Retro68/gcc/libobjc/sarray.c

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2012-03-27 23:13:14 +00:00
/* Sparse Arrays for Objective C dispatch tables
Copyright (C) 1993-2017 Free Software Foundation, Inc.
2012-03-27 23:13:14 +00:00
This file is part of GCC.
GCC is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3, or (at your option)
any later version.
GCC is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
Under Section 7 of GPL version 3, you are granted additional
permissions described in the GCC Runtime Library Exception, version
3.1, as published by the Free Software Foundation.
You should have received a copy of the GNU General Public License and
a copy of the GCC Runtime Library Exception along with this program;
see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
<http://www.gnu.org/licenses/>. */
#include "objc-private/common.h"
#include "objc-private/sarray.h"
#include "objc/runtime.h" /* For objc_malloc */
#include "objc/thr.h" /* For objc_mutex_lock */
#include "objc-private/module-abi-8.h"
#include "objc-private/runtime.h"
#include <stdio.h>
#include <string.h> /* For memset */
#include <assert.h> /* For assert */
int nbuckets = 0; /* !T:MUTEX */
int nindices = 0; /* !T:MUTEX */
int narrays = 0; /* !T:MUTEX */
int idxsize = 0; /* !T:MUTEX */
static void *first_free_data = NULL; /* !T:MUTEX */
#ifdef OBJC_SPARSE2
const char *__objc_sparse2_id = "2 level sparse indices";
#endif
#ifdef OBJC_SPARSE3
const char *__objc_sparse3_id = "3 level sparse indices";
#endif
/* This function removes any structures left over from free operations
that were not safe in a multi-threaded environment. */
void
sarray_remove_garbage (void)
{
void **vp;
void *np;
objc_mutex_lock (__objc_runtime_mutex);
vp = first_free_data;
first_free_data = NULL;
while (vp)
{
np = *vp;
objc_free (vp);
vp = np;
}
objc_mutex_unlock (__objc_runtime_mutex);
}
/* Free a block of dynamically allocated memory. If we are in
multi-threaded mode, it is ok to free it. If not, we add it to the
garbage heap to be freed later. */
static void
sarray_free_garbage (void *vp)
{
objc_mutex_lock (__objc_runtime_mutex);
if (__objc_runtime_threads_alive == 1)
{
objc_free (vp);
if (first_free_data)
sarray_remove_garbage ();
}
else
{
*(void **)vp = first_free_data;
first_free_data = vp;
}
objc_mutex_unlock (__objc_runtime_mutex);
}
/* sarray_at_put copies data in such a way as to be thread reader
safe. */
void
sarray_at_put (struct sarray *array, sidx index, void *element)
{
#ifdef OBJC_SPARSE3
struct sindex **the_index;
struct sindex *new_index;
#endif
struct sbucket **the_bucket;
struct sbucket *new_bucket;
#ifdef OBJC_SPARSE3
size_t ioffset;
#endif
size_t boffset;
size_t eoffset;
#ifdef PRECOMPUTE_SELECTORS
union sofftype xx;
xx.idx = index;
#ifdef OBJC_SPARSE3
ioffset = xx.off.ioffset;
#endif
boffset = xx.off.boffset;
eoffset = xx.off.eoffset;
#else /* not PRECOMPUTE_SELECTORS */
#ifdef OBJC_SPARSE3
ioffset = index/INDEX_CAPACITY;
boffset = (index/BUCKET_SIZE)%INDEX_SIZE;
eoffset = index%BUCKET_SIZE;
#else
boffset = index/BUCKET_SIZE;
eoffset = index%BUCKET_SIZE;
#endif
#endif /* not PRECOMPUTE_SELECTORS */
assert (soffset_decode (index) < array->capacity); /* Range check */
#ifdef OBJC_SPARSE3
the_index = &(array->indices[ioffset]);
the_bucket = &((*the_index)->buckets[boffset]);
#else
the_bucket = &(array->buckets[boffset]);
