Retro68/binutils/libiberty/obstacks.texi

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@node Obstacks
@subsection Obstacks
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@cindex obstacks
An @dfn{obstack} is a pool of memory containing a stack of objects. You
can create any number of separate obstacks, and then allocate objects in
specified obstacks. Within each obstack, the last object allocated must
always be the first one freed, but distinct obstacks are independent of
each other.
Aside from this one constraint of order of freeing, obstacks are totally
general: an obstack can contain any number of objects of any size. They
are implemented with macros, so allocation is usually very fast as long as
the objects are usually small. And the only space overhead per object is
the padding needed to start each object on a suitable boundary.
@menu
* Creating Obstacks:: How to declare an obstack in your program.
* Preparing for Obstacks:: Preparations needed before you can
use obstacks.
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* Allocation in an Obstack:: Allocating objects in an obstack.
* Freeing Obstack Objects:: Freeing objects in an obstack.
* Obstack Functions:: The obstack functions are both
functions and macros.
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* Growing Objects:: Making an object bigger by stages.
* Extra Fast Growing:: Extra-high-efficiency (though more
complicated) growing objects.
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* Status of an Obstack:: Inquiries about the status of an obstack.
* Obstacks Data Alignment:: Controlling alignment of objects in obstacks.
* Obstack Chunks:: How obstacks obtain and release chunks;
efficiency considerations.
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* Summary of Obstacks::
@end menu
@node Creating Obstacks
@subsubsection Creating Obstacks
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The utilities for manipulating obstacks are declared in the header
file @file{obstack.h}.
@pindex obstack.h
@comment obstack.h
@comment GNU
@deftp {Data Type} {struct obstack}
An obstack is represented by a data structure of type @code{struct
obstack}. This structure has a small fixed size; it records the status
of the obstack and how to find the space in which objects are allocated.
It does not contain any of the objects themselves. You should not try
to access the contents of the structure directly; use only the functions
described in this chapter.
@end deftp
You can declare variables of type @code{struct obstack} and use them as
obstacks, or you can allocate obstacks dynamically like any other kind
of object. Dynamic allocation of obstacks allows your program to have a
variable number of different stacks. (You can even allocate an
obstack structure in another obstack, but this is rarely useful.)
All the functions that work with obstacks require you to specify which
obstack to use. You do this with a pointer of type @code{struct obstack
*}. In the following, we often say ``an obstack'' when strictly
speaking the object at hand is such a pointer.
The objects in the obstack are packed into large blocks called
@dfn{chunks}. The @code{struct obstack} structure points to a chain of
the chunks currently in use.
The obstack library obtains a new chunk whenever you allocate an object
that won't fit in the previous chunk. Since the obstack library manages
chunks automatically, you don't need to pay much attention to them, but
you do need to supply a function which the obstack library should use to
get a chunk. Usually you supply a function which uses @code{malloc}
directly or indirectly. You must also supply a function to free a chunk.
These matters are described in the following section.
@node Preparing for Obstacks
@subsubsection Preparing for Using Obstacks
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Each source file in which you plan to use the obstack functions
must include the header file @file{obstack.h}, like this:
@smallexample
#include <obstack.h>
@end smallexample
@findex obstack_chunk_alloc
@findex obstack_chunk_free
Also, if the source file uses the macro @code{obstack_init}, it must
declare or define two functions or macros that will be called by the
obstack library. One, @code{obstack_chunk_alloc}, is used to allocate
the chunks of memory into which objects are packed. The other,
@code{obstack_chunk_free}, is used to return chunks when the objects in
them are freed. These macros should appear before any use of obstacks
in the source file.
Usually these are defined to use @code{malloc} via the intermediary
@code{xmalloc} (@pxref{Unconstrained Allocation, , , libc, The GNU C Library Reference Manual}). This is done with
the following pair of macro definitions:
@smallexample
#define obstack_chunk_alloc xmalloc
#define obstack_chunk_free free
@end smallexample
@noindent
Though the memory you get using obstacks really comes from @code{malloc},
using obstacks is faster because @code{malloc} is called less often, for
larger blocks of memory. @xref{Obstack Chunks}, for full details.
