lemon/bits/variant.h
author Balazs Dezso <deba@inf.elte.hu>
Thu, 24 Jun 2010 09:27:53 +0200
changeset 891 bb70ad62c95f
parent 431 9dfaf6efc36f
permissions -rw-r--r--
Fix critical bug in preflow (#372)

The wrong transition between the bound decrease and highest active
heuristics caused the bug. The last node chosen in bound decrease mode
is used in the first iteration in highest active mode.
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/* -*- mode: C++; indent-tabs-mode: nil; -*-
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 *
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 * This file is a part of LEMON, a generic C++ optimization library.
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 *
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 * Copyright (C) 2003-2009
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 * Egervary Jeno Kombinatorikus Optimalizalasi Kutatocsoport
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 * (Egervary Research Group on Combinatorial Optimization, EGRES).
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 *
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 * Permission to use, modify and distribute this software is granted
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 * provided that this copyright notice appears in all copies. For
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 * precise terms see the accompanying LICENSE file.
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 *
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 * This software is provided "AS IS" with no warranty of any kind,
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 * express or implied, and with no claim as to its suitability for any
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 * purpose.
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 *
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 */
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#ifndef LEMON_BITS_VARIANT_H
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#define LEMON_BITS_VARIANT_H
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#include <lemon/assert.h>
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// \file
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// \brief Variant types
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namespace lemon {
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  namespace _variant_bits {
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    template <int left, int right>
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    struct CTMax {
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      static const int value = left < right ? right : left;
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    };
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  }
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  // \brief Simple Variant type for two types
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  //
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  // Simple Variant type for two types. The Variant type is a type-safe
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  // union. C++ has strong limitations for using unions, for
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  // example you cannot store a type with non-default constructor or
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  // destructor in a union. This class always knowns the current
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  // state of the variant and it cares for the proper construction
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  // and destruction.
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  template <typename _First, typename _Second>
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  class BiVariant {
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  public:
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    // \brief The \c First type.
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    typedef _First First;
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    // \brief The \c Second type.
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    typedef _Second Second;
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    // \brief Constructor
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    //
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    // This constructor initalizes to the default value of the \c First
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    // type.
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    BiVariant() {
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      flag = true;
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      new(reinterpret_cast<First*>(data)) First();
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    }
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    // \brief Constructor
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    //
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    // This constructor initalizes to the given value of the \c First
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    // type.
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    BiVariant(const First& f) {
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      flag = true;
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      new(reinterpret_cast<First*>(data)) First(f);
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    }
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    // \brief Constructor
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    //
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    // This constructor initalizes to the given value of the \c
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    // Second type.
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    BiVariant(const Second& s) {
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      flag = false;
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      new(reinterpret_cast<Second*>(data)) Second(s);
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    }
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    // \brief Copy constructor
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    //
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    // Copy constructor
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    BiVariant(const BiVariant& bivariant) {
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      flag = bivariant.flag;
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      if (flag) {
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        new(reinterpret_cast<First*>(data)) First(bivariant.first());
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      } else {
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        new(reinterpret_cast<Second*>(data)) Second(bivariant.second());
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      }
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    }
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    // \brief Destrcutor
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    //
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    // Destructor
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    ~BiVariant() {
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      destroy();
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    }
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    // \brief Set to the default value of the \c First type.
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    //
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    // This function sets the variant to the default value of the \c
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    // First type.
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    BiVariant& setFirst() {
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      destroy();
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      flag = true;
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      new(reinterpret_cast<First*>(data)) First();
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      return *this;
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    }
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    // \brief Set to the given value of the \c First type.
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    //
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    // This function sets the variant to the given value of the \c
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    // First type.
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    BiVariant& setFirst(const First& f) {
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      destroy();
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      flag = true;
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      new(reinterpret_cast<First*>(data)) First(f);
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      return *this;
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    }
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    // \brief Set to the default value of the \c Second type.
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    //
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    // This function sets the variant to the default value of the \c
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    // Second type.
