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samba-mirror/libcli/security/conditional_ace.c
Douglas Bagnall a016ce7068 libcli/security: don't allow conditional ACE SIDs to have trailing bytes
They should be tightly packed, allowing conditional ACEs to
round-trip.

Credit to OSS-Fuzz.

REF: https://bugs.chromium.org/p/oss-fuzz/issues/detail?id=64197

Signed-off-by: Douglas Bagnall <douglas.bagnall@catalyst.net.nz>
Reviewed-by: Andrew Bartlett <abartlet@samba.org>
2023-12-14 03:31:37 +00:00

2551 lines
64 KiB
C

/*
* Unix SMB implementation.
* Functions for understanding conditional ACEs
*
* This program 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 of the License, or
* (at your option) any later version.
*
* This program 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.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, see <http://www.gnu.org/licenses/>.
*/
#include "replace.h"
#include "librpc/gen_ndr/ndr_security.h"
#include "librpc/gen_ndr/ndr_conditional_ace.h"
#include "librpc/gen_ndr/conditional_ace.h"
#include "libcli/security/security.h"
#include "libcli/security/conditional_ace.h"
#include "libcli/security/claims-conversions.h"
#include "lib/util/tsort.h"
#include "lib/util/debug.h"
#include "lib/util/bytearray.h"
#include "lib/util/talloc_stack.h"
#include "util/discard.h"
#include "lib/util/stable_sort.h"
/*
* Conditional ACE logic truth tables.
*
* Conditional ACES use a ternary logic, with "unknown" as well as true and
* false. The ultimate meaning of unknown depends on the context; in a deny
* ace, unknown means yes, in an allow ace, unknown means no. That is, we
* treat unknown results with maximum suspicion.
*
* AND true false unknown
* true T F ?
* false F F F
* unknown ? F ?
*
* OR true false unknown
* true T T T
* false T F ?
* unknown T ? ?
*
* NOT
* true F
* false T
* unknown ?
*
* This can be summed up by saying unknown values taint the result except in
* the cases where short circuit evaluation could apply (true OR anything,
* false AND anything, which hold their value).
*
* What counts as unknown
*
* - NULL attributes.
* - certain comparisons between incompatible types
*
* What counts as false
*
* - zero
* - empty strings
*
* An error means the entire expression is unknown.
*/
static bool check_integer_range(const struct ace_condition_token *tok)
{
int64_t val = tok->data.int64.value;
switch (tok->type) {
case CONDITIONAL_ACE_TOKEN_INT8:
if (val < -128 || val > 127) {
return false;
}
break;
case CONDITIONAL_ACE_TOKEN_INT16:
if (val < INT16_MIN || val > INT16_MAX) {
return false;
}
break;
case CONDITIONAL_ACE_TOKEN_INT32:
if (val < INT32_MIN || val > INT32_MAX) {
return false;
}
break;
case CONDITIONAL_ACE_TOKEN_INT64:
/* val has these limits naturally */
break;
default:
return false;
}
if (tok->data.int64.base != CONDITIONAL_ACE_INT_BASE_8 &&
tok->data.int64.base != CONDITIONAL_ACE_INT_BASE_10 &&
tok->data.int64.base != CONDITIONAL_ACE_INT_BASE_16) {
return false;
}
if (tok->data.int64.sign != CONDITIONAL_ACE_INT_SIGN_POSITIVE &&
tok->data.int64.sign != CONDITIONAL_ACE_INT_SIGN_NEGATIVE &&
tok->data.int64.sign != CONDITIONAL_ACE_INT_SIGN_NONE) {
return false;
}
return true;
}
static ssize_t pull_integer(TALLOC_CTX *mem_ctx,
uint8_t *data, size_t length,
struct ace_condition_int *tok)
{
ssize_t bytes_used;
enum ndr_err_code ndr_err;
DATA_BLOB v = data_blob_const(data, length);
struct ndr_pull *ndr = ndr_pull_init_blob(&v, mem_ctx);
if (ndr == NULL) {
return -1;
}
ndr_err = ndr_pull_ace_condition_int(ndr, NDR_SCALARS|NDR_BUFFERS, tok);
if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) {
TALLOC_FREE(ndr);
return -1;
}
bytes_used = ndr->offset;
TALLOC_FREE(ndr);
return bytes_used;
}
static ssize_t push_integer(uint8_t *data, size_t available,
const struct ace_condition_int *tok)
{
enum ndr_err_code ndr_err;
DATA_BLOB v;
ndr_err = ndr_push_struct_blob(&v, NULL,
tok,
(ndr_push_flags_fn_t)ndr_push_ace_condition_int);
if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) {
return -1;
}
if (available < v.length) {
talloc_free(v.data);
return -1;
}
memcpy(data, v.data, v.length);
talloc_free(v.data);
return v.length;
}
static ssize_t pull_unicode(TALLOC_CTX *mem_ctx,
uint8_t *data, size_t length,
struct ace_condition_unicode *tok)
{
ssize_t bytes_used;
enum ndr_err_code ndr_err;
DATA_BLOB v = data_blob_const(data, length);
struct ndr_pull *ndr = ndr_pull_init_blob(&v, mem_ctx);
if (ndr == NULL) {
return -1;
}
ndr_err = ndr_pull_ace_condition_unicode(ndr, NDR_SCALARS|NDR_BUFFERS, tok);
if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) {
TALLOC_FREE(ndr);
return -1;
}
bytes_used = ndr->offset;
TALLOC_FREE(ndr);
return bytes_used;
}
static ssize_t push_unicode(uint8_t *data, size_t available,
const struct ace_condition_unicode *tok)
{
enum ndr_err_code ndr_err;
DATA_BLOB v;
ndr_err = ndr_push_struct_blob(&v, NULL,
tok,
(ndr_push_flags_fn_t)ndr_push_ace_condition_unicode);
if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) {
return -1;
}
if (available < v.length) {
talloc_free(v.data);
return -1;
}
memcpy(data, v.data, v.length);
talloc_free(v.data);
return v.length;
}
static ssize_t pull_bytes(TALLOC_CTX *mem_ctx,
uint8_t *data, size_t length,
DATA_BLOB *tok)
{
ssize_t bytes_used;
enum ndr_err_code ndr_err;
DATA_BLOB v = data_blob_const(data, length);
struct ndr_pull *ndr = ndr_pull_init_blob(&v, mem_ctx);
if (ndr == NULL) {
return -1;
}
ndr_err = ndr_pull_DATA_BLOB(ndr, NDR_SCALARS|NDR_BUFFERS, tok);
if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) {
TALLOC_FREE(ndr);
return -1;
}
bytes_used = ndr->offset;
talloc_free(ndr);
return bytes_used;
}
static ssize_t push_bytes(uint8_t *data, size_t available,
const DATA_BLOB *tok)
{
size_t offset;
enum ndr_err_code ndr_err;
TALLOC_CTX *frame = talloc_stackframe();
struct ndr_push *ndr = ndr_push_init_ctx(frame);
if (ndr == NULL) {
TALLOC_FREE(frame);
return -1;
}
ndr_err = ndr_push_DATA_BLOB(ndr, NDR_SCALARS|NDR_BUFFERS, *tok);
if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) {
TALLOC_FREE(frame);
return -1;
}
if (available < ndr->offset) {
TALLOC_FREE(frame);
return -1;
}
memcpy(data, ndr->data, ndr->offset);
offset = ndr->offset;
TALLOC_FREE(frame);
return offset;
}
static ssize_t pull_sid(TALLOC_CTX *mem_ctx,
uint8_t *data, size_t length,
struct ace_condition_sid *tok)
{
ssize_t bytes_used;
enum ndr_err_code ndr_err;
DATA_BLOB v = data_blob_const(data, length);
struct ndr_pull *ndr = ndr_pull_init_blob(&v, mem_ctx);
if (ndr == NULL) {
return -1;
}
ndr->flags |= LIBNDR_FLAG_SUBCONTEXT_NO_UNREAD_BYTES;
ndr_err = ndr_pull_ace_condition_sid(ndr, NDR_SCALARS|NDR_BUFFERS, tok);
if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) {
TALLOC_FREE(ndr);
return -1;
}
bytes_used = ndr->offset;
TALLOC_FREE(ndr);
return bytes_used;
}
static ssize_t push_sid(uint8_t *data, size_t available,
const struct ace_condition_sid *tok)
{
enum ndr_err_code ndr_err;
DATA_BLOB v;
ndr_err = ndr_push_struct_blob(&v, NULL,
tok,
(ndr_push_flags_fn_t)ndr_push_ace_condition_sid);
if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) {
return -1;
}
if (available < v.length) {
talloc_free(v.data);
return -1;
}
memcpy(data, v.data, v.length);
talloc_free(v.data);
return v.length;
}
static ssize_t pull_composite(TALLOC_CTX *mem_ctx,
uint8_t *data, size_t length,
struct ace_condition_composite *tok)
{
size_t i, j;
size_t alloc_length;
size_t byte_size;
struct ace_condition_token *tokens = NULL;
if (length < 4) {
return -1;
}
byte_size = PULL_LE_U32(data, 0);
if (byte_size > length - 4) {
return -1;
}
/*
* There is a list of other literal tokens (possibly including nested
* composites), which we will store in an array.
*
* This array can *only* be literals.