At run time, before the program can use a @code{struct obstack} object
as an obstack, it must initialize the obstack by calling
@code{obstack_init}.
@comment obstack.h
@comment GNU
@deftypefun int obstack_init (struct obstack *@var{obstack-ptr})
Initialize obstack @var{obstack-ptr} for allocation of objects. This
function calls the obstack's @code{obstack_chunk_alloc} function. If
allocation of memory fails, the function pointed to by
@code{obstack_alloc_failed_handler} is called. The @code{obstack_init}
function always returns 1 (Compatibility notice: Former versions of
obstack returned 0 if allocation failed).
@end deftypefun
Here are two examples of how to allocate the space for an obstack and
initialize it. First, an obstack that is a static variable:
@smallexample
static struct obstack myobstack;
@dots{}
obstack_init (&myobstack);
@end smallexample
@noindent
Second, an obstack that is itself dynamically allocated:
@smallexample
struct obstack *myobstack_ptr
= (struct obstack *) xmalloc (sizeof (struct obstack));
obstack_init (myobstack_ptr);
@end smallexample
@comment obstack.h
@comment GNU
@defvar obstack_alloc_failed_handler
The value of this variable is a pointer to a function that
@code{obstack} uses when @code{obstack_chunk_alloc} fails to allocate
memory. The default action is to print a message and abort.
You should supply a function that either calls @code{exit}
(@pxref{Program Termination, , , libc, The GNU C Library Reference Manual}) or @code{longjmp} (@pxref{Non-Local
Exits, , , libc, The GNU C Library Reference Manual}) and doesn't return.
@smallexample
void my_obstack_alloc_failed (void)
@dots{}
obstack_alloc_failed_handler = &my_obstack_alloc_failed;
@end smallexample
@end defvar
@node Allocation in an Obstack
@subsubsection Allocation in an Obstack
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@cindex allocation (obstacks)
The most direct way to allocate an object in an obstack is with
@code{obstack_alloc}, which is invoked almost like @code{malloc}.
@comment obstack.h
@comment GNU
@deftypefun {void *} obstack_alloc (struct obstack *@var{obstack-ptr}, int @var{size})
This allocates an uninitialized block of @var{size} bytes in an obstack
and returns its address. Here @var{obstack-ptr} specifies which obstack
to allocate the block in; it is the address of the @code{struct obstack}
object which represents the obstack. Each obstack function or macro
requires you to specify an @var{obstack-ptr} as the first argument.
This function calls the obstack's @code{obstack_chunk_alloc} function if
it needs to allocate a new chunk of memory; it calls
@code{obstack_alloc_failed_handler} if allocation of memory by
@code{obstack_chunk_alloc} failed.
@end deftypefun
For example, here is a function that allocates a copy of a string @var{str}
in a specific obstack, which is in the variable @code{string_obstack}:
@smallexample
struct obstack string_obstack;
char *
copystring (char *string)
@{
size_t len = strlen (string) + 1;
char *s = (char *) obstack_alloc (&string_obstack, len);
memcpy (s, string, len);
return s;
@}
@end smallexample
To allocate a block with specified contents, use the function
@code{obstack_copy}, declared like this:
@comment obstack.h
@comment GNU
@deftypefun {void *} obstack_copy (struct obstack *@var{obstack-ptr}, void *@var{address}, int @var{size})
This allocates a block and initializes it by copying @var{size}
bytes of data starting at @var{address}. It calls
@code{obstack_alloc_failed_handler} if allocation of memory by
@code{obstack_chunk_alloc} failed.
@end deftypefun
@comment obstack.h
@comment GNU
@deftypefun {void *} obstack_copy0 (struct obstack *@var{obstack-ptr}, void *@var{address}, int @var{size})
Like @code{obstack_copy}, but appends an extra byte containing a null
character. This extra byte is not counted in the argument @var{size}.
