/* * Unix SMB/CIFS implementation. * RPC Pipe client / server routines * Copyright (C) Andrew Tridgell 1992-1998, * Copyright (C) Luke Kenneth Casson Leighton 1996-1998, * Copyright (C) Paul Ashton 1998. * Copyright (C) Jeremy Allison 1999. * * 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 2 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, write to the Free Software * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include "includes.h" #undef DBGC_CLASS #define DBGC_CLASS DBGC_RPC_CLI extern struct pipe_id_info pipe_names[]; /******************************************************************** Rpc pipe call id. ********************************************************************/ static uint32 get_rpc_call_id(void) { static uint32 call_id = 0; return ++call_id; } /******************************************************************* Use SMBreadX to get rest of one fragment's worth of rpc data. ********************************************************************/ static BOOL rpc_read(struct cli_state *cli, prs_struct *rdata, uint32 data_to_read, uint32 *rdata_offset) { size_t size = (size_t)cli->max_recv_frag; int stream_offset = 0; int num_read; char *pdata; int extra_data_size = ((int)*rdata_offset) + ((int)data_to_read) - (int)prs_data_size(rdata); DEBUG(5,("rpc_read: data_to_read: %u rdata offset: %u extra_data_size: %d\n", (int)data_to_read, (unsigned int)*rdata_offset, extra_data_size)); /* * Grow the buffer if needed to accommodate the data to be read. */ if (extra_data_size > 0) { if(!prs_force_grow(rdata, (uint32)extra_data_size)) { DEBUG(0,("rpc_read: Failed to grow parse struct by %d bytes.\n", extra_data_size )); return False; } DEBUG(5,("rpc_read: grew buffer by %d bytes to %u\n", extra_data_size, prs_data_size(rdata) )); } pdata = prs_data_p(rdata) + *rdata_offset; do /* read data using SMBreadX */ { uint32 ecode; uint8 eclass; if (size > (size_t)data_to_read) size = (size_t)data_to_read; num_read = (int)cli_read(cli, cli->nt_pipe_fnum, pdata, (off_t)stream_offset, size); DEBUG(5,("rpc_read: num_read = %d, read offset: %d, to read: %d\n", num_read, stream_offset, data_to_read)); if (cli_is_dos_error(cli)) { cli_dos_error(cli, &eclass, &ecode); if (eclass != ERRDOS && ecode != ERRmoredata) { DEBUG(0,("rpc_read: Error %d/%u in cli_read\n", eclass, (unsigned int)ecode)); return False; } } data_to_read -= num_read; stream_offset += num_read; pdata += num_read; } while (num_read > 0 && data_to_read > 0); /* && err == (0x80000000 | STATUS_BUFFER_OVERFLOW)); */ /* * Update the current offset into rdata by the amount read. */ *rdata_offset += stream_offset; return True; } /**************************************************************************** Checks the header. This will set the endian bit in the rdata prs_struct. JRA. ****************************************************************************/ static BOOL rpc_check_hdr(prs_struct *rdata, RPC_HDR *rhdr, BOOL *first, BOOL *last, uint32 *len) { DEBUG(5,("rpc_check_hdr: rdata->data_size = %u\n", (uint32)prs_data_size(rdata) )); /* Next call sets endian bit. */ if(!smb_io_rpc_hdr("rpc_hdr ", rhdr, rdata, 0)) { DEBUG(0,("rpc_check_hdr: Failed to unmarshall RPC_HDR.\n")); return False; } if (prs_offset(rdata) != RPC_HEADER_LEN) { DEBUG(0,("rpc_check_hdr: offset was %x, should be %x.\n", prs_offset(rdata), RPC_HEADER_LEN)); return False; } (*first) = ((rhdr->flags & RPC_FLG_FIRST) != 0); (*last) = ((rhdr->flags & RPC_FLG_LAST ) != 0); (*len) = (uint32)rhdr->frag_len - prs_data_size(rdata); return (rhdr->pkt_type != RPC_FAULT); } static void NTLMSSPcalc_ap( struct cli_state *cli, unsigned char *data, uint32 len) { unsigned char *hash = cli->ntlmssp_hash; unsigned char index_i = hash[256]; unsigned char index_j = hash[257]; int ind; for( ind = 0; ind < len; ind++) { unsigned char tc; unsigned char t; index_i++; index_j += hash[index_i]; tc = hash[index_i]; hash[index_i] = hash[index_j]; hash[index_j] = tc; t = hash[index_i] + hash[index_j]; data[ind] = data[ind] ^ hash[t]; } hash[256] = index_i; hash[257] = index_j; } /**************************************************************************** Verify data on an rpc pipe. The VERIFY & SEAL code is only executed on packets that look like this : Request/Response PDU's look like the following... |<------------------PDU len----------------------------------------------->| |<-HDR_LEN-->|<--REQ LEN------>|.............