*/
alloc_length = byte_size;
tokens = talloc_array(mem_ctx,
struct ace_condition_token,
alloc_length);
if (tokens == NULL) {
return -1;
}
byte_size += 4;
i = 4;
j = 0;
while (i < byte_size) {
struct ace_condition_token *el = &tokens[j];
ssize_t consumed;
uint8_t *el_data = NULL;
size_t available;
bool ok;
*el = (struct ace_condition_token) { .type = data[i] };
i++;
el_data = data + i;
available = byte_size - i;
switch (el->type) {
case CONDITIONAL_ACE_TOKEN_INT8:
case CONDITIONAL_ACE_TOKEN_INT16:
case CONDITIONAL_ACE_TOKEN_INT32:
case CONDITIONAL_ACE_TOKEN_INT64:
consumed = pull_integer(mem_ctx,
el_data,
available,
&el->data.int64);
ok = check_integer_range(el);
if (! ok) {
goto error;
}
break;
case CONDITIONAL_ACE_TOKEN_UNICODE:
consumed = pull_unicode(mem_ctx,
el_data,
available,
&el->data.unicode);
break;
case CONDITIONAL_ACE_TOKEN_OCTET_STRING:
consumed = pull_bytes(mem_ctx,
el_data,
available,
&el->data.bytes);
break;
case CONDITIONAL_ACE_TOKEN_SID:
consumed = pull_sid(mem_ctx,
el_data,
available,
&el->data.sid);
break;
case CONDITIONAL_ACE_TOKEN_COMPOSITE:
DBG_ERR("recursive composite tokens in conditional "
"ACEs are not currently supported\n");
goto error;
default:
goto error;
}
if (consumed < 0 || consumed + i > length) {
goto error;
}
i += consumed;
j++;
if (j == UINT16_MAX) {
talloc_free(tokens);
return -1;
}
if (j == alloc_length) {
struct ace_condition_token *new_tokens = NULL;
alloc_length += 5;
new_tokens = talloc_realloc(mem_ctx,
tokens,
struct ace_condition_token,
alloc_length);
if (new_tokens == NULL) {
goto error;
}
tokens = new_tokens;
}
}
tok->n_members = j;
tok->tokens = tokens;
return byte_size;
error:
talloc_free(tokens);
return -1;
}
static ssize_t push_composite(uint8_t *data, size_t length,
const struct ace_condition_composite *tok)
{
size_t i;
uint8_t *byte_length_ptr;
size_t used = 0;
if (length < 4) {
return -1;
}
/*
* We have no idea what the eventual length will be, so we keep a
* pointer to write it in at the end.
*/
byte_length_ptr = data;
PUSH_LE_U32(data, 0, 0);
used = 4;
for (i = 0; i < tok->n_members && used < length; i++) {
struct ace_condition_token *el = &tok->tokens[i];
ssize_t consumed;
uint8_t *el_data = NULL;
size_t available;
bool ok;
data[used] = el->type;
used++;
if (used == length) {
/*
* used == length is not expected here; the token
* types that only have an opcode and no data are not
* literals that can be in composites.
*/
return -1;
}
el_data = data + used;
available = length - used;
switch (el->type) {
case CONDITIONAL_ACE_TOKEN_INT8:
case CONDITIONAL_ACE_TOKEN_INT16:
case CONDITIONAL_ACE_TOKEN_INT32:
case CONDITIONAL_ACE_TOKEN_INT64:
ok = check_integer_range(el);
if (! ok) {
return -1;
}
consumed = push_integer(el_data,
available,
&el->data.int64);
break;
case CONDITIONAL_ACE_TOKEN_UNICODE:
consumed = push_unicode(el_data,
available,
&el->data.unicode);
break;
case CONDITIONAL_ACE_TOKEN_OCTET_STRING:
consumed = push_bytes(el_data,
available,
&el->data.bytes);
break;
case CONDITIONAL_ACE_TOKEN_SID:
consumed = push_sid(el_data,
available,
&el->data.sid);
break;
case CONDITIONAL_ACE_TOKEN_COMPOSITE:
consumed = push_composite(el_data,
available,
&el->data.composite);
break;
default:
return -1;
}
if (consumed < 0) {
return -1;
}
used += consumed;
}
if (used > length) {
return -1;
}
PUSH_LE_U32(byte_length_ptr, 0, used - 4);
return used;
}
static ssize_t pull_end_padding(uint8_t *data, size_t length)
{
/*
* We just check that we have the right kind of number of zero
* bytes. The blob must end on a multiple of 4. One zero byte
* has already been swallowed as tok->type, which sends us
* here, so we expect 1 or two more -- total padding is 0, 1,
* 2, or 3.
*
* zero is also called CONDITIONAL_ACE_TOKEN_INVALID_OR_PADDING.
*/
ssize_t i;
if (length > 2) {
return -1;
}
for (i = 0; i < length; i++) {
if (data[i] != 0) {
return -1;
}
}
return length;
}
struct ace_condition_script *parse_conditional_ace(TALLOC_CTX *mem_ctx,
DATA_BLOB data)
{
size_t i, j;
struct ace_condition_token *tokens = NULL;
size_t alloc_length;
struct ace_condition_script *program = NULL;
if (data.length < 4 ||
data.data[0] != 'a' ||
data.data[1] != 'r' ||
data.data[2] != 't' ||
data.data[3] != 'x') {
/*
* lacks the "artx" conditional ace identifier magic.
* NULL returns will deny access.
*/
return NULL;
}
if (data.length > CONDITIONAL_ACE_MAX_LENGTH ||
(data.length & 3) != 0) {
/*
* >= 64k or non-multiples of 4 are not possible in the ACE
* wire format.
*/
return NULL;
}
program = talloc(mem_ctx, struct ace_condition_script);
if (program == NULL) {
return NULL;
}
/*
* We will normally end up with fewer than data.length tokens, as
* values are stored in multiple bytes (all integers are 10 bytes,
* strings and attributes are utf16 + length, SIDs are SID-size +
* length, etc). But operators are one byte, so something like
* !(!(!(!(!(!(x)))))) -- where each '!(..)' is one byte -- will bring
* the number of tokens close to the number of bytes.
*
* This is all to say we're guessing a token length that hopes to
* avoid reallocs without wasting too much up front.
*/
alloc_length = data.length / 2 + 1;
tokens = talloc_array(program,
struct ace_condition_token,
alloc_length);
if (tokens == NULL) {
TALLOC_FREE(program);
return NULL;
}
i = 4;
j = 0;
while(i < data.length) {
struct ace_condition_token *tok = &tokens[j];
ssize_t consumed = 0;
uint8_t *tok_data = NULL;
size_t available;
bool ok;
tok->type = data.data[i];
tok->flags = 0;
i++;
tok_data = data.data + i;
available = data.length - i;
switch (tok->type) {
case CONDITIONAL_ACE_TOKEN_INT8:
case CONDITIONAL_ACE_TOKEN_INT16:
case CONDITIONAL_ACE_TOKEN_INT32:
case CONDITIONAL_ACE_TOKEN_INT64:
consumed = pull_integer(program,
tok_data,
available,
&tok->data.int64);
ok = check_integer_range(tok);
if (! ok) {
goto fail;
}
break;
case CONDITIONAL_ACE_TOKEN_UNICODE:
/*
* The next four are pulled as unicode, but are
* processed as user attribute look-ups.
*/
case CONDITIONAL_ACE_LOCAL_ATTRIBUTE:
case CONDITIONAL_ACE_USER_ATTRIBUTE:
case CONDITIONAL_ACE_RESOURCE_ATTRIBUTE:
case CONDITIONAL_ACE_DEVICE_ATTRIBUTE:
consumed = pull_unicode(program,
tok_data,
available,
&tok->data.unicode);
break;
case CONDITIONAL_ACE_TOKEN_OCTET_STRING:
consumed = pull_bytes(program,
tok_data,
available,
&tok->data.bytes);
break;
case CONDITIONAL_ACE_TOKEN_SID:
consumed = pull_sid(program,
tok_data,
available,
&tok->data.sid);
break;
case CONDITIONAL_ACE_TOKEN_COMPOSITE:
consumed = pull_composite(program,
tok_data,
available,
&tok->data.composite);
break;
case CONDITIONAL_ACE_TOKEN_MEMBER_OF:
case CONDITIONAL_ACE_TOKEN_DEVICE_MEMBER_OF:
case CONDITIONAL_ACE_TOKEN_MEMBER_OF_ANY:
case CONDITIONAL_ACE_TOKEN_DEVICE_MEMBER_OF_ANY:
case CONDITIONAL_ACE_TOKEN_NOT_MEMBER_OF:
case CONDITIONAL_ACE_TOKEN_NOT_DEVICE_MEMBER_OF:
case CONDITIONAL_ACE_TOKEN_NOT_MEMBER_OF_ANY:
case CONDITIONAL_ACE_TOKEN_NOT_DEVICE_MEMBER_OF_ANY:
/*
* these require a SID or composite SID list operand,
* and we could check that now in most cases.