@end deftypefun
The @code{obstack_copy0} function is convenient for copying a sequence
of characters into an obstack as a null-terminated string. Here is an
example of its use:
@smallexample
char *
obstack_savestring (char *addr, int size)
@{
return obstack_copy0 (&myobstack, addr, size);
@}
@end smallexample
@noindent
Contrast this with the previous example of @code{savestring} using
@code{malloc} (@pxref{Basic Allocation, , , libc, The GNU C Library Reference Manual}).
@node Freeing Obstack Objects
@subsubsection Freeing Objects in an Obstack
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@cindex freeing (obstacks)
To free an object allocated in an obstack, use the function
@code{obstack_free}. Since the obstack is a stack of objects, freeing
one object automatically frees all other objects allocated more recently
in the same obstack.
@comment obstack.h
@comment GNU
@deftypefun void obstack_free (struct obstack *@var{obstack-ptr}, void *@var{object})
If @var{object} is a null pointer, everything allocated in the obstack
is freed. Otherwise, @var{object} must be the address of an object
allocated in the obstack. Then @var{object} is freed, along with
everything allocated in @var{obstack} since @var{object}.
@end deftypefun
Note that if @var{object} is a null pointer, the result is an
uninitialized obstack. To free all memory in an obstack but leave it
valid for further allocation, call @code{obstack_free} with the address
of the first object allocated on the obstack:
@smallexample
obstack_free (obstack_ptr, first_object_allocated_ptr);
@end smallexample
Recall that the objects in an obstack are grouped into chunks. When all
the objects in a chunk become free, the obstack library automatically
frees the chunk (@pxref{Preparing for Obstacks}). Then other
obstacks, or non-obstack allocation, can reuse the space of the chunk.
@node Obstack Functions
@subsubsection Obstack Functions and Macros
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@cindex macros
The interfaces for using obstacks may be defined either as functions or
as macros, depending on the compiler. The obstack facility works with
all C compilers, including both @w{ISO C} and traditional C, but there are
precautions you must take if you plan to use compilers other than GNU C.
If you are using an old-fashioned @w{non-ISO C} compiler, all the obstack
``functions'' are actually defined only as macros. You can call these
macros like functions, but you cannot use them in any other way (for
example, you cannot take their address).
Calling the macros requires a special precaution: namely, the first
operand (the obstack pointer) may not contain any side effects, because
it may be computed more than once. For example, if you write this:
@smallexample
obstack_alloc (get_obstack (), 4);
@end smallexample
@noindent
you will find that @code{get_obstack} may be called several times.
If you use @code{*obstack_list_ptr++} as the obstack pointer argument,
you will get very strange results since the incrementation may occur
several times.
In @w{ISO C}, each function has both a macro definition and a function
definition. The function definition is used if you take the address of the
function without calling it. An ordinary call uses the macro definition by
default, but you can request the function definition instead by writing the
function name in parentheses, as shown here:
@smallexample
char *x;
void *(*funcp) ();
/* @r{Use the macro}. */
x = (char *) obstack_alloc (obptr, size);
/* @r{Call the function}. */
x = (char *) (obstack_alloc) (obptr, size);
/* @r{Take the address of the function}. */
funcp = obstack_alloc;
@end smallexample
@noindent
This is the same situation that exists in @w{ISO C} for the standard library
functions. @xref{Macro Definitions, , , libc, The GNU C Library Reference Manual}.
@strong{Warning:} When you do use the macros, you must observe the
precaution of avoiding side effects in the first operand, even in @w{ISO C}.
If you use the GNU C compiler, this precaution is not necessary, because
various language extensions in GNU C permit defining the macros so as to
compute each argument only once.
@node Growing Objects
@subsubsection Growing Objects
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@cindex growing objects (in obstacks)
@cindex changing the size of a block (obstacks)
Because memory in obstack chunks is used sequentially, it is possible to
build up an object step by step, adding one or more bytes at a time to the
end of the object. With this technique, you do not need to know how much
data you will put in the object until you come to the end of it. We call
this the technique of @dfn{growing objects}. The special functions
for adding data to the growing object are described in this section.