|<-AUTH_HDRLEN->|<-AUTH_LEN-->| +------------+-----------------+-------------+---------------+-------------+ | RPC HEADER | REQ/RESP HEADER | DATA ...... | AUTH_HDR | AUTH DATA | +------------+-----------------+-------------+---------------+-------------+ Never on bind requests/responses. ****************************************************************************/ static BOOL rpc_auth_pipe(struct cli_state *cli, prs_struct *rdata, int len, int auth_len) { /* * The following is that length of the data we must sign or seal. * This doesn't include the RPC headers or the auth_len or the RPC_HDR_AUTH_LEN * preceeding the auth_data. */ int data_len = len - RPC_HEADER_LEN - RPC_HDR_RESP_LEN - RPC_HDR_AUTH_LEN - auth_len; /* * The start of the data to sign/seal is just after the RPC headers. */ char *reply_data = prs_data_p(rdata) + RPC_HEADER_LEN + RPC_HDR_REQ_LEN; BOOL auth_verify = ((cli->ntlmssp_srv_flgs & NTLMSSP_NEGOTIATE_SIGN) != 0); BOOL auth_seal = ((cli->ntlmssp_srv_flgs & NTLMSSP_NEGOTIATE_SEAL) != 0); BOOL auth_schannel = (cli->saved_netlogon_pipe_fnum != 0); DEBUG(5,("rpc_auth_pipe: len: %d auth_len: %d verify %s seal %s schannel %s\n", len, auth_len, BOOLSTR(auth_verify), BOOLSTR(auth_seal), BOOLSTR(auth_schannel))); /* * Unseal any sealed data in the PDU, not including the * 8 byte auth_header or the auth_data. */ if (auth_seal) { DEBUG(10,("rpc_auth_pipe: unseal\n")); dump_data(100, reply_data, data_len); NTLMSSPcalc_ap(cli, (uchar*)reply_data, data_len); dump_data(100, reply_data, data_len); } if (auth_verify || auth_seal) { RPC_HDR_AUTH rhdr_auth; prs_struct auth_req; char data[RPC_HDR_AUTH_LEN]; /* * We set dp to be the end of the packet, minus the auth_len * and the length of the header that preceeds the auth_data. */ char *dp = prs_data_p(rdata) + len - auth_len - RPC_HDR_AUTH_LEN; if(dp - prs_data_p(rdata) > prs_data_size(rdata)) { DEBUG(0,("rpc_auth_pipe: auth data > data size !\n")); return False; } memcpy(data, dp, sizeof(data)); prs_init(&auth_req , 0, cli->mem_ctx, UNMARSHALL); /* The endianness must be preserved... JRA. */ prs_set_endian_data(&auth_req, rdata->bigendian_data); prs_give_memory(&auth_req, data, RPC_HDR_AUTH_LEN, False); /* * Unmarshall the 8 byte auth_header that comes before the * auth data. */ if(!smb_io_rpc_hdr_auth("hdr_auth", &rhdr_auth, &auth_req, 0)) { DEBUG(0,("rpc_auth_pipe: unmarshalling RPC_HDR_AUTH failed.\n")); return False; } if (!rpc_hdr_auth_chk(&rhdr_auth)) { DEBUG(0,("rpc_auth_pipe: rpc_hdr_auth_chk failed.\n")); return False; } } /* * Now unseal and check the auth verifier in the auth_data at * then end of the packet. The 4 bytes skipped in the unseal * seem to be a buffer pointer preceeding the sealed data. */ if (auth_verify) { RPC_AUTH_NTLMSSP_CHK chk; uint32 crc32; prs_struct auth_verf; char data[RPC_AUTH_NTLMSSP_CHK_LEN]; char *dp = prs_data_p(rdata) + len - auth_len; if(dp - prs_data_p(rdata) > prs_data_size(rdata)) { DEBUG(0,("rpc_auth_pipe: auth data > data size !\n")); return False; } DEBUG(10,("rpc_auth_pipe: verify\n")); dump_data(100, dp, auth_len); NTLMSSPcalc_ap(cli, (uchar*)(dp+4), auth_len - 4); memcpy(data, dp, RPC_AUTH_NTLMSSP_CHK_LEN); dump_data(100, data, auth_len); prs_init(&auth_verf, 0, cli->mem_ctx, UNMARSHALL); /* The endinness must be preserved. JRA. */ prs_set_endian_data( &auth_verf, rdata->bigendian_data); prs_give_memory(&auth_verf, data, RPC_AUTH_NTLMSSP_CHK_LEN, False); if(!smb_io_rpc_auth_ntlmssp_chk("auth_sign", &chk, &auth_verf, 0)) { DEBUG(0,("rpc_auth_pipe: unmarshalling RPC_AUTH_NTLMSSP_CHK failed.\n")); return False; } crc32 = crc32_calc_buffer(reply_data, data_len); if (!rpc_auth_ntlmssp_chk(&chk, crc32 , cli->ntlmssp_seq_num)) { DEBUG(0,("rpc_auth_pipe: rpc_auth_ntlmssp_chk failed.\n")); return False; } cli->ntlmssp_seq_num++; } if (auth_schannel) { RPC_AUTH_NETSEC_CHK chk; char data[RPC_AUTH_NETSEC_CHK_LEN]; char *dp = prs_data_p(rdata) + len - auth_len; prs_struct auth_verf; if (auth_len != RPC_AUTH_NETSEC_CHK_LEN) { DEBUG(0,("rpc_auth_pipe: wrong schannel auth len %d\n", auth_len)); return False; } if (dp - prs_data_p(rdata) > prs_data_size(rdata)) { DEBUG(0,("rpc_auth_pipe: schannel auth data > data size !\n")); return False; } DEBUG(10,("rpc_auth_pipe: schannel verify netsec\n")); dump_data(100, dp, auth_len); memcpy(data, dp, sizeof(data)); dump_data(100, data, sizeof(data)); prs_init(&auth_verf, 0, cli->mem_ctx, UNMARSHALL); /* The endinness must be preserved. JRA. */ prs_set_endian_data( &auth_verf, rdata->bigendian_data); prs_give_memory(&auth_verf, data, RPC_AUTH_NETSEC_CHK_LEN, False); if (!smb_io_rpc_auth_netsec_chk("schannel_auth_sign", &chk, &auth_verf, 0)) { DEBUG(0, ("rpc_auth_pipe: schannel unmarshalling " "RPC_AUTH_NETSECK_CHK failed\n")); return False; } cli->auth_info.seq_num++; if (!netsec_decode(&cli->auth_info, &chk, reply_data, data_len)) { DEBUG(0, ("rpc_auth_pipe: Could not decode schannel\n")); return False; } } return True; } /**************************************************************************** Send data on an rpc pipe via trans, which *must* be the last fragment. receive response data from an rpc pipe, which may be large... Read the first fragment: unfortunately have to use SMBtrans for the first bit, then SMBreadX for subsequent bits. If first fragment received also wasn't the last fragment, continue getting fragments until we _do_ receive the last fragment. Request/Response PDU's look like the following... |<------------------PDU len----------------------------------------------->| |<-HDR_LEN-->|<--REQ LEN------>|.............