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Documentation update in respect to code fragments 

Update of documentation in respect of code fragments
- making code fragments work in footnotes
- placing some words in in code tags
- completing some words to code tags
- removing some `#` as they are not necessary
- don't show obfuscation code in email
This commit is contained in:
albert-github 2022-04-21 17:56:14 +02:00
parent d433b1d61e
commit 461dba692d
24 changed files with 56 additions and 51 deletions
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12
Arrangement_on_surface_2/doc/Arrangement_on_surface_2/Arrangement_on_surface_2.txt
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@ -1739,7 +1739,7 @@ expected to either coincide with an existing vertex or lie inside a
face. It is possible to invoke one of the specialized insertion
functions (see Section \ref aos_ssec-basic-arr_class), based on the
query results, and insert \f$c\f$ at its proper
location.\cgalFootnote{The `CGAL::insert_non_intersecting_curve<>()`
location.\cgalFootnote{The \cgalFootnoteCode{CGAL::insert_non_intersecting_curve<>()}
function template, as all other functions reviewed in this section, is
parameterized by an arrangement type and a point-location type (The
latter must be substituted with a model of the
@ -1832,7 +1832,7 @@ consider vertical line-segments to be weakly \f$x\f$-monotone).
Consider an arrangement of circles. A circle is obviously not
\f$x\f$-monotone, so `CGAL::insert<>()` cannot be used in this
case.\cgalFootnote{A key operation performed by `CGAL::insert<>()` is
case.\cgalFootnote{A key operation performed by \cgalFootnoteCode{CGAL::insert<>()} is
to locate the left endpoint of the curve in the arrangement. A circle,
however, does not have any endpoints!} , it is necessary to subdivide
each circle into two \f$x\f$-monotone circular arcs, namely, its upper
@ -4142,7 +4142,7 @@ class template and the `Arr_segment_traits_2<Kernel>` class template
are both parameterized by a geometric kernel and model the concepts
`ArrangementTraits_2` and `ArrangementLandmarkTraits_2`.
\cgalFootnote{They also model the refined concept
`ArrangementDirectionalXMonotoneTraits_2`, which enables Boolean set
\cgalFootnoteCode{ArrangementDirectionalXMonotoneTraits_2}, which enables Boolean set
operations; see Package \ref PkgBooleanSetOperations2Ref.} The class
template `Arr_non_caching_segment_traits_2<Kernel>` derives from the
instance `Arr_non_caching_segment_basic_traits_2<Kernel>`, which
@ -4940,9 +4940,9 @@ template parameter is defined as the `Coefficient` type. This type
cannot be algebraic. Moreover, it is recommended that this type is not
made rational either, since using rational (as opposed to integral)
coefficients does not extend the range of the rational arcs and is
typically less efficient.\cgalFootnote{The `Algebraic_kernel_d_1`
typically less efficient.\cgalFootnote{The \cgalFootnoteCode{Algebraic_kernel_d_1}
class template uses the types provided by the \ref PkgPolynomial
package to define its nested `Polynomial_1` type and conveniently
package to define its nested \cgalFootnoteCode{Polynomial_1} type and conveniently
expose it to the user.} The `Bound` type, however, can be algebraic. A
point of type \link Arr_rational_function_traits_2::Point_2
`Point_2`\endlink nested in the `Arr_rational_function_traits_2` class
@ -6749,7 +6749,7 @@ and defines a simple textual input/output format.
<!-- ========================================================================= -->
\boost\cgalFootnote{See also \boost's homepage at:
<TT>www.boost.org</TT>.} is a collection of portable \cpp libraries
\cgalFootnoteCode{www.boost.org}.} is a collection of portable \cpp libraries
that extend the \cpp Standard Library. The \boost Graph Library
(\bgl), which one of the libraries in the collection, offers an
extensive set of generic graph algorithms parameterized through

2
Arrangement_on_surface_2/doc/Arrangement_on_surface_2/Concepts/ArrangementOpenBoundaryTraits_2.h
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@ -32,7 +32,7 @@
* `ArrangementOpenBoundaryTraits_2` must have all the four categories
* convertible to `CGAL::Arr_open_side_tag`.\cgalFootnote{We intend to introduce
* more concepts that require only a subset of the categories to be convertible
* to `CGAL::Arr_open_side_tag`.} In this case the \dcel of the arrangement
* to \cgalFootnoteCode{CGAL::Arr_open_side_tag}.} In this case the \dcel of the arrangement
* instantiated with the model is initialized with an implicit bounding
* rectangle. When the parameter space is bounded, it is the exact geometric
* embedding of the implicit bounding rectangle.

