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feedc0de:esp-idf-component feedc0de:feature/minstd_rand feedc0de:develop feedc0de:master feedc0de:feature/fix_operators_cxx20 feedc0de:feature/fix-eof-undeclared feedc0de:ostream_write feedc0de:feature/result_of-no-mpl feedc0de:string_view feedc0de:svn-branches/maintenance/1_55_0 feedc0de:svn-branches/modular-build feedc0de:svn-branches/maintenance/1_54_0 feedc0de:svn-branches/maintenance/1_50_0 feedc0de:svn-branches/filesystem-v3a feedc0de:sandbox-branches/birbacher/propertymap-functormap feedc0de:svn-branches/filesystem-v3 feedc0de:svn-branches/quickbook-dev feedc0de:sandbox-branches/optional_optimization feedc0de:svn-branches/doc-tools-docs feedc0de:svn-branches/quickbook-filenames feedc0de:svn-branches/filesystem3 feedc0de:svn-branches/inspect feedc0de:sandbox-branches/birbacher/fix_documentation feedc0de:svn-branches/units/autoprefix feedc0de:svn-branches/b2 feedc0de:svn-branches/maintenance/1_41 feedc0de:sandbox-branches/intrusive_fix_SunCC feedc0de:svn-branches/phoenix_v3 feedc0de:sandbox-branches/straszheim/merge_me_into_trunk feedc0de:svn-branches/sredl_2009_05_proptree_update feedc0de:sandbox-branches/bhy/py3k feedc0de:svn-branches/proto/v4 feedc0de:svn-branches/bcbboost feedc0de:svn-branches/initializer-list feedc0de:svn-branches/pdimov_pre_136 feedc0de:svn-branches/cpp0x feedc0de:svn-branches/doc feedc0de:svn-branches/proto/v4.bak feedc0de:svn-tags/start/Version_1_18_3 feedc0de:svn-branches/proto/v3 feedc0de:svn-branches/fix-links feedc0de:svn-branches/iostreams_dev feedc0de:svn-branches/bitten feedc0de:svn-branches/system feedc0de:sandbox-branches/birbacher/fix_iostreams feedc0de:svn-branches/hash feedc0de:svn-tags/tools/jam/Perforce_Jam_2_4_merge_1 feedc0de:svn-branches/multi_array feedc0de:svn-branches/xpressive/nested_dynamic_regex feedc0de:svn-branches/serialization_next_release feedc0de:svn-tags/jam/Perforce_Jam_2_4_merge_1 feedc0de:svn-tags/jam/perforce_2_4_merge_1 feedc0de:sandbox/trunk feedc0de:svn-tags/SPIRIT_MINIBOOST_1_34_0 feedc0de:svn-tags/SPIRIT_1_8_5_MINIBOOST feedc0de:svn-tags/SPIRIT_1_6_4_MINIBOOST feedc0de:svn-tags/merged_to_RC_1_34_0 feedc0de:svn-tags/RC_1_34_0_freeze feedc0de:svn-branches/array_wrapper feedc0de:svn-tags/merged_to_RC_1_33_0 feedc0de:svn-branches/RC_1_33_0 feedc0de:svn-branches/thread_rewrite feedc0de:svn-branches/SPIRIT_MINIBOOST feedc0de:svn-branches/RC_1_32_0 feedc0de:svn-tags/merged_to_RC_ feedc0de:svn-branches/SPIRIT_1_6 feedc0de:svn-branches/function_signature_patches_1_31 feedc0de:sandbox-branches/expaler feedc0de:svn-tags/minmax feedc0de:svn-tags/merged_to_RC_1_31_0 feedc0de:svn-branches/RC_1_31_0 feedc0de:svn-branches/RC_1_30_0 feedc0de:svn-tags/merged_to_RC_1_30_0 feedc0de:svn-branches/mpl_v2_2 feedc0de:svn-branches/RC_1_29_0 feedc0de:svn-tags/boost_python_llnl_ feedc0de:svn-branches/python-v2-dev feedc0de:svn-tags/RC_1_28_0_last_merge feedc0de:svn-branches/RC_1_28_0 feedc0de:svn-branches/compiler_supported_error_messages feedc0de:svn-tags/perforce_2_4_merge_1 feedc0de:svn-branches/RC_1_27_0 feedc0de:svn-branches/iterator_adaptor_update feedc0de:svn-branches/tmpw2001-paper feedc0de:svn-branches/split-config feedc0de:svn-branches/iter-adaptor-and-categories feedc0de:svn-branches/unlabeled-1.1.2 feedc0de:svn-branches/unlabeled-1.2.2 feedc0de:svn-branches/unlabeled-1.3.2 feedc0de:svn-branches/unlabeled-1.4.2 feedc0de:svn-branches/unlabeled-1.4.6 feedc0de:svn-branches/unlabeled-1.5.2 feedc0de:svn-branches/unlabeled-1.7.2 feedc0de:svn-branches/unlabeled-1.8.2 feedc0de:svn-branches/unlabeled-1.9.2 feedc0de:svn-branches/unlabeled-1.15.2 feedc0de:svn-branches/unlabeled-1.11.2 feedc0de:svn-branches/moved_pointer feedc0de:svn-branches/named-args feedc0de:svn-branches/better_indirect feedc0de:svn-branches/unlabeled-1.12.2 feedc0de:svn-branches/unlabeled-1.1.8 feedc0de:svn-branches/regex-sub feedc0de:svn-branches/boost-graph-library feedc0de:svn-tags/conversion-merge-1 feedc0de:svn-branches/conversion feedc0de:svn-branches/iterator-adaptors
feedc0de:boost-1.86.0 feedc0de:boost-1.86.0.beta1 feedc0de:boost-1.87.0 feedc0de:boost-1.87.0.beta1 feedc0de:boost-1.88.0 feedc0de:boost-1.88.0.beta1 feedc0de:boost-1.85.0 feedc0de:boost-1.85.0.beta1 feedc0de:boost-1.84.0 feedc0de:boost-1.84.0.beta1 feedc0de:boost-1.83.0 feedc0de:boost-1.83.0.beta1 feedc0de:boost-1.82.0 feedc0de:boost-1.81.0 feedc0de:boost-1.82.0.beta1 feedc0de:boost-1.81.0.beta1 feedc0de:boost-1.80.0 feedc0de:boost-1.80.0.beta1 feedc0de:boost-1.79.0 feedc0de:boost-1.79.0.beta1 feedc0de:boost-1.78.0 feedc0de:boost-1.78.0.beta1 feedc0de:boost-1.77.0 feedc0de:boost-1.77.0.beta1 feedc0de:boost-1.76.0 feedc0de:boost-1.76.0.beta1 feedc0de:boost-1.75.0 feedc0de:boost-1.75.0.beta1 feedc0de:boost-1.74.0.beta1 feedc0de:boost-1.74.0 feedc0de:boost-1.73.0.beta1 feedc0de:boost-1.73.0 feedc0de:boost-1.72.0 feedc0de:boost-1.72.0.beta1 feedc0de:boost-1.71.0.beta1 feedc0de:boost-1.71.0 feedc0de:boost-1.70.0 feedc0de:boost-1.70.0.beta1 feedc0de:boost-1.69.0 feedc0de:boost-1.69.0-beta1 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pull from: feedc0de:svn-branches/SPIRIT_1_6
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feedc0de:feature/minstd_rand feedc0de:esp-idf-component feedc0de:develop feedc0de:master feedc0de:feature/fix_operators_cxx20 feedc0de:feature/fix-eof-undeclared feedc0de:ostream_write feedc0de:feature/result_of-no-mpl feedc0de:string_view feedc0de:svn-branches/maintenance/1_55_0 feedc0de:svn-branches/modular-build feedc0de:svn-branches/maintenance/1_54_0 feedc0de:svn-branches/maintenance/1_50_0 feedc0de:svn-branches/filesystem-v3a feedc0de:sandbox-branches/birbacher/propertymap-functormap feedc0de:svn-branches/filesystem-v3 feedc0de:svn-branches/quickbook-dev feedc0de:sandbox-branches/optional_optimization feedc0de:svn-branches/doc-tools-docs feedc0de:svn-branches/quickbook-filenames feedc0de:svn-branches/filesystem3 feedc0de:svn-branches/inspect feedc0de:sandbox-branches/birbacher/fix_documentation feedc0de:svn-branches/units/autoprefix feedc0de:svn-branches/b2 feedc0de:svn-branches/maintenance/1_41 feedc0de:sandbox-branches/intrusive_fix_SunCC feedc0de:svn-branches/phoenix_v3 feedc0de:sandbox-branches/straszheim/merge_me_into_trunk feedc0de:svn-branches/sredl_2009_05_proptree_update feedc0de:sandbox-branches/bhy/py3k feedc0de:svn-branches/proto/v4 feedc0de:svn-branches/bcbboost feedc0de:svn-branches/initializer-list feedc0de:svn-branches/pdimov_pre_136 feedc0de:svn-branches/cpp0x feedc0de:svn-branches/doc feedc0de:svn-branches/proto/v4.bak feedc0de:svn-tags/start/Version_1_18_3 feedc0de:svn-branches/proto/v3 feedc0de:svn-branches/fix-links feedc0de:svn-branches/iostreams_dev feedc0de:svn-branches/bitten feedc0de:svn-branches/system feedc0de:sandbox-branches/birbacher/fix_iostreams feedc0de:svn-branches/hash feedc0de:svn-tags/tools/jam/Perforce_Jam_2_4_merge_1 feedc0de:svn-branches/multi_array feedc0de:svn-branches/xpressive/nested_dynamic_regex feedc0de:svn-branches/serialization_next_release feedc0de:svn-tags/jam/Perforce_Jam_2_4_merge_1 feedc0de:svn-tags/jam/perforce_2_4_merge_1 feedc0de:sandbox/trunk feedc0de:svn-tags/SPIRIT_MINIBOOST_1_34_0 feedc0de:svn-tags/SPIRIT_1_8_5_MINIBOOST feedc0de:svn-tags/SPIRIT_1_6_4_MINIBOOST feedc0de:svn-tags/merged_to_RC_1_34_0 feedc0de:svn-tags/RC_1_34_0_freeze feedc0de:svn-branches/array_wrapper feedc0de:svn-tags/merged_to_RC_1_33_0 feedc0de:svn-branches/RC_1_33_0 feedc0de:svn-branches/thread_rewrite feedc0de:svn-branches/SPIRIT_MINIBOOST feedc0de:svn-branches/RC_1_32_0 feedc0de:svn-tags/merged_to_RC_ feedc0de:svn-branches/SPIRIT_1_6 feedc0de:svn-branches/function_signature_patches_1_31 feedc0de:sandbox-branches/expaler feedc0de:svn-tags/minmax feedc0de:svn-tags/merged_to_RC_1_31_0 feedc0de:svn-branches/RC_1_31_0 feedc0de:svn-branches/RC_1_30_0 feedc0de:svn-tags/merged_to_RC_1_30_0 feedc0de:svn-branches/mpl_v2_2 feedc0de:svn-branches/RC_1_29_0 feedc0de:svn-tags/boost_python_llnl_ feedc0de:svn-branches/python-v2-dev feedc0de:svn-tags/RC_1_28_0_last_merge feedc0de:svn-branches/RC_1_28_0 feedc0de:svn-branches/compiler_supported_error_messages feedc0de:svn-tags/perforce_2_4_merge_1 feedc0de:svn-branches/RC_1_27_0 feedc0de:svn-branches/iterator_adaptor_update feedc0de:svn-branches/tmpw2001-paper feedc0de:svn-branches/split-config feedc0de:svn-branches/iter-adaptor-and-categories feedc0de:svn-branches/unlabeled-1.1.2 feedc0de:svn-branches/unlabeled-1.2.2 feedc0de:svn-branches/unlabeled-1.3.2 feedc0de:svn-branches/unlabeled-1.4.2 feedc0de:svn-branches/unlabeled-1.4.6 feedc0de:svn-branches/unlabeled-1.5.2 feedc0de:svn-branches/unlabeled-1.7.2 feedc0de:svn-branches/unlabeled-1.8.2 feedc0de:svn-branches/unlabeled-1.9.2 feedc0de:svn-branches/unlabeled-1.15.2 feedc0de:svn-branches/unlabeled-1.11.2 feedc0de:svn-branches/moved_pointer feedc0de:svn-branches/named-args feedc0de:svn-branches/better_indirect feedc0de:svn-branches/unlabeled-1.12.2 feedc0de:svn-branches/unlabeled-1.1.8 feedc0de:svn-branches/regex-sub feedc0de:svn-branches/boost-graph-library feedc0de:svn-tags/conversion-merge-1 feedc0de:svn-branches/conversion feedc0de:svn-branches/iterator-adaptors boostorg:develop boostorg:master boostorg:feature/minstd_rand boostorg:feature/fix_operators_cxx20 boostorg:feature/fix-eof-undeclared boostorg:ostream_write boostorg:feature/result_of-no-mpl boostorg:string_view boostorg:svn-branches/maintenance/1_55_0 boostorg:svn-branches/modular-build boostorg:svn-branches/maintenance/1_54_0 boostorg:svn-branches/maintenance/1_50_0 boostorg:svn-branches/filesystem-v3a boostorg:sandbox-branches/birbacher/propertymap-functormap boostorg:svn-branches/filesystem-v3 boostorg:svn-branches/quickbook-dev boostorg:sandbox-branches/optional_optimization boostorg:svn-branches/doc-tools-docs boostorg:svn-branches/quickbook-filenames boostorg:svn-branches/filesystem3 boostorg:svn-branches/inspect boostorg:sandbox-branches/birbacher/fix_documentation boostorg:svn-branches/units/autoprefix boostorg:svn-branches/b2 boostorg:svn-branches/maintenance/1_41 boostorg:sandbox-branches/intrusive_fix_SunCC boostorg:svn-branches/phoenix_v3 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boostorg:svn-tags/SPIRIT_1_8_5_MINIBOOST boostorg:svn-tags/SPIRIT_1_6_4_MINIBOOST boostorg:svn-tags/merged_to_RC_1_34_0 boostorg:svn-tags/RC_1_34_0_freeze boostorg:svn-branches/array_wrapper boostorg:svn-tags/merged_to_RC_1_33_0 boostorg:svn-branches/RC_1_33_0 boostorg:svn-branches/thread_rewrite boostorg:svn-branches/SPIRIT_MINIBOOST boostorg:svn-branches/RC_1_32_0 boostorg:svn-tags/merged_to_RC_ boostorg:svn-branches/SPIRIT_1_6 boostorg:svn-branches/function_signature_patches_1_31 boostorg:sandbox-branches/expaler boostorg:svn-tags/minmax boostorg:svn-tags/merged_to_RC_1_31_0 boostorg:svn-branches/RC_1_31_0 boostorg:svn-branches/RC_1_30_0 boostorg:svn-tags/merged_to_RC_1_30_0 boostorg:svn-branches/mpl_v2_2 boostorg:svn-branches/RC_1_29_0 boostorg:svn-tags/boost_python_llnl_ boostorg:svn-branches/python-v2-dev boostorg:svn-tags/RC_1_28_0_last_merge boostorg:svn-branches/RC_1_28_0 boostorg:svn-branches/compiler_supported_error_messages boostorg:svn-tags/perforce_2_4_merge_1 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1 Commits
svn-branch ... svn-branch

Author SHA1 Message Date
nobody
4af61235b9 This commit was manufactured by cvs2svn to create branch 'SPIRIT_1_6'. 
[SVN r23968]
 2004-07-23 02:16:28 +00:00
61 changed files with 0 additions and 12185 deletions
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<HTML>
<!--
-- Copyright (c) Jeremy Siek 2000
--
-- Permission to use, copy, modify, distribute and sell this software
-- and its documentation for any purpose is hereby granted without fee,
-- provided that the above copyright notice appears in all copies and
-- that both that copyright notice and this permission notice appear
-- in supporting documentation. Silicon Graphics makes no
-- representations about the suitability of this software for any
-- purpose. It is provided "as is" without express or implied warranty.
-->
<Head>
<Title>Assignable</Title>
</HEAD>
<BODY BGCOLOR="#ffffff" LINK="#0000ee" TEXT="#000000" VLINK="#551a8b"
ALINK="#ff0000">
<IMG SRC="../../c++boost.gif"
ALT="C++ Boost" width="277" height="86">
<!--end header-->
<BR Clear>
<H1>Assignable</H1>
<h3>Description</h3>
A type is Assignable if it is possible to assign one object of the type
to another object of that type.
<h3>Notation</h3>
<Table>
<TR>
<TD VAlign=top>
<tt>T</tt>
</TD>
<TD VAlign=top>
is type that is a model of Assignable
</TD>
</TR>
<TR>
<TD VAlign=top>
<tt>t</tt>
</TD>
<TD VAlign=top>
is an object of type <tt>T</tt>
</TD>
</tr>
<TR>
<TD VAlign=top>
<tt>u</tt>
</TD>
<TD VAlign=top>
is an object of type <tt>T</tt> or possibly <tt>const T</tt>
</TD>
</tr>
</table>
<h3>Definitions</h3>
<h3>Valid expressions</h3>
<Table border>
<TR>
<TH>
Name
</TH>
<TH>
Expression
</TH>
<TH>
Return type
</TH>
<TH>
Semantics
</TH>
</TR>
<TR>
<TD VAlign=top>
Assignment
</TD>
<TD VAlign=top>
<tt>t = u</tt>
</TD>
<TD VAlign=top>
<tt>T&amp;</tt>
</TD>
<TD VAlign=top>
<tt>t</tt> is equivalent to <tt>u</tt>
</TD>
</TR>
</table>
</table>
<h3>Models</h3>
<UL>
<LI><tt>int</tt>
<LI><tt>std::pair</tt>
</UL>
<h3>See also</h3>
<a href="http://www.sgi.com/tech/stl/DefaultConstructible.html">DefaultConstructible</A>
and
<A href="./CopyConstructible.html">CopyConstructible</A>
<br>
<HR>
<TABLE>
<TR valign=top>
<TD nowrap>Copyright &copy 2000</TD><TD>
<A HREF=http://www.lsc.nd.edu/~jsiek>Jeremy Siek</A>, Univ.of Notre Dame (<A HREF="mailto:jsiek@lsc.nd.edu">jsiek@lsc.nd.edu</A>)
</TD></TR></TABLE>
</BODY>
</HTML>

648
Collection.html
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<HTML>
<!--
-- Copyright (c) Jeremy Siek 2000
--
-- Permission to use, copy, modify, distribute and sell this software
-- and its documentation for any purpose is hereby granted without fee,
-- provided that the above copyright notice appears in all copies and
-- that both that copyright notice and this permission notice appear
-- in supporting documentation. Silicon Graphics makes no
-- representations about the suitability of this software for any
-- purpose. It is provided "as is" without express or implied warranty.
-->
<Head>
<Title>Collection</Title>
</HEAD>
<BODY BGCOLOR="#ffffff" LINK="#0000ee" TEXT="#000000" VLINK="#551a8b"
ALINK="#ff0000">
<h1>
<img src="../../c++boost.gif" alt="boost logo"
width="277" align="middle" height="86">
<br>Collection
</h1>
<h3>Description</h3>
A Collection is a <i>concept</i> similar to the STL <a
href="http://www.sgi.com/tech/stl/Container.html">Container</a>
concept. A Collection provides iterators for accessing a range of
elements and provides information about the number of elements in the
Collection. However, a Collection has fewer requirements than a
Container. The motivation for the Collection concept is that there are
many useful Container-like types that do not meet the full
requirements of Container, and many algorithms that can be written
with this reduced set of requirements. To summarize the reduction
in requirements:
<UL>
<LI>It is not required to &quot;own&quot; its elements: the lifetime
of an element in a Collection does not have to match the lifetime of
the Collection object, though the lifetime of the element should cover
the lifetime of the Collection object.
<LI>The semantics of copying a Collection object is not defined (it
could be a deep or shallow copy or not even support copying).
<LI>The associated reference type of a Collection does
not have to be a real C++ reference.
</UL>
Because of the reduced requirements, some care must be taken when
writing code that is meant to be generic for all Collection types.
In particular, a Collection object should be passed by-reference
since assumptions can not be made about the behaviour of the
copy constructor.
<p>
<h3>Associated types</h3>
<Table border>
<TR>
<TD VAlign=top>
Value type
</TD>
<TD VAlign=top>
<tt>X::value_type</tt>
</TD>
<TD VAlign=top>
The type of the object stored in a Collection.
If the Collection is <i>mutable</i> then
the value type must be <A
href="http://www.sgi.com/tech/stl/Assignable.html">Assignable</A>.
Otherwise the value type must be <a href="./CopyConstructible.html">CopyConstructible</a>.
</TD>
</TR>
<TR>
<TD VAlign=top>
Iterator type
</TD>
<TD VAlign=top>
<tt>X::iterator</tt>
</TD>
<TD VAlign=top>
The type of iterator used to iterate through a Collection's
elements. The iterator's value type is expected to be the
Collection's value type. A conversion
from the iterator type to the const iterator type must exist.
The iterator type must be an <A href="http://www.sgi.com/tech/stl/InputIterator.html">InputIterator</A>.
</TD>
</TR>
<TR>
<TD VAlign=top>
Const iterator type
</TD>
<TD VAlign=top>
<tt>X::const_iterator</tt>
</TD>
<TD VAlign=top>
A type of iterator that may be used to examine, but not to modify,
a Collection's elements.
</TD>
</TR>
<TR>
<TD VAlign=top>
Reference type
</TD>
<TD VAlign=top>
<tt>X::reference</tt>
</TD>
<TD VAlign=top>
A type that behaves like a reference to the Collection's value type.
<a href="#1">[1]</a>
</TD>
</TR>
<TR>
<TD VAlign=top>
Const reference type
</TD>
<TD VAlign=top>
<tt>X::const_reference</tt>
</TD>
<TD VAlign=top>
A type that behaves like a const reference to the Collection's value type.
</TD>
</TR>
<TR>
<TD VAlign=top>
Pointer type
</TD>
<TD VAlign=top>
<tt>X::pointer</tt>
</TD>
<TD VAlign=top>
A type that behaves as a pointer to the Collection's value type.
</TD>
</TR>
<TR>
<TD VAlign=top>
Distance type
</TD>
<TD VAlign=top>
<tt>X::difference_type</tt>
</TD>
<TD VAlign=top>
A signed integral type used to represent the distance between two
of the Collection's iterators. This type must be the same as
the iterator's distance type.
</TD>
</TR>
<TR>
<TD VAlign=top>
Size type
</TD>
<TD VAlign=top>
<tt>X::size_type</tt>
</TD>
<TD VAlign=top>
An unsigned integral type that can represent any nonnegative value
of the Collection's distance type.
</TD>
</tr>
</table>
<h3>Notation</h3>
<Table>
<TR>
<TD VAlign=top>
<tt>X</tt>
</TD>
<TD VAlign=top>
A type that is a model of Collection.
</TD>
</TR>
<TR>
<TD VAlign=top>
<tt>a</tt>, <tt>b</tt>
</TD>
<TD VAlign=top>
Object of type <tt>X</tt>.
</TD>
</TR>
<TR>
<TD VAlign=top>
<tt>T</tt>
</TD>
<TD VAlign=top>
The value type of <tt>X</tt>.
</TD>
</tr>
</table>
<h3>Valid expressions</h3>
The following expressions must be valid.
<p>
<Table border>
<TR>
<TH>
Name
</TH>
<TH>
Expression
</TH>
<TH>
Return type
</TH>
</TR>
<TR>
<TD VAlign=top>
Beginning of range
</TD>
<TD VAlign=top>
<tt>a.begin()</tt>
</TD>
<TD VAlign=top>
<tt>iterator</tt> if <tt>a</tt> is mutable, <tt>const_iterator</tt> otherwise
</TD>
</TR>
<TR>
<TD VAlign=top>
End of range
</TD>
<TD VAlign=top>
<tt>a.end()</tt>
</TD>
<TD VAlign=top>
<tt>iterator</tt> if <tt>a</tt> is mutable, <tt>const_iterator</tt> otherwise
</TD>
</TR>
<TR>
<TD VAlign=top>
Size
</TD>
<TD VAlign=top>
<tt>a.size()</tt>
</TD>
<TD VAlign=top>
<tt>size_type</tt>
</TD>
</TR>
<!--
<TR>
<TD VAlign=top>
Maximum size
</TD>
<TD VAlign=top>
<tt>a.max_size()</tt>
</TD>
<TD VAlign=top>
<tt>size_type</tt>
</TD>
</TR>
<TR>
-->
<TD VAlign=top>
Empty Collection
</TD>
<TD VAlign=top>
<tt>a.empty()</tt>
</TD>
<TD VAlign=top>
Convertible to <tt>bool</tt>
</TD>
</TR>
<TR>
<TD VAlign=top>
Swap
</TD>
<TD VAlign=top>
<tt>a.swap(b)</tt>
</TD>
<TD VAlign=top>
<tt>void</tt>
</TD>
</tr>
</table>
<h3>Expression semantics</h3>
<Table border>
<TR>
<TH>
Name
</TH>
<TH>
Expression
</TH>
<TH>
Semantics
</TH>
<TH>
Postcondition
</TH>
</TR>
<TD VAlign=top>
<TR>
<TD VAlign=top>
Beginning of range
</TD>
<TD VAlign=top>
<tt>a.begin()</tt>
</TD>
<TD VAlign=top>
Returns an iterator pointing to the first element in the Collection.
</TD>
<TD VAlign=top>
<tt>a.begin()</tt> is either dereferenceable or past-the-end. It is
past-the-end if and only if <tt>a.size() == 0</tt>.
</TD>
</TR>
<TR>
<TD VAlign=top>
End of range
</TD>
<TD VAlign=top>
<tt>a.end()</tt>
</TD>
<TD VAlign=top>
Returns an iterator pointing one past the last element in the
Collection.
</TD>
<TD VAlign=top>
<tt>a.end()</tt> is past-the-end.
</TD>
</TR>
<TR>
<TD VAlign=top>
Size
</TD>
<TD VAlign=top>
<tt>a.size()</tt>
</TD>
<TD VAlign=top>
Returns the size of the Collection, that is, its number of elements.
</TD>
<TD VAlign=top>
<tt>a.size() &gt;= 0
</TD>
</TR>
<!--
<TR>
<TD VAlign=top>
Maximum size
</TD>
<TD VAlign=top>
<tt>a.max_size()</tt>
</TD>
<TD VAlign=top>
&nbsp;
</TD>
<TD VAlign=top>
Returns the largest size that this Collection can ever have. <A href="#8">[8]</A>
</TD>
<TD VAlign=top>
<tt>a.max_size() &gt;= 0 &amp;&amp; a.max_size() &gt;= a.size()</tt>
</TD>
</TR>
-->
<TR>
<TD VAlign=top>
Empty Collection
</TD>
<TD VAlign=top>
<tt>a.empty()</tt>
</TD>
<TD VAlign=top>
Equivalent to <tt>a.size() == 0</tt>. (But possibly faster.)
</TD>
<TD VAlign=top>
&nbsp;
</TD>
</TR>
<TR>
<TD VAlign=top>
Swap
</TD>
<TD VAlign=top>
<tt>a.swap(b)</tt>
</TD>
<TD VAlign=top>
Equivalent to <tt>swap(a,b)</tt>
</TD>
<TD VAlign=top>
&nbsp;
</TD>
</tr>
</table>
<h3>Complexity guarantees</h3>
<tt>begin()</tt> and <tt>end()</tt> are amortized constant time.
<P>
<tt>size()</tt> is at most linear in the Collection's
size. <tt>empty()</tt> is amortized constant time.
<P>
<tt>swap()</tt> is at most linear in the size of the two collections.
<h3>Invariants</h3>
<Table border>
<TR>
<TD VAlign=top>
Valid range
</TD>
<TD VAlign=top>
For any Collection <tt>a</tt>, <tt>[a.begin(), a.end())</tt> is a valid
range.
</TD>
</TR>
<TR>
<TD VAlign=top>
Range size
</TD>
<TD VAlign=top>
<tt>a.size()</tt> is equal to the distance from <tt>a.begin()</tt> to <tt>a.end()</tt>.
</TD>
</TR>
<TR>
<TD VAlign=top>
Completeness
</TD>
<TD VAlign=top>
An algorithm that iterates through the range <tt>[a.begin(), a.end())</tt>
will pass through every element of <tt>a</tt>.
</TD>
</tr>
</table>
<h3>Models</h3>
<UL>
<LI> <tt>array</tt>
<LI> <tt>array_ptr</tt>
<LI> <tt>vector&lt;bool&gt;</tt>
</UL>
<h3>Collection Refinements</h3>
There are quite a few concepts that refine the Collection concept,
similar to the concepts that refine the Container concept. Here
is a brief overview of the refining concepts.
<h4>ForwardCollection</h4>
The elements are arranged in some order that
does not change spontaneously from one iteration to the next. As
a result, a ForwardCollection is
<A
href="http://www.sgi.com/tech/stl/EqualityComparable.html">EqualityComparable</A>
and
<A
href="http://www.sgi.com/tech/stl/LessThanComparable.html">LessThanComparable</A>.
In addition, the iterator type of a ForwardCollection is a
MultiPassInputIterator which is just an InputIterator with the added
requirements that the iterator can be used to make multiple passes
through a range, and that if <tt>it1 == it2</tt> and <tt>it1</tt> is
dereferenceable then <tt>++it1 == ++it2</tt>. The ForwardCollection
also has a <tt>front()</tt> method.
<p>
<Table border>
<TR>
<TH>
Name
</TH>
<TH>
Expression
</TH>
<TH>
Return type
</TH>
<TH>
Semantics
</TH>
</TR>
<TR>
<TD VAlign=top>
Front
</TD>
<TD VAlign=top>
<tt>a.front()</tt>
</TD>
<TD VAlign=top>
<tt>reference</tt> if <tt>a</tt> is mutable, <br> <tt>const_reference</tt>
otherwise.
</TD>
<TD VAlign=top>
Equivalent to <tt>*(a.begin())</tt>.
</TD>
</TR>
</table>
<h4>ReversibleCollection</h4>
The container provides access to iterators that traverse in both
directions (forward and reverse). The iterator type must meet all of
the requirements of
<a href="http://www.sgi.com/tech/stl/BidirectionalIterator.html">BidirectionalIterator</a>
except that the reference type does not have to be a real C++
reference. The ReversibleCollection adds the following requirements
to those of ForwardCollection.
<p>
<Table border>
<TR>
<TH>
Name
</TH>
<TH>
Expression
</TH>
<TH>
Return type
</TH>
<TH>
Semantics
</TH>
</TR>
<TR>
<TD VAlign=top>
Beginning of range
</TD>
<TD VAlign=top>
<tt>a.rbegin()</tt>
</TD>
<TD VAlign=top>
<tt>reverse_iterator</tt> if <tt>a</tt> is mutable,
<tt>const_reverse_iterator</tt> otherwise.
</TD>
<TD VAlign=top>
Equivalent to <tt>X::reverse_iterator(a.end())</tt>.
</TD>
</TR>
<TR>
<TD VAlign=top>
End of range
</TD>
<TD VAlign=top>
<tt>a.rend()</tt>
</TD>
<TD VAlign=top>
<tt>reverse_iterator</tt> if <tt>a</tt> is mutable,
<tt>const_reverse_iterator</tt> otherwise.
</TD>
<TD VAlign=top>
Equivalent to <tt>X::reverse_iterator(a.begin())</tt>.
</TD>
</tr>
<TR>
<TD VAlign=top>
Back
</TD>
<TD VAlign=top>
<tt>a.back()</tt>
</TD>
<TD VAlign=top>
<tt>reference</tt> if <tt>a</tt> is mutable, <br> <tt>const_reference</tt>
otherwise.
</TD>
<TD VAlign=top>
Equivalent to <tt>*(--a.end())</tt>.
</TD>
</TR>
</table>
<h4>SequentialCollection</h4>
The elements are arranged in a strict linear order. No extra methods
are required.
<h4>RandomAccessCollection</h4>
The iterators of a RandomAccessCollection satisfy all of the
requirements of <a
href="http://www.sgi.com/tech/stl/RandomAccessIterator.html">RandomAccessIterator</a>
except that the reference type does not have to be a real C++
reference. In addition, a RandomAccessCollection provides
an element access operator.
<p>
<Table border>
<TR>
<TH>
Name
</TH>
<TH>
Expression
</TH>
<TH>
Return type
</TH>
<TH>
Semantics
</TH>
</TR>
<TR>
<TD VAlign=top>
Element Access
</TD>
<TD VAlign=top>
<tt>a[n]</tt>
</TD>
<TD VAlign=top>
<tt>reference</tt> if <tt>a</tt> is mutable,
<tt>const_reference</tt> otherwise.
</TD>
<TD VAlign=top>
Returns the nth element of the Collection.
<tt>n</tt> must be convertible to <tt>size_type</tt>.
Precondition: <tt>0 &lt;= n &lt; a.size()</tt>.
</TD>
</TR>
</table>
<h3>Notes</h3>
<P><A name="1">[1]</A>
The reference type does not have to be a real C++ reference. The
requirements of the reference type depend on the context within which
the Collection is being used. Specifically it depends on the
requirements the context places on the value type of the Collection.
The reference type of the Collection must meet the same requirements
as the value type. In addition, the reference objects must be
equivalent to the value type objects in the collection (which is
trivially true if they are the same object). Also, in a mutable
Collection, an assignment to the reference object must result in an
assignment to the object in the Collection (again, which is trivially
true if they are the same object, but non-trivial if the reference
type is a proxy class).
<h3>See also</h3>
<A href="http://www.sgi.com/tech/stl/Container.html">Container</A>
<br>
<HR>
<TABLE>
<TR valign=top>
<TD nowrap>Copyright &copy 2000</TD><TD>
<A HREF=http://www.boost.org/people/jeremy_siek.htm>Jeremy Siek</A>, Univ.of Notre Dame and C++ Library & Compiler Group/SGI (<A HREF="mailto:jsiek@engr.sgi.com">jsiek@engr.sgi.com</A>)
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<Head>
<Title>Copy Constructible</Title>
</HEAD>
<BODY BGCOLOR="#ffffff" LINK="#0000ee" TEXT="#000000" VLINK="#551a8b"
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<IMG SRC="../../c++boost.gif"
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<BR Clear>
<H1>Copy Constructible</H1>
<h3>Description</h3>
A type is Copy Constructible if it is possible to copy objects of that
type.
<h3>Notation</h3>
<Table>
<TR>
<TD VAlign=top>
<tt>T</tt>
</TD>
<TD VAlign=top>
is type that is a model of Copy Constructible
</TD>
</TR>
<TR>
<TD VAlign=top>
<tt>t</tt>
</TD>
<TD VAlign=top>
is an object of type <tt>T</tt>
</TD>
</tr>
<TR>
<TD VAlign=top>
<tt>u</tt>
</TD>
<TD VAlign=top>
is an object of type <tt>const T</tt>
</TD>
</tr>
</table>
<h3>Definitions</h3>
<h3>Valid expressions</h3>
<Table border>
<TR>
<TH>
Name
</TH>
<TH>
Expression
</TH>
<TH>
Return type
</TH>
<TH>
Semantics
</TH>
</TR>
<TR>
<TD VAlign=top>
Copy constructor
</TD>
<TD VAlign=top>
<tt>T(t)</tt>
</TD>
<TD VAlign=top>
<tt>T</tt>
</TD>
<TD VAlign=top>
<tt>t</tt> is equivalent to <tt>T(t)</tt>
</TD>
</TR>
<TR>
<TD VAlign=top>
Copy constructor
</TD>
<TD VAlign=top>
<pre>
T(u)
</pre>
</TD>
<TD VAlign=top>
<tt>T</tt>
</TD>
<TD VAlign=top>
<tt>u</tt> is equivalent to <tt>T(u)</tt>
</TD>
</TR>
<TR>
<TD VAlign=top>
Destructor
</TD>
<TD VAlign=top>
<pre>
t.~T()
</pre>
</TD>
<TD VAlign=top>
<tt>T</tt>
</TD>
<TD VAlign=top>
&nbsp;
</TD>
</TR>
<TR>
<TD VAlign=top>
Address Operator
</TD>
<TD VAlign=top>
<pre>
&amp;t
</pre>
</TD>
<TD VAlign=top>
<tt>T*</tt>
</TD>
<TD VAlign=top>
denotes the address of <tt>t</tt>
</TD>
</TR>
<TR>
<TD VAlign=top>
Address Operator
</TD>
<TD VAlign=top>
<pre>
&amp;u
</pre>
</TD>
<TD VAlign=top>
<tt>T*</tt>
</TD>
<TD VAlign=top>
denotes the address of <tt>u</tt>
</TD>
</TR>
</table>
</table>
<h3>Models</h3>
<UL>
<LI><tt>int</tt>
<LI><tt>std::pair</tt>
</UL>
<h3>Concept Checking Class</h3>
<pre>
template &lt;class T&gt;
struct CopyConstructibleConcept
{
void constraints() {
T a(b); // require copy constructor
T* ptr = &amp;a; // require address of operator
const_constraints(a);
ignore_unused_variable_warning(ptr);
}
void const_constraints(const T&amp; a) {
T c(a); // require const copy constructor
const T* ptr = &amp;a; // require const address of operator
ignore_unused_variable_warning(c);
ignore_unused_variable_warning(ptr);
}
T b;
};
</pre>
<h3>See also</h3>
<A
href="http://www.sgi.com/tech/stl/DefaultConstructible.html">Default Constructible</A>
and
<A hrefa="./Assignable.html">Assignable</A>
<br>
<HR>
<TABLE>
<TR valign=top>
<TD nowrap>Copyright &copy 2000</TD><TD>
<A HREF=http://www.lsc.nd.edu/~jsiek>Jeremy Siek</A>, Univ.of Notre Dame (<A HREF="mailto:jsiek@lsc.nd.edu">jsiek@lsc.nd.edu</A>)
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-- in supporting documentation. Silicon Graphics makes no
-- representations about the suitability of this software for any
-- purpose. It is provided "as is" without express or implied warranty.
-->
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-- Copyright (c) 1996-1999
-- Silicon Graphics Computer Systems, Inc.
--
-- Permission to use, copy, modify, distribute and sell this software
-- and its documentation for any purpose is hereby granted without fee,
-- provided that the above copyright notice appears in all copies and
-- that both that copyright notice and this permission notice appear
-- in supporting documentation. Silicon Graphics makes no
-- representations about the suitability of this software for any
-- purpose. It is provided "as is" without express or implied warranty.
--
-- Copyright (c) 1994
-- Hewlett-Packard Company
--
-- Permission to use, copy, modify, distribute and sell this software
-- and its documentation for any purpose is hereby granted without fee,
-- provided that the above copyright notice appears in all copies and
-- that both that copyright notice and this permission notice appear
-- in supporting documentation. Hewlett-Packard Company makes no
-- representations about the suitability of this software for any
-- purpose. It is provided "as is" without express or implied warranty.
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<Head>
<Title>LessThanComparable</Title>
</Head>
<BODY BGCOLOR="#ffffff" LINK="#0000ee" TEXT="#000000" VLINK="#551a8b"
ALINK="#ff0000">
<IMG SRC="../../c++boost.gif"
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<!--end header-->
<BR Clear>
<H1>LessThanComparable</H1>
<h3>Description</h3>
A type is LessThanComparable if it is ordered: it must
be possible to compare two objects of that type using <tt>operator&lt;</tt>, and
<tt>operator&lt;</tt> must be a strict weak ordering relation.
<h3>Refinement of</h3>
<h3>Associated types</h3>
<h3>Notation</h3>
<Table>
<TR>
<TD VAlign=top>
<tt>X</tt>
</TD>
<TD VAlign=top>
A type that is a model of LessThanComparable
</TD>
</TR>
<TR>
<TD VAlign=top>
<tt>x</tt>, <tt>y</tt>, <tt>z</tt>
</TD>
<TD VAlign=top>
Object of type <tt>X</tt>
</TD>
</tr>
</table>
<h3>Definitions</h3>
Consider the relation <tt>!(x &lt; y) &amp;&amp; !(y &lt; x)</tt>. If this relation is
transitive (that is, if <tt>!(x &lt; y) &amp;&amp; !(y &lt; x) &amp;&amp; !(y &lt; z) &amp;&amp; !(z &lt; y)</tt>
implies <tt>!(x &lt; z) &amp;&amp; !(z &lt; x)</tt>), then it satisfies the mathematical
definition of an equivalence relation. In this case, <tt>operator&lt;</tt>
is a <i>strict weak ordering</i>.
<P>
If <tt>operator&lt;</tt> is a strict weak ordering, and if each equivalence class
has only a single element, then <tt>operator&lt;</tt> is a <i>total ordering</i>.
<h3>Valid expressions</h3>
<Table border>
<TR>
<TH>
Name
</TH>
<TH>
Expression
</TH>
<TH>
Type requirements
</TH>
<TH>
Return type
</TH>
</TR>
<TR>
<TD VAlign=top>
Less
</TD>
<TD VAlign=top>
<tt>x &lt; y</tt>
</TD>
<TD VAlign=top>
&nbsp;
</TD>
<TD VAlign=top>
Convertible to <tt>bool</tt>
</TD>
</TR>
</table>
<h3>Expression semantics</h3>
<Table border>
<TR>
<TH>
Name
</TH>
<TH>
Expression
</TH>
<TH>
Precondition
</TH>
<TH>
Semantics
</TH>
<TH>
Postcondition
</TH>
</TR>
<TR>
<TD VAlign=top>
Less
</TD>
<TD VAlign=top>
<tt>x &lt; y</tt>
</TD>
<TD VAlign=top>
<tt>x</tt> and <tt>y</tt> are in the domain of <tt>&lt;</tt>
</TD>
<TD VAlign=top>
&nbsp;
</TD>
</table>
<h3>Complexity guarantees</h3>
<h3>Invariants</h3>
<Table border>
<TR>
<TD VAlign=top>
Irreflexivity
</TD>
<TD VAlign=top>
<tt>x &lt; x</tt> must be false.
</TD>
</TR>
<TR>
<TD VAlign=top>
Antisymmetry
</TD>
<TD VAlign=top>
<tt>x &lt; y</tt> implies !(y &lt; x) <A href="#2">[2]</A>
</TD>
</TR>
<TR>
<TD VAlign=top>
Transitivity
</TD>
<TD VAlign=top>
<tt>x &lt; y</tt> and <tt>y &lt; z</tt> implies <tt>x &lt; z</tt> <A href="#3">[3]</A>
</TD>
</tr>
</table>
<h3>Models</h3>
<UL>
<LI>
int
</UL>
<h3>Notes</h3>
<P><A name="1">[1]</A>
Only <tt>operator&lt;</tt> is fundamental; the other inequality operators
are essentially syntactic sugar.
<P><A name="2">[2]</A>
Antisymmetry is a theorem, not an axiom: it follows from
irreflexivity and transitivity.
<P><A name="3">[3]</A>
Because of irreflexivity and transitivity, <tt>operator&lt;</tt> always
satisfies the definition of a <i>partial ordering</i>. The definition of
a <i>strict weak ordering</i> is stricter, and the definition of a
<i>total ordering</i> is stricter still.
<h3>See also</h3>
<A href="http://www.sgi.com/tech/stl/EqualityComparable.html">EqualityComparable</A>, <A href="http://www.sgi.com/tech/stl/StrictWeakOrdering.html">StrictWeakOrdering</A>
<br>
<HR>
<TABLE>
<TR valign=top>
<TD nowrap>Copyright &copy 2000</TD><TD>
<A HREF=http://www.lsc.nd.edu/~jsiek>Jeremy Siek</A>, Univ.of Notre Dame (<A HREF="mailto:jsiek@lsc.nd.edu">jsiek@lsc.nd.edu</A>)
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<Head>
<Title>MultiPassInputIterator</Title>
<BODY BGCOLOR="#ffffff" LINK="#0000ee" TEXT="#000000" VLINK="#551a8b"
ALINK="#ff0000">
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<BR Clear>
<H2>
<A NAME="concept:MultiPassInputIterator"></A>
Multi-Pass Input Iterator
</H2>
This concept is a refinement of <a
href="http://www.sgi.com/tech/stl/InputIterator.html">Input Iterator</a>,
adding the requirements that the iterator can be used to make multiple
passes through a range, and that if <TT>it1 == it2</TT> and
<TT>it1</TT> is dereferenceable then <TT>++it1 == ++it2</TT>. The
Multi-Pass Input Iterator is very similar to the <a
href="http://www.sgi.com/tech/stl/ForwardIterator.hmtl">Forward Iterator</a>. The
only difference is that a <a
href="http://www.sgi.com/tech/stl/ForwardIterator.hmtl">Forward Iterator</a>
requires the <TT>reference</TT> type to be <TT>value_type&amp;</TT>, whereas
MultiPassInputIterator is like <a
href="http://www.sgi.com/tech/stl/InputIterator.html">Input Iterator</a>
in that the <TT>reference</TT> type merely has to be convertible to
<TT>value_type</TT>.
<h3>Design Notes</h3>
comments by Valentin Bonnard:
<p> I think that introducing Multi-Pass Input Iterator isn't the right
solution. Do you also want to define Multi-Pass Bidirectionnal Iterator
and Multi-Pass Random Access Iterator ? I don't, definitly. It only
confuses the issue. The problem lies into the existing hierarchy of
iterators, which mixes movabillity, modifiabillity and lvalue-ness,
and these are clearly independant.
<p> The terms Forward, Bidirectionnal and Random Access are about
movabillity and shouldn't be used to mean anything else. In a
completly orthogonal way, iterators can be immutable, mutable, or
neither. Lvalueness of iterators is also orthogonal with
immutabillity. With these clean concepts, your Multi-Pass Input Iterator
is just called a Forward Iterator.
<p>
Other translations are:<br>
std::Forward Iterator -> ForwardIterator & Lvalue Iterator<br>
std::Bidirectionnal Iterator -> Bidirectionnal Iterator & Lvalue Iterator<br>
std::Random Access Iterator -> Random Access Iterator & Lvalue Iterator<br>
<p>
Note that in practice the only operation not allowed on my
Forward Iterator which is allowed on std::Forward Iterator is
<tt>&*it</tt>. I think that <tt>&*</tt> is rarely needed in generic code.
<p>
reply by Jeremy Siek:
<p>
The above analysis by Valentin is right on. Of course, there is
the problem with backward compatibility. The current STL implementations
are based on the old definition of Forward Iterator. The right course
of action is to get Forward Iterator, etc. changed in the C++ standard.
Once that is done we can drop Multi-Pass Input Iterator.
<br>
<HR>
<TABLE>
<TR valign=top>
<TD nowrap>Copyright &copy 2000</TD><TD>
<a HREF="../../people/jeremy_siek.htm">Jeremy Siek</a>, Univ.of Notre Dame (<A HREF="mailto:jsiek@lsc.nd.edu">jsiek@lsc.nd.edu</A>)
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<BR Clear>
<H1>Concept: OptionalPointee</H1>
<h3>Description</h3>
A type is a model of <i>OptionalPointee</i> if it points to (or refers to) a value
that may not exist. That is, if it has a <b>pointee</b> which might be <b>valid</b>
(existent) or <b>invalid</b> (inexistent); and it is possible to test whether the
pointee is valid or not.
This model does <u>not</u> imply pointer semantics: i.e., it does not imply shallow copy nor
aliasing.
<h3>Notation</h3>
<Table>
<TR>
<TD VAlign=top> <tt>T</tt> </TD>
<TD VAlign=top> is a type that is a model of OptionalPointee</TD>
</TR>
<TR>
<TD VAlign=top> <tt>t</tt> </TD>
<TD VAlign=top> is an object of type <tt>T</tt> or possibly <tt>const T</tt></TD>
</tr>
</table>
<h3>Definitions</h3>
<h3>Valid expressions</h3>
<Table border>
<TR>
<TH> Name </TH>
<TH> Expression </TH>
<TH> Return type </TH>
<TH> Semantics </TH>
</TR>
<TR>
<TD VAlign=top>Value Access</TD>
<TD VAlign=top>&nbsp;<tt>*t</tt></TD>
<TD VAlign=top>&nbsp;<tt>T&amp;</tt></TD>
<TD VAlign=top>If the pointee is valid returns a reference to
the pointee.<br>
If the pointee is invalid the result is <i>undefined</i>.</TD>
<TD VAlign=top> </TD>
</TR>
<TR>
<TD VAlign=top>Value Access</TD>
<TD VAlign=top>&nbsp;<tt>t-><i>xyz</i></tt></TD>
<TD VAlign=top>&nbsp;<tt>T*</tt></TD>
<TD VAlign=top>If the pointee is valid returns a builtin pointer to the pointee.<br>
If the pointee is invalid the result is <i>undefined</i> (It might not even return NULL).<br>
</TD>
<TD VAlign=top> </TD>
</TR>
<TR>
<TD VAlign=top>Validity Test</TD>
<TD VAlign=top>&nbsp;<tt>t</tt><br>
&nbsp;<tt>t != 0</tt><br>
&nbsp;<tt>!!t</tt>
</TD>
<TD VAlign=top>&nbsp;bool </TD>
<TD VAlign=top>If the pointee is valid returns true.<br>
If the pointee is invalid returns false.</TD>
<TD VAlign=top></TD>
</TR>
<TR>
<TD VAlign=top>Invalidity Test</TD>
<TD VAlign=top>&nbsp;<tt>t == 0</tt><br>
&nbsp;<tt>!t</tt>
</TD>
<TD VAlign=top>&nbsp;bool </TD>
<TD VAlign=top>If the pointee is valid returns false.<br>
If the pointee is invalid returns true.</TD>
<TD VAlign=top></TD>
</TR>
</table>
<h3>Models</h3>
<UL>
<LI><tt>pointers, both builtin and smart.</tt>
<LI><tt>boost::optional&lt;&gt;</tt>
</UL>
<HR>
<h3>OptionalPointee and relational operations</h3>
<p>This concept does not define any particular semantic for relational operations, therefore,
a type which models this concept might have either shallow or deep relational semantics.<br>
For instance, pointers, which are models of OptionalPointee, have shallow relational operators:
comparisons of pointers do not involve comparisons of pointees.
This makes sense for pointers because they have shallow copy semantics.<br>
But boost::optional&lt;T&gt;, on the other hand, which is also a model of OptionalPointee, has
deep-copy and deep-relational semantics.<br>
If generic code is written for this concept, it is important not to use relational
operators directly because the semantics might be different depending on the actual type.<br>
Still, the concept itsef can be used to define <i>deep</i> relational tests that can
be used in generic code with any type which models OptionalPointee:</p>
<a name="equal"></a>
<p><u>Equivalence relation:</u></p>
<pre>template&lt;class OptionalPointee&gt;
inline
bool equal_pointees ( OptionalPointee const&amp; x, OptionalPointee const&amp; y )
{
return (!x) != (!y) ? false : ( !x ? true : (*x) == (*y) ) ;
}
template&lt;class OptionalPointee&gt;
struct equal_pointees_t : std::binary_function&lt;OptionalPointee,OptionalPointee,bool&gt;
{
bool operator() ( OptionalPointee const& x, OptionalPointee const& y ) const
{ return equal_pointees(x,y) ; }
} ;
</pre>
<p>The preceding generic function and function object have the following semantics:<br>
If both <b>x</b> and <b>y</b> have valid pointees, it compares values via <code>(*x == *y)</code>.<br>
If only one has a valid pointee, returns <code>false</code>.<br>
If both have invalid pointees, returns <code>true</code>.</p>
<a name="less"></a>
<p><u>Less-than relation:</u></p>
<pre>template&lt;class OptionalPointee&gt;
inline
bool less_pointees ( OptionalPointee const&amp; x, OptionalPointee const&amp; y )
{
return !y ? false : ( !x ? true : (*x) < (*y) ) ;
}
template&lt;class OptionalPointee&gt;
struct less_pointees_t : std::binary_function&lt;OptionalPointee,OptionalPointee,bool&gt;
{
bool operator() ( OptionalPointee const& x, OptionalPointee const& y ) const
{ return less_pointees(x,y) ; }
} ;
</pre>
<p>The preceding generic function and function object have the following semantics:<br>
If <b>y</b> has an invalid pointee, returns <code>false</code>.<br>
Else, if <b>x</b> has an invalid pointee, returns <code>true</code>.<br>
Else, ( <b>x</b> and <b>y</b> have valid pointees), compares values via <code>(*x &lt;
*y).</code></p>
<p><br>
All these functions and function
objects are is implemented in <a href="../../boost/utility/compare_pointees.hpp">compare_pointees.hpp</a></p>
<p>Notice that OptionalPointee does not imply aliasing (and optional&lt;&gt; for instance does not alias);
so direct usage of relational operators with the implied aliasing of shallow semantics
-as with pointers- should not be used with generic code written for this concept.</p>
<br>
<HR>
<TABLE>
<TR valign=top>
<TD nowrap>Copyright &copy 2003</TD><TD>
<A HREF="mailto:fernando_cacciola@hotmail.com">Fernando Cacciola</A>,
based on the original concept developed by Augustus Saunders.
</TD></TR></TABLE>
</BODY>
</HTML>

