C++ Boost


Color Base

Overview

A color base is a container of color elements. The most common use of color base is in the implementation of a pixel, in which case the color elements are channel values. The color base concept, however, can be used in other scenarios. For example, a planar pixel has channels that are not contiguous in memory. Its reference is a proxy class that uses a color base whose elements are channel references. Its iterator uses a color base whose elements are channel iterators.

Color base models must satisfy the following concepts:

concept ColorBaseConcept<typename T>
    : CopyConstructible<T>, EqualityComparable<T>
{
  // a GIL layout (the color space and element permutation)
  typename layout_t;

  // The type of K-th element
  template <int K> struct kth_element_type;
      where Metafunction<kth_element_type>;

  // The result of at_c
  template <int K> struct kth_element_const_reference_type;
      where Metafunction<kth_element_const_reference_type>;

  template <int K> kth_element_const_reference_type<T,K>::type at_c(T);

  template <ColorBaseConcept T2> where { ColorBasesCompatibleConcept<T,T2> }
      T::T(T2);
  template <ColorBaseConcept T2> where { ColorBasesCompatibleConcept<T,T2> }
      bool operator==(const T&, const T2&);
  template <ColorBaseConcept T2> where { ColorBasesCompatibleConcept<T,T2> }
      bool operator!=(const T&, const T2&);

};

concept MutableColorBaseConcept<ColorBaseConcept T>
    : Assignable<T>, Swappable<T>
{
  template <int K> struct kth_element_reference_type;
      where Metafunction<kth_element_reference_type>;

  template <int K> kth_element_reference_type<T,K>::type at_c(T);

  template <ColorBaseConcept T2> where { ColorBasesCompatibleConcept<T,T2> }
      T& operator=(T&, const T2&);
};

concept ColorBaseValueConcept<typename T> : MutableColorBaseConcept<T>, Regular<T>
{
};

concept HomogeneousColorBaseConcept<ColorBaseConcept CB>
{
  // For all K in [0 ... size<C1>::value-1):
  //     where SameType<kth_element_type<K>::type, kth_element_type<K+1>::type>;
  kth_element_const_reference_type<0>::type dynamic_at_c(const CB&, std::size_t n) const;
};

concept MutableHomogeneousColorBaseConcept<MutableColorBaseConcept CB>
    : HomogeneousColorBaseConcept<CB>
{
  kth_element_reference_type<0>::type dynamic_at_c(const CB&, std::size_t n);
};

concept HomogeneousColorBaseValueConcept<typename T>
    : MutableHomogeneousColorBaseConcept<T>, Regular<T>
{
};

concept ColorBasesCompatibleConcept<ColorBaseConcept C1, ColorBaseConcept C2>
{
  where SameType<C1::layout_t::color_space_t, C2::layout_t::color_space_t>;
  // also, for all K in [0 ... size<C1>::value):
  //     where Convertible<kth_semantic_element_type<C1,K>::type, kth_semantic_element_type<C2,K>::type>;
  //     where Convertible<kth_semantic_element_type<C2,K>::type, kth_semantic_element_type<C1,K>::type>;
};

A color base must have an associated layout (which consists of a color space, as well as an ordering of the channels). There are two ways to index the elements of a color base: A physical index corresponds to the way they are ordered in memory, and a semantic index corresponds to the way the elements are ordered in their color space. For example, in the RGB color space the elements are ordered as {red_t, green_t, blue_t}. For a color base with a BGR layout, the first element in physical ordering is the blue element, whereas the first semantic element is the red one. Models of ColorBaseConcept are required to provide the at_c<K>(ColorBase) function, which allows for accessing the elements based on their physical order. GIL provides a semantic_at_c<K>(ColorBase) function (described later) which can operate on any model of ColorBaseConcept and returns the corresponding semantic element.

Two color bases are compatible if they have the same color space and their elements (paired semantically) are convertible to each other.

Models

GIL provides a model for a homogeneous color base (a color base whose elements all have the same type).

namespace detail
{
  template <typename Element, typename Layout, int K>
  struct homogeneous_color_base;
}

It is used in the implementation of GIL’s pixel, planar pixel reference and planar pixel iterator. Another model of ColorBaseConcept is packed_pixel - it is a pixel whose channels are bit ranges.

See the Pixel section for more.

Algorithms

GIL provides the following functions and metafunctions operating on color bases:

// Metafunction returning an mpl::int_ equal to the number of elements in the color base
template <class ColorBase> struct size;

// Returns the type of the return value of semantic_at_c<K>(color_base)
template <class ColorBase, int K> struct kth_semantic_element_reference_type;
template <class ColorBase, int K> struct kth_semantic_element_const_reference_type;

// Returns a reference to the element with K-th semantic index.
template <class ColorBase, int K>
typename kth_semantic_element_reference_type<ColorBase,K>::type       semantic_at_c(ColorBase& p)
template <class ColorBase, int K>
typename kth_semantic_element_const_reference_type<ColorBase,K>::type semantic_at_c(const ColorBase& p)

// Returns the type of the return value of get_color<Color>(color_base)
template <typename Color, typename ColorBase> struct color_reference_t;
template <typename Color, typename ColorBase> struct color_const_reference_t;

