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@node String and Array Utilities, Character Set Handling, Character Handling, Top
@c %MENU% Utilities for copying and comparing strings and arrays
@chapter String and Array Utilities

Operations on strings (or arrays of characters) are an important part of
many programs.  The GNU C library provides an extensive set of string
utility functions, including functions for copying, concatenating,
comparing, and searching strings.  Many of these functions can also
operate on arbitrary regions of storage; for example, the @code{memcpy}
function can be used to copy the contents of any kind of array.

It's fairly common for beginning C programmers to ``reinvent the wheel''
by duplicating this functionality in their own code, but it pays to
become familiar with the library functions and to make use of them,
since this offers benefits in maintenance, efficiency, and portability.

For instance, you could easily compare one string to another in two
lines of C code, but if you use the built-in @code{strcmp} function,
you're less likely to make a mistake.  And, since these library
functions are typically highly optimized, your program may run faster
too.

@menu
* Representation of Strings::   Introduction to basic concepts.
* String/Array Conventions::    Whether to use a string function or an
				 arbitrary array function.
* String Length::               Determining the length of a string.
* Copying and Concatenation::   Functions to copy the contents of strings
				 and arrays.
* String/Array Comparison::     Functions for byte-wise and character-wise
				 comparison.
* Collation Functions::         Functions for collating strings.
* Search Functions::            Searching for a specific element or substring.
* Finding Tokens in a String::  Splitting a string into tokens by looking
				 for delimiters.
* Encode Binary Data::          Encoding and Decoding of Binary Data.
* Argz and Envz Vectors::       Null-separated string vectors.
@end menu

@node Representation of Strings
@section Representation of Strings
@cindex string, representation of

This section is a quick summary of string concepts for beginning C
programmers.  It describes how character strings are represented in C
and some common pitfalls.  If you are already familiar with this
material, you can skip this section.

@cindex string
@cindex null character
A @dfn{string} is an array of @code{char} objects.  But string-valued
variables are usually declared to be pointers of type @code{char *}.
Such variables do not include space for the text of a string; that has
to be stored somewhere else---in an array variable, a string constant,
or dynamically allocated memory (@pxref{Memory Allocation}).  It's up to
you to store the address of the chosen memory space into the pointer
variable.  Alternatively you can store a @dfn{null pointer} in the
pointer variable.  The null pointer does not point anywhere, so
attempting to reference the string it points to gets an error.

By convention, a @dfn{null character}, @code{'\0'}, marks the end of a
string.  For example, in testing to see whether the @code{char *}
variable @var{p} points to a null character marking the end of a string,
you can write @code{!*@var{p}} or @code{*@var{p} == '\0'}.

A null character is quite different conceptually from a null pointer,
although both are represented by the integer @code{0}.

@cindex string literal
@dfn{String literals} appear in C program source as strings of
characters between double-quote characters (@samp{"}).  In @w{ISO C},
string literals can also be formed by @dfn{string concatenation}:
@code{"a" "b"} is the same as @code{"ab"}.  Modification of string
literals is not allowed by the GNU C compiler, because literals
are placed in read-only storage.

Character arrays that are declared @code{const} cannot be modified
either.  It's generally good style to declare non-modifiable string
pointers to be of type @code{const char *}, since this often allows the
C compiler to detect accidental modifications as well as providing some
amount of documentation about what your program intends to do with the
string.

The amount of memory allocated for the character array may extend past
the null character that normally marks the end of the string.  In this
document, the term @dfn{allocated size} is always used to refer to the
total amount of memory allocated for the string, while the term
@dfn{length} refers to the number of characters up to (but not
including) the terminating null character.
@cindex length of string
@cindex allocation size of string
@cindex size of string
@cindex string length
@cindex string allocation

A notorious source of program bugs is trying to put more characters in a
string than fit in its allocated size.  When writing code that extends
strings or moves characters into a pre-allocated array, you should be
very careful to keep track of the length of the text and make explicit
checks for overflowing the array.  Many of the library functions
@emph{do not} do this for you!  Remember also that you need to allocate
an extra byte to hold the null character that marks the end of the
string.

@node String/Array Conventions
@section String and Array Conventions

This chapter describes both functions that work on arbitrary arrays or
blocks of memory, and functions that are specific to null-terminated
arrays of characters.

Functions that operate on arbitrary blocks of memory have names
beginning with @samp{mem} (such as @code{memcpy}) and invariably take an
argument which specifies the size (in bytes) of the block of memory to
operate on.  The array arguments and return values for these functions
have type @code{void *}, and as a matter of style, the elements of these
arrays are referred to as ``bytes''.  You can pass any kind of pointer
to these functions, and the @code{sizeof} operator is useful in
computing the value for the size argument.

In contrast, functions that operate specifically on strings have names
beginning with @samp{str} (such as @code{strcpy}) and look for a null
character to terminate the string instead of requiring an explicit size
argument to be passed.  (Some of these functions accept a specified
maximum length, but they also check for premature termination with a
null character.)  The array arguments and return values for these
functions have type @code{char *}, and the array elements are referred
to as ``characters''.

In many cases, there are both @samp{mem} and @samp{str} versions of a
function.  The one that is more appropriate to use depends on the exact
situation.  When your program is manipulating arbitrary arrays or blocks of
storage, then you should always use the @samp{mem} functions.  On the
other hand, when you are manipulating null-terminated strings it is
usually more convenient to use the @samp{str} functions, unless you
already know the length of the string in advance.

@node String Length
@section String Length

You can get the length of a string using the @code{strlen} function.
This function is declared in the header file @file{string.h}.
@pindex string.h

@comment string.h
@comment ISO
@deftypefun size_t strlen (const char *@var{s})
The @code{strlen} function returns the length of the null-terminated
string @var{s}.  (In other words, it returns the offset of the terminating
null character within the array.)

For example,
@smallexample
strlen ("hello, world")
    @result{} 12
@end smallexample

When applied to a character array, the @code{strlen} function returns
the length of the string stored there, not its allocated size.  You can
get the allocated size of the character array that holds a string using
the @code{sizeof} operator:

@smallexample
char string[32] = "hello, world";
sizeof (string)
    @result{} 32
strlen (string)
    @result{} 12
@end smallexample

But beware, this will not work unless @var{string} is the character
array itself, not a pointer to it.  For example:

@smallexample
char string[32] = "hello, world";
char *ptr = string;
sizeof (string)
    @result{} 32
sizeof (ptr)
    @result{} 4  /* @r{(on a machine with 4 byte pointers)} */
@end smallexample

This is an easy mistake to make when you are working with functions that
take string arguments; those arguments are always pointers, not arrays.

@end deftypefun

@comment string.h
@comment GNU
@deftypefun size_t strnlen (const char *@var{s}, size_t @var{maxlen})
The @code{strnlen} function returns the length of the null-terminated
string @var{s} is this length is smaller than @var{maxlen}.  Otherwise
it returns @var{maxlen}.  Therefore this function is equivalent to
@code{(strlen (@var{s}) < n ? strlen (@var{s}) : @var{maxlen})} but it
is more efficient.

@smallexample
char string[32] = "hello, world";
strnlen (string, 32)
    @result{} 12
strnlen (string, 5)
    @result{} 5
@end smallexample

This function is a GNU extension.
@end deftypefun

@node Copying and Concatenation
@section Copying and Concatenation

You can use the functions described in this section to copy the contents
of strings and arrays, or to append the contents of one string to
another.  These functions are declared in the header file
@file{string.h}.
@pindex string.h
@cindex copying strings and arrays
@cindex string copy functions
@cindex array copy functions
@cindex concatenating strings
@cindex string concatenation functions

A helpful way to remember the ordering of the arguments to the functions
in this section is that it corresponds to an assignment expression, with
the destination array specified to the left of the source array.  All
of these functions return the address of the destination array.

Most of these functions do not work properly if the source and
destination arrays overlap.  For example, if the beginning of the
destination array overlaps the end of the source array, the original
contents of that part of the source array may get overwritten before it
is copied.  Even worse, in the case of the string functions, the null
character marking the end of the string may be lost, and the copy
function might get stuck in a loop trashing all the memory allocated to
your program.

