x
Yes
No
Do you want to visit DriveHQ English website?
首页
产品服务
价格
免费试用
下载客户端
关于我们
云文件服务
|
云备份服务
|
FTP服务
|
企业邮箱服务
|
网站托管
|
客户端软件
云文件服务
云备份服务
FTP服务
企业级邮箱服务
网站托管
客户端软件
step_iterator.hpp - Hosted on DriveHQ Cloud IT Platform
返回上层目录
上传
下载
共享
发布
新建文件夹
新建文件
复制
剪切
删除
粘贴
评论
升级服务
路径: \\game3dprogramming\materials\GameFactory\GameFactoryDemo\references\boost_1_35_0\boost\gil\step_iterator.hpp
旋转
特效
属性
历史版本
/* Copyright 2005-2007 Adobe Systems Incorporated Use, modification and distribution are subject to the Boost Software License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt). See http://opensource.adobe.com/gil for most recent version including documentation. */ /*************************************************************************************************/ #ifndef GIL_STEP_ITERATOR_H #define GIL_STEP_ITERATOR_H //////////////////////////////////////////////////////////////////////////////////////// /// \file /// \brief pixel step iterator /// \author Lubomir Bourdev and Hailin Jin \n /// Adobe Systems Incorporated /// \date 2005-2007 \n Last updated on September 18, 2007 /// //////////////////////////////////////////////////////////////////////////////////////// #include
#include
#include
#include "gil_config.hpp" #include "utilities.hpp" #include "pixel_iterator.hpp" #include "pixel_iterator_adaptor.hpp" namespace boost { namespace gil { /// \defgroup PixelIteratorModelStepPtr step iterators /// \ingroup PixelIteratorModel /// \brief Iterators that allow for specifying the step between two adjacent values namespace detail { /// \ingroup PixelIteratorModelStepPtr /// \brief An adaptor over an existing iterator that changes the step unit /// /// (i.e. distance(it,it+1)) by a given predicate. Instead of calling base's /// operators ++, --, +=, -=, etc. the adaptor is using the passed policy object SFn /// for advancing and for computing the distance between iterators. template
// A policy object that can compute the distance between two iterators of type Iterator // and can advance an iterator of type Iterator a given number of Iterator's units class step_iterator_adaptor : public iterator_adaptor
{ public: typedef iterator_adaptor
parent_t; typedef typename std::iterator_traits
::difference_type base_difference_type; typedef typename SFn::difference_type difference_type; typedef typename std::iterator_traits
::reference reference; step_iterator_adaptor() {} step_iterator_adaptor(const Iterator& it, SFn step_fn=SFn()) : parent_t(it), _step_fn(step_fn) {} difference_type step() const { return _step_fn.step(); } protected: SFn _step_fn; private: friend class boost::iterator_core_access; void increment() { _step_fn.advance(this->base_reference(),1); } void decrement() { _step_fn.advance(this->base_reference(),-1); } void advance(base_difference_type d) { _step_fn.advance(this->base_reference(),d); } difference_type distance_to(const step_iterator_adaptor& it) const { return _step_fn.difference(this->base_reference(),it.base_reference()); } }; // although iterator_adaptor defines these, the default implementation computes distance and compares for zero. // it is often faster to just apply the relation operator to the base template
inline bool operator>(const step_iterator_adaptor
& p1, const step_iterator_adaptor
& p2) { return p1.step()>0 ? p1.base()> p2.base() : p1.base()< p2.base(); } template
inline bool operator<(const step_iterator_adaptor
& p1, const step_iterator_adaptor
& p2) { return p1.step()>0 ? p1.base()< p2.base() : p1.base()> p2.base(); } template
inline bool operator>=(const step_iterator_adaptor
& p1, const step_iterator_adaptor
& p2) { return p1.step()>0 ? p1.base()>=p2.base() : p1.base()<=p2.base(); } template
inline bool operator<=(const step_iterator_adaptor
& p1, const step_iterator_adaptor
& p2) { return p1.step()>0 ? p1.base()<=p2.base() : p1.base()>=p2.base(); } template
inline bool operator==(const step_iterator_adaptor
& p1, const step_iterator_adaptor
& p2) { return p1.base()==p2.base(); } template
inline bool operator!=(const step_iterator_adaptor
