libquantlib0-dev 1.4-2 / usr / include / ql / math / functional.hpp

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/* -*- mode: c++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */

/*
 Copyright (C) 2003 RiskMap srl

 This file is part of QuantLib, a free-software/open-source library
 for financial quantitative analysts and developers - http://quantlib.org/

 QuantLib is free software: you can redistribute it and/or modify it
 under the terms of the QuantLib license.  You should have received a
 copy of the license along with this program; if not, please email
 <quantlib-dev@lists.sf.net>. The license is also available online at
 <http://quantlib.org/license.shtml>.

 This program is distributed in the hope that it will be useful, but WITHOUT
 ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
 FOR A PARTICULAR PURPOSE.  See the license for more details.
*/

/*! \file functional.hpp
    \brief functionals and combinators not included in the STL
*/

#ifndef quantlib_functional_hpp
#define quantlib_functional_hpp

#include <ql/types.hpp>
#include <cmath>
#include <functional>

namespace QuantLib {

    // functions

    template <class T, class U>
    class constant : public std::unary_function<T,U> {
      public:
        constant(const U& u) : u_(u) {}
        U operator()(const T&) const { return u_; }
      private:
        U u_;
    };

    template <class T>
    class identity : public std::unary_function<T,T> {
      public:
        T operator()(const T& t) const { return t; }
    };

    template <class T>
    class square : public std::unary_function<T,T> {
      public:
        T operator()(const T& t) const { return t*t; }
    };

    template <class T>
    class cube : public std::unary_function<T,T> {
      public:
        T operator()(const T& t) const { return t*t*t; }
    };

    template <class T>
    class fourth_power : public std::unary_function<T,T> {
      public:
        T operator()(const T& t) const { T t2 = t*t; return t2*t2; }
    };

    // predicates

    class everywhere : public constant<Real,bool> {
      public:
        everywhere() : constant<Real,bool>(true) {}
    };

    class nowhere : public constant<Real,bool> {
      public:
        nowhere() : constant<Real,bool>(false) {}
    };

    template <class T>
    class equal_within : public std::binary_function<T, T, bool> {
      public:
        equal_within(const T& eps) : eps_(eps) {}
        bool operator()(const T a, const T b) const {
            return std::fabs(a-b) <= eps_;
        }
      private:
        const T eps_;
    };

    // combinators
    template <class F, class R>
    class clipped_function {
      public:
        typedef typename F::argument_type argument_type;
        typedef typename F::result_type result_type;
        clipped_function(const F& f, const R& r) : f_(f), r_(r) {}
        result_type operator()(const argument_type& x) const {
            return r_(x) ? f_(x) : result_type();
        }
      private:
        F f_;
        R r_;
    };

    template <class F, class R>
    clipped_function<F,R> clip(const F& f, const R& r) {
        return clipped_function<F,R>(f,r);
    }


    template <class F, class G>
    class composed_function {
      public:
        typedef typename G::argument_type argument_type;
        typedef typename F::result_type result_type;
        composed_function(const F& f, const G& g) : f_(f), g_(g) {}
        result_type operator()(const argument_type& x) const {
            return f_(g_(x));
        }
      private:
        F f_;
        G g_;
    };

    template <class F, class G>
    composed_function<F,G> compose(const F& f, const G& g) {
        return composed_function<F,G>(f,g);
    }

    template <class F, class G, class H>
    class binary_compose3_function :
        public std::binary_function<typename G::argument_type,
                                    typename H::argument_type,
                                    typename F::result_type>{
      public:
        typedef typename G::argument_type first_argument_type;
        typedef typename H::argument_type second_argument_type;
        typedef typename F::result_type result_type;

        binary_compose3_function(const F& f, const G& g, const H& h)
        : f_(f), g_(g), h_(h) {}

        result_type operator()(const first_argument_type&  x,
                               const second_argument_type& y) const {
            return f_(g_(x), h_(y));
        }

      private:
        F f_;
        G g_;
        H h_;
    };

    template <class F, class G, class H> binary_compose3_function<F, G, H>
    compose3(const F& f, const G& g, const H& h) {
        return binary_compose3_function<F, G, H>(f, g, h);
    }
}


#endif

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