All functions that have problems copying between overlapping arrays are
explicitly identified in this manual.  In addition to functions in this
section, there are a few others like @code{sprintf} (@pxref{Formatted
Output Functions}) and @code{scanf} (@pxref{Formatted Input
Functions}).

@comment string.h
@comment ISO
@deftypefun {void *} memcpy (void *@var{to}, const void *@var{from}, size_t @var{size})
The @code{memcpy} function copies @var{size} bytes from the object
beginning at @var{from} into the object beginning at @var{to}.  The
behavior of this function is undefined if the two arrays @var{to} and
@var{from} overlap; use @code{memmove} instead if overlapping is possible.

The value returned by @code{memcpy} is the value of @var{to}.

Here is an example of how you might use @code{memcpy} to copy the
contents of an array:

@smallexample
struct foo *oldarray, *newarray;
int arraysize;
@dots{}
memcpy (new, old, arraysize * sizeof (struct foo));
@end smallexample
@end deftypefun

@comment string.h
@comment GNU
@deftypefun {void *} mempcpy (void *@var{to}, const void *@var{from}, size_t @var{size})
The @code{mempcpy} function is nearly identical to the @code{memcpy}
function.  It copies @var{size} bytes from the object beginning at
@code{from} into the object pointed to by @var{to}.  But instead of
returning the value of @code{to} it returns a pointer to the byte
following the last written byte in the object beginning at @var{to}.
I.e., the value is @code{((void *) ((char *) @var{to} + @var{size}))}.

This function is useful in situations where a number of objects shall be
copied to consecutive memory positions.

@smallexample
void *
combine (void *o1, size_t s1, void *o2, size_t s2)
@{
  void *result = malloc (s1 + s2);
  if (result != NULL)
    mempcpy (mempcpy (result, o1, s1), o2, s2);
  return result;
@}
@end smallexample

This function is a GNU extension.
@end deftypefun

@comment string.h
@comment ISO
@deftypefun {void *} memmove (void *@var{to}, const void *@var{from}, size_t @var{size})
@code{memmove} copies the @var{size} bytes at @var{from} into the
@var{size} bytes at @var{to}, even if those two blocks of space
overlap.  In the case of overlap, @code{memmove} is careful to copy the
original values of the bytes in the block at @var{from}, including those
bytes which also belong to the block at @var{to}.
@end deftypefun

@comment string.h
@comment SVID
@deftypefun {void *} memccpy (void *@var{to}, const void *@var{from}, int @var{c}, size_t @var{size})
This function copies no more than @var{size} bytes from @var{from} to
@var{to}, stopping if a byte matching @var{c} is found.  The return
value is a pointer into @var{to} one byte past where @var{c} was copied,
or a null pointer if no byte matching @var{c} appeared in the first
@var{size} bytes of @var{from}.
@end deftypefun

@comment string.h
@comment ISO
@deftypefun {void *} memset (void *@var{block}, int @var{c}, size_t @var{size})
This function copies the value of @var{c} (converted to an
@code{unsigned char}) into each of the first @var{size} bytes of the
object beginning at @var{block}.  It returns the value of @var{block}.
@end deftypefun

@comment string.h
@comment ISO
@deftypefun {char *} strcpy (char *@var{to}, const char *@var{from})
This copies characters from the string @var{from} (up to and including
the terminating null character) into the string @var{to}.  Like
@code{memcpy}, this function has undefined results if the strings
overlap.  The return value is the value of @var{to}.
@end deftypefun

@comment string.h
@comment ISO
@deftypefun {char *} strncpy (char *@var{to}, const char *@var{from}, size_t @var{size})
This function is similar to @code{strcpy} but always copies exactly
@var{size} characters into @var{to}.

If the length of @var{from} is more than @var{size}, then @code{strncpy}
copies just the first @var{size} characters.  Note that in this case
there is no null terminator written into @var{to}.

If the length of @var{from} is less than @var{size}, then @code{strncpy}
copies all of @var{from}, followed by enough null characters to add up
to @var{size} characters in all.  This behavior is rarely useful, but it
is specified by the @w{ISO C} standard.

The behavior of @code{strncpy} is undefined if the strings overlap.

Using @code{strncpy} as opposed to @code{strcpy} is a way to avoid bugs
relating to writing past the end of the allocated space for @var{to}.
However, it can also make your program much slower in one common case:
copying a string which is probably small into a potentially large buffer.
In this case, @var{size} may be large, and when it is, @code{strncpy} will
waste a considerable amount of time copying null characters.
@end deftypefun

@comment string.h
@comment SVID
@deftypefun {char *} strdup (const char *@var{s})
This function copies the null-terminated string @var{s} into a newly
allocated string.  The string is allocated using @code{malloc}; see
@ref{Unconstrained Allocation}.  If @code{malloc} cannot allocate space
for the new string, @code{strdup} returns a null pointer.  Otherwise it
returns a pointer to the new string.
@end deftypefun

@comment string.h
@comment GNU
@deftypefun {char *} strndup (const char *@var{s}, size_t @var{size})
This function is similar to @code{strdup} but always copies at most
@var{size} characters into the newly allocated string.

If the length of @var{s} is more than @var{size}, then @code{strndup}
copies just the first @var{size} characters and adds a closing null
terminator.  Otherwise all characters are copied and the string is
terminated.

This function is different to @code{strncpy} in that it always
terminates the destination string.

@code{strndup} is a GNU extension.
@end deftypefun

@comment string.h
@comment Unknown origin
@deftypefun {char *} stpcpy (char *@var{to}, const char *@var{from})
This function is like @code{strcpy}, except that it returns a pointer to
the end of the string @var{to} (that is, the address of the terminating
null character) rather than the beginning.

For example, this program uses @code{stpcpy} to concatenate @samp{foo}
and @samp{bar} to produce @samp{foobar}, which it then prints.

@smallexample
@include stpcpy.c.texi
@end smallexample

This function is not part of the ISO or POSIX standards, and is not
customary on Unix systems, but we did not invent it either.  Perhaps it
comes from MS-DOG.

Its behavior is undefined if the strings overlap.
@end deftypefun

@comment string.h
@comment GNU
@deftypefun {char *} stpncpy (char *@var{to}, const char *@var{from}, size_t @var{size})
This function is similar to @code{stpcpy} but copies always exactly
@var{size} characters into @var{to}.

If the length of @var{from} is more then @var{size}, then @code{stpncpy}
copies just the first @var{size} characters and returns a pointer to the
character directly following the one which was copied last.  Note that in
this case there is no null terminator written into @var{to}.

If the length of @var{from} is less than @var{size}, then @code{stpncpy}
copies all of @var{from}, followed by enough null characters to add up
to @var{size} characters in all.  This behaviour is rarely useful, but it
is implemented to be useful in contexts where this behaviour of the
@code{strncpy} is used.  @code{stpncpy} returns a pointer to the
@emph{first} written null character.

This function is not part of ISO or POSIX but was found useful while
developing the GNU C Library itself.

Its behaviour is undefined if the strings overlap.
@end deftypefun

@comment string.h
@comment GNU
@deftypefn {Macro} {char *} strdupa (const char *@var{s})
This function is similar to @code{strdup} but allocates the new string
using @code{alloca} instead of @code{malloc} (@pxref{Variable Size
Automatic}).  This means of course the returned string has the same
limitations as any block of memory allocated using @code{alloca}.

For obvious reasons @code{strdupa} is implemented only as a macro;
you cannot get the address of this function.  Despite this limitation
it is a useful function.  The following code shows a situation where
using @code{malloc} would be a lot more expensive.

@smallexample
@include strdupa.c.texi
@end smallexample

Please note that calling @code{strtok} using @var{path} directly is
invalid.

