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author | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-03-21 17:19:04 +0000 |
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committer | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-03-21 17:19:04 +0000 |
commit | 310edf444908b09ea6d00c03baceb7925f3bb7a2 (patch) | |
tree | 7064577c7fa7a851e2e930beb606ea8237b0bbd2 /ml/dlib/docs/docs/enable_if.html | |
parent | Releasing debian version 1.44.3-2. (diff) | |
download | netdata-310edf444908b09ea6d00c03baceb7925f3bb7a2.tar.xz netdata-310edf444908b09ea6d00c03baceb7925f3bb7a2.zip |
Merging upstream version 1.45.0.
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to 'ml/dlib/docs/docs/enable_if.html')
-rw-r--r-- | ml/dlib/docs/docs/enable_if.html | 387 |
1 files changed, 0 insertions, 387 deletions
diff --git a/ml/dlib/docs/docs/enable_if.html b/ml/dlib/docs/docs/enable_if.html deleted file mode 100644 index 09cc2d4d2..000000000 --- a/ml/dlib/docs/docs/enable_if.html +++ /dev/null @@ -1,387 +0,0 @@ -<!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="boost.png" align="center" width="277" height="86">enable_if</h1> -<BR> -<BR> -Copyright 2003 Jaakko Järvi, Jeremiah Willcock, Andrew Lumsdaine.<BR> -<BR> -<!--TOC section Introduction--> - -<H2><A NAME="htoc1">1</A> 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 [<A HREF="#jarvi:03:cuj_arbitrary_overloading"><CITE>1</CITE></A>] and [<A HREF="#jarvi:03:c++typeclasses"><CITE>2</CITE></A>].<BR> -<BR> -<!--TOC subsection Synopsis--> - -<H3><A NAME="htoc2">1.1</A> Synopsis</H3><!--SEC END --> - -<A NAME="sec:synopsis"></A> -<PRE>namespace boost { - template <class Cond, class T = void> struct enable_if; - template <class Cond, class T = void> struct disable_if; - template <class Cond, class T> struct lazy_enable_if; - template <class Cond, class T> struct lazy_disable_if; - - template <bool B, class T = void> struct enable_if_c; - template <bool B, class T = void> struct disable_if_c; - template <bool B, class T> struct lazy_enable_if_c; - template <bool B, class T> struct lazy_disable_if_c; -} -</PRE> -<!--TOC subsection Background--> - -<H3><A NAME="htoc3">1.2</A> 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 [<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 [<A HREF="#jarvi:03:cuj_arbitrary_overloading"><CITE>1</CITE></A>], -demonstrates why this is important: -<PRE>int negate(int i) { return -i; } - -template <class F> -typename F::result_type negate(const F& 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&); - -</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> 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 <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 <bool B, class T = void> -struct enable_if_c { - typedef T type; -}; - -template <class T> -struct enable_if_c<false, T> {}; - -template <class Cond, class T = void> -struct enable_if : public enable_if_c<Cond::value, T> {}; - -</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<B, T>::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<B, T>::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/doc/libs/release/libs/type_traits/index.html">Boost type_traits library</A>): -<PRE>template <class T> -typename enable_if_c<boost::is_arithmetic<T>::value, T>::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 <class T> -typename disable_if_c<boost::is_arithmetic<T>::value, T>::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 <class T> -typename enable_if<boost::is_arithmetic<T>, T>::type -foo(T t) { return t; } - -</PRE> -<!--TOC section Using <TT>enable_if</TT>--> - -<H2><A NAME="htoc5">3</A> 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 <class T> -T foo(T t, typename enable_if<boost::is_arithmetic<T> >::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> 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 <class T, class Enable = void> -class A { ... }; - -template <class T> -class A<T, typename enable_if<is_integral<T> >::type> { ... }; - -template <class T> -class A<T, typename enable_if<is_float<T> >::type> { ... }; - -</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> 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 <class T> -typename enable_if<boost::is_integral<T>, void>::type -foo(T t) {} - -template <class T> -typename enable_if<boost::is_arithmetic<T>, void>::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> 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 <class T, class U> class mult_traits; - -template <class T, class U> -typename enable_if<is_multipliable<T, U>, typename mult_traits<T, U>::type>::type -operator*(const T& t, const U& 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<A, B>::value</TT> is <TT>true</TT> for some types <TT>A</TT> and <TT>B</TT>, -then <TT>mult_traits<A, B>::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<C, D>::value</TT> is <TT>false</TT> -and <TT>mult_traits<C, D>::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<class T, class U> -typename lazy_enable_if<is_multipliable<T, U>, mult_traits<T, U> >::type -operator*(const T& t, const U& 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<T, U>::value</TT> defines when -<TT>mult_traits<T, U>::type</TT> is valid.<BR> -<BR> -<!--TOC subsection Compiler workarounds--> - -<H3><A NAME="htoc9">3.4</A> 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 <class T> -typename enable_if<boost::is_arithmetic<T>, T>::type -foo(T t); - -template <class T> -typename disable_if<boost::is_arithmetic<T>, T>::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 <int> struct dummy { dummy(int) {} }; - -template <class T> -typename enable_if<boost::is_arithmetic<T>, T>::type -foo(T t, dummy<0> = 0); - -template <class T> -typename disable_if<boost::is_arithmetic<T>, T>::type -foo(T t, dummy<1> = 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 <class T> - typename enable_if<boost::is_arithmetic<T>, T>::type - foo(T t); -} - -namespace B { - template <class T> - typename disable_if<boost::is_arithmetic<T>, T>::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> 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 Järvi, 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 Järvi, 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 M. Josuttis. -<EM>C++ Templates: The Complete Guide</EM>. -Addison-Wesley, 2002.</DL> - - - - - -<hr></hr> - -<B>Contributed by:</B> <BR> -Jaakko Järvi, Jeremiah Willcock and Andrew Lumsdaine<BR> -<EM>{jajarvi|jewillco|lums}@osl.iu.edu</EM><BR> -Indiana University<BR> -Open Systems Lab -<!--HTMLFOOT--> -<!--ENDHTML--> -<!--FOOTER--> -<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>. -</EM></BLOCKQUOTE> -</BODY> -</HTML> |