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/////////////////////////////////////////////////////////////////////////////// // foreach.hpp header file // // Copyright 2004 Eric Niebler. // Distributed under 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://www.boost.org/libs/foreach for documentation // // Credits: // Anson Tsao - for the initial inspiration and several good suggestions. // Thorsten Ottosen - for Boost.Range, and for suggesting a way to detect // const-qualified rvalues at compile time on VC7.1+ // Russell Hind - For help porting to Borland // Alisdair Meredith - For help porting to Borland // Stefan Slapeta - For help porting to Intel // David Jenkins - For help finding a Microsoft Code Analysis bug #ifndef BOOST_FOREACH // MS compatible compilers support #pragma once #if defined(_MSC_VER) && (_MSC_VER >= 1020) # pragma once #endif #include
#include
// for std::pair #include
#include
// Some compilers let us detect even const-qualified rvalues at compile-time #if BOOST_WORKAROUND(BOOST_MSVC, >= 1310) && !defined(_PREFAST_) \ || (BOOST_WORKAROUND(__GNUC__, >= 4) && !defined(BOOST_INTEL)) \ || (BOOST_WORKAROUND(__GNUC__, == 3) && (__GNUC_MINOR__ >= 4) && !defined(BOOST_INTEL)) # define BOOST_FOREACH_COMPILE_TIME_CONST_RVALUE_DETECTION #else // Some compilers allow temporaries to be bound to non-const references. // These compilers make it impossible to for BOOST_FOREACH to detect // temporaries and avoid reevaluation of the collection expression. # if BOOST_WORKAROUND(BOOST_MSVC, <= 1300) \ || BOOST_WORKAROUND(__BORLANDC__, BOOST_TESTED_AT(0x564)) \ || (BOOST_WORKAROUND(BOOST_INTEL_CXX_VERSION, <= 700) && defined(_MSC_VER)) \ || BOOST_WORKAROUND(__SUNPRO_CC, BOOST_TESTED_AT(0x570)) \ || BOOST_WORKAROUND(__DECCXX_VER, BOOST_TESTED_AT(60590042)) # define BOOST_FOREACH_NO_RVALUE_DETECTION # endif // Some compilers do not correctly implement the lvalue/rvalue conversion // rules of the ternary conditional operator. # if defined(BOOST_FOREACH_NO_RVALUE_DETECTION) \ || defined(BOOST_NO_SFINAE) \ || BOOST_WORKAROUND(BOOST_MSVC, BOOST_TESTED_AT(1400)) \ || BOOST_WORKAROUND(BOOST_INTEL_WIN, <= 810) \ || BOOST_WORKAROUND(__GNUC__, < 3) \ || (BOOST_WORKAROUND(__GNUC__, == 3) && (__GNUC_MINOR__ <= 2)) \ || (BOOST_WORKAROUND(__GNUC__, == 3) && (__GNUC_MINOR__ <= 3) && defined(__APPLE_CC__)) \ || BOOST_WORKAROUND(__IBMCPP__, BOOST_TESTED_AT(600)) \ || BOOST_WORKAROUND(__MWERKS__, BOOST_TESTED_AT(0x3206)) # define BOOST_FOREACH_NO_CONST_RVALUE_DETECTION # else # define BOOST_FOREACH_RUN_TIME_CONST_RVALUE_DETECTION # endif #endif #include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#ifdef BOOST_FOREACH_RUN_TIME_CONST_RVALUE_DETECTION # include
# include
# include
# include
#endif // This must be at global scope, hence the uglified name enum boost_foreach_argument_dependent_lookup_hack { boost_foreach_argument_dependent_lookup_hack_value }; namespace boost { // forward declarations for iterator_range template
class iterator_range; // forward declarations for sub_range template
class sub_range; namespace foreach { /////////////////////////////////////////////////////////////////////////////// // in_range // template
inline std::pair
in_range(T begin, T end) { return std::make_pair(begin, end); } /////////////////////////////////////////////////////////////////////////////// // boost::foreach::tag // typedef boost_foreach_argument_dependent_lookup_hack tag; /////////////////////////////////////////////////////////////////////////////// // boost::foreach::is_lightweight_proxy // Specialize this for user-defined collection types if they are inexpensive to copy. // This tells BOOST_FOREACH it can avoid the rvalue/lvalue detection stuff. template