This function is only available if GNU CC is used.
@end deftypefn

@comment string.h
@comment GNU
@deftypefn {Macro} {char *} strndupa (const char *@var{s}, size_t @var{size})
This function is similar to @code{strndup} but like @code{strdupa} it
allocates the new string using @code{alloca}
@pxref{Variable Size Automatic}.  The same advantages and limitations
of @code{strdupa} are valid for @code{strndupa}, too.

This function is implemented only as a macro, just like @code{strdupa}.

@code{strndupa} is only available if GNU CC is used.
@end deftypefn

@comment string.h
@comment ISO
@deftypefun {char *} strcat (char *@var{to}, const char *@var{from})
The @code{strcat} function is similar to @code{strcpy}, except that the
characters from @var{from} are concatenated or appended to the end of
@var{to}, instead of overwriting it.  That is, the first character from
@var{from} overwrites the null character marking the end of @var{to}.

An equivalent definition for @code{strcat} would be:

@smallexample
char *
strcat (char *to, const char *from)
@{
  strcpy (to + strlen (to), from);
  return to;
@}
@end smallexample

This function has undefined results if the strings overlap.
@end deftypefun

Programmers using the @code{strcat} function (or the following
@code{strncat} function for that matter) can easily be recognize as
lazy.  In almost all situations the lengths of the participating strings
are known.  Or at least, one could know them if one keeps track of the
results of the various function calls.  But then it is very inefficient
to use @code{strcat}.  A lot of time is wasted finding the end of the
destination string so that the actual copying can start.  This is a
common example:

@cindex __va_copy
@cindex va_copy
@smallexample
/* @r{This function concats arbitrary many strings.  The last}
   @r{parameter must be @code{NULL}.}  */
char *
concat (const char *str, ...)
@{
  va_list ap, ap2;
  size_t total = 1;
  const char *s;
  char *result;

  va_start (ap, str);
  /* @r{Actually @code{va_copy}, but this is the name more gcc versions}
     @r{understand.}  */
  __va_copy (ap2, ap);

  /* @r{Determine how much space we need.}  */
  for (s = str; s != NULL; s = va_arg (ap, const char *))
    total += strlen (s);

  va_end (ap);

  result = (char *) malloc (total);
  if (result != NULL)
    @{
      result[0] = '\0';

      /* @r{Copy the strings.}  */
      for (s = str; s != NULL; s = va_arg (ap2, const char *))
        strcat (result, s);
    @}

  va_end (ap2);

  return result;
@}
@end smallexample

This looks quite simple, especially the second loop where the strings
are actually copied.  But these innocent lines hide a major performance
penalty.  Just imagine that ten strings of 100 bytes each have to be
concatenated.  For the second string we search the already stored 100
bytes for the end of the string so that we can append the next string.
For all strings in total the comparisons necessary to find the end of
the intermediate results sums up to 5500!  If we combine the copying
with the search for the allocation we can write this function more
efficent:

@smallexample
char *
concat (const char *str, ...)
@{
  va_list ap;
  size_t allocated = 100;
  char *result = (char *) malloc (allocated);
  char *wp;

  if (allocated != NULL)
    @{
      char *newp;

      va_start (ap, atr);

      wp = result;
      for (s = str; s != NULL; s = va_arg (ap, const char *))
        @{
          size_t len = strlen (s);

          /* @r{Resize the allocated memory if necessary.}  */
          if (wp + len + 1 > result + allocated)
            @{
              allocated = (allocated + len) * 2;
              newp = (char *) realloc (result, allocated);
              if (newp == NULL)
                @{
                  free (result);
                  return NULL;
                @}
              wp = newp + (wp - result);
              result = newp;
            @}

          wp = mempcpy (wp, s, len);
        @}

      /* @r{Terminate the result string.}  */
      *wp++ = '\0';

      /* @r{Resize memory to the optimal size.}  */
      newp = realloc (result, wp - result);
      if (newp != NULL)
        result = newp;

      va_end (ap);
    @}

  return result;
@}
@end smallexample

With a bit more knowledge about the input strings one could fine-tune
the memory allocation.  The difference we are pointing to here is that
we don't use @code{strcat} anymore.  We always keep track of the length
of the current intermediate result so we can safe us the search for the
end of the string and use @code{mempcpy}.  Please note that we also
don't use @code{stpcpy} which might seem more natural since we handle
with strings.  But this is not necessary since we already know the
length of the string and therefore can use the faster memory copying
function.

Whenever a programmer feels the need to use @code{strcat} she or he
should think twice and look through the program whether the code cannot
be rewritten to take advantage of already calculated results.  Again: it
is almost always unnecessary to use @code{strcat}.

@comment string.h
@comment ISO
@deftypefun {char *} strncat (char *@var{to}, const char *@var{from}, size_t @var{size})
This function is like @code{strcat} except that not more than @var{size}
characters from @var{from} are appended to the end of @var{to}.  A
single null character is also always appended to @var{to}, so the total
allocated size of @var{to} must be at least @code{@var{size} + 1} bytes
longer than its initial length.

The @code{strncat} function could be implemented like this:

@smallexample
@group
char *
strncat (char *to, const char *from, size_t size)
@{
  strncpy (to + strlen (to), from, size);
  return to;
@}
@end group
@end smallexample

The behavior of @code{strncat} is undefined if the strings overlap.
@end deftypefun

Here is an example showing the use of @code{strncpy} and @code{strncat}.
Notice how, in the call to @code{strncat}, the @var{size} parameter
is computed to avoid overflowing the character array @code{buffer}.

@smallexample
@include strncat.c.texi
@end smallexample

@noindent
The output produced by this program looks like:

@smallexample
hello
hello, wo
@end smallexample

@comment string.h
@comment BSD
@deftypefun void bcopy (const void *@var{from}, void *@var{to}, size_t @var{size})
This is a partially obsolete alternative for @code{memmove}, derived from
BSD.  Note that it is not quite equivalent to @code{memmove}, because the
arguments are not in the same order and there is no return value.
@end deftypefun

@comment string.h
@comment BSD
@deftypefun void bzero (void *@var{block}, size_t @var{size})
This is a partially obsolete alternative for @code{memset}, derived from
BSD.  Note that it is not as general as @code{memset}, because the only
value it can store is zero.
@end deftypefun

@node String/Array Comparison
@section String/Array Comparison
@cindex comparing strings and arrays
@cindex string comparison functions
@cindex array comparison functions
@cindex predicates on strings
@cindex predicates on arrays

You can use the functions in this section to perform comparisons on the
contents of strings and arrays.  As well as checking for equality, these
functions can also be used as the ordering functions for sorting
operations.  @xref{Searching and Sorting}, for an example of this.

Unlike most comparison operations in C, the string comparison functions
return a nonzero value if the strings are @emph{not} equivalent rather
than if they are.  The sign of the value indicates the relative ordering
of the first characters in the strings that are not equivalent:  a
negative value indicates that the first string is ``less'' than the
second, while a positive value indicates that the first string is
``greater''.

The most common use of these functions is to check only for equality.
This is canonically done with an expression like @w{@samp{! strcmp (s1, s2)}}.

All of these functions are declared in the header file @file{string.h}.
@pindex string.h

@comment string.h
@comment ISO
@deftypefun int memcmp (const void *@var{a1}, const void *@var{a2}, size_t @var{size})
The function @code{memcmp} compares the @var{size} bytes of memory
beginning at @var{a1} against the @var{size} bytes of memory beginning
at @var{a2}.  The value returned has the same sign as the difference
between the first differing pair of bytes (interpreted as @code{unsigned
char} objects, then promoted to @code{int}).

If the contents of the two blocks are equal, @code{memcmp} returns
@code{0}.
@end deftypefun

On arbitrary arrays, the @code{memcmp} function is mostly useful for
testing equality.  It usually isn't meaningful to do byte-wise ordering
comparisons on arrays of things other than bytes.  For example, a
byte-wise comparison on the bytes that make up floating-point numbers
isn't likely to tell you anything about the relationship between the
values of the floating-point numbers.