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// Copyright (C) 2002 Brad King (brad.king@kitware.com)
// Doug Gregor (gregod@cs.rpi.edu)
//
// Permission to copy, use, sell and distribute this software is granted
// provided this copyright notice appears in all copies.
// Permission to modify the code and to distribute modified code is granted
// provided this copyright notice appears in all copies, and a notice
// that the code was modified is included with the copyright notice.
//
// This software is provided "as is" without express or implied warranty,
// and with no claim as to its suitability for any purpose.
// For more information, see http://www.boost.org
#define BOOST_INCLUDE_MAIN
#include <boost/test/test_tools.hpp>
#include <boost/utility.hpp>
struct useless_type {};
class nonaddressable {
public:
void dummy(); // Silence GCC warning: all member of class are private
private:
useless_type operator&() const;
};
int test_main(int, char*[])
{
nonaddressable* px = new nonaddressable();
nonaddressable& x = *px;
BOOST_TEST(boost::addressof(x) == px);
const nonaddressable& cx = *px;
BOOST_TEST(boost::addressof(cx) == static_cast<const nonaddressable*>(px));
volatile nonaddressable& vx = *px;
BOOST_TEST(boost::addressof(vx) == static_cast<volatile nonaddressable*>(px));
const volatile nonaddressable& cvx = *px;
BOOST_TEST(boost::addressof(cvx) == static_cast<const volatile nonaddressable*>(px));
return 0;
}

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<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.0 Transitional//EN">
<html>
<head>
<title>Boost: assert.hpp documentation</title>
<meta http-equiv="Content-Type" content="text/html; charset=iso-8859-1">
</head>
<body bgcolor="white" style="MARGIN-LEFT: 5%; MARGIN-RIGHT: 5%">
<table border="0" width="100%">
<tr>
<td width="277">
<img src="../../c++boost.gif" alt="c++boost.gif (8819 bytes)" width="277" height="86">
</td>
<td align="middle">
<h1>assert.hpp</h1>
</td>
</tr>
<tr>
<td colspan="2" height="64">&nbsp;</td>
</tr>
</table>
<p>
The header <STRONG>&lt;boost/assert.hpp&gt;</STRONG> defines the macro <b>BOOST_ASSERT</b>,
which is similar to the standard <STRONG>assert</STRONG> macro defined in <STRONG>&lt;cassert&gt;</STRONG>.
The macro is intended to be used in Boost libraries.
</p>
<P>By default, <tt>BOOST_ASSERT(expr)</tt> is equivalent to <tt>assert(expr)</tt>.</P>
<P>When the macro <STRONG>BOOST_DISABLE_ASSERTS</STRONG> is defined when <STRONG>&lt;boost/assert.hpp&gt;</STRONG>
is included, <tt>BOOST_ASSERT(expr)</tt> is defined as <tt>((void)0)</tt>. This
allows users to selectively disable <STRONG>BOOST_ASSERT</STRONG> without
affecting the definition of the standard <STRONG>assert</STRONG>.</P>
<P>When the macro <STRONG>BOOST_ENABLE_ASSERT_HANDLER</STRONG> is defined when <STRONG>&lt;boost/assert.hpp&gt;</STRONG>
is included, <tt>BOOST_ASSERT(expr)</tt> evaluates <b>expr</b> and, if the
result is false, evaluates the expression</P>
<P><tt>::boost::assertion_failed(#expr, <a href="current_function.html">BOOST_CURRENT_FUNCTION</a>,
__FILE__, __LINE__)</tt></P>
<P><STRONG>assertion_failed</STRONG> is declared in <STRONG>&lt;boost/assert.hpp&gt;</STRONG>
as</P>
<pre>
namespace boost
{
void assertion_failed(char const * expr, char const * function, char const * file, long line);
}
</pre>
<p>but it is never defined. The user is expected to supply an appropriate
definition.</p>
<P>As is the case with <STRONG>&lt;cassert&gt;</STRONG>, <STRONG>&lt;boost/assert.hpp&gt;</STRONG>
can be included multiple times in a single translation unit. <STRONG>BOOST_ASSERT</STRONG>
will be redefined each time as specified above.</P>
<p><br>
<small>Copyright <20> 2002 by Peter Dimov. Permission to copy, use, modify, sell and
distribute this document is granted provided this copyright notice appears in
all copies. This document is provided "as is" without express or implied
warranty, and with no claim as to its suitability for any purpose.</small></p>
</body>
</html>

105
assert_test.cpp
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//
// assert_test.cpp - a test for boost/assert.hpp
//
// Copyright (c) 2002 Peter Dimov and Multi Media Ltd.
//
// Permission to copy, use, modify, sell and distribute this software
// is granted provided this copyright notice appears in all copies.
// This software is provided "as is" without express or implied
// warranty, and with no claim as to its suitability for any purpose.
//
#include <boost/detail/lightweight_test.hpp>
#include <boost/assert.hpp>
void test_default()
{
int x = 1;
BOOST_ASSERT(1);
BOOST_ASSERT(x);
BOOST_ASSERT(x == 1);
BOOST_ASSERT(&x);
}
#define BOOST_DISABLE_ASSERTS
#include <boost/assert.hpp>
void test_disabled()
{
int x = 1;
BOOST_ASSERT(1);
BOOST_ASSERT(x);
BOOST_ASSERT(x == 1);
BOOST_ASSERT(&x);
BOOST_ASSERT(0);
BOOST_ASSERT(!x);
BOOST_ASSERT(x == 0);
void * p = 0;
BOOST_ASSERT(p);
// supress warnings
p = &x;
p = &p;
}
#undef BOOST_DISABLE_ASSERTS
#define BOOST_ENABLE_ASSERT_HANDLER
#include <boost/assert.hpp>
#include <cstdio>
int handler_invoked = 0;
void boost::assertion_failed(char const * expr, char const * function, char const * file, long line)
{
std::printf("Expression: %s\nFunction: %s\nFile: %s\nLine: %ld\n\n", expr, function, file, line);
++handler_invoked;
}
struct X
{
static void f()
{
BOOST_ASSERT(0);
}
};
void test_handler()
{
int x = 1;
BOOST_ASSERT(1);
BOOST_ASSERT(x);
BOOST_ASSERT(x == 1);
BOOST_ASSERT(&x);
BOOST_ASSERT(0);
BOOST_ASSERT(!x);
BOOST_ASSERT(x == 0);
void * p = 0;
BOOST_ASSERT(p);
X::f();
BOOST_ASSERT(handler_invoked == 5);
BOOST_TEST(handler_invoked == 5);
}
#undef BOOST_ENABLE_ASSERT_HANDLER
int main()
{
test_default();
test_disabled();
test_handler();
return boost::report_errors();
}

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<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 3.2//EN">
<html>
<head>
<title>Boost: Base-from-Member Idiom Documentation</title>
</head>
<body bgcolor="white" link="blue" text="black" vlink="purple" alink="red">
<h1><img src="../../c++boost.gif" alt="C++ Boost" align="middle"
width="277" height="86">Base-from-Member Idiom</h1>
<p>The class template <code>boost::base_from_member</code> provides
a workaround for a class that needs to initialize a base class with a
member. The class template is in <cite><a
href="../../boost/utility/base_from_member.hpp">boost/utility/base_from_member.hpp</a></cite>
which is included in <i><a href="../../boost/utility.hpp">boost/utility.hpp</a></i>.
The class template is forward declared in <i><a href="../../boost/utility_fwd.hpp">boost/utility_fwd.hpp</a></i>.</p>
<p>There is test/example code in <cite><a
href="base_from_member_test.cpp">base_from_member_test.cpp</a></cite>.</p>
<h2><a name="contents">Contents</a></h2>
<ul>
<li><a href="#contents">Contents</a></li>
<li><a href="#rationale">Rationale</a></li>
<li><a href="#synopsis">Synopsis</a></li>
<li><a href="#usage">Usage</a></li>
<li><a href="#example">Example</a></li>
<li><a href="#credits">Credits</a>
<ul>
<li><a href="#contributors">Contributors</a></li>
</ul></li>
</ul>
<h2><a name="rationale">Rationale</a></h2>
<p>When developing a class, sometimes a base class needs to be
initialized with a member of the current class. As a na&iuml;ve
example:</p>
<blockquote><pre>
#include &lt;streambuf&gt; <i>// for std::streambuf</i>
#include &lt;ostream&gt; <i>// for std::ostream</i>
class fdoutbuf
: public std::streambuf
{
public:
explicit fdoutbuf( int fd );
//...
};
class fdostream
: public std::ostream
{
protected:
fdoutbuf buf;
public:
explicit fdostream( int fd )
: buf( fd ), std::ostream( &amp;buf )
{}
//...
};
</pre></blockquote>
<p>This is undefined because C++'s initialization order mandates that
the base class is initialized before the member it uses. <a
href="http://www.moocat.org">R. Samuel Klatchko</a> developed a way
around this by using the initialization order in his favor. Base
classes are intialized in order of declaration, so moving the desired
member to another base class, that is initialized before the desired
base class, can ensure proper initialization.</p>
<p>A custom base class can be made for this idiom:</p>
<blockquote><pre>
#include &lt;streambuf&gt; <i>// for std::streambuf</i>
#include &lt;ostream&gt; <i>// for std::ostream</i>
class fdoutbuf
: public std::streambuf
{
public:
explicit fdoutbuf( int fd );
//...
};
struct fdostream_pbase
{
fdoutbuf sbuffer;
explicit fdostream_pbase( int fd )
: sbuffer( fd )
{}
};
class fdostream
: private fdostream_pbase
, public std::ostream
{
typedef fdostream_pbase pbase_type;
typedef std::ostream base_type;
public:
explicit fdostream( int fd )
: pbase_type( fd ), base_type( &amp;sbuffer )
{}
//...
};
</pre></blockquote>
<p>Other projects can use similar custom base classes. The technique
is basic enough to make a template, with a sample template class in
this library. The main template parameter is the type of the enclosed
member. The template class has several (explicit) constructor member
templates, which implicitly type the constructor arguments and pass them
to the member. The template class uses implicit copy construction and
assignment, cancelling them if the enclosed member is non-copyable.</p>
<p>Manually coding a base class may be better if the construction
and/or copying needs are too complex for the supplied template class,
or if the compiler is not advanced enough to use it.</p>
<p>Since base classes are unnamed, a class cannot have multiple (direct)
base classes of the same type. The supplied template class has an
extra template parameter, an integer, that exists solely to provide type
differentiation. This parameter has a default value so a single use of a
particular member type does not need to concern itself with the integer.</p>
<h2><a name="synopsis">Synopsis</a></h2>
<blockquote><pre>
template &lt; typename MemberType, int UniqueID = 0 &gt;
class boost::base_from_member
{
protected:
MemberType member;
base_from_member();
template&lt; typename T1 &gt;
explicit base_from_member( T1 x1 );
template&lt; typename T1, typename T2 &gt;
base_from_member( T1 x1, T2 x2 );
//...
template&lt; typename T1, typename T2, typename T3, typename T4,
typename T5, typename T6, typename T7, typename T8, typename T9,
typename T10 &gt;
base_from_member( T1 x1, T2 x2, T3 x3, T4 x4, T5 x5, T6 x6, T7 x7,
T8 x8, T9 x9, T10 x10 );
};
</pre></blockquote>
<p>The class template has a first template parameter
<var>MemberType</var> representing the type of the based-member.
It has a last template parameter <var>UniqueID</var>, that is an
<code>int</code>, to differentiate between multiple base classes that use
the same based-member type. The last template parameter has a default
value of zero if it is omitted. The class template has a protected
data member called <var>member</var> that the derived class can use
for later base classes (or itself).</p>
<p>There is a default constructor and several constructor member
templates. These constructor templates can take as many arguments
(currently up to ten) as possible and pass them to a constructor of
the data member. Since C++ does not allow any way to explicitly state
the template parameters of a templated constructor, make sure that
the arguments are already close as possible to the actual type used in
the data member's desired constructor.</p>
<h2><a name="usage">Usage</a></h2>
<p>With the starting example, the <code>fdoutbuf</code> sub-object needs
to be encapsulated in a base class that is inheirited before
<code>std::ostream</code>.</p>
<blockquote><pre>
#include &lt;boost/utility/base_from_member.hpp&gt;
#include &lt;streambuf&gt; <i>// for std::streambuf</i>
#include &lt;ostream&gt; <i>// for std::ostream</i>
class fdoutbuf
: public std::streambuf
{
public:
explicit fdoutbuf( int fd );
//...
};
class fdostream
: private boost::base_from_member&lt;fdoutbuf&gt;
, public std::ostream
{
// Helper typedef's
typedef boost::base_from_member&lt;fdoutbuf&gt; pbase_type;
typedef std::ostream base_type;
public:
explicit fdostream( int fd )
: pbase_type( fd ), base_type( &amp;member )
{}
//...
};
</pre></blockquote>
<p>The base-from-member idiom is an implementation detail, so it
should not be visible to the clients (or any derived classes) of
<code>fdostream</code>. Due to the initialization order, the
<code>fdoutbuf</code> sub-object will get initialized before the
<code>std::ostream</code> sub-object does, making the former
sub-object safe to use in the latter sub-object's construction. Since the
<code>fdoutbuf</code> sub-object of the final type is the only sub-object
with the name &quot;member,&quot; that name can be used
unqualified within the final class.</p>
<h2><a name="example">Example</a></h2>
<p>The base-from-member class templates should commonly involve
only one base-from-member sub-object, usually for attaching a
stream-buffer to an I/O stream. The next example demonstrates how
to use multiple base-from-member sub-objects and the resulting
qualification issues.</p>
<blockquote><pre>
#include &lt;boost/utility/base_from_member.hpp&gt;
#include &lt;cstddef&gt; <i>// for NULL</i>
struct an_int
{
int y;
an_int( float yf );
};
class switcher
{
public:
switcher();
switcher( double, int * );
//...
};
class flow_regulator
{
public:
flow_regulator( switcher &amp;, switcher &amp; );
//...
};
template &lt; unsigned Size &gt;
class fan
{
public:
explicit fan( switcher );
//...
};
class system
: private boost::base_from_member&lt;an_int&gt;
, private boost::base_from_member&lt;switcher&gt;
, private boost::base_from_member&lt;switcher, 1&gt;
, private boost::base_from_member&lt;switcher, 2&gt;
, protected flow_regulator
, public fan&lt;6&gt;
{
// Helper typedef's
typedef boost::base_from_member&lt;an_int&gt; pbase0_type;
typedef boost::base_from_member&lt;switcher&gt; pbase1_type;
typedef boost::base_from_member&lt;switcher, 1&gt; pbase2_type;
typedef boost::base_from_member&lt;switcher, 2&gt; pbase3_type;
typedef flow_regulator base1_type;
typedef fan&lt;6&gt; base2_type;
public:
system( double x );
//...
};
system::system( double x )
: pbase0_type( 0.2 )
, pbase1_type()
, pbase2_type( -16, &amp;this-&gt;pbase0_type::member )
, pbase3_type( x, static_cast&lt;int *&gt;(NULL) )
, base1_type( pbase3_type::member, pbase1_type::member )
, base2_type( pbase2_type::member )
{
//...
}
</pre></blockquote>
<p>The final class has multiple sub-objects with the name
&quot;member,&quot; so any use of that name needs qualification by
a name of the appropriate base type. (Using <code>typedef</code>s
ease mentioning the base types.) However, the fix introduces a new
problem when a pointer is needed. Using the address operator with
a sub-object qualified with its class's name results in a pointer-to-member
(here, having a type of <code>an_int boost::base_from_member&lt;an_int,
0&gt; :: *</code>) instead of a pointer to the member (having a type of
<code>an_int *</code>). The new problem is fixed by qualifying the
sub-object with &quot;<code>this-&gt;</code>,&quot; and is needed just
for pointers, and not for references or values.</p>
<p>There are some argument conversions in the initialization. The
constructor argument for <code>pbase0_type</code> is converted from
<code>double</code> to <code>float</code>. The first constructor
argument for <code>pbase2_type</code> is converted from <code>int</code>
to <code>double</code>. The second constructor argument for
<code>pbase3_type</code> is a special case of necessary conversion; all
forms of the null-pointer literal in C++ also look like compile-time
integral expressions, so C++ always interprets such code as an integer
when it has overloads that can take either an integer or a pointer. The
last conversion is necessary for the compiler to call a constructor form
with the exact pointer type used in <code>switcher</code>'s constructor.</p>
<h2><a name="credits">Credits</a></h2>
<h3><a name="contributors">Contributors</a></h3>
<dl>
<dt><a href="../../people/ed_brey.htm">Ed Brey</a>
<dd>Suggested some interface changes.
<dt><a href="http://www.moocat.org">R. Samuel Klatchko</a> (<a
href="mailto:rsk@moocat.org">rsk@moocat.org</a>, <a
href="mailto:rsk@brightmail.com">rsk@brightmail.com</a>)
<dd>Invented the idiom of how to use a class member for initializing
a base class.
<dt><a href="../../people/dietmar_kuehl.htm">Dietmar Kuehl</a>
<dd>Popularized the base-from-member idiom in his
<a href="http://www.informatik.uni-konstanz.de/~kuehl/c++/iostream/">IOStream
example classes</a>.
<dt><a href="../../people/daryle_walker.html">Daryle Walker</a>
<dd>Started the library. Contributed the test file <cite><a
href="base_from_member_test.cpp">base_from_member_test.cpp</a></cite>.
</dl>
<hr>
<p>Revised: 14 June 2003</p>
<p>Copyright 2001, 2003 Daryle Walker. Use, modification, and distribution
are subject to the Boost Software License, Version 1.0. (See accompanying
file <a href="../../LICENSE_1_0.txt">LICENSE_1_0.txt</a> or a copy at &lt;<a
href="http://www.boost.org/LICENSE_1_0.txt">http://www.boost.org/LICENSE_1_0.txt</a>&gt;.)</p>
</body>
</html>

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// Boost test program for base-from-member class templates -----------------//
// Copyright 2001, 2003 Daryle Walker. Use, modification, and distribution are
// subject to the Boost Software License, Version 1.0. (See accompanying file
// LICENSE_1_0.txt or a copy at <http://www.boost.org/LICENSE_1_0.txt>.)
// See <http://www.boost.org/libs/utility/> for the library's home page.
// Revision History
// 14 Jun 2003 Adjusted code for Boost.Test changes (Daryle Walker)
// 29 Aug 2001 Initial Version (Daryle Walker)
#include <boost/test/minimal.hpp> // for BOOST_CHECK, main
#include <boost/config.hpp> // for BOOST_NO_MEMBER_TEMPLATES
#include <boost/cstdlib.hpp> // for boost::exit_success
#include <boost/noncopyable.hpp> // for boost::noncopyable
#include <boost/utility/base_from_member.hpp> // for boost::base_from_member
#include <functional> // for std::binary_function, std::less
#include <iostream> // for std::cout (std::ostream, std::endl indirectly)
#include <set> // for std::set
#include <typeinfo> // for std::type_info
#include <utility> // for std::pair, std::make_pair
#include <vector> // for std::vector
// Control if extra information is printed
#ifndef CONTROL_EXTRA_PRINTING
#define CONTROL_EXTRA_PRINTING 1
#endif
// A (sub)object can be identified by its memory location and its type.
// Both are needed since an object can start at the same place as its
// first base class subobject and/or contained subobject.
typedef std::pair< void *, std::type_info const * > object_id;
// Object IDs need to be printed
std::ostream & operator <<( std::ostream &os, object_id const &oi );
// A way to generate an object ID
template < typename T >
object_id identify( T &obj );
// A custom comparison type is needed
struct object_id_compare
: std::binary_function<object_id, object_id, bool>
{
bool operator ()( object_id const &a, object_id const &b ) const;
}; // object_id_compare
// A singleton of this type coordinates the acknowledgements
// of objects being created and used.
class object_registrar
: private boost::noncopyable
{
public:
#ifndef BOOST_NO_MEMBER_TEMPLATES
template < typename T >
void register_object( T &obj )
{ this->register_object_imp( identify(obj) ); }
template < typename T, typename U >
void register_use( T &owner, U &owned )
{ this->register_use_imp( identify(owner), identify(owned) ); }
template < typename T, typename U >
void unregister_use( T &owner, U &owned )
{ this->unregister_use_imp( identify(owner), identify(owned) ); }
template < typename T >
void unregister_object( T &obj )
{ this->unregister_object_imp( identify(obj) ); }
#endif
void register_object_imp( object_id obj );
void register_use_imp( object_id owner, object_id owned );
void unregister_use_imp( object_id owner, object_id owned );
void unregister_object_imp( object_id obj );
typedef std::set<object_id, object_id_compare> set_type;
typedef std::vector<object_id> error_record_type;
typedef std::vector< std::pair<object_id, object_id> > error_pair_type;
set_type db_;
error_pair_type defrauders_in_, defrauders_out_;
error_record_type overeager_, overkilled_;
}; // object_registrar
// A sample type to be used by containing types
class base_or_member
{
public:
explicit base_or_member( int x = 1, double y = -0.25 );
~base_or_member();
}; // base_or_member
// A sample type that uses base_or_member, used
// as a base for the main demonstration classes
class base_class
{
public:
explicit base_class( base_or_member &x, base_or_member *y = 0,
base_or_member *z = 0 );
~base_class();
private:
base_or_member *x_, *y_, *z_;
}; // base_class
// This bad class demonstrates the direct method of a base class needing
// to be initialized by a member. This is improper since the member
// isn't initialized until after the base class.
class bad_class
: public base_class
{
public:
bad_class();
~bad_class();
private:
base_or_member x_;
}; // bad_class
// The first good class demonstrates the correct way to initialize a
// base class with a member. The member is changed to another base
// class, one that is initialized before the base that needs it.
class good_class_1
: private boost::base_from_member<base_or_member>
, public base_class
{
typedef boost::base_from_member<base_or_member> pbase_type;
typedef base_class base_type;
public:
good_class_1();
~good_class_1();
}; // good_class_1
// The second good class also demonstrates the correct way to initialize
// base classes with other subobjects. This class uses the other helpers
// in the library, and shows the technique of using two base subobjects
// of the "same" type.
class good_class_2
: private boost::base_from_member<base_or_member, 0>
, private boost::base_from_member<base_or_member, 1>
, private boost::base_from_member<base_or_member, 2>
, public base_class
{
typedef boost::base_from_member<base_or_member, 0> pbase_type0;
typedef boost::base_from_member<base_or_member, 1> pbase_type1;
typedef boost::base_from_member<base_or_member, 2> pbase_type2;
typedef base_class base_type;
public:
good_class_2();
~good_class_2();
}; // good_class_2
// Declare/define the single object registrar
object_registrar obj_reg;
// Main functionality
int
test_main( int , char * [] )
{
BOOST_CHECK( obj_reg.db_.empty() );
BOOST_CHECK( obj_reg.defrauders_in_.empty() );
BOOST_CHECK( obj_reg.defrauders_out_.empty() );
BOOST_CHECK( obj_reg.overeager_.empty() );
BOOST_CHECK( obj_reg.overkilled_.empty() );
// Make a separate block to examine pre- and post-effects
{
using std::cout;
using std::endl;
bad_class bc;
BOOST_CHECK( obj_reg.db_.size() == 3 );
BOOST_CHECK( obj_reg.defrauders_in_.size() == 1 );
good_class_1 gc1;
BOOST_CHECK( obj_reg.db_.size() == 6 );
BOOST_CHECK( obj_reg.defrauders_in_.size() == 1 );
good_class_2 gc2;
BOOST_CHECK( obj_reg.db_.size() == 11 );
BOOST_CHECK( obj_reg.defrauders_in_.size() == 1 );
BOOST_CHECK( obj_reg.defrauders_out_.empty() );
BOOST_CHECK( obj_reg.overeager_.empty() );
BOOST_CHECK( obj_reg.overkilled_.empty() );
// Getting the addresses of the objects ensure
// that they're used, and not optimized away.
cout << "Object 'bc' is at " << &bc << '.' << endl;
cout << "Object 'gc1' is at " << &gc1 << '.' << endl;
cout << "Object 'gc2' is at " << &gc2 << '.' << endl;
}
BOOST_CHECK( obj_reg.db_.empty() );
BOOST_CHECK( obj_reg.defrauders_in_.size() == 1 );
BOOST_CHECK( obj_reg.defrauders_out_.size() == 1 );
BOOST_CHECK( obj_reg.overeager_.empty() );
BOOST_CHECK( obj_reg.overkilled_.empty() );
return boost::exit_success;
}
// Print an object's ID
std::ostream &
operator <<
(
std::ostream & os,
object_id const & oi
)
{
// I had an std::ostringstream to help, but I did not need it since
// the program never screws around with formatting. Worse, using
// std::ostringstream is an issue with some compilers.
return os << '[' << ( oi.second ? oi.second->name() : "NOTHING" )
<< " at " << oi.first << ']';
}
// Get an object ID given an object
template < typename T >
inline
object_id
identify
(
T & obj
)
{
return std::make_pair( static_cast<void *>(&obj), &(typeid( obj )) );
}
// Compare two object IDs
bool
object_id_compare::operator ()
(
object_id const & a,
object_id const & b
) const
{
std::less<void *> vp_cmp;
if ( vp_cmp(a.first, b.first) )
{
return true;
}
else if ( vp_cmp(b.first, a.first) )
{
return false;
}
else
{
// object pointers are equal, compare the types
if ( a.second == b.second )
{
return false;
}
else if ( !a.second )
{
return true; // NULL preceeds anything else
}
else if ( !b.second )
{
return false; // NULL preceeds anything else
}
else
{
return a.second->before( *b.second );
}
}
}
// Let an object register its existence
void
object_registrar::register_object_imp
(
object_id obj
)
{
if ( db_.count(obj) <= 0 )
{
db_.insert( obj );
#if CONTROL_EXTRA_PRINTING
std::cout << "Registered " << obj << '.' << std::endl;
#endif
}
else
{
overeager_.push_back( obj );
#if CONTROL_EXTRA_PRINTING
std::cout << "Attempted to register a non-existant " << obj
<< '.' << std::endl;
#endif
}
}
// Let an object register its use of another object
void
object_registrar::register_use_imp
(
object_id owner,
object_id owned
)
{
if ( db_.count(owned) > 0 )
{
// We don't care to record usage registrations
}
else
{
defrauders_in_.push_back( std::make_pair(owner, owned) );
#if CONTROL_EXTRA_PRINTING
std::cout << "Attempted to own a non-existant " << owned
<< " by " << owner << '.' << std::endl;
#endif
}
}
// Let an object un-register its use of another object
void
object_registrar::unregister_use_imp
(
object_id owner,
object_id owned
)
{
if ( db_.count(owned) > 0 )
{
// We don't care to record usage un-registrations
}
else
{
defrauders_out_.push_back( std::make_pair(owner, owned) );
#if CONTROL_EXTRA_PRINTING
std::cout << "Attempted to disown a non-existant " << owned
<< " by " << owner << '.' << std::endl;
#endif
}
}
// Let an object un-register its existence
void
object_registrar::unregister_object_imp
(
object_id obj
)
{
set_type::iterator const i = db_.find( obj );
if ( i != db_.end() )
{
db_.erase( i );
#if CONTROL_EXTRA_PRINTING
std::cout << "Unregistered " << obj << '.' << std::endl;
#endif
}
else
{
overkilled_.push_back( obj );
#if CONTROL_EXTRA_PRINTING
std::cout << "Attempted to unregister a non-existant " << obj
<< '.' << std::endl;
#endif
}
}
// Macros to abstract the registration of objects
#ifndef BOOST_NO_MEMBER_TEMPLATES
#define PRIVATE_REGISTER_BIRTH(o) obj_reg.register_object( (o) )
#define PRIVATE_REGISTER_DEATH(o) obj_reg.unregister_object( (o) )
#define PRIVATE_REGISTER_USE(o, w) obj_reg.register_use( (o), (w) )
#define PRIVATE_UNREGISTER_USE(o, w) obj_reg.unregister_use( (o), (w) )
#else
#define PRIVATE_REGISTER_BIRTH(o) obj_reg.register_object_imp( \
identify((o)) )
#define PRIVATE_REGISTER_DEATH(o) obj_reg.unregister_object_imp( \
identify((o)) )
#define PRIVATE_REGISTER_USE(o, w) obj_reg.register_use_imp( identify((o)), \
identify((w)) )
#define PRIVATE_UNREGISTER_USE(o, w) obj_reg.unregister_use_imp( \
identify((o)), identify((w)) )
#endif
// Create a base_or_member, with arguments to simulate member initializations
base_or_member::base_or_member
(
int x, // = 1
double y // = -0.25
)
{
PRIVATE_REGISTER_BIRTH( *this );
#if CONTROL_EXTRA_PRINTING
std::cout << "\tMy x-factor is " << x << " and my y-factor is " << y
<< '.' << std::endl;
#endif
}
// Destroy a base_or_member
inline
base_or_member::~base_or_member
(
)
{
PRIVATE_REGISTER_DEATH( *this );
}
// Create a base_class, registering any objects used
base_class::base_class
(
base_or_member & x,
base_or_member * y, // = 0
base_or_member * z // = 0
)
: x_( &x ), y_( y ), z_( z )
{
PRIVATE_REGISTER_BIRTH( *this );
#if CONTROL_EXTRA_PRINTING
std::cout << "\tMy x-factor is " << x_;
#endif
PRIVATE_REGISTER_USE( *this, *x_ );
if ( y_ )
{
#if CONTROL_EXTRA_PRINTING
std::cout << ", my y-factor is " << y_;
#endif
PRIVATE_REGISTER_USE( *this, *y_ );
}
if ( z_ )
{
#if CONTROL_EXTRA_PRINTING
std::cout << ", my z-factor is " << z_;
#endif
PRIVATE_REGISTER_USE( *this, *z_ );
}
#if CONTROL_EXTRA_PRINTING
std::cout << '.' << std::endl;
#endif
}
// Destroy a base_class, unregistering the objects it uses
base_class::~base_class
(
)
{
PRIVATE_REGISTER_DEATH( *this );
#if CONTROL_EXTRA_PRINTING
std::cout << "\tMy x-factor was " << x_;
#endif
PRIVATE_UNREGISTER_USE( *this, *x_ );
if ( y_ )
{
#if CONTROL_EXTRA_PRINTING
std::cout << ", my y-factor was " << y_;
#endif
PRIVATE_UNREGISTER_USE( *this, *y_ );
}
if ( z_ )
{
#if CONTROL_EXTRA_PRINTING
std::cout << ", my z-factor was " << z_;
#endif
PRIVATE_UNREGISTER_USE( *this, *z_ );
}
#if CONTROL_EXTRA_PRINTING
std::cout << '.' << std::endl;
#endif
}
// Create a bad_class, noting the improper construction order
bad_class::bad_class
(
)
: x_( -7, 16.75 ), base_class( x_ ) // this order doesn't matter
{
PRIVATE_REGISTER_BIRTH( *this );
#if CONTROL_EXTRA_PRINTING
std::cout << "\tMy factor is at " << &x_
<< " and my base is at " << static_cast<base_class *>(this) << '.'
<< std::endl;
#endif
}
// Destroy a bad_class, noting the improper destruction order
bad_class::~bad_class
(
)
{
PRIVATE_REGISTER_DEATH( *this );
#if CONTROL_EXTRA_PRINTING
std::cout << "\tMy factor was at " << &x_
<< " and my base was at " << static_cast<base_class *>(this)
<< '.' << std::endl;
#endif
}
// Create a good_class_1, noting the proper construction order
good_class_1::good_class_1
(
)
: pbase_type( 8 ), base_type( member )
{
PRIVATE_REGISTER_BIRTH( *this );
#if CONTROL_EXTRA_PRINTING
std::cout << "\tMy factor is at " << &member
<< " and my base is at " << static_cast<base_class *>(this) << '.'
<< std::endl;
#endif
}
// Destroy a good_class_1, noting the proper destruction order
good_class_1::~good_class_1
(
)
{
PRIVATE_REGISTER_DEATH( *this );
#if CONTROL_EXTRA_PRINTING
std::cout << "\tMy factor was at " << &member
<< " and my base was at " << static_cast<base_class *>(this)
<< '.' << std::endl;
#endif
}
// Create a good_class_2, noting the proper construction order
good_class_2::good_class_2
(
)
: pbase_type0(), pbase_type1(-16, 0.125), pbase_type2(2, -3)
, base_type( pbase_type1::member, &this->pbase_type0::member,
&this->pbase_type2::member )
{
PRIVATE_REGISTER_BIRTH( *this );
#if CONTROL_EXTRA_PRINTING
std::cout << "\tMy factors are at " << &this->pbase_type0::member
<< ", " << &this->pbase_type1::member << ", "
<< &this->pbase_type2::member << ", and my base is at "
<< static_cast<base_class *>(this) << '.' << std::endl;
#endif
}
// Destroy a good_class_2, noting the proper destruction order
good_class_2::~good_class_2
(
)
{
PRIVATE_REGISTER_DEATH( *this );
#if CONTROL_EXTRA_PRINTING
std::cout << "\tMy factors were at " << &this->pbase_type0::member
<< ", " << &this->pbase_type1::member << ", "
<< &this->pbase_type2::member << ", and my base was at "
<< static_cast<base_class *>(this) << '.' << std::endl;
#endif
}