struct is_lightweight_proxy : boost::mpl::false_ { }; /////////////////////////////////////////////////////////////////////////////// // boost::foreach::is_noncopyable // Specialize this for user-defined collection types if they cannot be copied. // This also tells BOOST_FOREACH to avoid the rvalue/lvalue detection stuff. template
struct is_noncopyable #if !defined(BOOST_BROKEN_IS_BASE_AND_DERIVED) && !defined(BOOST_NO_IS_ABSTRACT) : boost::mpl::or_< boost::is_abstract
, boost::is_base_and_derived
> #elif !defined(BOOST_BROKEN_IS_BASE_AND_DERIVED) : boost::is_base_and_derived
#elif !defined(BOOST_NO_IS_ABSTRACT) : boost::is_abstract
#else : boost::mpl::false_ #endif { }; } // namespace foreach } // namespace boost // vc6/7 needs help ordering the following overloads #ifdef BOOST_NO_FUNCTION_TEMPLATE_ORDERING # define BOOST_FOREACH_TAG_DEFAULT ... #else # define BOOST_FOREACH_TAG_DEFAULT boost::foreach::tag #endif /////////////////////////////////////////////////////////////////////////////// // boost_foreach_is_lightweight_proxy // Another customization point for the is_lightweight_proxy optimization, // this one works on legacy compilers. Overload boost_foreach_is_lightweight_proxy // at the global namespace for your type. template
inline boost::foreach::is_lightweight_proxy
* boost_foreach_is_lightweight_proxy(T *&, BOOST_FOREACH_TAG_DEFAULT) { return 0; } template
inline boost::mpl::true_ * boost_foreach_is_lightweight_proxy(std::pair
*&, boost::foreach::tag) { return 0; } template
inline boost::mpl::true_ * boost_foreach_is_lightweight_proxy(boost::iterator_range
*&, boost::foreach::tag) { return 0; } template
inline boost::mpl::true_ * boost_foreach_is_lightweight_proxy(boost::sub_range
*&, boost::foreach::tag) { return 0; } template
inline boost::mpl::true_ * boost_foreach_is_lightweight_proxy(T **&, boost::foreach::tag) { return 0; } /////////////////////////////////////////////////////////////////////////////// // boost_foreach_is_noncopyable // Another customization point for the is_noncopyable trait, // this one works on legacy compilers. Overload boost_foreach_is_noncopyable // at the global namespace for your type. template
inline boost::foreach::is_noncopyable
* boost_foreach_is_noncopyable(T *&, BOOST_FOREACH_TAG_DEFAULT) { return 0; } namespace boost { namespace foreach_detail_ { /////////////////////////////////////////////////////////////////////////////// // Define some utilities for assessing the properties of expressions // typedef char yes_type; typedef char (&no_type)[2]; yes_type is_true(boost::mpl::true_ *); no_type is_true(boost::mpl::false_ *); // Extracts the desired property from the expression without evaluating it #define BOOST_FOREACH_PROTECT(expr) \ (static_cast
*>(0)) template
inline boost::mpl::and_
*and_(Bool1 *, Bool2 *) { return 0; } template
inline boost::mpl::and_
*and_(Bool1 *, Bool2 *, Bool3 *) { return 0; } template
inline boost::mpl::or_
*or_(Bool1 *, Bool2 *) { return 0; } template
inline boost::mpl::or_
*or_(Bool1 *, Bool2 *, Bool3 *) { return 0; } template
inline boost::mpl::not_
*not_(Bool *) { return 0; } template
inline boost::mpl::false_ *is_rvalue_(T &, int) { return 0; } template
inline boost::mpl::true_ *is_rvalue_(T const &, ...) { return 0; } template
inline boost::is_array