#endif
if ((*the_bucket)->elems[eoffset] == element)
return; /* Great! we just avoided a lazy copy. */
#ifdef OBJC_SPARSE3
/* First, perform lazy copy/allocation of index if needed. */
if ((*the_index) == array->empty_index)
{
/* The index was previously empty, allocate a new. */
new_index = (struct sindex *) objc_malloc (sizeof (struct sindex));
memcpy (new_index, array->empty_index, sizeof (struct sindex));
new_index->version.version = array->version.version;
*the_index = new_index; /* Prepared for install. */
the_bucket = &((*the_index)->buckets[boffset]);
nindices += 1;
}
else if ((*the_index)->version.version != array->version.version)
{
/* This index must be lazy copied. */
struct sindex *old_index = *the_index;
new_index = (struct sindex *) objc_malloc (sizeof (struct sindex));
memcpy (new_index, old_index, sizeof (struct sindex));
new_index->version.version = array->version.version;
*the_index = new_index; /* Prepared for install. */
the_bucket = &((*the_index)->buckets[boffset]);
nindices += 1;
}
#endif /* OBJC_SPARSE3 */
/* Next, perform lazy allocation/copy of the bucket if needed. */
if ((*the_bucket) == array->empty_bucket)
{
/* The bucket was previously empty (or something like that),
allocate a new. This is the effect of `lazy' allocation. */
new_bucket = (struct sbucket *) objc_malloc (sizeof (struct sbucket));
memcpy ((void *) new_bucket, (const void *) array->empty_bucket,
sizeof (struct sbucket));
new_bucket->version.version = array->version.version;
*the_bucket = new_bucket; /* Prepared for install. */
nbuckets += 1;
}
else if ((*the_bucket)->version.version != array->version.version)
{
/* Perform lazy copy. */
struct sbucket *old_bucket = *the_bucket;
new_bucket = (struct sbucket *) objc_malloc (sizeof (struct sbucket));
memcpy (new_bucket, old_bucket, sizeof (struct sbucket));
new_bucket->version.version = array->version.version;
*the_bucket = new_bucket; /* Prepared for install. */
nbuckets += 1;
}
(*the_bucket)->elems[eoffset] = element;
}
void
sarray_at_put_safe (struct sarray *array, sidx index, void *element)
{
if (soffset_decode (index) >= array->capacity)
sarray_realloc (array, soffset_decode (index) + 1);
sarray_at_put (array, index, element);
}
struct sarray *
sarray_new (int size, void *default_element)
{
struct sarray *arr;
#ifdef OBJC_SPARSE3
size_t num_indices = ((size - 1)/(INDEX_CAPACITY)) + 1;
struct sindex **new_indices;
#else /* OBJC_SPARSE2 */
size_t num_indices = ((size - 1)/BUCKET_SIZE) + 1;
struct sbucket **new_buckets;
#endif
size_t counter;
assert (size > 0);
/* Allocate core array. */
arr = (struct sarray *) objc_malloc (sizeof (struct sarray));
arr->version.version = 0;
/* Initialize members. */
#ifdef OBJC_SPARSE3
arr->capacity = num_indices*INDEX_CAPACITY;
new_indices = (struct sindex **)
objc_malloc (sizeof (struct sindex *) * num_indices);
arr->empty_index = (struct sindex *) objc_malloc (sizeof (struct sindex));
arr->empty_index->version.version = 0;
narrays += 1;
idxsize += num_indices;
nindices += 1;
#else /* OBJC_SPARSE2 */
arr->capacity = num_indices*BUCKET_SIZE;
new_buckets = (struct sbucket **)
objc_malloc (sizeof (struct sbucket *) * num_indices);
narrays += 1;
idxsize += num_indices;
#endif
arr->empty_bucket = (struct sbucket *) objc_malloc (sizeof (struct sbucket));
arr->empty_bucket->version.version = 0;
nbuckets += 1;
