interval>();
if (equal(interval.from, otherInterval.from) != Tristate::True)
return Tristate::Unknown;
if (equal(interval.to, otherInterval.to) != Tristate::True)
return Tristate::Unknown;
return Tristate::True;
}
Tristate visit(const SpecialInteger &specialInteger, const Term &otherTerm)
{
if (!otherTerm.is<SpecialInteger>())
return Tristate::Unknown;
const auto &otherSpecialInteger = otherTerm.get<SpecialInteger>();
return (specialInteger.type == otherSpecialInteger.type)
? Tristate::True
: Tristate::False;
}
Tristate visit(const String &string, const Term &otherTerm)
{
if (!otherTerm.is<String>())
return Tristate::Unknown;
const auto &otherString = otherTerm.get<String>();
return (string.text == otherString.text)
? Tristate::True
: Tristate::False;
}
Tristate visit(const UnaryOperation &unaryOperation, const Term &otherTerm)
{
if (!otherTerm.is<UnaryOperation>())
return Tristate::Unknown;
const auto &otherUnaryOperation = otherTerm.get<UnaryOperation>();
if (unaryOperation.operator_ != otherUnaryOperation.operator_)
return Tristate::Unknown;
return equal(unaryOperation.argument, otherUnaryOperation.argument);
}
Tristate visit(const Variable &variable, const Term &otherTerm)
{
if (!otherTerm.is<Variable>())
return Tristate::Unknown;
const auto &otherVariable = otherTerm.get<Variable>();
return (variable.declaration == otherVariable.declaration)
? Tristate::True
: Tristate::False;
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
Tristate equal(const Formula &lhs, const Formula &rhs)
{
return lhs.accept(FormulaEqualityVisitor(), rhs);
}
////////////////////////////////////////////////////////////////////////////////////////////////////
Tristate equal(const Term &lhs, const Term &rhs)
{
return lhs.accept(TermEqualityVisitor(), rhs);
}
////////////////////////////////////////////////////////////////////////////////////////////////////
}
}
#endif

8
include/anthem/Simplification.h
View File

@@ -12,14 +12,6 @@ namespace anthem
//
////////////////////////////////////////////////////////////////////////////////////////////////////
enum class SimplificationResult
{
Simplified,
Unchanged,
};
////////////////////////////////////////////////////////////////////////////////////////////////////
void simplify(ast::Formula &formula);
////////////////////////////////////////////////////////////////////////////////////////////////////

198
include/anthem/SimplificationVisitors.h
View File

@@ -1,198 +0,0 @@
#ifndef __ANTHEM__SIMPLIFICATION_VISITORS_H
#define __ANTHEM__SIMPLIFICATION_VISITORS_H
#include <anthem/AST.h>
#include <anthem/Simplification.h>
namespace anthem
{
namespace ast
{
////////////////////////////////////////////////////////////////////////////////////////////////////
//
// Simplification Visitor
//
////////////////////////////////////////////////////////////////////////////////////////////////////
template<class T>
struct FormulaSimplificationVisitor
{
template <class... Arguments>
SimplificationResult visit(And &and_, Formula &formula, Arguments &&... arguments)
{
for (auto &argument : and_.arguments)
if (argument.accept(*this, argument, std::forward<Arguments>(arguments)...) == SimplificationResult::Simplified)
return SimplificationResult::Simplified;
return T::accept(formula, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(Biconditional &biconditional, Formula &formula, Arguments &&... arguments)
{
if (biconditional.left.accept(*this, biconditional.left, std::forward<Arguments>(arguments)...) == SimplificationResult::Simplified)
return SimplificationResult::Simplified;
if (biconditional.right.accept(*this, biconditional.right, std::forward<Arguments>(arguments)...) == SimplificationResult::Simplified)
return SimplificationResult::Simplified;
return T::accept(formula, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(Boolean &, Formula &formula, Arguments &&... arguments)
{
return T::accept(formula, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(Comparison &, Formula &formula, Arguments &&... arguments)
{
return T::accept(formula, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(Exists &exists, Formula &formula, Arguments &&... arguments)
{
if (exists.argument.accept(*this, exists.argument, std::forward<Arguments>(arguments)...) == SimplificationResult::Simplified)
return SimplificationResult::Simplified;
return T::accept(formula, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(ForAll &forAll, Formula &formula, Arguments &&... arguments)
{
if (forAll.argument.accept(*this, forAll.argument, std::forward<Arguments>(arguments)...) == SimplificationResult::Simplified)
return SimplificationResult::Simplified;
return T::accept(formula, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(Implies &implies, Formula &formula, Arguments &&... arguments)
{
if (implies.antecedent.accept(*this, implies.antecedent, std::forward<Arguments>(arguments)...) == SimplificationResult::Simplified)
return SimplificationResult::Simplified;
if (implies.consequent.accept(*this, implies.consequent, std::forward<Arguments>(arguments)...) == SimplificationResult::Simplified)
return SimplificationResult::Simplified;
return T::accept(formula, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(In &, Formula &formula, Arguments &&... arguments)
{
return T::accept(formula, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(Not &not_, Formula &formula, Arguments &&... arguments)
{
if (not_.argument.accept(*this, not_.argument, std::forward<Arguments>(arguments)...) == SimplificationResult::Simplified)
return SimplificationResult::Simplified;
return T::accept(formula, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(Or &or_, Formula &formula, Arguments &&... arguments)
{
for (auto &argument : or_.arguments)
if (argument.accept(*this, argument, std::forward<Arguments>(arguments)...) == SimplificationResult::Simplified)
return SimplificationResult::Simplified;
return T::accept(formula, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(Predicate &, Formula &formula, Arguments &&... arguments)
{
return T::accept(formula, std::forward<Arguments>(arguments)...);
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
template<class T, class SimplificationResult = void>
struct TermSimplificationVisitor
{
template <class... Arguments>
SimplificationResult visit(BinaryOperation &binaryOperation, Term &term, Arguments &&... arguments)
{
if (binaryOperation.left.accept(*this, binaryOperation.left, std::forward<Arguments>(arguments)...) == SimplificationResult::Simplified)
return SimplificationResult::Simplified;
if (binaryOperation.right.accept(*this, binaryOperation.right, std::forward<Arguments>(arguments)...) == SimplificationResult::Simplified)
return SimplificationResult::Simplified;
return T::accept(term, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(Boolean &, Term &term, Arguments &&... arguments)
{
return T::accept(term, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(Constant &, Term &term, Arguments &&... arguments)
{
return T::accept(term, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(Function &function, Term &term, Arguments &&... arguments)
{
for (auto &argument : function.arguments)
if (argument.accept(*this, argument, std::forward<Arguments>(arguments)...) == SimplificationResult::Simplified)
return SimplificationResult::Simplified;
return T::accept(term, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(Integer &, Term &term, Arguments &&... arguments)
{
return T::accept(term, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(Interval &interval, Term &term, Arguments &&... arguments)
{
if (interval.from.accept(*this, interval.from, std::forward<Arguments>(arguments)...) == SimplificationResult::Simplified)
return SimplificationResult::Simplified;
if (interval.to.accept(*this, interval.to, std::forward<Arguments>(arguments)...) == SimplificationResult::Simplified)
return SimplificationResult::Simplified;
return T::accept(term, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(SpecialInteger &, Term &term, Arguments &&... arguments)
{
return T::accept(term, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(String &, Term &term, Arguments &&... arguments)
{
return T::accept(term, std::forward<Arguments>(arguments)...);
}
template <class... Arguments>
SimplificationResult visit(Variable &, Term &term, Arguments &&... arguments)
{
return T::accept(term, std::forward<Arguments>(arguments)...);
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
}
}
#endif