*is_array_(T const &) { return 0; } template
inline boost::is_const
*is_const_(T &) { return 0; } #ifndef BOOST_FOREACH_NO_RVALUE_DETECTION template
inline boost::mpl::true_ *is_const_(T const &) { return 0; } #endif /////////////////////////////////////////////////////////////////////////////// // auto_any_t/auto_any // General utility for putting an object of any type into automatic storage struct auto_any_base { // auto_any_base must evaluate to false in boolean context so that // they can be declared in if() statements. operator bool() const { return false; } }; template
struct auto_any : auto_any_base { auto_any(T const &t) : item(t) { } // temporaries of type auto_any will be bound to const auto_any_base // references, but we still want to be able to mutate the stored // data, so declare it as mutable. mutable T item; }; typedef auto_any_base const &auto_any_t; template
inline BOOST_DEDUCED_TYPENAME boost::mpl::if_
::type &auto_any_cast(auto_any_t a) { return static_cast
const &>(a).item; } typedef boost::mpl::true_ const_; /////////////////////////////////////////////////////////////////////////////// // type2type // template
struct type2type : boost::mpl::if_
{ }; template
struct wrap_cstr { typedef T type; }; template<> struct wrap_cstr
{ typedef wrap_cstr
type; typedef char *iterator; typedef char *const_iterator; }; template<> struct wrap_cstr
{ typedef wrap_cstr
type; typedef char const *iterator; typedef char const *const_iterator; }; template<> struct wrap_cstr
{ typedef wrap_cstr
type; typedef wchar_t *iterator; typedef wchar_t *const_iterator; }; template<> struct wrap_cstr
{ typedef wrap_cstr
type; typedef wchar_t const *iterator; typedef wchar_t const *const_iterator; }; template
struct is_char_array : mpl::and_< is_array
, mpl::or_< is_convertible
, is_convertible
> > {}; template
struct foreach_iterator { // **** READ THIS IF YOUR COMPILE BREAKS HERE **** // // There is an ambiguity about how to iterate over arrays of char and wchar_t. // Should the last array element be treated as a null terminator to be skipped, or // is it just like any other element in the array? To fix the problem, you must // say which behavior you want. // // To treat the container as a null-terminated string, merely cast it to a // char const *, as in BOOST_FOREACH( char ch, (char const *)"hello" ) ... // // To treat the container as an array, use boost::as_array() in
, // as in BOOST_FOREACH( char ch, boost::as_array("hello") ) ... #if BOOST_MSVC > 1300 BOOST_MPL_ASSERT_MSG( (!is_char_array
::value), IS_THIS_AN_ARRAY_OR_A_NULL_TERMINATED_STRING, (T) ); #endif // If the type is a pointer to a null terminated string (as opposed // to an array type), there is no ambiguity. typedef BOOST_DEDUCED_TYPENAME wrap_cstr
::type container; typedef BOOST_DEDUCED_TYPENAME boost::mpl::eval_if< C , range_const_iterator
, range_mutable_iterator
>::type type; }; template
struct foreach_reference : iterator_reference
::type> { }; /////////////////////////////////////////////////////////////////////////////// // encode_type // template
inline type2type
*encode_type(T &, boost::mpl::false_ *) { return 0; } template
inline type2type
*encode_type(T const &, boost::mpl::true_ *) { return 0; } /////////////////////////////////////////////////////////////////////////////// // set_false // inline bool set_false(bool &b) { return b = false; } /////////////////////////////////////////////////////////////////////////////// // to_ptr // template