& p1, const step_iterator_adaptor
& p2) { return p1.base()!=p2.base(); } } // namespace detail //////////////////////////////////////////////////////////////////////////////////////// /// MEMORY-BASED STEP ITERATOR //////////////////////////////////////////////////////////////////////////////////////// /// \class memory_based_step_iterator /// \ingroup PixelIteratorModelStepPtr PixelBasedModel /// \brief Iterator with dynamically specified step in memory units (bytes or bits). Models StepIteratorConcept, IteratorAdaptorConcept, MemoryBasedIteratorConcept, PixelIteratorConcept, HasDynamicXStepTypeConcept /// /// A refinement of step_iterator_adaptor that uses a dynamic parameter for the step /// which is specified in memory units, such as bytes or bits /// /// Pixel step iterators are used to provide iteration over non-adjacent pixels. /// Common use is a vertical traversal, where the step is the row stride. /// /// Another application is as a sub-channel view. For example, a red intensity image over /// interleaved RGB data would use a step iterator adaptor with step sizeof(channel_t)*3 /// In the latter example the step size could be fixed at compile time for efficiency. /// Compile-time fixed step can be implemented by providing a step function object that takes the step as a template //////////////////////////////////////////////////////////////////////////////////////// /// \ingroup PixelIteratorModelStepPtr /// \brief function object that returns the memory unit distance between two iterators and advances a given iterator a given number of mem units (bytes or bits) template
struct memunit_step_fn { typedef std::ptrdiff_t difference_type; memunit_step_fn(difference_type step=memunit_step(Iterator())) : _step(step) {} difference_type difference(const Iterator& it1, const Iterator& it2) const { return memunit_distance(it1,it2)/_step; } void advance(Iterator& it, difference_type d) const { memunit_advance(it,d*_step); } difference_type step() const { return _step; } void set_step(std::ptrdiff_t step) { _step=step; } private: GIL_CLASS_REQUIRE(Iterator, boost::gil, MemoryBasedIteratorConcept) difference_type _step; }; template
class memory_based_step_iterator : public detail::step_iterator_adaptor
, Iterator, memunit_step_fn
> { GIL_CLASS_REQUIRE(Iterator, boost::gil, MemoryBasedIteratorConcept) public: typedef detail::step_iterator_adaptor
, Iterator, memunit_step_fn
> parent_t; typedef typename parent_t::reference reference; typedef typename parent_t::difference_type difference_type; typedef Iterator x_iterator; memory_based_step_iterator() : parent_t(Iterator()) {} memory_based_step_iterator(Iterator it, std::ptrdiff_t memunit_step) : parent_t(it, memunit_step_fn
(memunit_step)) {} template
memory_based_step_iterator(const memory_based_step_iterator
& it) : parent_t(it.base(), memunit_step_fn
(it.step())) {} /// For some reason operator[] provided by iterator_adaptor returns a custom class that is convertible to reference /// We require our own reference because it is registered in iterator_traits reference operator[](difference_type d) const { return *(*this+d); } void set_step(std::ptrdiff_t memunit_step) { this->_step_fn.set_step(memunit_step); } x_iterator& base() { return parent_t::base_reference(); } x_iterator const& base() const { return parent_t::base_reference(); } }; template
struct const_iterator_type
> { typedef memory_based_step_iterator
::type> type; }; template
struct iterator_is_mutable
> : public iterator_is_mutable
{}; ///////////////////////////// // IteratorAdaptorConcept ///////////////////////////// template
struct is_iterator_adaptor
> : public mpl::true_{}; template
struct iterator_adaptor_get_base
> { typedef Iterator type; }; template
struct iterator_adaptor_rebind
,NewBaseIterator> { typedef memory_based_step_iterator
type; }; ///////////////////////////// // PixelBasedConcept ///////////////////////////// template
struct color_space_type
> : public color_space_type
{}; template
struct channel_mapping_type
> : public channel_mapping_type
{}; template
struct is_planar
