/* 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 . */ #include "includes.h" #include "../librpc/gen_ndr/ndr_schannel.h" #undef DBGC_CLASS #define DBGC_CLASS DBGC_RPC_PARSE /** * Dump a prs to a file: from the current location through to the end. **/ void prs_dump(const char *name, int v, prs_struct *ps) { prs_dump_region(name, v, ps, ps->data_offset, ps->buffer_size); } /** * Dump from the start of the prs to the current location. **/ void prs_dump_before(const char *name, int v, prs_struct *ps) { prs_dump_region(name, v, ps, 0, ps->data_offset); } /** * Dump everything from the start of the prs up to the current location. **/ void prs_dump_region(const char *name, int v, prs_struct *ps, int from_off, int to_off) { int fd, i; char *fname = NULL; ssize_t sz; if (DEBUGLEVEL < 50) return; for (i=1;i<100;i++) { if (v != -1) { if (asprintf(&fname,"/tmp/%s_%d.%d.prs", name, v, i) < 0) { return; } } else { if (asprintf(&fname,"/tmp/%s.%d.prs", name, i) < 0) { return; } } fd = open(fname, O_WRONLY|O_CREAT|O_EXCL, 0644); if (fd != -1 || errno != EEXIST) break; } if (fd != -1) { sz = write(fd, ps->data_p + from_off, to_off - from_off); i = close(fd); if ( (sz != to_off-from_off) || (i != 0) ) { DEBUG(0,("Error writing/closing %s: %ld!=%ld %d\n", fname, (unsigned long)sz, (unsigned long)to_off-from_off, i )); } else { DEBUG(0,("created %s\n", fname)); } } SAFE_FREE(fname); } /******************************************************************* 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 malloc(). * * @return False if allocation fails, otherwise True. **/ bool prs_init(prs_struct *ps, uint32 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; if((ps->data_p = (char *)SMB_MALLOC((size_t)size)) == NULL) { DEBUG(0,("prs_init: malloc fail for %u bytes.\n", (unsigned int)size)); return False; } memset(ps->data_p, '\0', (size_t)size); 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 attached to the talloc context given by ps->mem_ctx. ********************************************************************/ void prs_mem_free(prs_struct *ps) { if(ps->is_dynamic) SAFE_FREE(ps->data_p); ps->is_dynamic = False; ps->buffer_size = 0; ps->data_offset = 0; } /******************************************************************* Clear the memory in a parse structure. ********************************************************************/ void prs_mem_clear(prs_struct *ps) { if (ps->buffer_size) memset(ps->data_p, '\0', (size_t)ps->buffer_size); } /******************************************************************* 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; } /******************************************************************* Hand some already allocated memory to a prs_struct. ********************************************************************/ void prs_give_memory(prs_struct *ps, char *buf, uint32 size, bool is_dynamic) { ps->is_dynamic = is_dynamic; ps->data_p = buf; ps->buffer_size = size; } /******************************************************************* Take some memory back from a prs_struct. ********************************************************************/ char *prs_take_memory(prs_struct *ps, uint32 *psize) { char *ret = ps->data_p; if(psize) *psize = ps->buffer_size; ps->is_dynamic = False; prs_mem_free(ps); return ret; } /******************************************************************* Set a prs_struct to exactly a given size. Will grow or tuncate if neccessary. ********************************************************************/ bool prs_set_buffer_size(prs_struct *ps, uint32 newsize) { if (newsize > ps->buffer_size) return prs_force_grow(ps, newsize - ps->buffer_size); if (newsize < ps->buffer_size) { ps->buffer_size = newsize; /* newsize == 0 acts as a free and set pointer to NULL */ if (newsize == 0) { SAFE_FREE(ps->data_p); } else { ps->data_p = (char *)SMB_REALLOC(ps->data_p, newsize); if (ps->data_p == NULL) { DEBUG(0,("prs_set_buffer_size: Realloc failure for size %u.\n", (unsigned int)newsize)); DEBUG(0,("prs_set_buffer_size: Reason %s\n",strerror(errno))); return False; } } } return True; } /******************************************************************* Attempt, if needed, to grow a data buffer. Also depends on the data stream mode (io). ********************************************************************/ bool prs_grow(prs_struct *ps, uint32 extra_space) { uint32 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); if((ps->data_p = (char *)SMB_MALLOC(new_size)) == NULL) { DEBUG(0,("prs_grow: Malloc failure for size %u.\n", (unsigned int)new_size)); return False; } memset(ps->data_p, '\0', (size_t)new_size ); } 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); if ((ps->data_p = (char *)SMB_REALLOC(ps->data_p, new_size)) == 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; } /******************************************************************* Attempt to force a data buffer to grow by len bytes. This is only used when appending more data onto a prs_struct when reading an rpc reply, before unmarshalling it. ********************************************************************/ bool prs_force_grow(prs_struct *ps, uint32 extra_space) { uint32 new_size = ps->buffer_size + extra_space; if(!UNMARSHALLING(ps) || !ps->is_dynamic) { DEBUG(0,("prs_force_grow: Buffer overflow - unable to expand buffer by %u bytes.