inline T *&to_ptr(T const &) { static T *t = 0; return t; } // Borland needs a little extra help with arrays #if BOOST_WORKAROUND(__BORLANDC__, BOOST_TESTED_AT(0x564)) template
inline T (*&to_ptr(T (&)[N]))[N] { static T (*t)[N] = 0; return t; } #endif /////////////////////////////////////////////////////////////////////////////// // derefof // template
inline T &derefof(T *t) { // This is a work-around for a compiler bug in Borland. If T* is a pointer to array type U(*)[N], // then dereferencing it results in a U* instead of U(&)[N]. The cast forces the issue. return reinterpret_cast
( *const_cast
( reinterpret_cast
(t) ) ); } #ifdef BOOST_FOREACH_COMPILE_TIME_CONST_RVALUE_DETECTION /////////////////////////////////////////////////////////////////////////////// // Detect at compile-time whether an expression yields an rvalue or // an lvalue. This is rather non-standard, but some popular compilers // accept it. /////////////////////////////////////////////////////////////////////////////// /////////////////////////////////////////////////////////////////////////////// // rvalue_probe // template
struct rvalue_probe { struct private_type_ {}; // can't ever return an array by value typedef BOOST_DEDUCED_TYPENAME boost::mpl::if_< boost::mpl::or_
, boost::is_array
>, private_type_, T >::type value_type; operator value_type(); operator T &() const; }; template
rvalue_probe
const make_probe(T const &t); # define BOOST_FOREACH_IS_RVALUE(COL) \ boost::foreach_detail_::and_( \ boost::foreach_detail_::not_(boost::foreach_detail_::is_array_(COL)) \ , BOOST_FOREACH_PROTECT(boost::foreach_detail_::is_rvalue_( \ (true ? boost::foreach_detail_::make_probe(COL) : (COL)), 0))) #elif defined(BOOST_FOREACH_RUN_TIME_CONST_RVALUE_DETECTION) /////////////////////////////////////////////////////////////////////////////// // Detect at run-time whether an expression yields an rvalue // or an lvalue. This is 100% standard C++, but not all compilers // accept it. Also, it causes FOREACH to break when used with non- // copyable collection types. /////////////////////////////////////////////////////////////////////////////// /////////////////////////////////////////////////////////////////////////////// // rvalue_probe // template
struct rvalue_probe { rvalue_probe(T &t, bool &b) : value(t) , is_rvalue(b) { } struct private_type_ {}; // can't ever return an array or an abstract type by value #ifdef BOOST_NO_IS_ABSTRACT typedef BOOST_DEDUCED_TYPENAME boost::mpl::if_< boost::is_array
, private_type_, T >::type value_type; #else typedef BOOST_DEDUCED_TYPENAME boost::mpl::if_< boost::mpl::or_
, boost::is_array
>, private_type_, T >::type value_type; #endif operator value_type() { this->is_rvalue = true; return this->value; } operator T &() const { return this->value; } private: T &value; bool &is_rvalue; }; template
rvalue_probe
make_probe(T &t, bool &b) { return rvalue_probe
(t, b); } template
rvalue_probe
make_probe(T const &t, bool &b) { return rvalue_probe
(t, b); } /////////////////////////////////////////////////////////////////////////////// // simple_variant // holds either a T or a T const* template
struct simple_variant { simple_variant(T const *t) : is_rvalue(false) { *static_cast
(this->data.address()) = t; } simple_variant(T const &t) : is_rvalue(true) { ::new(this->data.address()) T(t); } simple_variant(simple_variant const &that) : is_rvalue(that.is_rvalue) { if(this->is_rvalue) ::new(this->data.address()) T(*that.get()); else *static_cast