|<-AUTH_HDRLEN->|<-AUTH_LEN-->| +------------+-----------------+-------------+---------------+-------------+ | RPC HEADER | REQ/RESP HEADER | DATA ...... | AUTH_HDR | AUTH DATA | +------------+-----------------+-------------+---------------+-------------+ Where the presence of the AUTH_HDR and AUTH are dependent on the signing & sealing being negotiated. ****************************************************************************/ static BOOL rpc_api_pipe(struct cli_state *cli, prs_struct *data, prs_struct *rdata) { uint32 len; char *rparam = NULL; uint32 rparam_len = 0; uint16 setup[2]; BOOL first = True; BOOL last = True; RPC_HDR rhdr; char *pdata = data ? prs_data_p(data) : NULL; uint32 data_len = data ? prs_offset(data) : 0; char *prdata = NULL; uint32 rdata_len = 0; uint32 current_offset = 0; uint32 max_data = cli->max_xmit_frag ? cli->max_xmit_frag : 1024; /* Create setup parameters - must be in native byte order. */ setup[0] = TRANSACT_DCERPCCMD; setup[1] = cli->nt_pipe_fnum; /* Pipe file handle. */ DEBUG(5,("rpc_api_pipe: fnum:%x\n", (int)cli->nt_pipe_fnum)); /* Send the RPC request and receive a response. For short RPC calls (about 1024 bytes or so) the RPC request and response appears in a SMBtrans request and response. Larger RPC responses are received further on. */ if (!cli_api_pipe(cli, "\\PIPE\\", setup, 2, 0, /* Setup, length, max */ NULL, 0, 0, /* Params, length, max */ pdata, data_len, max_data, /* data, length, max */ &rparam, &rparam_len, /* return params, len */ &prdata, &rdata_len)) /* return data, len */ { DEBUG(0, ("cli_pipe: return critical error. Error was %s\n", cli_errstr(cli))); return False; } /* Throw away returned params - we know we won't use them. */ SAFE_FREE(rparam); if (prdata == NULL) { DEBUG(0,("rpc_api_pipe: pipe %x failed to return data.\n", (int)cli->nt_pipe_fnum)); return False; } /* * Give this memory as dynamically allocated to the return parse * struct. */ prs_give_memory(rdata, prdata, rdata_len, True); current_offset = rdata_len; /* This next call sets the endian bit correctly in rdata. */ if (!rpc_check_hdr(rdata, &rhdr, &first, &last, &len)) { prs_mem_free(rdata); return False; } if (rhdr.pkt_type == RPC_BINDACK) { if (!last && !first) { DEBUG(5,("rpc_api_pipe: bug in server (AS/U?), setting fragment first/last ON.\n")); first = True; last = True; } } if (rhdr.pkt_type == RPC_RESPONSE) { RPC_HDR_RESP rhdr_resp; if(!smb_io_rpc_hdr_resp("rpc_hdr_resp", &rhdr_resp, rdata, 0)) { DEBUG(5,("rpc_api_pipe: failed to unmarshal RPC_HDR_RESP.\n")); prs_mem_free(rdata); return False; } } DEBUG(5,("rpc_api_pipe: len left: %u smbtrans read: %u\n", (unsigned int)len, (unsigned int)rdata_len )); /* check if data to be sent back was too large for one SMBtrans */ /* err status is only informational: the _real_ check is on the length */ if (len > 0) { /* || err == (0x80000000 | STATUS_BUFFER_OVERFLOW)) */ /* Read the remaining part of the first response fragment */ if (!rpc_read(cli, rdata, len, ¤t_offset)) { prs_mem_free(rdata); return False; } } /* * Now we have a complete PDU, check the auth struct if any was sent. */ if (rhdr.auth_len != 0) { if(!rpc_auth_pipe(cli, rdata, rhdr.frag_len, rhdr.auth_len)) return False; /* * Drop the auth footers from the current offset. * We need this if there are more fragments. * The auth footers consist of the auth_data and the * preceeding 8 byte auth_header. */ current_offset -= (rhdr.auth_len + RPC_HDR_AUTH_LEN); } /* * Only one rpc fragment, and it has been read. */ if (first && last) { DEBUG(6,("rpc_api_pipe: fragment first and last both set\n")); return True; } /* * Read more fragments using SMBreadX until we get one with the * last bit set. */ while (!last) { RPC_HDR_RESP rhdr_resp; int num_read; char hdr_data[RPC_HEADER_LEN+RPC_HDR_RESP_LEN]; prs_struct hps; uint8 eclass; uint32 ecode; /* * First read the header of the next PDU. */ prs_init(&hps, 0, cli->mem_ctx, UNMARSHALL); prs_give_memory(&hps, hdr_data, sizeof(hdr_data), False); num_read = cli_read(cli, cli->nt_pipe_fnum, hdr_data, 0, RPC_HEADER_LEN+RPC_HDR_RESP_LEN); if (cli_is_dos_error(cli)) { cli_dos_error(cli, &eclass, &ecode); if (eclass != ERRDOS && ecode != ERRmoredata) { DEBUG(0,("rpc_api_pipe: cli_read error : %d/%d\n", eclass, ecode)); return False; } } DEBUG(5,("rpc_api_pipe: read header (size:%d)\n", num_read)); if (num_read != RPC_HEADER_LEN+RPC_HDR_RESP_LEN) { DEBUG(0,("rpc_api_pipe: Error : requested %d bytes, got %d.