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/*
Unix SMB/CIFS implementation.
Samba memory buffer functions
Copyright (C) Andrew Tridgell 1992-1997
Copyright (C) Luke Kenneth Casson Leighton 1996-1997
Copyright (C) Jeremy Allison 1999
Copyright (C) Andrew Bartlett 2003.
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 "includes.h"
#include "reg_parse_prs.h"
#include "rpc_dce.h"
#undef DBGC_CLASS
#define DBGC_CLASS DBGC_RPC_PARSE
/*******************************************************************
Debug output for parsing info
XXXX side-effect of this function is to increase the debug depth XXXX.
********************************************************************/
void prs_debug(prs_struct *ps, int depth, const char *desc, const char *fn_name)
{
DEBUG(5+depth, ("%s%06x %s %s\n", tab_depth(5+depth,depth), ps->data_offset, fn_name, desc));
}
/**
* Initialise an expandable parse structure.
*
* @param size Initial buffer size. If >0, a new buffer will be
* created with talloc().
*
* @return False if allocation fails, otherwise True.
**/
bool prs_init(prs_struct *ps, uint32_t size, TALLOC_CTX *ctx, bool io)
{
ZERO_STRUCTP(ps);
ps->io = io;
ps->bigendian_data = RPC_LITTLE_ENDIAN;
ps->align = RPC_PARSE_ALIGN;
ps->is_dynamic = False;
ps->data_offset = 0;
ps->buffer_size = 0;
ps->data_p = NULL;
ps->mem_ctx = ctx;
if (size != 0) {
ps->buffer_size = size;
ps->data_p = (char *)talloc_zero_size(ps->mem_ctx, size);
if(ps->data_p == NULL) {
DEBUG(0,("prs_init: talloc fail for %u bytes.\n", (unsigned int)size));
return False;
}
ps->is_dynamic = True; /* We own this memory. */
} else if (MARSHALLING(ps)) {
/* If size is zero and we're marshalling we should allocate memory on demand. */
ps->is_dynamic = True;
}
return True;
}
/*******************************************************************
Delete the memory in a parse structure - if we own it.
NOTE: Contrary to the somewhat confusing naming, this function is not
intended for freeing memory allocated by prs_alloc_mem().
That memory is also attached to the talloc context given by
ps->mem_ctx, but is only freed when that talloc context is
freed. prs_mem_free() is used to delete "dynamic" memory
allocated in marshalling/unmarshalling.
********************************************************************/
void prs_mem_free(prs_struct *ps)
{
if(ps->is_dynamic) {
TALLOC_FREE(ps->data_p);
}
ps->is_dynamic = False;
ps->buffer_size = 0;
ps->data_offset = 0;
}
/*******************************************************************
Allocate memory when unmarshalling... Always zero clears.
********************************************************************/
#if defined(PARANOID_MALLOC_CHECKER)
char *prs_alloc_mem_(prs_struct *ps, size_t size, unsigned int count)
#else
char *prs_alloc_mem(prs_struct *ps, size_t size, unsigned int count)
#endif
{
char *ret = NULL;
if (size && count) {
/* We can't call the type-safe version here. */
ret = (char *)_talloc_zero_array(ps->mem_ctx, size, count,
"parse_prs");
}
return ret;
}
/*******************************************************************
Return the current talloc context we're using.
********************************************************************/
TALLOC_CTX *prs_get_mem_context(prs_struct *ps)
{
return ps->mem_ctx;
}
/*******************************************************************
Attempt, if needed, to grow a data buffer.
Also depends on the data stream mode (io).
********************************************************************/
bool prs_grow(prs_struct *ps, uint32_t extra_space)
{
uint32_t new_size;
ps->grow_size = MAX(ps->grow_size, ps->data_offset + extra_space);
if(ps->data_offset + extra_space <= ps->buffer_size)
return True;
/*
* We cannot grow the buffer if we're not reading
* into the prs_struct, or if we don't own the memory.
*/
if(UNMARSHALLING(ps) || !ps->is_dynamic) {
DEBUG(0,("prs_grow: Buffer overflow - unable to expand buffer by %u bytes.\n",
(unsigned int)extra_space));
return False;
}
/*
* Decide how much extra space we really need.
*/
extra_space -= (ps->buffer_size - ps->data_offset);
if(ps->buffer_size == 0) {
/*
* Start with 128 bytes (arbitrary value), enough for small rpc
* requests
*/
new_size = MAX(128, extra_space);
ps->data_p = (char *)talloc_zero_size(ps->mem_ctx, new_size);
if(ps->data_p == NULL) {
DEBUG(0,("prs_grow: talloc failure for size %u.\n", (unsigned int)new_size));
return False;
}
} else {
/*
* If the current buffer size is bigger than the space needed,
* just double it, else add extra_space. Always keep 64 bytes
* more, so that after we added a large blob we don't have to
* realloc immediately again.
*/
new_size = MAX(ps->buffer_size*2,
ps->buffer_size + extra_space + 64);
ps->data_p = talloc_realloc(ps->mem_ctx,
ps->data_p,
char,
new_size);
if (ps->data_p == NULL) {
DEBUG(0,("prs_grow: Realloc failure for size %u.\n",
(unsigned int)new_size));
return False;
}
memset(&ps->data_p[ps->buffer_size], '\0', (size_t)(new_size - ps->buffer_size));
}
ps->buffer_size = new_size;
return True;
}
/*******************************************************************
Get the data pointer (external interface).
********************************************************************/
char *prs_data_p(prs_struct *ps)
{
return ps->data_p;
}
/*******************************************************************
Get the current data size (external interface).
********************************************************************/
uint32_t prs_data_size(prs_struct *ps)
{
return ps->buffer_size;
}
/*******************************************************************
Fetch the current offset (external interface).