*/
break;
/* binary relational operators */
case CONDITIONAL_ACE_TOKEN_EQUAL:
case CONDITIONAL_ACE_TOKEN_NOT_EQUAL:
case CONDITIONAL_ACE_TOKEN_LESS_THAN:
case CONDITIONAL_ACE_TOKEN_LESS_OR_EQUAL:
case CONDITIONAL_ACE_TOKEN_GREATER_THAN:
case CONDITIONAL_ACE_TOKEN_GREATER_OR_EQUAL:
case CONDITIONAL_ACE_TOKEN_CONTAINS:
case CONDITIONAL_ACE_TOKEN_ANY_OF:
case CONDITIONAL_ACE_TOKEN_NOT_CONTAINS:
case CONDITIONAL_ACE_TOKEN_NOT_ANY_OF:
/* unary logical operators */
case CONDITIONAL_ACE_TOKEN_EXISTS:
case CONDITIONAL_ACE_TOKEN_NOT_EXISTS:
case CONDITIONAL_ACE_TOKEN_NOT:
/* binary logical operators */
case CONDITIONAL_ACE_TOKEN_AND:
case CONDITIONAL_ACE_TOKEN_OR:
break;
case CONDITIONAL_ACE_TOKEN_INVALID_OR_PADDING:
/* this is only valid at the end */
consumed = pull_end_padding(tok_data,
available);
j--; /* don't add this token */
break;
default:
goto fail;
}
if (consumed < 0) {
goto fail;
}
if (consumed + i < i || consumed + i > data.length) {
goto fail;
}
i += consumed;
j++;
if (j == alloc_length) {
alloc_length *= 2;
tokens = talloc_realloc(program,
tokens,
struct ace_condition_token,
alloc_length);
if (tokens == NULL) {
goto fail;
}
}
}
program->length = j;
program->tokens = talloc_realloc(program,
tokens,
struct ace_condition_token,
program->length + 1);
if (program->tokens == NULL) {
goto fail;
}
/*
* When interpreting the program we will need a stack, which in the
* very worst case can be as deep as the program is long.
*/
program->stack = talloc_array(program,
struct ace_condition_token,
program->length + 1);
if (program->stack == NULL) {
goto fail;
}
return program;
fail:
talloc_free(program);
return NULL;
}
static bool claim_lookup_internal(
TALLOC_CTX *mem_ctx,
struct CLAIM_SECURITY_ATTRIBUTE_RELATIVE_V1 *claim,
struct ace_condition_token *result)
{
bool ok = claim_v1_to_ace_token(mem_ctx, claim, result);
return ok;
}
static bool resource_claim_lookup(
TALLOC_CTX *mem_ctx,
const struct ace_condition_token *op,
const struct security_descriptor *sd,
struct ace_condition_token *result)
{
/*
* For a @Resource.attr, the claims come from a resource ACE
* in the object's SACL. That's why we need a security descriptor.
*
* If there is no matching resource ACE, a NULL result is returned,
* which should compare UNKNOWN to anything. The NULL will have the
* CONDITIONAL_ACE_FLAG_NULL_MEANS_ERROR flag set if it seems failure
* is not simply due to the sought claim not existing. This is useful for
* the Exists and Not_Exists operators.
*/
size_t i;
struct ace_condition_unicode name;
result->type = CONDITIONAL_ACE_SAMBA_RESULT_NULL;
if (op->type != CONDITIONAL_ACE_RESOURCE_ATTRIBUTE) {
/* what are we even doing here? */
result->type = CONDITIONAL_ACE_SAMBA_RESULT_ERROR;
return false;
}
name = op->data.resource_attr;
if (sd->sacl == NULL) {
DBG_NOTICE("Resource attribute ACE '%s' not found, "
"because there is no SACL\n",
name.value);
return true;
}
for (i = 0; i < sd->sacl->num_aces; i++) {
struct security_ace *ace = &sd->sacl->aces[i];
bool ok;
if (ace->type != SEC_ACE_TYPE_SYSTEM_RESOURCE_ATTRIBUTE) {
continue;
}
if (strcasecmp_m(name.value,
ace->coda.claim.name) != 0) {
continue;
}
/* this is the one */
ok = claim_lookup_internal(mem_ctx, &ace->coda.claim, result);
if (ok) {
return true;
}
}
DBG_NOTICE("Resource attribute ACE '%s' not found.\n",
name.value);
return false;
}
static bool token_claim_lookup(
TALLOC_CTX *mem_ctx,
const struct security_token *token,
const struct ace_condition_token *op,
struct ace_condition_token *result)
{
/*
* The operator has an attribute name; if there is a claim of
* the right type with that name, that is returned as the result.
*
* XXX what happens otherwise? NULL result?
*/
struct CLAIM_SECURITY_ATTRIBUTE_RELATIVE_V1 *claims = NULL;
size_t num_claims;
bool ok;
const struct ace_condition_unicode *name = NULL;
size_t i;
result->type = CONDITIONAL_ACE_SAMBA_RESULT_NULL;
switch (op->type) {
case CONDITIONAL_ACE_LOCAL_ATTRIBUTE:
claims = token->local_claims;
num_claims = token->num_local_claims;
name = &op->data.local_attr;
break;
case CONDITIONAL_ACE_USER_ATTRIBUTE:
claims = token->user_claims;
num_claims = token->num_user_claims;
name = &op->data.user_attr;
break;
case CONDITIONAL_ACE_DEVICE_ATTRIBUTE:
claims = token->device_claims;
num_claims = token->num_device_claims;
name = &op->data.device_attr;
break;
default:
DBG_WARNING("Conditional ACE claim lookup got bad arg type %u\n",
op->type);
result->type = CONDITIONAL_ACE_SAMBA_RESULT_ERROR;
return false;
}
if (num_claims == 0) {
DBG_NOTICE("There are no type %u claims\n", op->type);
return false;
}
if (claims == NULL) {
DBG_ERR("Type %u claim list unexpectedly NULL!\n", op->type);
result->type = CONDITIONAL_ACE_SAMBA_RESULT_ERROR;
return false;
}
/*
* Loop backwards: a later claim will override an earlier one with the
* same name.
*/
for (i = num_claims - 1; i < num_claims; i--) {
if (claims[i].name == NULL) {
DBG_ERR("claim %zu has no name!\n", i);
continue;
}
if (strcasecmp_m(claims[i].name, name->value) == 0) {
/* this is the one */
ok = claim_lookup_internal(mem_ctx, &claims[i], result);
return ok;
}
}
DBG_NOTICE("Claim not found\n");
return false;
}
static bool member_lookup(
const struct security_token *token,
const struct ace_condition_token *op,
const struct ace_condition_token *arg,
struct ace_condition_token *result)
{
/*
* We need to compare the lists of SIDs in the token with the
* SID[s] in the argument. There are 8 combinations of
* operation, depending on whether we want to match all or any
* of the SIDs, whether we're using the device SIDs or user
* SIDs, and whether the operator name starts with "Not_".
*
* _MEMBER_OF User has all operand SIDs
* _DEVICE_MEMBER_OF Device has all operand SIDs
* _MEMBER_OF_ANY User has one or more operand SIDs
* _DEVICE_MEMBER_OF_ANY Device has one or more operand SIDs
*
* NOT_* has the effect of !(the operator without NOT_).
*
* The operand can either be a composite of SIDs or a single SID.
* This adds an additional branch.
*/
bool match = false;
bool it_is_a_not_op;
bool it_is_an_any_op;
bool it_is_a_device_op;
bool arg_is_a_single_sid;
struct dom_sid *sid_array = NULL;
size_t num_sids, i, j;
const struct dom_sid *sid = NULL;
result->type = CONDITIONAL_ACE_SAMBA_RESULT_BOOL;
result->data.result.value = ACE_CONDITION_UNKNOWN;
switch (arg->type) {
case CONDITIONAL_ACE_TOKEN_SID:
arg_is_a_single_sid = true;
break;
case CONDITIONAL_ACE_TOKEN_COMPOSITE:
arg_is_a_single_sid = false;
break;
default:
DBG_WARNING("Conditional ACE Member_Of got bad arg type %u\n",
arg->type);
return false;
}
switch (op->type) {
case CONDITIONAL_ACE_TOKEN_NOT_MEMBER_OF:
case CONDITIONAL_ACE_TOKEN_NOT_MEMBER_OF_ANY:
it_is_a_not_op = true;
it_is_a_device_op = false;
break;
case CONDITIONAL_ACE_TOKEN_NOT_DEVICE_MEMBER_OF_ANY:
case CONDITIONAL_ACE_TOKEN_NOT_DEVICE_MEMBER_OF:
it_is_a_not_op = true;
it_is_a_device_op = true;
break;
case CONDITIONAL_ACE_TOKEN_MEMBER_OF:
case CONDITIONAL_ACE_TOKEN_MEMBER_OF_ANY:
it_is_a_not_op = false;
it_is_a_device_op = false;
break;
case CONDITIONAL_ACE_TOKEN_DEVICE_MEMBER_OF_ANY:
case CONDITIONAL_ACE_TOKEN_DEVICE_MEMBER_OF:
it_is_a_not_op = false;
it_is_a_device_op = true;
break;
default:
DBG_WARNING("Conditional ACE Member_Of got bad op type %u\n",
op->type);
return false;
}
switch (op->type) {
case CONDITIONAL_ACE_TOKEN_NOT_MEMBER_OF_ANY:
case CONDITIONAL_ACE_TOKEN_NOT_DEVICE_MEMBER_OF_ANY:
case CONDITIONAL_ACE_TOKEN_MEMBER_OF_ANY:
case CONDITIONAL_ACE_TOKEN_DEVICE_MEMBER_OF_ANY:
it_is_an_any_op = true;
break;
default:
it_is_an_any_op = false;
}
if (it_is_a_device_op) {
sid_array = token->device_sids;
num_sids = token->num_device_sids;
} else {
sid_array = token->sids;
num_sids = token->num_sids;
}
if (arg_is_a_single_sid) {
/*
* In this case the any and all operations are the
* same.