43
include/anthem/Term.h
View File

@@ -23,12 +23,6 @@ ast::BinaryOperation::Operator translate(Clingo::AST::BinaryOperator binaryOpera
{
switch (binaryOperator)
{
case Clingo::AST::BinaryOperator::XOr:
throw TranslationException(term.location, "binary operation “xor” currently unsupported");
case Clingo::AST::BinaryOperator::Or:
throw TranslationException(term.location, "binary operation “or” currently unsupported");
case Clingo::AST::BinaryOperator::And:
throw TranslationException(term.location, "binary operation “and” currently unsupported");
case Clingo::AST::BinaryOperator::Plus:
return ast::BinaryOperation::Operator::Plus;
case Clingo::AST::BinaryOperator::Minus:
@@ -39,28 +33,11 @@ ast::BinaryOperation::Operator translate(Clingo::AST::BinaryOperator binaryOpera
return ast::BinaryOperation::Operator::Division;
case Clingo::AST::BinaryOperator::Modulo:
return ast::BinaryOperation::Operator::Modulo;
case Clingo::AST::BinaryOperator::Power:
return ast::BinaryOperation::Operator::Power;
default:
throw TranslationException(term.location, "“binary operation” terms currently unsupported");
}
throw TranslationException(term.location, "unknown binary operation");
}
////////////////////////////////////////////////////////////////////////////////////////////////////
ast::UnaryOperation::Operator translate(Clingo::AST::UnaryOperator unaryOperator, const Clingo::AST::Term &term)
{
switch (unaryOperator)
{
case Clingo::AST::UnaryOperator::Absolute:
return ast::UnaryOperation::Operator::Absolute;
case Clingo::AST::UnaryOperator::Minus:
throw TranslationException(term.location, "binary operation “minus” currently unsupported");
case Clingo::AST::UnaryOperator::Negation:
throw TranslationException(term.location, "binary operation “negation” currently unsupported");
}
throw TranslationException(term.location, "unknown unary operation");
return ast::BinaryOperation::Operator::Plus;
}
////////////////////////////////////////////////////////////////////////////////////////////////////
@@ -123,6 +100,12 @@ struct TermTranslateVisitor
return ast::Term::make<ast::Variable>(ruleContext.freeVariables.back().get());
}
std::optional<ast::Term> visit(const Clingo::AST::UnaryOperation &, const Clingo::AST::Term &term, RuleContext &, const ast::VariableStack &)
{
throw TranslationException(term.location, "“unary operation” terms currently unsupported");
return std::nullopt;
}
std::optional<ast::Term> visit(const Clingo::AST::BinaryOperation &binaryOperation, const Clingo::AST::Term &term, RuleContext &ruleContext, const ast::VariableStack &variableStack)
{
const auto operator_ = translate(binaryOperation.binary_operator, term);
@@ -132,14 +115,6 @@ struct TermTranslateVisitor
return ast::Term::make<ast::BinaryOperation>(operator_, std::move(left), std::move(right));
}
std::optional<ast::Term> visit(const Clingo::AST::UnaryOperation &unaryOperation, const Clingo::AST::Term &term, RuleContext &ruleContext, const ast::VariableStack &variableStack)
{
const auto operator_ = translate(unaryOperation.unary_operator, term);
auto argument = translate(unaryOperation.argument, ruleContext, variableStack);
return ast::Term::make<ast::UnaryOperation>(operator_, std::move(argument));
}
std::optional<ast::Term> visit(const Clingo::AST::Interval &interval, const Clingo::AST::Term &, RuleContext &ruleContext, const ast::VariableStack &variableStack)
{
auto left = translate(interval.left, ruleContext, variableStack);