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    BiVariant& setSecond() {
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      destroy();
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      flag = false;
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      new(reinterpret_cast<Second*>(data)) Second();
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      return *this;
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    }
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    // \brief Set to the given value of the \c Second type.
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    //
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    // This function sets the variant to the given value of the \c
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    // Second type.
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    BiVariant& setSecond(const Second& s) {
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      destroy();
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      flag = false;
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      new(reinterpret_cast<Second*>(data)) Second(s);
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      return *this;
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    }
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    // \brief Operator form of the \c setFirst()
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    BiVariant& operator=(const First& f) {
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      return setFirst(f);
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    }
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    // \brief Operator form of the \c setSecond()
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    BiVariant& operator=(const Second& s) {
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      return setSecond(s);
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    }
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    // \brief Assign operator
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    BiVariant& operator=(const BiVariant& bivariant) {
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      if (this == &bivariant) return *this;
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      destroy();
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      flag = bivariant.flag;
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      if (flag) {
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        new(reinterpret_cast<First*>(data)) First(bivariant.first());
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      } else {
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        new(reinterpret_cast<Second*>(data)) Second(bivariant.second());
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      }
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      return *this;
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    }
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    // \brief Reference to the value
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    //
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    // Reference to the value of the \c First type.
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    // \pre The BiVariant should store value of \c First type.
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    First& first() {
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      LEMON_DEBUG(flag, "Variant wrong state");
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      return *reinterpret_cast<First*>(data);
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    }
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    // \brief Const reference to the value
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    //
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    // Const reference to the value of the \c First type.
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    // \pre The BiVariant should store value of \c First type.
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    const First& first() const {
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      LEMON_DEBUG(flag, "Variant wrong state");
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      return *reinterpret_cast<const First*>(data);
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    }
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    // \brief Operator form of the \c first()
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    operator First&() { return first(); }
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    // \brief Operator form of the const \c first()
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    operator const First&() const { return first(); }
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    // \brief Reference to the value
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    //
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    // Reference to the value of the \c Second type.
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    // \pre The BiVariant should store value of \c Second type.
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    Second& second() {
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      LEMON_DEBUG(!flag, "Variant wrong state");
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      return *reinterpret_cast<Second*>(data);
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    }
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    // \brief Const reference to the value
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    //
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    // Const reference to the value of the \c Second type.
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    // \pre The BiVariant should store value of \c Second type.
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    const Second& second() const {
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      LEMON_DEBUG(!flag, "Variant wrong state");
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      return *reinterpret_cast<const Second*>(data);
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    }
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    // \brief Operator form of the \c second()
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    operator Second&() { return second(); }
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    // \brief Operator form of the const \c second()
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    operator const Second&() const { return second(); }
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    // \brief %True when the variant is in the first state
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    //
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    // %True when the variant stores value of the \c First type.
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    bool firstState() const { return flag; }
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    // \brief %True when the variant is in the second state
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    //
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    // %True when the variant stores value of the \c Second type.