> : public is_planar
{}; template
struct channel_type
> : public channel_type
{}; ///////////////////////////// // MemoryBasedIteratorConcept ///////////////////////////// template
struct byte_to_memunit
> : public byte_to_memunit
{}; template
inline std::ptrdiff_t memunit_step(const memory_based_step_iterator
& p) { return p.step(); } template
inline std::ptrdiff_t memunit_distance(const memory_based_step_iterator
& p1, const memory_based_step_iterator
& p2) { return memunit_distance(p1.base(),p2.base()); } template
inline void memunit_advance(memory_based_step_iterator
& p, std::ptrdiff_t diff) { memunit_advance(p.base(), diff); } template
inline memory_based_step_iterator
memunit_advanced(const memory_based_step_iterator
& p, std::ptrdiff_t diff) { return memory_based_step_iterator
(memunit_advanced(p.base(), diff),p.step()); } template
inline typename std::iterator_traits
::reference memunit_advanced_ref(const memory_based_step_iterator
& p, std::ptrdiff_t diff) { return memunit_advanced_ref(p.base(), diff); } ///////////////////////////// // HasDynamicXStepTypeConcept ///////////////////////////// template
struct dynamic_x_step_type
> { typedef memory_based_step_iterator
type; }; // For step iterators, pass the function object to the base template
struct iterator_add_deref
,Deref> { GIL_CLASS_REQUIRE(Deref, boost::gil, PixelDereferenceAdaptorConcept) typedef memory_based_step_iterator
::type> type; static type make(const memory_based_step_iterator
& it, const Deref& d) { return type(iterator_add_deref
::make(it.base(),d),it.step()); } }; //////////////////////////////////////////////////////////////////////////////////////// /// make_step_iterator //////////////////////////////////////////////////////////////////////////////////////// template
typename dynamic_x_step_type
::type make_step_iterator(const I& it, std::ptrdiff_t step); namespace detail { // if the iterator is a plain base iterator (non-adaptor), wraps it in memory_based_step_iterator template
typename dynamic_x_step_type
::type make_step_iterator_impl(const I& it, std::ptrdiff_t step, mpl::false_) { return memory_based_step_iterator
(it, step); } // If the iterator is compound, put the step in its base template
typename dynamic_x_step_type
::type make_step_iterator_impl(const I& it, std::ptrdiff_t step, mpl::true_) { return make_step_iterator(it.base(), step); } // If the iterator is memory_based_step_iterator, change the step template
memory_based_step_iterator
make_step_iterator_impl(const memory_based_step_iterator
& it, std::ptrdiff_t step, mpl::true_) { return memory_based_step_iterator
(it.base(), step); } } /// \brief Constructs a step iterator from a base iterator and a step. /// /// To construct a step iterator from a given iterator Iterator and a given step, if Iterator does not /// already have a dynamic step, we wrap it in a memory_based_step_iterator. Otherwise we /// do a compile-time traversal of the chain of iterator adaptors to locate the step iterator /// and then set it step to the new one. /// /// The step iterator of Iterator is not always memory_based_step_iterator
. For example, Iterator may /// already be a memory_based_step_iterator, in which case it will be inefficient to stack them; /// we can obtain the same result by multiplying their steps. Note that for Iterator to be a /// step iterator it does not necessarily have to have the form memory_based_step_iterator
. /// The step iterator can be wrapped inside another iterator. Also, it may not have the /// type memory_based_step_iterator, but it could be a user-provided type. template
// Models MemoryBasedIteratorConcept, HasDynamicXStepTypeConcept typename dynamic_x_step_type
::type make_step_iterator(const I& it, std::ptrdiff_t step) { return detail::make_step_iterator_impl(it, step, typename is_iterator_adaptor
::type()); } } } // namespace boost::gil #endif
step_iterator.hpp
网页地址
文件地址
上一页
31/34
下一页
下载
( 14 KB )
Comments
Total ratings:
0
Average rating:
无评论
of 10
Would you like to comment?
Join now
, or
Logon
if you are already a member.