*/
sid = &arg->data.sid.sid;
match = false;
for (i = 0; i < num_sids; i++) {
match = dom_sid_equal(sid, &sid_array[i]);
if (match) {
break;
}
}
if (it_is_a_not_op) {
match = ! match;
}
if (match) {
result->data.result.value = ACE_CONDITION_TRUE;
} else {
result->data.result.value = ACE_CONDITION_FALSE;
}
return true;
}
/* This is a composite list (hopefully of SIDs) */
if (arg->data.composite.n_members == 0) {
DBG_WARNING("Conditional ACE Member_Of argument is empty\n");
return false;
}
for (j = 0; j < arg->data.composite.n_members; j++) {
const struct ace_condition_token *member =
&arg->data.composite.tokens[j];
if (member->type != CONDITIONAL_ACE_TOKEN_SID) {
DBG_WARNING("Conditional ACE Member_Of argument contains "
"non-sid element [%zu]: %u\n",
j, member->type);
return false;
}
sid = &member->data.sid.sid;
match = false;
for (i = 0; i < num_sids; i++) {
match = dom_sid_equal(sid, &sid_array[i]);
if (match) {
break;
}
}
if (it_is_an_any_op) {
if (match) {
/* we have matched one SID, which is enough */
goto apply_not;
}
} else { /* an all op */
if (! match) {
/* failing one is enough */
goto apply_not;
}
}
}
/*
* Reaching the end of that loop means either:
* 1. it was an ALL op and we never failed to find one, or
* 2. it was an ANY op, and we didn't find one.
*/
match = !it_is_an_any_op;
apply_not:
if (it_is_a_not_op) {
match = ! match;
}
if (match) {
result->data.result.value = ACE_CONDITION_TRUE;
} else {
result->data.result.value = ACE_CONDITION_FALSE;
}
return true;
}
static bool ternary_value(
const struct ace_condition_token *arg,
struct ace_condition_token *result)
{
/*
* Find the truth value of the argument, stored in the result token.
*
* A return value of false means the operation is invalid, and the
* result is undefined.
*/
if (arg->type == CONDITIONAL_ACE_SAMBA_RESULT_BOOL) {
/* pass through */
*result = *arg;
return true;
}
result->type = CONDITIONAL_ACE_SAMBA_RESULT_BOOL;
result->data.result.value = ACE_CONDITION_UNKNOWN;
if (IS_INT_TOKEN(arg)) {
/* zero is false */
if (arg->data.int64.value == 0) {
result->data.result.value = ACE_CONDITION_FALSE;
} else {
result->data.result.value = ACE_CONDITION_TRUE;
}
return true;
}
if (arg->type == CONDITIONAL_ACE_TOKEN_UNICODE) {
/* empty is false */
if (arg->data.unicode.value[0] == '\0') {
result->data.result.value = ACE_CONDITION_FALSE;
} else {
result->data.result.value = ACE_CONDITION_TRUE;
}
return true;
}
/*
* everything else in UNKNOWN. This includes NULL values (i.e. an
* unsuccessful look-up).
*/
result->data.result.value = ACE_CONDITION_UNKNOWN;
return true;
}
static bool not_operator(
const struct ace_condition_token *arg,
struct ace_condition_token *result)
{
bool ok;
if (IS_LITERAL_TOKEN(arg)) {
/*
* Logic operators don't work on literals.
*/
return false;
}
ok = ternary_value(arg, result);
if (! ok) {
return false;
}
if (result->data.result.value == ACE_CONDITION_FALSE) {
result->data.result.value = ACE_CONDITION_TRUE;
} else if (result->data.result.value == ACE_CONDITION_TRUE) {
result->data.result.value = ACE_CONDITION_FALSE;
}
/* unknown stays unknown */
return true;
}
static bool unary_logic_operator(
TALLOC_CTX *mem_ctx,
const struct security_token *token,
const struct ace_condition_token *op,
const struct ace_condition_token *arg,
const struct security_descriptor *sd,
struct ace_condition_token *result)
{
bool ok;
bool found;
struct ace_condition_token claim = {
.type = CONDITIONAL_ACE_SAMBA_RESULT_ERROR
};
if (op->type == CONDITIONAL_ACE_TOKEN_NOT) {
return not_operator(arg, result);
}
result->type = CONDITIONAL_ACE_SAMBA_RESULT_BOOL;
result->data.result.value = ACE_CONDITION_UNKNOWN;
/*
* Not_Exists and Exists require the same work, except we negate the
* answer in one case. From [MS-DTYP] 2.4.4.17.7:
*
* If the type of the operand is "Local Attribute"
* If the value is non-null return TRUE
* Else return FALSE
* Else if the type of the operand is "Resource Attribute"
* Return TRUE if value is non-null; FALSE otherwise.
* Else return Error
*/
switch (op->type) {
case CONDITIONAL_ACE_LOCAL_ATTRIBUTE:
ok = token_claim_lookup(mem_ctx, token, arg, &claim);
/*
* "not ok" usually means a failure to find the attribute,
* which is the false condition and not an error.
*
* XXX or do we need an extra flag?
*/
break;
case CONDITIONAL_ACE_RESOURCE_ATTRIBUTE:
ok = resource_claim_lookup(mem_ctx, arg, sd, &claim);
break;
default:
return false;
}
/*
*
*/
if (claim.type != CONDITIONAL_ACE_SAMBA_RESULT_NULL) {
found = true;
} else if (ok) {
found = false;
} else {
return false;
}
if (op->type == CONDITIONAL_ACE_TOKEN_NOT_EXISTS) {
found = ! found;
} else if (op->type != CONDITIONAL_ACE_TOKEN_EXISTS) {
/* should not get here */
return false;
}
result->data.result.value = found ? ACE_CONDITION_TRUE: ACE_CONDITION_FALSE;
return true;
}
static bool binary_logic_operator(
const struct security_token *token,
const struct ace_condition_token *op,
const struct ace_condition_token *lhs,
const struct ace_condition_token *rhs,
struct ace_condition_token *result)
{
struct ace_condition_token at, bt;
int a, b;
bool ok;
result->type = CONDITIONAL_ACE_SAMBA_RESULT_BOOL;
result->data.result.value = ACE_CONDITION_UNKNOWN;
if (IS_LITERAL_TOKEN(lhs) || IS_LITERAL_TOKEN(rhs)) {
/*
* Logic operators don't work on literals.
*/
return false;
}
ok = ternary_value(lhs, &at);
if (! ok) {
return false;
}
ok = ternary_value(rhs, &bt);
if (! ok) {
return false;
}
a = at.data.result.value;
b = bt.data.result.value;
if (op->type == CONDITIONAL_ACE_TOKEN_AND) {
/*
* AND true false unknown
* true T F ?
* false F F F
* unknown ? F ?
*
* unknown unless BOTH true or EITHER false
*/
if (a == ACE_CONDITION_TRUE &&
b == ACE_CONDITION_TRUE) {
result->data.result.value = ACE_CONDITION_TRUE;
return true;
}
if (a == ACE_CONDITION_FALSE ||
b == ACE_CONDITION_FALSE) {
result->data.result.value = ACE_CONDITION_FALSE;
return true;
}
/*
* Neither value is False, so the result is Unknown,
* as set at the start of this function.
*/
return true;
}
/*
* OR true false unknown
* true T T T
* false T F ?
* unknown T ? ?
*
* unknown unless EITHER true or BOTH false
*/
if (a == ACE_CONDITION_TRUE ||
b == ACE_CONDITION_TRUE) {
result->data.result.value = ACE_CONDITION_TRUE;
return true;
}
if (a == ACE_CONDITION_FALSE &&
b == ACE_CONDITION_FALSE) {
result->data.result.value = ACE_CONDITION_FALSE;
return true;
}
return true;
}
static bool tokens_are_comparable(const struct ace_condition_token *op,
const struct ace_condition_token *lhs,
const struct ace_condition_token *rhs)
{
uint64_t n;
/*
* we can't compare different types *unless* they are both
* integers, or one is a bool and the other is an integer 0 or
* 1, and the operator is == or != (or NULL, which for convenience,
* is treated as ==).
*/
//XXX actually it says "literal integers", do we need to check flags?
if (lhs->type == rhs->type) {
return true;
}
if (IS_INT_TOKEN(lhs) && IS_INT_TOKEN(rhs)) {
/* don't block e.g. comparing an int32 to an int64 */
return true;
}
/* is it == or != */
if (op != NULL &&
op->type != CONDITIONAL_ACE_TOKEN_EQUAL &&
op->type != CONDITIONAL_ACE_TOKEN_NOT_EQUAL) {
return false;
}
/* is one a bool and the other an int? */
if (IS_INT_TOKEN(lhs) && IS_BOOL_TOKEN(rhs)) {
n = lhs->data.int64.value;
} else if (IS_INT_TOKEN(rhs) && IS_BOOL_TOKEN(lhs)) {
n = rhs->data.int64.value;
} else {
return false;
}
if (n == 0 || n == 1) {
return true;
}
return false;
}
static bool cmp_to_result(const struct ace_condition_token *op,
struct ace_condition_token *result,
int cmp)
{
bool answer;
switch (op->type) {
case CONDITIONAL_ACE_TOKEN_EQUAL:
answer = cmp == 0;
break;
case CONDITIONAL_ACE_TOKEN_NOT_EQUAL:
answer = cmp != 0;
break;
case CONDITIONAL_ACE_TOKEN_LESS_THAN:
answer = cmp < 0;
break;
case CONDITIONAL_ACE_TOKEN_LESS_OR_EQUAL:
answer = cmp <= 0;
break;
case CONDITIONAL_ACE_TOKEN_GREATER_THAN:
answer = cmp > 0;
break;
case CONDITIONAL_ACE_TOKEN_GREATER_OR_EQUAL:
answer = cmp >= 0;
break;
default:
result->data.result.value = ACE_CONDITION_UNKNOWN;
return false;
}
result->data.result.value = \
answer ? ACE_CONDITION_TRUE : ACE_CONDITION_FALSE;
return true;
}
static bool compare_unicode(const struct ace_condition_token *op,
const struct ace_condition_token *lhs,
const struct ace_condition_token *rhs,
int *cmp)
{
struct ace_condition_unicode a = lhs->data.unicode;
struct ace_condition_unicode b = rhs->data.unicode;
/*
* Comparison is case-insensitive UNLESS the claim structure
* has the case-sensitive flag, which is passed through as a
* flag on the token. Usually only the LHS is a claim value,
* but in the event that they both are, we allow either to
* request case-sensitivity.