You don't need to do anything special when you start to grow an object.
Using one of the functions to add data to the object automatically
starts it. However, it is necessary to say explicitly when the object is
finished. This is done with the function @code{obstack_finish}.
The actual address of the object thus built up is not known until the
object is finished. Until then, it always remains possible that you will
add so much data that the object must be copied into a new chunk.
While the obstack is in use for a growing object, you cannot use it for
ordinary allocation of another object. If you try to do so, the space
already added to the growing object will become part of the other object.
@comment obstack.h
@comment GNU
@deftypefun void obstack_blank (struct obstack *@var{obstack-ptr}, int @var{size})
The most basic function for adding to a growing object is
@code{obstack_blank}, which adds space without initializing it.
@end deftypefun
@comment obstack.h
@comment GNU
@deftypefun void obstack_grow (struct obstack *@var{obstack-ptr}, void *@var{data}, int @var{size})
To add a block of initialized space, use @code{obstack_grow}, which is
the growing-object analogue of @code{obstack_copy}. It adds @var{size}
bytes of data to the growing object, copying the contents from
@var{data}.
@end deftypefun
@comment obstack.h
@comment GNU
@deftypefun void obstack_grow0 (struct obstack *@var{obstack-ptr}, void *@var{data}, int @var{size})
This is the growing-object analogue of @code{obstack_copy0}. It adds
@var{size} bytes copied from @var{data}, followed by an additional null
character.
@end deftypefun
@comment obstack.h
@comment GNU
@deftypefun void obstack_1grow (struct obstack *@var{obstack-ptr}, char @var{c})
To add one character at a time, use the function @code{obstack_1grow}.
It adds a single byte containing @var{c} to the growing object.
@end deftypefun
@comment obstack.h
@comment GNU
@deftypefun void obstack_ptr_grow (struct obstack *@var{obstack-ptr}, void *@var{data})
Adding the value of a pointer one can use the function
@code{obstack_ptr_grow}. It adds @code{sizeof (void *)} bytes
containing the value of @var{data}.
@end deftypefun
@comment obstack.h
@comment GNU
@deftypefun void obstack_int_grow (struct obstack *@var{obstack-ptr}, int @var{data})
A single value of type @code{int} can be added by using the
@code{obstack_int_grow} function. It adds @code{sizeof (int)} bytes to
the growing object and initializes them with the value of @var{data}.
@end deftypefun
@comment obstack.h
@comment GNU
@deftypefun {void *} obstack_finish (struct obstack *@var{obstack-ptr})
When you are finished growing the object, use the function
@code{obstack_finish} to close it off and return its final address.
Once you have finished the object, the obstack is available for ordinary
allocation or for growing another object.
This function can return a null pointer under the same conditions as
@code{obstack_alloc} (@pxref{Allocation in an Obstack}).
@end deftypefun
When you build an object by growing it, you will probably need to know
afterward how long it became. You need not keep track of this as you grow
the object, because you can find out the length from the obstack just
before finishing the object with the function @code{obstack_object_size},
declared as follows:
@comment obstack.h
@comment GNU
@deftypefun int obstack_object_size (struct obstack *@var{obstack-ptr})
This function returns the current size of the growing object, in bytes.
Remember to call this function @emph{before} finishing the object.
After it is finished, @code{obstack_object_size} will return zero.
@end deftypefun
If you have started growing an object and wish to cancel it, you should
finish it and then free it, like this:
@smallexample
obstack_free (obstack_ptr, obstack_finish (obstack_ptr));
@end smallexample
@noindent
This has no effect if no object was growing.
@cindex shrinking objects
You can use @code{obstack_blank} with a negative size argument to make
the current object smaller. Just don't try to shrink it beyond zero
length---there's no telling what will happen if you do that.
@node Extra Fast Growing
@subsubsection Extra Fast Growing Objects
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@cindex efficiency and obstacks
The usual functions for growing objects incur overhead for checking
whether there is room for the new growth in the current chunk. If you
are frequently constructing objects in small steps of growth, this
overhead can be significant.