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    bool secondState() const { return !flag; }
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  private:
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    void destroy() {
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      if (flag) {
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        reinterpret_cast<First*>(data)->~First();
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      } else {
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        reinterpret_cast<Second*>(data)->~Second();
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      }
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    }
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    char data[_variant_bits::CTMax<sizeof(First), sizeof(Second)>::value];
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    bool flag;
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  };
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  namespace _variant_bits {
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    template <int _idx, typename _TypeMap>
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    struct Memory {
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      typedef typename _TypeMap::template Map<_idx>::Type Current;
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      static void destroy(int index, char* place) {
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        if (index == _idx) {
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          reinterpret_cast<Current*>(place)->~Current();
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        } else {
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          Memory<_idx - 1, _TypeMap>::destroy(index, place);
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        }
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      }
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      static void copy(int index, char* to, const char* from) {
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        if (index == _idx) {
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          new (reinterpret_cast<Current*>(to))
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            Current(reinterpret_cast<const Current*>(from));
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        } else {
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          Memory<_idx - 1, _TypeMap>::copy(index, to, from);
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        }
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      }
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    };
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    template <typename _TypeMap>
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    struct Memory<-1, _TypeMap> {
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      static void destroy(int, char*) {
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        LEMON_DEBUG(false, "Variant wrong index.");
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      }
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      static void copy(int, char*, const char*) {
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        LEMON_DEBUG(false, "Variant wrong index.");
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      }
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    };
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    template <int _idx, typename _TypeMap>
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    struct Size {
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      static const int value =
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      CTMax<sizeof(typename _TypeMap::template Map<_idx>::Type),
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            Size<_idx - 1, _TypeMap>::value>::value;
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    };
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    template <typename _TypeMap>
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    struct Size<0, _TypeMap> {
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      static const int value =
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      sizeof(typename _TypeMap::template Map<0>::Type);
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    };
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  }
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  // \brief Variant type
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  //
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  // Simple Variant type. The Variant type is a type-safe union.
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  // C++ has strong limitations for using unions, for example you
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  // cannot store type with non-default constructor or destructor in
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  // a union. This class always knowns the current state of the
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  // variant and it cares for the proper construction and
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  // destruction.
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  //
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  // \param _num The number of the types which can be stored in the
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  // variant type.
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  // \param _TypeMap This class describes the types of the Variant. The
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  // _TypeMap::Map<index>::Type should be a valid type for each index
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  // in the range {0, 1, ..., _num - 1}. The \c VariantTypeMap is helper
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  // class to define such type mappings up to 10 types.
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  //
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  // And the usage of the class:
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  //\code
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  // typedef Variant<3, VariantTypeMap<int, std::string, double> > MyVariant;
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  // MyVariant var;
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  // var.set<0>(12);
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  // std::cout << var.get<0>() << std::endl;
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  // var.set<1>("alpha");
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  // std::cout << var.get<1>() << std::endl;
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  // var.set<2>(0.75);
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  // std::cout << var.get<2>() << std::endl;
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  //\endcode
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  //
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  // The result of course:
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  //\code
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  // 12
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  // alpha
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  // 0.75
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  //\endcode
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  template <int _num, typename _TypeMap>
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  class Variant {
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  public:
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    static const int num = _num;
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    typedef _TypeMap TypeMap;
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    // \brief Constructor
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    //
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    // This constructor initalizes to the default value of the \c type
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    // with 0 index.
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    Variant() {
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      flag = 0;
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      new(reinterpret_cast<typename TypeMap::template Map<0>::Type*>(data))
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        typename TypeMap::template Map<0>::Type();
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    }
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    // \brief Copy constructor
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    //
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    // Copy constructor
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    Variant(const Variant& variant) {
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      flag = variant.flag;
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      _variant_bits::Memory<num - 1, TypeMap>::copy(flag, data, variant.data);
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    }
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    // \brief Assign operator
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    //
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    // Assign operator
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    Variant& operator=(const Variant& variant) {
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      if (this == &variant) return *this;
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      _variant_bits::Memory<num - 1, TypeMap>::
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        destroy(flag, data);
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      flag = variant.flag;
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      _variant_bits::Memory<num - 1, TypeMap>::
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        copy(flag, data, variant.data);
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      return *this;
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    }
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    // \brief Destrcutor
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    //
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    // Destructor
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    ~Variant() {
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      _variant_bits::Memory<num - 1, TypeMap>::destroy(flag, data);
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    }
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    // \brief Set to the default value of the type with \c _idx index.
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    //
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    // This function sets the variant to the default value of the
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    // type with \c _idx index.
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    template <int _idx>
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    Variant& set() {
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      _variant_bits::Memory<num - 1, TypeMap>::destroy(flag, data);
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      flag = _idx;
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      new(reinterpret_cast<typename TypeMap::template Map<_idx>::Type*>(data))
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        typename TypeMap::template Map<_idx>::Type();
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      return *this;
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    }
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    // \brief Set to the given value of the type with \c _idx index.