(this->data.address()) = that.get(); } ~simple_variant() { if(this->is_rvalue) this->get()->~T(); } T const *get() const { if(this->is_rvalue) return static_cast
(this->data.address()); else return *static_cast
(this->data.address()); } private: enum size_type { size = sizeof(T) > sizeof(T*) ? sizeof(T) : sizeof(T*) }; simple_variant &operator =(simple_variant const &); bool const is_rvalue; aligned_storage
data; }; // If the collection is an array or is noncopyable, it must be an lvalue. // If the collection is a lightweight proxy, treat it as an rvalue // BUGBUG what about a noncopyable proxy? template
inline BOOST_DEDUCED_TYPENAME boost::enable_if
, IsProxy>::type * should_copy_impl(LValue *, IsProxy *, bool *) { return 0; } // Otherwise, we must determine at runtime whether it's an lvalue or rvalue inline bool * should_copy_impl(boost::mpl::false_ *, boost::mpl::false_ *, bool *is_rvalue) { return is_rvalue; } #endif /////////////////////////////////////////////////////////////////////////////// // contain // template
inline auto_any
contain(T const &t, boost::mpl::true_ *) // rvalue { return t; } template
inline auto_any
contain(T &t, boost::mpl::false_ *) // lvalue { // Cannot seem to get sunpro to handle addressof() with array types. #if BOOST_WORKAROUND(__SUNPRO_CC, BOOST_TESTED_AT(0x570)) return &t; #else return boost::addressof(t); #endif } #ifdef BOOST_FOREACH_RUN_TIME_CONST_RVALUE_DETECTION template
auto_any
> contain(T const &t, bool *rvalue) { return *rvalue ? simple_variant
(t) : simple_variant
(&t); } #endif ///////////////////////////////////////////////////////////////////////////// // begin // template
inline auto_any
::type> begin(auto_any_t col, type2type
*, boost::mpl::true_ *) // rvalue { return boost::begin(auto_any_cast
(col)); } template
inline auto_any
::type> begin(auto_any_t col, type2type
*, boost::mpl::false_ *) // lvalue { typedef BOOST_DEDUCED_TYPENAME type2type
::type type; typedef BOOST_DEDUCED_TYPENAME foreach_iterator
::type iterator; return iterator(boost::begin(derefof(auto_any_cast
(col)))); } #ifdef BOOST_FOREACH_RUN_TIME_CONST_RVALUE_DETECTION template
auto_any
::type> begin(auto_any_t col, type2type
*, bool *) { return boost::begin(*auto_any_cast
, boost::mpl::false_>(col).get()); } #endif #ifndef BOOST_NO_FUNCTION_TEMPLATE_ORDERING template
inline auto_any
begin(auto_any_t col, type2type
*, boost::mpl::true_ *) // null-terminated C-style strings { return auto_any_cast
(col); } #endif /////////////////////////////////////////////////////////////////////////////// // end // template
inline auto_any
::type> end(auto_any_t col, type2type
*, boost::mpl::true_ *) // rvalue { return boost::end(auto_any_cast
(col)); } template
inline auto_any
::type> end(auto_any_t col, type2type
*, boost::mpl::false_ *) // lvalue { typedef BOOST_DEDUCED_TYPENAME type2type
::type type; typedef BOOST_DEDUCED_TYPENAME foreach_iterator
::type iterator; return iterator(boost::end(derefof(auto_any_cast
(col)))); } #ifdef BOOST_FOREACH_RUN_TIME_CONST_RVALUE_DETECTION template
auto_any
::type> end(auto_any_t col, type2type
*, bool *) { return boost::end(*auto_any_cast
, boost::mpl::false_>(col).get()); } #endif #ifndef BOOST_NO_FUNCTION_TEMPLATE_ORDERING template
inline auto_any
end(auto_any_t col, type2type
*, boost::mpl::true_ *) // null-terminated C-style strings { return 0; // not used } #endif /////////////////////////////////////////////////////////////////////////////// // done // template
inline bool done(auto_any_t cur, auto_any_t end, type2type
*) { typedef BOOST_DEDUCED_TYPENAME foreach_iterator