4
Boolean_set_operations_2/doc/Boolean_set_operations_2/Boolean_set_operations_2.txt
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@ -168,7 +168,7 @@ Section \ref bso_secbso_gen.
The basic components of our package are the free (global) functions
`complement()` that accepts a single `Polygon_2` object, and
`intersection()`, `join()`,\cgalFootnote{The function that computes the union of two polygons is called `join()`, since the word `union` is reserved in \cpp.} `difference()`,
`intersection()`, `join()`,\cgalFootnote{The function that computes the union of two polygons is called \cgalFootnoteCode{join()}, since the word \cgalFootnoteCode{union} is reserved in \cpp.} `difference()`,
`symmetric_difference()` and the predicate `do_intersect()`
that accept two `Polygon_2` objects as their input. We explain how
these functions should be used through several examples in the
@ -702,7 +702,7 @@ The traits classes `Arr_segment_traits_2`,
`Arr_conic_traits_2` and `Arr_rational_function_traits_2`, which are
bundled in the `Arrangement_2` package and distributed with \cgal,
are all models of the refined concept
`ArrangementDirectionalXMonotoneTraits_2`.\cgalFootnote{The `Arr_polyline_traits_2` class is <I>not</I> a model of the, `ArrangementDirectionalXMonotoneTraits_2` concept, as the \f$ x\f$-monotone curve it defines is always directed from left to right. Thus, an opposite curve cannot be constructed. However, it is not very useful to construct a polygon whose edges are polylines, as an ordinary polygon with linear edges can represent the same entity.}
`ArrangementDirectionalXMonotoneTraits_2`.\cgalFootnote{The \cgalFootnoteCode{Arr_polyline_traits_2} class is <I>not</I> a model of the, \cgalFootnoteCode{ArrangementDirectionalXMonotoneTraits_2} concept, as the \f$ x\f$-monotone curve it defines is always directed from left to right. Thus, an opposite curve cannot be constructed. However, it is not very useful to construct a polygon whose edges are polylines, as an ordinary polygon with linear edges can represent the same entity.}
Just as with the case of computations using models of the
`ArrangementXMonotoneTraits_2` concept, operations are robust only

2
Documentation/doc/Customizations.txt
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@ -29,7 +29,7 @@ TDS_2, which don't reside in their own packages in the SCM.
### Footnotes ###
A JQuery footnotes plug-in jquery.footnotes is used to handle
footnotes. The special doxygen command \cgalFootnote expands to the
footnotes. The special doxygen command `\cgalFootnote` expands to the
appropriate html marker. Some JavaScript in `header.html` is used to
append the `<ol div="autoFootnotes0">` to the current doc-content
div. It is not added to the footer because this would break when tree

6
Documentation/doc/Documentation/Developer_manual/Chapter_code_format.txt
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@ -243,13 +243,13 @@ The first list of items are meant as rules, <I>i.e.</I>, you should follow them.
modify the object to which it is applied,
<I>e.g.</I>, `class A { int f( void) const; };`. This should also be
done when it is only conceptually `const`.
This means that the member function `f()` is `c`onst as seen from
This means that the member function `f()` is `const` as seen from
the outside, but internally it may modify some data members
that are declared `m`utable. An example
that are declared `mutable`. An example
is the caching of results from expensive computations. For more
information about conceptually `c`onst functions and mutable data
members see \cgalCite{cgal:m-ec-97}.
- Prefer \cpp-style to C-style casts, <I>e.g.</I>, use `static_cast<double>( i)` instead of `(`double)i.
- Prefer \cpp-style to C-style casts, <I>e.g.</I>, use `static_cast<double>( i)` instead of `(double)i`.
- Protect header files against multiple inclusion, <I>e.g.</I> the file <TT>This_is_an_example.h</TT> should begin/end with
\code{.cpp}
#ifndef CGAL_THIS_IS_AN_EXAMPLE_H

4
Documentation/doc/Documentation/Developer_manual/Chapter_iterators_and_circulators.txt
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@ -86,9 +86,9 @@ struct iterator_traits<T*> {
\section secinput_and_output_iterators Input and output iterators
<B>Operator * for input and output iterators</B>
<B>Operator `*` for input and output iterators</B>
The operator * of input and output iterators has a restricted semantics.
The operator `*` of input and output iterators has a restricted semantics.
Input iterators are designed for input operations, and it is not
required that the value type `T`
of an input iterator `it` be assignable.