165
include/anthem/output/AST.h
View File

@@ -41,39 +41,37 @@ struct PrintContext
////////////////////////////////////////////////////////////////////////////////////////////////////
output::ColorStream &print(output::ColorStream &stream, const BinaryOperation::Operator operator_, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const BinaryOperation &binaryOperation, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const Boolean &boolean, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const Comparison &comparison, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, Comparison::Operator operator_, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const Constant &constant, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const Function &function, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const In &in, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const Integer &integer, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const Interval &interval, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const Predicate &predicate, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const SpecialInteger &specialInteger, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const String &string, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const UnaryOperation &unaryOperation, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const Variable &variable, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const VariableDeclaration &variableDeclaration, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const BinaryOperation::Operator operator_, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const BinaryOperation &binaryOperation, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const Boolean &boolean, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const Comparison &comparison, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const Constant &constant, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const Function &function, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const In &in, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const Integer &integer, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const Interval &interval, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const Predicate &predicate, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const SpecialInteger &specialInteger, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const String &string, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const Variable &variable, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const VariableDeclaration &variableDeclaration, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const And &and_, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const Biconditional &biconditional, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const Exists &exists, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const ForAll &forAll, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const Implies &implies, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const Not &not_, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const Or &or_, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const And &and_, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const Biconditional &biconditional, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const Exists &exists, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const ForAll &forAll, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const Implies &implies, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const Not &not_, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const Or &or_, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const Formula &formula, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const Term &term, PrintContext &printContext, bool omitParentheses = false);
output::ColorStream &print(output::ColorStream &stream, const Formula &formula, PrintContext &printContext);
output::ColorStream &print(output::ColorStream &stream, const Term &term, PrintContext &printContext);
////////////////////////////////////////////////////////////////////////////////////////////////////
// Primitives
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, BinaryOperation::Operator operator_, PrintContext &, bool)
inline output::ColorStream &print(output::ColorStream &stream, BinaryOperation::Operator operator_, PrintContext &)
{
switch (operator_)
{
@@ -87,8 +85,6 @@ inline output::ColorStream &print(output::ColorStream &stream, BinaryOperation::
return (stream << output::Operator("/"));
case BinaryOperation::Operator::Modulo:
return (stream << output::Operator("%"));
case BinaryOperation::Operator::Power:
return (stream << output::Operator("**"));
}
return stream;
@@ -96,26 +92,22 @@ inline output::ColorStream &print(output::ColorStream &stream, BinaryOperation::
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const BinaryOperation &binaryOperation, PrintContext &printContext, bool omitParentheses)
inline output::ColorStream &print(output::ColorStream &stream, const BinaryOperation &binaryOperation, PrintContext &printContext)
{
if (!omitParentheses || printContext.context.parenthesisStyle == ParenthesisStyle::Full)
stream << "(";
stream << "(";
print(stream, binaryOperation.left, printContext);
stream << " ";
print(stream, binaryOperation.operator_, printContext);
stream << " ";
print(stream, binaryOperation.right, printContext);
if (!omitParentheses || printContext.context.parenthesisStyle == ParenthesisStyle::Full)
stream << ")";
stream << ")";
return stream;
}
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const Boolean &boolean, PrintContext &, bool)
inline output::ColorStream &print(output::ColorStream &stream, const Boolean &boolean, PrintContext &)
{
if (boolean.value)
return (stream << output::Boolean("#true"));
@@ -125,7 +117,7 @@ inline output::ColorStream &print(output::ColorStream &stream, const Boolean &bo
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, Comparison::Operator operator_, PrintContext &, bool)
inline output::ColorStream &print(output::ColorStream &stream, Comparison::Operator operator_, PrintContext &)
{
switch (operator_)
{
@@ -148,7 +140,7 @@ inline output::ColorStream &print(output::ColorStream &stream, Comparison::Opera
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const Comparison &comparison, PrintContext &printContext, bool)
inline output::ColorStream &print(output::ColorStream &stream, const Comparison &comparison, PrintContext &printContext)
{
if (printContext.context.parenthesisStyle == ParenthesisStyle::Full)
stream << "(";
@@ -167,14 +159,14 @@ inline output::ColorStream &print(output::ColorStream &stream, const Comparison
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const Constant &constant, PrintContext &, bool)
inline output::ColorStream &print(output::ColorStream &stream, const Constant &constant, PrintContext &)
{
return (stream << constant.name);
}
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const Function &function, PrintContext &printContext, bool)
inline output::ColorStream &print(output::ColorStream &stream, const Function &function, PrintContext &printContext)
{
stream << function.name;
@@ -201,7 +193,7 @@ inline output::ColorStream &print(output::ColorStream &stream, const Function &f
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const In &in, PrintContext &printContext, bool)
inline output::ColorStream &print(output::ColorStream &stream, const In &in, PrintContext &printContext)
{
if (printContext.context.parenthesisStyle == ParenthesisStyle::Full)
stream << "(";
@@ -218,14 +210,14 @@ inline output::ColorStream &print(output::ColorStream &stream, const In &in, Pri
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const Integer &integer, PrintContext &, bool)
inline output::ColorStream &print(output::ColorStream &stream, const Integer &integer, PrintContext &)
{
return (stream << output::Number<int>(integer.value));