You should also be careful about using @code{memcmp} to compare objects
that can contain ``holes'', such as the padding inserted into structure
objects to enforce alignment requirements, extra space at the end of
unions, and extra characters at the ends of strings whose length is less
than their allocated size.  The contents of these ``holes'' are
indeterminate and may cause strange behavior when performing byte-wise
comparisons.  For more predictable results, perform an explicit
component-wise comparison.

For example, given a structure type definition like:

@smallexample
struct foo
  @{
    unsigned char tag;
    union
      @{
        double f;
        long i;
        char *p;
      @} value;
  @};
@end smallexample

@noindent
you are better off writing a specialized comparison function to compare
@code{struct foo} objects instead of comparing them with @code{memcmp}.

@comment string.h
@comment ISO
@deftypefun int strcmp (const char *@var{s1}, const char *@var{s2})
The @code{strcmp} function compares the string @var{s1} against
@var{s2}, returning a value that has the same sign as the difference
between the first differing pair of characters (interpreted as
@code{unsigned char} objects, then promoted to @code{int}).

If the two strings are equal, @code{strcmp} returns @code{0}.

A consequence of the ordering used by @code{strcmp} is that if @var{s1}
is an initial substring of @var{s2}, then @var{s1} is considered to be
``less than'' @var{s2}.
@end deftypefun

@comment string.h
@comment BSD
@deftypefun int strcasecmp (const char *@var{s1}, const char *@var{s2})
This function is like @code{strcmp}, except that differences in case are
ignored.  How uppercase and lowercase characters are related is
determined by the currently selected locale.  In the standard @code{"C"}
locale the characters @"A and @"a do not match but in a locale which
regards these characters as parts of the alphabet they do match.

@noindent
@code{strcasecmp} is derived from BSD.
@end deftypefun

@comment string.h
@comment BSD
@deftypefun int strncasecmp (const char *@var{s1}, const char *@var{s2}, size_t @var{n})
This function is like @code{strncmp}, except that differences in case
are ignored.  Like @code{strcasecmp}, it is locale dependent how
uppercase and lowercase characters are related.

@noindent
@code{strncasecmp} is a GNU extension.
@end deftypefun

@comment string.h
@comment ISO
@deftypefun int strncmp (const char *@var{s1}, const char *@var{s2}, size_t @var{size})
This function is the similar to @code{strcmp}, except that no more than
@var{size} characters are compared.  In other words, if the two strings are
the same in their first @var{size} characters, the return value is zero.
@end deftypefun

Here are some examples showing the use of @code{strcmp} and @code{strncmp}.
These examples assume the use of the ASCII character set.  (If some
other character set---say, EBCDIC---is used instead, then the glyphs
are associated with different numeric codes, and the return values
and ordering may differ.)

@smallexample
strcmp ("hello", "hello")
    @result{} 0    /* @r{These two strings are the same.} */
strcmp ("hello", "Hello")
    @result{} 32   /* @r{Comparisons are case-sensitive.} */
strcmp ("hello", "world")
    @result{} -15  /* @r{The character @code{'h'} comes before @code{'w'}.} */
strcmp ("hello", "hello, world")
    @result{} -44  /* @r{Comparing a null character against a comma.} */
strncmp ("hello", "hello, world", 5)
    @result{} 0    /* @r{The initial 5 characters are the same.} */
strncmp ("hello, world", "hello, stupid world!!!", 5)
    @result{} 0    /* @r{The initial 5 characters are the same.} */
@end smallexample

@comment string.h
@comment GNU
@deftypefun int strverscmp (const char *@var{s1}, const char *@var{s2})
The @code{strverscmp} function compares the string @var{s1} against
@var{s2}, considering them as holding indices/version numbers.  Return
value follows the same conventions as found in the @code{strverscmp}
function.  In fact, if @var{s1} and @var{s2} contain no digits,
@code{strverscmp} behaves like @code{strcmp}.

Basically, we compare strings normally (character by character), until
we find a digit in each string - then we enter a special comparison
mode, where each sequence of digits is taken as a whole.  If we reach the
end of these two parts without noticing a difference, we return to the
standard comparison mode.  There are two types of numeric parts:
"integral" and "fractional" (those  begin with a '0'). The types
of the numeric parts affect the way we sort them:

@itemize @bullet
@item
integral/integral: we compare values as you would expect.

@item
fractional/integral: the fractional part is less than the integral one.
Again, no surprise.

@item
fractional/fractional: the things become a bit more complex.
If the common prefix contains only leading zeroes, the longest part is less
than the other one; else the comparison behaves normally.
@end itemize

@smallexample
strverscmp ("no digit", "no digit")
    @result{} 0    /* @r{same behaviour as strcmp.} */
strverscmp ("item#99", "item#100")
    @result{} <0   /* @r{same prefix, but 99 < 100.} */
strverscmp ("alpha1", "alpha001")
    @result{} >0   /* @r{fractional part inferior to integral one.} */
strverscmp ("part1_f012", "part1_f01")
    @result{} >0   /* @r{two fractional parts.} */
strverscmp ("foo.009", "foo.0")
    @result{} <0   /* @r{idem, but with leading zeroes only.} */
@end smallexample

This function is especially useful when dealing with filename sorting,
because filenames frequently hold indices/version numbers.

@code{strverscmp} is a GNU extension.
@end deftypefun

@comment string.h
@comment BSD
@deftypefun int bcmp (const void *@var{a1}, const void *@var{a2}, size_t @var{size})
This is an obsolete alias for @code{memcmp}, derived from BSD.
@end deftypefun

@node Collation Functions
@section Collation Functions

@cindex collating strings
@cindex string collation functions

In some locales, the conventions for lexicographic ordering differ from
the strict numeric ordering of character codes.  For example, in Spanish
most glyphs with diacritical marks such as accents are not considered
distinct letters for the purposes of collation.  On the other hand, the
two-character sequence @samp{ll} is treated as a single letter that is
collated immediately after @samp{l}.

You can use the functions @code{strcoll} and @code{strxfrm} (declared in
the header file @file{string.h}) to compare strings using a collation
ordering appropriate for the current locale.  The locale used by these
functions in particular can be specified by setting the locale for the
@code{LC_COLLATE} category; see @ref{Locales}.
@pindex string.h

In the standard C locale, the collation sequence for @code{strcoll} is
the same as that for @code{strcmp}.

Effectively, the way these functions work is by applying a mapping to
transform the characters in a string to a byte sequence that represents
the string's position in the collating sequence of the current locale.
Comparing two such byte sequences in a simple fashion is equivalent to
comparing the strings with the locale's collating sequence.

The function @code{strcoll} performs this translation implicitly, in
order to do one comparison.  By contrast, @code{strxfrm} performs the
mapping explicitly.  If you are making multiple comparisons using the
same string or set of strings, it is likely to be more efficient to use
@code{strxfrm} to transform all the strings just once, and subsequently
compare the transformed strings with @code{strcmp}.

@comment string.h
@comment ISO
@deftypefun int strcoll (const char *@var{s1}, const char *@var{s2})
The @code{strcoll} function is similar to @code{strcmp} but uses the
collating sequence of the current locale for collation (the
@code{LC_COLLATE} locale).
@end deftypefun

Here is an example of sorting an array of strings, using @code{strcoll}
to compare them.  The actual sort algorithm is not written here; it
comes from @code{qsort} (@pxref{Array Sort Function}).  The job of the
code shown here is to say how to compare the strings while sorting them.
(Later on in this section, we will show a way to do this more
efficiently using @code{strxfrm}.)

@smallexample
/* @r{This is the comparison function used with @code{qsort}.} */

int
compare_elements (char **p1, char **p2)
@{
  return strcoll (*p1, *p2);
@}

/* @r{This is the entry point---the function to sort}
   @r{strings using the locale's collating sequence.} */

void
sort_strings (char **array, int nstrings)
@{
  /* @r{Sort @code{temp_array} by comparing the strings.} */
  qsort (array, nstrings,
         sizeof (char *), compare_elements);
@}
@end smallexample

@cindex converting string to collation order
@comment string.h
@comment ISO
@deftypefun size_t strxfrm (char *@var{to}, const char *@var{from}, size_t @var{size})
The function @code{strxfrm} transforms @var{string} using the collation
transformation determined by the locale currently selected for
collation, and stores the transformed string in the array @var{to}.  Up
to @var{size} characters (including a terminating null character) are
stored.