2
Documentation/doc/Documentation/Developer_manual/Chapter_kernels.txt
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@ -11,7 +11,7 @@ basic geometric entities of constant size\cgalFootnote{In dimension \f$ d\f$, an
primitive operations on them. Each entity is provided as both a
stand-alone class, which is parameterized by a kernel class, and as a
type in the kernel class. Each operation in the kernel is provided via
a functor class\cgalFootnote{A class which defines a member `operator()`.} in the kernel
a functor class\cgalFootnote{A class which defines a member \cgalFootnoteCode{operator()}.} in the kernel
class and also as either a member function or a global function.
See \cgalCite{hhkps-aegk-01} for more details about this design.
Ideally, if the kernel provides all the primitives required, you can

4
Documentation/doc/Documentation/Developer_manual/Chapter_multithreading.txt
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@ -7,7 +7,7 @@
\section Developer_manualThreadlocal Thread Local Storage
The header file <CGAL/tss.h> provides a macro `CGAL_STATIC_THREAD_LOCAL_VARIABLE(TYPE,VAR,ARG1)`
The header file `<CGAL/tss.h>` provides a macro `CGAL_STATIC_THREAD_LOCAL_VARIABLE(TYPE,VAR,ARG1)`
that creates a thread local variable `VAR` of type `TYPE`, and passes `ARG1` to the
constructor. The variable is either `threadlocal`, or a `boost::thread_specific_ptr`,
or just a local variable if `CGAL_HAS_THREADS` is not defined.
@ -15,6 +15,6 @@ or just a local variable if `CGAL_HAS_THREADS` is not defined.
\section Developer_manualMutex Mutex
The header file <CGAL/mutex.h> provides a macro `CGAL_MUTEX` and a macro `CGAL_SCOPED_LOCK(M)` that is either a `std::unique_lock<std::mutex>` or a `boost::mutex::scoped_lock`.
The header file `<CGAL/mutex.h>` provides a macro `CGAL_MUTEX` and a macro `CGAL_SCOPED_LOCK(M)` that is either a `std::unique_lock<std::mutex>` or a `boost::mutex::scoped_lock`.
*/

2
Documentation/doc/Documentation/Developer_manual/Chapter_namespaces.txt
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@ -14,7 +14,7 @@ and FLTK adds `fl`. \leda uses prefix `leda_`
to some extent,
but you have to tell \leda not to make the corresponding unprefixed names
available as well.\cgalFootnote{\cgal's makefile does this by setting `-DLEDA_PREFIX`.} Initially, \cgal used
available as well.\cgalFootnote{\cgal's makefile does this by setting \cgalFootnoteCode{-DLEDA_PREFIX}.} Initially, \cgal used
prefix `CGAL_`.
At the beginning of 1999, it was decided to drop prefix `CGAL_` and to
introduce namespace `CGAL`.

6
Documentation/doc/Documentation/Developer_manual/Chapter_objects.txt
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@ -25,9 +25,9 @@ UML class diagram for faked object hierarchies (since 2.2-I-4).
Functions having a polymorphic return type create an object of the actual
result type and wrap it into an object of type `Object`.
Refer to the documentation of `#CGAL::Object` class for more details.
Refer to the documentation of `CGAL::Object` class for more details.
An alternative is to use a class handling several output iterators at the same time such as the classes `#CGAL::Dispatch_output_iterator`.
and `#CGAL::Dispatch_or_drop_output_iterator`.
An alternative is to use a class handling several output iterators at the same time such as the classes `CGAL::Dispatch_output_iterator`.
and `CGAL::Dispatch_or_drop_output_iterator`.
*/