\n", RPC_HEADER_LEN+RPC_HDR_RESP_LEN, num_read )); return False; } /* This call sets the endianness in hps. */ if (!rpc_check_hdr(&hps, &rhdr, &first, &last, &len)) return False; /* Ensure the endianness in rdata is set correctly - must be same as hps. */ if (hps.bigendian_data != rdata->bigendian_data) { DEBUG(0,("rpc_api_pipe: Error : Endianness changed from %s to %s\n", rdata->bigendian_data ? "big" : "little", hps.bigendian_data ? "big" : "little" )); return False; } if(!smb_io_rpc_hdr_resp("rpc_hdr_resp", &rhdr_resp, &hps, 0)) { DEBUG(0,("rpc_api_pipe: Error in unmarshalling RPC_HDR_RESP.\n")); return False; } if (first) { DEBUG(0,("rpc_api_pipe: secondary PDU rpc header has 'first' set !\n")); return False; } /* * Now read the rest of the PDU. */ if (!rpc_read(cli, rdata, len, ¤t_offset)) return False; /* * Verify any authentication footer. */ if (rhdr.auth_len != 0 ) { if(!rpc_auth_pipe(cli, rdata, rhdr.frag_len, rhdr.auth_len)) return False; /* * Drop the auth footers from the current offset. * The auth footers consist of the auth_data and the * preceeding 8 byte auth_header. * We need this if there are more fragments. */ current_offset -= (rhdr.auth_len + RPC_HDR_AUTH_LEN); } } return True; } /******************************************************************* creates a DCE/RPC bind request - initialises the parse structure. - dynamically allocates the header data structure - caller is expected to free the header data structure once used. ********************************************************************/ static BOOL create_rpc_bind_req(prs_struct *rpc_out, BOOL do_auth, BOOL do_netsec, uint32 rpc_call_id, RPC_IFACE *abstract, RPC_IFACE *transfer, const char *my_name, const char *domain, uint32 neg_flags) { RPC_HDR hdr; RPC_HDR_RB hdr_rb; char buffer[4096]; prs_struct auth_info; int auth_len = 0; prs_init(&auth_info, 0, prs_get_mem_context(rpc_out), MARSHALL); if (do_auth) { RPC_HDR_AUTH hdr_auth; RPC_AUTH_VERIFIER auth_verifier; RPC_AUTH_NTLMSSP_NEG ntlmssp_neg; /* * Create the auth structs we will marshall. */ init_rpc_hdr_auth(&hdr_auth, NTLMSSP_AUTH_TYPE, NTLMSSP_AUTH_LEVEL, 0x00, 1); init_rpc_auth_verifier(&auth_verifier, "NTLMSSP", NTLMSSP_NEGOTIATE); init_rpc_auth_ntlmssp_neg(&ntlmssp_neg, neg_flags, my_name, domain); /* * Use the 4k buffer to store the auth info. */ prs_give_memory( &auth_info, buffer, sizeof(buffer), False); /* * Now marshall the data into the temporary parse_struct. */ if(!smb_io_rpc_hdr_auth("hdr_auth", &hdr_auth, &auth_info, 0)) { DEBUG(0,("create_rpc_bind_req: failed to marshall RPC_HDR_AUTH.\n")); return False; } if(!smb_io_rpc_auth_verifier("auth_verifier", &auth_verifier, &auth_info, 0)) { DEBUG(0,("create_rpc_bind_req: failed to marshall RPC_AUTH_VERIFIER.\n")); return False; } if(!smb_io_rpc_auth_ntlmssp_neg("ntlmssp_neg", &ntlmssp_neg, &auth_info, 0)) { DEBUG(0,("create_rpc_bind_req: failed to marshall RPC_AUTH_NTLMSSP_NEG.\n")); return False; } /* Auth len in the rpc header doesn't include auth_header. */ auth_len = prs_offset(&auth_info) - RPC_HDR_AUTH_LEN; } if (do_netsec) { RPC_HDR_AUTH hdr_auth; RPC_AUTH_NETSEC_NEG netsec_neg; /* * Create the auth structs we will marshall. */ init_rpc_hdr_auth(&hdr_auth, NETSEC_AUTH_TYPE, NETSEC_AUTH_LEVEL, 0x00, 1); init_rpc_auth_netsec_neg(&netsec_neg, domain, my_name); /* * Use the 4k buffer to store the auth info. */ prs_give_memory( &auth_info, buffer, sizeof(buffer), False); /* * Now marshall the data into the temporary parse_struct. */ if(!smb_io_rpc_hdr_auth("hdr_auth", &hdr_auth, &auth_info, 0)) { DEBUG(0,("Failed to marshall RPC_HDR_AUTH.\n")); return False; } if(!smb_io_rpc_auth_netsec_neg("netsec_neg", &netsec_neg, &auth_info, 0)) { DEBUG(0,("Failed to marshall RPC_AUTH_NETSEC_NEG.\n")); return False; } /* Auth len in the rpc header doesn't include auth_header. */ auth_len = prs_offset(&auth_info) - RPC_HDR_AUTH_LEN; } /* create the request RPC_HDR */ init_rpc_hdr(&hdr, RPC_BIND, 0x3, rpc_call_id, RPC_HEADER_LEN + RPC_HDR_RB_LEN + prs_offset(&auth_info), auth_len); if(!smb_io_rpc_hdr("hdr" , &hdr, rpc_out, 0)) { DEBUG(0,("create_rpc_bind_req: failed to marshall RPC_HDR.\n")); return False; } /* create the bind request RPC_HDR_RB */ init_rpc_hdr_rb(&hdr_rb, MAX_PDU_FRAG_LEN, MAX_PDU_FRAG_LEN, 0x0, 0x1, 0x0, 0x1, abstract, transfer); /* Marshall the bind request data */ if(!smb_io_rpc_hdr_rb("", &hdr_rb, rpc_out, 0)) { DEBUG(0,("create_rpc_bind_req: failed to marshall RPC_HDR_RB.