258
binary_search_test.cpp
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// (C) Copyright David Abrahams 2000. Permission to copy, use, modify,
// sell and distribute this software is granted provided this
// copyright notice appears in all copies. This software is provided
// "as is" without express or implied warranty, and with no claim as
// to its suitability for any purpose.
#include <vector>
#include <string>
#include <memory>
#include <climits>
#include <iostream>
#include <cassert>
#include <stdlib.h> // for rand(). Would use cstdlib but VC6.4 doesn't put it in std::
#include <list>
#include <algorithm>
#include <boost/detail/binary_search.hpp>
#include <boost/detail/workaround.hpp>
#if defined(__SGI_STL_PORT) ? defined(__SGI_STL_OWN_IOSTREAMS) : (!defined(__GNUC__) || __GNUC__ > 2)
# define USE_SSTREAM
#endif
#ifdef USE_SSTREAM
# include <sstream>
#else
# include <strstream>
#endif
namespace {
// In order to get ADL to find the comparison operators defined below, they have
struct mystring : std::string
{
typedef std::string base;
mystring(std::string const& x)
: base(x) {}
};
typedef std::vector<mystring> string_vector;
const std::size_t sequence_length = 1000;
unsigned random_number()
{
return static_cast<unsigned>(::rand()) % sequence_length;
}
# ifndef USE_SSTREAM
class unfreezer {
public:
unfreezer(std::ostrstream& s) : m_stream(s) {}
~unfreezer() { m_stream.freeze(false); }
private:
std::ostrstream& m_stream;
};
# endif
template <class T>
void push_back_random_number_string(T& seq)
{
unsigned value = random_number();
# if defined(__SGI_STL_PORT) ? defined(__SGI_STL_OWN_IOSTREAMS) : (!defined(__GNUC__) || __GNUC__ > 2)
std::ostringstream s;
s << value;
seq.push_back(s.str());
# else
std::ostrstream s;
auto unfreezer unfreeze(s);
s << value << char(0);
seq.push_back(std::string(s.str()));
# endif
}
inline unsigned to_int(unsigned x) { return x; }
inline unsigned to_int(const std::string& x) { return atoi(x.c_str()); }
struct cmp
{
template <class A1, class A2>
inline bool operator()(const A1& a1, const A2& a2) const
{
return to_int(a1) < to_int(a2);
}
};
inline bool operator<(const mystring& x, const unsigned y)
{
return to_int(x) < y;
}
inline bool operator<(const unsigned y, const mystring& x)
{
return y < to_int(x);
}
template <class T>
void sort_by_value(T& x);
template <class T>
void sort_by_value_(T& v, long)
{
std::sort(v.begin(), v.end(), cmp());
}
template <class T>
void random_sorted_sequence(T& seq)
{
seq.clear();
for (std::size_t i = 0; i < sequence_length; ++i)
{
push_back_random_number_string(seq);
}
sort_by_value(seq);
}
template <class T, class A>
void sort_by_value_(std::list<T,A>& l, int)
{
# if BOOST_WORKAROUND(BOOST_DINKUMWARE_STDLIB, == 1) && !defined(__SGI_STL_PORT)
// VC6's standard lib doesn't have a template member function for list::sort()
std::vector<T> seq;
seq.reserve(sequence_length);
std::copy(l.begin(), l.end(), std::back_inserter(seq));
sort_by_value(seq);
std::copy(seq.begin(), seq.end(), l.begin());
# else
l.sort(cmp());
# endif
}
template <class T>
void sort_by_value(T& x)
{
(sort_by_value_)(x, 1);
}
// A way to select the comparisons with/without a Compare parameter for testing.
template <class Compare> struct searches
{
template <class Iterator, class Key>
static Iterator lower_bound(Iterator start, Iterator finish, Key key, Compare cmp)
{ return boost::detail::lower_bound(start, finish, key, cmp); }
template <class Iterator, class Key>
static Iterator upper_bound(Iterator start, Iterator finish, Key key, Compare cmp)
{ return boost::detail::upper_bound(start, finish, key, cmp); }
template <class Iterator, class Key>
static std::pair<Iterator, Iterator> equal_range(Iterator start, Iterator finish, Key key, Compare cmp)
{ return boost::detail::equal_range(start, finish, key, cmp); }
template <class Iterator, class Key>
static bool binary_search(Iterator start, Iterator finish, Key key, Compare cmp)
{ return boost::detail::binary_search(start, finish, key, cmp); }
};
struct no_compare {};
template <> struct searches<no_compare>
{
template <class Iterator, class Key>
static Iterator lower_bound(Iterator start, Iterator finish, Key key, no_compare)
{ return boost::detail::lower_bound(start, finish, key); }
template <class Iterator, class Key>
static Iterator upper_bound(Iterator start, Iterator finish, Key key, no_compare)
{ return boost::detail::upper_bound(start, finish, key); }
template <class Iterator, class Key>
static std::pair<Iterator, Iterator> equal_range(Iterator start, Iterator finish, Key key, no_compare)
{ return boost::detail::equal_range(start, finish, key); }
template <class Iterator, class Key>
static bool binary_search(Iterator start, Iterator finish, Key key, no_compare)
{ return boost::detail::binary_search(start, finish, key); }
};
template <class Sequence, class Compare>
void test_loop(Sequence& x, Compare cmp, unsigned long test_count)
{
typedef typename Sequence::const_iterator const_iterator;
for (unsigned long i = 0; i < test_count; ++i)
{
random_sorted_sequence(x);
const const_iterator start = x.begin();
const const_iterator finish = x.end();
unsigned key = random_number();
const const_iterator l = searches<Compare>::lower_bound(start, finish, key, cmp);
const const_iterator u = searches<Compare>::upper_bound(start, finish, key, cmp);
bool found_l = false;
bool found_u = false;
std::size_t index = 0;
std::size_t count = 0;
unsigned last_value = 0;
for (const_iterator p = start; p != finish; ++p)
{
if (p == l)
found_l = true;
if (p == u)
{
assert(found_l);
found_u = true;
}
unsigned value = to_int(*p);
assert(value >= last_value);
last_value = value;
if (!found_l)
{
++index;
assert(to_int(*p) < key);
}
else if (!found_u)
{
++count;
assert(to_int(*p) == key);
}
else
assert(to_int(*p) > key);
}
assert(found_l || l == finish);
assert(found_u || u == finish);
std::pair<const_iterator, const_iterator>
range = searches<Compare>::equal_range(start, finish, key, cmp);
assert(range.first == l);
assert(range.second == u);
bool found = searches<Compare>::binary_search(start, finish, key, cmp);
assert(found == (u != l));
std::cout << "found " << count << " copies of " << key << " at index " << index << "\n";
}
}
}
int main()
{
string_vector x;
std::cout << "=== testing random-access iterators with <: ===\n";
test_loop(x, no_compare(), 25);
std::cout << "=== testing random-access iterators with compare: ===\n";
test_loop(x, cmp(), 25);
std::list<mystring> y;
std::cout << "=== testing bidirectional iterators with <: ===\n";
test_loop(y, no_compare(), 25);
std::cout << "=== testing bidirectional iterators with compare: ===\n";
test_loop(y, cmp(), 25);
std::cerr << "******TEST PASSED******\n";
return 0;
}

764
call_traits.htm
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@ -1,764 +0,0 @@
<html>
<head>
<meta http-equiv="Content-Type"
content="text/html; charset=iso-8859-1">
<meta name="Template"
content="C:\PROGRAM FILES\MICROSOFT OFFICE\OFFICE\html.dot">
<meta name="GENERATOR" content="Microsoft FrontPage Express 2.0">
<title>Call Traits</title>
</head>
<body bgcolor="#FFFFFF" text="#000000" link="#0000FF"
vlink="#800080">
<h1><img src="../../c++boost.gif" width="276" height="86">Header
&lt;<a href="../../boost/detail/call_traits.hpp">boost/call_traits.hpp</a>&gt;</h1>
<p>All of the contents of &lt;boost/call_traits.hpp&gt; are
defined inside namespace boost.</p>
<p>The template class call_traits&lt;T&gt; encapsulates the
&quot;best&quot; method to pass a parameter of some type T to or
from a function, and consists of a collection of typedefs defined
as in the table below. The purpose of call_traits is to ensure
that problems like &quot;<a href="#refs">references to references</a>&quot;
never occur, and that parameters are passed in the most efficient
manner possible (see <a href="#examples">examples</a>). In each
case if your existing practice is to use the type defined on the
left, then replace it with the call_traits defined type on the
right. </p>
<p>Note that for compilers that do not support either partial
specialization or member templates, no benefit will occur from
using call_traits: the call_traits defined types will always be
the same as the existing practice in this case. In addition if
only member templates and not partial template specialisation is
support by the compiler (for example Visual C++ 6) then
call_traits can not be used with array types (although it can be
used to solve the reference to reference problem).</p>
<table border="0" cellpadding="7" cellspacing="1" width="797">
<tr>
<td valign="top" width="17%" bgcolor="#008080"><p
align="center">Existing practice</p>
</td>
<td valign="top" width="35%" bgcolor="#008080"><p
align="center">call_traits equivalent</p>
</td>
<td valign="top" width="32%" bgcolor="#008080"><p
align="center">Description</p>
</td>
<td valign="top" width="16%" bgcolor="#008080"><p
align="center">Notes</p>
</td>
</tr>
<tr>
<td valign="top" width="17%"><p align="center">T<br>
(return by value)</p>
</td>
<td valign="top" width="35%"><p align="center"><code>call_traits&lt;T&gt;::value_type</code></p>
</td>
<td valign="top" width="32%">Defines a type that
represents the &quot;value&quot; of type T. Use this for
functions that return by value, or possibly for stored
values of type T.</td>
<td valign="top" width="16%"><p align="center">2</p>
</td>
</tr>
<tr>
<td valign="top" width="17%"><p align="center">T&amp;<br>
(return value)</p>
</td>
<td valign="top" width="35%"><p align="center"><code>call_traits&lt;T&gt;::reference</code></p>
</td>
<td valign="top" width="32%">Defines a type that
represents a reference to type T. Use for functions that
would normally return a T&amp;.</td>
<td valign="top" width="16%"><p align="center">1</p>
</td>
</tr>
<tr>
<td valign="top" width="17%"><p align="center">const
T&amp;<br>
(return value)</p>
</td>
<td valign="top" width="35%"><p align="center"><code>call_traits&lt;T&gt;::const_reference</code></p>
</td>
<td valign="top" width="32%">Defines a type that
represents a constant reference to type T. Use for
functions that would normally return a const T&amp;.</td>
<td valign="top" width="16%"><p align="center">1</p>
</td>
</tr>
<tr>
<td valign="top" width="17%"><p align="center">const
T&amp;<br>
(function parameter)</p>
</td>
<td valign="top" width="35%"><p align="center"><code>call_traits&lt;T&gt;::param_type</code></p>
</td>
<td valign="top" width="32%">Defines a type that
represents the &quot;best&quot; way to pass a parameter
of type T to a function.</td>
<td valign="top" width="16%"><p align="center">1,3</p>
</td>
</tr>
</table>
<p>Notes:</p>
<ol>
<li>If T is already reference type, then call_traits is
defined such that <a href="#refs">references to
references</a> do not occur (requires partial
specialization).</li>
<li>If T is an array type, then call_traits defines <code>value_type</code>
as a &quot;constant pointer to type&quot; rather than an
&quot;array of type&quot; (requires partial
specialization). Note that if you are using value_type as
a stored value then this will result in storing a &quot;constant
pointer to an array&quot; rather than the array itself.
This may or may not be a good thing depending upon what
you actually need (in other words take care!).</li>
<li>If T is a small built in type or a pointer, then <code>param_type</code>
is defined as <code>T const</code>, instead of <code>T
const&amp;</code>. This can improve the ability of the
compiler to optimize loops in the body of the function if
they depend upon the passed parameter, the semantics of
the passed parameter is otherwise unchanged (requires
partial specialization).</li>
</ol>
<p>&nbsp;</p>
<h3>Copy constructibility</h3>
<p>The following table defines which call_traits types can always
be copy-constructed from which other types, those entries marked
with a '?' are true only if and only if T is copy constructible:</p>
<table border="0" cellpadding="7" cellspacing="1" width="766">
<tr>
<td valign="top" width="17%">&nbsp;</td>
<td valign="top" colspan="5" width="85%"
bgcolor="#008080"><p align="center">To:</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#008080">From:</td>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">T</p>
</td>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">value_type</p>
</td>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">reference</p>
</td>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">const_reference</p>
</td>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">param_type</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0">T</td>
<td valign="top" width="17%"><p align="center">?</p>
</td>
<td valign="top" width="17%"><p align="center">?</p>
</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0">value_type</td>
<td valign="top" width="17%"><p align="center">?</p>
</td>
<td valign="top" width="17%"><p align="center">?</p>
</td>
<td valign="top" width="17%"><p align="center">N</p>
</td>
<td valign="top" width="17%"><p align="center">N</p>
</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0">reference</td>
<td valign="top" width="17%"><p align="center">?</p>
</td>
<td valign="top" width="17%"><p align="center">?</p>
</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0">const_reference</td>
<td valign="top" width="17%"><p align="center">?</p>
</td>
<td valign="top" width="17%"><p align="center">N</p>
</td>
<td valign="top" width="17%"><p align="center">N</p>
</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0">param_type</td>
<td valign="top" width="17%"><p align="center">?</p>
</td>
<td valign="top" width="17%"><p align="center">?</p>
</td>
<td valign="top" width="17%"><p align="center">N</p>
</td>
<td valign="top" width="17%"><p align="center">N</p>
</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
</tr>
</table>
<p>&nbsp;</p>
<p>If T is an assignable type the following assignments are
possible:</p>
<table border="0" cellpadding="7" cellspacing="1" width="766">
<tr>
<td valign="top" width="17%">&nbsp;</td>
<td valign="top" colspan="5" width="85%"
bgcolor="#008080"><p align="center">To:</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#008080">From:</td>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">T</p>
</td>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">value_type</p>
</td>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">reference</p>
</td>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">const_reference</p>
</td>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">param_type</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0">T</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
<td valign="top" width="17%"><p align="center">-</p>
</td>
<td valign="top" width="17%"><p align="center">-</p>
</td>
<td valign="top" width="17%"><p align="center">-</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0">value_type</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
<td valign="top" width="17%"><p align="center">-</p>
</td>
<td valign="top" width="17%"><p align="center">-</p>
</td>
<td valign="top" width="17%"><p align="center">-</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0">reference</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
<td valign="top" width="17%"><p align="center">-</p>
</td>
<td valign="top" width="17%"><p align="center">-</p>
</td>
<td valign="top" width="17%"><p align="center">-</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0">const_reference</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
<td valign="top" width="17%"><p align="center">-</p>
</td>
<td valign="top" width="17%"><p align="center">-</p>
</td>
<td valign="top" width="17%"><p align="center">-</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0">param_type</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
<td valign="top" width="17%"><p align="center">Y</p>
</td>
<td valign="top" width="17%"><p align="center">-</p>
</td>
<td valign="top" width="17%"><p align="center">-</p>
</td>
<td valign="top" width="17%"><p align="center">-</p>
</td>
</tr>
</table>
<p>&nbsp;</p>
<h3><a name="examples"></a>Examples</h3>
<p>The following table shows the effect that call_traits has on
various types, the table assumes that the compiler supports
partial specialization: if it doesn't then all types behave in
the same way as the entry for &quot;myclass&quot;, and
call_traits can not be used with reference or array types.</p>
<table border="0" cellpadding="7" cellspacing="1" width="766">
<tr>
<td valign="top" width="17%">&nbsp;</td>
<td valign="top" colspan="5" width="85%"
bgcolor="#008080"><p align="center">Call_traits type:</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#008080"><p
align="center">Original type T</p>
</td>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">value_type</p>
</td>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">reference</p>
</td>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">const_reference</p>
</td>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">param_type</p>
</td>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">Applies to:</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">myclass</p>
</td>
<td valign="top" width="17%"><p align="center">myclass</p>
</td>
<td valign="top" width="17%"><p align="center">myclass&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">const
myclass&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">myclass
const&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">All user
defined types.</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">int</p>
</td>
<td valign="top" width="17%"><p align="center">int</p>
</td>
<td valign="top" width="17%"><p align="center">int&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">const
int&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">int const</p>
</td>
<td valign="top" width="17%"><p align="center">All small
built-in types.</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">int*</p>
</td>
<td valign="top" width="17%"><p align="center">int*</p>
</td>
<td valign="top" width="17%"><p align="center">int*&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">int*const&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">int* const</p>
</td>
<td valign="top" width="17%"><p align="center">All
pointer types.</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">int&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">int&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">int&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">const
int&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">int&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">All
reference types.</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">const int&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">const
int&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">const
int&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">const
int&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">const
int&amp;</p>
</td>
<td valign="top" width="17%"><p align="center">All
constant-references.</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">int[3]</p>
</td>
<td valign="top" width="17%"><p align="center">const int*</p>
</td>
<td valign="top" width="17%"><p align="center">int(&amp;)[3]</p>
</td>
<td valign="top" width="17%"><p align="center">const int(&amp;)[3]</p>
</td>
<td valign="top" width="17%"><p align="center">const int*
const</p>
</td>
<td valign="top" width="17%"><p align="center">All array
types.</p>
</td>
</tr>
<tr>
<td valign="top" width="17%" bgcolor="#C0C0C0"><p
align="center">const int[3]</p>
</td>
<td valign="top" width="17%"><p align="center">const int*</p>
</td>
<td valign="top" width="17%"><p align="center">const int(&amp;)[3]</p>
</td>
<td valign="top" width="17%"><p align="center">const int(&amp;)[3]</p>
</td>
<td valign="top" width="17%"><p align="center">const int*
const</p>
</td>
<td valign="top" width="17%"><p align="center">All
constant-array types.</p>
</td>
</tr>
</table>
<p>&nbsp;</p>
<h4>Example 1:</h4>
<p>The following class is a trivial class that stores some type T
by value (see the <a href="call_traits_test.cpp">call_traits_test.cpp</a>
file), the aim is to illustrate how each of the available
call_traits typedefs may be used:</p>
<pre>template &lt;class T&gt;
struct contained
{
// define our typedefs first, arrays are stored by value
// so value_type is not the same as result_type:
typedef typename boost::call_traits&lt;T&gt;::param_type param_type;
typedef typename boost::call_traits&lt;T&gt;::reference reference;
typedef typename boost::call_traits&lt;T&gt;::const_reference const_reference;
typedef T value_type;
typedef typename boost::call_traits&lt;T&gt;::value_type result_type;
// stored value:
value_type v_;
// constructors:
contained() {}
contained(param_type p) : v_(p){}
// return byval:
result_type value() { return v_; }
// return by_ref:
reference get() { return v_; }
const_reference const_get()const { return v_; }
// pass value:
void call(param_type p){}
};</pre>
<h4><a name="refs"></a>Example 2 (the reference to reference
problem):</h4>
<p>Consider the definition of std::binder1st:</p>
<pre>template &lt;class Operation&gt;
class binder1st :
public unary_function&lt;typename Operation::second_argument_type, typename Operation::result_type&gt;
{
protected:
Operation op;
typename Operation::first_argument_type value;
public:
binder1st(const Operation&amp; x, const typename Operation::first_argument_type&amp; y);
typename Operation::result_type operator()(const typename Operation::second_argument_type&amp; x) const;
}; </pre>
<p>Now consider what happens in the relatively common case that
the functor takes its second argument as a reference, that
implies that <code>Operation::second_argument_type</code> is a
reference type, <code>operator()</code> will now end up taking a
reference to a reference as an argument, and that is not
currently legal. The solution here is to modify <code>operator()</code>
to use call_traits:</p>
<pre>typename Operation::result_type operator()(typename call_traits&lt;typename Operation::second_argument_type&gt;::param_type x) const;</pre>
<p>Now in the case that <code>Operation::second_argument_type</code>
is a reference type, the argument is passed as a reference, and
the no &quot;reference to reference&quot; occurs.</p>
<h4><a name="ex3"></a>Example 3 (the make_pair problem):</h4>
<p>If we pass the name of an array as one (or both) arguments to <code>std::make_pair</code>,
then template argument deduction deduces the passed parameter as
&quot;const reference to array of T&quot;, this also applies to
string literals (which are really array literals). Consequently
instead of returning a pair of pointers, it tries to return a
pair of arrays, and since an array type is not copy-constructible
the code fails to compile. One solution is to explicitly cast the
arguments to make_pair to pointers, but call_traits provides a
better (i.e. automatic) solution (and one that works safely even
in generic code where the cast might do the wrong thing):</p>
<pre>template &lt;class T1, class T2&gt;
std::pair&lt;
typename boost::call_traits&lt;T1&gt;::value_type,
typename boost::call_traits&lt;T2&gt;::value_type&gt;
make_pair(const T1&amp; t1, const T2&amp; t2)
{
return std::pair&lt;
typename boost::call_traits&lt;T1&gt;::value_type,
typename boost::call_traits&lt;T2&gt;::value_type&gt;(t1, t2);
}</pre>
<p>Here, the deduced argument types will be automatically
degraded to pointers if the deduced types are arrays, similar
situations occur in the standard binders and adapters: in
principle in any function that &quot;wraps&quot; a temporary
whose type is deduced. Note that the function arguments to
make_pair are not expressed in terms of call_traits: doing so
would prevent template argument deduction from functioning.</p>
<h4><a name="ex4"></a>Example 4 (optimising fill):</h4>
<p>The call_traits template will &quot;optimize&quot; the passing
of a small built-in type as a function parameter, this mainly has
an effect when the parameter is used within a loop body. In the
following example (see <a
href="../type_traits/examples/fill_example.cpp">fill_example.cpp</a>),
a version of std::fill is optimized in two ways: if the type
passed is a single byte built-in type then std::memset is used to
effect the fill, otherwise a conventional C++ implemention is
used, but with the passed parameter &quot;optimized&quot; using
call_traits:</p>
<pre>namespace detail{
template &lt;bool opt&gt;
struct filler
{
template &lt;typename I, typename T&gt;
static void do_fill(I first, I last, typename boost::call_traits&lt;T&gt;::param_type val);
{
while(first != last)
{
*first = val;
++first;
}
}
};
template &lt;&gt;
struct filler&lt;true&gt;
{
template &lt;typename I, typename T&gt;
static void do_fill(I first, I last, T val)
{
memset(first, val, last-first);
}
};
}
template &lt;class I, class T&gt;
inline void fill(I first, I last, const T&amp; val)
{
enum{ can_opt = boost::is_pointer&lt;I&gt;::value
&amp;&amp; boost::is_arithmetic&lt;T&gt;::value
&amp;&amp; (sizeof(T) == 1) };
typedef detail::filler&lt;can_opt&gt; filler_t;
filler_t::template do_fill&lt;I,T&gt;(first, last, val);
}</pre>
<p>Footnote: the reason that this is &quot;optimal&quot; for
small built-in types is that with the value passed as &quot;T
const&quot; instead of &quot;const T&amp;&quot; the compiler is
able to tell both that the value is constant and that it is free
of aliases. With this information the compiler is able to cache
the passed value in a register, unroll the loop, or use
explicitly parallel instructions: if any of these are supported.
Exactly how much mileage you will get from this depends upon your
compiler - we could really use some accurate benchmarking
software as part of boost for cases like this.</p>
<p>Note that the function arguments to fill are not expressed in
terms of call_traits: doing so would prevent template argument
deduction from functioning. Instead fill acts as a &quot;thin
wrapper&quot; that is there to perform template argument
deduction, the compiler will optimise away the call to fill all
together, replacing it with the call to filler&lt;&gt;::do_fill,
which does use call_traits.</p>
<h3>Rationale</h3>
<p>The following notes are intended to briefly describe the
rational behind choices made in call_traits.</p>
<p>All user-defined types follow &quot;existing practice&quot;
and need no comment.</p>
<p>Small built-in types (what the standard calls fundamental
types [3.9.1]) differ from existing practice only in the <i>param_type</i>
typedef. In this case passing &quot;T const&quot; is compatible
with existing practice, but may improve performance in some cases
(see <a href="#ex4">Example 4</a>), in any case this should never
be any worse than existing practice.</p>
<p>Pointers follow the same rational as small built-in types.</p>
<p>For reference types the rational follows <a href="#refs">Example
2</a> - references to references are not allowed, so the
call_traits members must be defined such that these problems do
not occur. There is a proposal to modify the language such that
&quot;a reference to a reference is a reference&quot; (issue #106,
submitted by Bjarne Stroustrup), call_traits&lt;T&gt;::value_type
and call_traits&lt;T&gt;::param_type both provide the same effect
as that proposal, without the need for a language change (in
other words it's a workaround).</p>
<p>For array types, a function that takes an array as an argument
will degrade the array type to a pointer type: this means that
the type of the actual parameter is different from its declared
type, something that can cause endless problems in template code
that relies on the declared type of a parameter. For example:</p>
<pre>template &lt;class T&gt;
struct A
{
void foo(T t);
};</pre>
<p><font face="Times New Roman">In this case if we instantiate
A&lt;int[2]&gt; then the declared type of the parameter passed to
member function foo is int[2], but it's actual type is const int*,
if we try to use the type T within the function body, then there
is a strong likelyhood that our code will not compile:</font></p>
<pre>template &lt;class T&gt;
void A&lt;T&gt;::foo(T t)
{
T dup(t); // doesn't compile for case that T is an array.
}</pre>
<p>By using call_traits the degradation from array to pointer is
explicit, and the type of the parameter is the same as it's
declared type:</p>
<pre>template &lt;class T&gt;
struct A
{
void foo(typename call_traits&lt;T&gt;::value_type t);
};
template &lt;class T&gt;
void A&lt;T&gt;::foo(typename call_traits&lt;T&gt;::value_type t)
{
typename call_traits&lt;T&gt;::value_type dup(t); // OK even if T is an array type.
}</pre>
<p>For value_type (return by value), again only a pointer may be
returned, not a copy of the whole array, and again call_traits
makes the degradation explicit. The value_type member is useful
whenever an array must be explicitly degraded to a pointer - <a
href="#ex3">Example 3</a> provides the test case (Footnote: the
array specialisation for call_traits is the least well understood
of all the call_traits specialisations, if the given semantics
cause specific problems for you, or don't solve a particular
array-related problem, then I would be interested to hear about
it. Most people though will probably never need to use this
specialisation).</p>
<hr>
<p>Revised 01 September 2000</p>
<p><EFBFBD> Copyright boost.org 2000. Permission to copy, use, modify,
sell and distribute this document is granted provided this
copyright notice appears in all copies. This document is provided
&quot;as is&quot; without express or implied warranty, and with
no claim as to its suitability for any purpose.</p>
<p>Based on contributions by Steve Cleary, Beman Dawes, Howard
Hinnant and John Maddock.</p>
<p>Maintained by <a href="mailto:john@johnmaddock.co.uk">John
Maddock</a>, the latest version of this file can be found at <a
href="http://www.boost.org/">www.boost.org</a>, and the boost
discussion list at <a
href="http://www.yahoogroups.com/list/boost">www.yahoogroups.com/list/boost</a>.</p>
<p>.</p>
<p>&nbsp;</p>
<p>&nbsp;</p>
</body>
</html>

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// boost::compressed_pair test program
// (C) Copyright John Maddock 2000.
// 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).
// standalone test program for <boost/call_traits.hpp>
// 18 Mar 2002:
// Changed some names to prevent conflicts with some new type_traits additions.
// 03 Oct 2000:
// Enabled extra tests for VC6.
#include <cassert>
#include <iostream>
#include <iomanip>
#include <algorithm>
#include <typeinfo>
#include <boost/call_traits.hpp>
#include <boost/type_traits/type_traits_test.hpp>
// a way prevent warnings for unused variables
template<class T> inline void unused_variable(const T&) {}
//
// struct contained models a type that contains a type (for example std::pair)
// arrays are contained by value, and have to be treated as a special case:
//
template <class T>
struct contained
{
// define our typedefs first, arrays are stored by value
// so value_type is not the same as result_type:
typedef typename boost::call_traits<T>::param_type param_type;
typedef typename boost::call_traits<T>::reference reference;
typedef typename boost::call_traits<T>::const_reference const_reference;
typedef T value_type;
typedef typename boost::call_traits<T>::value_type result_type;
// stored value:
value_type v_;
// constructors:
contained() {}
contained(param_type p) : v_(p){}
// return byval:
result_type value()const { return v_; }
// return by_ref:
reference get() { return v_; }
const_reference const_get()const { return v_; }
// pass value:
void call(param_type){}
};
#ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
template <class T, std::size_t N>
struct contained<T[N]>
{
typedef typename boost::call_traits<T[N]>::param_type param_type;
typedef typename boost::call_traits<T[N]>::reference reference;
typedef typename boost::call_traits<T[N]>::const_reference const_reference;
typedef T value_type[N];
typedef typename boost::call_traits<T[N]>::value_type result_type;
value_type v_;
contained(param_type p)
{
std::copy(p, p+N, v_);
}
// return byval:
result_type value()const { return v_; }
// return by_ref:
reference get() { return v_; }
const_reference const_get()const { return v_; }
void call(param_type){}
};
#endif
template <class T>
contained<typename boost::call_traits<T>::value_type> test_wrap_type(const T& t)
{
typedef typename boost::call_traits<T>::value_type ct;
return contained<ct>(t);
}
namespace test{
template <class T1, class T2>
std::pair<
typename boost::call_traits<T1>::value_type,
typename boost::call_traits<T2>::value_type>
make_pair(const T1& t1, const T2& t2)
{
return std::pair<
typename boost::call_traits<T1>::value_type,
typename boost::call_traits<T2>::value_type>(t1, t2);
}
} // namespace test
using namespace std;
//
// struct call_traits_checker:
// verifies behaviour of contained example:
//
template <class T>
struct call_traits_checker
{
typedef typename boost::call_traits<T>::param_type param_type;
void operator()(param_type);
};
template <class T>
void call_traits_checker<T>::operator()(param_type p)
{
T t(p);
contained<T> c(t);
cout << "checking contained<" << typeid(T).name() << ">..." << endl;
assert(t == c.value());
assert(t == c.get());
assert(t == c.const_get());
#ifndef __ICL
//cout << "typeof contained<" << typeid(T).name() << ">::v_ is: " << typeid(&contained<T>::v_).name() << endl;
cout << "typeof contained<" << typeid(T).name() << ">::value() is: " << typeid(&contained<T>::value).name() << endl;
cout << "typeof contained<" << typeid(T).name() << ">::get() is: " << typeid(&contained<T>::get).name() << endl;
cout << "typeof contained<" << typeid(T).name() << ">::const_get() is: " << typeid(&contained<T>::const_get).name() << endl;
cout << "typeof contained<" << typeid(T).name() << ">::call() is: " << typeid(&contained<T>::call).name() << endl;
cout << endl;
#endif
}
#ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
template <class T, std::size_t N>
struct call_traits_checker<T[N]>
{
typedef typename boost::call_traits<T[N]>::param_type param_type;
void operator()(param_type t)
{
contained<T[N]> c(t);
cout << "checking contained<" << typeid(T[N]).name() << ">..." << endl;
unsigned int i = 0;
for(i = 0; i < N; ++i)
assert(t[i] == c.value()[i]);
for(i = 0; i < N; ++i)
assert(t[i] == c.get()[i]);
for(i = 0; i < N; ++i)
assert(t[i] == c.const_get()[i]);
cout << "typeof contained<" << typeid(T[N]).name() << ">::v_ is: " << typeid(&contained<T[N]>::v_).name() << endl;
cout << "typeof contained<" << typeid(T[N]).name() << ">::value is: " << typeid(&contained<T[N]>::value).name() << endl;
cout << "typeof contained<" << typeid(T[N]).name() << ">::get is: " << typeid(&contained<T[N]>::get).name() << endl;
cout << "typeof contained<" << typeid(T[N]).name() << ">::const_get is: " << typeid(&contained<T[N]>::const_get).name() << endl;
cout << "typeof contained<" << typeid(T[N]).name() << ">::call is: " << typeid(&contained<T[N]>::call).name() << endl;
cout << endl;
}
};
#endif
//
// check_wrap:
template <class W, class U>
void check_wrap(const W& w, const U& u)
{
cout << "checking " << typeid(W).name() << "..." << endl;
assert(w.value() == u);
}
//
// check_make_pair:
// verifies behaviour of "make_pair":
//
template <class T, class U, class V>
void check_make_pair(T c, U u, V v)
{
cout << "checking std::pair<" << typeid(c.first).name() << ", " << typeid(c.second).name() << ">..." << endl;
assert(c.first == u);
assert(c.second == v);
cout << endl;
}
struct comparible_UDT
{
int i_;
comparible_UDT() : i_(2){}
comparible_UDT(const comparible_UDT& other) : i_(other.i_){}
comparible_UDT& operator=(const comparible_UDT& other)
{
i_ = other.i_;
return *this;
}
bool operator == (const comparible_UDT& v){ return v.i_ == i_; }
};
int main(int argc, char *argv[ ])
{
call_traits_checker<comparible_UDT> c1;
comparible_UDT u;
c1(u);
call_traits_checker<int> c2;
int i = 2;
c2(i);
int* pi = &i;
int a[2] = {1,2};
#if defined(BOOST_MSVC6_MEMBER_TEMPLATES) && !defined(__ICL)
call_traits_checker<int*> c3;
c3(pi);
call_traits_checker<int&> c4;
c4(i);
call_traits_checker<const int&> c5;
c5(i);
#if !defined (BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION) && !defined(__MWERKS__) && !defined(__SUNPRO_CC)
call_traits_checker<int[2]> c6;
c6(a);
#endif
#endif
check_wrap(test_wrap_type(2), 2);
#if !defined(BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION) && !defined(__SUNPRO_CC)
check_wrap(test_wrap_type(a), a);
check_make_pair(test::make_pair(a, a), a, a);
#endif
// cv-qualifiers applied to reference types should have no effect
// declare these here for later use with is_reference and remove_reference:
typedef int& r_type;
typedef const r_type cr_type;
type_test(comparible_UDT, boost::call_traits<comparible_UDT>::value_type)
type_test(comparible_UDT&, boost::call_traits<comparible_UDT>::reference)
type_test(const comparible_UDT&, boost::call_traits<comparible_UDT>::const_reference)
type_test(const comparible_UDT&, boost::call_traits<comparible_UDT>::param_type)
type_test(int, boost::call_traits<int>::value_type)
type_test(int&, boost::call_traits<int>::reference)
type_test(const int&, boost::call_traits<int>::const_reference)
type_test(const int, boost::call_traits<int>::param_type)
type_test(int*, boost::call_traits<int*>::value_type)
type_test(int*&, boost::call_traits<int*>::reference)
type_test(int*const&, boost::call_traits<int*>::const_reference)
type_test(int*const, boost::call_traits<int*>::param_type)
#if defined(BOOST_MSVC6_MEMBER_TEMPLATES)
type_test(int&, boost::call_traits<int&>::value_type)
type_test(int&, boost::call_traits<int&>::reference)
type_test(const int&, boost::call_traits<int&>::const_reference)
type_test(int&, boost::call_traits<int&>::param_type)
#if !(defined(__GNUC__) && ((__GNUC__ < 3) || (__GNUC__ == 3) && (__GNUC_MINOR__ < 1)))
type_test(int&, boost::call_traits<cr_type>::value_type)
type_test(int&, boost::call_traits<cr_type>::reference)
type_test(const int&, boost::call_traits<cr_type>::const_reference)
type_test(int&, boost::call_traits<cr_type>::param_type)
#else
std::cout << "Your compiler cannot instantiate call_traits<int&const>, skipping four tests (4 errors)" << std::endl;
failures += 4;
test_count += 4;
#endif
type_test(const int&, boost::call_traits<const int&>::value_type)
type_test(const int&, boost::call_traits<const int&>::reference)
type_test(const int&, boost::call_traits<const int&>::const_reference)
type_test(const int&, boost::call_traits<const int&>::param_type)
#ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
type_test(const int*, boost::call_traits<int[3]>::value_type)
type_test(int(&)[3], boost::call_traits<int[3]>::reference)
type_test(const int(&)[3], boost::call_traits<int[3]>::const_reference)
type_test(const int*const, boost::call_traits<int[3]>::param_type)
type_test(const int*, boost::call_traits<const int[3]>::value_type)
type_test(const int(&)[3], boost::call_traits<const int[3]>::reference)
type_test(const int(&)[3], boost::call_traits<const int[3]>::const_reference)
type_test(const int*const, boost::call_traits<const int[3]>::param_type)
// test with abstract base class:
type_test(test_abc1, boost::call_traits<test_abc1>::value_type)
type_test(test_abc1&, boost::call_traits<test_abc1>::reference)
type_test(const test_abc1&, boost::call_traits<test_abc1>::const_reference)
type_test(const test_abc1&, boost::call_traits<test_abc1>::param_type)
#else
std::cout << "You're compiler does not support partial template specialiation, skipping 8 tests (8 errors)" << std::endl;
failures += 12;
test_count += 12;
#endif
#else
std::cout << "You're compiler does not support partial template specialiation, skipping 20 tests (20 errors)" << std::endl;
failures += 24;
test_count += 24;
#endif
// test with an incomplete type:
type_test(incomplete_type, boost::call_traits<incomplete_type>::value_type)
type_test(incomplete_type&, boost::call_traits<incomplete_type>::reference)
type_test(const incomplete_type&, boost::call_traits<incomplete_type>::const_reference)
type_test(const incomplete_type&, boost::call_traits<incomplete_type>::param_type)
return check_result(argc, argv);
}
//
// define call_traits tests to check that the assertions in the docs do actually work
// this is an instantiate only set of tests:
//
template <typename T, bool isarray = false>
struct call_traits_test
{
typedef ::boost::call_traits<T> ct;
typedef typename ct::param_type param_type;
typedef typename ct::reference reference;
typedef typename ct::const_reference const_reference;
typedef typename ct::value_type value_type;
static void assert_construct(param_type val);
};
template <typename T, bool isarray>
void call_traits_test<T, isarray>::assert_construct(typename call_traits_test<T, isarray>::param_type val)
{
//
// this is to check that the call_traits assertions are valid:
T t(val);
value_type v(t);
reference r(t);
const_reference cr(t);
param_type p(t);
value_type v2(v);
value_type v3(r);
value_type v4(p);
reference r2(v);
reference r3(r);
const_reference cr2(v);
const_reference cr3(r);
const_reference cr4(cr);
const_reference cr5(p);
param_type p2(v);
param_type p3(r);
param_type p4(p);
unused_variable(v2);
unused_variable(v3);
unused_variable(v4);
unused_variable(r2);
unused_variable(r3);
unused_variable(cr2);
unused_variable(cr3);
unused_variable(cr4);
unused_variable(cr5);
unused_variable(p2);
unused_variable(p3);
unused_variable(p4);
}
#ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
template <typename T>
struct call_traits_test<T, true>
{
typedef ::boost::call_traits<T> ct;
typedef typename ct::param_type param_type;
typedef typename ct::reference reference;
typedef typename ct::const_reference const_reference;
typedef typename ct::value_type value_type;
static void assert_construct(param_type val);
};
template <typename T>
void call_traits_test<T, true>::assert_construct(typename boost::call_traits<T>::param_type val)
{
//
// this is to check that the call_traits assertions are valid:
T t;
value_type v(t);
value_type v5(val);
reference r = t;
const_reference cr = t;
reference r2 = r;
#ifndef __BORLANDC__
// C++ Builder buglet:
const_reference cr2 = r;
#endif
param_type p(t);
value_type v2(v);
const_reference cr3 = cr;
value_type v3(r);
value_type v4(p);
param_type p2(v);
param_type p3(r);
param_type p4(p);
unused_variable(v2);
unused_variable(v3);
unused_variable(v4);
unused_variable(v5);
#ifndef __BORLANDC__
unused_variable(r2);
unused_variable(cr2);
#endif
unused_variable(cr3);
unused_variable(p2);
unused_variable(p3);
unused_variable(p4);
}
#endif //BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
//
// now check call_traits assertions by instantiating call_traits_test:
template struct call_traits_test<int>;
template struct call_traits_test<const int>;
template struct call_traits_test<int*>;
#if defined(BOOST_MSVC6_MEMBER_TEMPLATES)
template struct call_traits_test<int&>;
template struct call_traits_test<const int&>;
#if !defined(BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION) && !defined(__SUNPRO_CC)
template struct call_traits_test<int[2], true>;
#endif
#endif
#if defined(BOOST_MSVC) && _MSC_VER <= 1300
unsigned int expected_failures = 14;
#elif defined(__SUNPRO_CC)
#if(__SUNPRO_CC <= 0x520)
unsigned int expected_failures = 18;
#elif(__SUNPRO_CC < 0x530)
unsigned int expected_failures = 17;
#else
unsigned int expected_failures = 6;
#endif
#elif defined(__BORLANDC__)
unsigned int expected_failures = 2;
#elif (defined(__GNUC__) && ((__GNUC__ < 3) || (__GNUC__ == 3) && (__GNUC_MINOR__ < 1)))
unsigned int expected_failures = 4;
#elif defined(__HP_aCC)
unsigned int expected_failures = 24;
#else
unsigned int expected_failures = 0;
#endif