22
Documentation/doc/Documentation/Developer_manual/Chapter_portability.txt
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@ -219,19 +219,19 @@ where <I>os-compiler</I> refers to a string describing your
operating system and compiler that is defined as follows.
<CENTER>
<I>\f$ <\f$arch\f$ >\f$</I><TT><I>_</I></TT><I>\f$ <\f$os\f$ >\f$</I><TT><I>-</I></TT><I>\f$ <\f$os-version\f$ >\f$</I><TT><I>_</I></TT><I>\f$ <\f$comp\f$ >\f$</I><TT><I>-</I></TT><I>\f$ <\f$comp-version\f$ >\f$</I>
<I>`<arch>_<os>-<os-version>_<comp>-<comp-version>`</I>
</CENTER>
<DL>
<DT><B>\f$ <\f$arch\f$ >\f$</B><DD> is the system architecture as defined by <TT>uname -p</TT> or <TT>uname -m</TT>,
<DT><B>\f$ <\f$os\f$ >\f$</B><DD> is the operating system as defined by <TT>uname
<DT><B>`<arch>`</B><DD> is the system architecture as defined by <TT>uname -p</TT> or <TT>uname -m</TT>,
<DT><B>`<os>`</B><DD> is the operating system as defined by <TT>uname
-s</TT>,
<DT><B>\f$ <\f$os-version\f$ >\f$</B><DD> is the operating system version as defined by
"<TT>uname -r</TT>",
<DT><B>\f$ <\f$comp\f$ >\f$</B><DD> is the basename of the compiler executable (if it
<DT><B>`<os-version>`</B><DD> is the operating system version as defined by
<TT>uname -r</TT>,
<DT><B>`<comp>`</B><DD> is the basename of the compiler executable (if it
contains spaces, these are replaced by "-"), and
<DT><B>\f$ <\f$comp-version\f$ >\f$</B><DD> is the compiler's version number (which
<DT><B>`<comp-version>`</B><DD> is the compiler's version number (which
unfortunately can not be derived in a uniform manner, since it is
quite compiler specific).
</DL>
@ -251,12 +251,12 @@ These test programs reside in the directory
where <TT>$(CGAL_ROOT)</TT> represents the installation directory for the library.
The names of all testfiles, which correspond to the names of the flags,
start with "<TT>CGAL_CFG_</TT>" followed by
start with <TT>CGAL_CFG_</TT> followed by
<UL>
<LI><I>either</I> a description of a bug ending with
"<TT>_BUG</TT>"
<TT>_BUG</TT>
<LI><I>or</I> a description of a feature starting with
"<TT>NO_</TT>".
<TT>NO_</TT>.
</UL>
For any of these files a corresponding flag is set in the
platform-specific configuration file, iff either compilation or execution
@ -304,7 +304,7 @@ up-to-date version of this list.
\subsection secworkaround_macros Macros connected to workarounds/compilers
Some macros are defined according to certain workaround flags. This is
done to avoid some \#`ifdef`s in our actual code.
done to avoid some `#ifdef`s in our actual code.
<DL>
<DT><B><TT>CGAL_LITTLE_ENDIAN</TT></B><DD> set, iff

2
Documentation/doc/Documentation/Developer_manual/Chapter_testing.txt
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@ -16,7 +16,7 @@ Here is what you need:
- define the environment variable `CGAL_DIR`. It should be the directory where you built CGAL.
- <i>optional:</i> define the environment variables for Boost, GMP, and any optional third party lib, e.g. Eigen.
- <i>On Windows:</i> define the environment variable `MAKE_CMD` (put the line `export MAKE_CMD=nmake` in your `$HOME/.bashrc` for VC++)
- <i>On Windows:</i> define the environment variable `CMAKE_GENERATOR` (put the line `export CMAKE_GENERATOR='-GNMake Makefiles'` in your `$HOME/.bashrc` for VC++)
- <i>On Windows:</i> define the environment variable `CMAKE_GENERATOR` (put the line <tt>export CMAKE_GENERATOR='-GNMake Makefiles'</tt> in your `$HOME/.bashrc` for VC++)
- go in the directory you want to test
- Run `cgal_test_with_cmake` in the `test` and `examples` directories of the package. This should run CMake, compile and run, and you can see what happened in the generated file `error.txt`.