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    //
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    // This function sets the variant to the given value of the type
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    // with \c _idx index.
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    template <int _idx>
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    Variant& set(const typename _TypeMap::template Map<_idx>::Type& init) {
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      _variant_bits::Memory<num - 1, TypeMap>::destroy(flag, data);
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      flag = _idx;
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      new(reinterpret_cast<typename TypeMap::template Map<_idx>::Type*>(data))
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        typename TypeMap::template Map<_idx>::Type(init);
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      return *this;
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    }
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    // \brief Gets the current value of the type with \c _idx index.
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    //
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    // Gets the current value of the type with \c _idx index.
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    template <int _idx>
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    const typename TypeMap::template Map<_idx>::Type& get() const {
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      LEMON_DEBUG(_idx == flag, "Variant wrong index");
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      return *reinterpret_cast<const typename TypeMap::
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        template Map<_idx>::Type*>(data);
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    }
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    // \brief Gets the current value of the type with \c _idx index.
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    //
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    // Gets the current value of the type with \c _idx index.
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    template <int _idx>
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    typename _TypeMap::template Map<_idx>::Type& get() {
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      LEMON_DEBUG(_idx == flag, "Variant wrong index");
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      return *reinterpret_cast<typename TypeMap::template Map<_idx>::Type*>
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        (data);
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    }
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    // \brief Returns the current state of the variant.
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    //
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    // Returns the current state of the variant.
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    int state() const {
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      return flag;
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    }
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  private:
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    char data[_variant_bits::Size<num - 1, TypeMap>::value];
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    int flag;
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  };
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  namespace _variant_bits {
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    template <int _index, typename _List>
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    struct Get {
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      typedef typename Get<_index - 1, typename _List::Next>::Type Type;
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    };
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    template <typename _List>
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    struct Get<0, _List> {
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      typedef typename _List::Type Type;
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    };
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    struct List {};
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    template <typename _Type, typename _List>
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    struct Insert {
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      typedef _List Next;
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      typedef _Type Type;
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    };
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    template <int _idx, typename _T0, typename _T1, typename _T2,
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              typename _T3, typename _T4, typename _T5, typename _T6,
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              typename _T7, typename _T8, typename _T9>
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    struct Mapper {
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      typedef List L10;
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      typedef Insert<_T9, L10> L9;
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      typedef Insert<_T8, L9> L8;
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      typedef Insert<_T7, L8> L7;
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      typedef Insert<_T6, L7> L6;
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      typedef Insert<_T5, L6> L5;
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      typedef Insert<_T4, L5> L4;
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      typedef Insert<_T3, L4> L3;
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      typedef Insert<_T2, L3> L2;
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   465
      typedef Insert<_T1, L2> L1;
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      typedef Insert<_T0, L1> L0;
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      typedef typename Get<_idx, L0>::Type Type;
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   468
    };
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   469
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   470
  }
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   471
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  // \brief Helper class for Variant
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   473
  //
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   474
  // Helper class to define type mappings for Variant. This class
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   475
  // converts the template parameters to be mappable by integer.
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   476
  // \see Variant
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  template <
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   478
    typename _T0,
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   479
    typename _T1 = void, typename _T2 = void, typename _T3 = void,
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   480
    typename _T4 = void, typename _T5 = void, typename _T6 = void,
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   481
    typename _T7 = void, typename _T8 = void, typename _T9 = void>
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   482
  struct VariantTypeMap {
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   483
    template <int _idx>
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   484
    struct Map {
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   485
      typedef typename _variant_bits::
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   486
      Mapper<_idx, _T0, _T1, _T2, _T3, _T4, _T5, _T6, _T7, _T8, _T9>::Type
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   487
      Type;
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   488
    };
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   489
  };
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   490
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   491
}
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   492
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   493
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   494
#endif