arr->ref_count = 1;
arr->is_copy_of = (struct sarray *) 0;
for (counter = 0; counter < BUCKET_SIZE; counter++)
arr->empty_bucket->elems[counter] = default_element;
#ifdef OBJC_SPARSE3
for (counter = 0; counter < INDEX_SIZE; counter++)
arr->empty_index->buckets[counter] = arr->empty_bucket;
for (counter = 0; counter < num_indices; counter++)
new_indices[counter] = arr->empty_index;
#else /* OBJC_SPARSE2 */
for (counter = 0; counter < num_indices; counter++)
new_buckets[counter] = arr->empty_bucket;
#endif
#ifdef OBJC_SPARSE3
arr->indices = new_indices;
#else /* OBJC_SPARSE2 */
arr->buckets = new_buckets;
#endif
return arr;
}
/* Reallocate the sparse array to hold `newsize' entries Note: We
really allocate and then free. We have to do this to ensure that
any concurrent readers notice the update. */
void
sarray_realloc (struct sarray *array, int newsize)
{
#ifdef OBJC_SPARSE3
size_t old_max_index = (array->capacity - 1)/INDEX_CAPACITY;
size_t new_max_index = ((newsize - 1)/INDEX_CAPACITY);
size_t rounded_size = (new_max_index + 1) * INDEX_CAPACITY;
struct sindex **new_indices;
struct sindex **old_indices;
#else /* OBJC_SPARSE2 */
size_t old_max_index = (array->capacity - 1)/BUCKET_SIZE;
size_t new_max_index = ((newsize - 1)/BUCKET_SIZE);
size_t rounded_size = (new_max_index + 1) * BUCKET_SIZE;
struct sbucket **new_buckets;
struct sbucket **old_buckets;
#endif
size_t counter;
assert (newsize > 0);
/* The size is the same, just ignore the request. */
if (rounded_size <= array->capacity)
return;
assert (array->ref_count == 1); /* stop if lazy copied... */
/* We are asked to extend the array -- allocate new bucket table,
and insert empty_bucket in newly allocated places. */
if (rounded_size > array->capacity)
{
#ifdef OBJC_SPARSE3
new_max_index += 4;
rounded_size = (new_max_index + 1) * INDEX_CAPACITY;
#else /* OBJC_SPARSE2 */
new_max_index += 4;
rounded_size = (new_max_index + 1) * BUCKET_SIZE;
#endif
/* Update capacity. */
array->capacity = rounded_size;
#ifdef OBJC_SPARSE3
/* Alloc to force re-read by any concurrent readers. */
old_indices = array->indices;
new_indices = (struct sindex **)
objc_malloc ((new_max_index + 1) * sizeof (struct sindex *));
#else /* OBJC_SPARSE2 */
old_buckets = array->buckets;
new_buckets = (struct sbucket **)
objc_malloc ((new_max_index + 1) * sizeof (struct sbucket *));
#endif
/* Copy buckets below old_max_index (they are still valid). */
for (counter = 0; counter <= old_max_index; counter++ )
{
#ifdef OBJC_SPARSE3
new_indices[counter] = old_indices[counter];
#else /* OBJC_SPARSE2 */
new_buckets[counter] = old_buckets[counter];
#endif
}
#ifdef OBJC_SPARSE3
/* Reset entries above old_max_index to empty_bucket. */
for (counter = old_max_index + 1; counter <= new_max_index; counter++)
new_indices[counter] = array->empty_index;
#else /* OBJC_SPARSE2 */
/* Reset entries above old_max_index to empty_bucket. */
for (counter = old_max_index + 1; counter <= new_max_index; counter++)
new_buckets[counter] = array->empty_bucket;
#endif
#ifdef OBJC_SPARSE3
/* Install the new indices. */
array->indices = new_indices;
#else /* OBJC_SPARSE2 */
array->buckets = new_buckets;
#endif
#ifdef OBJC_SPARSE3
/* Free the old indices. */
sarray_free_garbage (old_indices);
#else /* OBJC_SPARSE2 */
sarray_free_garbage (old_buckets);
#endif
idxsize += (new_max_index-old_max_index);
return;