*
* For greater than and less than, the sort order is utf-8 order,
* which is not exactly what Windows does, but we don't sort like
* Windows does anywhere else either.
*/
uint8_t flags = lhs->flags | rhs->flags;
if (flags & CLAIM_SECURITY_ATTRIBUTE_VALUE_CASE_SENSITIVE) {
*cmp = strcmp(a.value, b.value);
} else {
*cmp = strcasecmp_m(a.value, b.value);
}
return true;
}
static bool compare_bytes(const struct ace_condition_token *op,
const struct ace_condition_token *lhs,
const struct ace_condition_token *rhs,
int *cmp)
{
DATA_BLOB a = lhs->data.bytes;
DATA_BLOB b = rhs->data.bytes;
*cmp = data_blob_cmp(&a, &b);
return true;
}
static bool compare_sids(const struct ace_condition_token *op,
const struct ace_condition_token *lhs,
const struct ace_condition_token *rhs,
int *cmp)
{
*cmp = dom_sid_compare(&lhs->data.sid.sid,
&rhs->data.sid.sid);
return true;
}
static bool compare_ints(const struct ace_condition_token *op,
const struct ace_condition_token *lhs,
const struct ace_condition_token *rhs,
int *cmp)
{
int64_t a = lhs->data.int64.value;
int64_t b = rhs->data.int64.value;
if (a < b) {
*cmp = -1;
} else if (a == b) {
*cmp = 0;
} else {
*cmp = 1;
}
return true;
}
static bool compare_bools(const struct ace_condition_token *op,
const struct ace_condition_token *lhs,
const struct ace_condition_token *rhs,
int *cmp)
{
bool ok;
struct ace_condition_token a, b;
*cmp = -1;
if (IS_LITERAL_TOKEN(lhs)) {
/*
* we can compare a boolean LHS to a literal RHS, but not
* vice versa
*/
return false;
}
ok = ternary_value(lhs, &a);
if (! ok) {
return false;
}
ok = ternary_value(rhs, &b);
if (! ok) {
return false;
}
if (a.data.result.value == ACE_CONDITION_UNKNOWN ||
b.data.result.value == ACE_CONDITION_UNKNOWN) {
return false;
}
switch (op->type) {
case CONDITIONAL_ACE_TOKEN_EQUAL:
case CONDITIONAL_ACE_TOKEN_NOT_EQUAL:
*cmp = a.data.result.value - b.data.result.value;
break;
default:
/* we are not allowing non-equality comparisons with bools */
return false;
}
return true;
}
static bool simple_relational_operator(const struct ace_condition_token *op,
const struct ace_condition_token *lhs,
const struct ace_condition_token *rhs,
int *cmp);
struct composite_sort_context {
bool failed;
};
static int composite_sort_cmp(const struct ace_condition_token *lhs,
const struct ace_condition_token *rhs,
struct composite_sort_context *ctx)
{
bool ok;
int cmp = -1;
/*
* simple_relational_operator uses the operator token only to
* decide whether the comparison is allowed for the type. In
* particular, boolean result and composite arguments can only
* be used with equality operators. We want those to fail (we
* should not see them here, remembering that claim booleans
* become composite integers), so we use a non-equality op.
*/
static const struct ace_condition_token op = {
.type = CONDITIONAL_ACE_TOKEN_LESS_THAN
};
ok = simple_relational_operator(&op, lhs, rhs, &cmp);
if (ok) {
return cmp;
}
/*
* This sort isn't going to work out, but the sort function
* will only find out at the end.
*/
ctx->failed = true;
return cmp;
}
/*
* Return a sorted copy of the composite tokens array.
*
* The copy is shallow, so the actual string pointers are the same, which is
* fine for the purposes of comparison.
*/
static struct ace_condition_token *composite_sorted_copy(
TALLOC_CTX *mem_ctx,
const struct ace_condition_composite *c,
bool case_sensitive)
{
struct ace_condition_token *copy = NULL;
bool ok;
size_t i;
struct composite_sort_context sort_ctx = {
.failed = false
};
/*
* Case sensitivity is a bit tricky. Each token can have a flag saying
* it should be sorted case-sensitively and when comparing two tokens,
* we should respect this flag on either side. The flag can only come
* from claims (including resource attribute ACEs), and as there is only
* one flag per claim, it must apply the same to all members (in fact we
* don't set it on the members, only the composite). So to be sure we
* sort in the way we want, we might need to set the flag on all the
* members of the copy *before* sorting it.
*
* When it comes to comparing two composites, we want to be
* case-sensitive if either side has the flag. This can have odd
* effects. Think of these RA claims:
*
* (RA;;;;;WD;("foo",TS,0,"a","A"))
* (RA;;;;;WD;("bar",TS,2,"a","A")) <-- 2 is the case-sensitive flag
* (RA;;;;;WD;("baz",TS,0,"a"))
*
* (@Resource.foo == @Resource.bar) is true
* (@Resource.bar == @Resource.foo) is true
* (@Resource.bar == @Resource.bar) is true
* (@Resource.foo == @Resource.foo) is an error (duplicate values on LHS)
* (@Resource.baz == @Resource.foo) is true (RHS case-folds down)
* (@Resource.baz == @Resource.bar) is false
* (@Resource.bar == {"A", "a"}) is true
* (@Resource.baz == {"A", "a"}) is true
* (@Resource.foo == {"A", "a"}) is an error
*/
copy = talloc_array(mem_ctx, struct ace_condition_token, c->n_members);
if (copy == NULL) {
return NULL;
}
memcpy(copy, c->tokens, sizeof(struct ace_condition_token) * c->n_members);
if (case_sensitive) {
for (i = 0; i < c->n_members; i++) {
c->tokens[i].flags |= CLAIM_SECURITY_ATTRIBUTE_VALUE_CASE_SENSITIVE;
}
}
ok = stable_sort_talloc_r(mem_ctx,
copy,
c->n_members,
sizeof(struct ace_condition_token),
(samba_compare_with_context_fn_t)composite_sort_cmp,
&sort_ctx);
if (!ok || sort_ctx.failed) {
DBG_NOTICE("composite sort of %"PRIu32" members failed\n",
c->n_members);
TALLOC_FREE(copy);
return NULL;
}
return copy;
}
/*
* This is a helper for compare composites.
*/
static bool compare_composites_via_sort(const struct ace_condition_token *lhs,
const struct ace_condition_token *rhs,
int *cmp)
{
const struct ace_condition_composite *lc = &lhs->data.composite;
const struct ace_condition_composite *rc = &rhs->data.composite;
size_t i;
TALLOC_CTX *tmp_ctx = NULL;
bool ok;
int cmp_pair;
bool case_sensitive, rhs_case_sensitive;
bool rhs_sorted;
struct ace_condition_token *ltok = lc->tokens;
struct ace_condition_token *rtok = rc->tokens;
static const struct ace_condition_token eq = {
.type = CONDITIONAL_ACE_TOKEN_EQUAL
};
*cmp = -1;
if (lc->n_members == 0 ||
rc->n_members < lc->n_members) {
/* we should not have got this far */
return false;
}
tmp_ctx = talloc_new(NULL);
if (tmp_ctx == NULL) {
return false;
}
case_sensitive = lhs->flags & CLAIM_SECURITY_ATTRIBUTE_VALUE_CASE_SENSITIVE;
rhs_case_sensitive = rhs->flags & CLAIM_SECURITY_ATTRIBUTE_VALUE_CASE_SENSITIVE;
rhs_sorted = rhs->flags & CLAIM_SECURITY_ATTRIBUTE_UNIQUE_AND_SORTED;
if (lc->tokens[0].type != CONDITIONAL_ACE_TOKEN_UNICODE) {
/*
* All LHS tokens are the same type (because it is a
* claim), and that type is not one that cares about
* case, so nor do we.
*/
case_sensitive = false;
} else if (case_sensitive == rhs_case_sensitive) {
/* phew, no extra work */
} else if (case_sensitive) {
/* trigger a sorted copy */
rhs_sorted = false;
} else if (rhs_case_sensitive) {
/*
* Do we need to rescan for uniqueness, given the new
* comparison function? No! The strings were already
* unique in the looser comparison, and now they can
* only be more so. The number of unique values can't
* change, just their order.
