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/*
* Copyright 2021-2022 The OpenSSL Project Authors. All Rights Reserved.
*
* Licensed under the Apache License 2.0 (the "License"). You may not use
* this file except in compliance with the License. You can obtain a copy
* in the file LICENSE in the source distribution or at
* https://www.openssl.org/source/license.html
*/
#include <string.h>
#include <openssl/params.h>
#include <openssl/param_build.h>
#include "internal/param_build_set.h"
#define OSSL_PARAM_ALLOCATED_END 127
#define OSSL_PARAM_MERGE_LIST_MAX 128
#define OSSL_PARAM_BUF_PUBLIC 0
#define OSSL_PARAM_BUF_SECURE 1
#define OSSL_PARAM_BUF_MAX (OSSL_PARAM_BUF_SECURE + 1)
typedef struct {
OSSL_PARAM_ALIGNED_BLOCK *alloc; /* The allocated buffer */
OSSL_PARAM_ALIGNED_BLOCK *cur; /* Current position in the allocated buf */
size_t blocks; /* Number of aligned blocks */
size_t alloc_sz; /* The size of the allocated buffer (in bytes) */
} OSSL_PARAM_BUF;
size_t ossl_param_bytes_to_blocks(size_t bytes)
{
return (bytes + OSSL_PARAM_ALIGN_SIZE - 1) / OSSL_PARAM_ALIGN_SIZE;
}
static int ossl_param_buf_alloc(OSSL_PARAM_BUF *out, size_t extra_blocks,
int is_secure)
{
size_t sz = OSSL_PARAM_ALIGN_SIZE * (extra_blocks + out->blocks);
out->alloc = is_secure ? OPENSSL_secure_zalloc(sz) : OPENSSL_zalloc(sz);
if (out->alloc == NULL) {
ERR_raise(ERR_LIB_CRYPTO, is_secure ? CRYPTO_R_SECURE_MALLOC_FAILURE
: ERR_R_MALLOC_FAILURE);
return 0;
}
out->alloc_sz = sz;
out->cur = out->alloc + extra_blocks;
return 1;
}
void ossl_param_set_secure_block(OSSL_PARAM *last, void *secure_buffer,
size_t secure_buffer_sz)
{
last->key = NULL;
last->data_size = secure_buffer_sz;
last->data = secure_buffer;
last->data_type = OSSL_PARAM_ALLOCATED_END;
}
static OSSL_PARAM *ossl_param_dup(const OSSL_PARAM *src, OSSL_PARAM *dst,
OSSL_PARAM_BUF buf[OSSL_PARAM_BUF_MAX],
int *param_count)
{
const OSSL_PARAM *in;
int has_dst = (dst != NULL);
int is_secure;
size_t param_sz, blks;
for (in = src; in->key != NULL; in++) {
is_secure = CRYPTO_secure_allocated(in->data);
if (has_dst) {
*dst = *in;
dst->data = buf[is_secure].cur;
}
if (in->data_type == OSSL_PARAM_OCTET_PTR
|| in->data_type == OSSL_PARAM_UTF8_PTR) {
param_sz = sizeof(in->data);
if (has_dst)
*((const void **)dst->data) = *(const void **)in->data;
} else {
param_sz = in->data_size;
if (has_dst)
memcpy(dst->data, in->data, param_sz);
}
if (in->data_type == OSSL_PARAM_UTF8_STRING)
param_sz++; /* NULL terminator */
blks = ossl_param_bytes_to_blocks(param_sz);
if (has_dst) {
dst++;
buf[is_secure].cur += blks;
} else {
buf[is_secure].blocks += blks;
}
if (param_count != NULL)
++*param_count;
}
return dst;
}
OSSL_PARAM *OSSL_PARAM_dup(const OSSL_PARAM *src)
{
size_t param_blocks;
OSSL_PARAM_BUF buf[OSSL_PARAM_BUF_MAX];
OSSL_PARAM *last, *dst;
int param_count = 1; /* Include terminator in the count */
if (src == NULL)
return NULL;
memset(buf, 0, sizeof(buf));
/* First Pass: get the param_count and block sizes required */
(void)ossl_param_dup(src, NULL, buf, ¶m_count);
param_blocks = ossl_param_bytes_to_blocks(param_count * sizeof(*src));
/*
* The allocated buffer consists of an array of OSSL_PARAM followed by
* aligned data bytes that the array elements will point to.