The behavior is undefined if the strings @var{to} and @var{from}
overlap; see @ref{Copying and Concatenation}.

The return value is the length of the entire transformed string.  This
value is not affected by the value of @var{size}, but if it is greater
or equal than @var{size}, it means that the transformed string did not
entirely fit in the array @var{to}.  In this case, only as much of the
string as actually fits was stored.  To get the whole transformed
string, call @code{strxfrm} again with a bigger output array.

The transformed string may be longer than the original string, and it
may also be shorter.

If @var{size} is zero, no characters are stored in @var{to}.  In this
case, @code{strxfrm} simply returns the number of characters that would
be the length of the transformed string.  This is useful for determining
what size string to allocate.  It does not matter what @var{to} is if
@var{size} is zero; @var{to} may even be a null pointer.
@end deftypefun

Here is an example of how you can use @code{strxfrm} when
you plan to do many comparisons.  It does the same thing as the previous
example, but much faster, because it has to transform each string only
once, no matter how many times it is compared with other strings.  Even
the time needed to allocate and free storage is much less than the time
we save, when there are many strings.

@smallexample
struct sorter @{ char *input; char *transformed; @};

/* @r{This is the comparison function used with @code{qsort}}
   @r{to sort an array of @code{struct sorter}.} */

int
compare_elements (struct sorter *p1, struct sorter *p2)
@{
  return strcmp (p1->transformed, p2->transformed);
@}

/* @r{This is the entry point---the function to sort}
   @r{strings using the locale's collating sequence.} */

void
sort_strings_fast (char **array, int nstrings)
@{
  struct sorter temp_array[nstrings];
  int i;

  /* @r{Set up @code{temp_array}.  Each element contains}
     @r{one input string and its transformed string.} */
  for (i = 0; i < nstrings; i++)
    @{
      size_t length = strlen (array[i]) * 2;
      char *transformed;
      size_t transformed_length;

      temp_array[i].input = array[i];

      /* @r{First try a buffer perhaps big enough.}  */
      transformed = (char *) xmalloc (length);

      /* @r{Transform @code{array[i]}.}  */
      transformed_length = strxfrm (transformed, array[i], length);

      /* @r{If the buffer was not large enough, resize it}
         @r{and try again.}  */
      if (transformed_length >= length)
        @{
          /* @r{Allocate the needed space. +1 for terminating}
             @r{@code{NUL} character.}  */
          transformed = (char *) xrealloc (transformed,
                                           transformed_length + 1);

          /* @r{The return value is not interesting because we know}
             @r{how long the transformed string is.}  */
          (void) strxfrm (transformed, array[i],
                          transformed_length + 1);
        @}

      temp_array[i].transformed = transformed;
    @}

  /* @r{Sort @code{temp_array} by comparing transformed strings.} */
  qsort (temp_array, sizeof (struct sorter),
         nstrings, compare_elements);

  /* @r{Put the elements back in the permanent array}
     @r{in their sorted order.} */
  for (i = 0; i < nstrings; i++)
    array[i] = temp_array[i].input;

  /* @r{Free the strings we allocated.} */
  for (i = 0; i < nstrings; i++)
    free (temp_array[i].transformed);
@}
@end smallexample

@strong{Compatibility Note:}  The string collation functions are a new
feature of @w{ISO C 89}.  Older C dialects have no equivalent feature.

@node Search Functions
@section Search Functions

This section describes library functions which perform various kinds
of searching operations on strings and arrays.  These functions are
declared in the header file @file{string.h}.
@pindex string.h
@cindex search functions (for strings)
@cindex string search functions

@comment string.h
@comment ISO
@deftypefun {void *} memchr (const void *@var{block}, int @var{c}, size_t @var{size})
This function finds the first occurrence of the byte @var{c} (converted
to an @code{unsigned char}) in the initial @var{size} bytes of the
object beginning at @var{block}.  The return value is a pointer to the
located byte, or a null pointer if no match was found.
@end deftypefun

@comment string.h
@comment ISO
@deftypefun {char *} strchr (const char *@var{string}, int @var{c})
The @code{strchr} function finds the first occurrence of the character
@var{c} (converted to a @code{char}) in the null-terminated string
beginning at @var{string}.  The return value is a pointer to the located
character, or a null pointer if no match was found.

For example,
@smallexample
strchr ("hello, world", 'l')
    @result{} "llo, world"
strchr ("hello, world", '?')
    @result{} NULL
@end smallexample

The terminating null character is considered to be part of the string,
so you can use this function get a pointer to the end of a string by
specifying a null character as the value of the @var{c} argument.
@end deftypefun

@comment string.h
@comment BSD
@deftypefun {char *} index (const char *@var{string}, int @var{c})
@code{index} is another name for @code{strchr}; they are exactly the same.
New code should always use @code{strchr} since this name is defined in
@w{ISO C} while @code{index} is a BSD invention which never was available
on @w{System V} derived systems.
@end deftypefun

One useful, but unusual, use of the @code{strchr} or @code{index}
function is when one wants to have a pointer pointing to the NUL byte
terminating a string.  This is often written in this way:

@smallexample
  s += strlen (s);
@end smallexample

@noindent
This is almost optimal but the addition operation duplicated a bit of
the work already done in the @code{strlen} function.  A better solution
is this:

@smallexample
  s = strchr (s, '\0');
@end smallexample

There is no restriction on the second parameter of @code{strchr} so it
could very well also be the NUL character.  Those readers thinking very
hard about this might now point out that the @code{strchr} function is
more expensive than the @code{strlen} function since we have two abort
criteria.  This is right.  But when using the GNU C library is used this
@code{strchr} call gets optimized in a special way so that this version
actually is faster.

@comment string.h
@comment ISO
@deftypefun {char *} strrchr (const char *@var{string}, int @var{c})
The function @code{strrchr} is like @code{strchr}, except that it searches
backwards from the end of the string @var{string} (instead of forwards
from the front).

For example,
@smallexample
strrchr ("hello, world", 'l')
    @result{} "ld"
@end smallexample
@end deftypefun

@comment string.h
@comment BSD
@deftypefun {char *} rindex (const char *@var{string}, int @var{c})
@code{rindex} is another name for @code{strrchr}; they are exactly the same.
New code should always use @code{strrchr} since this name is defined in
@w{ISO C} while @code{rindex} is a BSD invention which never was available
on @w{System V} derived systems.
@end deftypefun

@comment string.h
@comment ISO
@deftypefun {char *} strstr (const char *@var{haystack}, const char *@var{needle})
This is like @code{strchr}, except that it searches @var{haystack} for a
substring @var{needle} rather than just a single character.  It
returns a pointer into the string @var{haystack} that is the first
character of the substring, or a null pointer if no match was found.  If
@var{needle} is an empty string, the function returns @var{haystack}.

For example,
@smallexample
strstr ("hello, world", "l")
    @result{} "llo, world"
strstr ("hello, world", "wo")
    @result{} "world"
@end smallexample
@end deftypefun


@comment string.h
@comment GNU
@deftypefun {void *} memmem (const void *@var{haystack}, size_t @var{haystack-len},@*const void *@var{needle}, size_t @var{needle-len})
This is like @code{strstr}, but @var{needle} and @var{haystack} are byte
arrays rather than null-terminated strings.  @var{needle-len} is the
length of @var{needle} and @var{haystack-len} is the length of
@var{haystack}.@refill

This function is a GNU extension.
@end deftypefun

@comment string.h
@comment ISO
@deftypefun size_t strspn (const char *@var{string}, const char *@var{skipset})
The @code{strspn} (``string span'') function returns the length of the
initial substring of @var{string} that consists entirely of characters that
are members of the set specified by the string @var{skipset}.  The order
of the characters in @var{skipset} is not important.