::type iter_t; return auto_any_cast
(cur) == auto_any_cast
(end); } #ifndef BOOST_NO_FUNCTION_TEMPLATE_ORDERING template
inline bool done(auto_any_t cur, auto_any_t, type2type
*) // null-terminated C-style strings { return ! *auto_any_cast
(cur); } #endif /////////////////////////////////////////////////////////////////////////////// // next // template
inline void next(auto_any_t cur, type2type
*) { typedef BOOST_DEDUCED_TYPENAME foreach_iterator
::type iter_t; ++auto_any_cast
(cur); } /////////////////////////////////////////////////////////////////////////////// // deref // template
inline BOOST_DEDUCED_TYPENAME foreach_reference
::type deref(auto_any_t cur, type2type
*) { typedef BOOST_DEDUCED_TYPENAME foreach_iterator
::type iter_t; return *auto_any_cast
(cur); } } // namespace foreach_detail_ } // namespace boost // A sneaky way to get the type of the collection without evaluating the expression #define BOOST_FOREACH_TYPEOF(COL) \ (true ? 0 : boost::foreach_detail_::encode_type(COL, boost::foreach_detail_::is_const_(COL))) // returns true_* if the type is noncopyable #define BOOST_FOREACH_IS_NONCOPYABLE(COL) \ boost_foreach_is_noncopyable( \ boost::foreach_detail_::to_ptr(COL) \ , boost_foreach_argument_dependent_lookup_hack_value) // returns true_* if the type is a lightweight proxy (and is not noncopyable) #define BOOST_FOREACH_IS_LIGHTWEIGHT_PROXY(COL) \ boost::foreach_detail_::and_( \ boost::foreach_detail_::not_(BOOST_FOREACH_IS_NONCOPYABLE(COL)) \ , boost_foreach_is_lightweight_proxy( \ boost::foreach_detail_::to_ptr(COL) \ , boost_foreach_argument_dependent_lookup_hack_value)) #ifdef BOOST_FOREACH_COMPILE_TIME_CONST_RVALUE_DETECTION /////////////////////////////////////////////////////////////////////////////// // R-values and const R-values supported here with zero runtime overhead /////////////////////////////////////////////////////////////////////////////// // No variable is needed to track the rvalue-ness of the collection expression # define BOOST_FOREACH_PREAMBLE() \ /**/ // Evaluate the collection expression # define BOOST_FOREACH_EVALUATE(COL) \ (COL) # define BOOST_FOREACH_SHOULD_COPY(COL) \ (true ? 0 : boost::foreach_detail_::or_( \ BOOST_FOREACH_IS_RVALUE(COL) \ , BOOST_FOREACH_IS_LIGHTWEIGHT_PROXY(COL))) #elif defined(BOOST_FOREACH_RUN_TIME_CONST_RVALUE_DETECTION) /////////////////////////////////////////////////////////////////////////////// // R-values and const R-values supported here /////////////////////////////////////////////////////////////////////////////// // Declare a variable to track the rvalue-ness of the collection expression # define BOOST_FOREACH_PREAMBLE() \ if (bool _foreach_is_rvalue = false) {} else // Evaluate the collection expression, and detect if it is an lvalue or and rvalue # define BOOST_FOREACH_EVALUATE(COL) \ (true ? boost::foreach_detail_::make_probe((COL), _foreach_is_rvalue) : (COL)) // The rvalue/lvalue-ness of the collection expression is determined dynamically, unless // type type is an array or is noncopyable or is non-const, in which case we know it's an lvalue. // If the type happens to be a lightweight proxy, always make a copy. # define BOOST_FOREACH_SHOULD_COPY(COL) \ (boost::foreach_detail_::should_copy_impl( \ true ? 0 : boost::foreach_detail_::or_( \ boost::foreach_detail_::is_array_(COL) \ , BOOST_FOREACH_IS_NONCOPYABLE(COL) \ , boost::foreach_detail_::not_(boost::foreach_detail_::is_const_(COL))) \ , true ? 