// Returns a reference to the element corresponding to the given color
template <typename ColorBase, typename Color>
typename color_reference_t<Color,ColorBase>::type get_color(ColorBase& cb, Color=Color());
template <typename ColorBase, typename Color>
typename color_const_reference_t<Color,ColorBase>::type get_color(const ColorBase& cb, Color=Color());

// Returns the element type of the color base. Defined for homogeneous color bases only
template <typename ColorBase> struct element_type;
template <typename ColorBase> struct element_reference_type;
template <typename ColorBase> struct element_const_reference_type;

GIL also provides the following algorithms which operate on color bases. Note that they all pair the elements semantically:

// Equivalents to std::equal, std::copy, std::fill, std::generate
template <typename CB1,typename CB2>   bool static_equal(const CB1& p1, const CB2& p2);
template <typename Src,typename Dst>   void static_copy(const Src& src, Dst& dst);
template <typename CB, typename Op>    void static_generate(CB& dst,Op op);

// Equivalents to std::transform
template <typename CB ,             typename Dst,typename Op> Op static_transform(      CB&,Dst&,Op);
template <typename CB ,             typename Dst,typename Op> Op static_transform(const CB&,Dst&,Op);
template <typename CB1,typename CB2,typename Dst,typename Op> Op static_transform(      CB1&,      CB2&,Dst&,Op);
template <typename CB1,typename CB2,typename Dst,typename Op> Op static_transform(const CB1&,      CB2&,Dst&,Op);
template <typename CB1,typename CB2,typename Dst,typename Op> Op static_transform(      CB1&,const CB2&,Dst&,Op);
template <typename CB1,typename CB2,typename Dst,typename Op> Op static_transform(const CB1&,const CB2&,Dst&,Op);

// Equivalents to std::for_each
template <typename CB1,                          typename Op> Op static_for_each(      CB1&,Op);
template <typename CB1,                          typename Op> Op static_for_each(const CB1&,Op);
template <typename CB1,typename CB2,             typename Op> Op static_for_each(      CB1&,      CB2&,Op);
template <typename CB1,typename CB2,             typename Op> Op static_for_each(      CB1&,const CB2&,Op);
template <typename CB1,typename CB2,             typename Op> Op static_for_each(const CB1&,      CB2&,Op);
template <typename CB1,typename CB2,             typename Op> Op static_for_each(const CB1&,const CB2&,Op);
template <typename CB1,typename CB2,typename CB3,typename Op> Op static_for_each(      CB1&,      CB2&,      CB3&,Op);
template <typename CB1,typename CB2,typename CB3,typename Op> Op static_for_each(      CB1&,      CB2&,const CB3&,Op);
template <typename CB1,typename CB2,typename CB3,typename Op> Op static_for_each(      CB1&,const CB2&,      CB3&,Op);
template <typename CB1,typename CB2,typename CB3,typename Op> Op static_for_each(      CB1&,const CB2&,const CB3&,Op);
template <typename CB1,typename CB2,typename CB3,typename Op> Op static_for_each(const CB1&,      CB2&,      CB3&,Op);
template <typename CB1,typename CB2,typename CB3,typename Op> Op static_for_each(const CB1&,      CB2&,const CB3&,Op);
template <typename CB1,typename CB2,typename CB3,typename Op> Op static_for_each(const CB1&,const CB2&,      CB3&,Op);
template <typename CB1,typename CB2,typename CB3,typename Op> Op static_for_each(const CB1&,const CB2&,const CB3&,Op);

// The following algorithms are only defined for homogeneous color bases:
// Equivalent to std::fill
template <typename HCB, typename Element> void static_fill(HCB& p, const Element& v);

// Equivalents to std::min_element and std::max_element
template <typename HCB> typename element_const_reference_type<HCB>::type static_min(const HCB&);
template <typename HCB> typename element_reference_type<HCB>::type       static_min(      HCB&);
template <typename HCB> typename element_const_reference_type<HCB>::type static_max(const HCB&);
template <typename HCB> typename element_reference_type<HCB>::type       static_max(      HCB&);

These algorithms are designed after the corresponding STL algorithms, except that instead of ranges they take color bases and operate on their elements. In addition, they are implemented with a compile-time recursion (thus the prefix “static_”). Finally, they pair the elements semantically instead of based on their physical order in memory.

For example, here is the implementation of static_equal:

namespace detail
{
  template <int K> struct element_recursion
  {
    template <typename P1,typename P2>
    static bool static_equal(const P1& p1, const P2& p2)
    {
      return element_recursion<K-1>::static_equal(p1,p2) &&
             semantic_at_c<K-1>(p1)==semantic_at_c<N-1>(p2);
    }
  };
  template <> struct element_recursion<0>
  {
    template <typename P1,typename P2>
    static bool static_equal(const P1&, const P2&) { return true; }
  };
}

template <typename P1,typename P2>
bool static_equal(const P1& p1, const P2& p2)
{
  gil_function_requires<ColorSpacesCompatibleConcept<P1::layout_t::color_space_t,P2::layout_t::color_space_t> >();
  return detail::element_recursion<size<P1>::value>::static_equal(p1,p2);
}

This algorithm is used when invoking operator== on two pixels, for example. By using semantic accessors we are properly comparing an RGB pixel to a BGR pixel. Notice also that all of the above algorithms taking more than one color base require that they all have the same color space.