For example,
@smallexample
strspn ("hello, world", "abcdefghijklmnopqrstuvwxyz")
    @result{} 5
@end smallexample
@end deftypefun

@comment string.h
@comment ISO
@deftypefun size_t strcspn (const char *@var{string}, const char *@var{stopset})
The @code{strcspn} (``string complement span'') function returns the length
of the initial substring of @var{string} that consists entirely of characters
that are @emph{not} members of the set specified by the string @var{stopset}.
(In other words, it returns the offset of the first character in @var{string}
that is a member of the set @var{stopset}.)

For example,
@smallexample
strcspn ("hello, world", " \t\n,.;!?")
    @result{} 5
@end smallexample
@end deftypefun

@comment string.h
@comment ISO
@deftypefun {char *} strpbrk (const char *@var{string}, const char *@var{stopset})
The @code{strpbrk} (``string pointer break'') function is related to
@code{strcspn}, except that it returns a pointer to the first character
in @var{string} that is a member of the set @var{stopset} instead of the
length of the initial substring.  It returns a null pointer if no such
character from @var{stopset} is found.

@c @group  Invalid outside the example.
For example,

@smallexample
strpbrk ("hello, world", " \t\n,.;!?")
    @result{} ", world"
@end smallexample
@c @end group
@end deftypefun

@node Finding Tokens in a String
@section Finding Tokens in a String

@cindex tokenizing strings
@cindex breaking a string into tokens
@cindex parsing tokens from a string
It's fairly common for programs to have a need to do some simple kinds
of lexical analysis and parsing, such as splitting a command string up
into tokens.  You can do this with the @code{strtok} function, declared
in the header file @file{string.h}.
@pindex string.h

@comment string.h
@comment ISO
@deftypefun {char *} strtok (char *@var{newstring}, const char *@var{delimiters})
A string can be split into tokens by making a series of calls to the
function @code{strtok}.

The string to be split up is passed as the @var{newstring} argument on
the first call only.  The @code{strtok} function uses this to set up
some internal state information.  Subsequent calls to get additional
tokens from the same string are indicated by passing a null pointer as
the @var{newstring} argument.  Calling @code{strtok} with another
non-null @var{newstring} argument reinitializes the state information.
It is guaranteed that no other library function ever calls @code{strtok}
behind your back (which would mess up this internal state information).

The @var{delimiters} argument is a string that specifies a set of delimiters
that may surround the token being extracted.  All the initial characters
that are members of this set are discarded.  The first character that is
@emph{not} a member of this set of delimiters marks the beginning of the
next token.  The end of the token is found by looking for the next
character that is a member of the delimiter set.  This character in the
original string @var{newstring} is overwritten by a null character, and the
pointer to the beginning of the token in @var{newstring} is returned.

On the next call to @code{strtok}, the searching begins at the next
character beyond the one that marked the end of the previous token.
Note that the set of delimiters @var{delimiters} do not have to be the
same on every call in a series of calls to @code{strtok}.

If the end of the string @var{newstring} is reached, or if the remainder of
string consists only of delimiter characters, @code{strtok} returns
a null pointer.
@end deftypefun

@strong{Warning:} Since @code{strtok} alters the string it is parsing,
you should always copy the string to a temporary buffer before parsing
it with @code{strtok}.  If you allow @code{strtok} to modify a string
that came from another part of your program, you are asking for trouble;
that string might be used for other purposes after @code{strtok} has
modified it, and it would not have the expected value.

The string that you are operating on might even be a constant.  Then
when @code{strtok} tries to modify it, your program will get a fatal
signal for writing in read-only memory.  @xref{Program Error Signals}.

This is a special case of a general principle: if a part of a program
does not have as its purpose the modification of a certain data
structure, then it is error-prone to modify the data structure
temporarily.

The function @code{strtok} is not reentrant.  @xref{Nonreentrancy}, for
a discussion of where and why reentrancy is important.

Here is a simple example showing the use of @code{strtok}.

@comment Yes, this example has been tested.
@smallexample
#include <string.h>
#include <stddef.h>

@dots{}

const char string[] = "words separated by spaces -- and, punctuation!";
const char delimiters[] = " .,;:!-";
char *token, *cp;

@dots{}

cp = strdupa (string);                /* Make writable copy.  */
token = strtok (cp, delimiters);      /* token => "words" */
token = strtok (NULL, delimiters);    /* token => "separated" */
token = strtok (NULL, delimiters);    /* token => "by" */
token = strtok (NULL, delimiters);    /* token => "spaces" */
token = strtok (NULL, delimiters);    /* token => "and" */
token = strtok (NULL, delimiters);    /* token => "punctuation" */
token = strtok (NULL, delimiters);    /* token => NULL */
@end smallexample

The GNU C library contains two more functions for tokenizing a string
which overcome the limitation of non-reentrancy.

@comment string.h
@comment POSIX
@deftypefun {char *} strtok_r (char *@var{newstring}, const char *@var{delimiters}, char **@var{save_ptr})
Just like @code{strtok}, this function splits the string into several
tokens which can be accessed by successive calls to @code{strtok_r}.
The difference is that the information about the next token is stored in
the space pointed to by the third argument, @var{save_ptr}, which is a
pointer to a string pointer.  Calling @code{strtok_r} with a null
pointer for @var{newstring} and leaving @var{save_ptr} between the calls
unchanged does the job without hindering reentrancy.

This function is defined in POSIX-1 and can be found on many systems
which support multi-threading.
@end deftypefun

@comment string.h
@comment BSD
@deftypefun {char *} strsep (char **@var{string_ptr}, const char *@var{delimiter})
This function is just @code{strtok_r} with the @var{newstring} argument
replaced by the @var{save_ptr} argument.  The initialization of the
moving pointer has to be done by the user.  Successive calls to
@code{strsep} move the pointer along the tokens separated by
@var{delimiter}, returning the address of the next token and updating
@var{string_ptr} to point to the beginning of the next token.

If the input string contains more than one character from
@var{delimiter} in a row @code{strsep} returns an empty string for each
pair of characters from @var{delimiter}.  This means that a program
normally should test for @code{strsep} returning an empty string before
processing it.

This function was introduced in 4.3BSD and therefore is widely available.
@end deftypefun

Here is how the above example looks like when @code{strsep} is used.

@comment Yes, this example has been tested.
@smallexample
#include <string.h>
#include <stddef.h>

@dots{}

const char string[] = "words separated by spaces -- and, punctuation!";
const char delimiters[] = " .,;:!-";
char *running;
char *token;

@dots{}

running = strdupa (string);
token = strsep (&running, delimiters);    /* token => "words" */
token = strsep (&running, delimiters);    /* token => "separated" */
token = strsep (&running, delimiters);    /* token => "by" */
token = strsep (&running, delimiters);    /* token => "spaces" */
token = strsep (&running, delimiters);    /* token => "" */
token = strsep (&running, delimiters);    /* token => "" */
token = strsep (&running, delimiters);    /* token => "" */
token = strsep (&running, delimiters);    /* token => "and" */
token = strsep (&running, delimiters);    /* token => "" */
token = strsep (&running, delimiters);    /* token => "punctuation" */
token = strsep (&running, delimiters);    /* token => "" */
token = strsep (&running, delimiters);    /* token => NULL */
@end smallexample

@node Encode Binary Data
@section Encode Binary Data

To store or transfer binary data in environments which only support text
one has to encode the binary data by mapping the input bytes to
characters in the range allowed for storing or transfering.  SVID
systems (and nowadays XPG compliant systems) provide minimal support for
this task.

@comment stdlib.h
@comment XPG
@deftypefun {char *} l64a (long int @var{n})
This function encodes a 32-bit input value using characters from the
basic character set.  It returns a pointer to a 6 character buffer which
contains an encoded version of @var{n}.  To encode a series of bytes the
user must copy the returned string to a destination buffer.  It returns
the empty string if @var{n} is zero, which is somewhat bizarre but
mandated by the standard.@*
@strong{Warning:} Since a static buffer is used this function should not
be used in multi-threaded programs.  There is no thread-safe alternative
to this function in the C library.@*
@strong{Compatibility Note:} The XPG standard states that the return
value of @code{l64a} is undefined if @var{n} is negative.  In the GNU
implementation, @code{l64a} treats its argument as unsigned, so it will
return a sensible encoding for any nonzero @var{n}; however, portable
programs should not rely on this.