\n")); return False; } /* * Grow the outgoing buffer to store any auth info. */ if(hdr.auth_len != 0) { if(!prs_append_prs_data( rpc_out, &auth_info)) { DEBUG(0,("create_rpc_bind_req: failed to grow parse struct to add auth.\n")); return False; } } return True; } /******************************************************************* Creates a DCE/RPC bind authentication response. This is the packet that is sent back to the server once we have received a BIND-ACK, to finish the third leg of the authentication handshake. ********************************************************************/ static BOOL create_rpc_bind_resp(struct pwd_info *pwd, const char *domain, const char *user_name, const char *my_name, uint32 ntlmssp_cli_flgs, uint32 rpc_call_id, prs_struct *rpc_out) { unsigned char lm_owf[24]; unsigned char nt_owf[24]; RPC_HDR hdr; RPC_HDR_AUTHA hdr_autha; RPC_AUTH_VERIFIER auth_verifier; RPC_AUTH_NTLMSSP_RESP ntlmssp_resp; char buffer[4096]; prs_struct auth_info; /* * Marshall the variable length data into a temporary parse * struct, pointing into a 4k local buffer. */ prs_init(&auth_info, 0, prs_get_mem_context(rpc_out), MARSHALL); /* * Use the 4k buffer to store the auth info. */ prs_give_memory( &auth_info, buffer, sizeof(buffer), False); /* * Create the variable length auth_data. */ init_rpc_auth_verifier(&auth_verifier, "NTLMSSP", NTLMSSP_AUTH); pwd_get_lm_nt_owf(pwd, lm_owf, nt_owf); init_rpc_auth_ntlmssp_resp(&ntlmssp_resp, lm_owf, nt_owf, domain, user_name, my_name, ntlmssp_cli_flgs); /* * Marshall the variable length auth_data into a temp parse_struct. */ if(!smb_io_rpc_auth_verifier("auth_verifier", &auth_verifier, &auth_info, 0)) { DEBUG(0,("create_rpc_bind_resp: failed to marshall RPC_AUTH_VERIFIER.\n")); return False; } if(!smb_io_rpc_auth_ntlmssp_resp("ntlmssp_resp", &ntlmssp_resp, &auth_info, 0)) { DEBUG(0,("create_rpc_bind_resp: failed to marshall RPC_AUTH_NTLMSSP_RESP.\n")); return False; } /* Create the request RPC_HDR */ init_rpc_hdr(&hdr, RPC_BINDRESP, 0x0, rpc_call_id, RPC_HEADER_LEN + RPC_HDR_AUTHA_LEN + prs_offset(&auth_info), prs_offset(&auth_info) ); /* Marshall it. */ if(!smb_io_rpc_hdr("hdr", &hdr, rpc_out, 0)) { DEBUG(0,("create_rpc_bind_resp: failed to marshall RPC_HDR.\n")); return False; } /* Create the request RPC_HDR_AUTHA */ init_rpc_hdr_autha(&hdr_autha, MAX_PDU_FRAG_LEN, MAX_PDU_FRAG_LEN, NTLMSSP_AUTH_TYPE, NTLMSSP_AUTH_LEVEL, 0x00); if(!smb_io_rpc_hdr_autha("hdr_autha", &hdr_autha, rpc_out, 0)) { DEBUG(0,("create_rpc_bind_resp: failed to marshall RPC_HDR_AUTHA.\n")); return False; } /* * Append the auth data to the outgoing buffer. */ if(!prs_append_prs_data(rpc_out, &auth_info)) { DEBUG(0,("create_rpc_bind_req: failed to grow parse struct to add auth.\n")); return False; } return True; } /******************************************************************* Creates a DCE/RPC request. ********************************************************************/ static uint32 create_rpc_request(prs_struct *rpc_out, uint8 op_num, int data_len, int auth_len, uint8 flags, uint32 oldid, uint32 data_left) { uint32 alloc_hint; RPC_HDR hdr; RPC_HDR_REQ hdr_req; uint32 callid = oldid ? oldid : get_rpc_call_id(); DEBUG(5,("create_rpc_request: opnum: 0x%x data_len: 0x%x\n", op_num, data_len)); /* create the rpc header RPC_HDR */ init_rpc_hdr(&hdr, RPC_REQUEST, flags, callid, data_len, auth_len); /* * The alloc hint should be the amount of data, not including * RPC headers & footers. */ if (auth_len != 0) alloc_hint = data_len - RPC_HEADER_LEN - RPC_HDR_AUTH_LEN - auth_len; else alloc_hint = data_len - RPC_HEADER_LEN; DEBUG(10,("create_rpc_request: data_len: %x auth_len: %x alloc_hint: %x\n", data_len, auth_len, alloc_hint)); /* Create the rpc request RPC_HDR_REQ */ init_rpc_hdr_req(&hdr_req, alloc_hint, op_num); /* stream-time... */ if(!smb_io_rpc_hdr("hdr ", &hdr, rpc_out, 0)) return 0; if(!smb_io_rpc_hdr_req("hdr_req", &hdr_req, rpc_out, 0)) return 0; if (prs_offset(rpc_out) != RPC_HEADER_LEN + RPC_HDR_REQ_LEN) return 0; return callid; } /******************************************************************* Puts an NTLMSSP auth header into an rpc request. ********************************************************************/ static BOOL create_ntlmssp_auth_hdr(prs_struct *outgoing_packet, BOOL auth_verify) { RPC_HDR_AUTH hdr_auth; init_rpc_hdr_auth(&hdr_auth, NTLMSSP_AUTH_TYPE, NTLMSSP_AUTH_LEVEL, 0x08, (auth_verify ? 1 : 0)); if(!smb_io_rpc_hdr_auth("hdr_auth", &hdr_auth, outgoing_packet, 0)) { DEBUG(0,("create_auth_hdr:Failed to marshal RPC_HDR_AUTH.