*/
if (!ossl_param_buf_alloc(&buf[OSSL_PARAM_BUF_PUBLIC], param_blocks, 0))
return NULL;
/* Allocate a secure memory buffer if required */
if (buf[OSSL_PARAM_BUF_SECURE].blocks > 0
&& !ossl_param_buf_alloc(&buf[OSSL_PARAM_BUF_SECURE], 0, 1)) {
OPENSSL_free(buf[OSSL_PARAM_BUF_PUBLIC].alloc);
return NULL;
}
dst = (OSSL_PARAM *)buf[OSSL_PARAM_BUF_PUBLIC].alloc;
last = ossl_param_dup(src, dst, buf, NULL);
/* Store the allocated secure memory buffer in the last param block */
ossl_param_set_secure_block(last, buf[OSSL_PARAM_BUF_SECURE].alloc,
buf[OSSL_PARAM_BUF_SECURE].alloc_sz);
return dst;
}
static int compare_params(const void *left, const void *right)
{
const OSSL_PARAM *l = *(const OSSL_PARAM **)left;
const OSSL_PARAM *r = *(const OSSL_PARAM **)right;
return OPENSSL_strcasecmp(l->key, r->key);
}
OSSL_PARAM *OSSL_PARAM_merge(const OSSL_PARAM *p1, const OSSL_PARAM *p2)
{
const OSSL_PARAM *list1[OSSL_PARAM_MERGE_LIST_MAX + 1];
const OSSL_PARAM *list2[OSSL_PARAM_MERGE_LIST_MAX + 1];
const OSSL_PARAM *p = NULL;
const OSSL_PARAM **p1cur, **p2cur;
OSSL_PARAM *params, *dst;
size_t list1_sz = 0, list2_sz = 0;
int diff;
if (p1 == NULL && p2 == NULL)
return NULL;
/* Copy p1 to list1 */
if (p1 != NULL) {
for (p = p1; p->key != NULL && list1_sz < OSSL_PARAM_MERGE_LIST_MAX; p++)
list1[list1_sz++] = p;
}
list1[list1_sz] = NULL;
/* copy p2 to a list2 */
if (p2 != NULL) {
for (p = p2; p->key != NULL && list2_sz < OSSL_PARAM_MERGE_LIST_MAX; p++)
list2[list2_sz++] = p;
}
list2[list2_sz] = NULL;
if (list1_sz == 0 && list2_sz == 0)
return NULL;
/* Sort the 2 lists */
qsort(list1, list1_sz, sizeof(OSSL_PARAM *), compare_params);
qsort(list2, list2_sz, sizeof(OSSL_PARAM *), compare_params);
/* Allocate enough space to store the merged parameters */
params = OPENSSL_zalloc((list1_sz + list2_sz + 1) * sizeof(*p1));
if (params == NULL) {
ERR_raise(ERR_LIB_CRYPTO, ERR_R_MALLOC_FAILURE);
return NULL;
}
dst = params;
p1cur = list1;
p2cur = list2;
while (1) {
/* If list1 is finished just tack list2 onto the end */
if (*p1cur == NULL) {
do {
*dst++ = **p2cur;
p2cur++;
} while (*p2cur != NULL);
break;
}
/* If list2 is finished just tack list1 onto the end */
if (*p2cur == NULL) {
do {
*dst++ = **p1cur;
p1cur++;
} while (*p1cur != NULL);
break;
}
/* consume the list element with the smaller key */
diff = OPENSSL_strcasecmp((*p1cur)->key, (*p2cur)->key);
if (diff == 0) {
/* If the keys are the same then throw away the list1 element */
*dst++ = **p2cur;
p2cur++;
p1cur++;
} else if (diff > 0) {
*dst++ = **p2cur;
p2cur++;
} else {
*dst++ = **p1cur;
p1cur++;
}
}
return params;
}
void OSSL_PARAM_free(OSSL_PARAM *params)
{
if (params != NULL) {
OSSL_PARAM *p;
for (p = params; p->key != NULL; p++)
;
if (p->data_type == OSSL_PARAM_ALLOCATED_END)
OPENSSL_secure_clear_free(p->data, p->data_size);
OPENSSL_free(params);
}
}
Zerion Mini Shell 1.0