124
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<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.0 Transitional//EN">
<html>
<head>
<title>Boost: checked_delete.hpp documentation</title>
<meta http-equiv="Content-Type" content="text/html; charset=iso-8859-1">
</head>
<body bgcolor="white" style="MARGIN-LEFT: 5%; MARGIN-RIGHT: 5%">
<table border="0" width="100%">
<tr>
<td width="277">
<img src="../../c++boost.gif" alt="c++boost.gif (8819 bytes)" width="277" height="86">
</td>
<td align="middle">
<h1>checked_delete.hpp</h1>
</td>
</tr>
<tr>
<td colspan="2" height="64">&nbsp;</td>
</tr>
</table>
<p>
The header <STRONG>&lt;boost/checked_delete.hpp&gt;</STRONG> defines two
function templates, <STRONG>checked_delete</STRONG> and <STRONG>checked_array_delete</STRONG>,
and two class templates, <STRONG>checked_deleter</STRONG> and <STRONG>checked_array_deleter</STRONG>.
</p>
<P>The C++ Standard allows, in 5.3.5/5, pointers to incomplete class types to be
deleted with a <EM>delete-expression</EM>. When the class has a non-trivial
destructor, or a class-specific operator delete, the behavior is undefined.
Some compilers issue a warning when an incomplete type is deleted, but
unfortunately, not all do, and programmers sometimes ignore or disable
warnings.</P>
<P>A particularly troublesome case is when a smart pointer's destructor, such as <STRONG>
boost::scoped_ptr&lt;T&gt;::~scoped_ptr</STRONG>, is instantiated with an
incomplete type. This can often lead to silent, hard to track failures.</P>
<P>The supplied function and class templates can be used to prevent these problems,
as they require a complete type, and cause a compilation error otherwise.</P>
<h3><a name="Synopsis">Synopsis</a></h3>
<pre>
namespace boost
{
template&lt;class T&gt; void checked_delete(T * p);
template&lt;class T&gt; void checked_array_delete(T * p);
template&lt;class T&gt; struct checked_deleter;
template&lt;class T&gt; struct checked_array_deleter;
}
</pre>
<h3>checked_delete</h3>
<h4><a name="checked_delete">template&lt;class T&gt; void checked_delete(T * p);</a></h4>
<blockquote>
<p>
<b>Requires:</b> <b>T</b> must be a complete type. The expression <tt>delete p</tt>
must be well-formed.
</p>
<p>
<b>Effects:</b> <tt>delete p;</tt>
</p>
</blockquote>
<h3>checked_array_delete</h3>
<h4><a name="checked_array_delete">template&lt;class T&gt; void checked_array_delete(T
* p);</a></h4>
<blockquote>
<p>
<b>Requires:</b> <b>T</b> must be a complete type. The expression <tt>delete [] p</tt>
must be well-formed.
</p>
<p>
<b>Effects:</b> <tt>delete [] p;</tt>
</p>
</blockquote>
<h3>checked_deleter</h3>
<pre>
template&lt;class T&gt; struct checked_deleter
{
typedef void result_type;
typedef T * argument_type;
void operator()(T * p) const;
};
</pre>
<h4>void checked_deleter&lt;T&gt;::operator()(T * p) const;</h4>
<blockquote>
<p>
<b>Requires:</b> <b>T</b> must be a complete type. The expression <tt>delete p</tt>
must be well-formed.
</p>
<p>
<b>Effects:</b> <tt>delete p;</tt>
</p>
</blockquote>
<h3>checked_array_deleter</h3>
<pre>
template&lt;class T&gt; struct checked_array_deleter
{
typedef void result_type;
typedef T * argument_type;
void operator()(T * p) const;
};
</pre>
<h4>void checked_array_deleter&lt;T&gt;::operator()(T * p) const;</h4>
<blockquote>
<p>
<b>Requires:</b> <b>T</b> must be a complete type. The expression <tt>delete [] p</tt>
must be well-formed.
</p>
<p>
<b>Effects:</b> <tt>delete [] p;</tt>
</p>
</blockquote>
<h3><a name="Acknowledgements">Acknowledgements</a></h3>
<p>
The function templates <STRONG>checked_delete</STRONG> and <STRONG>checked_array_delete</STRONG>
were originally part of <STRONG>&lt;boost/utility.hpp&gt;</STRONG>, and the
documentation acknowledged Beman Dawes, Dave Abrahams, Vladimir Prus, Rainer
Deyke, John Maddock, and others as contributors.
</p>
<p>
<br>
<small>Copyright <20> 2002 by Peter Dimov. Permission to copy, use, modify, sell and
distribute this document is granted provided this copyright notice appears in
all copies. This document is provided "as is" without express or implied
warranty, and with no claim as to its suitability for any purpose.</small></p>
</body>
</html>

27
checked_delete_test.cpp
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// Boost checked_delete test program ---------------------------------------//
// Copyright Beman Dawes 2001.
// See accompanying license for terms and conditions of use.
// See http://www.boost.org/libs/utility for documentation.
// Revision History
// 21 May 01 Initial version (Beman Dawes)
#include <boost/checked_delete.hpp> // for checked_delete
// This program demonstrates compiler errors when trying to delete an
// incomplete type.
namespace
{
class Incomplete;
}
int main()
{
Incomplete * p = 0;
boost::checked_delete(p); // should cause compile time error
boost::checked_array_delete(p); // should cause compile time error
return 0;
} // main

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<html>
<head>
<meta http-equiv="Content-Type"
content="text/html; charset=iso-8859-1">
<meta name="Template"
content="C:\PROGRAM FILES\MICROSOFT OFFICE\OFFICE\html.dot">
<meta name="GENERATOR" content="Microsoft FrontPage Express 2.0">
<title>Header </title>
<boost/compressed_pair.hpp>
</head>
<body bgcolor="#FFFFFF" text="#000000" link="#0000FF"
vlink="#800080">
<h2><img src="../../c++boost.gif" width="276" height="86">Header
&lt;<a href="../../boost/detail/compressed_pair.hpp">boost/compressed_pair.hpp</a>&gt;</h2>
<p>All of the contents of &lt;boost/compressed_pair.hpp&gt; are
defined inside namespace boost.</p>
<p>The class compressed pair is very similar to std::pair, but if
either of the template arguments are empty classes, then the
&quot;empty base-class optimisation&quot; is applied to compress
the size of the pair.</p>
<pre>template &lt;class T1, class T2&gt;
class compressed_pair
{
public:
typedef T1 first_type;
typedef T2 second_type;
typedef typename call_traits&lt;first_type&gt;::param_type first_param_type;
typedef typename call_traits&lt;second_type&gt;::param_type second_param_type;
typedef typename call_traits&lt;first_type&gt;::reference first_reference;
typedef typename call_traits&lt;second_type&gt;::reference second_reference;
typedef typename call_traits&lt;first_type&gt;::const_reference first_const_reference;
typedef typename call_traits&lt;second_type&gt;::const_reference second_const_reference;
compressed_pair() : base() {}
compressed_pair(first_param_type x, second_param_type y);
explicit compressed_pair(first_param_type x);
explicit compressed_pair(second_param_type y);
compressed_pair&amp; operator=(const compressed_pair&amp;);
first_reference first();
first_const_reference first() const;
second_reference second();
second_const_reference second() const;
void swap(compressed_pair&amp; y);
};</pre>
<p>The two members of the pair can be accessed using the member
functions first() and second(). Note that not all member
functions can be instantiated for all template parameter types.
In particular compressed_pair can be instantiated for reference
and array types, however in these cases the range of constructors
that can be used are limited. If types T1 and T2 are the same
type, then there is only one version of the single-argument
constructor, and this constructor initialises both values in the
pair to the passed value.</p>
<p>Note that compressed_pair can not be instantiated if either of
the template arguments is a union type, unless there is compiler
support for boost::is_union, or if boost::is_union is specialised
for the union type.</p>
<p>Finally, a word of caution for Visual C++ 6 users: if either
argument is an empty type, then assigning to that member will
produce memory corruption, unless the empty type has a &quot;do
nothing&quot; assignment operator defined. This is due to a bug
in the way VC6 generates implicit assignment operators.</p>
<hr>
<p>Revised 08 May 2001</p>
<p><EFBFBD> Copyright boost.org 2000. Permission to copy, use, modify,
sell and distribute this document is granted provided this
copyright notice appears in all copies. This document is provided
&quot;as is&quot; without express or implied warranty, and with
no claim as to its suitability for any purpose.</p>
<p>Based on contributions by Steve Cleary, Beman Dawes, Howard
Hinnant and John Maddock.</p>
<p>Maintained by <a href="mailto:john@johnmaddock.co.uk">John
Maddock</a>, the latest version of this file can be found at <a
href="http://www.boost.org">www.boost.org</a>, and the boost
discussion list at <a
href="http://www.yahoogroups.com/list/boost">www.yahoogroups.com/list/boost</a>.</p>
<p>&nbsp;</p>
</body>
</html>

401
compressed_pair_test.cpp
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// boost::compressed_pair test program
// (C) Copyright John Maddock 2000.
// 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).
// standalone test program for <boost/compressed_pair.hpp>
// Revised 03 Oct 2000:
// Enabled tests for VC6.
#include <iostream>
#include <typeinfo>
#include <cassert>
#include <boost/compressed_pair.hpp>
#include <boost/type_traits/type_traits_test.hpp>
#define BOOST_INCLUDE_MAIN
#include <boost/test/test_tools.hpp>
using namespace boost;
namespace boost {
#ifndef BOOST_NO_INCLASS_MEMBER_INITIALIZATION
template <> struct is_empty<empty_UDT>
{ static const bool value = true; };
template <> struct is_empty<empty_POD_UDT>
{ static const bool value = true; };
template <> struct is_POD<empty_POD_UDT>
{ static const bool value = true; };
#else
template <> struct is_empty<empty_UDT>
{ enum{ value = true }; };
template <> struct is_empty<empty_POD_UDT>
{ enum{ value = true }; };
template <> struct is_POD<empty_POD_UDT>
{ enum{ value = true }; };
#endif
}
struct non_empty1
{
int i;
non_empty1() : i(1){}
non_empty1(int v) : i(v){}
friend bool operator==(const non_empty1& a, const non_empty1& b)
{ return a.i == b.i; }
};
struct non_empty2
{
int i;
non_empty2() : i(3){}
non_empty2(int v) : i(v){}
friend bool operator==(const non_empty2& a, const non_empty2& b)
{ return a.i == b.i; }
};
#ifdef __GNUC__
using std::swap;
#endif
template <class T1, class T2>
struct compressed_pair_tester
{
// define the types we need:
typedef T1 first_type;
typedef T2 second_type;
typedef typename call_traits<first_type>::param_type first_param_type;
typedef typename call_traits<second_type>::param_type second_param_type;
// define our test proc:
static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
};
template <class T1, class T2>
void compressed_pair_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4)
{
#ifndef __GNUC__
// gcc 2.90 can't cope with function scope using
// declarations, and generates an internal compiler error...
using std::swap;
#endif
// default construct:
boost::compressed_pair<T1,T2> cp1;
// first param construct:
boost::compressed_pair<T1,T2> cp2(p1);
cp2.second() = p2;
BOOST_TEST(cp2.first() == p1);
BOOST_TEST(cp2.second() == p2);
// second param construct:
boost::compressed_pair<T1,T2> cp3(p2);
cp3.first() = p1;
BOOST_TEST(cp3.second() == p2);
BOOST_TEST(cp3.first() == p1);
// both param construct:
boost::compressed_pair<T1,T2> cp4(p1, p2);
BOOST_TEST(cp4.first() == p1);
BOOST_TEST(cp4.second() == p2);
boost::compressed_pair<T1,T2> cp5(p3, p4);
BOOST_TEST(cp5.first() == p3);
BOOST_TEST(cp5.second() == p4);
// check const members:
const boost::compressed_pair<T1,T2>& cpr1 = cp4;
BOOST_TEST(cpr1.first() == p1);
BOOST_TEST(cpr1.second() == p2);
// copy construct:
boost::compressed_pair<T1,T2> cp6(cp4);
BOOST_TEST(cp6.first() == p1);
BOOST_TEST(cp6.second() == p2);
// assignment:
cp1 = cp4;
BOOST_TEST(cp1.first() == p1);
BOOST_TEST(cp1.second() == p2);
cp1 = cp5;
BOOST_TEST(cp1.first() == p3);
BOOST_TEST(cp1.second() == p4);
// swap:
cp4.swap(cp5);
BOOST_TEST(cp4.first() == p3);
BOOST_TEST(cp4.second() == p4);
BOOST_TEST(cp5.first() == p1);
BOOST_TEST(cp5.second() == p2);
swap(cp4,cp5);
BOOST_TEST(cp4.first() == p1);
BOOST_TEST(cp4.second() == p2);
BOOST_TEST(cp5.first() == p3);
BOOST_TEST(cp5.second() == p4);
}
//
// tests for case where one or both
// parameters are reference types:
//
template <class T1, class T2>
struct compressed_pair_reference_tester
{
// define the types we need:
typedef T1 first_type;
typedef T2 second_type;
typedef typename call_traits<first_type>::param_type first_param_type;
typedef typename call_traits<second_type>::param_type second_param_type;
// define our test proc:
static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
};
template <class T1, class T2>
void compressed_pair_reference_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4)
{
#ifndef __GNUC__
// gcc 2.90 can't cope with function scope using
// declarations, and generates an internal compiler error...
using std::swap;
#endif
// both param construct:
boost::compressed_pair<T1,T2> cp4(p1, p2);
BOOST_TEST(cp4.first() == p1);
BOOST_TEST(cp4.second() == p2);
boost::compressed_pair<T1,T2> cp5(p3, p4);
BOOST_TEST(cp5.first() == p3);
BOOST_TEST(cp5.second() == p4);
// check const members:
const boost::compressed_pair<T1,T2>& cpr1 = cp4;
BOOST_TEST(cpr1.first() == p1);
BOOST_TEST(cpr1.second() == p2);
// copy construct:
boost::compressed_pair<T1,T2> cp6(cp4);
BOOST_TEST(cp6.first() == p1);
BOOST_TEST(cp6.second() == p2);
// assignment:
// VC6 bug:
// When second() is an empty class, VC6 performs the
// assignment by doing a memcpy - even though the empty
// class is really a zero sized base class, the result
// is that the memory of first() gets trampled over.
// Similar arguments apply to the case that first() is
// an empty base class.
// Strangely the problem is dependent upon the compiler
// settings - some generate the problem others do not.
cp4.first() = p3;
cp4.second() = p4;
BOOST_TEST(cp4.first() == p3);
BOOST_TEST(cp4.second() == p4);
}
//
// supplimentary tests for case where first arg only is a reference type:
//
template <class T1, class T2>
struct compressed_pair_reference1_tester
{
// define the types we need:
typedef T1 first_type;
typedef T2 second_type;
typedef typename call_traits<first_type>::param_type first_param_type;
typedef typename call_traits<second_type>::param_type second_param_type;
// define our test proc:
static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
};
template <class T1, class T2>
void compressed_pair_reference1_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type, second_param_type)
{
#ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
// first param construct:
boost::compressed_pair<T1,T2> cp2(p1);
cp2.second() = p2;
BOOST_TEST(cp2.first() == p1);
BOOST_TEST(cp2.second() == p2);
#endif
}
//
// supplimentary tests for case where second arg only is a reference type:
//
template <class T1, class T2>
struct compressed_pair_reference2_tester
{
// define the types we need:
typedef T1 first_type;
typedef T2 second_type;
typedef typename call_traits<first_type>::param_type first_param_type;
typedef typename call_traits<second_type>::param_type second_param_type;
// define our test proc:
static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
};
template <class T1, class T2>
void compressed_pair_reference2_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type, second_param_type)
{
#ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
// second param construct:
boost::compressed_pair<T1,T2> cp3(p2);
cp3.first() = p1;
BOOST_TEST(cp3.second() == p2);
BOOST_TEST(cp3.first() == p1);
#endif
}
//
// tests for where one or the other parameter is an array:
//
template <class T1, class T2>
struct compressed_pair_array1_tester
{
// define the types we need:
typedef T1 first_type;
typedef T2 second_type;
typedef typename call_traits<first_type>::param_type first_param_type;
typedef typename call_traits<second_type>::param_type second_param_type;
// define our test proc:
static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
};
template <class T1, class T2>
void compressed_pair_array1_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type, second_param_type)
{
// default construct:
boost::compressed_pair<T1,T2> cp1;
// second param construct:
boost::compressed_pair<T1,T2> cp3(p2);
cp3.first()[0] = p1[0];
BOOST_TEST(cp3.second() == p2);
BOOST_TEST(cp3.first()[0] == p1[0]);
// check const members:
const boost::compressed_pair<T1,T2>& cpr1 = cp3;
BOOST_TEST(cpr1.first()[0] == p1[0]);
BOOST_TEST(cpr1.second() == p2);
BOOST_TEST(sizeof(T1) == sizeof(cp1.first()));
}
template <class T1, class T2>
struct compressed_pair_array2_tester
{
// define the types we need:
typedef T1 first_type;
typedef T2 second_type;
typedef typename call_traits<first_type>::param_type first_param_type;
typedef typename call_traits<second_type>::param_type second_param_type;
// define our test proc:
static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
};
template <class T1, class T2>
void compressed_pair_array2_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type, second_param_type)
{
// default construct:
boost::compressed_pair<T1,T2> cp1;
// first param construct:
boost::compressed_pair<T1,T2> cp2(p1);
cp2.second()[0] = p2[0];
BOOST_TEST(cp2.first() == p1);
BOOST_TEST(cp2.second()[0] == p2[0]);
// check const members:
const boost::compressed_pair<T1,T2>& cpr1 = cp2;
BOOST_TEST(cpr1.first() == p1);
BOOST_TEST(cpr1.second()[0] == p2[0]);
BOOST_TEST(sizeof(T2) == sizeof(cp1.second()));
}
template <class T1, class T2>
struct compressed_pair_array_tester
{
// define the types we need:
typedef T1 first_type;
typedef T2 second_type;
typedef typename call_traits<first_type>::param_type first_param_type;
typedef typename call_traits<second_type>::param_type second_param_type;
// define our test proc:
static void test(first_param_type p1, second_param_type p2, first_param_type p3, second_param_type p4);
};
template <class T1, class T2>
void compressed_pair_array_tester<T1, T2>::test(first_param_type p1, second_param_type p2, first_param_type, second_param_type)
{
// default construct:
boost::compressed_pair<T1,T2> cp1;
cp1.first()[0] = p1[0];
cp1.second()[0] = p2[0];
BOOST_TEST(cp1.first()[0] == p1[0]);
BOOST_TEST(cp1.second()[0] == p2[0]);
// check const members:
const boost::compressed_pair<T1,T2>& cpr1 = cp1;
BOOST_TEST(cpr1.first()[0] == p1[0]);
BOOST_TEST(cpr1.second()[0] == p2[0]);
BOOST_TEST(sizeof(T1) == sizeof(cp1.first()));
BOOST_TEST(sizeof(T2) == sizeof(cp1.second()));
}
int test_main(int, char *[])
{
// declare some variables to pass to the tester:
non_empty1 ne1(2);
non_empty1 ne2(3);
non_empty2 ne3(4);
non_empty2 ne4(5);
empty_POD_UDT e1;
empty_UDT e2;
// T1 != T2, both non-empty
compressed_pair_tester<non_empty1,non_empty2>::test(ne1, ne3, ne2, ne4);
// T1 != T2, T2 empty
compressed_pair_tester<non_empty1,empty_POD_UDT>::test(ne1, e1, ne2, e1);
// T1 != T2, T1 empty
compressed_pair_tester<empty_POD_UDT,non_empty2>::test(e1, ne3, e1, ne4);
// T1 != T2, both empty
compressed_pair_tester<empty_POD_UDT,empty_UDT>::test(e1, e2, e1, e2);
// T1 == T2, both non-empty
compressed_pair_tester<non_empty1,non_empty1>::test(ne1, ne1, ne2, ne2);
// T1 == T2, both empty
compressed_pair_tester<empty_UDT,empty_UDT>::test(e2, e2, e2, e2);
// test references:
// T1 != T2, both non-empty
compressed_pair_reference_tester<non_empty1&,non_empty2>::test(ne1, ne3, ne2, ne4);
compressed_pair_reference_tester<non_empty1,non_empty2&>::test(ne1, ne3, ne2, ne4);
compressed_pair_reference1_tester<non_empty1&,non_empty2>::test(ne1, ne3, ne2, ne4);
compressed_pair_reference2_tester<non_empty1,non_empty2&>::test(ne1, ne3, ne2, ne4);
// T1 != T2, T2 empty
compressed_pair_reference_tester<non_empty1&,empty_POD_UDT>::test(ne1, e1, ne2, e1);
compressed_pair_reference1_tester<non_empty1&,empty_POD_UDT>::test(ne1, e1, ne2, e1);
// T1 != T2, T1 empty
compressed_pair_reference_tester<empty_POD_UDT,non_empty2&>::test(e1, ne3, e1, ne4);
compressed_pair_reference2_tester<empty_POD_UDT,non_empty2&>::test(e1, ne3, e1, ne4);
// T1 == T2, both non-empty
compressed_pair_reference_tester<non_empty1&,non_empty1&>::test(ne1, ne1, ne2, ne2);
// tests arrays:
non_empty1 nea1[2];
non_empty1 nea2[2];
non_empty2 nea3[2];
non_empty2 nea4[2];
nea1[0] = non_empty1(5);
nea2[0] = non_empty1(6);
nea3[0] = non_empty2(7);
nea4[0] = non_empty2(8);
// T1 != T2, both non-empty
compressed_pair_array1_tester<non_empty1[2],non_empty2>::test(nea1, ne3, nea2, ne4);
compressed_pair_array2_tester<non_empty1,non_empty2[2]>::test(ne1, nea3, ne2, nea4);
compressed_pair_array_tester<non_empty1[2],non_empty2[2]>::test(nea1, nea3, nea2, nea4);
// T1 != T2, T2 empty
compressed_pair_array1_tester<non_empty1[2],empty_POD_UDT>::test(nea1, e1, nea2, e1);
// T1 != T2, T1 empty
compressed_pair_array2_tester<empty_POD_UDT,non_empty2[2]>::test(e1, nea3, e1, nea4);
// T1 == T2, both non-empty
compressed_pair_array_tester<non_empty1[2],non_empty1[2]>::test(nea1, nea1, nea2, nea2);
return 0;
}
unsigned int expected_failures = 0;

60
counting_iterator_example.cpp
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// (C) Copyright Jeremy Siek 2000. Permission to copy, use, modify, sell and
// distribute this software is granted provided this copyright notice appears
// in all copies. This software is provided "as is" without express or implied
// warranty, and with no claim as to its suitability for any purpose.
#include <boost/config.hpp>
#include <algorithm>
#include <iostream>
#include <iterator>
#include <vector>
#include <boost/iterator/counting_iterator.hpp>
#include <boost/iterator/indirect_iterator.hpp>
int main(int, char*[])
{
// Example of using counting_iterator_generator
std::cout << "counting from 0 to 4:" << std::endl;
boost::counting_iterator<int> first(0), last(4);
std::copy(first, last, std::ostream_iterator<int>(std::cout, " "));
std::cout << std::endl;
// Example of using make_counting_iterator()
std::cout << "counting from -5 to 4:" << std::endl;
std::copy(boost::make_counting_iterator(-5),
boost::make_counting_iterator(5),
std::ostream_iterator<int>(std::cout, " "));
std::cout << std::endl;
// Example of using counting iterator to create an array of pointers.
#if !BOOST_WORKAROUND(__BORLANDC__, BOOST_TESTED_AT(0x551))
const
#endif
int N = 7;
std::vector<int> numbers;
// Fill "numbers" array with [0,N)
std::copy(
boost::make_counting_iterator(0)
, boost::make_counting_iterator(N)
, std::back_inserter(numbers));
std::vector<std::vector<int>::iterator> pointers;
// Use counting iterator to fill in the array of pointers.
// causes an ICE with MSVC6
std::copy(boost::make_counting_iterator(numbers.begin()),
boost::make_counting_iterator(numbers.end()),
std::back_inserter(pointers));
// Use indirect iterator to print out numbers by accessing
// them through the array of pointers.
std::cout << "indirectly printing out the numbers from 0 to "
<< N << std::endl;
std::copy(boost::make_indirect_iterator(pointers.begin()),
boost::make_indirect_iterator(pointers.end()),
std::ostream_iterator<int>(std::cout, " "));
std::cout << std::endl;
return 0;
}

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current_function.html
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<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.0 Transitional//EN">
<html>
<head>
<title>Boost: current_function.hpp documentation</title>
<meta http-equiv="Content-Type" content="text/html; charset=iso-8859-1">
</head>
<body bgcolor="white" style="MARGIN-LEFT: 5%; MARGIN-RIGHT: 5%">
<table border="0" width="100%">
<tr>
<td width="277">
<img src="../../c++boost.gif" alt="c++boost.gif (8819 bytes)" width="277" height="86">
</td>
<td align="middle">
<h1>current_function.hpp</h1>
</td>
</tr>
<tr>
<td colspan="2" height="64">&nbsp;</td>
</tr>
</table>
<p>
The header <STRONG>&lt;boost/current_function.hpp&gt;</STRONG> defines a single
macro, <STRONG>BOOST_CURRENT_FUNCTION</STRONG>,<STRONG> </STRONG>similar to the
C99 predefined identifier <STRONG>__func__</STRONG>.
</p>
<P><STRONG>BOOST_CURRENT_FUNCTION</STRONG> expands to a string literal containing
the (fully qualified, if possible) name of the enclosing function. If there is
no enclosing function, the behavior is undefined.</P>
<p>Some compilers do not provide a way to obtain the name of the current enclosing
function. On such compilers, the string literal has an unspecified value.</p>
<p>
<br>
<small>Copyright <20> 2002 by Peter Dimov. Permission to copy, use, modify, sell and
distribute this document is granted provided this copyright notice appears in
all copies. This document is provided "as is" without express or implied
warranty, and with no claim as to its suitability for any purpose.</small></p>
</body>
</html>

34
current_function_test.cpp
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@ -1,34 +0,0 @@
#include <boost/config.hpp>
#if defined(BOOST_MSVC)
#pragma warning(disable: 4786) // identifier truncated in debug info
#pragma warning(disable: 4710) // function not inlined
#pragma warning(disable: 4711) // function selected for automatic inline expansion
#pragma warning(disable: 4514) // unreferenced inline removed
#endif
//
// current_function_test.cpp - a test for boost/current_function.hpp
//
// Copyright (c) 2002 Peter Dimov and Multi Media Ltd.
//
// Permission to copy, use, modify, sell and distribute this software
// is granted provided this copyright notice appears in all copies.
// This software is provided "as is" without express or implied
// warranty, and with no claim as to its suitability for any purpose.
//
#include <boost/current_function.hpp>
#include <cstdio>
void message(char const * file, long line, char const * func, char const * msg)
{
std::printf("%s(%ld): %s in function '%s'\n", file, line, msg, func);
}
#define MESSAGE(msg) message(__FILE__, __LINE__, BOOST_CURRENT_FUNCTION, msg)
int main()
{
MESSAGE("assertion failed");
}

388
enable_if.html
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<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.0 Transitional//EN"
"http://www.w3.org/TR/REC-html40/loose.dtd">
<HTML>
<HEAD><TITLE>enable_if</TITLE>
<META http-equiv="Content-Type" content="text/html; charset=ISO-8859-1">
<META name="GENERATOR" content="Microsoft FrontPage 5.0">
</HEAD>
<BODY >
<!--HEVEA command line is: hevea -nosymb -noiso -pedantic -v enable_if_docs_for_boost.tex -->
<!--HTMLHEAD-->
<!--ENDHTML-->
<!--PREFIX <ARG ></ARG>-->
<!--CUT DEF section 1 -->
<BR>
<BR>
<h1>
<img border="0" src="../../c++boost.gif" align="center" width="277" height="86">enable_if</h1>
<BR>
<BR>
Copyright 2003 Jaakko J&auml;rvi, Jeremiah Willcock, Andrew Lumsdaine.<BR>
<BR>
<!--TOC section Introduction-->
<H2><A NAME="htoc1">1</A>&nbsp;&nbsp;Introduction</H2><!--SEC END -->
<A NAME="introduction"></A>
The <TT>enable_if</TT> family of templates is a set of tools to allow a function template or a class template specialization
to include or exclude itself from a set of matching functions or specializations
based on properties of its template arguments.
For example, one can define function templates that
are only enabled for, and thus only match, an arbitrary set of types
defined by a traits class. The <TT>enable_if</TT> templates can also be
applied to enable class template specializations. Applications of
<TT>enable_if</TT> are discussed in length
in&nbsp;[<A HREF="#jarvi:03:cuj_arbitrary_overloading"><CITE>1</CITE></A>] and&nbsp;[<A HREF="#jarvi:03:c++typeclasses"><CITE>2</CITE></A>].<BR>
<BR>
<!--TOC subsection Synopsis-->
<H3><A NAME="htoc2">1.1</A>&nbsp;&nbsp;Synopsis</H3><!--SEC END -->
<A NAME="sec:synopsis"></A>
<PRE>namespace boost {
template &lt;class Cond, class T = void&gt; struct enable_if;
template &lt;class Cond, class T = void&gt; struct disable_if;
template &lt;class Cond, class T&gt; struct lazy_enable_if;
template &lt;class Cond, class T&gt; struct lazy_disable_if;
template &lt;bool B, class T = void&gt; struct enable_if_c;
template &lt;bool B, class T = void&gt; struct disable_if_c;
template &lt;bool B, class T&gt; struct lazy_enable_if_c;
template &lt;bool B, class T&gt; struct lazy_disable_if_c;
}
</PRE>
<!--TOC subsection Background-->
<H3><A NAME="htoc3">1.2</A>&nbsp;&nbsp;Background</H3><!--SEC END -->
<A NAME="sec:background"></A>
Sensible operation of template function overloading in C++ relies
on the <EM>SFINAE</EM> (substitution-failure-is-not-an-error)
principle&nbsp;[<A HREF="#vandevoorde2002:templates"><CITE>3</CITE></A>]: if an invalid argument
or return type is formed during the instantiation of a function
template, the instantiation is removed from the overload resolution
set instead of causing a compilation error. The following example,
taken from&nbsp;[<A HREF="#jarvi:03:cuj_arbitrary_overloading"><CITE>1</CITE></A>],
demonstrates why this is important:
<PRE>int negate(int i) { return -i; }
template &lt;class F&gt;
typename F::result_type negate(const F&amp; f) { return -f(); }
</PRE>
Suppose the compiler encounters the call <TT>negate(1)</TT>. The first
definition is obviously a better match, but the compiler must
nevertheless consider (and instantiate the prototypes) of both
definitions to find this out. Instantiating the latter definition with
<TT>F</TT> as <TT>int</TT> would result in:
<PRE>int::result_type negate(const int&amp;);
</PRE>
where the return type is invalid. If this was an error, adding an unrelated function template
(that was never called) could break otherwise valid code.
Due to the SFINAE principle the above example is not, however, erroneous.
The latter definition of <TT>negate</TT> is simply removed from the overload resolution set.<BR>
<BR>
The <TT>enable_if</TT> templates are tools for controlled creation of the SFINAE
conditions.<BR>
<BR>
<!--TOC section The <TT>enable_if</TT> templates-->
<H2><A NAME="htoc4">2</A>&nbsp;&nbsp;The <TT>enable_if</TT> templates</H2><!--SEC END -->
<A NAME="enable_if"></A>
The names of the <TT>enable_if</TT> templates have three parts: an optional <TT>lazy_</TT> tag,
either <TT>enable_if</TT> or <TT>disable_if</TT>, and an optional <TT>_c</TT> tag.
All eight combinations of these parts are supported.
The meaning of the <TT>lazy_</TT> tag is described in Section&nbsp;<A HREF="#sec:enable_if_lazy">3.3</A>.
The second part of the name indicates whether a true condition argument should
enable or disable the current overload.
The third part of the name indicates whether the condition argument is a <TT>bool</TT> value
(<TT>_c</TT> suffix), or a type containing a static <TT>bool</TT> constant named <TT>value</TT> (no suffix).
The latter version interoperates with Boost.MPL. <BR>
<BR>
The definitions of <TT>enable_if_c</TT> and <TT>enable_if</TT> are as follows (we use <TT>enable_if</TT> templates
unqualified but they are in the <TT>boost</TT> namespace).
<PRE>template &lt;bool B, class T = void&gt;
struct enable_if_c {
typedef T type;
};
template &lt;class T&gt;
struct enable_if_c&lt;false, T&gt; {};
template &lt;class Cond, class T = void&gt;
struct enable_if : public enable_if_c&lt;Cond::value, T&gt; {};
</PRE>
An instantiation of the <TT>enable_if_c</TT> template with the parameter
<TT>B</TT> as <TT>true</TT> contains a member type <TT>type</TT>, defined
to be <TT>T</TT>. If <TT>B</TT> is
<TT>false</TT>, no such member is defined. Thus
<TT>enable_if_c&lt;B, T&gt;::type</TT> is either a valid or an invalid type
expression, depending on the value of <TT>B</TT>.
When valid, <TT>enable_if_c&lt;B, T&gt;::type</TT> equals <TT>T</TT>.
The <TT>enable_if_c</TT> template can thus be used for controlling when functions are considered for
overload resolution and when they are not.
For example, the following function is defined for all arithmetic types (according to the
classification of the <A HREF="http://www.boost.org/libs/type_traits">Boost type_traits library</A>):
<PRE>template &lt;class T&gt;
typename enable_if_c&lt;boost::is_arithmetic&lt;T&gt;::value, T&gt;::type
foo(T t) { return t; }
</PRE>
The <TT>disable_if_c</TT> template is provided as well, and has the
same functionality as <TT>enable_if_c</TT> except for the negated condition. The following
function is enabled for all non-arithmetic types.
<PRE>template &lt;class T&gt;
typename disable_if_c&lt;boost::is_arithmetic&lt;T&gt;::value, T&gt;::type
bar(T t) { return t; }
</PRE>
For easier syntax in some cases and interoperation with Boost.MPL we provide versions of
the <TT>enable_if</TT> templates taking any type with a <TT>bool</TT> member constant named
<TT>value</TT> as the condition argument.
The MPL <TT>bool_</TT>, <TT>and_</TT>, <TT>or_</TT>, and <TT>not_</TT> templates are likely to be
useful for creating such types. Also, the traits classes in the Boost.Type_traits library
follow this convention.
For example, the above example function <TT>foo</TT> can be alternatively written as:
<PRE>template &lt;class T&gt;
typename enable_if&lt;boost::is_arithmetic&lt;T&gt;, T&gt;::type
foo(T t) { return t; }
</PRE>
<!--TOC section Using <TT>enable_if</TT>-->
<H2><A NAME="htoc5">3</A>&nbsp;&nbsp;Using <TT>enable_if</TT></H2><!--SEC END -->
<A NAME="sec:using_enable_if"></A>
The <TT>enable_if</TT> templates are defined in
<TT>boost/utility/enable_if.hpp</TT>, which is included by <TT>boost/utility.hpp</TT>.<BR>
<BR>
The <TT>enable_if</TT> template can be used either as the return type, or as an
extra argument. For example, the <TT>foo</TT> function in the previous section could also be written
as:
<PRE>template &lt;class T&gt;
T foo(T t, typename enable_if&lt;boost::is_arithmetic&lt;T&gt; &gt;::type* dummy = 0);
</PRE>Hence, an extra parameter of type <TT>void*</TT> is added, but it is given
a default value to keep the parameter hidden from client code.
Note that the second template argument was not given to <TT>enable_if</TT>, as the default
<TT>void</TT> gives the desired behavior.<BR>
<BR>
Whether to write the enabler as an argument or within the return type is
largely a matter of taste, but for certain functions, only one
alternative is possible:
<UL><LI>
Operators have a fixed number of arguments, thus <TT>enable_if</TT> must be used in the return type.
<LI>Constructors and destructors do not have a return type; an extra argument is the only option.
<LI>There does not seem to be a way to specify an enabler for a conversion operator. Converting constructors,
however, can have enablers as extra default arguments.
</UL>
<!--TOC subsection Enabling template class specializations-->
<H3><A NAME="htoc6">3.1</A>&nbsp;&nbsp;Enabling template class specializations</H3><!--SEC END -->
<A NAME="sec:enable_if_classes"></A>
Class template specializations can be enabled or disabled with <TT>enable_if</TT>.
One extra template parameter needs to be added for the enabler expressions.
This parameter has the default value <TT>void</TT>.
For example:
<PRE>template &lt;class T, class Enable = void&gt;
class A { ... };
template &lt;class T&gt;
class A&lt;T, typename enable_if&lt;is_integral&lt;T&gt; &gt;::type&gt; { ... };
template &lt;class T&gt;
class A&lt;T, typename enable_if&lt;is_float&lt;T&gt; &gt;::type&gt; { ... };
</PRE>Instantiating <TT>A</TT> with any integral type matches the first specialization,
whereas any floating point type matches the second one. All other types
match the primary template.
The condition can be any compile-time boolean expression that depends on the
template arguments of the class.
Note that again, the second argument to <TT>enable_if</TT> is not needed; the default (<TT>void</TT>)
is the correct value.<BR>
<BR>
<!--TOC subsection Overlapping enabler conditions-->
<H3><A NAME="htoc7">3.2</A>&nbsp;&nbsp;Overlapping enabler conditions</H3><!--SEC END -->
<A NAME="sec:overlapping_conditions"></A>
Once the compiler has examined the enabling conditions and included the
function into the overload resolution set, normal C++ overload resolution
rules are used to select the best matching function.
In particular, there is no ordering between enabling conditions.
Function templates with enabling conditions that are not mutually exclusive can
lead to ambiguities. For example:
<PRE>template &lt;class T&gt;
typename enable_if&lt;boost::is_integral&lt;T&gt;, void&gt;::type
foo(T t) {}
template &lt;class T&gt;
typename enable_if&lt;boost::is_arithmetic&lt;T&gt;, void&gt;::type
foo(T t) {}
</PRE>
All integral types are also arithmetic. Therefore, say, for the call <TT>foo(1)</TT>,
both conditions are true and both functions are thus in the overload resolution set.
They are both equally good matches and thus ambiguous.
Of course, more than one enabling condition can be simultaneously true as long as
other arguments disambiguate the functions.<BR>
<BR>
The above discussion applies to using <TT>enable_if</TT> in class template
partial specializations as well.<BR>
<BR>
<!--TOC subsection Lazy <TT>enable_if</TT>-->
<H3><A NAME="htoc8">3.3</A>&nbsp;&nbsp;Lazy <TT>enable_if</TT></H3><!--SEC END -->
<A NAME="sec:enable_if_lazy"></A>
In some cases it is necessary to avoid instantiating part of a
function signature unless an enabling condition is true. For example:
<PRE>template &lt;class T, class U&gt; class mult_traits;
template &lt;class T, class U&gt;
typename enable_if&lt;is_multipliable&lt;T, U&gt;, typename mult_traits&lt;T, U&gt;::type&gt;::type
operator*(const T&amp; t, const U&amp; u) { ... }
</PRE>Assume the class template <TT>mult_traits</TT> is a traits class defining
the resulting type of a multiplication operator. The <TT>is_multipliable</TT> traits
class specifies for which types to enable the operator. Whenever
<TT>is_multipliable&lt;A, B&gt;::value</TT> is <TT>true</TT> for some types <TT>A</TT> and <TT>B</TT>,
then <TT>mult_traits&lt;A, B&gt;::type</TT> is defined.<BR>
<BR>
Now, trying to invoke (some other overload) of <TT>operator*</TT> with, say, operand types <TT>C</TT> and <TT>D</TT>
for which <TT>is_multipliable&lt;C, D&gt;::value</TT> is <TT>false</TT>
and <TT>mult_traits&lt;C, D&gt;::type</TT> is not defined is an error on some compilers.
The SFINAE principle is not applied because
the invalid type occurs as an argument to another template. The <TT>lazy_enable_if</TT>
and <TT>lazy_disable_if</TT> templates (and their <TT>_c</TT> versions) can be used in such
situations:
<PRE>template&lt;class T, class U&gt;
typename lazy_enable_if&lt;is_multipliable&lt;T, U&gt;, mult_traits&lt;T, U&gt; &gt;::type
operator*(const T&amp; t, const U&amp; u) { ... }
</PRE>The second argument of <TT>lazy_enable_if</TT> must be a class type
that defines a nested type named <TT>type</TT> whenever the first
parameter (the condition) is true.<BR>
<BR>
<!--TOC paragraph Note-->
<H5>Note</H5><!--SEC END -->
Referring to one member type or static constant in a traits class
causes all of the members (type and static constant) of that
specialization to be instantiated. Therefore, if your traits classes
can sometimes contain invalid types, you should use two distinct
templates for describing the conditions and the type mappings. In the
above example, <TT>is_multipliable&lt;T, U&gt;::value</TT> defines when
<TT>mult_traits&lt;T, U&gt;::type</TT> is valid.<BR>
<BR>
<!--TOC subsection Compiler workarounds-->
<H3><A NAME="htoc9">3.4</A>&nbsp;&nbsp;Compiler workarounds</H3><!--SEC END -->
<A NAME="sec:workarounds"></A>
Some compilers flag functions as ambiguous if the only distinguishing factor is a different
condition in an enabler (even though the functions could never be ambiguous). For example,
some compilers (e.g. GCC 3.2) diagnose the following two functions as ambiguous:
<PRE>template &lt;class T&gt;
typename enable_if&lt;boost::is_arithmetic&lt;T&gt;, T&gt;::type
foo(T t);
template &lt;class T&gt;
typename disable_if&lt;boost::is_arithmetic&lt;T&gt;, T&gt;::type
foo(T t);
</PRE>Two workarounds can be applied:
<UL><LI>
Use an extra dummy parameter which disambiguates the functions. Use a default value for
it to hide the parameter from the caller. For example:
<PRE>template &lt;int&gt; struct dummy { dummy(int) {} };
template &lt;class T&gt;
typename enable_if&lt;boost::is_arithmetic&lt;T&gt;, T&gt;::type
foo(T t, dummy&lt;0&gt; = 0);
template &lt;class T&gt;
typename disable_if&lt;boost::is_arithmetic&lt;T&gt;, T&gt;::type
foo(T t, dummy&lt;1&gt; = 0);
</PRE><BR>
<BR>
<LI>Define the functions in different namespaces and bring them into a common
namespace with <TT>using</TT> declarations:
<PRE>namespace A {
template &lt;class T&gt;
typename enable_if&lt;boost::is_arithmetic&lt;T&gt;, T&gt;::type
foo(T t);
}
namespace B {
template &lt;class T&gt;
typename disable_if&lt;boost::is_arithmetic&lt;T&gt;, T&gt;::type
foo(T t);
}
using A::foo;
using B::foo;
</PRE>
Note that the second workaround above cannot be used for member
templates. On the other hand, operators do not accept extra arguments,
which makes the first workaround unusable. As the net effect,
neither of the workarounds are of assistance for templated operators that
need to be defined as member functions (assignment and
subscript operators).
</UL>
<!--TOC section Acknowledgements-->
<H2><A NAME="htoc10">4</A>&nbsp;&nbsp;Acknowledgements</H2><!--SEC END -->
We are grateful to Howard Hinnant, Jason Shirk, Paul Mensonides, and Richard
Smith whose findings have influenced the library.<BR>
<BR>
<!--TOC section References-->
<H2>References</H2><!--SEC END -->
<DL COMPACT=compact><DT><A NAME="jarvi:03:cuj_arbitrary_overloading"><FONT COLOR=purple>[1]</FONT></A><DD>
Jaakko J&auml;rvi, Jeremiah Willcock, Howard Hinnant, and Andrew Lumsdaine.
Function overloading based on arbitrary properties of types.
<EM>C/C++ Users Journal</EM>, 21(6):25--32, June 2003.<BR>
<BR>
<DT><A NAME="jarvi:03:c++typeclasses"><FONT COLOR=purple>[2]</FONT></A><DD>
Jaakko J&auml;rvi, Jeremiah Willcock, and Andrew Lumsdaine.
Concept-controlled polymorphism.
In Frank Pfennig and Yannis Smaragdakis, editors, <EM>Generative
Programming and Component Engineering</EM>, volume 2830 of <EM>LNCS</EM>, pages
228--244. Springer Verlag, September 2003.<BR>
<BR>
<DT><A NAME="vandevoorde2002:templates"><FONT COLOR=purple>[3]</FONT></A><DD>
David Vandevoorde and Nicolai&nbsp;M. Josuttis.
<EM>C++ Templates: The Complete Guide</EM>.
Addison-Wesley, 2002.</DL>
<hr></hr>
<B>Contributed by:</B> <BR>
Jaakko J&auml;rvi, Jeremiah Willcock and Andrew Lumsdaine<BR>
<EM>{jajarvi|jewillco|lums}@osl.iu.edu</EM><BR>
Indiana University<BR>
Open Systems Lab
<!--HTMLFOOT-->
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<HR SIZE=2>
<BLOCKQUOTE><EM>This document was translated from L<sup>A</sup>T<sub>E</sub>X by
</EM><A HREF="http://pauillac.inria.fr/~maranget/hevea/index.html"><EM>H<FONT SIZE=2><sup>E</sup></FONT>V<FONT SIZE=2><sup>E</sup></FONT>A</EM></A><EM>.
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enable_if_constructors.cpp
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// Boost enable_if library
// Copyright 2003 <20> The Trustees of Indiana University.
// Use, modification, and distribution is 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)
// Authors: Jaakko J<>rvi (jajarvi at osl.iu.edu)
// Jeremiah Willcock (jewillco at osl.iu.edu)
// Andrew Lumsdaine (lums at osl.iu.edu)
#include <boost/test/minimal.hpp>
#include <boost/utility/enable_if.hpp>
#include <boost/type_traits.hpp>
using boost::enable_if;
using boost::disable_if;
using boost::is_arithmetic;
struct container {
bool my_value;
template <class T>
container(const T&, const typename enable_if<is_arithmetic<T>, T>::type * = 0):
my_value(true) {}
template <class T>
container(const T&, const typename disable_if<is_arithmetic<T>, T>::type * = 0):
my_value(false) {}
};
// example from Howard Hinnant (tests enable_if template members of a templated class)
template <class charT>
struct xstring
{
template <class It>
xstring(It begin, It end, typename
disable_if<is_arithmetic<It> >::type* = 0)
: data(end-begin) {}
int data;
};
int test_main(int, char*[])
{
BOOST_CHECK(container(1).my_value);
BOOST_CHECK(container(1.0).my_value);
BOOST_CHECK(!container("1").my_value);
BOOST_CHECK(!container(static_cast<void*>(0)).my_value);
char sa[] = "123456";
BOOST_CHECK(xstring<char>(sa, sa+6).data == 6);
return 0;
}

