newlib-cygwin/newlib/libc/stdlib/malloc.c

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/* VxWorks provides its own version of malloc, and we can't use this
one because VxWorks does not provide sbrk. So we have a hook to
not compile this code. */
/* The routines here are simple cover fns to the routines that do the real
work (the reentrant versions). */
/* FIXME: Does the warning below (see WARNINGS) about non-reentrancy still
apply? A first guess would be "no", but how about reentrancy in the *same*
thread? */
#ifdef MALLOC_PROVIDED
int _dummy_malloc = 1;
#else
/*
FUNCTION
<<malloc>>, <<realloc>>, <<free>>---manage memory
INDEX
malloc
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realloc
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reallocf
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INDEX
free
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memalign
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malloc_usable_size
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_malloc_r
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_realloc_r
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_reallocf_r
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INDEX
_free_r
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_memalign_r
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_malloc_usable_size_r
SYNOPSIS
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#include <stdlib.h>
void *malloc(size_t <[nbytes]>);
void *realloc(void *<[aptr]>, size_t <[nbytes]>);
void *reallocf(void *<[aptr]>, size_t <[nbytes]>);
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void free(void *<[aptr]>);
void *memalign(size_t <[align]>, size_t <[nbytes]>);
size_t malloc_usable_size(void *<[aptr]>);
void *_malloc_r(void *<[reent]>, size_t <[nbytes]>);
void *_realloc_r(void *<[reent]>,
void *<[aptr]>, size_t <[nbytes]>);
void *_reallocf_r(void *<[reent]>,
void *<[aptr]>, size_t <[nbytes]>);
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void _free_r(void *<[reent]>, void *<[aptr]>);
void *_memalign_r(void *<[reent]>,
size_t <[align]>, size_t <[nbytes]>);
size_t _malloc_usable_size_r(void *<[reent]>, void *<[aptr]>);
DESCRIPTION
These functions manage a pool of system memory.
Use <<malloc>> to request allocation of an object with at least
<[nbytes]> bytes of storage available. If the space is available,
<<malloc>> returns a pointer to a newly allocated block as its result.
If you already have a block of storage allocated by <<malloc>>, but
you no longer need all the space allocated to it, you can make it
smaller by calling <<realloc>> with both the object pointer and the
new desired size as arguments. <<realloc>> guarantees that the
contents of the smaller object match the beginning of the original object.
Similarly, if you need more space for an object, use <<realloc>> to
request the larger size; again, <<realloc>> guarantees that the
beginning of the new, larger object matches the contents of the
original object.
When you no longer need an object originally allocated by <<malloc>>
or <<realloc>> (or the related function <<calloc>>), return it to the
memory storage pool by calling <<free>> with the address of the object
as the argument. You can also use <<realloc>> for this purpose by
calling it with <<0>> as the <[nbytes]> argument.
The <<reallocf>> function behaves just like <<realloc>> except if the
function is required to allocate new storage and this fails. In this
case <<reallocf>> will free the original object passed in whereas
<<realloc>> will not.
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The <<memalign>> function returns a block of size <[nbytes]> aligned
to a <[align]> boundary. The <[align]> argument must be a power of
two.
The <<malloc_usable_size>> function takes a pointer to a block
allocated by <<malloc>>. It returns the amount of space that is
available in the block. This may or may not be more than the size
requested from <<malloc>>, due to alignment or minimum size
constraints.
The alternate functions <<_malloc_r>>, <<_realloc_r>>, <<_reallocf_r>>,
<<_free_r>>, <<_memalign_r>>, and <<_malloc_usable_size_r>> are reentrant
versions. The extra argument <[reent]> is a pointer to a reentrancy structure.
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If you have multiple threads of execution which may call any of these
routines, or if any of these routines may be called reentrantly, then
you must provide implementations of the <<__malloc_lock>> and
<<__malloc_unlock>> functions for your system. See the documentation
for those functions.
These functions operate by calling the function <<_sbrk_r>> or
<<sbrk>>, which allocates space. You may need to provide one of these
functions for your system. <<_sbrk_r>> is called with a positive
value to allocate more space, and with a negative value to release
previously allocated space if it is no longer required.
@xref{Stubs}.
RETURNS
<<malloc>> returns a pointer to the newly allocated space, if
successful; otherwise it returns <<NULL>>. If your application needs
to generate empty objects, you may use <<malloc(0)>> for this purpose.
<<realloc>> returns a pointer to the new block of memory, or <<NULL>>
if a new block could not be allocated. <<NULL>> is also the result
when you use `<<realloc(<[aptr]>,0)>>' (which has the same effect as
`<<free(<[aptr]>)>>'). You should always check the result of
<<realloc>>; successful reallocation is not guaranteed even when
you request a smaller object.
<<free>> does not return a result.
<<memalign>> returns a pointer to the newly allocated space.
<<malloc_usable_size>> returns the usable size.
PORTABILITY
<<malloc>>, <<realloc>>, and <<free>> are specified by the ANSI C
standard, but other conforming implementations of <<malloc>> may
behave differently when <[nbytes]> is zero.
<<memalign>> is part of SVR4.
<<malloc_usable_size>> is not portable.
Supporting OS subroutines required: <<sbrk>>. */
#include <_ansi.h>
#include <reent.h>
#include <stdlib.h>
#include <malloc.h>
#ifndef _REENT_ONLY
void *
malloc (size_t nbytes) /* get a block */
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{
return _malloc_r (_REENT, nbytes);
}
void
free (void *aptr)
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{
_free_r (_REENT, aptr);
}
#endif
#endif /* ! defined (MALLOC_PROVIDED) */