You can reduce the overhead by using special ``fast growth''
functions that grow the object without checking. In order to have a
robust program, you must do the checking yourself. If you do this checking
in the simplest way each time you are about to add data to the object, you
have not saved anything, because that is what the ordinary growth
functions do. But if you can arrange to check less often, or check
more efficiently, then you make the program faster.
The function @code{obstack_room} returns the amount of room available
in the current chunk. It is declared as follows:
@comment obstack.h
@comment GNU
@deftypefun int obstack_room (struct obstack *@var{obstack-ptr})
This returns the number of bytes that can be added safely to the current
growing object (or to an object about to be started) in obstack
@var{obstack} using the fast growth functions.
@end deftypefun
While you know there is room, you can use these fast growth functions
for adding data to a growing object:
@comment obstack.h
@comment GNU
@deftypefun void obstack_1grow_fast (struct obstack *@var{obstack-ptr}, char @var{c})
The function @code{obstack_1grow_fast} adds one byte containing the
character @var{c} to the growing object in obstack @var{obstack-ptr}.
@end deftypefun
@comment obstack.h
@comment GNU
@deftypefun void obstack_ptr_grow_fast (struct obstack *@var{obstack-ptr}, void *@var{data})
The function @code{obstack_ptr_grow_fast} adds @code{sizeof (void *)}
bytes containing the value of @var{data} to the growing object in
obstack @var{obstack-ptr}.
@end deftypefun
@comment obstack.h
@comment GNU
@deftypefun void obstack_int_grow_fast (struct obstack *@var{obstack-ptr}, int @var{data})
The function @code{obstack_int_grow_fast} adds @code{sizeof (int)} bytes
containing the value of @var{data} to the growing object in obstack
@var{obstack-ptr}.
@end deftypefun
@comment obstack.h
@comment GNU
@deftypefun void obstack_blank_fast (struct obstack *@var{obstack-ptr}, int @var{size})
The function @code{obstack_blank_fast} adds @var{size} bytes to the
growing object in obstack @var{obstack-ptr} without initializing them.
@end deftypefun
When you check for space using @code{obstack_room} and there is not
enough room for what you want to add, the fast growth functions
are not safe. In this case, simply use the corresponding ordinary
growth function instead. Very soon this will copy the object to a
new chunk; then there will be lots of room available again.
So, each time you use an ordinary growth function, check afterward for
sufficient space using @code{obstack_room}. Once the object is copied
to a new chunk, there will be plenty of space again, so the program will
start using the fast growth functions again.
Here is an example:
@smallexample
@group
void
add_string (struct obstack *obstack, const char *ptr, int len)
@{
while (len > 0)
@{
int room = obstack_room (obstack);
if (room == 0)
@{
/* @r{Not enough room. Add one character slowly,}
@r{which may copy to a new chunk and make room.} */
obstack_1grow (obstack, *ptr++);
len--;
@}
else
@{
if (room > len)
room = len;
/* @r{Add fast as much as we have room for.} */
len -= room;
while (room-- > 0)
obstack_1grow_fast (obstack, *ptr++);
@}
@}
@}
@end group
@end smallexample
@node Status of an Obstack
@subsubsection Status of an Obstack
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@cindex obstack status
@cindex status of obstack
Here are functions that provide information on the current status of
allocation in an obstack. You can use them to learn about an object while
still growing it.
@comment obstack.h
@comment GNU
@deftypefun {void *} obstack_base (struct obstack *@var{obstack-ptr})
This function returns the tentative address of the beginning of the
currently growing object in @var{obstack-ptr}. If you finish the object
immediately, it will have that address. If you make it larger first, it
may outgrow the current chunk---then its address will change!
If no object is growing, this value says where the next object you
allocate will start (once again assuming it fits in the current
chunk).