*/
case_sensitive = true;
ltok = composite_sorted_copy(tmp_ctx, lc, case_sensitive);
if (ltok == NULL) {
DBG_WARNING("sort of LHS failed\n");
goto error;
}
}
if (! rhs_sorted) {
/*
* we need an RHS sorted copy (it's a literal, or
* there was a case sensitivity disagreement).
*/
rtok = composite_sorted_copy(tmp_ctx, rc, case_sensitive);
if (rtok == NULL) {
DBG_WARNING("sort of RHS failed\n");
goto error;
}
}
/*
* Each member of LHS must match one or more members of RHS.
* Each member of RHS must match at least one of LHS.
*
* If they are the same length we can compare directly, so let's get
* rid of duplicates in RHS. This can only happen with literal
* composites.
*/
if (rc->n_members > lc->n_members) {
size_t gap = 0;
for (i = 1; i < rc->n_members; i++) {
ok = simple_relational_operator(&eq,
&rtok[i - 1],
&rtok[i],
&cmp_pair);
if (! ok) {
goto error;
}
if (cmp_pair == 0) {
gap++;
}
if (gap != 0) {
rtok[i - gap] = rtok[i];
}
}
if (rc->n_members - lc->n_members != gap) {
/*
* There were too many or too few duplicates to account
* for the difference, and no further comparison is
* necessary.
*/
goto not_equal;
}
}
/*
* OK, now we know LHS and RHS are the same length and sorted in the
* same way, so we can just iterate over them and check each pair.
*/
for (i = 0; i < lc->n_members; i++) {
ok = simple_relational_operator(&eq,
&ltok[i],
&rtok[i],
&cmp_pair);
if (! ok){
goto error;
}
if (cmp_pair != 0) {
goto not_equal;
}
}
*cmp = 0;
not_equal:
TALLOC_FREE(tmp_ctx);
return true;
error:
TALLOC_FREE(tmp_ctx);
return false;
}
static bool composite_is_comparable(const struct ace_condition_token *tok,
const struct ace_condition_token *comp)
{
/*
* Are all members of the composite comparable to the token?
*/
size_t i;
const struct ace_condition_composite *rc = &comp->data.composite;
size_t n = rc->n_members;
if ((comp->flags & CLAIM_SECURITY_ATTRIBUTE_UNIQUE_AND_SORTED) &&
n > 1) {
/*
* all members are known to be the same type, so we
* can just check one.
*/
n = 1;
}
for (i = 0; i < n; i++) {
if (! tokens_are_comparable(NULL,
tok,
&rc->tokens[i])) {
DBG_NOTICE("token type %u != composite type %u\n",
tok->type, rc->tokens[i].type);
return false;
}
}
return true;
}
static bool compare_composites(const struct ace_condition_token *op,
const struct ace_condition_token *lhs,
const struct ace_condition_token *rhs,
int *cmp)
{
/*
* This is for comparing multivalued sets, which includes
* conditional ACE composites and claim sets. Because these
* are sets, there are no < and > operations, just equality or
* otherwise.
*
* Claims are true sets, while composites are multisets --
* duplicate values are allowed -- but these are reduced to
* sets in evaluation, and the number of duplicates has no
* effect in comparisons. Resource attribute ACEs live in an
* intermediate state -- they can contain duplicates on the
* wire and as ACE structures, but as soon as they are
* evaluated as claims their values must be unique. Windows
* will treat RA ACEs with duplicate values as not existing,
* rather than as UNKNOWN (This is significant for the Exists
* operator). Claims can have a case-sensitive flags set,
* meaning they must be compared case-sensitively.
*
* Some good news is that the LHS of a comparison must always
* be a claim. That means we can assume it has unique values
* when it comes to pairwise comparisons. Using the magic of
* flags, we try to check this only once per claim.
*
* Conditional ACE composites, which can have duplicates (and
* mixed types), can only be on the RHS.
*
* To summarise:
*
* {a, b} vs {a, b} equal
* { } vs { } equal
* {a, b} vs {b, a} equal
* {a, b} vs {a, c} not equal
* {a, b} vs {a, a, b} equal
* {b, a} vs {a, b, a} equal
* {a, b} vs {a, a, b, c} not equal
* {a, b, a} vs {a, b} should not happen, error
* {a, b, a} vs {a, b, a} should not happen, error
*
* mixed types:
* {1, 2} vs {1, "2"} error
* {1, "2"} vs {1, "2"} should not happen, error
*
* case sensitivity (*{ }* indicates case-sensitive flag):
*
* {"a", "b"} vs {"a", "B"} equal
* {"a", "b"} vs *{"a", "B"}* not equal
* *{"a", "b"}* vs {"a", "B"} not equal
* *{"a", "A"}* vs {"a", "A"} equal (if RHS is composite)
* {"a", "A"} vs *{"a", "A"}* impossible (LHS is not unique)
* *{"a"}* vs {"a", "A"} not equal
*
* The naive approach is of course O(n * m) with an additional O(n²)
* if the LHS values are not known to be unique (that is, in resource
* attribute claims). We want to avoid that with big sets.
*/
const struct ace_condition_composite *lc = &lhs->data.composite;
const struct ace_condition_composite *rc = &rhs->data.composite;
bool ok;
if (!(lhs->flags & CLAIM_SECURITY_ATTRIBUTE_UNIQUE_AND_SORTED)) {
/*
* The LHS needs to be a claim, and it should have gone
* through claim_v1_check_and_sort() to get here.
*/
*cmp = -1;
return false;
}
/* if one or both are empty, the answer is easy */
if (lc->n_members == 0) {
if (rc->n_members == 0) {
*cmp = 0;
return true;
}
*cmp = -1;
return true;
}
if (rc->n_members == 0) {
*cmp = -1;
return true;
}
/*
* LHS must be a claim, so it must be unique, so if there are
* fewer members on the RHS, we know they can't be equal.
*
* If you think about it too much, you might think this is
* affected by case sensitivity, but it isn't. One side can be
* infected by case-sensitivity by the other, but that can't
* shrink the number of elements on the RHS -- it can only
* make a literal {"a", "A"} have effective length 2 rather
* than 1.
*
* On the other hand, if the RHS is case sensitive, it must be
* a claim and unique in its own terms, and its finer-grained
* distinctions can't collapse members of the case sensitive
* LHS.
*/
if (lc->n_members > rc->n_members) {
*cmp = -1;
return composite_is_comparable(&lc->tokens[0], rhs);
}
/*
* It *could* be that RHS is also unique and we know it. In that
* case we can short circuit if RHS has more members. This is
* the case when both sides are claims.
*
* This is also not affected by case-senstivity.
*/
if (lc->n_members < rc->n_members &&
(rhs->flags & CLAIM_SECURITY_ATTRIBUTE_UNIQUE_AND_SORTED)) {
*cmp = -1;
return composite_is_comparable(&lc->tokens[0], rhs);
}
ok = compare_composites_via_sort(lhs, rhs, cmp);
if (! ok) {
return false;
}
return true;
}
static bool simple_relational_operator(const struct ace_condition_token *op,
const struct ace_condition_token *lhs,
const struct ace_condition_token *rhs,
int *cmp)
{
if (lhs->type != rhs->type) {
if (! tokens_are_comparable(op, lhs, rhs)) {
return false;
}
}
switch (lhs->type) {
case CONDITIONAL_ACE_TOKEN_INT8:
case CONDITIONAL_ACE_TOKEN_INT16:
case CONDITIONAL_ACE_TOKEN_INT32:
case CONDITIONAL_ACE_TOKEN_INT64:
if (rhs->type == CONDITIONAL_ACE_SAMBA_RESULT_BOOL) {
return compare_bools(op, lhs, rhs, cmp);
}
return compare_ints(op, lhs, rhs, cmp);
case CONDITIONAL_ACE_SAMBA_RESULT_BOOL:
return compare_bools(op, lhs, rhs, cmp);
case CONDITIONAL_ACE_TOKEN_UNICODE:
return compare_unicode(op, lhs, rhs, cmp);
case CONDITIONAL_ACE_TOKEN_OCTET_STRING:
return compare_bytes(op, lhs, rhs, cmp);
case CONDITIONAL_ACE_TOKEN_SID:
return compare_sids(op, lhs, rhs, cmp);
case CONDITIONAL_ACE_TOKEN_COMPOSITE:
return compare_composites(op, lhs, rhs, cmp);
case CONDITIONAL_ACE_SAMBA_RESULT_NULL:
/* leave the result unknown */
return false;
default:
DBG_ERR("did not expect ace type %u\n", lhs->type);
return false;
}
return false;
}
static bool find_in_composite(const struct ace_condition_token *tok,
struct ace_condition_composite candidates,
bool *answer)
{
size_t i;
int cmp;
bool ok;
const struct ace_condition_token equals = {
.type = CONDITIONAL_ACE_TOKEN_EQUAL
};
*answer = false;
for (i = 0; i < candidates.n_members; i++) {
ok = simple_relational_operator(&equals,
tok,
&candidates.tokens[i],
&cmp);
if (! ok) {
return false;
}
if (cmp == 0) {
*answer = true;
return true;
}
}
return true;
}
static bool contains_operator(const struct ace_condition_token *lhs,
const struct ace_condition_token *rhs,
bool *answer)
{
size_t i;
bool ok;
int cmp;
const struct ace_condition_token equals = {
.type = CONDITIONAL_ACE_TOKEN_EQUAL
};
/*
* All the required objects must be identical to something in
* candidates. But what do we mean by *identical*? We'll use
* the equality operator to decide that.