46
enable_if_dummy_arg_disambiguation.cpp
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// Boost enable_if library
// Copyright 2003 <20> The Trustees of Indiana University.
// Use, modification, and distribution is 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)
// Authors: Jaakko J<>rvi (jajarvi at osl.iu.edu)
// Jeremiah Willcock (jewillco at osl.iu.edu)
// Andrew Lumsdaine (lums at osl.iu.edu)
#include <boost/test/minimal.hpp>
#include <boost/utility/enable_if.hpp>
#include <boost/type_traits/is_arithmetic.hpp>
using boost::enable_if;
using boost::disable_if;
using boost::is_arithmetic;
template <int N> struct dummy {
dummy(int) {};
};
template<class T>
typename enable_if<is_arithmetic<T>, bool>::type
arithmetic_object(T t, dummy<0> = 0) { return true; }
template<class T>
typename disable_if<is_arithmetic<T>, bool>::type
arithmetic_object(T t, dummy<1> = 0) { return false; }
int test_main(int, char*[])
{
BOOST_CHECK(arithmetic_object(1));
BOOST_CHECK(arithmetic_object(1.0));
BOOST_CHECK(!arithmetic_object("1"));
BOOST_CHECK(!arithmetic_object(static_cast<void*>(0)));
return 0;
}

82
enable_if_lazy.cpp
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// Boost enable_if library
// Copyright 2003 <20> The Trustees of Indiana University.
// Use, modification, and distribution is 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)
// Authors: Jaakko J<>rvi (jajarvi at osl.iu.edu)
// Jeremiah Willcock (jewillco at osl.iu.edu)
// Andrew Lumsdaine (lums at osl.iu.edu)
#include <boost/test/minimal.hpp>
#include <boost/utility/enable_if.hpp>
#include <boost/type_traits/is_same.hpp>
using boost::enable_if_c;
using boost::lazy_enable_if_c;
// This class provides a reduced example of a traits class for
// computing the result of multiplying two types. The member typedef
// 'type' in this traits class defines the return type of this
// operator. The return type member is invalid unless both arguments
// for mult_traits are values that mult_traits expects (ints in this
// case). This kind of situation may arise if a traits class only
// makes sense for some set of types, not all C++ types.
template <class T> struct is_int {
BOOST_STATIC_CONSTANT(bool, value = (boost::is_same<T, int>::value));
};
template <class T, class U>
struct mult_traits {
typedef typename T::does_not_exist type;
};
template <>
struct mult_traits<int, int> {
typedef int type;
};
// Next, a forwarding function mult() is defined. It is enabled only
// when both arguments are of type int. The first version, using
// non-lazy enable_if_c does not work.
#if 0
template <class T, class U>
typename enable_if_c<
is_int<T>::value && is_int<U>::value,
typename mult_traits<T, U>::type
>::type
mult(const T& x, const U& y) {return x * y;}
#endif
// A correct version uses lazy_enable_if_c.
// This template removes compiler errors from invalid code used as an
// argument to enable_if_c.
#if 1
template <class T, class U>
typename lazy_enable_if_c<
is_int<T>::value && is_int<U>::value,
mult_traits<T, U>
>::type
mult(const T& x, const U& y) {return x * y;}
#endif
double mult(int i, double d) { return (double)i * d; }
int test_main(int, char*[])
{
BOOST_CHECK(mult(1, 2) == 2);
BOOST_CHECK(mult(1, 3.0) == 3.0);
return 0;
}

100
enable_if_lazy_test.cpp
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// Boost enable_if library
// Copyright 2003 <20> The Trustees of Indiana University.
// Use, modification, and distribution is 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)
// Authors: Jaakko J<>rvi (jajarvi at osl.iu.edu)
// Jeremiah Willcock (jewillco at osl.iu.edu)
// Andrew Lumsdaine (lums at osl.iu.edu)
// Testing all variations of lazy_enable_if.
#include <boost/test/minimal.hpp>
#include <boost/mpl/not.hpp>
#include <boost/utility/enable_if.hpp>
#include <boost/type_traits/is_same.hpp>
using boost::lazy_enable_if;
using boost::lazy_disable_if;
using boost::lazy_enable_if_c;
using boost::lazy_disable_if_c;
template <class T>
struct is_int_or_double {
BOOST_STATIC_CONSTANT(bool,
value = (boost::is_same<T, int>::value ||
boost::is_same<T, double>::value));
};
template <class T>
struct some_traits {
typedef typename T::does_not_exist type;
};
template <>
struct some_traits<int> {
typedef bool type;
};
template <>
struct some_traits<double> {
typedef bool type;
};
template <class T>
struct make_bool {
typedef bool type;
};
template <>
struct make_bool<int> {};
template <>
struct make_bool<double> {};
namespace A {
template<class T>
typename lazy_enable_if<is_int_or_double<T>, some_traits<T> >::type
foo(T t) { return true; }
template<class T>
typename lazy_enable_if_c<is_int_or_double<T>::value, some_traits<T> >::type
foo2(T t) { return true; }
}
namespace B {
template<class T>
typename lazy_disable_if<is_int_or_double<T>, make_bool<T> >::type
foo(T t) { return false; }
template<class T>
typename lazy_disable_if_c<is_int_or_double<T>::value, make_bool<T> >::type
foo2(T t) { return false; }
}
int test_main(int, char*[])
{
using namespace A;
using namespace B;
BOOST_CHECK(foo(1));
BOOST_CHECK(foo(1.0));
BOOST_CHECK(!foo("1"));
BOOST_CHECK(!foo(static_cast<void*>(0)));
BOOST_CHECK(foo2(1));
BOOST_CHECK(foo2(1.0));
BOOST_CHECK(!foo2("1"));
BOOST_CHECK(!foo2(static_cast<void*>(0)));
return 0;
}

43
enable_if_member_templates.cpp
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// Boost enable_if library
// Copyright 2003 <20> The Trustees of Indiana University.
// Use, modification, and distribution is 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)
// Authors: Jaakko J<>rvi (jajarvi at osl.iu.edu)
// Jeremiah Willcock (jewillco at osl.iu.edu)
// Andrew Lumsdaine (lums at osl.iu.edu)
#include <boost/test/minimal.hpp>
#include <boost/utility/enable_if.hpp>
#include <boost/type_traits/is_arithmetic.hpp>
using boost::enable_if;
using boost::disable_if;
using boost::is_arithmetic;
struct container {
template <class T>
typename enable_if<is_arithmetic<T>, bool>::type
arithmetic_object(const T&, const int* /* disambiguate */ = 0) {return true;}
template <class T>
typename disable_if<is_arithmetic<T>, bool>::type
arithmetic_object(const T&) {return false;}
};
int test_main(int, char*[])
{
BOOST_CHECK(container().arithmetic_object(1));
BOOST_CHECK(container().arithmetic_object(1.0));
BOOST_CHECK(!container().arithmetic_object("1"));
BOOST_CHECK(!container().arithmetic_object(static_cast<void*>(0)));
return 0;
}

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enable_if_namespace_disambiguation.cpp
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// Boost enable_if library
// Copyright 2003 <20> The Trustees of Indiana University.
// Use, modification, and distribution is 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)
// Authors: Jaakko J<>rvi (jajarvi at osl.iu.edu)
// Jeremiah Willcock (jewillco at osl.iu.edu)
// Andrew Lumsdaine (lums at osl.iu.edu)
#include <boost/test/minimal.hpp>
#include <boost/mpl/not.hpp>
#include <boost/utility/enable_if.hpp>
#include <boost/type_traits/is_arithmetic.hpp>
using boost::enable_if;
using boost::mpl::not_;
using boost::is_arithmetic;
namespace A {
template<class T>
typename enable_if<is_arithmetic<T>, bool>::type
arithmetic_object(T t) { return true; }
}
namespace B {
template<class T>
typename enable_if<not_<is_arithmetic<T> >, bool>::type
arithmetic_object(T t) { return false; }
}
int test_main(int, char*[])
{
using namespace A;
using namespace B;
BOOST_CHECK(arithmetic_object(1));
BOOST_CHECK(arithmetic_object(1.0));
BOOST_CHECK(!arithmetic_object("1"));
BOOST_CHECK(!arithmetic_object(static_cast<void*>(0)));
return 0;
}

43
enable_if_no_disambiguation.cpp
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// Boost enable_if library
// Copyright 2003 <20> The Trustees of Indiana University.
// Use, modification, and distribution is 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)
// Authors: Jaakko J<>rvi (jajarvi at osl.iu.edu)
// Jeremiah Willcock (jewillco at osl.iu.edu)
// Andrew Lumsdaine (lums at osl.iu.edu)
#include <boost/test/minimal.hpp>
#include <boost/mpl/not.hpp>
#include <boost/utility/enable_if.hpp>
#include <boost/type_traits/is_arithmetic.hpp>
using boost::mpl::not_;
using boost::enable_if;
using boost::is_arithmetic;
template<class T>
typename enable_if<is_arithmetic<T>, bool>::type
arithmetic_object(T t) { return true; }
template<class T>
typename enable_if<not_<is_arithmetic<T> >, bool>::type
arithmetic_object(T t) { return false; }
int test_main(int, char*[])
{
BOOST_CHECK(arithmetic_object(1));
BOOST_CHECK(arithmetic_object(1.0));
BOOST_CHECK(!arithmetic_object("1"));
BOOST_CHECK(!arithmetic_object(static_cast<void*>(0)));
return 0;
}

67
enable_if_partial_specializations.cpp
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// Boost enable_if library
// Copyright 2003 <20> The Trustees of Indiana University.
// Use, modification, and distribution is 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)
// Authors: Jaakko J<>rvi (jajarvi at osl.iu.edu)
// Jeremiah Willcock (jewillco at osl.iu.edu)
// Andrew Lumsdaine (lums at osl.iu.edu)
#include <boost/test/minimal.hpp>
#include <boost/utility/enable_if.hpp>
#include <boost/type_traits/is_arithmetic.hpp>
using boost::enable_if_c;
using boost::disable_if_c;
using boost::enable_if;
using boost::disable_if;
using boost::is_arithmetic;
template <class T, class Enable = void>
struct tester;
template <class T>
struct tester<T, typename enable_if_c<is_arithmetic<T>::value>::type> {
BOOST_STATIC_CONSTANT(bool, value = true);
};
template <class T>
struct tester<T, typename disable_if_c<is_arithmetic<T>::value>::type> {
BOOST_STATIC_CONSTANT(bool, value = false);
};
template <class T, class Enable = void>
struct tester2;
template <class T>
struct tester2<T, typename enable_if<is_arithmetic<T> >::type> {
BOOST_STATIC_CONSTANT(bool, value = true);
};
template <class T>
struct tester2<T, typename disable_if<is_arithmetic<T> >::type> {
BOOST_STATIC_CONSTANT(bool, value = false);
};
int test_main(int, char*[])
{
BOOST_CHECK(tester<int>::value);
BOOST_CHECK(tester<double>::value);
BOOST_CHECK(!tester<char*>::value);
BOOST_CHECK(!tester<void*>::value);
BOOST_CHECK(tester2<int>::value);
BOOST_CHECK(tester2<double>::value);
BOOST_CHECK(!tester2<char*>::value);
BOOST_CHECK(!tester2<void*>::value);
return 0;
}

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filter_iterator_example.cpp
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// Example of using the filter iterator adaptor from
// boost/iterator_adaptors.hpp.
// (C) Copyright Jeremy Siek 1999. Permission to copy, use, modify,
// sell and distribute this software is granted provided this
// copyright notice appears in all copies. This software is provided
// "as is" without express or implied warranty, and with no claim as
// to its suitability for any purpose.
#include <boost/config.hpp>
#include <algorithm>
#include <functional>
#include <iostream>
#include <boost/iterator/filter_iterator.hpp>
struct is_positive_number {
bool operator()(int x) { return 0 < x; }
};
int main()
{
int numbers_[] = { 0, -1, 4, -3, 5, 8, -2 };
const int N = sizeof(numbers_)/sizeof(int);
typedef int* base_iterator;
base_iterator numbers(numbers_);
// Example using make_filter_iterator()
std::copy(boost::make_filter_iterator<is_positive_number>(numbers, numbers + N),
boost::make_filter_iterator<is_positive_number>(numbers + N, numbers + N),
std::ostream_iterator<int>(std::cout, " "));
std::cout << std::endl;
// Example using filter_iterator
typedef boost::filter_iterator<is_positive_number, base_iterator>
FilterIter;
is_positive_number predicate;
FilterIter filter_iter_first(predicate, numbers, numbers + N);
FilterIter filter_iter_last(predicate, numbers + N, numbers + N);
std::copy(filter_iter_first, filter_iter_last, std::ostream_iterator<int>(std::cout, " "));
std::cout << std::endl;
// Another example using make_filter_iterator()
std::copy(
boost::make_filter_iterator(
std::bind2nd(std::greater<int>(), -2)
, numbers, numbers + N)
, boost::make_filter_iterator(
std::bind2nd(std::greater<int>(), -2)
, numbers + N, numbers + N)
, std::ostream_iterator<int>(std::cout, " ")
);
std::cout << std::endl;
return 0;
}

47
fun_out_iter_example.cpp
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// (C) Copyright Jeremy Siek 2001. Permission to copy, use, modify,
// sell and distribute this software is granted provided this
// copyright notice appears in all copies. This software is provided
// "as is" without express or implied warranty, and with no claim as
// to its suitability for any purpose.
// Revision History:
// 27 Feb 2001 Jeremy Siek
// Initial checkin.
#include <iostream>
#include <string>
#include <vector>
#include <boost/function_output_iterator.hpp>
struct string_appender
{
string_appender(std::string& s)
: m_str(&s)
{}
void operator()(const std::string& x) const
{
*m_str += x;
}
std::string* m_str;
};
int main(int, char*[])
{
std::vector<std::string> x;
x.push_back("hello");
x.push_back(" ");
x.push_back("world");
x.push_back("!");
std::string s = "";
std::copy(x.begin(), x.end(),
boost::make_function_output_iterator(string_appender(s)));
std::cout << s << std::endl;
return 0;
}

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generator_iterator.htm
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<!DOCTYPE html PUBLIC "-//W3C//DTD HTML 3.2//EN">
<html>
<head>
<title>Generator Iterator Adaptor Documentation</title>
</head>
<body bgcolor="#FFFFFF" text="#000000">
<img src="../../c++boost.gif" alt="c++boost.gif (8819 bytes)" align="center" width="277" height="86">
<h1>Generator Iterator Adaptor</h1>
Defined in header <a href="../../boost/generator_iterator.hpp">boost/generator_iterator.hpp</a>
<p>
The generator iterator adaptor makes it easier to create custom input
iterators from 0-ary functions and function objects. The adaptor
takes a
<a href="http://www.sgi.com/tech/stl/Generator.html">Generator</a>
and creates a model of
<a href="http://www.sgi.com/tech/stl/InputIterator.html">Input Iterator</a>.
Each increment retrieves an item from the generator and makes it
available to be retrieved by dereferencing. The motivation for this
iterator is that some concepts can be more naturally expressed as a
generator, while most STL algorithms expect an iterator. An example
is the <a href="../random/index.html">Random Number</a> library.
<h2>Synopsis</h2>
<blockquote>
<pre>
namespace boost {
template &lt;class Generator&gt;
class generator_iterator_policies;
template &lt;class Generator&gt;
class generator_iterator_generator;
template &lt;class Generator&gt;
typename generator_iterator_generator&lt;Generator&gt;::type
make_generator_iterator(Generator &amp; gen);
}
</pre>
</blockquote>
<hr>
<h2>The Generator Iterator Generator Class</h2>
The class generator_iterator_generator is a helper class whose purpose
is to construct a generator iterator type. The template parameter for
this class is the Generator function object type that is being
wrapped. The generator iterator adaptor only holds a reference (or
pointer) to the function object, therefore the function object must
outlive the generator iterator adaptor constructed from it.
<pre>
template &lt;class Generator>
class generator_iterator_generator
{
public:
typedef <a href="iterator_adaptors.htm#iterator_adaptor">iterator_adaptor</a>&lt...&gt; type; // the resulting generator iterator type
}
</pre>
<h3>Template Parameters</h3>
<table border>
<tr>
<th>Parameter</th>
<th>Description</th>
</tr>
<tr>
<td><tt><a href="http://www.sgi.com/tech/stl/Generator.html">Generator</a></tt>
<td>The generator (0-ary function object) type being
wrapped. The return type of the function must be defined as
<tt>Generator::result_type</tt>. The function object must be a model
of
<a href="http://www.sgi.com/tech/stl/Generator.html">Generator</a>.
</td>
</table>
<h3>Concept Model</h3>
The generator iterator class is a model of
<a href="http://www.sgi.com/tech/stl/InputIterator.html">Input Iterator</a>.
<h3>Members</h3>
The generator iterator implements the member functions
and operators required of the
<a href="http://www.sgi.com/tech/stl/InputIterator.html">Input Iterator</a>
concept.
<br>
<hr>
<h2><a name="make_generator_iterator">The Generator Iterator Object Generator</a></h2>
The <tt>make_generator_iterator()</tt> function provides a
convenient way to create generator iterator objects. The function
saves the user the trouble of explicitly writing out the iterator
types.
<blockquote>
<pre>
template &lt;class Generator&gt;
typename generator_iterator_generator&lt;Generator&gt;::type
make_generator_iterator(Generator &amp; gen);
</pre>
</blockquote>
<hr>
<h3>Example</h3>
The following program shows how <code>generator_iterator</code>
transforms a generator into an input iterator.
<blockquote>
<pre>
#include &lt;iostream>
#include &lt;boost/generator_iterator.hpp>
class my_generator
{
public:
typedef int result_type;
my_generator() : state(0) { }
int operator()() { return ++state; }
private:
int state;
};
int main()
{
my_generator gen;
boost::generator_iterator_generator&lt;my_generator&gt;::type it = boost::make_generator_iterator(gen);
for(int i = 0; i &lt; 10; ++i, ++it)
std::cout &lt;&lt; *it &lt;&lt; std::endl;
}
</pre>
</blockquote>
<hr>
Written by Jens Maurer.
</body>
</html>

366
half_open_range_test.cpp
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// (C) Copyright David Abrahams 2001. Permission to copy, use, modify, sell and
// distribute this software is granted provided this copyright notice appears in
// all copies. This software is provided "as is" without express or implied
// warranty, and with no claim as to its suitability for any purpose.
//
// See http://www.boost.org for most recent version including documentation.
//
// Revision History
// 11 Feb 2001 Compile with Borland, re-enable failing tests (David Abrahams)
// 29 Jan 2001 Initial revision (David Abrahams)
#include <boost/half_open_range.hpp>
#include <boost/utility.hpp>
#include <iterator>
#include <stdlib.h>
#include <vector>
#include <list>
#include <cassert>
#include <stdexcept>
#ifndef BOOST_NO_LIMITS
# include <limits>
#endif
#ifndef BOOST_NO_SLIST
# include <slist>
#endif
inline unsigned unsigned_random(unsigned max)
{
return (max > 0) ? (unsigned)rand() % max : 0;
}
// Special tests for ranges supporting random access
template <class T>
void category_test_1(
const boost::half_open_range<T>& r, std::random_access_iterator_tag)
{
typedef boost::half_open_range<T> range;
typedef typename range::size_type size_type;
size_type size = r.size();
// pick a random offset
size_type offset = unsigned_random(size);
typename range::value_type x = *(r.begin() + offset);
// test contains(value_type)
assert(r.contains(r.start()) == !r.empty());
assert(!r.contains(r.finish()));
assert(r.contains(x) == (offset != size));
range::const_iterator p = r.find(x);
assert((p == r.end()) == (x == r.finish()));
assert(r.find(r.finish()) == r.end());
if (offset != size)
{
assert(x == r[offset]);
assert(x == r.at(offset));
}
bool caught_out_of_range = false;
try {
bool never_initialized = x == r.at(size);
(void)never_initialized;
}
catch(std::out_of_range&)
{
caught_out_of_range = true;
}
catch(...)
{
}
assert(caught_out_of_range);
}
// Those tests must be skipped for other ranges
template <class T>
void category_test_1(
const boost::half_open_range<T>&, std::forward_iterator_tag)
{
}
unsigned indices[][2] = { {0,0},{0,1},{0,2},{0,3},
{1,1},{1,2},{1,3},
{2,2},{2,3},
{3,3}};
template <class Range>
void category_test_2(
const std::vector<Range>& ranges, unsigned i, unsigned j, std::random_access_iterator_tag)
{
typedef Range range;
const range& ri = ranges[i];
const range& rj = ranges[j];
if (indices[i][0] <= indices[j][0] && indices[i][1] >= indices[j][1])
assert(ri.contains(rj));
if (ri.contains(rj))
assert((ri & rj) == rj);
assert(boost::intersects(ri, rj) == !(ri & rj).empty());
range t1(ri);
t1 &= rj;
assert(t1 == range(indices[i][0] > indices[j][0] ? ri.start() : rj.start(),
indices[i][1] < indices[j][1] ? ri.finish() : rj.finish()));
assert(t1 == (ri & rj));
range t2(ri);
t2 |= rj;
if (ri.empty())
assert(t2 == rj);
else if (rj.empty())
assert(t2 == ri);
else
assert(t2 == range(indices[i][0] < indices[j][0] ? ri.start() : rj.start(),
indices[i][1] > indices[j][1] ? ri.finish() : rj.finish()));
assert(t2 == (ri | rj));
if (i == j)
assert(ri == rj);
if (ri.empty() || rj.empty())
assert((ri == rj) == (ri.empty() && rj.empty()));
else
assert((ri == rj) == (ri.start() == rj.start() && ri.finish() == rj.finish()));
assert((ri == rj) == !(ri != rj));
bool same = ri == rj;
bool one_empty = ri.empty() != rj.empty();
std::less<range> less;
std::less_equal<range> less_equal;
std::greater<range> greater;
std::greater_equal<range> greater_equal;
if (same)
{
assert(greater_equal(ri,rj));
assert(less_equal(ri,rj));
assert(!greater(ri,rj));
assert(!less(ri,rj));
}
else if (one_empty)
{
const range& empty = ri.empty() ? ri : rj;
const range& non_empty = rj.empty() ? ri : rj;
assert(less(empty,non_empty));
assert(less_equal(empty,non_empty));
assert(!greater(empty,non_empty));
assert(!greater_equal(empty,non_empty));
assert(!less(non_empty,empty));
assert(!less_equal(non_empty,empty));
assert(greater(non_empty,empty));
assert(greater_equal(non_empty,empty));
}
else {
if (indices[i][0] < indices[j][0] ||
indices[i][0] == indices[j][0] && indices[i][1] < indices[j][1])
{
assert(!greater_equal(ri,rj));
assert(less(ri,rj));
}
if (indices[i][0] < indices[j][0] ||
indices[i][0] == indices[j][0] && indices[i][1] <= indices[j][1])
{
assert(!greater(ri,rj));
assert(less_equal(ri,rj));
}
if (indices[i][0] > indices[j][0] ||
indices[i][0] == indices[j][0] && indices[i][1] > indices[j][1])
{
assert(!less_equal(ri,rj));
assert(greater(ri,rj));
}
if (indices[i][0] > indices[j][0] ||
indices[i][0] == indices[j][0] && indices[i][1] >= indices[j][1])
{
assert(!less(ri,rj));
assert(greater_equal(ri,rj));
}
}
}
template <class Range>
void category_test_2(
const std::vector<Range>&, unsigned, unsigned, std::forward_iterator_tag)
{
}
template <class T>
void category_test_2(
const std::vector<boost::half_open_range<T> >&, unsigned, unsigned, std::bidirectional_iterator_tag)
{
}
template <class Range>
void test_back(Range& x, std::bidirectional_iterator_tag)
{
assert(x.back() == boost::prior(x.finish()));
}
template <class Range>
void test_back(Range& x, std::forward_iterator_tag)
{
}
template <class T>
boost::half_open_range<T> range_identity(const boost::half_open_range<T>& x)
{
return x;
}
template <class T>
void test(T x0, T x1, T x2, T x3)
{
std::vector<boost::half_open_range<T> > ranges;
typedef boost::half_open_range<T> range;
T bounds[4] = { x0, x1, x2, x3 };
const std::size_t num_ranges = sizeof(indices)/sizeof(*indices);
// test construction
for (std::size_t n = 0; n < num_ranges;++n)
{
T start = bounds[indices[n][0]];
T finish = bounds[indices[n][1]];
boost::half_open_range<T> r(start, finish);
ranges.push_back(r);
}
// test implicit conversion from std::pair<T,T>
range converted = std::pair<T,T>(x0,x0);
(void)converted;
// test assignment, equality and inequality
range r00 = range(x0, x0);
assert(r00 == range(x0,x0));
assert(r00 == range(x1,x1)); // empty ranges are all equal
if (x3 != x0)
assert(r00 != range(x0, x3));
r00 = range(x0, x3);
assert(r00 == range(x0, x3));
if (x3 != x0)
assert(r00 != range(x0, x0));
typedef typename range::iterator iterator;
typedef typename iterator::iterator_category category;
for (unsigned i = 0; i < num_ranges; ++i)
{
const range& r = ranges[i];
// test begin(), end(), basic iteration.
unsigned count = 0;
for (range::const_iterator p = r.begin(), finish = r.end();
p != finish;
++p, ++count)
{
assert(count < 2100);
}
// test size(), empty(), front(), back()
assert((unsigned)r.size() == count);
if (indices[i][0] == indices[i][1])
assert(r.empty());
if (r.empty())
assert(r.size() == 0);
if (!r.empty())
{
assert(r.front() == r.start());
test_back(r, category());
}
// test swap
range r1(r);
range r2(x0,x3);
const bool same = r1 == r2;
r1.swap(r2);
assert(r1 == range(x0,x3));
assert(r2 == r);
if (!same) {
assert(r1 != r);
assert(r2 != range(x0,x3));
}
// do individual tests for random-access iterators
category_test_1(r, category());
}
for (unsigned j = 0; j < num_ranges; ++j) {
for (unsigned k = 0; k < num_ranges; ++k) {
category_test_2(ranges, j, k, category());
}
}
}
template <class Integer>
void test_integer(Integer* = 0) // default arg works around MSVC bug
{
Integer a = 0;
Integer b = a + unsigned_random(128 - a);
Integer c = b + unsigned_random(128 - b);
Integer d = c + unsigned_random(128 - c);
test(a, b, c, d);
}
template <class Container>
void test_container(Container* = 0) // default arg works around MSVC bug
{
Container c(unsigned_random(1673));
const typename Container::size_type offset1 = unsigned_random(c.size());
const typename Container::size_type offset2 = unsigned_random(c.size() - offset1);
typename Container::iterator internal1 = c.begin();
std::advance(internal1, offset1);
typename Container::iterator internal2 = internal1;
std::advance(internal2, offset2);
test(c.begin(), internal1, internal2, c.end());
typedef typename Container::const_iterator const_iterator;
test(const_iterator(c.begin()),
const_iterator(internal1),
const_iterator(internal2),
const_iterator(c.end()));
}
int main()
{
// Test the built-in integer types.
test_integer<char>();
test_integer<unsigned char>();
test_integer<signed char>();
test_integer<wchar_t>();
test_integer<short>();
test_integer<unsigned short>();
test_integer<int>();
test_integer<unsigned int>();
test_integer<long>();
test_integer<unsigned long>();
#if defined(BOOST_HAS_LONG_LONG)
test_integer<long long>();
test_integer<unsigned long long>();
#endif
// Some tests on container iterators, to prove we handle a few different categories
test_container<std::vector<int> >();
test_container<std::list<int> >();
#ifndef BOOST_NO_SLIST
test_container<BOOST_STD_EXTENSION_NAMESPACE::slist<int> >();
#endif
// Also prove that we can handle raw pointers.
int array[2000];
const std::size_t a = 0;
const std::size_t b = a + unsigned_random(2000 - a);
const std::size_t c = b + unsigned_random(2000 - b);
test(array, array+b, array+c, array+2000);
return 0;
}

34
index.html
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@ -1,34 +0,0 @@
<html>
<head>
<meta http-equiv="Content-Language" content="en-us">
<meta name="GENERATOR" content="Microsoft FrontPage 5.0">
<meta name="ProgId" content="FrontPage.Editor.Document">
<meta http-equiv="Content-Type" content="text/html; charset=windows-1252">
<title>Boost Utility Library</title>
</head>
<body bgcolor="#FFFFFF">
<h1><IMG SRC="../../c++boost.gif" WIDTH="276" HEIGHT="86" align="center">Boost
Utility Library</h1>
<p>The Boost Utility Library isn't really a single library at all. It is just a
collection for components too small to be called libraries in their own right.</p>
<p>But that doesn't mean there isn't useful stuff here. Take a look:</p>
<blockquote>
<p>
<a href="assert.html">assert</a><br>
<a href="base_from_member.html">base_from_member</a><br>
<a href="call_traits.htm">call_traits</a><br>
<a href="checked_delete.html">checked_delete</a><br>
<a href="compressed_pair.htm">compressed_pair</a><br>
<a href="enable_if.html">enable_if</a><br>
<a href="iterator_adaptors.htm">iterator_adaptors</a><br>
<a href="operators.htm">operators</a><br>
<a href="throw_exception.html">throw_exception</a><br>
<a href="utility.htm">utility</a><br>
<a href="value_init.htm">value_init</a></p>
</blockquote>
<hr>
<p>Revised
<!--webbot bot="Timestamp" S-Type="EDITED" S-Format="%d %B, %Y" startspan -->01 September, 2003<!--webbot bot="Timestamp" endspan i-checksum="38582" --></p>
<p>&nbsp;</p>
</body>
</html>

59
indirect_iterator_example.cpp
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// (C) Copyright Jeremy Siek 2000. Permission to copy, use, modify, sell and
// distribute this software is granted provided this copyright notice appears
// in all copies. This software is provided "as is" without express or implied
// warranty, and with no claim as to its suitability for any purpose.
#include <boost/config.hpp>
#include <vector>
#include <iostream>
#include <iterator>
#include <functional>
#include <algorithm>
#include <boost/iterator/indirect_iterator.hpp>
int main(int, char*[])
{
char characters[] = "abcdefg";
const int N = sizeof(characters)/sizeof(char) - 1; // -1 since characters has a null char
char* pointers_to_chars[N]; // at the end.
for (int i = 0; i < N; ++i)
pointers_to_chars[i] = &characters[i];
// Example of using indirect_iterator_generator
boost::indirect_iterator<char**, char>
indirect_first(pointers_to_chars), indirect_last(pointers_to_chars + N);
std::copy(indirect_first, indirect_last, std::ostream_iterator<char>(std::cout, ","));
std::cout << std::endl;
// Example of using indirect_iterator_pair_generator
char mutable_characters[N];
char* pointers_to_mutable_chars[N];
for (int j = 0; j < N; ++j)
pointers_to_mutable_chars[j] = &mutable_characters[j];
boost::indirect_iterator<char* const*> mutable_indirect_first(pointers_to_mutable_chars),
mutable_indirect_last(pointers_to_mutable_chars + N);
boost::indirect_iterator<char* const*, char const> const_indirect_first(pointers_to_chars),
const_indirect_last(pointers_to_chars + N);
std::transform(const_indirect_first, const_indirect_last,
mutable_indirect_first, std::bind1st(std::plus<char>(), 1));
std::copy(mutable_indirect_first, mutable_indirect_last,
std::ostream_iterator<char>(std::cout, ","));
std::cout << std::endl;
// Example of using make_indirect_iterator()
std::copy(boost::make_indirect_iterator(pointers_to_chars),
boost::make_indirect_iterator(pointers_to_chars + N),
std::ostream_iterator<char>(std::cout, ","));
std::cout << std::endl;
return 0;
}

46
iterator_adaptor_examples.cpp
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@ -1,46 +0,0 @@
// (C) Copyright Jeremy Siek 2000. Permission to copy, use, modify, sell and
// distribute this software is granted provided this copyright notice appears
// in all copies. This software is provided "as is" without express or implied
// warranty, and with no claim as to its suitability for any purpose.
#include <functional>
#include <algorithm>
#include <iostream>
#include <boost/iterator/transform_iterator.hpp>
#include <boost/pending/integer_range.hpp>
int
main(int, char*[])
{
// This is a simple example of using the transform_iterators class to
// generate iterators that multiply the value returned by dereferencing
// the iterator. In this case we are multiplying by 2.
// Would be cooler to use lambda library in this example.
int x[] = { 1, 2, 3, 4, 5, 6, 7, 8 };
typedef std::binder1st< std::multiplies<int> > Function;
typedef boost::transform_iterator<Function, int*> doubling_iterator;
doubling_iterator i(x, std::bind1st(std::multiplies<int>(), 2)),
i_end(x + sizeof(x)/sizeof(int), std::bind1st(std::multiplies<int>(), 2));
std::cout << "multiplying the array by 2:" << std::endl;
while (i != i_end)
std::cout << *i++ << " ";
std::cout << std::endl;
// Here is an example of counting from 0 to 5 using the integer_range class.
boost::integer_range<int> r(0,5);
std::cout << "counting to from 0 to 4:" << std::endl;
std::copy(r.begin(), r.end(), std::ostream_iterator<int>(std::cout, " "));
std::cout << std::endl;
return 0;
}