}
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const Interval &interval, PrintContext &printContext, bool)
inline output::ColorStream &print(output::ColorStream &stream, const Interval &interval, PrintContext &printContext)
{
if (printContext.context.parenthesisStyle == ParenthesisStyle::Full)
stream << "(";
@@ -242,7 +234,7 @@ inline output::ColorStream &print(output::ColorStream &stream, const Interval &i
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const Predicate &predicate, PrintContext &printContext, bool)
inline output::ColorStream &print(output::ColorStream &stream, const Predicate &predicate, PrintContext &printContext)
{
stream << predicate.name;
@@ -266,7 +258,7 @@ inline output::ColorStream &print(output::ColorStream &stream, const Predicate &
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const SpecialInteger &specialInteger, PrintContext &, bool)
inline output::ColorStream &print(output::ColorStream &stream, const SpecialInteger &specialInteger, PrintContext &)
{
switch (specialInteger.type)
{
@@ -281,37 +273,14 @@ inline output::ColorStream &print(output::ColorStream &stream, const SpecialInte
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const String &string, PrintContext &, bool)
inline output::ColorStream &print(output::ColorStream &stream, const String &string, PrintContext &)
{
return (stream << output::String(string.text.c_str()));
}
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const UnaryOperation &unaryOperation, PrintContext &printContext, bool)
{
switch (unaryOperation.operator_)
{
case UnaryOperation::Operator::Absolute:
stream << "|";
break;
}
print(stream, unaryOperation.argument, printContext, true);
switch (unaryOperation.operator_)
{
case UnaryOperation::Operator::Absolute:
stream << "|";
break;
}
return stream;
}
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const Variable &variable, PrintContext &printContext, bool)
inline output::ColorStream &print(output::ColorStream &stream, const Variable &variable, PrintContext &printContext)
{
assert(variable.declaration != nullptr);
@@ -320,7 +289,7 @@ inline output::ColorStream &print(output::ColorStream &stream, const Variable &v
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const VariableDeclaration &variableDeclaration, PrintContext &printContext, bool)
inline output::ColorStream &print(output::ColorStream &stream, const VariableDeclaration &variableDeclaration, PrintContext &printContext)
{
const auto printVariableDeclaration =
[&stream, &variableDeclaration](const auto *prefix, auto &variableIDs) -> output::ColorStream &
@@ -356,10 +325,9 @@ inline output::ColorStream &print(output::ColorStream &stream, const VariableDec
// Expressions
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const And &and_, PrintContext &printContext, bool omitParentheses)
inline output::ColorStream &print(output::ColorStream &stream, const And &and_, PrintContext &printContext)
{
if (!omitParentheses || printContext.context.parenthesisStyle == ParenthesisStyle::Full)
stream << "(";
stream << "(";
for (auto i = and_.arguments.cbegin(); i != and_.arguments.cend(); i++)
{
@@ -369,32 +337,27 @@ inline output::ColorStream &print(output::ColorStream &stream, const And &and_,
print(stream, *i, printContext);
}
if (!omitParentheses || printContext.context.parenthesisStyle == ParenthesisStyle::Full)
stream << ")";
stream << ")";
return stream;
}
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const Biconditional &biconditional, PrintContext &printContext, bool omitParentheses)
inline output::ColorStream &print(output::ColorStream &stream, const Biconditional &biconditional, PrintContext &printContext)
{
if (!omitParentheses || printContext.context.parenthesisStyle == ParenthesisStyle::Full)
stream << "(";
stream << "(";
print(stream, biconditional.left, printContext);
stream << " <-> ";
print(stream, biconditional.right, printContext);
if (!omitParentheses || printContext.context.parenthesisStyle == ParenthesisStyle::Full)
stream << ")";
stream << ")";
return stream;
}
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const Exists &exists, PrintContext &printContext, bool)
inline output::ColorStream &print(output::ColorStream &stream, const Exists &exists, PrintContext &printContext)
{
if (printContext.context.parenthesisStyle == ParenthesisStyle::Full)
stream << "(";
@@ -420,7 +383,7 @@ inline output::ColorStream &print(output::ColorStream &stream, const Exists &exi
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const ForAll &forAll, PrintContext &printContext, bool)
inline output::ColorStream &print(output::ColorStream &stream, const ForAll &forAll, PrintContext &printContext)
{
if (printContext.context.parenthesisStyle == ParenthesisStyle::Full)
stream << "(";
@@ -446,24 +409,20 @@ inline output::ColorStream &print(output::ColorStream &stream, const ForAll &for
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const Implies &implies, PrintContext &printContext, bool omitParentheses)
inline output::ColorStream &print(output::ColorStream &stream, const Implies &implies, PrintContext &printContext)
{
if (!omitParentheses || printContext.context.parenthesisStyle == ParenthesisStyle::Full)
stream << "(";
stream << "(";
print(stream, implies.antecedent, printContext);
stream << " -> ";
print(stream, implies.consequent, printContext);
if (!omitParentheses || printContext.context.parenthesisStyle == ParenthesisStyle::Full)
stream << ")";
stream << ")";
return stream;
}
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const Not &not_, PrintContext &printContext, bool)
inline output::ColorStream &print(output::ColorStream &stream, const Not &not_, PrintContext &printContext)
{
if (printContext.context.parenthesisStyle == ParenthesisStyle::Full)
stream << "(";
@@ -479,10 +438,9 @@ inline output::ColorStream &print(output::ColorStream &stream, const Not &not_,
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const Or &or_, PrintContext &printContext, bool omitParentheses)
inline output::ColorStream &print(output::ColorStream &stream, const Or &or_, PrintContext &printContext)
{
if (!omitParentheses || printContext.context.parenthesisStyle == ParenthesisStyle::Full)
stream << "(";
stream << "(";
for (auto i = or_.arguments.cbegin(); i != or_.arguments.cend(); i++)
{
@@ -492,8 +450,7 @@ inline output::ColorStream &print(output::ColorStream &stream, const Or &or_, Pr
print(stream, *i, printContext);
}
if (!omitParentheses || printContext.context.parenthesisStyle == ParenthesisStyle::Full)
stream << ")";
stream << ")";
return stream;
}
@@ -506,24 +463,24 @@ template<class Variant>
struct VariantPrintVisitor
{
template<class T>
output::ColorStream &visit(const T &x, output::ColorStream &stream, PrintContext &printContext, bool omitParentheses)
output::ColorStream &visit(const T &x, output::ColorStream &stream, PrintContext &printContext)
{
return print(stream, x, printContext, omitParentheses);
return print(stream, x, printContext);
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const Formula &formula, PrintContext &printContext, bool omitParentheses)
inline output::ColorStream &print(output::ColorStream &stream, const Formula &formula, PrintContext &printContext)
{
return formula.accept(VariantPrintVisitor<Formula>(), stream, printContext, omitParentheses);
return formula.accept(VariantPrintVisitor<Formula>(), stream, printContext);
}
////////////////////////////////////////////////////////////////////////////////////////////////////
inline output::ColorStream &print(output::ColorStream &stream, const Term &term, PrintContext &printContext, bool omitParentheses)
inline output::ColorStream &print(output::ColorStream &stream, const Term &term, PrintContext &printContext)
{
return term.accept(VariantPrintVisitor<Term>(), stream, printContext, omitParentheses);
return term.accept(VariantPrintVisitor<Term>(), stream, printContext);
}
////////////////////////////////////////////////////////////////////////////////////////////////////