*
* Both the lhs or rhs can be solitary objects or composites.
* This makes it a bit fiddlier.
*
* NOTE: this operator does not take advantage of the
* CLAIM_SECURITY_ATTRIBUTE_UNIQUE_AND_SORTED flag. It could, but it
* doesn't.
*/
if (lhs->type == CONDITIONAL_ACE_TOKEN_COMPOSITE) {
struct ace_condition_composite candidates = lhs->data.composite;
struct ace_condition_composite required;
if (rhs->type != CONDITIONAL_ACE_TOKEN_COMPOSITE) {
return find_in_composite(rhs, candidates, answer);
}
required = rhs->data.composite;
if (required.n_members == 0) {
return false;
}
for (i = 0; i < required.n_members; i++) {
const struct ace_condition_token *t = &required.tokens[i];
ok = find_in_composite(t, candidates, answer);
if (! ok) {
return false;
}
if (! *answer) {
/*
* one required item was not there,
* *answer is false
*/
return true;
}
}
/* all required items are there, *answer will be true */
return true;
}
/* LHS is a single item */
if (rhs->type == CONDITIONAL_ACE_TOKEN_COMPOSITE) {
/*
* There could be more than one RHS member that is
* equal to the single LHS value, so it doesn't help
* to compare lengths or anything.
*/
struct ace_condition_composite required = rhs->data.composite;
if (required.n_members == 0) {
return false;
}
for (i = 0; i < required.n_members; i++) {
ok = simple_relational_operator(&equals,
lhs,
&required.tokens[i],
&cmp);
if (! ok) {
return false;
}
if (cmp != 0) {
/*
* one required item was not there,
* *answer is false
*/
*answer = false;
return true;
}
}
*answer = true;
return true;
}
/* LHS and RHS are both single */
ok = simple_relational_operator(&equals,
lhs,
rhs,
&cmp);
if (! ok) {
return false;
}
*answer = (cmp == 0);
return true;
}
static bool any_of_operator(const struct ace_condition_token *lhs,
const struct ace_condition_token *rhs,
bool *answer)
{
size_t i;
bool ok;
int cmp;
const struct ace_condition_token equals = {
.type = CONDITIONAL_ACE_TOKEN_EQUAL
};
/*
* There has to be *some* overlap between the LHS and RHS.
* Both sides can be solitary objects or composites.
*
* We can exploit this symmetry.
*/
if (lhs->type != CONDITIONAL_ACE_TOKEN_COMPOSITE) {
const struct ace_condition_token *tmp = lhs;
lhs = rhs;
rhs = tmp;
}
if (lhs->type != CONDITIONAL_ACE_TOKEN_COMPOSITE) {
/* both singles */
ok = simple_relational_operator(&equals,
lhs,
rhs,
&cmp);
if (! ok) {
return false;
}
*answer = (cmp == 0);
return true;
}
if (rhs->type != CONDITIONAL_ACE_TOKEN_COMPOSITE) {
return find_in_composite(rhs, lhs->data.composite, answer);
}
/* both are composites */
if (lhs->data.composite.n_members == 0) {
return false;
}
for (i = 0; i < lhs->data.composite.n_members; i++) {
ok = find_in_composite(&lhs->data.composite.tokens[i],
rhs->data.composite,
answer);
if (! ok) {
return false;
}
if (*answer) {
/* We have found one match, which is enough. */
return true;
}
}
return true;
}
static bool composite_relational_operator(const struct ace_condition_token *op,
const struct ace_condition_token *lhs,
const struct ace_condition_token *rhs,
struct ace_condition_token *result)
{
bool ok, answer;
switch(op->type) {
case CONDITIONAL_ACE_TOKEN_CONTAINS:
case CONDITIONAL_ACE_TOKEN_NOT_CONTAINS:
ok = contains_operator(lhs, rhs, &answer);
break;
case CONDITIONAL_ACE_TOKEN_ANY_OF:
case CONDITIONAL_ACE_TOKEN_NOT_ANY_OF:
ok = any_of_operator(lhs, rhs, &answer);
break;
default:
return false;
}
if (!ok) {
return false;
}
/* negate the NOTs */
if (op->type == CONDITIONAL_ACE_TOKEN_NOT_CONTAINS ||
op->type == CONDITIONAL_ACE_TOKEN_NOT_ANY_OF)
{
answer = !answer;
}
if (answer) {
result->data.result.value = ACE_CONDITION_TRUE;
} else {
result->data.result.value = ACE_CONDITION_FALSE;
}
return true;
}
static bool relational_operator(
const struct security_token *token,
const struct ace_condition_token *op,
const struct ace_condition_token *lhs,
const struct ace_condition_token *rhs,
struct ace_condition_token *result)
{
int cmp;
bool ok;
result->type = CONDITIONAL_ACE_SAMBA_RESULT_BOOL;
result->data.result.value = ACE_CONDITION_UNKNOWN;
if ((lhs->flags & CONDITIONAL_ACE_FLAG_TOKEN_FROM_ATTR) == 0) {
/* LHS was not derived from an attribute */
return false;
}
/*
* This first nested switch is ensuring that >, >=, <, <= are
* not being tried on tokens that are not numbers, strings, or
* octet strings. Equality operators are available for all types.
*/
switch (lhs->type) {
case CONDITIONAL_ACE_TOKEN_INT8:
case CONDITIONAL_ACE_TOKEN_INT16:
case CONDITIONAL_ACE_TOKEN_INT32:
case CONDITIONAL_ACE_TOKEN_INT64:
case CONDITIONAL_ACE_TOKEN_UNICODE:
case CONDITIONAL_ACE_TOKEN_OCTET_STRING:
break;
default:
switch(op->type) {
case CONDITIONAL_ACE_TOKEN_LESS_THAN:
case CONDITIONAL_ACE_TOKEN_LESS_OR_EQUAL:
case CONDITIONAL_ACE_TOKEN_GREATER_THAN:
case CONDITIONAL_ACE_TOKEN_GREATER_OR_EQUAL:
return false;
default:
break;
}
}
/*
* Dispatch according to operator type.
*/
switch (op->type) {
case CONDITIONAL_ACE_TOKEN_EQUAL:
case CONDITIONAL_ACE_TOKEN_NOT_EQUAL:
case CONDITIONAL_ACE_TOKEN_LESS_THAN:
case CONDITIONAL_ACE_TOKEN_LESS_OR_EQUAL:
case CONDITIONAL_ACE_TOKEN_GREATER_THAN:
case CONDITIONAL_ACE_TOKEN_GREATER_OR_EQUAL:
ok = simple_relational_operator(op,
lhs,
rhs,
&cmp);
if (ok) {
ok = cmp_to_result(op, result, cmp);
}
return ok;
case CONDITIONAL_ACE_TOKEN_CONTAINS:
case CONDITIONAL_ACE_TOKEN_ANY_OF:
case CONDITIONAL_ACE_TOKEN_NOT_CONTAINS:
case CONDITIONAL_ACE_TOKEN_NOT_ANY_OF:
return composite_relational_operator(op,
lhs,
rhs,
result);
default:
return false;
}
}
int run_conditional_ace(TALLOC_CTX *mem_ctx,
const struct security_token *token,
struct ace_condition_script *program,
const struct security_descriptor *sd)
{
size_t i;
size_t depth = 0;
struct ace_condition_token *lhs = NULL;
struct ace_condition_token *rhs = NULL;
struct ace_condition_token result = {};
bool ok;
for (i = 0; i < program->length; i++) {
struct ace_condition_token *tok = &program->tokens[i];
switch (tok->type) {
case CONDITIONAL_ACE_TOKEN_INT8:
case CONDITIONAL_ACE_TOKEN_INT16:
case CONDITIONAL_ACE_TOKEN_INT32:
case CONDITIONAL_ACE_TOKEN_INT64:
case CONDITIONAL_ACE_TOKEN_UNICODE:
case CONDITIONAL_ACE_TOKEN_OCTET_STRING:
case CONDITIONAL_ACE_TOKEN_SID:
case CONDITIONAL_ACE_TOKEN_COMPOSITE:
/* just plonk these literals on the stack */
program->stack[depth] = *tok;
depth++;
break;
case CONDITIONAL_ACE_LOCAL_ATTRIBUTE:
case CONDITIONAL_ACE_USER_ATTRIBUTE:
case CONDITIONAL_ACE_DEVICE_ATTRIBUTE:
ok = token_claim_lookup(mem_ctx, token, tok, &result);
if (! ok) {
goto error;
}
program->stack[depth] = result;
depth++;
break;
case CONDITIONAL_ACE_RESOURCE_ATTRIBUTE:
ok = resource_claim_lookup(mem_ctx,
tok,
sd,
&result);
if (! ok) {
goto error;
}
program->stack[depth] = result;
depth++;
break;
case CONDITIONAL_ACE_TOKEN_MEMBER_OF:
case CONDITIONAL_ACE_TOKEN_DEVICE_MEMBER_OF:
case CONDITIONAL_ACE_TOKEN_MEMBER_OF_ANY:
case CONDITIONAL_ACE_TOKEN_DEVICE_MEMBER_OF_ANY:
case CONDITIONAL_ACE_TOKEN_NOT_MEMBER_OF:
case CONDITIONAL_ACE_TOKEN_NOT_DEVICE_MEMBER_OF:
case CONDITIONAL_ACE_TOKEN_NOT_MEMBER_OF_ANY:
case CONDITIONAL_ACE_TOKEN_NOT_DEVICE_MEMBER_OF_ANY:
if (depth == 0) {
goto error;
}
depth--;
lhs = &program->stack[depth];
ok = member_lookup(token, tok, lhs, &result);
if (! ok) {
goto error;
}
program->stack[depth] = result;
depth++;
break;
/* binary relational operators */
case CONDITIONAL_ACE_TOKEN_EQUAL:
case CONDITIONAL_ACE_TOKEN_NOT_EQUAL:
case CONDITIONAL_ACE_TOKEN_LESS_THAN:
case CONDITIONAL_ACE_TOKEN_LESS_OR_EQUAL:
case CONDITIONAL_ACE_TOKEN_GREATER_THAN:
case CONDITIONAL_ACE_TOKEN_GREATER_OR_EQUAL:
case CONDITIONAL_ACE_TOKEN_CONTAINS:
case CONDITIONAL_ACE_TOKEN_ANY_OF:
case CONDITIONAL_ACE_TOKEN_NOT_CONTAINS:
case CONDITIONAL_ACE_TOKEN_NOT_ANY_OF:
if (depth < 2) {
goto error;
}
depth--;
rhs = &program->stack[depth];
depth--;
lhs = &program->stack[depth];
ok = relational_operator(token, tok, lhs, rhs, &result);
if (! ok) {
goto error;
}
program->stack[depth] = result;
depth++;
break;
/* unary logical operators */
case CONDITIONAL_ACE_TOKEN_EXISTS:
case CONDITIONAL_ACE_TOKEN_NOT_EXISTS:
case CONDITIONAL_ACE_TOKEN_NOT:
if (depth == 0) {
goto error;
}
depth--;
lhs = &program->stack[depth];
ok = unary_logic_operator(mem_ctx, token, tok, lhs, sd, &result);
if (!ok) {
goto error;
}
program->stack[depth] = result;
depth++;
break;
/* binary logical operators */
case CONDITIONAL_ACE_TOKEN_AND:
case CONDITIONAL_ACE_TOKEN_OR:
if (depth < 2) {
goto error;
}
depth--;
rhs = &program->stack[depth];
depth--;
lhs = &program->stack[depth];
ok = binary_logic_operator(token, tok, lhs, rhs, &result);
if (! ok) {
goto error;
}
program->stack[depth] = result;
depth++;
break;
default:
goto error;
}
}
/*
* The evaluation should have left a single result value (true, false,
* or unknown) on the stack. If not, the expression was malformed.