@end deftypefun
@comment obstack.h
@comment GNU
@deftypefun {void *} obstack_next_free (struct obstack *@var{obstack-ptr})
This function returns the address of the first free byte in the current
chunk of obstack @var{obstack-ptr}. This is the end of the currently
growing object. If no object is growing, @code{obstack_next_free}
returns the same value as @code{obstack_base}.
@end deftypefun
@comment obstack.h
@comment GNU
@deftypefun int obstack_object_size (struct obstack *@var{obstack-ptr})
This function returns the size in bytes of the currently growing object.
This is equivalent to
@smallexample
obstack_next_free (@var{obstack-ptr}) - obstack_base (@var{obstack-ptr})
@end smallexample
@end deftypefun
@node Obstacks Data Alignment
@subsubsection Alignment of Data in Obstacks
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@cindex alignment (in obstacks)
Each obstack has an @dfn{alignment boundary}; each object allocated in
the obstack automatically starts on an address that is a multiple of the
specified boundary. By default, this boundary is aligned so that
the object can hold any type of data.
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To access an obstack's alignment boundary, use the macro
@code{obstack_alignment_mask}, whose function prototype looks like
this:
@comment obstack.h
@comment GNU
@deftypefn Macro int obstack_alignment_mask (struct obstack *@var{obstack-ptr})
The value is a bit mask; a bit that is 1 indicates that the corresponding
bit in the address of an object should be 0. The mask value should be one
less than a power of 2; the effect is that all object addresses are
multiples of that power of 2. The default value of the mask is a value
that allows aligned objects to hold any type of data: for example, if
its value is 3, any type of data can be stored at locations whose
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addresses are multiples of 4. A mask value of 0 means an object can start
on any multiple of 1 (that is, no alignment is required).
The expansion of the macro @code{obstack_alignment_mask} is an lvalue,
so you can alter the mask by assignment. For example, this statement:
@smallexample
obstack_alignment_mask (obstack_ptr) = 0;
@end smallexample
@noindent
has the effect of turning off alignment processing in the specified obstack.
@end deftypefn
Note that a change in alignment mask does not take effect until
@emph{after} the next time an object is allocated or finished in the
obstack. If you are not growing an object, you can make the new
alignment mask take effect immediately by calling @code{obstack_finish}.
This will finish a zero-length object and then do proper alignment for
the next object.
@node Obstack Chunks
@subsubsection Obstack Chunks
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@cindex efficiency of chunks
@cindex chunks
Obstacks work by allocating space for themselves in large chunks, and
then parceling out space in the chunks to satisfy your requests. Chunks
are normally 4096 bytes long unless you specify a different chunk size.
The chunk size includes 8 bytes of overhead that are not actually used
for storing objects. Regardless of the specified size, longer chunks
will be allocated when necessary for long objects.
The obstack library allocates chunks by calling the function
@code{obstack_chunk_alloc}, which you must define. When a chunk is no
longer needed because you have freed all the objects in it, the obstack
library frees the chunk by calling @code{obstack_chunk_free}, which you
must also define.
These two must be defined (as macros) or declared (as functions) in each
source file that uses @code{obstack_init} (@pxref{Creating Obstacks}).
Most often they are defined as macros like this:
@smallexample
#define obstack_chunk_alloc malloc
#define obstack_chunk_free free
@end smallexample
Note that these are simple macros (no arguments). Macro definitions with
arguments will not work! It is necessary that @code{obstack_chunk_alloc}
or @code{obstack_chunk_free}, alone, expand into a function name if it is
not itself a function name.
If you allocate chunks with @code{malloc}, the chunk size should be a
power of 2. The default chunk size, 4096, was chosen because it is long
enough to satisfy many typical requests on the obstack yet short enough
not to waste too much memory in the portion of the last chunk not yet used.
@comment obstack.h
@comment GNU
@deftypefn Macro int obstack_chunk_size (struct obstack *@var{obstack-ptr})
This returns the chunk size of the given obstack.