2
lib/clingo

Submodule lib/clingo updated: 969ce8f618...e2187b697f

2
lib/cxxopts

Submodule lib/cxxopts updated: ca6e9f70eb...abe9ebd6b4

13
src/anthem/ASTCopy.cpp
View File

@@ -159,13 +159,6 @@ String prepareCopy(const String &other)
////////////////////////////////////////////////////////////////////////////////////////////////////
UnaryOperation prepareCopy(const UnaryOperation &other)
{
return UnaryOperation(other.operator_, prepareCopy(other.argument));
}
////////////////////////////////////////////////////////////////////////////////////////////////////
Variable prepareCopy(const Variable &other)
{
return Variable(other.declaration);
@@ -327,12 +320,6 @@ struct FixDanglingVariablesInTermVisitor
{
}
template <class... Arguments>
void visit(UnaryOperation &unaryOperation, Arguments &&... arguments)
{
unaryOperation.argument.accept(*this, std::forward<Arguments>(arguments)...);
}
void visit(Variable &variable, ScopedFormula &scopedFormula, VariableStack &variableStack,
std::map<VariableDeclaration *, VariableDeclaration *> &replacements)
{

7
src/anthem/ASTUtils.cpp
View File

@@ -59,7 +59,7 @@ bool VariableStack::contains(const VariableDeclaration &variableDeclaration) con
};
const auto layerContainsVariableDeclaration =
[&variableDeclarationMatches](const auto &layer)
[&variableDeclaration, &variableDeclarationMatches](const auto &layer)
{
return (std::find_if(layer->cbegin(), layer->cend(), variableDeclarationMatches) != layer->cend());
};
@@ -178,11 +178,6 @@ struct CollectFreeVariablesVisitor
{
}
void visit(UnaryOperation &unaryOperation, VariableStack &variableStack, std::vector<VariableDeclaration *> &freeVariables)
{
unaryOperation.argument.accept(*this, variableStack, freeVariables);
}
void visit(Variable &variable, VariableStack &variableStack, std::vector<VariableDeclaration *> &freeVariables)
{
if (variableStack.contains(*variable.declaration))