\n", (unsigned int)extra_space)); return False; } if((ps->data_p = (char *)SMB_REALLOC(ps->data_p, new_size)) == NULL) { DEBUG(0,("prs_force_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 prs_data_size(prs_struct *ps) { return ps->buffer_size; } /******************************************************************* Fetch the current offset (external interface). ********************************************************************/ uint32 prs_offset(prs_struct *ps) { return ps->data_offset; } /******************************************************************* Set the current offset (external interface). ********************************************************************/ bool prs_set_offset(prs_struct *ps, uint32 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 one parse_struct into another. ********************************************************************/ bool prs_append_prs_data(prs_struct *dst, prs_struct *src) { if (prs_offset(src) == 0) return True; if(!prs_grow(dst, prs_offset(src))) return False; memcpy(&dst->data_p[dst->data_offset], src->data_p, (size_t)prs_offset(src)); dst->data_offset += prs_offset(src); return True; } /******************************************************************* Append some data from one parse_struct into another. ********************************************************************/ bool prs_append_some_data(prs_struct *dst, void *src_base, uint32_t start, uint32_t len) { if (len == 0) { return true; } if(!prs_grow(dst, len)) { return false; } memcpy(&dst->data_p[dst->data_offset], ((char *)src_base) + start, (size_t)len); dst->data_offset += len; return true; } bool prs_append_some_prs_data(prs_struct *dst, prs_struct *src, int32 start, uint32 len) { return prs_append_some_data(dst, src->data_p, start, len); } /******************************************************************* Append the data from a buffer into a parse_struct. ********************************************************************/ bool prs_copy_data_in(prs_struct *dst, const char *src, uint32 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; } /******************************************************************* Copy some data from a parse_struct into a buffer. ********************************************************************/ bool prs_copy_data_out(char *dst, prs_struct *src, uint32 len) { if (len == 0) return True; if(!prs_mem_get(src, len)) return False; memcpy(dst, &src->data_p[src->data_offset], (size_t)len); src->data_offset += len; return True; } /******************************************************************* Copy all the data from a parse_struct into a buffer. ********************************************************************/ bool prs_copy_all_data_out(char *dst, prs_struct *src) { uint32 len = prs_offset(src); if (!len) return True; prs_set_offset(src, 0); return prs_copy_data_out(dst, src, len); } /******************************************************************* Set the data as X-endian (external interface). ********************************************************************/ void prs_set_endian_data(prs_struct *ps, bool endian) { ps->bigendian_data = endian; } /******************************************************************* Align a the data_len to a multiple of align bytes - filling with zeros. ********************************************************************/ bool prs_align(prs_struct *ps) { uint32 mod = ps->data_offset & (ps->align-1); if (ps->align != 0 && mod != 0) { uint32 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 2 byte boundary *****************************************************************/ bool prs_align_uint16(prs_struct *ps) { bool ret; uint8 old_align = ps->align; ps->align = 2; ret = prs_align(ps); ps->align = old_align; return ret; } /****************************************************************** Align on a 8 byte boundary *****************************************************************/ bool prs_align_uint64(prs_struct *ps) { bool ret; uint8 old_align = ps->align; ps->align = 8; ret = prs_align(ps); ps->align = old_align; return ret; } /****************************************************************** Align on a specific byte boundary *****************************************************************/ bool prs_align_custom(prs_struct *ps, uint8 boundary) { bool ret; uint8 old_align = ps->align; ps->align = boundary; ret = prs_align(ps); ps->align = old_align; return ret; } /******************************************************************* Align only if required (for the unistr2 string