*/
if (depth != 1) {
goto error;
}
result = program->stack[0];
if (result.type != CONDITIONAL_ACE_SAMBA_RESULT_BOOL) {
goto error;
}
return result.data.result.value;
error:
/*
* the result of an error is always UNKNOWN, which should be
* interpreted pessimistically, not allowing access.
*/
return ACE_CONDITION_UNKNOWN;
}
/** access_check_conditional_ace()
*
* Run the conditional ACE from the blob form. Return false if it is
* not a valid conditional ACE, true if it is, even if there is some
* other error in running it. The *result parameter is set to
* ACE_CONDITION_FALSE, ACE_CONDITION_TRUE, or ACE_CONDITION_UNKNOWN.
*
* ACE_CONDITION_UNKNOWN should be treated pessimistically, as if it were
* TRUE for deny ACEs, and FALSE for allow ACEs.
*
* @param[in] ace - the ACE being processed.
* @param[in] token - the security token the ACE is processing.
* @param[out] result - a ternary result value.
*
* @return true if it is a valid conditional ACE.
*/
bool access_check_conditional_ace(const struct security_ace *ace,
const struct security_token *token,
const struct security_descriptor *sd,
int *result)
{
TALLOC_CTX *tmp_ctx = talloc_new(NULL);
struct ace_condition_script *program = NULL;
program = parse_conditional_ace(tmp_ctx, ace->coda.conditions);
if (program == NULL) {
*result = ACE_CONDITION_UNKNOWN;
TALLOC_FREE(tmp_ctx);
return false;
}
*result = run_conditional_ace(tmp_ctx, token, program, sd);
TALLOC_FREE(tmp_ctx);
return true;
}
bool conditional_ace_encode_binary(TALLOC_CTX *mem_ctx,
struct ace_condition_script *program,
DATA_BLOB *dest)
{
size_t i, j, alloc_size, required_size;
uint8_t *data = NULL;
uint8_t *new_data = NULL;
*dest = (DATA_BLOB){NULL, 0};
alloc_size = CONDITIONAL_ACE_MAX_LENGTH;
data = talloc_array(mem_ctx,
uint8_t,
alloc_size);
if (data == NULL) {
return false;
}
data[0] = 'a';
data[1] = 'r';
data[2] = 't';
data[3] = 'x';
j = 4;
for (i = 0; i < program->length; i++) {
struct ace_condition_token *tok = &program->tokens[i];
ssize_t consumed;
bool ok;
/*
* In all cases we write the token type byte.
*/
data[j] = tok->type;
j++;
if (j >= alloc_size) {
DBG_ERR("program exceeds %zu bytes\n", alloc_size);
goto error;
}
switch (tok->type) {
case CONDITIONAL_ACE_TOKEN_MEMBER_OF:
case CONDITIONAL_ACE_TOKEN_DEVICE_MEMBER_OF:
case CONDITIONAL_ACE_TOKEN_MEMBER_OF_ANY:
case CONDITIONAL_ACE_TOKEN_DEVICE_MEMBER_OF_ANY:
case CONDITIONAL_ACE_TOKEN_NOT_MEMBER_OF:
case CONDITIONAL_ACE_TOKEN_NOT_DEVICE_MEMBER_OF:
case CONDITIONAL_ACE_TOKEN_NOT_MEMBER_OF_ANY:
case CONDITIONAL_ACE_TOKEN_NOT_DEVICE_MEMBER_OF_ANY:
case CONDITIONAL_ACE_TOKEN_EQUAL:
case CONDITIONAL_ACE_TOKEN_NOT_EQUAL:
case CONDITIONAL_ACE_TOKEN_LESS_THAN:
case CONDITIONAL_ACE_TOKEN_LESS_OR_EQUAL:
case CONDITIONAL_ACE_TOKEN_GREATER_THAN:
case CONDITIONAL_ACE_TOKEN_GREATER_OR_EQUAL:
case CONDITIONAL_ACE_TOKEN_CONTAINS:
case CONDITIONAL_ACE_TOKEN_ANY_OF:
case CONDITIONAL_ACE_TOKEN_NOT_CONTAINS:
case CONDITIONAL_ACE_TOKEN_NOT_ANY_OF:
case CONDITIONAL_ACE_TOKEN_EXISTS:
case CONDITIONAL_ACE_TOKEN_NOT_EXISTS:
case CONDITIONAL_ACE_TOKEN_NOT:
case CONDITIONAL_ACE_TOKEN_AND:
case CONDITIONAL_ACE_TOKEN_OR:
/*
* All of these are simple operators that operate on
* the stack. We have already added the tok->type and
* there's nothing else to do.
*/
continue;
case CONDITIONAL_ACE_TOKEN_INT8:
case CONDITIONAL_ACE_TOKEN_INT16:
case CONDITIONAL_ACE_TOKEN_INT32:
case CONDITIONAL_ACE_TOKEN_INT64:
ok = check_integer_range(tok);
if (! ok) {
goto error;
}
consumed = push_integer(data + j,
alloc_size - j,
&tok->data.int64);
break;
case CONDITIONAL_ACE_LOCAL_ATTRIBUTE:
case CONDITIONAL_ACE_USER_ATTRIBUTE:
case CONDITIONAL_ACE_RESOURCE_ATTRIBUTE:
case CONDITIONAL_ACE_DEVICE_ATTRIBUTE:
case CONDITIONAL_ACE_TOKEN_UNICODE:
consumed = push_unicode(data + j,
alloc_size - j,
&tok->data.unicode);
break;
case CONDITIONAL_ACE_TOKEN_OCTET_STRING:
consumed = push_bytes(data + j,
alloc_size - j,
&tok->data.bytes);
break;
case CONDITIONAL_ACE_TOKEN_SID:
consumed = push_sid(data + j,
alloc_size - j,
&tok->data.sid);
break;
case CONDITIONAL_ACE_TOKEN_COMPOSITE:
consumed = push_composite(data + j,
alloc_size - j,
&tok->data.composite);
break;
default:
DBG_ERR("unknown token 0x%02x at position %zu\n",
tok->type, i);
goto error;
}
if (consumed == -1) {
DBG_ERR("program exceeds %zu bytes\n", alloc_size);
goto error;
}
j += consumed;
if (j >= alloc_size) {
DBG_ERR("program exceeds %zu bytes\n", alloc_size);
goto error;
}
}
/* align to a 4 byte boundary */
required_size = (j + 3) & ~((size_t)3);
if (required_size > alloc_size) {
DBG_ERR("program exceeds %zu bytes\n", alloc_size);
goto error;
}
while (j < required_size) {
data[j] = 0;
j++;
}
new_data = talloc_realloc(mem_ctx,
data,
uint8_t,
required_size);
if (new_data == NULL) {
goto error;
}
data = new_data;
(*dest).data = data;
(*dest).length = j;
return true;
error:
TALLOC_FREE(data);
return false;
}