480
src/anthem/Simplification.cpp
View File

@@ -3,9 +3,7 @@
#include <optional>
#include <anthem/ASTCopy.h>
#include <anthem/Equality.h>
#include <anthem/output/AST.h>
#include <anthem/SimplificationVisitors.h>
#include <anthem/ASTVisitors.h>
namespace anthem
{
@@ -99,65 +97,18 @@ struct ReplaceVariableInFormulaVisitor : public ast::RecursiveFormulaVisitor<Rep
////////////////////////////////////////////////////////////////////////////////////////////////////
template<class SimplificationRule>
SimplificationResult simplify(ast::Formula &formula)
// Simplifies exists statements by using the equivalence “exists X (X = t and F(X))” == “F(t)”
// The exists statement has to be of the form “exists <variables> <conjunction>”
void simplify(ast::Exists &exists, ast::Formula &formula)
{
return SimplificationRule::apply(formula);
}
////////////////////////////////////////////////////////////////////////////////////////////////////
template<class FirstSimplificationRule, class SecondSimplificationRule, class... OtherSimplificationRules>
SimplificationResult simplify(ast::Formula &formula)
{
if (simplify<FirstSimplificationRule>(formula) == SimplificationResult::Simplified)
return SimplificationResult::Simplified;
return simplify<SecondSimplificationRule, OtherSimplificationRules...>(formula);
}
////////////////////////////////////////////////////////////////////////////////////////////////////
struct SimplificationRuleExistsWithoutQuantifiedVariables
{
static constexpr const auto Description = "exists () (F) === F";
static SimplificationResult apply(ast::Formula &formula)
// Simplify formulas like “exists X (X = Y)” to “#true”
// TODO: check that this covers all cases
if (exists.argument.is<ast::Comparison>())
{
if (!formula.is<ast::Exists>())
return SimplificationResult::Unchanged;
auto &exists = formula.get<ast::Exists>();
if (!exists.variables.empty())
return SimplificationResult::Unchanged;
formula = std::move(exists.argument);
return SimplificationResult::Simplified;
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
struct SimplificationRuleTrivialAssignmentInExists
{
static constexpr const auto Description = "exists X (X = Y) === #true";
static SimplificationResult apply(ast::Formula &formula)
{
if (!formula.is<ast::Exists>())
return SimplificationResult::Unchanged;
const auto &exists = formula.get<ast::Exists>();
if (!exists.argument.is<ast::Comparison>())
return SimplificationResult::Unchanged;
const auto &comparison = exists.argument.get<ast::Comparison>();
if (comparison.operator_ != ast::Comparison::Operator::Equal)
return SimplificationResult::Unchanged;
return;
const auto matchingAssignment = std::find_if(exists.variables.cbegin(), exists.variables.cend(),
[&](const auto &variableDeclaration)
@@ -166,378 +117,107 @@ struct SimplificationRuleTrivialAssignmentInExists
|| matchesVariableDeclaration(comparison.right, *variableDeclaration);
});
if (matchingAssignment == exists.variables.cend())
return SimplificationResult::Unchanged;
if (matchingAssignment != exists.variables.cend())
formula = ast::Formula::make<ast::Boolean>(true);
formula = ast::Formula::make<ast::Boolean>(true);
return SimplificationResult::Simplified;
return;
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
if (!exists.argument.is<ast::And>())
return;
struct SimplificationRuleAssignmentInExists
{
static constexpr const auto Description = "exists X (X = t and F(X)) === exists () (F(t))";
auto &conjunction = exists.argument.get<ast::And>();
auto &arguments = conjunction.arguments;
static SimplificationResult apply(ast::Formula &formula)
// Simplify formulas of type “exists X (X = t and F(X))” to “F(t)”
for (auto i = exists.variables.begin(); i != exists.variables.end();)
{
if (!formula.is<ast::Exists>())
return SimplificationResult::Unchanged;
const auto &variableDeclaration = **i;
auto &exists = formula.get<ast::Exists>();
bool wasVariableReplaced = false;
if (!exists.argument.is<ast::And>())
return SimplificationResult::Unchanged;
auto &and_ = exists.argument.get<ast::And>();
auto &arguments = and_.arguments;
auto simplificationResult = SimplificationResult::Unchanged;
for (auto i = exists.variables.begin(); i != exists.variables.end();)
// TODO: refactor
for (auto j = arguments.begin(); j != arguments.end(); j++)
{
const auto &variableDeclaration = **i;
auto &argument = *j;
// Find term that is equivalent to the given variable
auto assignedTerm = extractAssignedTerm(argument, variableDeclaration);
bool wasVariableReplaced = false;
if (!assignedTerm)
continue;
// TODO: refactor
for (auto j = arguments.begin(); j != arguments.end(); j++)
// Replace all occurrences of the variable with the equivalent term
for (auto k = arguments.begin(); k != arguments.end(); k++)
{
auto &argument = *j;
// Find term that is equivalent to the given variable
auto assignedTerm = extractAssignedTerm(argument, variableDeclaration);
if (!assignedTerm)
if (k == j)
continue;
// Replace all occurrences of the variable with the equivalent term
for (auto k = arguments.begin(); k != arguments.end(); k++)
{
if (k == j)
continue;
auto &otherArgument = *k;
otherArgument.accept(ReplaceVariableInFormulaVisitor(), otherArgument, variableDeclaration, assignedTerm.value());
}
arguments.erase(j);
wasVariableReplaced = true;
simplificationResult = SimplificationResult::Simplified;
break;
auto &otherArgument = *k;
otherArgument.accept(ReplaceVariableInFormulaVisitor(), otherArgument, variableDeclaration, assignedTerm.value());
}
if (wasVariableReplaced)
{
i = exists.variables.erase(i);
continue;
}
i++;
arguments.erase(j);
wasVariableReplaced = true;
break;
}
return simplificationResult;
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
struct SimplificationRuleEmptyConjunction
{
static constexpr const auto Description = "[empty conjunction] === #true";
static SimplificationResult apply(ast::Formula &formula)
{
if (!formula.is<ast::And>())
return SimplificationResult::Unchanged;
auto &and_ = formula.get<ast::And>();
if (!and_.arguments.empty())
return SimplificationResult::Unchanged;
formula = ast::Formula::make<ast::Boolean>(true);
return SimplificationResult::Simplified;
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
struct SimplificationRuleOneElementConjunction
{
static constexpr const auto Description = "[conjunction of only F] === F";
static SimplificationResult apply(ast::Formula &formula)
{
if (!formula.is<ast::And>())
return SimplificationResult::Unchanged;
auto &and_ = formula.get<ast::And>();
if (and_.arguments.size() != 1)
return SimplificationResult::Unchanged;
formula = std::move(and_.arguments.front());
return SimplificationResult::Simplified;
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
struct SimplificationRuleTrivialExists
{
static constexpr const auto Description = "exists ... ([#true/#false]) === [#true/#false]";
static SimplificationResult apply(ast::Formula &formula)
{
if (!formula.is<ast::Exists>())
return SimplificationResult::Unchanged;
auto &exists = formula.get<ast::Exists>();
if (!exists.argument.is<ast::Boolean>())
return SimplificationResult::Unchanged;
formula = std::move(exists.argument);
return SimplificationResult::Simplified;
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
struct SimplificationRuleInWithPrimitiveArguments
{
static constexpr const auto Description = "[primitive A] in [primitive B] === A = B";
static SimplificationResult apply(ast::Formula &formula)
{
if (!formula.is<ast::In>())
return SimplificationResult::Unchanged;
auto &in = formula.get<ast::In>();
assert(ast::isPrimitive(in.element));
if (!ast::isPrimitive(in.element) || !ast::isPrimitive(in.set))
return SimplificationResult::Unchanged;
formula = ast::Comparison(ast::Comparison::Operator::Equal, std::move(in.element), std::move(in.set));
return SimplificationResult::Simplified;
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