6
Documentation/doc/Documentation/Developer_manual/Chapter_traits_classes.txt
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@ -84,7 +84,7 @@ scope of the traits class in order for the algorithm to work.
As you can guess, `Left_turn_2` is responsible for the orientation
test, while `Less_xy_2` does the sorting. So, obviously, the traits class
must provide these three identifiers. The requirements it has to satisfy
beyond that are documented in full with the concept ConvexHullTraits_2.
beyond that are documented in full with the concept `ConvexHullTraits_2`.
\subsection subsectraits_class_requirements Traits class requirements
@ -92,7 +92,7 @@ Whenever you write a function or class that is parameterized with a traits
class, you must provide the requirements that class has to fulfill. These
requirements should be documented as a concept. For the
example above, if you look in the manual at the description of the concept
`#ConvexHullTraits_2`, you will find that the
`ConvexHullTraits_2`, you will find that the
traits class itself and the identifiers that are mentioned have to meet the
following specifications:
@ -157,7 +157,7 @@ to the default traits class, and the last function parameter defaults to
a default instance of the default traits class. Of course, such behavior
must be specified in the \ref CGAL::ch_graham_andrew() "description of the function".
The implication is that a user can call `ch_graham_andrews` with
The implication is that a user can call `ch_graham_andrew` with
just three parameters, which delimit the iterator range to be handled and
supply the iterator for the result. The types
and primitives used by the algorithm in this case are the ones from the \cgal 2D and 3D kernel.

10
Documentation/doc/Documentation/Third_party.txt
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@ -11,11 +11,11 @@ supporting <a href="https://isocpp.org/wiki/faq/cpp14">C++14</a> or later.
| Operating System | Compiler |
| :---------- | :--------------- |
| Linux | \gnu `g++` 10.2.1 or later\cgalFootnote{<A HREF="http://gcc.gnu.org/">`http://gcc.gnu.org/`</A>} |
| | `Clang` \cgalFootnote{<A HREF="http://clang.llvm.org/">`http://clang.llvm.org/`</A>} compiler version 13.0.0 |
| \ms Windows | \gnu `g++` 10.2.1 or later\cgalFootnote{<A HREF="http://gcc.gnu.org/">`http://gcc.gnu.org/`</A>} |
| | \ms Visual `C++` 14.0, 15.9, 16.10, 17.0 (\visualstudio 2015, 2017, 2019, and 2022)\cgalFootnote{<A HREF="https://visualstudio.microsoft.com/">`https://visualstudio.microsoft.com/`</A>} |
| MacOS X | \gnu `g++` 10.2.1 or later\cgalFootnote{<A HREF="http://gcc.gnu.org/">`http://gcc.gnu.org/`</A>} |
| Linux | \gnu `g++` 10.2.1 or later\cgalFootnote{<A HREF="http://gcc.gnu.org/">\cgalFootnoteCode{http://gcc.gnu.org/}</A>} |
| | `Clang` \cgalFootnote{<A HREF="http://clang.llvm.org/">\cgalFootnoteCode{http://clang.llvm.org/}</A>} compiler version 13.0.0 |
| \ms Windows | \gnu `g++` 10.2.1 or later\cgalFootnote{<A HREF="http://gcc.gnu.org/">\cgalFootnoteCode{http://gcc.gnu.org/}</A>} |
| | \ms Visual `C++` 14.0, 15.9, 16.10, 17.0 (\visualstudio 2015, 2017, 2019, and 2022)\cgalFootnote{<A HREF="https://visualstudio.microsoft.com/">\cgalFootnoteCode{https://visualstudio.microsoft.com/}</A>} |
| MacOS X | \gnu `g++` 10.2.1 or later\cgalFootnote{<A HREF="http://gcc.gnu.org/">\cgalFootnoteCode{http://gcc.gnu.org/}</A>} |
| | Apple `Clang` compiler versions 10.0.1, 12.0.5, and 13.0.0 |
<!-- Windows supported version are also listed on windows.html (must change both) -->