}
}
/* Free a sparse array allocated with sarray_new */
void
sarray_free (struct sarray *array) {
#ifdef OBJC_SPARSE3
size_t old_max_index = (array->capacity - 1)/INDEX_CAPACITY;
struct sindex **old_indices;
#else
size_t old_max_index = (array->capacity - 1)/BUCKET_SIZE;
struct sbucket **old_buckets;
#endif
size_t counter = 0;
assert (array->ref_count != 0); /* Freed multiple times!!! */
if (--(array->ref_count) != 0) /* There exists copies of me */
return;
#ifdef OBJC_SPARSE3
old_indices = array->indices;
#else
old_buckets = array->buckets;
#endif
/* Free all entries that do not point to empty_bucket. */
for (counter = 0; counter <= old_max_index; counter++ )
{
#ifdef OBJC_SPARSE3
struct sindex *idx = old_indices[counter];
if ((idx != array->empty_index)
&& (idx->version.version == array->version.version))
{
int c2;
for (c2 = 0; c2 < INDEX_SIZE; c2++)
{
struct sbucket *bkt = idx->buckets[c2];
if ((bkt != array->empty_bucket)
&& (bkt->version.version == array->version.version))
{
sarray_free_garbage (bkt);
nbuckets -= 1;
}
}
sarray_free_garbage (idx);
nindices -= 1;
}
#else /* OBJC_SPARSE2 */
struct sbucket *bkt = old_buckets[counter];
if ((bkt != array->empty_bucket)
&& (bkt->version.version == array->version.version))
{
sarray_free_garbage (bkt);
nbuckets -= 1;
}
#endif
}
#ifdef OBJC_SPARSE3
/* Free empty_index. */
if (array->empty_index->version.version == array->version.version)
{
sarray_free_garbage (array->empty_index);
nindices -= 1;
}
#endif
/* Free empty_bucket. */
if (array->empty_bucket->version.version == array->version.version)
{
sarray_free_garbage (array->empty_bucket);
nbuckets -= 1;
}
idxsize -= (old_max_index + 1);
narrays -= 1;
#ifdef OBJC_SPARSE3
/* Free bucket table. */
sarray_free_garbage (array->indices);
#else
/* Free bucket table. */
sarray_free_garbage (array->buckets);
#endif
/* If this is a copy of another array, we free it (which might just
decrement its reference count so it will be freed when no longer
in use). */
if (array->is_copy_of)
sarray_free (array->is_copy_of);
/* Free array. */
sarray_free_garbage (array);
}
/* This is a lazy copy. Only the core of the structure is actually
copied. */
struct sarray *
sarray_lazy_copy (struct sarray *oarr)
{
struct sarray *arr;
#ifdef OBJC_SPARSE3
size_t num_indices = ((oarr->capacity - 1)/INDEX_CAPACITY) + 1;
struct sindex **new_indices;
#else /* OBJC_SPARSE2 */
size_t num_indices = ((oarr->capacity - 1)/BUCKET_SIZE) + 1;
struct sbucket **new_buckets;
#endif
/* Allocate core array. */
arr = (struct sarray *) objc_malloc (sizeof (struct sarray)); /* !!! */
arr->version.version = oarr->version.version + 1;
#ifdef OBJC_SPARSE3
arr->empty_index = oarr->empty_index;
#endif
arr->empty_bucket = oarr->empty_bucket;
arr->ref_count = 1;
oarr->ref_count += 1;
arr->is_copy_of = oarr;
arr->capacity = oarr->capacity;
#ifdef OBJC_SPARSE3
/* Copy bucket table. */
new_indices = (struct sindex **)
objc_malloc (sizeof (struct sindex *) * num_indices);
memcpy (new_indices, oarr->indices, sizeof (struct sindex *) * num_indices);
arr->indices = new_indices;
#else
/* Copy bucket table. */
new_buckets = (struct sbucket **)
objc_malloc (sizeof (struct sbucket *) * num_indices);
memcpy (new_buckets, oarr->buckets, sizeof (struct sbucket *) * num_indices);
arr->buckets = new_buckets;
#endif
idxsize += num_indices;
narrays += 1;
return arr;
}