The source code and dockerfile for the GSW2024 AI Lab.
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%module VariableT
%{
#include <carl/core/Variable.h>
#include <carl/core/Monomial.h>
#include <carl/core/Term.h>
#include <carl/core/MultivariatePolynomial.h>
#include <carl/core/RationalFunction.h>
typedef mpq_class Rational;
typedef carl::Term<Rational> Term;
typedef carl::MultivariatePolynomial<Rational> Polynomial;
typedef carl::RationalFunction<Polynomial> RationalFunction;
%}
%include "std_string.i"
%import "monomial.i"
%import "term.i"
%import "polynomial.i"
%import "rationalfunction.i"
//TODO: for 32 bit support this has to be changed..
//%import <stddef> //for size_t maybe?
typedef long unsigned int size_t; //this should be okay for 64 bits at least
typedef mpq_class Rational;
typedef carl::Term<Rational> Term;
typedef carl::MultivariatePolynomial<Rational> Polynomial;
//typedef carl::RationalFunction<Polynomial> RationalFunction;
namespace carl {
//%include "enums.swg"
//%javaconst(1);
//maybe also define the toString for this enum, if needed
//enum VariableType { VT_BOOL = 0, VT_REAL = 1, VT_INT = 2, VT_UNINTERPRETED = 3, VT_BITVECTOR = 4, MIN_TYPE = VT_BOOL, MAX_TYPE = VT_BITVECTOR};
enum class VariableType { VT_BOOL = 0, VT_REAL = 1, VT_INT = 2, VT_UNINTERPRETED = 3, VT_BITVECTOR = 4, MIN_TYPE = VT_BOOL, MAX_TYPE = VT_BITVECTOR, TYPE_SIZE = MAX_TYPE - MIN_TYPE + 1 };
class Variable {
public:
#ifdef VARIABLE_PASS_BY_VALUE
/// Argument type for variables being function arguments.
typedef Variable Arg;
#else
/// Argument type for variables being function arguments.
typedef const Variable& Arg;
#endif
%extend {
Variable(std::string name, carl::VariableType type) {
//try and generate new variable from pool
carl::Variable newVar;
auto& pool = carl::VariablePool::getInstance();
carl::Variable res = pool.findVariableWithName(name);
if (res != carl::Variable::NO_VARIABLE) {
newVar = res;
} else {
newVar = freshVariable(name, type);
}
return new carl::Variable(newVar);
}
Variable(carl::VariableType type) {
carl::Variable newVar = freshVariable(type);
return new carl::Variable(newVar);
}
std::string toString() {
std::stringstream ss;
ss << *$self;
return ss.str();
}
}
std::size_t getId() const;
VariableType getType() const;
std::string getName() const;
std::size_t getRank();
%extend {
bool equals(carl::Variable::Arg other) {
return *$self == other;
}
bool notEquals(carl::Variable::Arg other) {
return *$self != other;
}
bool less(carl::Variable::Arg other) {
return *$self < other;
}
bool lessEquals(carl::Variable::Arg other) {
return *$self <= other;
}
bool greater(carl::Variable::Arg other) {
return *$self > other;
}
bool greaterEquals(carl::Variable::Arg other) {
return *$self >= other;
}
Polynomial add(const Polynomial& rhs) {
return *($self)+rhs;
}
Polynomial add(const Term& rhs) {
return *($self)+rhs;
}
Polynomial add(const carl::Monomial::Arg& rhs) {
return carl::operator+<Rational,carl::GrLexOrdering,carl::StdMultivariatePolynomialPolicies<>>(*($self),rhs);
}
Polynomial add(carl::Variable::Arg rhs) {
return carl::operator+<Rational,carl::GrLexOrdering,carl::StdMultivariatePolynomialPolicies<>>(*($self),rhs);
}
Polynomial add(const Rational& rhs) {
return *($self)+Term(rhs);
}
Polynomial sub(const Polynomial& rhs) {
return *($self)-rhs;
}
Polynomial sub(const Term& rhs) {
return *($self)-rhs;
}
Polynomial sub(const carl::Monomial::Arg& rhs) {
return carl::operator-<Rational,carl::GrLexOrdering,carl::StdMultivariatePolynomialPolicies<>>(*($self),rhs);
}
Polynomial sub(carl::Variable::Arg rhs) {
return carl::operator-<Rational,carl::GrLexOrdering,carl::StdMultivariatePolynomialPolicies<>>(*($self),rhs);
}
Polynomial sub(const Rational& rhs) {
return *($self)-Term(rhs);
}
Polynomial mul(const Polynomial& rhs) {
return *($self)*rhs;
}
Term mul(const Term& rhs) {
return *($self)*rhs;
}
Polynomial mul(const Monomial::Arg& rhs) {
//const std::shared_ptr<const carl::Monomial> ptr(rhs);
return carl::operator*(*($self),Polynomial(rhs));
}
Polynomial mul(carl::Variable::Arg rhs) {
return carl::operator*(*($self),Polynomial(rhs));
}
Term mul(const Rational& rhs) {
return *($self)*Term(rhs);
}
RationalFunction div(const carl::RationalFunction<Polynomial>& rhs) {
return RationalFunction(*($self)) / rhs;
}
RationalFunction div(const Polynomial& rhs) {
return RationalFunction(*($self)) / rhs;
}
RationalFunction div(const Term& rhs) {
return RationalFunction(*($self)) / rhs;
}
RationalFunction div(const carl::Monomial::Arg& rhs) {
return RationalFunction(*($self)) / rhs;
}
RationalFunction div(carl::Variable::Arg rhs) {
return RationalFunction(*($self)) / rhs;
}
Polynomial div(const Rational& rhs) {
if (carl::isZero(rhs)) throw std::runtime_error("Div by zero");
return Polynomial(*($self)) / rhs;
}
Term neg() {
return *$self*Rational(-1);
}
carl::Monomial::Arg pow(uint exp) {
carl::Monomial m(*$self);
return m.pow(exp);
}
}
};
}