\n")); return False; } return True; } /******************************************************************* Puts a NETLOGON schannel auth header into an rpc request. ********************************************************************/ static BOOL create_netsec_auth_hdr(prs_struct *outgoing_packet, int padding) { RPC_HDR_AUTH hdr_auth; init_rpc_hdr_auth(&hdr_auth, NETSEC_AUTH_TYPE, NETSEC_AUTH_LEVEL, padding, 1); if(!smb_io_rpc_hdr_auth("hdr_auth", &hdr_auth, outgoing_packet, 0)) { DEBUG(0,("create_auth_hdr:Failed to marshal RPC_HDR_AUTH.\n")); return False; } return True; } /******************************************************************* Puts auth data into an rpc request. ********************************************************************/ static BOOL create_auth_data(struct cli_state *cli, uint32 crc32, prs_struct *outgoing_packet) { char *pdata_out = prs_data_p(outgoing_packet); RPC_AUTH_NTLMSSP_CHK chk; uint32 current_offset = prs_offset(outgoing_packet); init_rpc_auth_ntlmssp_chk(&chk, NTLMSSP_SIGN_VERSION, crc32, cli->ntlmssp_seq_num++); if(!smb_io_rpc_auth_ntlmssp_chk("auth_sign", &chk, outgoing_packet, 0)) { DEBUG(0,("create_auth_data: Failed to marshal RPC_AUTH_NTLMSSP_CHK.\n")); return False; } NTLMSSPcalc_ap(cli, (unsigned char*) &pdata_out[current_offset+4], RPC_AUTH_NTLMSSP_CHK_LEN - 4); return True; } /** * Send a request on an RPC pipe and get a response. * * @param data NDR contents of the request to be sent. * @param rdata Unparsed NDR response data. **/ BOOL rpc_api_pipe_req(struct cli_state *cli, uint8 op_num, prs_struct *data, prs_struct *rdata) { uint32 auth_len, max_data, data_left, data_sent; BOOL ret = False; BOOL auth_verify, auth_seal, auth_schannel; uint32 callid = 0; fstring dump_name; auth_verify = ((cli->ntlmssp_srv_flgs & NTLMSSP_NEGOTIATE_SIGN) != 0); auth_seal = ((cli->ntlmssp_srv_flgs & NTLMSSP_NEGOTIATE_SEAL) != 0); auth_schannel = (cli->saved_netlogon_pipe_fnum != 0); auth_len = 0; if (auth_verify) auth_len = RPC_AUTH_NTLMSSP_CHK_LEN; if (auth_schannel) auth_len = RPC_AUTH_NETSEC_CHK_LEN; /* * calc how much actual data we can send in a PDU fragment */ max_data = cli->max_xmit_frag - RPC_HEADER_LEN - RPC_HDR_REQ_LEN - (auth_verify ? RPC_HDR_AUTH_LEN : 0) - auth_len - 8; for (data_left = prs_offset(data), data_sent = 0; data_left > 0;) { prs_struct outgoing_packet; uint32 data_len, send_size; uint8 flags = 0; uint32 crc32 = 0; uint32 auth_padding = 0; RPC_AUTH_NETSEC_CHK verf; /* * how much will we send this time */ send_size = MIN(data_left, max_data); /* * NT expects the data that is sealed to be 8-byte * aligned. The padding must be encrypted as well and * taken into account when generating the * authentication verifier. The amount of padding must * be stored in the auth header. */ if (auth_schannel) auth_padding = 8 - (send_size & 7); data_len = RPC_HEADER_LEN + RPC_HDR_REQ_LEN + send_size + ((auth_verify|auth_schannel) ? RPC_HDR_AUTH_LEN : 0) + auth_len + auth_padding; /* * Malloc parse struct to hold it (and enough for alignments). */ if(!prs_init(&outgoing_packet, data_len + 8, cli->mem_ctx, MARSHALL)) { DEBUG(0,("rpc_api_pipe_req: Failed to malloc %u bytes.\n", (unsigned int)data_len )); return False; } if (data_left == prs_offset(data)) flags |= RPC_FLG_FIRST; if (data_left <= max_data) flags |= RPC_FLG_LAST; /* * Write out the RPC header and the request header. */ if(!(callid = create_rpc_request(&outgoing_packet, op_num, data_len, auth_len, flags, callid, data_left))) { DEBUG(0,("rpc_api_pipe_req: Failed to create RPC request.\n")); prs_mem_free(&outgoing_packet); return False; } /* * Seal the outgoing data if requested. */ if (auth_seal) { crc32 = crc32_calc_buffer(prs_data_p(data) + data_sent, send_size); NTLMSSPcalc_ap(cli, (unsigned char*)prs_data_p(data) + data_sent, send_size); } /* * Now copy the data into the outgoing packet. */ if (auth_schannel) { static const uchar netsec_sig[8] = NETSEC_SIGNATURE; static const uchar nullbytes[8] = { 0,0,0,0,0,0,0,0 }; uchar sign[8]; prs_struct netsec_blob; if ((cli->auth_info.seq_num & 1) != 0) { DEBUG(0,("SCHANNEL ERROR: seq_num must be even in client (seq_num=%d)\n", cli->auth_info.seq_num)); } DEBUG(10,("SCHANNEL seq_num=%d\n", cli->auth_info.seq_num)); RSIVAL(sign, 0, cli->auth_info.seq_num); SIVAL(sign, 4, 0x80); if (!prs_init(&netsec_blob, send_size+auth_padding, cli->mem_ctx, MARSHALL)) { DEBUG(0,("Could not malloc %u bytes", send_size+auth_padding)); prs_mem_free(&outgoing_packet); return False; } if(!prs_append_some_prs_data(&netsec_blob, data, data_sent, send_size)) { DEBUG(0,("Failed to append data to netsec blob\n")); prs_mem_free(&outgoing_packet); return False; } netsec_blob.align = 8; if (!prs_align(&netsec_blob)) { DEBUG(0,("Could not align netsec blob\n")); prs_mem_free(&outgoing_packet); return False; } init_rpc_auth_netsec_chk(&verf, netsec_sig, nullbytes, sign, nullbytes); netsec_encode(&cli->auth_info, &verf, prs_data_p(&netsec_blob), prs_data_size(&netsec_blob)); prs_append_prs_data(&outgoing_packet, &netsec_blob); prs_mem_free(&netsec_blob); cli->auth_info.seq_num++; } else { if(!prs_append_some_prs_data(&outgoing_packet, data, data_sent, send_size)) { DEBUG(0,("rpc_api_pipe_req: Failed to append " "data to outgoing packet.