2
Documentation/doc/Documentation/advanced/Configuration_variables.txt
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@ -130,7 +130,7 @@ For example, you can add the path to the \boost `.dll` to the
| Variable | Description | Type |
| :- | :- | :- |
| `BOOST_ROOT`\cgalFootnote{The environment variable can be spelled either `BOOST_ROOT` or `BOOSTROOT`} | Root directory of your \boost installation | Either CMake or Environment |
| `BOOST_ROOT`\cgalFootnote{The environment variable can be spelled either \cgalFootnoteCode{BOOST_ROOT} or \cgalFootnoteCode{BOOSTROOT}} | Root directory of your \boost installation | Either CMake or Environment |
| `Boost_INCLUDE_DIR` | Directory containing the `boost/version.hpp` file | CMake |
| `BOOST_INCLUDEDIR` | Idem | Environment |
| `Boost_LIBRARY_DIRS` | Directory containing the compiled \boost libraries | CMake |

1
Documentation/doc/resources/1.9.3/BaseDoxyfile.in
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@ -354,6 +354,7 @@ ALIASES = "cgal=%CGAL" \
"cgalModifEnd=\htmlonly </div> \endhtmlonly \latexonly END MODIFICATIONS \endlatexonly" \
"cgalPkgBib{1}=<B>BibTeX:</B> <a href=\"../Manual/how_to_cite_cgal.html#\1-${CGAL_RELEASE_YEAR_ID}\">\1-${CGAL_RELEASE_YEAR_ID}</a><BR>" \
"cgalFootnote{1}=<span class=\"footnote\">\1</span>" \
"cgalFootnoteCode{1}=<tt style='display:inline'>\1</tt>" \
"cgalAutoToc=\htmlonly[block] <div id=\"autotoc\" class=\"toc\"></div> \endhtmlonly" \
"cgalTagTrue=\link CGAL::Tag_true `CGAL::Tag_true`\endlink" \
"cgalTagFalse=\link CGAL::Tag_false `CGAL::Tag_false`\endlink" \

4
Documentation/doc/resources/1.9.3/stylesheet.css
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@ -107,6 +107,10 @@ span.legend {
text-align: center;
}
span.obfuscator {
display: none;
}
h3.version {
font-size: 90%;
text-align: center;

2
Kernel_23/doc/Kernel_23/Kernel_23.txt
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@ -353,7 +353,7 @@ assert( p == q );
In order to obtain the point corresponding to a vector \f$ v\f$ you simply
have to add \f$ v\f$ to \ref ORIGIN. If you want to determine
the point \f$ q\f$ in the middle between two points \f$ p_1\f$ and \f$ p_2\f$, you can write\cgalFootnote{you might call `midpoint(p_1,p_2)` instead.}
the point \f$ q\f$ in the middle between two points \f$ p_1\f$ and \f$ p_2\f$, you can write\cgalFootnote{you might call \cgalFootnoteCode{midpoint(p_1,p_2)} instead.}
\code{.cpp}
q = p_1 + (p_2 - p_1) / 2.0;

2
Kernel_d/doc/Kernel_d/Kernel_d.txt
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@ -349,7 +349,7 @@ assert( p == q );
In order to obtain the point corresponding to a vector \f$ v\f$ you simply
have to add \f$ v\f$ to `ORIGIN`. If you want to determine
the point \f$ q\f$ in the middle between two points \f$ p_1\f$ and \f$ p_2\f$, you can
write\cgalFootnote{you might call `midpoint(p_1,p_2)` instead}
write\cgalFootnote{you might call \cgalFootnoteCode{midpoint(p_1,p_2)} instead}
\code{.cpp}
q = p_1 + (p_2 - p_1) / 2.0;

2
Nef_2/doc/Nef_2/CGAL/Nef_polyhedron_2.h
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@ -297,7 +297,7 @@ is a pair of vertices `(v,w)` with incidence operations `v = source(e)`, `w = ta
`v` is called the adjacency list `A(v)`.
Edges are paired into twins. For each edge `e = (v,w)` there's an
edge `twin(e) = (w,v)` and `twin(twin(e)) == e`\cgalFootnote{The existence of the edge pairs makes `P` a bidirected graph, the `twin` links make `P` a map.}.
edge `twin(e) = (w,v)` and `twin(twin(e)) == e`\cgalFootnote{The existence of the edge pairs makes \cgalFootnoteCode{P} a bidirected graph, the \cgalFootnoteCode{twin} links make \cgalFootnoteCode{P} a map.}.
An edge `e = (v,w)` knows two adjacent edges `en = next(e)`
and `ep = previous(e)` where `source(en) = w`,