mainly) ********************************************************************/ bool prs_align_needed(prs_struct *ps, uint32 needed) { if (needed==0) return True; else return prs_align(ps); } /******************************************************************* Ensure we can read/write to a given offset. ********************************************************************/ char *prs_mem_get(prs_struct *ps, uint32 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; } /******************************************************************* Force a prs_struct to be dynamic even when it's size is 0. ********************************************************************/ void prs_force_dynamic(prs_struct *ps) { ps->is_dynamic=True; } /******************************************************************* Associate a session key with a parse struct. ********************************************************************/ void prs_set_session_key(prs_struct *ps, const char sess_key[16]) { ps->sess_key = sess_key; } /******************************************************************* Stream a uint8. ********************************************************************/ bool prs_uint8(const char *name, prs_struct *ps, int depth, uint8 *data8) { char *q = prs_mem_get(ps, 1); if (q == NULL) return False; if (UNMARSHALLING(ps)) *data8 = CVAL(q,0); else SCVAL(q,0,*data8); DEBUGADD(5,("%s%04x %s: %02x\n", tab_depth(5,depth), ps->data_offset, name, *data8)); ps->data_offset += 1; return True; } /******************************************************************* Stream a uint16. ********************************************************************/ bool prs_uint16(const char *name, prs_struct *ps, int depth, uint16 *data16) { char *q = prs_mem_get(ps, sizeof(uint16)); 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); return True; } /******************************************************************* Stream a uint32. ********************************************************************/ bool prs_uint32(const char *name, prs_struct *ps, int depth, uint32 *data32) { char *q = prs_mem_get(ps, sizeof(uint32)); 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); return True; } /******************************************************************* Stream an int32. ********************************************************************/ bool prs_int32(const char *name, prs_struct *ps, int depth, int32 *data32) { char *q = prs_mem_get(ps, sizeof(int32)); if (q == NULL) return False; if (UNMARSHALLING(ps)) { if (ps->bigendian_data) *data32 = RIVALS(q,0); else *data32 = IVALS(q,0); } else { if (ps->bigendian_data) RSIVALS(q,0,*data32); else SIVALS(q,0,*data32); } DEBUGADD(5,("%s%04x %s: %08x\n", tab_depth(5,depth), ps->data_offset, name, *data32)); ps->data_offset += sizeof(int32); return True; } /******************************************************************* Stream a uint64_struct ********************************************************************/ bool prs_uint64(const char *name, prs_struct *ps, int depth, uint64 *data64) { if (UNMARSHALLING(ps)) { uint32 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 high = (*data64) >> 32, low = (*data64) & 0xFFFFFFFF; return prs_uint32(name, ps, depth+1, &low) && prs_uint32(name, ps, depth+1, &high); } } /******************************************************************* Stream a DCE error code ********************************************************************/ bool prs_dcerpc_status(const char *name, prs_struct *ps, int depth, NTSTATUS *status) { char *q = prs_mem_get(ps, sizeof(uint32)); if (q == NULL) return False; if (UNMARSHALLING(ps)) { if (ps->bigendian_data) *status = NT_STATUS(RIVAL(q,0)); else *status = NT_STATUS(IVAL(q,0)); } else { if (ps->bigendian_data) RSIVAL(q,0,NT_STATUS_V(*status)); else SIVAL(q,0,NT_STATUS_V(*status)); } DEBUGADD(5,("%s%04x %s: %s\n", tab_depth(5,depth), ps->data_offset, name, dcerpc_errstr(talloc_tos(), NT_STATUS_V(*status)))); ps->data_offset += sizeof(uint32); return True; } /****************************************************************** Stream an array of uint8s. Length is number of uint8s. ********************************************************************/ bool prs_uint8s(bool charmode, const char *name, prs_struct *ps, int depth, uint8 *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; } /****************************************************************** Stream an array of uint16s. Length is number of uint16s. ********************************************************************/ bool prs_uint16s(bool charmode, const char *name, prs_struct *ps, int depth, uint16 *data16s, int len) { int i; char *q = prs_mem_get(ps, len * sizeof(uint16)); if (q == NULL) return False; if (UNMARSHALLING(ps)) { if (ps->bigendian_data) { for (i = 0; i < len; i++) data16s[i] = RSVAL(q, 2*i); } else { for (i = 0; i < len; i++) data16s[i] = SVAL(q, 2*i); } } else { if (ps->bigendian_data) { for (i = 0; i < len; i++) RSSVAL(q, 2*i, data16s[i]); } else { for (i = 0; i < len; i++) SSVAL(q, 2*i, data16s[i]); } } DEBUGADD(5,("%s%04x %s: ", tab_depth(5,depth), ps->data_offset, name)); if (charmode) print_asc(5, (unsigned char*)data16s, 2*len); else { for (i = 0; i < len; i++) DEBUGADD(5,("%04x ", data16s[i])); } DEBUGADD(5,("\n")); ps->data_offset += (len * sizeof(uint16)); return True; } /****************************************************************** Stream an array of uint32s. Length is number of uint32s. ********************************************************************/ bool prs_uint32s(bool charmode, const char *name, prs_struct *ps, int depth, uint32 *data32s, int len) { int i; char *q = prs_mem_get(ps, len * sizeof(uint32)); if (q == NULL) return False; if (UNMARSHALLING(ps)) { if (ps->bigendian_data) { for (i = 0; i < len; i++) data32s[i] = RIVAL(q, 4*i); } else { for (i = 0; i < len; i++) data32s[i] = IVAL(q, 4*i); } } else { if (ps->bigendian_data) { for (i = 0; i < len; i++) RSIVAL(q, 4*i, data32s[i]); } else { for (i = 0; i < len; i++) SIVAL(q, 4*i, data32s[i]); } } DEBUGADD(5,("%s%04x %s: ", tab_depth(5,depth), ps->data_offset, name)); if (charmode) print_asc(5, (unsigned char*)data32s, 4*len); else { for (i = 0; i < len; i++) DEBUGADD(5,("%08x ", data32s[i])); } DEBUGADD(5,("\n")); ps->data_offset += (len * sizeof(uint32)); return True; } /******************************************************************* Stream a unicode null-terminated string. As the string is already in little-endian format then do it as a stream of bytes. ********************************************************************/ bool prs_unistr(const char *name, prs_struct *ps, int depth, UNISTR *str) { unsigned int len = 0; unsigned char *p = (unsigned char *)str->buffer; uint8 *start; char *q; uint32 max_len; uint16* ptr; if (MARSHALLING(ps)) { for(len = 0; str->buffer[len] != 0; len++) ; q = prs_mem_get(ps, (len+1)*2); if (q == NULL) return False; start = (uint8*)q; for(len = 0; str->buffer[len] != 0; len++) { if(ps->bigendian_data) { /* swap bytes - p is little endian, q is big endian. */ q[0] = (char)p[1]; q[1] = (char)p[0]; p += 2; q += 2; } else { q[0] = (char)p[0]; q[1] = (char)p[1]; p += 2; q += 2; } } /* * even if the string is 'empty' (only an \0 char) * at this point the leading \0 hasn't been parsed. * so parse it now */ q[0] = 0; q[1] = 0; q += 2; len++; DEBUGADD(5,("%s%04x %s: ", tab_depth(5,depth), ps->data_offset, name)); print_asc(5, (unsigned char*)start, 2*len); DEBUGADD(5, ("\n")); } else { /* unmarshalling */ uint32 alloc_len = 0; q = ps->data_p + prs_offset(ps); /* * Work out how much space we need and talloc it. */ max_len = (ps->buffer_size - ps->data_offset)/sizeof(uint16); /* the test of the value of *ptr helps to catch the circumstance where we have an emtpty (non-existent) string in the buffer */ for ( ptr = (uint16 *)q; *ptr++ && (alloc_len <= max_len); alloc_len++) /* do nothing */ ; if (alloc_len < max_len) alloc_len += 1; /* should we allocate anything at all? */ str->buffer = PRS_ALLOC_MEM(ps,uint16,alloc_len); if ((str->buffer == NULL) && (alloc_len > 0)) return False; p = (unsigned char *)str->buffer; len = 0; /* the (len < alloc_len) test is to prevent us from overwriting memory that is not ours...if we get that far, we have a non-null terminated string in the buffer and have messed up somewhere */ while ((len < alloc_len) && (*(uint16 *)q != 0)) { if(ps->bigendian_data) { /* swap bytes - q is big endian, p is little endian. */ p[0] = (unsigned char)q[1]; p[1] = (unsigned char)q[0]; p += 2; q += 2; } else { p[0] = (unsigned char)q[0]; p[1] = (unsigned char)q[1]; p += 2; q += 2; } len++; } if (len < alloc_len) { /* NULL terminate the UNISTR */ str->buffer[len++] = '\0'; } DEBUGADD(5,("%s%04x %s: ", tab_depth(5,depth), ps->data_offset, name)); print_asc(5, (unsigned char*)str->buffer, 2*len); DEBUGADD(5, ("\n")); } /* set the offset in the prs_struct; 'len' points to the terminiating NULL in the UNISTR so we need to go one more uint16 */ ps->data_offset += (len)*2; return True; } /******************************************************************* creates a new prs_struct containing a DATA_BLOB ********************************************************************/ bool prs_init_data_blob(prs_struct *prs, DATA_BLOB *blob, TALLOC_CTX *mem_ctx) { if (!prs_init( prs, RPC_MAX_PDU_FRAG_LEN, mem_ctx, MARSHALL )) return False; if (!prs_copy_data_in(prs, (char *)blob->data, blob->length)) return False; return True; } /******************************************************************* return the contents of a prs_struct in a DATA_BLOB ********************************************************************/ bool prs_data_blob(prs_struct *prs, DATA_BLOB *blob, TALLOC_CTX *mem_ctx) { blob->length = prs_data_size(prs); blob->data = (uint8 *)TALLOC_ZERO_SIZE(mem_ctx, blob->length); /* set the pointer at the end of the buffer */ prs_set_offset( prs, prs_data_size(prs) ); if (!prs_copy_all_data_out((char *)blob->data, prs)) return False; return True; }