\n")); prs_mem_free(&outgoing_packet); return False; } } /* * Add a trailing auth_verifier if needed. */ if (auth_seal || auth_verify) { if(!create_ntlmssp_auth_hdr(&outgoing_packet, auth_verify)) { prs_mem_free(&outgoing_packet); return False; } } /* * Finally the auth data itself. */ if (auth_verify) { if (!create_auth_data(cli, crc32, &outgoing_packet)) { prs_mem_free(&outgoing_packet); return False; } } if (auth_schannel) { if (!create_netsec_auth_hdr(&outgoing_packet, auth_padding)) { prs_mem_free(&outgoing_packet); return False; } if (!smb_io_rpc_auth_netsec_chk("", &verf, &outgoing_packet, 0)) { prs_mem_free(&outgoing_packet); return False; } } DEBUG(100,("data_len: %x data_calc_len: %x\n", data_len, prs_offset(&outgoing_packet))); if (flags & RPC_FLG_LAST) ret = rpc_api_pipe(cli, &outgoing_packet, rdata); else { cli_write(cli, cli->nt_pipe_fnum, 0x0008, prs_data_p(&outgoing_packet), data_sent, data_len); } prs_mem_free(&outgoing_packet); data_sent += send_size; data_left -= send_size; } /* Also capture received data */ slprintf(dump_name, sizeof(dump_name) - 1, "reply_%s", cli_pipe_get_name(cli)); prs_dump(dump_name, op_num, rdata); return ret; } /**************************************************************************** Set the handle state. ****************************************************************************/ static BOOL rpc_pipe_set_hnd_state(struct cli_state *cli, const char *pipe_name, uint16 device_state) { BOOL state_set = False; char param[2]; uint16 setup[2]; /* only need 2 uint16 setup parameters */ char *rparam = NULL; char *rdata = NULL; uint32 rparam_len, rdata_len; if (pipe_name == NULL) return False; DEBUG(5,("Set Handle state Pipe[%x]: %s - device state:%x\n", cli->nt_pipe_fnum, pipe_name, device_state)); /* create parameters: device state */ SSVAL(param, 0, device_state); /* create setup parameters. */ setup[0] = 0x0001; setup[1] = cli->nt_pipe_fnum; /* pipe file handle. got this from an SMBOpenX. */ /* send the data on \PIPE\ */ if (cli_api_pipe(cli, "\\PIPE\\", setup, 2, 0, /* setup, length, max */ param, 2, 0, /* param, length, max */ NULL, 0, 1024, /* data, length, max */ &rparam, &rparam_len, /* return param, length */ &rdata, &rdata_len)) /* return data, length */ { DEBUG(5, ("Set Handle state: return OK\n")); state_set = True; } SAFE_FREE(rparam); SAFE_FREE(rdata); return state_set; } /**************************************************************************** check the rpc bind acknowledge response ****************************************************************************/ int get_pipe_index( const char *pipe_name ) { int pipe_idx = 0; while (pipe_names[pipe_idx].client_pipe != NULL) { if (strequal(pipe_name, pipe_names[pipe_idx].client_pipe )) return pipe_idx; pipe_idx++; }; return -1; } /**************************************************************************** check the rpc bind acknowledge response ****************************************************************************/ const char* get_pipe_name_from_index( const int pipe_index ) { if ( (pipe_index < 0) || (pipe_index >= PI_MAX_PIPES) ) return NULL; return pipe_names[pipe_index].client_pipe; } /**************************************************************************** Check to see if this pipe index points to one of the pipes only supported by Win2k ****************************************************************************/ BOOL is_win2k_pipe( const int pipe_idx ) { switch ( pipe_idx ) { case PI_LSARPC_DS: return True; } return False; } /**************************************************************************** check the rpc bind acknowledge response ****************************************************************************/ static BOOL valid_pipe_name(const int pipe_idx, RPC_IFACE *abstract, RPC_IFACE *transfer) { if ( pipe_idx >= PI_MAX_PIPES ) { DEBUG(0,("valid_pipe_name: Programmer error! Invalid pipe index [%d]\n", pipe_idx)); return False; } DEBUG(5,("Bind Abstract Syntax: ")); dump_data(5, (char*)&(pipe_names[pipe_idx].abstr_syntax), sizeof(pipe_names[pipe_idx].abstr_syntax)); DEBUG(5,("Bind Transfer Syntax: ")); dump_data(5, (char*)&(pipe_names[pipe_idx].trans_syntax), sizeof(pipe_names[pipe_idx].trans_syntax)); /* copy the required syntaxes out so we can do the right bind */ *transfer = pipe_names[pipe_idx].trans_syntax; *abstract = pipe_names[pipe_idx].abstr_syntax; return True; } /**************************************************************************** check the rpc bind acknowledge response ****************************************************************************/ static BOOL check_bind_response(RPC_HDR_BA *hdr_ba, const int pipe_idx, RPC_IFACE *transfer) { int i = 0; if ( hdr_ba->addr.len <= 0) return False; if ( !strequal(hdr_ba->addr.str, pipe_names[pipe_idx].server_pipe )) { DEBUG(4,("bind_rpc_pipe: pipe_name %s != expected pipe %s. oh well!