0 : BOOST_FOREACH_IS_LIGHTWEIGHT_PROXY(COL) \ , &_foreach_is_rvalue)) #elif !defined(BOOST_FOREACH_NO_RVALUE_DETECTION) /////////////////////////////////////////////////////////////////////////////// // R-values supported here, const R-values NOT supported here /////////////////////////////////////////////////////////////////////////////// // No variable is needed to track the rvalue-ness of the collection expression # define BOOST_FOREACH_PREAMBLE() \ /**/ // Evaluate the collection expression # define BOOST_FOREACH_EVALUATE(COL) \ (COL) // Determine whether the collection expression is an lvalue or an rvalue. // NOTE: this gets the answer wrong for const rvalues. # define BOOST_FOREACH_SHOULD_COPY(COL) \ (true ? 0 : boost::foreach_detail_::or_( \ boost::foreach_detail_::is_rvalue_((COL), 0) \ , BOOST_FOREACH_IS_LIGHTWEIGHT_PROXY(COL))) #else /////////////////////////////////////////////////////////////////////////////// // R-values NOT supported here /////////////////////////////////////////////////////////////////////////////// // No variable is needed to track the rvalue-ness of the collection expression # define BOOST_FOREACH_PREAMBLE() \ /**/ // Evaluate the collection expression # define BOOST_FOREACH_EVALUATE(COL) \ (COL) // Can't use rvalues with BOOST_FOREACH (unless they are lightweight proxies) # define BOOST_FOREACH_SHOULD_COPY(COL) \ (true ? 0 : BOOST_FOREACH_IS_LIGHTWEIGHT_PROXY(COL)) #endif #define BOOST_FOREACH_CONTAIN(COL) \ boost::foreach_detail_::contain( \ BOOST_FOREACH_EVALUATE(COL) \ , BOOST_FOREACH_SHOULD_COPY(COL)) #define BOOST_FOREACH_BEGIN(COL) \ boost::foreach_detail_::begin( \ _foreach_col \ , BOOST_FOREACH_TYPEOF(COL) \ , BOOST_FOREACH_SHOULD_COPY(COL)) #define BOOST_FOREACH_END(COL) \ boost::foreach_detail_::end( \ _foreach_col \ , BOOST_FOREACH_TYPEOF(COL) \ , BOOST_FOREACH_SHOULD_COPY(COL)) #define BOOST_FOREACH_DONE(COL) \ boost::foreach_detail_::done( \ _foreach_cur \ , _foreach_end \ , BOOST_FOREACH_TYPEOF(COL)) #define BOOST_FOREACH_NEXT(COL) \ boost::foreach_detail_::next( \ _foreach_cur \ , BOOST_FOREACH_TYPEOF(COL)) #define BOOST_FOREACH_DEREF(COL) \ boost::foreach_detail_::deref( \ _foreach_cur \ , BOOST_FOREACH_TYPEOF(COL)) /////////////////////////////////////////////////////////////////////////////// // BOOST_FOREACH // // For iterating over collections. Collections can be // arrays, null-terminated strings, or STL containers. // The loop variable can be a value or reference. For // example: // // std::list
int_list(/*stuff*/); // BOOST_FOREACH(int &i, int_list) // { // /* // * loop body goes here. // * i is a reference to the int in int_list. // */ // } // // Alternately, you can declare the loop variable first, // so you can access it after the loop finishes. Obviously, // if you do it this way, then the loop variable cannot be // a reference. // // int i; // BOOST_FOREACH(i, int_list) // { ... } // #define BOOST_FOREACH(VAR, COL) \ BOOST_FOREACH_PREAMBLE() \ if (boost::foreach_detail_::auto_any_t _foreach_col = BOOST_FOREACH_CONTAIN(COL)) {} else \ if (boost::foreach_detail_::auto_any_t _foreach_cur = BOOST_FOREACH_BEGIN(COL)) {} else \ if (boost::foreach_detail_::auto_any_t _foreach_end = BOOST_FOREACH_END(COL)) {} else \ for (bool _foreach_continue = true; \ _foreach_continue && !BOOST_FOREACH_DONE(COL); \ _foreach_continue ? BOOST_FOREACH_NEXT(COL) : (void)0) \ if (boost::foreach_detail_::set_false(_foreach_continue)) {} else \ for (VAR = BOOST_FOREACH_DEREF(COL); !_foreach_continue; _foreach_continue = true) #endif
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