mirror of
https://github.com/openssl/openssl.git
synced 2024-12-21 06:09:35 +08:00
3c2bdd7df9
Reviewed-by: Tomas Mraz <tomas@openssl.org> (Merged from https://github.com/openssl/openssl/pull/14801)
220 lines
5.9 KiB
C
220 lines
5.9 KiB
C
/*
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* Copyright 2019-2021 The OpenSSL Project Authors. All Rights Reserved.
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* Copyright (c) 2019, Oracle and/or its affiliates. All rights reserved.
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*
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* Licensed under the Apache License 2.0 (the "License"). You may not use
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* this file except in compliance with the License. You can obtain a copy
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* in the file LICENSE in the source distribution or at
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* https://www.openssl.org/source/license.html
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*/
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#include <openssl/crypto.h>
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#include <openssl/bn.h>
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#include "crypto/sparse_array.h"
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/*
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* How many bits are used to index each level in the tree structure?
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* This setting determines the number of pointers stored in each node of the
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* tree used to represent the sparse array. Having more pointers reduces the
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* depth of the tree but potentially wastes more memory. That is, this is a
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* direct space versus time tradeoff.
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*
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* The large memory model uses twelve bits which means that the are 4096
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* pointers in each tree node. This is more than sufficient to hold the
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* largest defined NID (as of Feb 2019). This means that using a NID to
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* index a sparse array becomes a constant time single array look up.
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*
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* The small memory model uses four bits which means the tree nodes contain
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* sixteen pointers. This reduces the amount of unused space significantly
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* at a cost in time.
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*
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* The library builder is also permitted to define other sizes in the closed
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* interval [2, sizeof(ossl_uintmax_t) * 8].
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*/
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#ifndef OPENSSL_SA_BLOCK_BITS
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# ifdef OPENSSL_SMALL_FOOTPRINT
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# define OPENSSL_SA_BLOCK_BITS 4
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# else
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# define OPENSSL_SA_BLOCK_BITS 12
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# endif
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#elif OPENSSL_SA_BLOCK_BITS < 2 || OPENSSL_SA_BLOCK_BITS > (BN_BITS2 - 1)
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# error OPENSSL_SA_BLOCK_BITS is out of range
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#endif
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/*
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* From the number of bits, work out:
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* the number of pointers in a tree node;
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* a bit mask to quickly extract an index and
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* the maximum depth of the tree structure.
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*/
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#define SA_BLOCK_MAX (1 << OPENSSL_SA_BLOCK_BITS)
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#define SA_BLOCK_MASK (SA_BLOCK_MAX - 1)
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#define SA_BLOCK_MAX_LEVELS (((int)sizeof(ossl_uintmax_t) * 8 \
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+ OPENSSL_SA_BLOCK_BITS - 1) \
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/ OPENSSL_SA_BLOCK_BITS)
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struct sparse_array_st {
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int levels;
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ossl_uintmax_t top;
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size_t nelem;
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void **nodes;
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};
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OPENSSL_SA *ossl_sa_new(void)
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{
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OPENSSL_SA *res = OPENSSL_zalloc(sizeof(*res));
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return res;
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}
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static void sa_doall(const OPENSSL_SA *sa, void (*node)(void **),
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void (*leaf)(ossl_uintmax_t, void *, void *), void *arg)
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{
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int i[SA_BLOCK_MAX_LEVELS];
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void *nodes[SA_BLOCK_MAX_LEVELS];
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ossl_uintmax_t idx = 0;
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int l = 0;
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i[0] = 0;
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nodes[0] = sa->nodes;
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while (l >= 0) {
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const int n = i[l];
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void ** const p = nodes[l];
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if (n >= SA_BLOCK_MAX) {
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if (p != NULL && node != NULL)
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(*node)(p);
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l--;
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idx >>= OPENSSL_SA_BLOCK_BITS;
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} else {
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i[l] = n + 1;
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if (p != NULL && p[n] != NULL) {
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idx = (idx & ~SA_BLOCK_MASK) | n;
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if (l < sa->levels - 1) {
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i[++l] = 0;
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nodes[l] = p[n];
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idx <<= OPENSSL_SA_BLOCK_BITS;
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} else if (leaf != NULL) {