215
iterator_traits_test.cpp
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@ -1,215 +0,0 @@
// (C) Copyright David Abrahams 2002. Permission to copy, use, modify,
// sell and distribute this software is granted provided this
// copyright notice appears in all copies. This software is provided
// "as is" without express or implied warranty, and with no claim as
// to its suitability for any purpose.
// See http://www.boost.org for most recent version including documentation.
// Revision History
// 04 Mar 2001 Patches for Intel C++ (Dave Abrahams)
// 19 Feb 2001 Take advantage of improved iterator_traits to do more tests
// on MSVC. Reordered some #ifdefs for coherency.
// (David Abrahams)
// 13 Feb 2001 Test new VC6 workarounds (David Abrahams)
// 11 Feb 2001 Final fixes for Borland (David Abrahams)
// 11 Feb 2001 Some fixes for Borland get it closer on that compiler
// (David Abrahams)
// 07 Feb 2001 More comprehensive testing; factored out static tests for
// better reuse (David Abrahams)
// 21 Jan 2001 Quick fix to my_iterator, which wasn't returning a
// reference type from operator* (David Abrahams)
// 19 Jan 2001 Initial version with iterator operators (David Abrahams)
#include <boost/detail/iterator.hpp>
#include <boost/type_traits/is_same.hpp>
#include <boost/operators.hpp>
#include <boost/static_assert.hpp>
#include <iterator>
#include <vector>
#include <list>
#include <cassert>
#include <iostream>
// A UDT for which we can specialize std::iterator_traits<element*> on
// compilers which don't support partial specialization. There's no
// other reasonable way to test pointers on those compilers.
struct element {};
// An iterator for which we can get traits.
struct my_iterator1
: boost::forward_iterator_helper<my_iterator1, char, long, const char*, const char&>
{
my_iterator1(const char* p) : m_p(p) {}
bool operator==(const my_iterator1& rhs) const
{ return this->m_p == rhs.m_p; }
my_iterator1& operator++() { ++this->m_p; return *this; }
const char& operator*() { return *m_p; }
private:
const char* m_p;
};
// Used to prove that we don't require std::iterator<> in the hierarchy under
// MSVC6, and that we can compute all the traits for a standard-conforming UDT
// iterator.
struct my_iterator2
: boost::equality_comparable<my_iterator2
, boost::incrementable<my_iterator2
, boost::dereferenceable<my_iterator2,const char*> > >
{
typedef char value_type;
typedef long difference_type;
typedef const char* pointer;
typedef const char& reference;
typedef std::forward_iterator_tag iterator_category;
my_iterator2(const char* p) : m_p(p) {}
bool operator==(const my_iterator2& rhs) const
{ return this->m_p == rhs.m_p; }
my_iterator2& operator++() { ++this->m_p; return *this; }
const char& operator*() { return *m_p; }
private:
const char* m_p;
};
// Used to prove that we're not overly confused by the existence of
// std::iterator<> in the hierarchy under MSVC6 - we should find that
// boost::detail::iterator_traits<my_iterator3>::difference_type is int.
struct my_iterator3 : my_iterator1
{
typedef int difference_type;
my_iterator3(const char* p)
: my_iterator1(p) {}
};
//
// Assertion tools. Used instead of BOOST_STATIC_ASSERT because that
// doesn't give us a nice stack backtrace
//
template <bool = false> struct assertion;
template <> struct assertion<true>
{
typedef char type;
};
template <class T, class U>
struct assert_same
: assertion<(::boost::is_same<T,U>::value)>
{
};
// Iterator tests
template <class Iterator,
class value_type, class difference_type, class pointer, class reference, class category>
struct non_portable_tests
{
typedef typename boost::detail::iterator_traits<Iterator>::pointer test_pt;
typedef typename boost::detail::iterator_traits<Iterator>::reference test_rt;
typedef typename assert_same<test_pt, pointer>::type a1;
typedef typename assert_same<test_rt, reference>::type a2;
};
template <class Iterator,
class value_type, class difference_type, class pointer, class reference, class category>
struct portable_tests
{
typedef typename boost::detail::iterator_traits<Iterator>::difference_type test_dt;
typedef typename boost::detail::iterator_traits<Iterator>::iterator_category test_cat;
typedef typename assert_same<test_dt, difference_type>::type a1;
typedef typename assert_same<test_cat, category>::type a2;
};
// Test iterator_traits
template <class Iterator,
class value_type, class difference_type, class pointer, class reference, class category>
struct input_iterator_test
: portable_tests<Iterator,value_type,difference_type,pointer,reference,category>
{
typedef typename boost::detail::iterator_traits<Iterator>::value_type test_vt;
typedef typename assert_same<test_vt, value_type>::type a1;
};
template <class Iterator,
class value_type, class difference_type, class pointer, class reference, class category>
struct non_pointer_test
: input_iterator_test<Iterator,value_type,difference_type,pointer,reference,category>
, non_portable_tests<Iterator,value_type,difference_type,pointer,reference,category>
{
};
template <class Iterator,
class value_type, class difference_type, class pointer, class reference, class category>
struct maybe_pointer_test
: portable_tests<Iterator,value_type,difference_type,pointer,reference,category>
, non_portable_tests<Iterator,value_type,difference_type,pointer,reference,category>
{
};
input_iterator_test<std::istream_iterator<int>, int, std::ptrdiff_t, int*, int&, std::input_iterator_tag>
istream_iterator_test;
#if defined(__BORLANDC__) && !defined(__SGI_STL_PORT)
typedef ::std::char_traits<char>::off_type distance;
non_pointer_test<std::ostream_iterator<int>,int,
distance,int*,int&,std::output_iterator_tag> ostream_iterator_test;
#elif defined(BOOST_MSVC_STD_ITERATOR)
non_pointer_test<std::ostream_iterator<int>,
int, void, int*, int&, std::output_iterator_tag>
ostream_iterator_test;
#else
non_pointer_test<std::ostream_iterator<int>,
void, void, void, void, std::output_iterator_tag>
ostream_iterator_test;
#endif
#ifdef __KCC
typedef long std_list_diff_type;
#else
typedef std::ptrdiff_t std_list_diff_type;
#endif
non_pointer_test<std::list<int>::iterator, int, std_list_diff_type, int*, int&, std::bidirectional_iterator_tag>
list_iterator_test;
maybe_pointer_test<std::vector<int>::iterator, int, std::ptrdiff_t, int*, int&, std::random_access_iterator_tag>
vector_iterator_test;
maybe_pointer_test<int*, int, std::ptrdiff_t, int*, int&, std::random_access_iterator_tag>
int_pointer_test;
non_pointer_test<my_iterator1, char, long, const char*, const char&, std::forward_iterator_tag>
my_iterator1_test;
non_pointer_test<my_iterator2, char, long, const char*, const char&, std::forward_iterator_tag>
my_iterator2_test;
non_pointer_test<my_iterator3, char, int, const char*, const char&, std::forward_iterator_tag>
my_iterator3_test;
int main()
{
char chars[100];
int ints[100];
for (int length = 3; length < 100; length += length / 3)
{
std::list<int> l(length);
assert(boost::detail::distance(l.begin(), l.end()) == length);
std::vector<int> v(length);
assert(boost::detail::distance(v.begin(), v.end()) == length);
assert(boost::detail::distance(&ints[0], ints + length) == length);
assert(boost::detail::distance(my_iterator1(chars), my_iterator1(chars + length)) == length);
assert(boost::detail::distance(my_iterator2(chars), my_iterator2(chars + length)) == length);
assert(boost::detail::distance(my_iterator3(chars), my_iterator3(chars + length)) == length);
}
return 0;
}

325
iterators_test.cpp
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// Demonstrate and test boost/operators.hpp on std::iterators --------------//
// (C) Copyright Jeremy Siek 1999. Permission to copy, use, modify,
// sell and distribute this software is granted provided this
// copyright notice appears in all copies. This software is provided
// "as is" without express or implied warranty, and with no claim as
// to its suitability for any purpose.
// See http://www.boost.org for most recent version including documentation.
// Revision History
// 29 May 01 Factored implementation, added comparison tests, use Test Tools
// library (Daryle Walker)
// 12 Dec 99 Initial version with iterator operators (Jeremy Siek)
#define BOOST_INCLUDE_MAIN
#include <boost/test/test_tools.hpp> // for main
#include <boost/config.hpp> // for BOOST_STATIC_CONSTANT
#include <boost/cstdlib.hpp> // for boost::exit_success
#include <boost/operators.hpp> // for boost::random_access_iterator_helper
#include <cstddef> // for std::ptrdiff_t, std::size_t
#include <cstring> // for std::strcmp
#include <iostream> // for std::cout (std::endl, ends, and flush indirectly)
#include <string> // for std::string
#include <sstream> // for std::stringstream
# ifdef BOOST_NO_STDC_NAMESPACE
namespace std { using ::strcmp; }
# endif
// Iterator test class
template <class T, class R, class P>
struct test_iter
: public boost::random_access_iterator_helper<
test_iter<T,R,P>, T, std::ptrdiff_t, P, R>
{
typedef test_iter self;
typedef R Reference;
typedef std::ptrdiff_t Distance;
public:
explicit test_iter(T* i =0) : _i(i) { }
test_iter(const self& x) : _i(x._i) { }
self& operator=(const self& x) { _i = x._i; return *this; }
Reference operator*() const { return *_i; }
self& operator++() { ++_i; return *this; }
self& operator--() { --_i; return *this; }
self& operator+=(Distance n) { _i += n; return *this; }
self& operator-=(Distance n) { _i -= n; return *this; }
bool operator==(const self& x) const { return _i == x._i; }
bool operator<(const self& x) const { return _i < x._i; }
friend Distance operator-(const self& x, const self& y) {
return x._i - y._i;
}
protected:
P _i;
};
// Iterator operator testing classes
class test_opr_base
{
protected:
// Test data and types
BOOST_STATIC_CONSTANT( std::size_t, fruit_length = 6u );
typedef std::string fruit_array_type[ fruit_length ];
static fruit_array_type fruit;
}; // test_opr_base
#ifndef BOOST_NO_INCLASS_MEMBER_INITIALIZATION
// A definition is required even for integral static constants
const std::size_t test_opr_base::fruit_length;
#endif
template <typename T, typename R = T&, typename P = T*>
class test_opr
: public test_opr_base
{
typedef test_opr<T, R, P> self_type;
public:
// Types
typedef T value_type;
typedef R reference;
typedef P pointer;
typedef test_iter<T, R, P> iter_type;
// Test controller
static void master_test( char const name[] );
private:
// Test data
static iter_type const fruit_begin;
static iter_type const fruit_end;
// Test parts
static void post_increment_test();
static void post_decrement_test();
static void indirect_referral_test();
static void offset_addition_test();
static void reverse_offset_addition_test();
static void offset_subtraction_test();
static void comparison_test();
static void indexing_test();
}; // test_opr
// Class-static data definitions
test_opr_base::fruit_array_type
test_opr_base::fruit = { "apple", "orange", "pear", "peach", "grape", "plum" };
template <typename T, typename R, typename P>
typename test_opr<T, R, P>::iter_type const
test_opr<T, R, P>::fruit_begin = test_iter<T,R,P>( fruit );
template <typename T, typename R, typename P>
typename test_opr<T, R, P>::iter_type const
test_opr<T, R, P>::fruit_end = test_iter<T,R,P>( fruit + fruit_length );
// Main testing function
int
test_main( int , char * [] )
{
using std::string;
typedef test_opr<string, string &, string *> test1_type;
typedef test_opr<string, string const &, string const *> test2_type;
test1_type::master_test( "non-const string" );
test2_type::master_test( "const string" );
return boost::exit_success;
}
// Tests for all of the operators added by random_access_iterator_helper
template <typename T, typename R, typename P>
void
test_opr<T, R, P>::master_test
(
char const name[]
)
{
std::cout << "Doing test run for " << name << '.' << std::endl;
post_increment_test();
post_decrement_test();
indirect_referral_test();
offset_addition_test();
reverse_offset_addition_test();
offset_subtraction_test();
comparison_test();
indexing_test();
}
// Test post-increment
template <typename T, typename R, typename P>
void
test_opr<T, R, P>::post_increment_test
(
)
{
std::cout << "\tDoing post-increment test." << std::endl;
std::stringstream oss;
for ( iter_type i = fruit_begin ; i != fruit_end ; )
{
oss << *i++ << ' ';
}
BOOST_TEST( oss.str() == "apple orange pear peach grape plum ");
}
// Test post-decrement
template <typename T, typename R, typename P>
void
test_opr<T, R, P>::post_decrement_test
(
)
{
std::cout << "\tDoing post-decrement test." << std::endl;
std::stringstream oss;
for ( iter_type i = fruit_end ; i != fruit_begin ; )
{
i--;
oss << *i << ' ';
}
BOOST_TEST( oss.str() == "plum grape peach pear orange apple ");
}
// Test indirect structure referral
template <typename T, typename R, typename P>
void
test_opr<T, R, P>::indirect_referral_test
(
)
{
std::cout << "\tDoing indirect reference test." << std::endl;
std::stringstream oss;
for ( iter_type i = fruit_begin ; i != fruit_end ; ++i )
{
oss << i->size() << ' ';
}
BOOST_TEST( oss.str() == "5 6 4 5 5 4 ");
}
// Test offset addition
template <typename T, typename R, typename P>
void
test_opr<T, R, P>::offset_addition_test
(
)
{
std::cout << "\tDoing offset addition test." << std::endl;
std::ptrdiff_t const two = 2;
std::stringstream oss;
for ( iter_type i = fruit_begin ; i != fruit_end ; i = i + two )
{
oss << *i << ' ';
}
BOOST_TEST( oss.str() == "apple pear grape ");
}
// Test offset addition, in reverse order
template <typename T, typename R, typename P>
void
test_opr<T, R, P>::reverse_offset_addition_test
(
)
{
std::cout << "\tDoing reverse offset addition test." << std::endl;
std::ptrdiff_t const two = 2;
std::stringstream oss;
for ( iter_type i = fruit_begin ; i != fruit_end ; i = two + i )
{
oss << *i << ' ';
}
BOOST_TEST( oss.str() == "apple pear grape ");
}
// Test offset subtraction
template <typename T, typename R, typename P>
void
test_opr<T, R, P>::offset_subtraction_test
(
)
{
std::cout << "\tDoing offset subtraction test." << std::endl;
std::ptrdiff_t const two = 2;
std::stringstream oss;
for ( iter_type i = fruit_end ; fruit_begin < i ; )
{
i = i - two;
if ( (fruit_begin < i) || (fruit_begin == i) )
{
oss << *i << ' ';
}
}
BOOST_TEST( oss.str() == "grape pear apple ");
}
// Test comparisons
template <typename T, typename R, typename P>
void
test_opr<T, R, P>::comparison_test
(
)
{
using std::cout;
using std::ptrdiff_t;
cout << "\tDoing comparison tests.\n\t\tPass:";
for ( iter_type i = fruit_begin ; i != fruit_end ; ++i )
{
ptrdiff_t const i_offset = i - fruit_begin;
cout << ' ' << *i << std::flush;
for ( iter_type j = fruit_begin ; j != fruit_end ; ++j )
{
ptrdiff_t const j_offset = j - fruit_begin;
BOOST_TEST( (i != j) == (i_offset != j_offset) );
BOOST_TEST( (i > j) == (i_offset > j_offset) );
BOOST_TEST( (i <= j) == (i_offset <= j_offset) );
BOOST_TEST( (i >= j) == (i_offset >= j_offset) );
}
}
cout << std::endl;
}
// Test indexing
template <typename T, typename R, typename P>
void
test_opr<T, R, P>::indexing_test
(
)
{
std::cout << "\tDoing indexing test." << std::endl;
std::stringstream oss;
for ( std::size_t k = 0u ; k < fruit_length ; ++k )
{
oss << fruit_begin[ k ] << ' ';
}
BOOST_TEST( oss.str() == "apple orange pear peach grape plum ");
}

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noncopyable_test.cpp
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// boost class noncopyable test program ------------------------------------//
// (C) Copyright boost.org 1999. Permission to copy, use, modify, sell
// and distribute this software is granted provided this copyright
// notice appears in all copies. This software is provided "as is" without
// express or implied warranty, and with no claim as to its suitability for
// any purpose.
// See http://www.boost.org for most recent version including documentation.
// Revision History
// 9 Jun 99 Add unnamed namespace
// 2 Jun 99 Initial Version
#include <boost/noncopyable.hpp>
#include <iostream>
// This program demonstrates compiler errors resulting from trying to copy
// construct or copy assign a class object derived from class noncopyable.
namespace
{
class DontTreadOnMe : private boost::noncopyable
{
public:
DontTreadOnMe() { std::cout << "defanged!" << std::endl; }
}; // DontTreadOnMe
} // unnamed namespace
int main()
{
DontTreadOnMe object1;
DontTreadOnMe object2(object1);
object1 = object2;
return 0;
} // main

387
numeric_traits_test.cpp
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@ -1,387 +0,0 @@
// (C) Copyright David Abrahams 2001. Permission to copy, use, modify,
// sell and distribute this software is granted provided this
// copyright notice appears in all copies. This software is provided
// "as is" without express or implied warranty, and with no claim as
// to its suitability for any purpose.
// See http://www.boost.org for most recent version including documentation.
// Revision History
// 1 Apr 2001 Fixes for ICL; use BOOST_STATIC_CONSTANT
// 11 Feb 2001 Fixes for Borland (David Abrahams)
// 23 Jan 2001 Added test for wchar_t (David Abrahams)
// 23 Jan 2001 Now statically selecting a test for signed numbers to avoid
// warnings with fancy compilers. Added commentary and
// additional dumping of traits data for tested types (David
// Abrahams).
// 21 Jan 2001 Initial version (David Abrahams)
#include <boost/detail/numeric_traits.hpp>
#include <cassert>
#include <boost/type_traits.hpp>
#include <boost/static_assert.hpp>
#include <boost/cstdint.hpp>
#include <boost/utility.hpp>
#include <boost/lexical_cast.hpp>
#include <climits>
#include <typeinfo>
#include <iostream>
#include <string>
#ifndef BOOST_NO_LIMITS
# include <limits>
#endif
// =================================================================================
// template class complement_traits<Number> --
//
// statically computes the max and min for 1s and 2s-complement binary
// numbers. This helps on platforms without <limits> support. It also shows
// an example of a recursive template that works with MSVC!
//
template <unsigned size> struct complement; // forward
// The template complement, below, does all the real work, using "poor man's
// partial specialization". We need complement_traits_aux<> so that MSVC doesn't
// complain about undefined min/max as we're trying to recursively define them.
template <class Number, unsigned size>
struct complement_traits_aux
{
BOOST_STATIC_CONSTANT(Number, max = complement<size>::template traits<Number>::max);
BOOST_STATIC_CONSTANT(Number, min = complement<size>::template traits<Number>::min);
};
template <unsigned size>
struct complement
{
template <class Number>
struct traits
{
private:
// indirection through complement_traits_aux neccessary to keep MSVC happy
typedef complement_traits_aux<Number, size - 1> prev;
public:
BOOST_STATIC_CONSTANT(Number, max =
Number(Number(prev::max) << CHAR_BIT)
+ Number(UCHAR_MAX));
BOOST_STATIC_CONSTANT(Number, min = Number(Number(prev::min) << CHAR_BIT));
};
};
// Template class complement_base<> -- defines values for min and max for
// complement<1>, at the deepest level of recursion. Uses "poor man's partial
// specialization" again.
template <bool is_signed> struct complement_base;
template <> struct complement_base<false>
{
template <class Number>
struct values
{
BOOST_STATIC_CONSTANT(Number, min = 0);
BOOST_STATIC_CONSTANT(Number, max = UCHAR_MAX);
};
};
template <> struct complement_base<true>
{
template <class Number>
struct values
{
BOOST_STATIC_CONSTANT(Number, min = SCHAR_MIN);
BOOST_STATIC_CONSTANT(Number, max = SCHAR_MAX);
};
};
// Base specialization of complement, puts an end to the recursion.
template <>
struct complement<1>
{
template <class Number>
struct traits
{
BOOST_STATIC_CONSTANT(bool, is_signed = boost::detail::is_signed<Number>::value);
BOOST_STATIC_CONSTANT(Number, min =
complement_base<is_signed>::template values<Number>::min);
BOOST_STATIC_CONSTANT(Number, max =
complement_base<is_signed>::template values<Number>::max);
};
};
// Now here's the "pretty" template you're intended to actually use.
// complement_traits<Number>::min, complement_traits<Number>::max are the
// minimum and maximum values of Number if Number is a built-in integer type.
template <class Number>
struct complement_traits
{
BOOST_STATIC_CONSTANT(Number, max = (complement_traits_aux<Number, sizeof(Number)>::max));
BOOST_STATIC_CONSTANT(Number, min = (complement_traits_aux<Number, sizeof(Number)>::min));
};
// =================================================================================
// Support for streaming various numeric types in exactly the format I want. I
// needed this in addition to all the assertions so that I could see exactly
// what was going on.
//
// Numbers go through a 2-stage conversion process (by default, though, no real
// conversion).
//
template <class T> struct stream_as {
typedef T t1;
typedef T t2;
};
// char types first get converted to unsigned char, then to unsigned.
template <> struct stream_as<char> {
typedef unsigned char t1;
typedef unsigned t2;
};
template <> struct stream_as<unsigned char> {
typedef unsigned char t1; typedef unsigned t2;
};
template <> struct stream_as<signed char> {
typedef unsigned char t1; typedef unsigned t2;
};
#if defined(BOOST_MSVC_STD_ITERATOR) // No intmax streaming built-in
// With this library implementation, __int64 and __uint64 get streamed as strings
template <> struct stream_as<boost::uintmax_t> {
typedef std::string t1;
typedef std::string t2;
};
template <> struct stream_as<boost::intmax_t> {
typedef std::string t1;
typedef std::string t2;
};
#endif
// Standard promotion process for streaming
template <class T> struct promote
{
static typename stream_as<T>::t1 from(T x) {
typedef typename stream_as<T>::t1 t1;
return t1(x);
}
};
#if defined(BOOST_MSVC_STD_ITERATOR) // No intmax streaming built-in
// On this platform, stream them as long/unsigned long if they fit.
// Otherwise, write a string.
template <> struct promote<boost::uintmax_t> {
std::string static from(const boost::uintmax_t x) {
if (x > ULONG_MAX)
return std::string("large unsigned value");
else
return boost::lexical_cast<std::string>((unsigned long)x);
}
};
template <> struct promote<boost::intmax_t> {
std::string static from(const boost::intmax_t x) {
if (x > boost::intmax_t(ULONG_MAX))
return std::string("large positive signed value");
else if (x >= 0)
return boost::lexical_cast<std::string>((unsigned long)x);
if (x < boost::intmax_t(LONG_MIN))
return std::string("large negative signed value");
else
return boost::lexical_cast<std::string>((long)x);
}
};
#endif
// This is the function which converts types to the form I want to stream them in.
template <class T>
typename stream_as<T>::t2 stream_number(T x)
{
return promote<T>::from(x);
}
// =================================================================================
//
// Tests for built-in signed and unsigned types
//
// Tag types for selecting tests
struct unsigned_tag {};
struct signed_tag {};
// Tests for unsigned numbers. The extra default Number parameter works around
// an MSVC bug.
template <class Number>
void test_aux(unsigned_tag, Number*)
{
typedef typename boost::detail::numeric_traits<Number>::difference_type difference_type;
BOOST_STATIC_ASSERT(!boost::detail::is_signed<Number>::value);
BOOST_STATIC_ASSERT(
(sizeof(Number) < sizeof(boost::intmax_t))
| (boost::is_same<difference_type, boost::intmax_t>::value));
// Force casting to Number here to work around the fact that it's an enum on MSVC
BOOST_STATIC_ASSERT(Number(complement_traits<Number>::max) > Number(0));
BOOST_STATIC_ASSERT(Number(complement_traits<Number>::min) == Number(0));
const Number max = complement_traits<Number>::max;
const Number min = complement_traits<Number>::min;
const Number test_max = (sizeof(Number) < sizeof(boost::intmax_t))
? max
: max / 2 - 1;
std::cout << std::hex << "(unsigned) min = " << stream_number(min) << ", max = "
<< stream_number(max) << "..." << std::flush;
std::cout << "difference_type = " << typeid(difference_type).name() << "..."
<< std::flush;
difference_type d1 = boost::detail::numeric_distance(Number(0), test_max);
difference_type d2 = boost::detail::numeric_distance(test_max, Number(0));
std::cout << "0->" << stream_number(test_max) << "==" << std::dec << stream_number(d1) << "; "
<< std::hex << stream_number(test_max) << "->0==" << std::dec << stream_number(d2) << "..." << std::flush;
assert(d1 == difference_type(test_max));
assert(d2 == -difference_type(test_max));
}
// Tests for signed numbers. The extra default Number parameter works around an
// MSVC bug.
struct out_of_range_tag {};
struct in_range_tag {};
// This test morsel gets executed for numbers whose difference will always be
// representable in intmax_t
template <class Number>
void signed_test(in_range_tag, Number*)
{
BOOST_STATIC_ASSERT(boost::detail::is_signed<Number>::value);
typedef typename boost::detail::numeric_traits<Number>::difference_type difference_type;
const Number max = complement_traits<Number>::max;
const Number min = complement_traits<Number>::min;
difference_type d1 = boost::detail::numeric_distance(min, max);
difference_type d2 = boost::detail::numeric_distance(max, min);
std::cout << stream_number(min) << "->" << stream_number(max) << "==";
std::cout << std::dec << stream_number(d1) << "; ";
std::cout << std::hex << stream_number(max) << "->" << stream_number(min)
<< "==" << std::dec << stream_number(d2) << "..." << std::flush;
assert(d1 == difference_type(max) - difference_type(min));
assert(d2 == difference_type(min) - difference_type(max));
}
// This test morsel gets executed for numbers whose difference may exceed the
// capacity of intmax_t.
template <class Number>
void signed_test(out_of_range_tag, Number*)
{
BOOST_STATIC_ASSERT(boost::detail::is_signed<Number>::value);
typedef typename boost::detail::numeric_traits<Number>::difference_type difference_type;
const Number max = complement_traits<Number>::max;
const Number min = complement_traits<Number>::min;
difference_type min_distance = complement_traits<difference_type>::min;
difference_type max_distance = complement_traits<difference_type>::max;
const Number n1 = Number(min + max_distance);
const Number n2 = Number(max + min_distance);
difference_type d1 = boost::detail::numeric_distance(min, n1);
difference_type d2 = boost::detail::numeric_distance(max, n2);
std::cout << stream_number(min) << "->" << stream_number(n1) << "==";
std::cout << std::dec << stream_number(d1) << "; ";
std::cout << std::hex << stream_number(max) << "->" << stream_number(n2)
<< "==" << std::dec << stream_number(d2) << "..." << std::flush;
assert(d1 == max_distance);
assert(d2 == min_distance);
}
template <class Number>
void test_aux(signed_tag, Number*)
{
typedef typename boost::detail::numeric_traits<Number>::difference_type difference_type;
BOOST_STATIC_ASSERT(boost::detail::is_signed<Number>::value);
BOOST_STATIC_ASSERT(
(sizeof(Number) < sizeof(boost::intmax_t))
| (boost::is_same<difference_type, Number>::value));
// Force casting to Number here to work around the fact that it's an enum on MSVC
BOOST_STATIC_ASSERT(Number(complement_traits<Number>::max) > Number(0));
BOOST_STATIC_ASSERT(Number(complement_traits<Number>::min) < Number(0));
const Number max = complement_traits<Number>::max;
const Number min = complement_traits<Number>::min;
std::cout << std::hex << "min = " << stream_number(min) << ", max = "
<< stream_number(max) << "..." << std::flush;
std::cout << "difference_type = " << typeid(difference_type).name() << "..."
<< std::flush;
typedef typename boost::detail::if_true<
(sizeof(Number) < sizeof(boost::intmax_t))>
::template then<
in_range_tag,
out_of_range_tag
>::type
range_tag;
signed_test<Number>(range_tag(), 0);
}
// Test for all numbers. The extra default Number parameter works around an MSVC
// bug.
template <class Number>
void test(Number* = 0)
{
std::cout << "testing " << typeid(Number).name() << ":\n"
#ifndef BOOST_NO_LIMITS_COMPILE_TIME_CONSTANTS
<< "is_signed: " << (std::numeric_limits<Number>::is_signed ? "true\n" : "false\n")
<< "is_bounded: " << (std::numeric_limits<Number>::is_bounded ? "true\n" : "false\n")
<< "digits: " << std::numeric_limits<Number>::digits << "\n"
#endif
<< "..." << std::flush;
// factoring out difference_type for the assert below confused Borland :(
typedef boost::detail::is_signed<
#if !defined(BOOST_MSVC) || BOOST_MSVC > 1300
typename
#endif
boost::detail::numeric_traits<Number>::difference_type
> is_signed;
BOOST_STATIC_ASSERT(is_signed::value);
typedef typename boost::detail::if_true<
boost::detail::is_signed<Number>::value
>::template then<signed_tag, unsigned_tag>::type signedness;
test_aux<Number>(signedness(), 0);
std::cout << "passed" << std::endl;
}
int main()
{
test<char>();
test<unsigned char>();
test<signed char>();
test<wchar_t>();
test<short>();
test<unsigned short>();
test<int>();
test<unsigned int>();
test<long>();
test<unsigned long>();
#if defined(BOOST_HAS_LONG_LONG) && !defined(BOOST_NO_INTEGRAL_INT64_T)
test<long long>();
test<unsigned long long>();
#elif defined(BOOST_MSVC)
// The problem of not having compile-time static class constants other than
// enums prevents this from working, since values get truncated.
// test<boost::uintmax_t>();
// test<boost::intmax_t>();
#endif
return 0;
}