2
Number_types/doc/Number_types/CGAL/Sqrt_extension.h
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@ -13,7 +13,7 @@ An instance of this class represents an extension of the type `NT` by *one* squa
For example, let `Integer` be some type representing \f$ \Z\f$, then
`Sqrt_extension<Integer,Integer>` is able to represent \f$ \Z[\sqrt{\mathrm{root}}]\f$
for some arbitrary Integer \f$\mathrm{root}\f$. \cgalFootnote{\f$ R[a]\f$ denotes the extension of a ring \f$ R\f$ by an element \f$ a\f$. See also: <A HREF="http://mathworld.wolfram.com/ExtensionRing.html"><TT>http://mathworld.wolfram.com/ExtensionRing.html</TT></A>}
for some arbitrary Integer \f$\mathrm{root}\f$. \cgalFootnote{\f$ R[a]\f$ denotes the extension of a ring \f$ R\f$ by an element \f$ a\f$. See also: <A HREF="http://mathworld.wolfram.com/ExtensionRing.html">\cgalFootnoteCode{http://mathworld.wolfram.com/ExtensionRing.html}</A>}
The value of \f$\mathrm{root}\f$ is set at
construction time, or set to zero if it is not specified.

2
Number_types/doc/Number_types/NumberTypeSupport.txt
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@ -23,7 +23,7 @@ structure concepts see Section \ref PkgAlgebraicFoundationsRef.
The built-in number types `float`, `double` and `long double` have
the required arithmetic and comparison operators. They lack some required
routines though which are automatically included by \cgal.
\cgalFootnote{The functions can be found in the header files <TT>CGAL/int.h</TT>, <TT>CGAL/float.h</TT>, <TT>CGAL/double.h</TT> and <TT>CGAL/long_long.h</TT>.}
\cgalFootnote{The functions can be found in the header files \cgalFootnoteCode{CGAL/int.h}, \cgalFootnoteCode{CGAL/float.h}, \cgalFootnoteCode{CGAL/double.h} and \cgalFootnoteCode{CGAL/long_long.h}.}
All built-in number types of \cpp can represent a discrete (bounded)
subset of the rational numbers only. We assume that the

2
Polynomial/doc/Polynomial/Polynomial.txt
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@ -236,7 +236,7 @@ structure of the innermost coefficient, for instance, a gcd is available
if and only if the innermost coefficient is a `Field` or a
`UniqueFactorizationDomain`. Hence, we can not provide a \f$ gcd\f$ if the
innermost coefficient is just an `IntegralDomain` since it is simply
not well defined\cgalFootnote{An example for such a number type is the template `Sqrt_extension<NT,ROOT>` representing an algebraic extension of degree two. This is just an `IntegralDomain` if NT is not a `Field`. }.
not well defined\cgalFootnote{An example for such a number type is the template S\cgalFootnoteCode{qrt_extension<NT,ROOT>} representing an algebraic extension of degree two. This is just an \cgalFootnoteCode{IntegralDomain} if NT is not a `Field`. }.
However, if we would consider the polynomial over the quotient field of the
integral domain the \f$ gcd\f$ would be well defined. The only problem is
that the result can not be represented over the ring since it contains

4
Polytope_distance_d/doc/Polytope_distance_d/CGAL/all_furthest_neighbors_2.h
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@ -6,8 +6,8 @@ namespace CGAL {
\brief computes all furthest neighbors for the vertices of the convex
polygon described by the range [`points_begin`, `points_end`), writes
their indices (relative to `points_begin`) to `o`\cgalFootnote{the
furthest neighbor of `points_begin[i]` is `points_begin[i-th number
written to o]`} and returns the past-the-end iterator of this
furthest neighbor of \cgalFootnoteCode{points_begin[i]} is \cgalFootnoteCode{points_begin[i-th number
written to o]}} and returns the past-the-end iterator of this
sequence.
The function `all_furthest_neighbors_2()` computes all furthest