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(*leaf)(idx, p[n], arg);
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}
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}
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}
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}
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}
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static void sa_free_node(void **p)
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{
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OPENSSL_free(p);
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}
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static void sa_free_leaf(ossl_uintmax_t n, void *p, void *arg)
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{
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OPENSSL_free(p);
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}
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void ossl_sa_free(OPENSSL_SA *sa)
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{
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sa_doall(sa, &sa_free_node, NULL, NULL);
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OPENSSL_free(sa);
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}
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void ossl_sa_free_leaves(OPENSSL_SA *sa)
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{
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sa_doall(sa, &sa_free_node, &sa_free_leaf, NULL);
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OPENSSL_free(sa);
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}
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/* Wrap this in a structure to avoid compiler warnings */
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struct trampoline_st {
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void (*func)(ossl_uintmax_t, void *);
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};
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static void trampoline(ossl_uintmax_t n, void *l, void *arg)
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{
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((const struct trampoline_st *)arg)->func(n, l);
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}
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void ossl_sa_doall(const OPENSSL_SA *sa, void (*leaf)(ossl_uintmax_t, void *))
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{
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struct trampoline_st tramp;
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tramp.func = leaf;
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if (sa != NULL)
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sa_doall(sa, NULL, &trampoline, &tramp);
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}
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void ossl_sa_doall_arg(const OPENSSL_SA *sa,
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void (*leaf)(ossl_uintmax_t, void *, void *),
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void *arg)
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{
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if (sa != NULL)
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sa_doall(sa, NULL, leaf, arg);
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}
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size_t ossl_sa_num(const OPENSSL_SA *sa)
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{
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return sa == NULL ? 0 : sa->nelem;
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}
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void *ossl_sa_get(const OPENSSL_SA *sa, ossl_uintmax_t n)
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{
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int level;
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void **p, *r = NULL;
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if (sa == NULL || sa->nelem == 0)
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return NULL;
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if (n <= sa->top) {
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p = sa->nodes;
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for (level = sa->levels - 1; p != NULL && level > 0; level--)
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p = (void **)p[(n >> (OPENSSL_SA_BLOCK_BITS * level))
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& SA_BLOCK_MASK];
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r = p == NULL ? NULL : p[n & SA_BLOCK_MASK];
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}
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return r;
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}
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static ossl_inline void **alloc_node(void)
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{
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return OPENSSL_zalloc(SA_BLOCK_MAX * sizeof(void *));
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}
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int ossl_sa_set(OPENSSL_SA *sa, ossl_uintmax_t posn, void *val)
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{
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int i, level = 1;
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ossl_uintmax_t n = posn;
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void **p;
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if (sa == NULL)
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return 0;
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for (level = 1; level < SA_BLOCK_MAX_LEVELS; level++)
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if ((n >>= OPENSSL_SA_BLOCK_BITS) == 0)
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break;
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for (;sa->levels < level; sa->levels++) {
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p = alloc_node();
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if (p == NULL)
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return 0;
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p[0] = sa->nodes;
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sa->nodes = p;
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}
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if (sa->top < posn)
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sa->top = posn;
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p = sa->nodes;
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for (level = sa->levels - 1; level > 0; level--) {
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i = (posn >> (OPENSSL_SA_BLOCK_BITS * level)) & SA_BLOCK_MASK;
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if (p[i] == NULL && (p[i] = alloc_node()) == NULL)
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return 0;
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p = p[i];
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}
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p += posn & SA_BLOCK_MASK;
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if (val == NULL && *p != NULL)
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sa->nelem--;
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else if (val != NULL && *p == NULL)
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sa->nelem++;
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*p = val;
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return 1;
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}
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