To encode a large buffer @code{l64a} must be called in a loop, once for
each 32-bit word of the buffer.  For example, one could do something
like this:

@smallexample
char *
encode (const void *buf, size_t len)
@{
  /* @r{We know in advance how long the buffer has to be.} */
  unsigned char *in = (unsigned char *) buf;
  char *out = malloc (6 + ((len + 3) / 4) * 6 + 1);
  char *cp = out;

  /* @r{Encode the length.} */
  /* @r{Using `htonl' is necessary so that the data can be}
     @r{decoded even on machines with different byte order.} */

  cp = mempcpy (cp, l64a (htonl (len)), 6);

  while (len > 3)
    @{
      unsigned long int n = *in++;
      n = (n << 8) | *in++;
      n = (n << 8) | *in++;
      n = (n << 8) | *in++;
      len -= 4;
      if (n)
        cp = mempcpy (cp, l64a (htonl (n)), 6);
      else
            /* @r{`l64a' returns the empty string for n==0, so we }
               @r{must generate its encoding (}"......"@r{) by hand.} */
        cp = stpcpy (cp, "......");
    @}
  if (len > 0)
    @{
      unsigned long int n = *in++;
      if (--len > 0)
        @{
          n = (n << 8) | *in++;
          if (--len > 0)
            n = (n << 8) | *in;
        @}
      memcpy (cp, l64a (htonl (n)), 6);
      cp += 6;
    @}
  *cp = '\0';
  return out;
@}
@end smallexample

It is strange that the library does not provide the complete
functionality needed but so be it.

@end deftypefun

To decode data produced with @code{l64a} the following function should be
used.

@comment stdlib.h
@comment XPG
@deftypefun {long int} a64l (const char *@var{string})
The parameter @var{string} should contain a string which was produced by
a call to @code{l64a}.  The function processes at least 6 characters of
this string, and decodes the characters it finds according to the table
below.  It stops decoding when it finds a character not in the table,
rather like @code{atoi}; if you have a buffer which has been broken into
lines, you must be careful to skip over the end-of-line characters.

The decoded number is returned as a @code{long int} value.
@end deftypefun

The @code{l64a} and @code{a64l} functions use a base 64 encoding, in
which each character of an encoded string represents six bits of an
input word.  These symbols are used for the base 64 digits:

@multitable {xxxxx} {xxx} {xxx} {xxx} {xxx} {xxx} {xxx} {xxx} {xxx}
@item              @tab 0 @tab 1 @tab 2 @tab 3 @tab 4 @tab 5 @tab 6 @tab 7
@item       0      @tab @code{.} @tab @code{/} @tab @code{0} @tab @code{1}
                   @tab @code{2} @tab @code{3} @tab @code{4} @tab @code{5}
@item       8      @tab @code{6} @tab @code{7} @tab @code{8} @tab @code{9}
                   @tab @code{A} @tab @code{B} @tab @code{C} @tab @code{D}
@item       16     @tab @code{E} @tab @code{F} @tab @code{G} @tab @code{H}
                   @tab @code{I} @tab @code{J} @tab @code{K} @tab @code{L}
@item       24     @tab @code{M} @tab @code{N} @tab @code{O} @tab @code{P}
                   @tab @code{Q} @tab @code{R} @tab @code{S} @tab @code{T}
@item       32     @tab @code{U} @tab @code{V} @tab @code{W} @tab @code{X}
                   @tab @code{Y} @tab @code{Z} @tab @code{a} @tab @code{b}
@item       40     @tab @code{c} @tab @code{d} @tab @code{e} @tab @code{f}
                   @tab @code{g} @tab @code{h} @tab @code{i} @tab @code{j}
@item       48     @tab @code{k} @tab @code{l} @tab @code{m} @tab @code{n}
                   @tab @code{o} @tab @code{p} @tab @code{q} @tab @code{r}
@item       56     @tab @code{s} @tab @code{t} @tab @code{u} @tab @code{v}
                   @tab @code{w} @tab @code{x} @tab @code{y} @tab @code{z}
@end multitable

This encoding scheme is not standard.  There are some other encoding
methods which are much more widely used (UU encoding, MIME encoding).
Generally, it is better to use one of these encodings.

@node Argz and Envz Vectors
@section Argz and Envz Vectors

@cindex argz vectors (string vectors)
@cindex string vectors, null-character separated
@cindex argument vectors, null-character separated
@dfn{argz vectors} are vectors of strings in a contiguous block of
memory, each element separated from its neighbors by null-characters
(@code{'\0'}).

@cindex envz vectors (environment vectors)
@cindex environment vectors, null-character separated
@dfn{Envz vectors} are an extension of argz vectors where each element is a
name-value pair, separated by a @code{'='} character (as in a Unix
environment).

@menu
* Argz Functions::              Operations on argz vectors.
* Envz Functions::              Additional operations on environment vectors.
@end menu

@node Argz Functions, Envz Functions, , Argz and Envz Vectors
@subsection Argz Functions

Each argz vector is represented by a pointer to the first element, of
type @code{char *}, and a size, of type @code{size_t}, both of which can
be initialized to @code{0} to represent an empty argz vector.  All argz
functions accept either a pointer and a size argument, or pointers to
them, if they will be modified.

The argz functions use @code{malloc}/@code{realloc} to allocate/grow
argz vectors, and so any argz vector creating using these functions may
be freed by using @code{free}; conversely, any argz function that may
grow a string expects that string to have been allocated using
@code{malloc} (those argz functions that only examine their arguments or
modify them in place will work on any sort of memory).
@xref{Unconstrained Allocation}.

All argz functions that do memory allocation have a return type of
@code{error_t}, and return @code{0} for success, and @code{ENOMEM} if an
allocation error occurs.

@pindex argz.h
These functions are declared in the standard include file @file{argz.h}.

@comment argz.h
@comment GNU
@deftypefun {error_t} argz_create (char *const @var{argv}[], char **@var{argz}, size_t *@var{argz_len})
The @code{argz_create} function converts the Unix-style argument vector
@var{argv} (a vector of pointers to normal C strings, terminated by
@code{(char *)0}; @pxref{Program Arguments}) into an argz vector with
the same elements, which is returned in @var{argz} and @var{argz_len}.
@end deftypefun

@comment argz.h
@comment GNU
@deftypefun {error_t} argz_create_sep (const char *@var{string}, int @var{sep}, char **@var{argz}, size_t *@var{argz_len})
The @code{argz_create_sep} function converts the null-terminated string
@var{string} into an argz vector (returned in @var{argz} and
@var{argz_len}) by splitting it into elements at every occurance of the
character @var{sep}.
@end deftypefun

@comment argz.h
@comment GNU
@deftypefun {size_t} argz_count (const char *@var{argz}, size_t @var{arg_len})
Returns the number of elements in the argz vector @var{argz} and
@var{argz_len}.
@end deftypefun

@comment argz.h
@comment GNU
@deftypefun {void} argz_extract (char *@var{argz}, size_t @var{argz_len}, char **@var{argv})
The @code{argz_extract} function converts the argz vector @var{argz} and
@var{argz_len} into a Unix-style argument vector stored in @var{argv},
by putting pointers to every element in @var{argz} into successive
positions in @var{argv}, followed by a terminator of @code{0}.
@var{Argv} must be pre-allocated with enough space to hold all the
elements in @var{argz} plus the terminating @code{(char *)0}
(@code{(argz_count (@var{argz}, @var{argz_len}) + 1) * sizeof (char *)}
bytes should be enough).  Note that the string pointers stored into
@var{argv} point into @var{argz}---they are not copies---and so
@var{argz} must be copied if it will be changed while @var{argv} is
still active.  This function is useful for passing the elements in
@var{argz} to an exec function (@pxref{Executing a File}).
@end deftypefun