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// Demonstrate and test boost/operators.hpp -------------------------------//
// Copyright Beman Dawes 1999.
// See accompanying license for terms and conditions of use.
// See http://www.boost.org/libs/utility for documentation.
// Revision History
// 01 Oct 01 Added tests for "left" operators
// and new grouped operators. (Helmut Zeisel)
// 20 May 01 Output progress messages. Added tests for new operator
// templates. Updated random number generator. Changed tests to
// use Boost Test Tools library. (Daryle Walker)
// 04 Jun 00 Added regression test for a bug I found (David Abrahams)
// 17 Jun 00 Fix for broken compilers (Aleksey Gurtovoy)
// ?? ??? 00 Major update to randomly test all one- and two- argument forms by
// wrapping integral types and comparing the results of operations
// to the results for the raw types (David Abrahams)
// 12 Dec 99 Minor update, output confirmation message.
// 15 Nov 99 Initial version
#define BOOST_INCLUDE_MAIN
#include <boost/config.hpp> // for BOOST_MSVC
#include <boost/cstdlib.hpp> // for boost::exit_success
#include <boost/operators.hpp> // for the tested items
#include <boost/random/linear_congruential.hpp> // for boost::minstd_rand
#include <boost/test/test_tools.hpp> // for main
#include <iostream> // for std::cout (std::endl indirectly)
namespace
{
// avoiding a template version of true_value so as to not confuse VC++
int true_value(int x) { return x; }
long true_value(long x) { return x; }
signed char true_value(signed char x) { return x; }
short true_value(short x) { return x; }
unsigned int true_value(unsigned int x) { return x; }
unsigned long true_value(unsigned long x) { return x; }
unsigned char true_value(unsigned char x) { return x; }
unsigned short true_value(unsigned short x) { return x; }
// The use of operators<> here tended to obscure
// interactions with certain compiler bugs
template <class T>
class Wrapped1
: boost::operators<Wrapped1<T> >
, boost::shiftable<Wrapped1<T> >
{
public:
explicit Wrapped1( T v = T() ) : _value(v) {}
T value() const { return _value; }
bool operator<(const Wrapped1& x) const { return _value < x._value; }
bool operator==(const Wrapped1& x) const { return _value == x._value; }
Wrapped1& operator+=(const Wrapped1& x)
{ _value += x._value; return *this; }
Wrapped1& operator-=(const Wrapped1& x)
{ _value -= x._value; return *this; }
Wrapped1& operator*=(const Wrapped1& x)
{ _value *= x._value; return *this; }
Wrapped1& operator/=(const Wrapped1& x)
{ _value /= x._value; return *this; }
Wrapped1& operator%=(const Wrapped1& x)
{ _value %= x._value; return *this; }
Wrapped1& operator|=(const Wrapped1& x)
{ _value |= x._value; return *this; }
Wrapped1& operator&=(const Wrapped1& x)
{ _value &= x._value; return *this; }
Wrapped1& operator^=(const Wrapped1& x)
{ _value ^= x._value; return *this; }
Wrapped1& operator<<=(const Wrapped1& x)
{ _value <<= x._value; return *this; }
Wrapped1& operator>>=(const Wrapped1& x)
{ _value >>= x._value; return *this; }
Wrapped1& operator++() { ++_value; return *this; }
Wrapped1& operator--() { --_value; return *this; }
private:
T _value;
};
template <class T>
T true_value(Wrapped1<T> x) { return x.value(); }
template <class T, class U>
class Wrapped2
: boost::operators<Wrapped2<T, U> >
, boost::operators2<Wrapped2<T, U>, U>
, boost::shiftable1<Wrapped2<T, U>
, boost::shiftable2<Wrapped2<T, U>, U > >
{
public:
explicit Wrapped2( T v = T() ) : _value(v) {}
T value() const { return _value; }
bool operator<(const Wrapped2& x) const { return _value < x._value; }
bool operator==(const Wrapped2& x) const { return _value == x._value; }
Wrapped2& operator+=(const Wrapped2& x)
{ _value += x._value; return *this; }
Wrapped2& operator-=(const Wrapped2& x)
{ _value -= x._value; return *this; }
Wrapped2& operator*=(const Wrapped2& x)
{ _value *= x._value; return *this; }
Wrapped2& operator/=(const Wrapped2& x)
{ _value /= x._value; return *this; }
Wrapped2& operator%=(const Wrapped2& x)
{ _value %= x._value; return *this; }
Wrapped2& operator|=(const Wrapped2& x)
{ _value |= x._value; return *this; }
Wrapped2& operator&=(const Wrapped2& x)
{ _value &= x._value; return *this; }
Wrapped2& operator^=(const Wrapped2& x)
{ _value ^= x._value; return *this; }
Wrapped2& operator<<=(const Wrapped2& x)
{ _value <<= x._value; return *this; }
Wrapped2& operator>>=(const Wrapped2& x)
{ _value >>= x._value; return *this; }
Wrapped2& operator++() { ++_value; return *this; }
Wrapped2& operator--() { --_value; return *this; }
bool operator<(U u) const { return _value < u; }
bool operator>(U u) const { return _value > u; }
bool operator==(U u) const { return _value == u; }
Wrapped2& operator+=(U u) { _value += u; return *this; }
Wrapped2& operator-=(U u) { _value -= u; return *this; }
Wrapped2& operator*=(U u) { _value *= u; return *this; }
Wrapped2& operator/=(U u) { _value /= u; return *this; }
Wrapped2& operator%=(U u) { _value %= u; return *this; }
Wrapped2& operator|=(U u) { _value |= u; return *this; }
Wrapped2& operator&=(U u) { _value &= u; return *this; }
Wrapped2& operator^=(U u) { _value ^= u; return *this; }
Wrapped2& operator<<=(U u) { _value <<= u; return *this; }
Wrapped2& operator>>=(U u) { _value >>= u; return *this; }
private:
T _value;
};
template <class T, class U>
T true_value(Wrapped2<T,U> x) { return x.value(); }
template <class T>
class Wrapped3
: boost::equivalent<Wrapped3<T> >
, boost::partially_ordered<Wrapped3<T> >
, boost::equality_comparable<Wrapped3<T> >
{
public:
explicit Wrapped3( T v = T() ) : _value(v) {}
T value() const { return _value; }
bool operator<(const Wrapped3& x) const { return _value < x._value; }
private:
T _value;
};
template <class T>
T true_value(Wrapped3<T> x) { return x.value(); }
template <class T, class U>
class Wrapped4
: boost::equality_comparable1<Wrapped4<T, U>
, boost::equivalent1<Wrapped4<T, U>
, boost::partially_ordered1<Wrapped4<T, U> > > >
, boost::partially_ordered2<Wrapped4<T, U>, U
, boost::equivalent2<Wrapped4<T, U>, U
, boost::equality_comparable2<Wrapped4<T, U>, U> > >
{
public:
explicit Wrapped4( T v = T() ) : _value(v) {}
T value() const { return _value; }
bool operator<(const Wrapped4& x) const { return _value < x._value; }
bool operator<(U u) const { return _value < u; }
bool operator>(U u) const { return _value > u; }
private:
T _value;
};
template <class T, class U>
T true_value(Wrapped4<T,U> x) { return x.value(); }
// U must be convertible to T
template <class T, class U>
class Wrapped5
: boost::ordered_field_operators2<Wrapped5<T, U>, U>
, boost::ordered_field_operators1<Wrapped5<T, U> >
{
public:
explicit Wrapped5( T v = T() ) : _value(v) {}
// Conversion from U to Wrapped5<T,U>
Wrapped5(U u) : _value(u) {}
T value() const { return _value; }
bool operator<(const Wrapped5& x) const { return _value < x._value; }
bool operator<(U u) const { return _value < u; }
bool operator>(U u) const { return _value > u; }
bool operator==(const Wrapped5& u) const { return _value == u._value; }
bool operator==(U u) const { return _value == u; }
Wrapped5& operator/=(const Wrapped5& u) { _value /= u._value; return *this;}
Wrapped5& operator/=(U u) { _value /= u; return *this;}
Wrapped5& operator*=(const Wrapped5& u) { _value *= u._value; return *this;}
Wrapped5& operator*=(U u) { _value *= u; return *this;}
Wrapped5& operator-=(const Wrapped5& u) { _value -= u._value; return *this;}
Wrapped5& operator-=(U u) { _value -= u; return *this;}
Wrapped5& operator+=(const Wrapped5& u) { _value += u._value; return *this;}
Wrapped5& operator+=(U u) { _value += u; return *this;}
private:
T _value;
};
template <class T, class U>
T true_value(Wrapped5<T,U> x) { return x.value(); }
// U must be convertible to T
template <class T, class U>
class Wrapped6
: boost::ordered_euclidian_ring_operators2<Wrapped6<T, U>, U>
, boost::ordered_euclidian_ring_operators1<Wrapped6<T, U> >
{
public:
explicit Wrapped6( T v = T() ) : _value(v) {}
// Conversion from U to Wrapped6<T,U>
Wrapped6(U u) : _value(u) {}
T value() const { return _value; }
bool operator<(const Wrapped6& x) const { return _value < x._value; }
bool operator<(U u) const { return _value < u; }
bool operator>(U u) const { return _value > u; }
bool operator==(const Wrapped6& u) const { return _value == u._value; }
bool operator==(U u) const { return _value == u; }
Wrapped6& operator%=(const Wrapped6& u) { _value %= u._value; return *this;}
Wrapped6& operator%=(U u) { _value %= u; return *this;}
Wrapped6& operator/=(const Wrapped6& u) { _value /= u._value; return *this;}
Wrapped6& operator/=(U u) { _value /= u; return *this;}
Wrapped6& operator*=(const Wrapped6& u) { _value *= u._value; return *this;}
Wrapped6& operator*=(U u) { _value *= u; return *this;}
Wrapped6& operator-=(const Wrapped6& u) { _value -= u._value; return *this;}
Wrapped6& operator-=(U u) { _value -= u; return *this;}
Wrapped6& operator+=(const Wrapped6& u) { _value += u._value; return *this;}
Wrapped6& operator+=(U u) { _value += u; return *this;}
private:
T _value;
};
template <class T, class U>
T true_value(Wrapped6<T,U> x) { return x.value(); }
// MyInt uses only the single template-argument form of all_operators<>
typedef Wrapped1<int> MyInt;
typedef Wrapped2<long, long> MyLong;
typedef Wrapped3<signed char> MyChar;
typedef Wrapped4<short, short> MyShort;
typedef Wrapped5<double, int> MyDoubleInt;
typedef Wrapped6<long, int> MyLongInt;
template <class X1, class Y1, class X2, class Y2>
void sanity_check(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
BOOST_TEST( true_value(y1) == true_value(y2) );
BOOST_TEST( true_value(x1) == true_value(x2) );
}
template <class X1, class Y1, class X2, class Y2>
void test_less_than_comparable_aux(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
BOOST_TEST( (x1 < y1) == (x2 < y2) );
BOOST_TEST( (x1 <= y1) == (x2 <= y2) );
BOOST_TEST( (x1 >= y1) == (x2 >= y2) );
BOOST_TEST( (x1 > y1) == (x2 > y2) );
}
template <class X1, class Y1, class X2, class Y2>
void test_less_than_comparable(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
sanity_check( x1, y1, x2, y2 );
test_less_than_comparable_aux( x1, y1, x2, y2 );
test_less_than_comparable_aux( y1, x1, y2, x2 );
}
template <class X1, class Y1, class X2, class Y2>
void test_equality_comparable_aux(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
BOOST_TEST( (x1 == y1) == (x2 == y2) );
BOOST_TEST( (x1 != y1) == (x2 != y2) );
}
template <class X1, class Y1, class X2, class Y2>
void test_equality_comparable(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
sanity_check( x1, y1, x2, y2 );
test_equality_comparable_aux( x1, y1, x2, y2 );
test_equality_comparable_aux( y1, x1, y2, x2 );
}
template <class X1, class Y1, class X2, class Y2>
void test_multipliable_aux(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
BOOST_TEST( (x1 * y1).value() == (x2 * y2) );
}
template <class X1, class Y1, class X2, class Y2>
void test_multipliable(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
sanity_check( x1, y1, x2, y2 );
test_multipliable_aux( x1, y1, x2, y2 );
test_multipliable_aux( y1, x1, y2, x2 );
}
template <class A, class B>
void test_value_equality(A a, B b)
{
BOOST_TEST(a.value() == b);
}
#define TEST_OP_R(op) test_value_equality(x1 op y1, x2 op y2)
#define TEST_OP_L(op) test_value_equality(y1 op x1, y2 op x2)
template <class X1, class Y1, class X2, class Y2>
void test_addable_aux(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
TEST_OP_R(+);
}
template <class X1, class Y1, class X2, class Y2>
void test_addable(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
sanity_check( x1, y1, x2, y2 );
test_addable_aux( x1, y1, x2, y2 );
test_addable_aux( y1, x1, y2, x2 );
}
template <class X1, class Y1, class X2, class Y2>
void test_subtractable(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
sanity_check( x1, y1, x2, y2 );
TEST_OP_R(-);
}
template <class X1, class Y1, class X2, class Y2>
void test_subtractable_left(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
sanity_check( x1, y1, x2, y2 );
TEST_OP_L(-);
}
template <class X1, class Y1, class X2, class Y2>
void test_dividable(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
sanity_check( x1, y1, x2, y2 );
if ( y2 != 0 )
TEST_OP_R(/);
}
template <class X1, class Y1, class X2, class Y2>
void test_dividable_left(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
sanity_check( x1, y1, x2, y2 );
if ( x2 != 0 )
TEST_OP_L(/);
}
template <class X1, class Y1, class X2, class Y2>
void test_modable(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
sanity_check( x1, y1, x2, y2 );
if ( y2 != 0 )
TEST_OP_R(%);
}
template <class X1, class Y1, class X2, class Y2>
void test_modable_left(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
sanity_check( x1, y1, x2, y2 );
if ( x2 != 0 )
TEST_OP_L(%);
}
template <class X1, class Y1, class X2, class Y2>
void test_xorable_aux(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
TEST_OP_R(^);
}
template <class X1, class Y1, class X2, class Y2>
void test_xorable(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
sanity_check( x1, y1, x2, y2 );
test_xorable_aux( x1, y1, x2, y2 );
test_xorable_aux( y1, x1, y2, x2 );
}
template <class X1, class Y1, class X2, class Y2>
void test_andable_aux(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
TEST_OP_R(&);
}
template <class X1, class Y1, class X2, class Y2>
void test_andable(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
sanity_check( x1, y1, x2, y2 );
test_andable_aux( x1, y1, x2, y2 );
test_andable_aux( y1, x1, y2, x2 );
}
template <class X1, class Y1, class X2, class Y2>
void test_orable_aux(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
TEST_OP_R(|);
}
template <class X1, class Y1, class X2, class Y2>
void test_orable(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
sanity_check( x1, y1, x2, y2 );
test_orable_aux( x1, y1, x2, y2 );
test_orable_aux( y1, x1, y2, x2 );
}
template <class X1, class Y1, class X2, class Y2>
void test_left_shiftable(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
sanity_check( x1, y1, x2, y2 );
TEST_OP_R(<<);
}
template <class X1, class Y1, class X2, class Y2>
void test_right_shiftable(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
sanity_check( x1, y1, x2, y2 );
TEST_OP_R(>>);
}
template <class X1, class X2>
void test_incrementable(X1 x1, X2 x2)
{
sanity_check( x1, x1, x2, x2 );
BOOST_TEST( (x1++).value() == x2++ );
BOOST_TEST( x1.value() == x2 );
}
template <class X1, class X2>
void test_decrementable(X1 x1, X2 x2)
{
sanity_check( x1, x1, x2, x2 );
BOOST_TEST( (x1--).value() == x2-- );
BOOST_TEST( x1.value() == x2 );
}
template <class X1, class Y1, class X2, class Y2>
void test_all(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
test_less_than_comparable( x1, y1, x2, y2 );
test_equality_comparable( x1, y1, x2, y2 );
test_multipliable( x1, y1, x2, y2 );
test_addable( x1, y1, x2, y2 );
test_subtractable( x1, y1, x2, y2 );
test_dividable( x1, y1, x2, y2 );
test_modable( x1, y1, x2, y2 );
test_xorable( x1, y1, x2, y2 );
test_andable( x1, y1, x2, y2 );
test_orable( x1, y1, x2, y2 );
test_left_shiftable( x1, y1, x2, y2 );
test_right_shiftable( x1, y1, x2, y2 );
test_incrementable( x1, x2 );
test_decrementable( x1, x2 );
}
template <class X1, class Y1, class X2, class Y2>
void test_left(X1 x1, Y1 y1, X2 x2, Y2 y2)
{
test_subtractable_left( x1, y1, x2, y2 );
test_dividable_left( x1, y1, x2, y2 );
test_modable_left( x1, y1, x2, y2 );
}
template <class Big, class Small>
struct tester
{
void operator()(boost::minstd_rand& randomizer) const
{
Big b1 = Big( randomizer() );
Big b2 = Big( randomizer() );
Small s = Small( randomizer() );
test_all( Wrapped1<Big>(b1), Wrapped1<Big>(b2), b1, b2 );
test_all( Wrapped2<Big, Small>(b1), s, b1, s );
}
};
template <class Big, class Small>
struct tester_left
{
void operator()(boost::minstd_rand& randomizer) const
{
Big b1 = Big( randomizer() );
Small s = Small( randomizer() );
test_left( Wrapped6<Big, Small>(b1), s, b1, s );
}
};
// added as a regression test. We had a bug which this uncovered.
struct Point
: boost::addable<Point
, boost::subtractable<Point> >
{
Point( int h, int v ) : h(h), v(v) {}
Point() :h(0), v(0) {}
const Point& operator+=( const Point& rhs )
{ h += rhs.h; v += rhs.v; return *this; }
const Point& operator-=( const Point& rhs )
{ h -= rhs.h; v -= rhs.v; return *this; }
int h;
int v;
};
} // unnamed namespace
// workaround for MSVC bug; for some reasons the compiler doesn't instantiate
// inherited operator templates at the moment it must, so the following
// explicit instantiations force it to do that.
#if defined(BOOST_MSVC) && (_MSC_VER <= 1200)
template Wrapped1<int>;
template Wrapped1<long>;
template Wrapped1<unsigned int>;
template Wrapped1<unsigned long>;
template Wrapped2<int, int>;
template Wrapped2<int, signed char>;
template Wrapped2<long, signed char>;
template Wrapped2<long, int>;
template Wrapped2<long, long>;
template Wrapped2<unsigned int, unsigned int>;
template Wrapped2<unsigned int, unsigned char>;
template Wrapped2<unsigned long, unsigned int>;
template Wrapped2<unsigned long, unsigned char>;
template Wrapped2<unsigned long, unsigned long>;
template Wrapped6<long, int>;
template Wrapped6<long, signed char>;
template Wrapped6<int, signed char>;
template Wrapped6<unsigned long, unsigned int>;
template Wrapped6<unsigned long, unsigned char>;
template Wrapped6<unsigned int, unsigned char>;
#endif
#define PRIVATE_EXPR_TEST(e, t) BOOST_TEST( ((e), (t)) )
int
test_main( int , char * [] )
{
using std::cout;
using std::endl;
// Regression test.
Point x;
x = x + Point(3, 4);
x = x - Point(3, 4);
cout << "Created point, and operated on it." << endl;
for (int n = 0; n < 1000; ++n) // was 10,000 but took too long (Beman)
{
boost::minstd_rand r;
tester<long, int>()(r);
tester<long, signed char>()(r);
tester<long, long>()(r);
tester<int, int>()(r);
tester<int, signed char>()(r);
tester<unsigned long, unsigned int>()(r);
tester<unsigned long, unsigned char>()(r);
tester<unsigned long, unsigned long>()(r);
tester<unsigned int, unsigned int>()(r);
tester<unsigned int, unsigned char>()(r);
tester_left<long, int>()(r);
tester_left<long, signed char>()(r);
tester_left<int, signed char>()(r);
tester_left<unsigned long, unsigned int>()(r);
tester_left<unsigned long, unsigned char>()(r);
tester_left<unsigned int, unsigned char>()(r);
}
cout << "Did random tester loop." << endl;
MyInt i1(1);
MyInt i2(2);
MyInt i;
BOOST_TEST( i1.value() == 1 );
BOOST_TEST( i2.value() == 2 );
BOOST_TEST( i.value() == 0 );
cout << "Created MyInt objects.\n";
PRIVATE_EXPR_TEST( (i = i2), (i.value() == 2) );
BOOST_TEST( i2 == i );
BOOST_TEST( i1 != i2 );
BOOST_TEST( i1 < i2 );
BOOST_TEST( i1 <= i2 );
BOOST_TEST( i <= i2 );
BOOST_TEST( i2 > i1 );
BOOST_TEST( i2 >= i1 );
BOOST_TEST( i2 >= i );
PRIVATE_EXPR_TEST( (i = i1 + i2), (i.value() == 3) );
PRIVATE_EXPR_TEST( (i = i + i2), (i.value() == 5) );
PRIVATE_EXPR_TEST( (i = i - i1), (i.value() == 4) );
PRIVATE_EXPR_TEST( (i = i * i2), (i.value() == 8) );
PRIVATE_EXPR_TEST( (i = i / i2), (i.value() == 4) );
PRIVATE_EXPR_TEST( (i = i % ( i - i1 )), (i.value() == 1) );
PRIVATE_EXPR_TEST( (i = i2 + i2), (i.value() == 4) );
PRIVATE_EXPR_TEST( (i = i1 | i2 | i), (i.value() == 7) );
PRIVATE_EXPR_TEST( (i = i & i2), (i.value() == 2) );
PRIVATE_EXPR_TEST( (i = i + i1), (i.value() == 3) );
PRIVATE_EXPR_TEST( (i = i ^ i1), (i.value() == 2) );
PRIVATE_EXPR_TEST( (i = ( i + i1 ) * ( i2 | i1 )), (i.value() == 9) );
PRIVATE_EXPR_TEST( (i = i1 << i2), (i.value() == 4) );
PRIVATE_EXPR_TEST( (i = i2 >> i1), (i.value() == 1) );
cout << "Performed tests on MyInt objects.\n";
MyLong j1(1);
MyLong j2(2);
MyLong j;
BOOST_TEST( j1.value() == 1 );
BOOST_TEST( j2.value() == 2 );
BOOST_TEST( j.value() == 0 );
cout << "Created MyLong objects.\n";
PRIVATE_EXPR_TEST( (j = j2), (j.value() == 2) );
BOOST_TEST( j2 == j );
BOOST_TEST( 2 == j );
BOOST_TEST( j2 == 2 );
BOOST_TEST( j == j2 );
BOOST_TEST( j1 != j2 );
BOOST_TEST( j1 != 2 );
BOOST_TEST( 1 != j2 );
BOOST_TEST( j1 < j2 );
BOOST_TEST( 1 < j2 );
BOOST_TEST( j1 < 2 );
BOOST_TEST( j1 <= j2 );
BOOST_TEST( 1 <= j2 );
BOOST_TEST( j1 <= j );
BOOST_TEST( j <= j2 );
BOOST_TEST( 2 <= j2 );
BOOST_TEST( j <= 2 );
BOOST_TEST( j2 > j1 );
BOOST_TEST( 2 > j1 );
BOOST_TEST( j2 > 1 );
BOOST_TEST( j2 >= j1 );
BOOST_TEST( 2 >= j1 );
BOOST_TEST( j2 >= 1 );
BOOST_TEST( j2 >= j );
BOOST_TEST( 2 >= j );
BOOST_TEST( j2 >= 2 );
BOOST_TEST( (j1 + 2) == 3 );
BOOST_TEST( (1 + j2) == 3 );
PRIVATE_EXPR_TEST( (j = j1 + j2), (j.value() == 3) );
BOOST_TEST( (j + 2) == 5 );
BOOST_TEST( (3 + j2) == 5 );
PRIVATE_EXPR_TEST( (j = j + j2), (j.value() == 5) );
BOOST_TEST( (j - 1) == 4 );
PRIVATE_EXPR_TEST( (j = j - j1), (j.value() == 4) );
BOOST_TEST( (j * 2) == 8 );
BOOST_TEST( (4 * j2) == 8 );
PRIVATE_EXPR_TEST( (j = j * j2), (j.value() == 8) );
BOOST_TEST( (j / 2) == 4 );
PRIVATE_EXPR_TEST( (j = j / j2), (j.value() == 4) );
BOOST_TEST( (j % 3) == 1 );
PRIVATE_EXPR_TEST( (j = j % ( j - j1 )), (j.value() == 1) );
PRIVATE_EXPR_TEST( (j = j2 + j2), (j.value() == 4) );
BOOST_TEST( (1 | j2 | j) == 7 );
BOOST_TEST( (j1 | 2 | j) == 7 );
BOOST_TEST( (j1 | j2 | 4) == 7 );
PRIVATE_EXPR_TEST( (j = j1 | j2 | j), (j.value() == 7) );
BOOST_TEST( (7 & j2) == 2 );
BOOST_TEST( (j & 2) == 2 );
PRIVATE_EXPR_TEST( (j = j & j2), (j.value() == 2) );
PRIVATE_EXPR_TEST( (j = j | j1), (j.value() == 3) );
BOOST_TEST( (3 ^ j1) == 2 );
BOOST_TEST( (j ^ 1) == 2 );
PRIVATE_EXPR_TEST( (j = j ^ j1), (j.value() == 2) );
PRIVATE_EXPR_TEST( (j = ( j + j1 ) * ( j2 | j1 )), (j.value() == 9) );
BOOST_TEST( (j1 << 2) == 4 );
BOOST_TEST( (j2 << 1) == 4 );
PRIVATE_EXPR_TEST( (j = j1 << j2), (j.value() == 4) );
BOOST_TEST( (j >> 2) == 1 );
BOOST_TEST( (j2 >> 1) == 1 );
PRIVATE_EXPR_TEST( (j = j2 >> j1), (j.value() == 1) );
cout << "Performed tests on MyLong objects.\n";
MyChar k1(1);
MyChar k2(2);
MyChar k;
BOOST_TEST( k1.value() == 1 );
BOOST_TEST( k2.value() == 2 );
BOOST_TEST( k.value() == 0 );
cout << "Created MyChar objects.\n";
PRIVATE_EXPR_TEST( (k = k2), (k.value() == 2) );
BOOST_TEST( k2 == k );
BOOST_TEST( k1 != k2 );
BOOST_TEST( k1 < k2 );
BOOST_TEST( k1 <= k2 );
BOOST_TEST( k <= k2 );
BOOST_TEST( k2 > k1 );
BOOST_TEST( k2 >= k1 );
BOOST_TEST( k2 >= k );
cout << "Performed tests on MyChar objects.\n";
MyShort l1(1);
MyShort l2(2);
MyShort l;
BOOST_TEST( l1.value() == 1 );
BOOST_TEST( l2.value() == 2 );
BOOST_TEST( l.value() == 0 );
cout << "Created MyShort objects.\n";
PRIVATE_EXPR_TEST( (l = l2), (l.value() == 2) );
BOOST_TEST( l2 == l );
BOOST_TEST( 2 == l );
BOOST_TEST( l2 == 2 );
BOOST_TEST( l == l2 );
BOOST_TEST( l1 != l2 );
BOOST_TEST( l1 != 2 );
BOOST_TEST( 1 != l2 );
BOOST_TEST( l1 < l2 );
BOOST_TEST( 1 < l2 );
BOOST_TEST( l1 < 2 );
BOOST_TEST( l1 <= l2 );
BOOST_TEST( 1 <= l2 );
BOOST_TEST( l1 <= l );
BOOST_TEST( l <= l2 );
BOOST_TEST( 2 <= l2 );
BOOST_TEST( l <= 2 );
BOOST_TEST( l2 > l1 );
BOOST_TEST( 2 > l1 );
BOOST_TEST( l2 > 1 );
BOOST_TEST( l2 >= l1 );
BOOST_TEST( 2 >= l1 );
BOOST_TEST( l2 >= 1 );
BOOST_TEST( l2 >= l );
BOOST_TEST( 2 >= l );
BOOST_TEST( l2 >= 2 );
cout << "Performed tests on MyShort objects.\n";
MyDoubleInt di1(1);
MyDoubleInt di2(2.);
MyDoubleInt half(0.5);
MyDoubleInt di;
MyDoubleInt tmp;
BOOST_TEST( di1.value() == 1 );
BOOST_TEST( di2.value() == 2 );
BOOST_TEST( di2.value() == 2 );
BOOST_TEST( di.value() == 0 );
cout << "Created MyDoubleInt objects.\n";
PRIVATE_EXPR_TEST( (di = di2), (di.value() == 2) );
BOOST_TEST( di2 == di );
BOOST_TEST( 2 == di );
BOOST_TEST( di == 2 );
BOOST_TEST( di1 < di2 );
BOOST_TEST( 1 < di2 );
BOOST_TEST( di1 <= di2 );
BOOST_TEST( 1 <= di2 );
BOOST_TEST( di2 > di1 );
BOOST_TEST( di2 > 1 );
BOOST_TEST( di2 >= di1 );
BOOST_TEST( di2 >= 1 );
BOOST_TEST( di1 / di2 == half );
BOOST_TEST( di1 / 2 == half );
BOOST_TEST( 1 / di2 == half );
PRIVATE_EXPR_TEST( (tmp=di1), ((tmp/=2) == half) );
PRIVATE_EXPR_TEST( (tmp=di1), ((tmp/=di2) == half) );
BOOST_TEST( di1 * di2 == di2 );
BOOST_TEST( di1 * 2 == di2 );
BOOST_TEST( 1 * di2 == di2 );
PRIVATE_EXPR_TEST( (tmp=di1), ((tmp*=2) == di2) );
PRIVATE_EXPR_TEST( (tmp=di1), ((tmp*=di2) == di2) );
BOOST_TEST( di2 - di1 == di1 );
BOOST_TEST( di2 - 1 == di1 );
BOOST_TEST( 2 - di1 == di1 );
PRIVATE_EXPR_TEST( (tmp=di2), ((tmp-=1) == di1) );
PRIVATE_EXPR_TEST( (tmp=di2), ((tmp-=di1) == di1) );
BOOST_TEST( di1 + di1 == di2 );
BOOST_TEST( di1 + 1 == di2 );
BOOST_TEST( 1 + di1 == di2 );
PRIVATE_EXPR_TEST( (tmp=di1), ((tmp+=1) == di2) );
PRIVATE_EXPR_TEST( (tmp=di1), ((tmp+=di1) == di2) );
cout << "Performed tests on MyDoubleInt objects.\n";
MyLongInt li1(1);
MyLongInt li2(2);
MyLongInt li;
MyLongInt tmp2;
BOOST_TEST( li1.value() == 1 );
BOOST_TEST( li2.value() == 2 );
BOOST_TEST( li.value() == 0 );
cout << "Created MyLongInt objects.\n";
PRIVATE_EXPR_TEST( (li = li2), (li.value() == 2) );
BOOST_TEST( li2 == li );
BOOST_TEST( 2 == li );
BOOST_TEST( li == 2 );
BOOST_TEST( li1 < li2 );
BOOST_TEST( 1 < li2 );
BOOST_TEST( li1 <= li2 );
BOOST_TEST( 1 <= li2 );
BOOST_TEST( li2 > li1 );
BOOST_TEST( li2 > 1 );
BOOST_TEST( li2 >= li1 );
BOOST_TEST( li2 >= 1 );
BOOST_TEST( li1 % li2 == li1 );
BOOST_TEST( li1 % 2 == li1 );
BOOST_TEST( 1 % li2 == li1 );
PRIVATE_EXPR_TEST( (tmp2=li1), ((tmp2%=2) == li1) );
PRIVATE_EXPR_TEST( (tmp2=li1), ((tmp2%=li2) == li1) );
BOOST_TEST( li1 / li2 == 0 );
BOOST_TEST( li1 / 2 == 0 );
BOOST_TEST( 1 / li2 == 0 );
PRIVATE_EXPR_TEST( (tmp2=li1), ((tmp2/=2) == 0) );
PRIVATE_EXPR_TEST( (tmp2=li1), ((tmp2/=li2) == 0) );
BOOST_TEST( li1 * li2 == li2 );
BOOST_TEST( li1 * 2 == li2 );
BOOST_TEST( 1 * li2 == li2 );
PRIVATE_EXPR_TEST( (tmp2=li1), ((tmp2*=2) == li2) );
PRIVATE_EXPR_TEST( (tmp2=li1), ((tmp2*=li2) == li2) );
BOOST_TEST( li2 - li1 == li1 );
BOOST_TEST( li2 - 1 == li1 );
BOOST_TEST( 2 - li1 == li1 );
PRIVATE_EXPR_TEST( (tmp2=li2), ((tmp2-=1) == li1) );
PRIVATE_EXPR_TEST( (tmp2=li2), ((tmp2-=li1) == li1) );
BOOST_TEST( li1 + li1 == li2 );
BOOST_TEST( li1 + 1 == li2 );
BOOST_TEST( 1 + li1 == li2 );
PRIVATE_EXPR_TEST( (tmp2=li1), ((tmp2+=1) == li2) );
PRIVATE_EXPR_TEST( (tmp2=li1), ((tmp2+=li1) == li2) );
cout << "Performed tests on MyLongInt objects.\n";
return boost::exit_success;
}

103
projection_iterator_example.cpp
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@ -1,103 +0,0 @@
// (C) Copyright Jeremy Siek 2000. Permission to copy, use, modify, sell and
// distribute this software is granted provided this copyright notice appears
// in all copies. This software is provided "as is" without express or implied
// warranty, and with no claim as to its suitability for any purpose.
#include <boost/config.hpp>
#include <list>
#include <iostream>
#include <iterator>
#include <algorithm>
#include <string>
#include <boost/iterator/transform_iterator.hpp>
struct personnel_record {
personnel_record(std::string n, int id) : m_name(n), m_ID(id) { }
std::string m_name;
int m_ID;
};
struct select_name {
typedef personnel_record argument_type;
typedef std::string const& result_type;
const std::string& operator()(const personnel_record& r) const {
return r.m_name;
}
std::string& operator()(personnel_record& r) const {
return r.m_name;
}
};
struct select_ID {
typedef personnel_record argument_type;
typedef int& result_type;
const int& operator()(const personnel_record& r) const {
return r.m_ID;
}
int& operator()(personnel_record& r) const {
return r.m_ID;
}
};
int main(int, char*[])
{
std::list<personnel_record> personnel_list;
personnel_list.push_back(personnel_record("Barney", 13423));
personnel_list.push_back(personnel_record("Fred", 12343));
personnel_list.push_back(personnel_record("Wilma", 62454));
personnel_list.push_back(personnel_record("Betty", 20490));
// Example of using transform_iterator to print out the names in the
// personnel list using a projection.
boost::transform_iterator<
select_name
, std::list<personnel_record>::iterator
#ifdef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
, std::string
#endif
>
personnel_first(personnel_list.begin()),
personnel_last(personnel_list.end());
std::copy(personnel_first, personnel_last,
std::ostream_iterator<std::string>(std::cout, "\n"));
std::cout << std::endl;
// Example of using transform_iterator with const_iterators to
// assign new ID numbers to the personnel.
boost::transform_iterator<
select_ID, std::list<personnel_record>::iterator
> ID_first(personnel_list.begin()),
ID_last(personnel_list.end());
int new_id = 0;
while (ID_first != ID_last) {
*ID_first = new_id++;
++ID_first;
}
boost::transform_iterator<
select_ID, std::list<personnel_record>::const_iterator, int const&
>
const_ID_first(personnel_list.begin()),
const_ID_last(personnel_list.end());
std::copy(const_ID_first, const_ID_last,
std::ostream_iterator<int>(std::cout, " "));
std::cout << std::endl;
std::cout << std::endl;
#ifndef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION
// Example of using make_const_projection_iterator()
// to print out the names in the personnel list again.
std::copy(
boost::make_transform_iterator<select_name>(personnel_list.begin())
, boost::make_transform_iterator<select_name>(personnel_list.end())
, std::ostream_iterator<std::string>(std::cout, "\n"));
#endif
return 0;
}

115
ref_ct_test.cpp
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@ -1,115 +0,0 @@
// compile-time test for "boost/ref.hpp" header content
// see 'ref_test.cpp' for run-time part
#include <boost/ref.hpp>
#include <boost/type_traits/same_traits.hpp>
#include <boost/static_assert.hpp>
namespace {
template< typename T, typename U >
void ref_test(boost::reference_wrapper<U>)
{
typedef typename boost::reference_wrapper<U>::type type;
BOOST_STATIC_ASSERT((boost::is_same<U,type>::value));
BOOST_STATIC_ASSERT((boost::is_same<T,type>::value));
}
template< typename T >
void assignable_test(T x)
{
x = x;
}
template< bool R, typename T >
void is_reference_wrapper_test(T)
{
BOOST_STATIC_ASSERT(boost::is_reference_wrapper<T>::value == R);
}
template< typename R, typename Ref >
void cxx_reference_test(Ref)
{
BOOST_STATIC_ASSERT((boost::is_same<R,Ref>::value));
}
template< typename R, typename Ref >
void unwrap_reference_test(Ref)
{
typedef typename boost::unwrap_reference<Ref>::type type;
BOOST_STATIC_ASSERT((boost::is_same<R,type>::value));
}
} // namespace
int main()
{
int i = 0;
int& ri = i;
int const ci = 0;
int const& rci = ci;
// 'ref/cref' functions test
ref_test<int>(boost::ref(i));
ref_test<int>(boost::ref(ri));
ref_test<int const>(boost::ref(ci));
ref_test<int const>(boost::ref(rci));
ref_test<int const>(boost::cref(i));
ref_test<int const>(boost::cref(ri));
ref_test<int const>(boost::cref(ci));
ref_test<int const>(boost::cref(rci));
// test 'assignable' requirement
assignable_test(boost::ref(i));
assignable_test(boost::ref(ri));
assignable_test(boost::cref(i));
assignable_test(boost::cref(ci));
assignable_test(boost::cref(rci));
// 'is_reference_wrapper' test
is_reference_wrapper_test<true>(boost::ref(i));
is_reference_wrapper_test<true>(boost::ref(ri));
is_reference_wrapper_test<true>(boost::cref(i));
is_reference_wrapper_test<true>(boost::cref(ci));
is_reference_wrapper_test<true>(boost::cref(rci));
is_reference_wrapper_test<false>(i);
is_reference_wrapper_test<false, int&>(ri);
is_reference_wrapper_test<false>(ci);
is_reference_wrapper_test<false, int const&>(rci);
// ordinary references/function template arguments deduction test
cxx_reference_test<int>(i);
cxx_reference_test<int>(ri);
cxx_reference_test<int>(ci);
cxx_reference_test<int>(rci);
cxx_reference_test<int&, int&>(i);
cxx_reference_test<int&, int&>(ri);
cxx_reference_test<int const&, int const&>(i);
cxx_reference_test<int const&, int const&>(ri);
cxx_reference_test<int const&, int const&>(ci);
cxx_reference_test<int const&, int const&>(rci);
// 'unwrap_reference' test
unwrap_reference_test<int>(boost::ref(i));
unwrap_reference_test<int>(boost::ref(ri));
unwrap_reference_test<int const>(boost::cref(i));
unwrap_reference_test<int const>(boost::cref(ci));
unwrap_reference_test<int const>(boost::cref(rci));
unwrap_reference_test<int>(i);
unwrap_reference_test<int>(ri);
unwrap_reference_test<int>(ci);
unwrap_reference_test<int>(rci);
unwrap_reference_test<int&, int&>(i);
unwrap_reference_test<int&, int&>(ri);
unwrap_reference_test<int const&, int const&>(i);
unwrap_reference_test<int const&, int const&>(ri);
unwrap_reference_test<int const&, int const&>(ci);
unwrap_reference_test<int const&, int const&>(rci);
return 0;
}

74
ref_test.cpp
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@ -1,74 +0,0 @@
// run-time test for "boost/ref.hpp" header content
// see 'ref_ct_test.cpp' for compile-time part
#if defined(_MSC_VER) && !defined(__ICL)
# pragma warning(disable: 4786) // identifier truncated in debug info
# pragma warning(disable: 4710) // function not inlined
# pragma warning(disable: 4711) // function selected for automatic inline expansion
# pragma warning(disable: 4514) // unreferenced inline removed
#endif
#include <boost/ref.hpp>
#if defined(BOOST_MSVC) && (BOOST_MSVC < 1300)
# pragma warning(push, 3)
#endif
#include <iostream>
#if defined(BOOST_MSVC) && (BOOST_MSVC < 1300)
# pragma warning(pop)
#endif
#define BOOST_INCLUDE_MAIN
#include <boost/test/test_tools.hpp>
namespace {
using namespace boost;
template <class T>
struct ref_wrapper
{
// Used to verify implicit conversion
static T* get_pointer(T& x)
{
return &x;
}
static T const* get_const_pointer(T const& x)
{
return &x;
}
template <class Arg>
static T* passthru(Arg x)
{
return get_pointer(x);
}
template <class Arg>
static T const* cref_passthru(Arg x)
{
return get_const_pointer(x);
}
static void test(T x)
{
BOOST_TEST(passthru(ref(x)) == &x);
BOOST_TEST(&ref(x).get() == &x);
BOOST_TEST(cref_passthru(cref(x)) == &x);
BOOST_TEST(&cref(x).get() == &x);
}
};
} // namespace unnamed
int test_main(int, char * [])
{
ref_wrapper<int>::test(1);
ref_wrapper<int const>::test(1);
return 0;
}

47
reverse_iterator_example.cpp
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@ -1,47 +0,0 @@
// (C) Copyright Jeremy Siek 2000. Permission to copy, use, modify, sell and
// distribute this software is granted provided this copyright notice appears
// in all copies. This software is provided "as is" without express or implied
// warranty, and with no claim as to its suitability for any purpose.
#include <boost/config.hpp>
#include <iostream>
#include <algorithm>
#include <boost/iterator/reverse_iterator.hpp>
#include <boost/detail/iterator.hpp>
//boost::detail::iterator_traits
int main(int, char*[])
{
char letters_[] = "hello world!";
const int N = sizeof(letters_)/sizeof(char) - 1;
typedef char* base_iterator;
base_iterator letters(letters_);
std::cout << "original sequence of letters:\t"
<< letters_ << std::endl;
std::sort(letters, letters + N);
// Use reverse_iterator_generator to print a sequence
// of letters in reverse order.
boost::reverse_iterator<base_iterator>
reverse_letters_first(letters + N),
reverse_letters_last(letters);
std::cout << "letters in descending order:\t";
std::copy(reverse_letters_first, reverse_letters_last,
std::ostream_iterator<char>(std::cout));
std::cout << std::endl;
// Use make_reverse_iterator() to print the sequence
// of letters in reverse-reverse order.
std::cout << "letters in ascending order:\t";
std::copy(boost::make_reverse_iterator(reverse_letters_last),
boost::make_reverse_iterator(reverse_letters_first),
std::ostream_iterator<char>(std::cout));
std::cout << std::endl;
return 0;
}

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shared_container_iterator.html
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<html>
<head>
<meta http-equiv="Content-Type" content="text/html; charset=windows-1252">
<meta name="GENERATOR" content="Microsoft FrontPage 4.0">
<meta name="ProgId" content="FrontPage.Editor.Document">
<title>Shared Container Iterator Documentation</title>
</head>
<body bgcolor="#FFFFFF" text="#000000">
<img src="../../c++boost.gif" alt="c++boost.gif (8819 bytes)"
align="center" width="277" height="86">
<h1>Shared Container Iterator</h1>
Defined in header
<a href="../../boost/shared_container_iterator.hpp">boost/shared_container_iterator.hpp</a>
<p>
The purpose of the shared container iterator is to attach the lifetime
of a container to the lifetime of its iterators. In other words, the
container will not be deleted until after all its iterators are
destroyed. The shared container iterator is typically used to
implement functions that return iterators over a range of objects that
only need to exist for the lifetime of the iterators. By returning a
pair of shared iterators from a function, the callee can return a
heap-allocated range of objects whose lifetime is automatically managed.
<p>
The shared container iterator augments an iterator over a shared
container. It maintains a reference count on the shared
container. If only shared container iterators hold references to
the container, the container's lifetime will end when the last shared
container iterator over it is destroyed. In any case, the shared
container is guaranteed to persist beyond the lifetime of all
the iterators. In all other ways, the
shared container iterator behaves the same as its base iterator.
<h2>Synopsis</h2>
<pre>
namespace boost {
template &lt;typename <a href="http://www.sgi.com/tech/stl/Container.html">Container</a>&gt;
class shared_container_iterator;
template &lt;typename <a href="http://www.sgi.com/tech/stl/Container.html">Container</a>&gt;
shared_container_iterator&lt;Container&gt;
make_shared_container_iterator(typename Container::iterator base,
boost::shared_ptr&lt;Container&gt; const&amp; container);
std::pair&lt;
typename shared_container_iterator&lt;Container&gt;,
typename shared_container_iterator&lt;Container&gt;
&gt;
make_shared_container_range(boost::shared_ptr&lt;Container&gt; const&amp; container);
}
</pre>
<hr>
<h2><a name="generator">The Shared Container Iterator Type</a></h2>
<pre>
template &lt;typename Container&gt; class shared_container_iterator;
</pre>
The class template <tt>shared_container_iterator</tt>
is the shared container iterator type. The <tt>Container</tt> template
type argument must model the
<a href="http://www.sgi.com/tech/stl/Container.html">Container</a>
concept.
<h3>Example</h3>
<p>
The following example illustrates how to create an iterator that
regulates the lifetime of a reference counted <tt>std::vector</tt>.
Though the original shared pointer <tt>ints</tt> ceases to exist
after <tt>set_range()</tt> returns, the
<tt>shared_counter_iterator</tt> objects maintain references to the
underlying vector and thereby extend the container's lifetime.
<p>
<a href="./shared_iterator_example1.cpp">shared_iterator_example1.cpp</a>:
<PRE>
<font color="#008040">#include "shared_container_iterator.hpp"</font>
<font color="#008040">#include "boost/shared_ptr.hpp"</font>
<font color="#008040">#include &lt;algorithm&gt;</font>
<font color="#008040">#include &lt;iostream&gt;</font>
<font color="#008040">#include &lt;vector&gt;</font>
<B>typedef</B> boost::shared_container_iterator&lt; std::vector&lt;<B>int</B>&gt; &gt; iterator;
<B>void</B> set_range(iterator& i, iterator& end) {
boost::shared_ptr&lt; std::vector&lt;<B>int</B>&gt; &gt; ints(<B>new</B> std::vector&lt;<B>int</B>&gt;());
ints-&gt;push_back(<font color="#0000A0">0</font>);
ints-&gt;push_back(<font color="#0000A0">1</font>);
ints-&gt;push_back(<font color="#0000A0">2</font>);
ints-&gt;push_back(<font color="#0000A0">3</font>);
ints-&gt;push_back(<font color="#0000A0">4</font>);
ints-&gt;push_back(<font color="#0000A0">5</font>);
i = iterator(ints-&gt;begin(),ints);
end = iterator(ints-&gt;end(),ints);
}
<B>int</B> main() {
iterator i,end;
set_range(i,end);
std::copy(i,end,std::ostream_iterator&lt;<B>int</B>&gt;(std::cout,<font color="#0000FF">","</font>));
std::cout.put(<font color="#0000FF">'\n'</font>);
<B>return</B> <font color="#0000A0">0</font>;
}
</PRE>
The output from this part is:
<pre>
0,1,2,3,4,5,
</pre>
<h3>Template Parameters</h3>
<Table border>
<TR>
<TH>Parameter</TH><TH>Description</TH>
</TR>
<TR>
<TD><a
href="http://www.sgi.com/tech/stl/Container.html"><tt>Container</tt></a></TD>
<TD>The type of the container that we wish to iterate over. It must be
a model of the
<a href="http://www.sgi.com/tech/stl/Container.html"><tt>Container</tt></a>
concept.
</TD>
</TR>
</Table>
<h3>Model of</h3>
The <tt>shared_container_iterator<Container></tt> type models the
same iterator concept as the base iterator
(<tt>Container::iterator</tt>).
<h3>Members</h3>
The shared container iterator type implements the member functions and
operators required of the <a
href="http://www.sgi.com/tech/stl/RandomAccessIterator.html">Random Access Iterator</a>
concept, though only operations defined for the base iterator will be valid.
In addition it has the following constructor:
<pre>
shared_container_iterator(Container::iterator const&amp; it,
boost::shared_ptr&lt;Container&gt; const&amp; container)
</pre>
<p>
<hr>
<p>
<h2><a name="make_iterator">The Shared Container Iterator Object Generator</a></h2>
<pre>
template &lt;typename Container&gt;
shared_container_iterator&lt;Container&gt;
make_shared_container_iterator(Container::iterator base,
boost::shared_ptr&lt;Container&gt; const&amp; container)
</pre>
This function provides an alternative to directly constructing a
shared container iterator. Using the object generator, a shared
container iterator can be created and passed to a function without
explicitly specifying its type.
<h3>Example</h3>
This example, similar to the previous, uses
<tt>make_shared_container_iterator()</tt> to create the iterators.
<p>
<a href="./shared_iterator_example2.cpp">shared_iterator_example2.cpp</a>:
<PRE>
<font color="#008040">#include "shared_container_iterator.hpp"</font>
<font color="#008040">#include "boost/shared_ptr.hpp"</font>
<font color="#008040">#include &lt;algorithm&gt;</font>
<font color="#008040">#include &lt;iterator&gt;</font>
<font color="#008040">#include &lt;iostream&gt;</font>
<font color="#008040">#include &lt;vector&gt;</font>
<B>template</B> &lt;<B>typename</B> Iterator&gt;
<B>void</B> print_range_nl (Iterator begin, Iterator end) {
<B>typedef</B> <B>typename</B> std::iterator_traits&lt;Iterator&gt;::value_type val;
std::copy(begin,end,std::ostream_iterator&lt;val&gt;(std::cout,<font color="#0000FF">","</font>));
std::cout.put(<font color="#0000FF">'\n'</font>);
}
<B>int</B> main() {
<B>typedef</B> boost::shared_ptr&lt; std::vector&lt;<B>int</B>&gt; &gt; ints_t;
{
ints_t ints(<B>new</B> std::vector&lt;<B>int</B>&gt;());
ints-&gt;push_back(<font color="#0000A0">0</font>);
ints-&gt;push_back(<font color="#0000A0">1</font>);
ints-&gt;push_back(<font color="#0000A0">2</font>);
ints-&gt;push_back(<font color="#0000A0">3</font>);
ints-&gt;push_back(<font color="#0000A0">4</font>);
ints-&gt;push_back(<font color="#0000A0">5</font>);
print_range_nl(boost::make_shared_container_iterator(ints-&gt;begin(),ints),
boost::make_shared_container_iterator(ints-&gt;end(),ints));
}
<B>return</B> <font color="#0000A0">0</font>;
}
</PRE>
Observe that the <tt>shared_container_iterator</tt> type is never
explicitly named. The output from this example is the same as the previous.
<h2><a name="make_range">The Shared Container Iterator Range Generator</a></h2>
<pre>
template &lt;typename Container&gt;
std::pair&lt
shared_container_iterator&lt;Container&gt;,
shared_container_iterator&lt;Container&gt;
&gt;
make_shared_container_range(boost::shared_ptr&lt;Container&gt; const&amp; container);
</pre>
Class <tt>shared_container_iterator</tt> is meant primarily to return,
using iterators, a range of values that we can guarantee will be alive as
long as the iterators are. This is a convenience
function to do just that. It is equivalent to
<pre>
std::make_pair(make_shared_container_iterator(container-&gt;begin(),container),
make_shared_container_iterator(container-&gt;end(),container));
</pre>
<h3>Example</h3>
In the following example, a range of values is returned as a pair of
<tt>shared_container_iterator</tt> objects.
<p>
<a href="./shared_iterator_example3.cpp">shared_iterator_example3.cpp</a>:
<PRE>
<font color="#008040">#include "shared_container_iterator.hpp"</font>
<font color="#008040">#include "boost/shared_ptr.hpp"</font>
<font color="#008040">#include "boost/tuple/tuple.hpp" // for boost::tie</font>
<font color="#008040">#include &lt;algorithm&gt; // for std::copy</font>
<font color="#008040">#include &lt;iostream&gt; </font>
<font color="#008040">#include &lt;vector&gt;</font>
<B>typedef</B> boost::shared_container_iterator&lt; std::vector&lt;<B>int</B>&gt; &gt; iterator;
std::pair&lt;iterator,iterator&gt;
return_range() {
boost::shared_ptr&lt; std::vector&lt;<B>int</B>&gt; &gt; range(<B>new</B> std::vector&lt;<B>int</B>&gt;());
range-&gt;push_back(<font color="#0000A0">0</font>);
range-&gt;push_back(<font color="#0000A0">1</font>);
range-&gt;push_back(<font color="#0000A0">2</font>);
range-&gt;push_back(<font color="#0000A0">3</font>);
range-&gt;push_back(<font color="#0000A0">4</font>);
range-&gt;push_back(<font color="#0000A0">5</font>);
<B>return</B> boost::make_shared_container_range(range);
}
<B>int</B> main() {
iterator i,end;
boost::tie(i,end) = return_range();
std::copy(i,end,std::ostream_iterator&lt;<B>int</B>&gt;(std::cout,<font color="#0000FF">","</font>));
std::cout.put(<font color="#0000FF">'\n'</font>);
<B>return</B> <font color="#0000A0">0</font>;
}
</PRE>
Though the <tt>range</tt> object only lives for the duration of the
<tt>return_range</tt> call, the reference counted
<tt>std::vector</tt> will live until <tt>i</tt> and <tt>end</tt>
are both destroyed. The output from this example is the same as
the previous two.
<hr>
<!-- hhmts start -->
Last modified: Mon Aug 11 11:27:03 EST 2003
<!-- hhmts end -->
<p><EFBFBD> Copyright 2003 The Trustees of Indiana University.
Use, modification and distribution is 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)</p>
</body>
</html>