struct SimplificationRuleSubsumptionInBiconditionals
{
static constexpr const auto Description = "(F <-> (F and G)) === (F -> G)";
static SimplificationResult apply(ast::Formula &formula)
{
if (!formula.is<ast::Biconditional>())
return SimplificationResult::Unchanged;
auto &biconditional = formula.get<ast::Biconditional>();
const auto leftIsPredicate = biconditional.left.is<ast::Predicate>();
const auto rightIsPredicate = biconditional.right.is<ast::Predicate>();
const auto leftIsAnd = biconditional.left.is<ast::And>();
const auto rightIsAnd = biconditional.right.is<ast::And>();
if (!(leftIsPredicate && rightIsAnd) && !(rightIsPredicate && leftIsAnd))
return SimplificationResult::Unchanged;
auto &predicateSide = (leftIsPredicate ? biconditional.left : biconditional.right);
auto &andSide = (leftIsPredicate ? biconditional.right : biconditional.left);
auto &and_ = andSide.get<ast::And>();
const auto matchingPredicate =
std::find_if(and_.arguments.cbegin(), and_.arguments.cend(),
[&](const auto &argument)
{
return (ast::equal(predicateSide, argument) == ast::Tristate::True);
});
if (matchingPredicate == and_.arguments.cend())
return SimplificationResult::Unchanged;
and_.arguments.erase(matchingPredicate);
formula = ast::Formula::make<ast::Implies>(std::move(predicateSide), std::move(andSide));
return SimplificationResult::Simplified;
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
struct SimplificationRuleDoubleNegation
{
static constexpr const auto Description = "not not F === F";
static SimplificationResult apply(ast::Formula &formula)
{
if (!formula.is<ast::Not>())
return SimplificationResult::Unchanged;
auto &not_ = formula.get<ast::Not>();
if (!not_.argument.is<ast::Not>())
return SimplificationResult::Unchanged;
auto &notNot = not_.argument.get<ast::Not>();
formula = std::move(notNot.argument);
return SimplificationResult::Simplified;
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
struct SimplificationRuleDeMorganForConjunctions
{
static constexpr const auto Description = "(not (F and G)) === (not F or not G)";
static SimplificationResult apply(ast::Formula &formula)
{
if (!formula.is<ast::Not>())
return SimplificationResult::Unchanged;
auto &not_ = formula.get<ast::Not>();
if (!not_.argument.is<ast::And>())
return SimplificationResult::Unchanged;
auto &and_ = not_.argument.get<ast::And>();
for (auto &argument : and_.arguments)
argument = ast::Formula::make<ast::Not>(std::move(argument));
formula = ast::Formula::make<ast::Or>(std::move(and_.arguments));
return SimplificationResult::Simplified;
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
struct SimplificationRuleImplicationFromDisjunction
{
static constexpr const auto Description = "(not F or G) === (F -> G)";
static SimplificationResult apply(ast::Formula &formula)
{
if (!formula.is<ast::Or>())
return SimplificationResult::Unchanged;
auto &or_ = formula.get<ast::Or>();
if (or_.arguments.size() != 2)
return SimplificationResult::Unchanged;
const auto leftIsNot = or_.arguments[0].is<ast::Not>();
const auto rightIsNot = or_.arguments[1].is<ast::Not>();
if (leftIsNot == rightIsNot)
return SimplificationResult::Unchanged;
auto &negativeSide = leftIsNot ? or_.arguments[0] : or_.arguments[1];
auto &positiveSide = leftIsNot ? or_.arguments[1] : or_.arguments[0];
assert(negativeSide.is<ast::Not>());
assert(!positiveSide.is<ast::Not>());
auto &negativeSideArgument = negativeSide.get<ast::Not>().argument;
formula = ast::Formula::make<ast::Implies>(std::move(negativeSideArgument), std::move(positiveSide));
return SimplificationResult::Simplified;
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
struct SimplificationRuleNegatedComparison
{
static constexpr const auto Description = "(not F [comparison] G) === (F [negated comparison] G)";
static SimplificationResult apply(ast::Formula &formula)
{
if (!formula.is<ast::Not>())
return SimplificationResult::Unchanged;
auto &not_ = formula.get<ast::Not>();
if (!not_.argument.is<ast::Comparison>())
return SimplificationResult::Unchanged;
auto &comparison = not_.argument.get<ast::Comparison>();
switch (comparison.operator_)
if (wasVariableReplaced)
{
case ast::Comparison::Operator::GreaterThan:
comparison.operator_ = ast::Comparison::Operator::LessEqual;
break;
case ast::Comparison::Operator::LessThan:
comparison.operator_ = ast::Comparison::Operator::GreaterEqual;
break;
case ast::Comparison::Operator::LessEqual:
comparison.operator_ = ast::Comparison::Operator::GreaterThan;
break;
case ast::Comparison::Operator::GreaterEqual:
comparison.operator_ = ast::Comparison::Operator::LessThan;
break;
case ast::Comparison::Operator::NotEqual:
comparison.operator_ = ast::Comparison::Operator::Equal;
break;
case ast::Comparison::Operator::Equal:
comparison.operator_ = ast::Comparison::Operator::NotEqual;
break;
i = exists.variables.erase(i);
continue;
}
formula = std::move(comparison);
return SimplificationResult::Simplified;
i++;
}
};
////////////////////////////////////////////////////////////////////////////////////////////////////
// If there are no arguments left, we had a formula of the form “exists X1, ..., Xn (X1 = Y1 and ... and Xn = Yn)”
// Such exists statements are useless and can be safely replaced with “#true”
if (arguments.empty())
{
formula = ast::Formula::make<ast::Boolean>(true);
return;
}
const auto simplifyWithDefaultRules =
simplify
<
SimplificationRuleDoubleNegation,
SimplificationRuleTrivialAssignmentInExists,
SimplificationRuleAssignmentInExists,
SimplificationRuleEmptyConjunction,
SimplificationRuleTrivialExists,
SimplificationRuleOneElementConjunction,
SimplificationRuleExistsWithoutQuantifiedVariables,
SimplificationRuleInWithPrimitiveArguments,
SimplificationRuleSubsumptionInBiconditionals,
SimplificationRuleDeMorganForConjunctions,
SimplificationRuleImplicationFromDisjunction,
SimplificationRuleNegatedComparison
>;
// If the argument now is a conjunction with just one element, directly replace the input formula with the argument
if (arguments.size() == 1)
exists.argument = std::move(arguments.front());
// If there are still remaining variables, simplification is over
if (!exists.variables.empty())
return;
assert(!arguments.empty());
// If there is more than one element in the conjunction, replace the input formula with the conjunction
formula = std::move(exists.argument);
}
////////////////////////////////////////////////////////////////////////////////////////////////////
// Performs the different simplification techniques
struct SimplifyFormulaVisitor : public ast::FormulaSimplificationVisitor<SimplifyFormulaVisitor>
struct SimplifyFormulaVisitor : public ast::RecursiveFormulaVisitor<SimplifyFormulaVisitor>
{
// Do nothing for all other types of expressions
static SimplificationResult accept(ast::Formula &formula)
// Forward exists statements to the dedicated simplification function
static void accept(ast::Exists &exists, ast::Formula &formula)
{
simplify(exists, formula);
}
// Simplify formulas of type “A in B” to “A = B” if A and B are primitive
static void accept(ast::In &in, ast::Formula &formula)
{
assert(ast::isPrimitive(in.element));
if (!ast::isPrimitive(in.element) || !ast::isPrimitive(in.set))
return;
formula = ast::Comparison(ast::Comparison::Operator::Equal, std::move(in.element), std::move(in.set));
}
// Do nothing for all other types of expressions
template<class T>
static void accept(T &, ast::Formula &)
{
return simplifyWithDefaultRules(formula);
}
};
@@ -545,7 +225,7 @@ struct SimplifyFormulaVisitor : public ast::FormulaSimplificationVisitor<Simplif
void simplify(ast::Formula &formula)
{
while (formula.accept(SimplifyFormulaVisitor(), formula) == SimplificationResult::Simplified);
formula.accept(SimplifyFormulaVisitor(), formula);
}
////////////////////////////////////////////////////////////////////////////////////////////////////