@comment argz.h
@comment GNU
@deftypefun {void} argz_stringify (char *@var{argz}, size_t @var{len}, int @var{sep})
The @code{argz_stringify} converts @var{argz} into a normal string with
the elements separated by the character @var{sep}, by replacing each
@code{'\0'} inside @var{argz} (except the last one, which terminates the
string) with @var{sep}.  This is handy for printing @var{argz} in a
readable manner.
@end deftypefun

@comment argz.h
@comment GNU
@deftypefun {error_t} argz_add (char **@var{argz}, size_t *@var{argz_len}, const char *@var{str})
The @code{argz_add} function adds the string @var{str} to the end of the
argz vector @code{*@var{argz}}, and updates @code{*@var{argz}} and
@code{*@var{argz_len}} accordingly.
@end deftypefun

@comment argz.h
@comment GNU
@deftypefun {error_t} argz_add_sep (char **@var{argz}, size_t *@var{argz_len}, const char *@var{str}, int @var{delim})
The @code{argz_add_sep} function is similar to @code{argz_add}, but
@var{str} is split into separate elements in the result at occurances of
the character @var{delim}.  This is useful, for instance, for
adding the components of a Unix search path to an argz vector, by using
a value of @code{':'} for @var{delim}.
@end deftypefun

@comment argz.h
@comment GNU
@deftypefun {error_t} argz_append (char **@var{argz}, size_t *@var{argz_len}, const char *@var{buf}, size_t @var{buf_len})
The @code{argz_append} function appends @var{buf_len} bytes starting at
@var{buf} to the argz vector @code{*@var{argz}}, reallocating
@code{*@var{argz}} to accommodate it, and adding @var{buf_len} to
@code{*@var{argz_len}}.
@end deftypefun

@comment argz.h
@comment GNU
@deftypefun {error_t} argz_delete (char **@var{argz}, size_t *@var{argz_len}, char *@var{entry})
If @var{entry} points to the beginning of one of the elements in the
argz vector @code{*@var{argz}}, the @code{argz_delete} function will
remove this entry and reallocate @code{*@var{argz}}, modifying
@code{*@var{argz}} and @code{*@var{argz_len}} accordingly.  Note that as
destructive argz functions usually reallocate their argz argument,
pointers into argz vectors such as @var{entry} will then become invalid.
@end deftypefun

@comment argz.h
@comment GNU
@deftypefun {error_t} argz_insert (char **@var{argz}, size_t *@var{argz_len}, char *@var{before}, const char *@var{entry})
The @code{argz_insert} function inserts the string @var{entry} into the
argz vector @code{*@var{argz}} at a point just before the existing
element pointed to by @var{before}, reallocating @code{*@var{argz}} and
updating @code{*@var{argz}} and @code{*@var{argz_len}}.  If @var{before}
is @code{0}, @var{entry} is added to the end instead (as if by
@code{argz_add}).  Since the first element is in fact the same as
@code{*@var{argz}}, passing in @code{*@var{argz}} as the value of
@var{before} will result in @var{entry} being inserted at the beginning.
@end deftypefun

@comment argz.h
@comment GNU
@deftypefun {char *} argz_next (char *@var{argz}, size_t @var{argz_len}, const char *@var{entry})
The @code{argz_next} function provides a convenient way of iterating
over the elements in the argz vector @var{argz}.  It returns a pointer
to the next element in @var{argz} after the element @var{entry}, or
@code{0} if there are no elements following @var{entry}.  If @var{entry}
is @code{0}, the first element of @var{argz} is returned.

This behavior suggests two styles of iteration:

@smallexample
    char *entry = 0;
    while ((entry = argz_next (@var{argz}, @var{argz_len}, entry)))
      @var{action};
@end smallexample

(the double parentheses are necessary to make some C compilers shut up
about what they consider a questionable @code{while}-test) and:

@smallexample
    char *entry;
    for (entry = @var{argz};
         entry;
         entry = argz_next (@var{argz}, @var{argz_len}, entry))
      @var{action};
@end smallexample

Note that the latter depends on @var{argz} having a value of @code{0} if
it is empty (rather than a pointer to an empty block of memory); this
invariant is maintained for argz vectors created by the functions here.
@end deftypefun

@comment argz.h
@comment GNU
@deftypefun error_t argz_replace (@w{char **@var{argz}, size_t *@var{argz_len}}, @w{const char *@var{str}, const char *@var{with}}, @w{unsigned *@var{replace_count}})
Replace any occurances of the string @var{str} in @var{argz} with
@var{with}, reallocating @var{argz} as necessary.  If
@var{replace_count} is non-zero, @code{*@var{replace_count}} will be
incremented by number of replacements performed.
@end deftypefun

@node Envz Functions, , Argz Functions, Argz and Envz Vectors
@subsection Envz Functions

Envz vectors are just argz vectors with additional constraints on the form
of each element; as such, argz functions can also be used on them, where it
makes sense.

Each element in an envz vector is a name-value pair, separated by a @code{'='}
character; if multiple @code{'='} characters are present in an element, those
after the first are considered part of the value, and treated like all other
non-@code{'\0'} characters.

If @emph{no} @code{'='} characters are present in an element, that element is
considered the name of a ``null'' entry, as distinct from an entry with an
empty value: @code{envz_get} will return @code{0} if given the name of null
entry, whereas an entry with an empty value would result in a value of
@code{""}; @code{envz_entry} will still find such entries, however.  Null
entries can be removed with @code{envz_strip} function.

As with argz functions, envz functions that may allocate memory (and thus
fail) have a return type of @code{error_t}, and return either @code{0} or
@code{ENOMEM}.

@pindex envz.h
These functions are declared in the standard include file @file{envz.h}.

@comment envz.h
@comment GNU
@deftypefun {char *} envz_entry (const char *@var{envz}, size_t @var{envz_len}, const char *@var{name})
The @code{envz_entry} function finds the entry in @var{envz} with the name
@var{name}, and returns a pointer to the whole entry---that is, the argz
element which begins with @var{name} followed by a @code{'='} character.  If
there is no entry with that name, @code{0} is returned.
@end deftypefun

@comment envz.h
@comment GNU
@deftypefun {char *} envz_get (const char *@var{envz}, size_t @var{envz_len}, const char *@var{name})
The @code{envz_get} function finds the entry in @var{envz} with the name
@var{name} (like @code{envz_entry}), and returns a pointer to the value
portion of that entry (following the @code{'='}).  If there is no entry with
that name (or only a null entry), @code{0} is returned.
@end deftypefun

@comment envz.h
@comment GNU
@deftypefun {error_t} envz_add (char **@var{envz}, size_t *@var{envz_len}, const char *@var{name}, const char *@var{value})
The @code{envz_add} function adds an entry to @code{*@var{envz}}
(updating @code{*@var{envz}} and @code{*@var{envz_len}}) with the name
@var{name}, and value @var{value}.  If an entry with the same name
already exists in @var{envz}, it is removed first.  If @var{value} is
@code{0}, then the new entry will the special null type of entry
(mentioned above).
@end deftypefun

@comment envz.h
@comment GNU
@deftypefun {error_t} envz_merge (char **@var{envz}, size_t *@var{envz_len}, const char *@var{envz2}, size_t @var{envz2_len}, int @var{override})
The @code{envz_merge} function adds each entry in @var{envz2} to @var{envz},
as if with @code{envz_add}, updating @code{*@var{envz}} and
@code{*@var{envz_len}}.  If @var{override} is true, then values in @var{envz2}
will supersede those with the same name in @var{envz}, otherwise not.

Null entries are treated just like other entries in this respect, so a null
entry in @var{envz} can prevent an entry of the same name in @var{envz2} from
being added to @var{envz}, if @var{override} is false.
@end deftypefun

@comment envz.h
@comment GNU
@deftypefun {void} envz_strip (char **@var{envz}, size_t *@var{envz_len})
The @code{envz_strip} function removes any null entries from @var{envz},
updating @code{*@var{envz}} and @code{*@var{envz_len}}.
@end deftypefun