********************************************************************/
uint32_t prs_offset(prs_struct *ps)
{
return ps->data_offset;
}
/*******************************************************************
Set the current offset (external interface).
********************************************************************/
bool prs_set_offset(prs_struct *ps, uint32_t offset)
{
if ((offset > ps->data_offset)
&& !prs_grow(ps, offset - ps->data_offset)) {
return False;
}
ps->data_offset = offset;
return True;
}
/*******************************************************************
Append the data from a buffer into a parse_struct.
********************************************************************/
bool prs_copy_data_in(prs_struct *dst, const char *src, uint32_t len)
{
if (len == 0)
return True;
if(!prs_grow(dst, len))
return False;
memcpy(&dst->data_p[dst->data_offset], src, (size_t)len);
dst->data_offset += len;
return True;
}
/*******************************************************************
Align a the data_len to a multiple of align bytes - filling with
zeros.
********************************************************************/
bool prs_align(prs_struct *ps)
{
uint32_t mod = ps->data_offset & (ps->align-1);
if (ps->align != 0 && mod != 0) {
uint32_t extra_space = (ps->align - mod);
if(!prs_grow(ps, extra_space))
return False;
memset(&ps->data_p[ps->data_offset], '\0', (size_t)extra_space);
ps->data_offset += extra_space;
}
return True;
}
/******************************************************************
Align on a 8 byte boundary
*****************************************************************/
bool prs_align_uint64(prs_struct *ps)
{
bool ret;
uint8_t old_align = ps->align;
ps->align = 8;
ret = prs_align(ps);
ps->align = old_align;
return ret;
}
/*******************************************************************
Ensure we can read/write to a given offset.
********************************************************************/
char *prs_mem_get(prs_struct *ps, uint32_t extra_size)
{
if(UNMARSHALLING(ps)) {
/*
* If reading, ensure that we can read the requested size item.
*/
if (ps->data_offset + extra_size > ps->buffer_size) {
DEBUG(0,("prs_mem_get: reading data of size %u would overrun "
"buffer by %u bytes.\n",
(unsigned int)extra_size,
(unsigned int)(ps->data_offset + extra_size - ps->buffer_size) ));
return NULL;
}
} else {
/*
* Writing - grow the buffer if needed.
*/
if(!prs_grow(ps, extra_size))
return NULL;
}
return &ps->data_p[ps->data_offset];
}
/*******************************************************************
Change the struct type.
********************************************************************/
void prs_switch_type(prs_struct *ps, bool io)
{
if ((ps->io ^ io) == True)
ps->io=io;
}
/*******************************************************************
Stream a uint16.
********************************************************************/
bool prs_uint16(const char *name, prs_struct *ps, int depth, uint16_t *data16)
{
char *q = prs_mem_get(ps, sizeof(uint16_t));
if (q == NULL)
return False;
if (UNMARSHALLING(ps)) {
if (ps->bigendian_data)
*data16 = RSVAL(q,0);
else
*data16 = SVAL(q,0);
} else {
if (ps->bigendian_data)
RSSVAL(q,0,*data16);
else
SSVAL(q,0,*data16);
}
DEBUGADD(5,("%s%04x %s: %04x\n", tab_depth(5,depth), ps->data_offset, name, *data16));
ps->data_offset += sizeof(uint16_t);
return True;
}
/*******************************************************************
Stream a uint32.
********************************************************************/
bool prs_uint32(const char *name, prs_struct *ps, int depth, uint32_t *data32)
{
char *q = prs_mem_get(ps, sizeof(uint32_t));
if (q == NULL)
return False;
if (UNMARSHALLING(ps)) {
if (ps->bigendian_data)
*data32 = RIVAL(q,0);
else
*data32 = IVAL(q,0);
} else {
if (ps->bigendian_data)
RSIVAL(q,0,*data32);
else
SIVAL(q,0,*data32);
}
DEBUGADD(5,("%s%04x %s: %08x\n", tab_depth(5,depth), ps->data_offset, name, *data32));
ps->data_offset += sizeof(uint32_t);
return True;
}
/*******************************************************************
Stream a uint64_struct
********************************************************************/
bool prs_uint64(const char *name, prs_struct *ps, int depth, uint64_t *data64)
{
if (UNMARSHALLING(ps)) {
uint32_t high, low;
if (!prs_uint32(name, ps, depth+1, &low))
return False;
if (!prs_uint32(name, ps, depth+1, &high))
return False;
*data64 = ((uint64_t)high << 32) + low;
return True;
} else {
uint32_t high = (*data64) >> 32, low = (*data64) & 0xFFFFFFFF;
return prs_uint32(name, ps, depth+1, &low) &&
prs_uint32(name, ps, depth+1, &high);
}
}
/******************************************************************
Stream an array of uint8s. Length is number of uint8s.
********************************************************************/
bool prs_uint8s(bool charmode, const char *name, prs_struct *ps, int depth, uint8_t *data8s, int len)
{
int i;
char *q = prs_mem_get(ps, len);
if (q == NULL)
return False;
if (UNMARSHALLING(ps)) {
for (i = 0; i < len; i++)
data8s[i] = CVAL(q,i);
} else {
for (i = 0; i < len; i++)
SCVAL(q, i, data8s[i]);
}
DEBUGADD(5,("%s%04x %s: ", tab_depth(5,depth), ps->data_offset ,name));
if (charmode)
print_asc(5, (unsigned char*)data8s, len);
else {
for (i = 0; i < len; i++)
DEBUGADD(5,("%02x ", data8s[i]));
}
DEBUGADD(5,("\n"));
ps->data_offset += len;
return True;
}
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