42
shared_iterator_example1.cpp
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@ -1,42 +0,0 @@
// Copyright 2003 The Trustees of Indiana University.
// Use, modification and distribution is 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)
#include "boost/shared_container_iterator.hpp"
#include "boost/shared_ptr.hpp"
#include <algorithm>
#include <iostream>
#include <vector>
typedef boost::shared_container_iterator< std::vector<int> > iterator;
void set_range(iterator& i, iterator& end) {
boost::shared_ptr< std::vector<int> > ints(new std::vector<int>());
ints->push_back(0);
ints->push_back(1);
ints->push_back(2);
ints->push_back(3);
ints->push_back(4);
ints->push_back(5);
i = iterator(ints->begin(),ints);
end = iterator(ints->end(),ints);
}
int main() {
iterator i,end;
set_range(i,end);
std::copy(i,end,std::ostream_iterator<int>(std::cout,","));
std::cout.put('\n');
return 0;
}

43
shared_iterator_example2.cpp
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@ -1,43 +0,0 @@
// Copyright 2003 The Trustees of Indiana University.
// Use, modification and distribution is 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)
#include "boost/shared_container_iterator.hpp"
#include "boost/shared_ptr.hpp"
#include <algorithm>
#include <iterator>
#include <iostream>
#include <vector>
template <typename Iterator>
void print_range_nl (Iterator begin, Iterator end) {
typedef typename std::iterator_traits<Iterator>::value_type val;
std::copy(begin,end,std::ostream_iterator<val>(std::cout,","));
std::cout.put('\n');
}
int main() {
typedef boost::shared_ptr< std::vector<int> > ints_t;
{
ints_t ints(new std::vector<int>());
ints->push_back(0);
ints->push_back(1);
ints->push_back(2);
ints->push_back(3);
ints->push_back(4);
ints->push_back(5);
print_range_nl(boost::make_shared_container_iterator(ints->begin(),ints),
boost::make_shared_container_iterator(ints->end(),ints));
}
return 0;
}

41
shared_iterator_example3.cpp
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@ -1,41 +0,0 @@
// Copyright 2003 The Trustees of Indiana University.
// Use, modification and distribution is 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)
#include "boost/shared_container_iterator.hpp"
#include "boost/shared_ptr.hpp"
#include "boost/tuple/tuple.hpp" // for boost::tie
#include <algorithm> // for std::copy
#include <iostream>
#include <vector>
typedef boost::shared_container_iterator< std::vector<int> > iterator;
std::pair<iterator,iterator>
return_range() {
boost::shared_ptr< std::vector<int> > range(new std::vector<int>());
range->push_back(0);
range->push_back(1);
range->push_back(2);
range->push_back(3);
range->push_back(4);
range->push_back(5);
return boost::make_shared_container_range(range);
}
int main() {
iterator i,end;
boost::tie(i,end) = return_range();
std::copy(i,end,std::ostream_iterator<int>(std::cout,","));
std::cout.put('\n');
return 0;
}

64
shared_iterator_test.cpp
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@ -1,64 +0,0 @@
// Copyright 2003 The Trustees of Indiana University.
// Use, modification and distribution is 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)
// Shared container iterator adaptor
// Author: Ronald Garcia
// See http://boost.org/libs/utility/shared_container_iterator.html
// for documentation.
//
// shared_iterator_test.cpp - Regression tests for shared_container_iterator.
//
#include "boost/shared_container_iterator.hpp"
#include "boost/shared_ptr.hpp"
#include <vector>
#include <cassert>
struct resource {
static int count;
resource() { ++count; }
resource(resource const&) { ++count; }
~resource() { --count; }
};
int resource::count = 0;
typedef std::vector<resource> resources_t;
typedef boost::shared_container_iterator< resources_t > iterator;
void set_range(iterator& i, iterator& end) {
boost::shared_ptr< resources_t > objs(new resources_t());
for (int j = 0; j != 6; ++j)
objs->push_back(resource());
i = iterator(objs->begin(),objs);
end = iterator(objs->end(),objs);
assert(resource::count == 6);
}
int main() {
assert(resource::count == 0);
{
iterator i;
{
iterator end;
set_range(i,end);
assert(resource::count == 6);
}
assert(resource::count == 6);
}
assert(resource::count == 0);
return 0;
}

44
test/Jamfile
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@ -1,44 +0,0 @@
# Copyright David Abrahams 2003. Permission to copy, use,
# modify, sell and distribute this software is granted provided this
# copyright notice appears in all copies. This software is provided
# "as is" without express or implied warranty, and with no claim as
# to its suitability for any purpose.
# For more information, see http://www.boost.org/
# Testing Jamfile autogenerated from XML source
subproject libs/utility/test ;
# bring in rules for testing
import testing ;
# Make tests run by default.
DEPENDS all : test ;
local test_monitor = <lib>@boost/libs/test/build/boost_test_exec_monitor ;
test-suite utility
:
[ run ../iterator_traits_test.cpp ]
[ run ../iterators_test.cpp $(test_monitor) ]
[ compile-fail ../noncopyable_test.cpp ]
[ run ../numeric_traits_test.cpp ]
[ run ../operators_test.cpp $(test_monitor) ]
[ run ../binary_search_test.cpp ]
[ run ../call_traits_test.cpp : -u ]
[ compile-fail ../checked_delete_test.cpp ]
[ run ../compressed_pair_test.cpp $(test_monitor) : -u ]
[ run ../addressof_test.cpp $(test_monitor) ]
[ run ../ref_test.cpp $(test_monitor) ]
[ run ../enable_if_constructors.cpp $(test_monitor) ]
[ run ../enable_if_dummy_arg_disambiguation.cpp $(test_monitor) ]
[ run ../enable_if_lazy.cpp $(test_monitor) ]
[ run ../enable_if_lazy_test.cpp $(test_monitor) ]
[ run ../enable_if_member_templates.cpp $(test_monitor) ]
[ run ../enable_if_namespace_disambiguation.cpp $(test_monitor) ]
[ run ../enable_if_no_disambiguation.cpp $(test_monitor) ]
[ run ../enable_if_partial_specializations.cpp $(test_monitor) ]
[ run next_prior_test.cpp $(test_monitor) ]
[ compile result_of_test.cpp ]
;

35
test/Jamfile.v2
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@ -1,35 +0,0 @@
# Copyright David Abrahams 2003. Permission to copy, use,
# modify, sell and distribute this software is granted provided this
# copyright notice appears in all copies. This software is provided
# "as is" without express or implied warranty, and with no claim as
# to its suitability for any purpose.
# For more information, see http://www.boost.org/
# bring in rules for testing
import testing ;
test-suite utility
:
[ run ../iterator_traits_test.cpp ]
[ run ../iterators_test.cpp ../../test/build//boost_test_exec_monitor ]
[ compile-fail ../noncopyable_test.cpp ]
[ run ../numeric_traits_test.cpp ]
[ run ../operators_test.cpp ../../test/build//boost_test_exec_monitor ]
[ run ../binary_search_test.cpp ]
[ run ../call_traits_test.cpp : -u ]
[ compile-fail ../checked_delete_test.cpp ]
[ run ../compressed_pair_test.cpp ../../test/build//boost_test_exec_monitor : -u ]
[ run ../addressof_test.cpp ../../test/build//boost_test_exec_monitor ]
[ run ../ref_test.cpp ../../test/build//boost_test_exec_monitor ]
[ run ../enable_if_constructors.cpp ../../test/build//boost_test_exec_monitor ]
[ run ../enable_if_dummy_arg_disambiguation.cpp ../../test/build//boost_test_exec_monitor ]
[ run ../enable_if_lazy.cpp ../../test/build//boost_test_exec_monitor ]
[ run ../enable_if_lazy_test.cpp ../../test/build//boost_test_exec_monitor ]
[ run ../enable_if_member_templates.cpp ../../test/build//boost_test_exec_monitor ]
[ run ../enable_if_namespace_disambiguation.cpp ../../test/build//boost_test_exec_monitor ]
[ run ../enable_if_no_disambiguation.cpp ../../test/build//boost_test_exec_monitor ]
[ run ../enable_if_partial_specializations.cpp ../../test/build//boost_test_exec_monitor ]
[ run next_prior_test.cpp ../../test/build//boost_test_exec_monitor ]
[ compile result_of_test.cpp ]
;

79
test/next_prior_test.cpp
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@ -1,79 +0,0 @@
// Boost test program for next() and prior() utilities.
// Copyright 2003 Daniel Walker. Use, modification, and distribution
// are subject to the Boost Software License, Version 1.0. (See
// accompanying file LICENSE_1_0.txt or a copy at
// http://www.boost.org/LICENSE_1_0.txt.)
// See http://www.boost.org/libs/utility for documentation.
// Revision History 13 Dec 2003 Initial Version (Daniel Walker)
// next() and prior() are replacements for operator+ and operator- for
// non-random-access iterators. The semantics of these operators are
// such that after executing j = i + n, std::distance(i, j) equals
// n. Tests are provided to ensure next() has the same
// result. Parallel tests are provided for prior(). The tests call
// next() and prior() several times. next() and prior() are very
// simple functions, though, and it would be very strange if these
// tests were to fail.
#define BOOST_INCLUDE_MAIN
#include <boost/test/test_tools.hpp>
#include <list>
#include <vector>
#include <boost/next_prior.hpp>
template<class RandomAccessIterator, class ForwardIterator>
bool plus_one_test(RandomAccessIterator first, RandomAccessIterator last, ForwardIterator first2)
{
RandomAccessIterator i = first;
ForwardIterator j = first2;
while(i != last)
i = i + 1, j = boost::next(j);
return std::distance(first, i) == std::distance(first2, j);
}
template<class RandomAccessIterator, class ForwardIterator>
bool plus_n_test(RandomAccessIterator first, RandomAccessIterator last, ForwardIterator first2)
{
RandomAccessIterator i = first;
ForwardIterator j = first2;
for(int n = 0; i != last; ++n)
i = first + n, j = boost::next(first2, n);
return std::distance(first, i) == std::distance(first2, j);
}
template<class RandomAccessIterator, class BidirectionalIterator>
bool minus_one_test(RandomAccessIterator first, RandomAccessIterator last, BidirectionalIterator last2)
{
RandomAccessIterator i = last;
BidirectionalIterator j = last2;
while(i != first)
i = i - 1, j = boost::prior(j);
return std::distance(i, last) == std::distance(j, last2);
}
template<class RandomAccessIterator, class BidirectionalIterator>
bool minus_n_test(RandomAccessIterator first, RandomAccessIterator last, BidirectionalIterator last2)
{
RandomAccessIterator i = last;
BidirectionalIterator j = last2;
for(int n = 0; i != first; ++n)
i = last - n, j = boost::prior(last2, n);
return std::distance(i, last) == std::distance(j, last2);
}
int test_main(int, char*[])
{
std::vector<int> x(8);
std::list<int> y(x.begin(), x.end());
BOOST_REQUIRE(plus_one_test(x.begin(), x.end(), y.begin()));
BOOST_REQUIRE(plus_n_test(x.begin(), x.end(), y.begin()));
BOOST_REQUIRE(minus_one_test(x.begin(), x.end(), y.end()));
BOOST_REQUIRE(minus_n_test(x.begin(), x.end(), y.end()));
return 0;
}

45
test/result_of_test.cpp
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#include <boost/utility/result_of.hpp>
#include <utility>
#include <boost/static_assert.hpp>
#include <boost/type_traits/is_same.hpp>
struct int_result_type { typedef int result_type; };
struct int_result_of
{
template<typename F> struct result { typedef int type; };
};
struct int_result_type_and_float_result_of
{
typedef int result_type;
template<typename F> struct result { typedef float type; };
};
struct X {};
int main()
{
using namespace boost;
typedef int (*func_ptr)(float, double);
typedef int (&func_ref)(float, double);
typedef int (X::*mem_func_ptr)(float);
typedef int (X::*mem_func_ptr_c)(float) const;
typedef int (X::*mem_func_ptr_v)(float) volatile;
typedef int (X::*mem_func_ptr_cv)(float) const volatile;
BOOST_STATIC_ASSERT((is_same<result_of<int_result_type(float)>::type, int>::value));
BOOST_STATIC_ASSERT((is_same<result_of<int_result_of(double)>::type, int>::value));
BOOST_STATIC_ASSERT((is_same<result_of<int_result_of(void)>::type, void>::value));
BOOST_STATIC_ASSERT((is_same<result_of<const int_result_of(double)>::type, int>::value));
BOOST_STATIC_ASSERT((is_same<result_of<volatile int_result_of(void)>::type, void>::value));
BOOST_STATIC_ASSERT((is_same<result_of<int_result_type_and_float_result_of(char)>::type, int>::value));
BOOST_STATIC_ASSERT((is_same<result_of<func_ptr(char, float)>::type, int>::value));
BOOST_STATIC_ASSERT((is_same<result_of<func_ref(char, float)>::type, int>::value));
BOOST_STATIC_ASSERT((is_same<result_of<mem_func_ptr(X,char)>::type, int>::value));
BOOST_STATIC_ASSERT((is_same<result_of<mem_func_ptr_c(X,char)>::type, int>::value));
BOOST_STATIC_ASSERT((is_same<result_of<mem_func_ptr_v(X,char)>::type, int>::value));
BOOST_STATIC_ASSERT((is_same<result_of<mem_func_ptr_cv(X,char)>::type, int>::value));
return 0;
}

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throw_exception.html
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<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.0 Transitional//EN">
<html>
<head>
<title>Boost: throw_exception.hpp documentation</title>
<meta http-equiv="Content-Type" content="text/html; charset=iso-8859-1">
</head>
<body bgcolor="white" style="MARGIN-LEFT: 5%; MARGIN-RIGHT: 5%">
<table border="0" width="100%">
<tr>
<td width="277">
<img src="../../c++boost.gif" alt="c++boost.gif (8819 bytes)" width="277" height="86">
</td>
<td align="middle">
<h1>throw_exception.hpp</h1>
</td>
</tr>
<tr>
<td colspan="2" height="64">&nbsp;</td>
</tr>
</table>
<p>
The header <STRONG>&lt;boost/throw_exception.hpp&gt;</STRONG> defines the
helper function <STRONG>boost::throw_exception</STRONG>. It is intended to be
used in Boost libraries that need to throw exceptions, but support
configurations and platforms where exceptions aren't available, as indicated by
the presence of the <STRONG>BOOST_NO_EXCEPTIONS</STRONG> <A href="../config/config.htm#macro_ref">
configuration macro</A>.
</p>
<P>When <STRONG>BOOST_NO_EXCEPTIONS</STRONG> is not defined, <tt>boost::throw_exception(e)</tt>
is equivalent to <tt>throw e</tt>. Otherwise, the function is left undefined,
and the user is expected to supply an appropriate definition. Callers of <tt>throw_exception</tt>
are allowed to assume that the function never returns; therefore, if the
user-defined <tt>throw_exception</tt> returns, the behavior is undefined.</P>
<h3><a name="Synopsis">Synopsis</a></h3>
<pre>
namespace boost
{
#ifdef BOOST_NO_EXCEPTIONS
void throw_exception(std::exception const &amp; e); // user defined
#else
template&lt;class E&gt; void throw_exception(E const &amp; e)
{
throw e;
}
#endif
}
</pre>
<p><br>
<small>Copyright <20> 2002 by Peter Dimov. Permission to copy, use, modify, sell and
distribute this document is granted provided this copyright notice appears in
all copies. This document is provided "as is" without express or implied
warranty, and with no claim as to its suitability for any purpose.</small></p>
</body>
</html>

76
transform_iterator_example.cpp
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// (C) Copyright Jeremy Siek 2000. Permission to copy, use, modify, sell and
// distribute this software is granted provided this copyright notice appears
// in all copies. This software is provided "as is" without express or implied
// warranty, and with no claim as to its suitability for any purpose.
#include <functional>
#include <algorithm>
#include <iostream>
#include <boost/iterator/transform_iterator.hpp>
// What a bummer. We can't use std::binder1st with transform iterator
// because it does not have a default constructor. Here's a version
// that does.
namespace boost {
template <class Operation>
class binder1st
: public std::unary_function<typename Operation::second_argument_type,
typename Operation::result_type> {
protected:
Operation op;
typename Operation::first_argument_type value;
public:
binder1st() { } // this had to be added!
binder1st(const Operation& x,
const typename Operation::first_argument_type& y)
: op(x), value(y) {}
typename Operation::result_type
operator()(const typename Operation::second_argument_type& x) const {
return op(value, x);
}
};
template <class Operation, class T>
inline binder1st<Operation> bind1st(const Operation& op, const T& x) {
typedef typename Operation::first_argument_type arg1_type;
return binder1st<Operation>(op, arg1_type(x));
}
} // namespace boost
int
main(int, char*[])
{
// This is a simple example of using the transform_iterators class to
// generate iterators that multiply the value returned by dereferencing
// the iterator. In this case we are multiplying by 2.
// Would be cooler to use lambda library in this example.
int x[] = { 1, 2, 3, 4, 5, 6, 7, 8 };
const int N = sizeof(x)/sizeof(int);
typedef boost::binder1st< std::multiplies<int> > Function;
typedef boost::transform_iterator<Function, int*> doubling_iterator;
doubling_iterator i(x, boost::bind1st(std::multiplies<int>(), 2)),
i_end(x + N, boost::bind1st(std::multiplies<int>(), 2));
std::cout << "multiplying the array by 2:" << std::endl;
while (i != i_end)
std::cout << *i++ << " ";
std::cout << std::endl;
std::cout << "adding 4 to each element in the array:" << std::endl;
std::copy(boost::make_transform_iterator(x, boost::bind1st(std::plus<int>(), 4)),
boost::make_transform_iterator(x + N, boost::bind1st(std::plus<int>(), 4)),
std::ostream_iterator<int>(std::cout, " "));
std::cout << std::endl;
return 0;
}

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utility.htm
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@ -1,192 +0,0 @@
<html>
<head>
<meta http-equiv="Content-Type" content="text/html; charset=iso-8859-1">
<title>Header boost/utility.hpp Documentation</title>
</head>
<body bgcolor="#FFFFFF" text="#000000">
<h1><img src="../../c++boost.gif" alt="c++boost.gif (8819 bytes)" align="center" WIDTH="277" HEIGHT="86">Header
<a href="../../boost/utility.hpp">boost/utility.hpp</a></h1>
<p>The entire contents of the header <code><a href="../../boost/utility.hpp">&lt;boost/utility.hpp&gt;</a></code>
are in <code>namespace boost</code>.</p>
<h2>Contents</h2>
<ul>
<li>
Class templates supporting the <a href="base_from_member.html">base-from-member
idiom</a></li>
<li>
Function templates <a href="#checked_delete">checked_delete() and
checked_array_delete()</a></li>
<li>
Function templates <a href="#functions_next_prior">next() and prior()</a></li>
<li>
Class <a href="#Class_noncopyable">noncopyable</a></li>
<li>
Function template <a href="#addressof">addressof()</a></li>
<li>Class template <a href="#result_of">result_of</a></li>
</ul>
<h2>
Function templates <a name="checked_delete">checked_delete</a>() and
checked_array_delete()</h2>
<p>See <a href="checked_delete.html">separate documentation</a>.</p>
<h2>
<a name="functions_next_prior">Function</a> templates next() and prior()</h2>
<p>Certain data types, such as the C++ Standard Library's forward and bidirectional
iterators, do not provide addition and subtraction via operator+() or
operator-().&nbsp; This means that non-modifying computation of the next or
prior value requires a temporary, even though operator++() or operator--() is
provided.&nbsp; It also means that writing code like <code>itr+1</code> inside
a template restricts the iterator category to random access iterators.</p>
<p>The next() and prior() functions provide a simple way around these problems:</p>
<blockquote>
<pre>template &lt;class T&gt;
T next(T x) { return ++x; }
template &lt;class T, class Distance&gt;
T next(T x, Distance n)
{
std::advance(x, n);
return x;
}
template &lt;class T&gt;
T prior(T x) { return --x; }
template &lt;class T, class Distance&gt;
T prior(T x, Distance n)
{
std::advance(x, -n);
return x;
}</pre>
</blockquote>
<p>Usage is simple:</p>
<blockquote>
<pre>const std::list&lt;T&gt;::iterator p = get_some_iterator();
const std::list&lt;T&gt;::iterator prev = boost::prior(p);
const std::list&lt;T&gt;::iterator next = boost::next(prev, 2);</pre>
</blockquote>
<p>The distance from the given iterator should be supplied as an absolute value. For
example, the iterator four iterators prior to the given iterator <code>p</code>
may be obtained by <code>prior(p, 4)</code>.</p>
<p>Contributed by <a href="../../people/dave_abrahams.htm">Dave Abrahams</a>. Two-argument versions by Daniel Walker.</p>
<h2><a name="Class_noncopyable">Class noncopyable</a></h2>
<p>Class <strong>noncopyable</strong> is a base class.&nbsp; Derive your own class
from <strong>noncopyable</strong> when you want to prohibit copy construction
and copy assignment.</p>
<p>Some objects, particularly those which hold complex resources like files or
network connections, have no sensible copy semantics.&nbsp; Sometimes there are
possible copy semantics, but these would be of very limited usefulness and be
very difficult to implement correctly.&nbsp; Sometimes you're implementing a
class that doesn't need to be copied just yet and you don't want to take the
time to write the appropriate functions.&nbsp; Deriving from <b>noncopyable</b>
will prevent the otherwise implicitly-generated functions (which don't have the
proper semantics) from becoming a trap for other programmers.</p>
<p>The traditional way to deal with these is to declare a private copy constructor
and copy assignment, and then document why this is done.&nbsp; But deriving
from <b>noncopyable</b> is simpler and clearer, and doesn't require additional
documentation.</p>
<p>The program <a href="noncopyable_test.cpp">noncopyable_test.cpp</a> can be used
to verify class <b>noncopyable</b> works as expected. It has have been run
successfully under GCC 2.95, Metrowerks CodeWarrior 5.0, and Microsoft Visual
C++ 6.0 sp 3.</p>
<p>Contributed by <a href="../../people/dave_abrahams.htm">Dave Abrahams</a>.</p>
<h3>Example</h3>
<blockquote>
<pre>// inside one of your own headers ...
#include &lt;boost/utility.hpp&gt;
class ResourceLadenFileSystem : boost::noncopyable {
...</pre>
</blockquote>
<h3>Rationale</h3>
<p>Class noncopyable has protected constructor and destructor members to emphasize
that it is to be used only as a base class.&nbsp; Dave Abrahams notes concern
about the effect on compiler optimization of adding (even trivial inline)
destructor declarations. He says &quot;Probably this concern is misplaced,
because noncopyable will be used mostly for classes which own resources and
thus have non-trivial destruction semantics.&quot;</p>
<h2><a name="addressof">Function template addressof()</a></h2>
<p>Function <strong>addressof()</strong> returns the address of an object.</p>
<blockquote>
<pre>template &lt;typename T&gt; inline T* addressof(T& v);
template &lt;typename T&gt; inline const T* addressof(const T& v);
template &lt;typename T&gt; inline volatile T* addressof(volatile T& v);
template &lt;typename T&gt; inline const volatile T* addressof(const volatile T& v);
</pre>
</blockquote>
<p>C++ allows programmers to replace the unary <strong>operator&()</strong> class
member used to get the address of an object. Getting the real address of an
object requires ugly casting tricks to avoid invoking the overloaded <strong>operator&()</strong>.
Function <strong>addressof()</strong> provides a wrapper around the necessary
code to make it easy to get an object's real address.
</p>
<p>The program <a href="addressof_test.cpp">addressof_test.cpp</a> can be used to
verify that <b>addressof()</b> works as expected.</p>
<p>Contributed by Brad King based on ideas from discussion with Doug Gregor.</p>
<h3>Example</h3>
<blockquote>
<pre>#include &lt;boost/utility.hpp&gt;
struct useless_type {};
class nonaddressable {
useless_type operator&() const;
};
void f() {
nonaddressable x;
nonaddressable* xp = boost::addressof(x);
// nonaddressable* xpe = &amp;x; /* error */
}</pre>
</blockquote>
<h2><a name="result_of">Class template
result_of</a></h2> <p>The class template
<code>result_of</code> helps determine the type of a
call expression. Given an lvalue <code>f</code> of
type <code>F</code> and lvalues <code>t1</code>,
<code>t2</code>, ..., <code>t<em>N</em></code> of
types <code>T1</code>, <code>T2</code>, ...,
<code>T<em>N</em></code>, respectively, the type
<code>result_of&lt;F(T1, T2, ...,
T<em>N</em>)&gt;::type</code> defines the result type
of the expression <code>f(t1, t2,
...,t<em>N</em>)</code>. The implementation permits
the type <code>F</code> to be a function pointer,
function reference, member function pointer, or class
type. When <code>F</code> is a class type with a
member type <code>result_type</code>,
<code>result_of&lt;F(T1, T2, ...,
T<em>N</em>)&gt;</code> is
<code>F::result_type</code>. Otherwise,
<code>result_of&lt;F(T1, T2, ...,
T<em>N</em>)&gt;</code> is <code>F::result&lt;F(T1,
T2, ..., T<em>N</em>)&gt;::type</code> when
<code><em>N</em> &gt; 0</code> or <code>void</code>
when <code><em>N</em> = 0</code>. For additional
information about <code>result_of</code>, see the
current draft of the C++ Library TR, <a
href="http://anubis.dkuug.dk/jtc1/sc22/wg21/docs/papers/2004/n1647.pdf">N1647</a>,
or the <code>result_of</code> <a
href="http://anubis.dkuug.dk/jtc1/sc22/wg21/docs/papers/2003/n1454.html">proposal</a>.</p>
<p>Class template <code>result_of</code> resides in
the header <code>&lt;<a
href="../../boost/utility/result_of.hpp">boost/utility/result_of.hpp</a>&gt;</code>. By
default, <em>N</em> may be any value between 0 and
10. To change the upper limit, define the macro
<code>BOOST_RESULT_OF_NUM_ARGS</code> to the maximum
value for <em>N</em>.</p>
<p>This implementation of <code>result_of</code> requires class template partial specialization, the ability to parse function types properly, and support for SFINAE. Contributed by Doug Gregor.</p>
<h2>Class templates for the Base-from-Member Idiom</h2>
<p>See <a href="base_from_member.html">separate documentation</a>.</p>
<hr>
<p>Revised&nbsp; <!--webbot bot="Timestamp" S-Type="EDITED" S-Format="%d %B, %Y" startspan
-->02 May, 2004<!--webbot bot="Timestamp" endspan i-checksum="38582"
-->
</p>
<p>&copy; Copyright boost.org 1999-2003. Permission to copy, use, modify, sell and distribute
this document is granted provided this copyright notice appears in all copies.
This document is provided &quot;as is&quot; without express or implied
warranty, and with no claim as to its suitability for any purpose.</p>
</body>
</html>

219
value_init.htm
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<html>
<head>
<meta http-equiv="Content-Type"
content="text/html; charset=iso-8859-1">
<title>value_initialized</title>
</head>
<body vlink="#800080" link="#0000ff" text="#000000" bgcolor="#ffffff">
<h2><img src="../../c++boost.gif" width="276" height="86">
Header &lt;<a href="../../boost/utility/value_init.hpp">boost/utility/value_init.hpp</a>&gt;
</h2>
<h2>Contents</h2>
<dl>
<dt><a href="#intro">Rationale</a></dt>
<dt><a href="#rationale">Introduction</a></dt>
</dl>
<ul>
<li><a href="#valueinit">value-initialization</a></li>
<li><a href="#valueinitsyn">value-initialization syntax</a></li>
</ul>
<dl class="page-index">
<dt><a href="#types">Types</a></dt>
</dl>
<ul>
<li><a href="#val_init"><code>value_initialized&lt;&gt;</code></a></li>
</ul>
<a href="#acknowledgements">Acknowledgements</a><br>
<br>
<hr>
<h2><a name="rationale"></a>Rationale</h2>
<p>Constructing and initializing objects in a generic way is difficult in
C++. The problem is that there are several different rules that apply
for initialization. Depending on the type, the value of a newly constructed
object can be zero-initialized (logically 0), default-constructed (using
the default constructor), or indeterminate. When writing generic code,
this problem must be addressed. <code>value_initialized</code> provides
a solution with consistent syntax for value initialization of scalar,
union and class types. <br>
</p>
<h2><a name="into"></a>Introduction</h2>
<p>The C++ standard [<a href="#references">1</a>] contains the definitions
of <code>zero-initialization</code> and <code>default-initialization</code>.
Informally, zero-initialization means that the object is given the initial
value 0 (converted to the type) and default-initialization means that
POD [<a href="#references">2</a>] types are zero-initialized, while class
types are initialized with their corresponding default constructors. A
<i>declaration</i> can contain an <i>initializer</i>, which specifies the
object's initial value. The initializer can be just '()', which states that
the object shall be default-initialized (but see below). However, if a <i>declaration</i>
has no <i>initializer</i> and it is of a non-<code>const</code>, non-<code>static</code>
POD type, the initial value is indeterminate:<cite>(see &sect;8.5 for the
accurate definitions).</cite></p>
<pre>int x ; // no initializer. x value is indeterminate.<br>std::string s ; // no initializer, s is default-constructed.<br><br>int y = int() ; <br>// y is initialized using copy-initialization<br>// but the temporary uses an empty set of parentheses as the initializer,<br>// so it is default-constructed.<br>// A default constructed POD type is zero-initialized,<br>// therefore, y == 0.<br><br>void foo ( std::string ) ;<br>foo ( std::string() ) ; <br>// the temporary string is default constructed <br>// as indicated by the initializer () </pre>
<h3><a name="valueinit">value-initialization</a></h3>
<p>The first <a
href="http://anubis.dkuug.dk/JTC1/SC22/WG21/docs/cwg_defects.html">Technical
Corrigendum for the C++ Standard</a> (TC1), whose draft was released to
the public in November 2001, introduced <a
href="http://anubis.dkuug.dk/JTC1/SC22/WG21/docs/cwg_defects.html#178">Core
Issue 178</a> (among many other issues, of course).</p>
<p> That issue introduced the new concept of <code>value-initialization</code>
(it also fixed the wording for zero-initialization). Informally, value-initialization
is similar to default-initialization with the exception that in some cases
non-static data members and base class sub-objects are also value-initialized.
The difference is that an object that is value-initialized won't have
(or at least is less likely to have) indeterminate values for data members
and base class sub-objects; unlike the case of an object default constructed.
(see Core Issue 178 for a normative description).</p>
<p>In order to specify value-initialization of an object we need to use the
empty-set initializer: (). </p>
<p><i>(but recall that the current C++ Standard states that '()' invokes default-initialization,
not value-initialization)</i></p>
<p>As before, a declaration with no intializer specifies default-initialization,
and a declaration with a non-empty initializer specifies copy (=xxx) or
direct (xxx) initialization. </p>
<pre>template&lt;class T&gt; void eat(T);<br>int x ; // indeterminate initial value.<br>std::string s; // default-initialized.<br>eat ( int() ) ; // value-initialized<br>eat ( std::string() ) ; // value-initialied</pre>
<h4><a name="valueinitsyn">value-initialization</a> syntax</h4>
<p>Value initialization is specified using (). However, the empty set of
parentheses is not permitted by the syntax of initializers because it is
parsed as the declaration of a function taking no arguments: </p>
<pre>int x() ; // declares function int(*)()<br>int y ( int() ) ; // decalares function int(*)( int(*)() )</pre>
<p>Thus, the empty () must be put in some other initialization context.</p>
<p>One alternative is to use copy-initialization syntax:</p>
<pre>int x = int() ;</pre>
<p>This works perfectly fine for POD types. But for non-POD class types,
copy-initialization searches for a suitable constructor, which could be,
for instance, the copy-constructor (it also searches for a suitable conversion
sequence but this doesn't apply in this context). For an arbitrary unknown
type, using this syntax may not have the value-initialization effect intended
because we don't know if a copy from a default constructed object is exactly
the same as a default constructed object, and the compiler is allowed (in
some cases), but never required to, optimize the copy away.</p>
<p>One possible generic solution is to use value-initialization of a non static
data member:</p>
<pre>template&lt;class T&gt; <br>struct W <br>{<br> // value-initialization of 'data' here.<br> W() : data() {}<br> T data ;<br>} ;<br>W&lt;int&gt; w ;<br>// w.data is value-initialized for any type. </pre>
<p><code>This is the solution supplied by the value_initialized&lt;&gt; template
class.</code></p>
<h2><a name="types"></a>Types</h2>
<h2><a name="val_init"><code>template class value_initialized&lt;T&gt;</code></a></h2>
<pre>namespace boost {<br><br>template&lt;class T&gt;<br>class value_initialized<br>{<br> public :<br> value_initialized() : x() {}<br> operator T&amp;() const { return x ; }<br> T&amp; data() const { return x ; }<br><br> private :<br> <i>impll-defined</i> x ;<br>} ;<br><br>template&lt;class T&gt;<br>T const&amp; get ( value_initialized&lt;T&gt; const&amp; x )<br>{<br> return x.data() ;<br>}<br><br>template&lt;class T&gt;<br>T&amp; get ( value_initialized&lt;T&gt;&amp; x )<br>{<br> return x.data() ;<br>}<br><br>} // namespace boost<br></pre>
<p>An object of this template class is a <code>T</code>-wrapper convertible
to <code>'T&amp;'</code> whose wrapped object (data member of type <code>T</code>)
is <a href="#valueinit">value-initialized</a> upon default-initialization
of this wrapper class: </p>
<pre>int zero = 0 ;<br>value_initialized&lt;int&gt; x ;<br>assert ( x == zero ) ;<br><br>std::string def ;<br>value_initialized&lt; std::string &gt; y ;<br>assert ( y == def ) ;<br></pre>
<p>The purpose of this wrapper is to provide a consistent syntax for value
initialization of scalar, union and class types (POD and non-POD) since
the correct syntax for value initialization varies (see <a
href="#valueinitsyn">value-initialization syntax</a>)</p>
<p>The wrapped object can be accessed either through the conversion operator
<code>T&amp;</code>, the member function <code>data()</code>, or the
non-member function <code>get()</code>: </p>
<pre>void watch(int);<br>value_initialized&lt;int&gt; x;<br><br>watch(x) ; // operator T&amp; used.<br>watch(x.data());<br>watch( get(x) ) // function get() used</pre>
<p>Both <code>const</code> and non-<code>const</code> objects can be wrapped.
Mutable objects can be modified directly from within the wrapper but constant
objects cannot:</p>
<pre>value_initialized&lt;int&gt; x ; <br>static_cast&lt;int&amp;&gt;(x) = 1 ; // OK<br>get(x) = 1 ; // OK<br><br>value_initialized&lt;int const&gt; y ; <br>static_cast&lt;int&amp;&gt;(y) = 1 ; // ERROR: cannot cast to int&amp;<br>static_cast&lt;int const&amp;&gt;(y) = 1 ; // ERROR: cannot modify a const value<br>get(y) = 1 ; // ERROR: cannot modify a const value</pre>
<h3>Warning:</h3>
<p>Both the conversion operator and the <code>data()</code> member function
are <code>const</code> in order to allow access to the wrapped object
from a constant wrapper:</p>
<pre>void foo(int);<br>value_initialized&lt;int&gt; const x ;<br>foo(x);<br></pre>
<p>But notice that this conversion operator is to <code>T&amp;</code> although
it is itself <code>const</code>. As a consequence, if <code>T</code> is
a non-<code>const</code> type, you can modify the wrapped object even from
within a constant wrapper:</p>
<pre>value_initialized&lt;int&gt; const x_c ;<br>int&amp; xr = x_c ; // OK, conversion to int&amp; available even though x_c is itself const.<br>xr = 2 ; </pre>
<p>The reason for this obscure behavior is that some commonly used compilers
just don't accept the following valid code:</p>
<pre>struct X<br>{<br> operator int&amp;() ;<br> operator int const&amp;() const ; <br>};<br>X x ;<br>(x == 1 ) ; // ERROR HERE!</pre>
<p>These compilers complain about ambiguity between the conversion operators.
This complaint is incorrect, but the only workaround that I know of is
to provide only one of them, which leads to the obscure behavior just explained.<br>
</p>
<h3>Recommended practice: The non-member get() idiom</h3>
<p>The obscure behavior of being able to modify a non-<code>const</code>
wrapped object from within a constant wrapper can be avoided if access to
the wrapped object is always performed with the <code>get()</code> idiom:</p>
<pre>value_initialized&lt;int&gt; x ;<br>get(x) = 1 ; // OK<br><br>value_initialized&lt;int const&gt; cx ;<br>get(x) = 1 ; // ERROR: Cannot modify a const object<br><br>value_initialized&lt;int&gt; const x_c ;<br>get(x_c) = 1 ; // ERROR: Cannot modify a const object<br><br>value_initialized&lt;int const&gt; const cx_c ;<br>get(cx_c) = 1 ; // ERROR: Cannot modify a const object<br></pre>
<h3><a name="references">References</a></h3>
[1] The C++ Standard, ISO/IEC 14882:98 <br>
[2] Plain Old Data
<h3><a name="acknowledgements"></a>Acknowledgements</h3>
value_initialized was developed by Fernando Cacciola, with help and
suggestions from David Abrahams and Darin Adler.<br>
Special thanks to Bj<42>rn Karlsson who carefully edited and completed this documentation.
<pre>&nbsp;</pre>
<hr>
<p>Revised 19 September 2002</p>
<p>&copy; Copyright boost.org 2002. Permission to copy, use, modify, sell
and distribute this document is granted provided this copyright notice appears
in all copies. This document is provided "as is" without express or implied
warranty, and with no claim as to its suitability for any purpose.</p>
<p>Developed by <a href="mailto:fernando_cacciola@hotmail.com">Fernando Cacciola</a>,
the latest version of this file can be found at <a
href="http://www.boost.org">www.boost.org</a>, and the boost discussion list
at <a href="http://www.yahoogroups.com/list/boost">www.yahoogroups.com/list/boost</a>.
</p>
<br>
<br>
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// (C) 2002, Fernando Luis Cacciola Carballal.
//
// This material is provided "as is", with absolutely no warranty expressed
// or implied. Any use is at your own risk.
//
// Permission to use or copy this software for any purpose is hereby granted
// without fee, provided the above notices are retained on all copies.
// Permission to modify the code and to distribute modified code is granted,
// provided the above notices are retained, and a notice that the code was
// modified is included with the above copyright notice.
//
// Test program for "boost/utility/value_init.hpp"
//
// Initial: 21 Agu 2002
#include <iostream>
#include <string>
#include "boost/utility/value_init.hpp"
#ifdef __BORLANDC__
#pragma hdrstop
#endif
#define BOOST_INCLUDE_MAIN
#include "boost/test/test_tools.hpp"
//
// Sample POD type
//
struct POD
{
POD () : c(0), i(0), f(0) {}
POD ( char c_, int i_, float f_ ) : c(c_), i(i_), f(f_) {}
friend std::ostream& operator << ( std::ostream& os, POD const& pod )
{ return os << '(' << pod.c << ',' << pod.i << ',' << pod.f << ')' ; }
friend bool operator == ( POD const& lhs, POD const& rhs )
{ return lhs.f == rhs.f && lhs.c == rhs.c && lhs.i == rhs.i ; }
float f;
char c;
int i;
} ;
//
// Sample non POD type
//
struct NonPODBase
{
virtual ~NonPODBase() {}
} ;
struct NonPOD : NonPODBase
{
NonPOD () : id() {}
NonPOD ( std::string const& id_) : id(id_) {}
friend std::ostream& operator << ( std::ostream& os, NonPOD const& npod )
{ return os << '(' << npod.id << ')' ; }
friend bool operator == ( NonPOD const& lhs, NonPOD const& rhs )
{ return lhs.id == rhs.id ; }
std::string id ;
} ;
template<class T>
void test ( T const& y, T const& z )
{
boost::value_initialized<T> x ;
BOOST_TEST ( y == x ) ;
BOOST_TEST ( y == get(x) ) ;
static_cast<T&>(x) = z ;
get(x) = z ;
BOOST_TEST ( x == z ) ;
boost::value_initialized<T> const x_c ;
BOOST_TEST ( y == x_c ) ;
BOOST_TEST ( y == get(x_c) ) ;
static_cast<T&>(x_c) = z ;
BOOST_TEST ( x_c == z ) ;
#ifdef PRODUCE_ERROR_1
get(x_c) = z ; // this should produce an ERROR
#endif
boost::value_initialized<T const> cx ;
BOOST_TEST ( y == cx ) ;
BOOST_TEST ( y == get(cx) ) ;
#ifdef PRODUCE_ERROR_2
get(cx) = z ; // this should produce an ERROR
#endif
boost::value_initialized<T const> const cx_c ;
BOOST_TEST ( y == cx_c ) ;
BOOST_TEST ( y == get(cx_c) ) ;
#ifdef PRODUCE_ERROR_3
get(cx_c) = z ; // this should produce an ERROR
#endif
}
int test_main(int, char **)
{
test( 0,1234 ) ;
test( 0.0,12.34 ) ;
test( POD(0,0,0.0), POD('a',1234,56.78) ) ;
test( NonPOD( std::string() ), NonPOD( std::string("something") ) ) ;
return 0;
}
unsigned int expected_failures = 0;