@end deftypefn
Since this macro expands to an lvalue, you can specify a new chunk size by
assigning it a new value. Doing so does not affect the chunks already
allocated, but will change the size of chunks allocated for that particular
obstack in the future. It is unlikely to be useful to make the chunk size
smaller, but making it larger might improve efficiency if you are
allocating many objects whose size is comparable to the chunk size. Here
is how to do so cleanly:
@smallexample
if (obstack_chunk_size (obstack_ptr) < @var{new-chunk-size})
obstack_chunk_size (obstack_ptr) = @var{new-chunk-size};
@end smallexample
@node Summary of Obstacks
@subsubsection Summary of Obstack Functions
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Here is a summary of all the functions associated with obstacks. Each
takes the address of an obstack (@code{struct obstack *}) as its first
argument.
@table @code
@item void obstack_init (struct obstack *@var{obstack-ptr})
Initialize use of an obstack. @xref{Creating Obstacks}.
@item void *obstack_alloc (struct obstack *@var{obstack-ptr}, int @var{size})
Allocate an object of @var{size} uninitialized bytes.
@xref{Allocation in an Obstack}.
@item void *obstack_copy (struct obstack *@var{obstack-ptr}, void *@var{address}, int @var{size})
Allocate an object of @var{size} bytes, with contents copied from
@var{address}. @xref{Allocation in an Obstack}.
@item void *obstack_copy0 (struct obstack *@var{obstack-ptr}, void *@var{address}, int @var{size})
Allocate an object of @var{size}+1 bytes, with @var{size} of them copied
from @var{address}, followed by a null character at the end.
@xref{Allocation in an Obstack}.
@item void obstack_free (struct obstack *@var{obstack-ptr}, void *@var{object})
Free @var{object} (and everything allocated in the specified obstack
more recently than @var{object}). @xref{Freeing Obstack Objects}.
@item void obstack_blank (struct obstack *@var{obstack-ptr}, int @var{size})
Add @var{size} uninitialized bytes to a growing object.
@xref{Growing Objects}.
@item void obstack_grow (struct obstack *@var{obstack-ptr}, void *@var{address}, int @var{size})
Add @var{size} bytes, copied from @var{address}, to a growing object.
@xref{Growing Objects}.
@item void obstack_grow0 (struct obstack *@var{obstack-ptr}, void *@var{address}, int @var{size})
Add @var{size} bytes, copied from @var{address}, to a growing object,
and then add another byte containing a null character. @xref{Growing
Objects}.
@item void obstack_1grow (struct obstack *@var{obstack-ptr}, char @var{data-char})
Add one byte containing @var{data-char} to a growing object.
@xref{Growing Objects}.
@item void *obstack_finish (struct obstack *@var{obstack-ptr})
Finalize the object that is growing and return its permanent address.
@xref{Growing Objects}.
@item int obstack_object_size (struct obstack *@var{obstack-ptr})
Get the current size of the currently growing object. @xref{Growing
Objects}.
@item void obstack_blank_fast (struct obstack *@var{obstack-ptr}, int @var{size})
Add @var{size} uninitialized bytes to a growing object without checking
that there is enough room. @xref{Extra Fast Growing}.
@item void obstack_1grow_fast (struct obstack *@var{obstack-ptr}, char @var{data-char})
Add one byte containing @var{data-char} to a growing object without
checking that there is enough room. @xref{Extra Fast Growing}.
@item int obstack_room (struct obstack *@var{obstack-ptr})
Get the amount of room now available for growing the current object.
@xref{Extra Fast Growing}.
@item int obstack_alignment_mask (struct obstack *@var{obstack-ptr})
The mask used for aligning the beginning of an object. This is an
lvalue. @xref{Obstacks Data Alignment}.
@item int obstack_chunk_size (struct obstack *@var{obstack-ptr})
The size for allocating chunks. This is an lvalue. @xref{Obstack Chunks}.
@item void *obstack_base (struct obstack *@var{obstack-ptr})
Tentative starting address of the currently growing object.
@xref{Status of an Obstack}.
@item void *obstack_next_free (struct obstack *@var{obstack-ptr})
Address just after the end of the currently growing object.
@xref{Status of an Obstack}.
@end table