22
tests/TestCompletion.cpp
View File

@@ -152,9 +152,9 @@ TEST_CASE("[completion] Rules are completed", "[completion]")
CHECK(output.str() ==
"forall V1 (covered(V1) <-> exists U1 in(V1, U1))\n"
"forall V2, V3 (in(V2, V3) -> (V2 in 1..n and V3 in 1..r))\n"
"forall U2 (U2 in 1..n -> covered(U2))\n"
"forall U3, U4, U5 (not in(U3, U4) or not in(U5, U4) or not exists X1 (X1 in (U3 + U5) and in(X1, U4)))\n");
"forall V2, V3 (in(V2, V3) <-> (V2 in 1..n and V3 in 1..r and in(V2, V3)))\n"
"forall U2 not (U2 in 1..n and not covered(U2))\n"
"forall U3, U4, U5 not (in(U3, U4) and in(U5, U4) and exists X1 (X1 in (U3 + U5) and in(X1, U4)))\n");
}
SECTION("binary operations with multiple variables")
@@ -176,20 +176,4 @@ TEST_CASE("[completion] Rules are completed", "[completion]")
CHECK(output.str() ==
"forall V1, V2, V3 (p(V1, V2, V3) <-> #true)\n");
}
SECTION("negated comparisons")
{
input << ":- color(V, C1), color(V, C2), C1 != C2.";
anthem::translate("input", input, context);
CHECK(output.str() == "forall V1, V2 not color(V1, V2)\nforall U1, U2, U3 (not color(U1, U2) or not color(U1, U3) or U2 = U3)\n");
}
SECTION("absolute value operation")
{
input << "adj(X, Y) :- X = 1..n, Y = 1..n, |X - Y| = 1.";
anthem::translate("input", input, context);
CHECK(output.str() == "forall V1, V2 (adj(V1, V2) <-> (V1 in 1..n and V2 in 1..n and |V1 - V2| = 1))\n");
}
}

12
tests/TestHiddenPredicateElimination.cpp
View File

@@ -103,10 +103,9 @@ TEST_CASE("[hidden predicate elimination] Hidden predicates are correctly elimin
"#show a/1.";
anthem::translate("input", input, context);
// TODO: simplify further
CHECK(output.str() ==
"forall V1 (a(V1) <-> not d(V1))\n"
"forall V2 (d(V2) <-> d(V2))\n"
"forall V2 (d(V2) <-> not not d(V2))\n"
"forall V3 (e(V3) <-> e(V3))\n");
}
@@ -165,11 +164,12 @@ TEST_CASE("[hidden predicate elimination] Hidden predicates are correctly elimin
"#show t/0.";
anthem::translate("input", input, context);
// TODO: simplify further
CHECK(output.str() ==
"(s -> not #false)\n"
"(t -> not #false)\n"
"(s -> t)\n"
"(#false or #false or not #false)\n");
"(s <-> (not #false and s))\n"
"(t <-> (not #false and t))\n"
"not (s and not t)\n"
"not (not #false and not #false and #false)\n");
}
SECTION("predicate with more than one argument is hidden correctly")

62
tests/TestPlaceholders.cpp
View File

@@ -1,62 +0,0 @@
#include <catch.hpp>
#include <sstream>
#include <anthem/AST.h>
#include <anthem/Context.h>
#include <anthem/Translation.h>
////////////////////////////////////////////////////////////////////////////////////////////////////
TEST_CASE("[placeholders] Programs with placeholders are correctly completed", "[placeholders]")
{
std::stringstream input;
std::stringstream output;
std::stringstream errors;
anthem::output::Logger logger(output, errors);
anthem::Context context(std::move(logger));
context.performSimplification = true;
context.performCompletion = true;
SECTION("no placeholders")
{
input <<
"colored(V, red) :- vertex(V), not colored(V, green), not colored(V, blue).";
anthem::translate("input", input, context);
CHECK(output.str() ==
"forall V1, V2 (colored(V1, V2) <-> (V2 = red and vertex(V1) and not colored(V1, green) and not colored(V1, blue)))\n"
"forall V3 not vertex(V3)\n");
}
SECTION("single placeholder")
{
input <<
"#external vertex(1).\n"
"colored(V, red) :- vertex(V), not colored(V, green), not colored(V, blue).";
anthem::translate("input", input, context);
CHECK(output.str() ==
"forall V1, V2 (colored(V1, V2) <-> (V2 = red and vertex(V1) and not colored(V1, green) and not colored(V1, blue)))\n");
}
SECTION("complex example: graph coloring")
{
input <<
"#external color(1).\n"
"#external edge(2).\n"
"#external vertex(1).\n"
"#show color/2.\n"
"{color(V, C)} :- vertex(V), color(C).\n"
"covered(V) :- color(V, _).\n"
":- vertex(V), not covered(V).\n"
":- color(V1, C), color(V2, C), edge(V1, V2).";
anthem::translate("input", input, context);
CHECK(output.str() ==
"forall V1, V2 (color(V1, V2) -> (vertex(V1) and color(V2)))\n"
"forall U1 (vertex(U1) -> exists U2 color(U1, U2))\n"
"forall U3, U4, U5 (not color(U3, U4) or not color(U5, U4) or not edge(U3, U5))\n");
}
}

8
tests/TestTranslation.cpp
View File

@@ -296,12 +296,4 @@ TEST_CASE("[translation] Rules are translated correctly", "[translation]")
CHECK(output.str() == "((V1 in U1 and V2 in U2 and exists X1, X2 (X1 in U3 and X2 in U4 and q(X1, X2))) -> p(V1, V2))\n");
}
SECTION("exponentiation operator")
{
input << "p(N, N ** N) :- N = 1..n.";
anthem::translate("input", input, context);
CHECK(output.str() == "((V1 in U1 and V2 in (U1 ** U1) and exists X1, X2 (X1 in U1 and X2 in 1..n and X1 = X2)) -> p(V1, V2))\n");
}
}