\n", pipe_names[i].server_pipe ,hdr_ba->addr.str)); return False; } DEBUG(5,("bind_rpc_pipe: server pipe_name found: %s\n", pipe_names[i].server_pipe )); if (pipe_names[pipe_idx].server_pipe == NULL) { DEBUG(2,("bind_rpc_pipe: pipe name %s unsupported\n", hdr_ba->addr.str)); return False; } /* check the transfer syntax */ if ((hdr_ba->transfer.version != transfer->version) || (memcmp(&hdr_ba->transfer.uuid, &transfer->uuid, sizeof(transfer->uuid)) !=0)) { DEBUG(2,("bind_rpc_pipe: transfer syntax differs\n")); return False; } /* lkclXXXX only accept one result: check the result(s) */ if (hdr_ba->res.num_results != 0x1 || hdr_ba->res.result != 0) { DEBUG(2,("bind_rpc_pipe: bind denied results: %d reason: %x\n", hdr_ba->res.num_results, hdr_ba->res.reason)); } DEBUG(5,("bind_rpc_pipe: accepted!\n")); return True; } /**************************************************************************** Create and send the third packet in an RPC auth. ****************************************************************************/ static BOOL rpc_send_auth_reply(struct cli_state *cli, prs_struct *rdata, uint32 rpc_call_id) { RPC_HDR_AUTH rhdr_auth; RPC_AUTH_VERIFIER rhdr_verf; RPC_AUTH_NTLMSSP_CHAL rhdr_chal; char buffer[MAX_PDU_FRAG_LEN]; prs_struct rpc_out; ssize_t ret; unsigned char p24[24]; unsigned char lm_owf[24]; unsigned char lm_hash[16]; if(!smb_io_rpc_hdr_auth("", &rhdr_auth, rdata, 0)) { DEBUG(0,("rpc_send_auth_reply: Failed to unmarshall RPC_HDR_AUTH.\n")); return False; } if(!smb_io_rpc_auth_verifier("", &rhdr_verf, rdata, 0)) { DEBUG(0,("rpc_send_auth_reply: Failed to unmarshall RPC_AUTH_VERIFIER.\n")); return False; } if(!smb_io_rpc_auth_ntlmssp_chal("", &rhdr_chal, rdata, 0)) { DEBUG(0,("rpc_send_auth_reply: Failed to unmarshall RPC_AUTH_NTLMSSP_CHAL.\n")); return False; } cli->ntlmssp_cli_flgs = rhdr_chal.neg_flags; pwd_make_lm_nt_owf(&cli->pwd, rhdr_chal.challenge); prs_init(&rpc_out, 0, cli->mem_ctx, MARSHALL); prs_give_memory( &rpc_out, buffer, sizeof(buffer), False); create_rpc_bind_resp(&cli->pwd, cli->domain, cli->user_name, global_myname(), cli->ntlmssp_cli_flgs, rpc_call_id, &rpc_out); pwd_get_lm_nt_owf(&cli->pwd, lm_owf, NULL); pwd_get_lm_nt_16(&cli->pwd, lm_hash, NULL); NTLMSSPOWFencrypt(lm_hash, lm_owf, p24); { unsigned char j = 0; int ind; unsigned char k2[8]; memcpy(k2, p24, 5); k2[5] = 0xe5; k2[6] = 0x38; k2[7] = 0xb0; for (ind = 0; ind < 256; ind++) cli->ntlmssp_hash[ind] = (unsigned char)ind; for( ind = 0; ind < 256; ind++) { unsigned char tc; j += (cli->ntlmssp_hash[ind] + k2[ind%8]); tc = cli->ntlmssp_hash[ind]; cli->ntlmssp_hash[ind] = cli->ntlmssp_hash[j]; cli->ntlmssp_hash[j] = tc; } cli->ntlmssp_hash[256] = 0; cli->ntlmssp_hash[257] = 0; } memset((char *)lm_hash, '\0', sizeof(lm_hash)); if ((ret = cli_write(cli, cli->nt_pipe_fnum, 0x8, prs_data_p(&rpc_out), 0, (size_t)prs_offset(&rpc_out))) != (ssize_t)prs_offset(&rpc_out)) { DEBUG(0,("rpc_send_auth_reply: cli_write failed. Return was %d\n", (int)ret)); return False; } cli->ntlmssp_srv_flgs = rhdr_chal.neg_flags; return True; } /**************************************************************************** Do an rpc bind. ****************************************************************************/ static BOOL rpc_pipe_bind(struct cli_state *cli, int pipe_idx, const char *my_name, BOOL do_netsec) { RPC_IFACE abstract; RPC_IFACE transfer; prs_struct rpc_out; prs_struct rdata; BOOL do_auth = (cli->ntlmssp_cli_flgs != 0); uint32 rpc_call_id; char buffer[MAX_PDU_FRAG_LEN]; if ( (pipe_idx < 0) || (pipe_idx >= PI_MAX_PIPES) ) return False; DEBUG(5,("Bind RPC Pipe[%x]: %s\n", cli->nt_pipe_fnum, pipe_names[pipe_idx].client_pipe)); if (!valid_pipe_name(pipe_idx, &abstract, &transfer)) return False; prs_init(&rpc_out, 0, cli->mem_ctx, MARSHALL); /* * Use the MAX_PDU_FRAG_LEN buffer to store the bind request. */ prs_give_memory( &rpc_out, buffer, sizeof(buffer), False); rpc_call_id = get_rpc_call_id(); /* Marshall the outgoing data. */ create_rpc_bind_req(&rpc_out, do_auth, do_netsec, rpc_call_id, &abstract, &transfer, global_myname(), cli->domain, cli->ntlmssp_cli_flgs); /* Initialize the incoming data struct. */ prs_init(&rdata, 0, cli->mem_ctx, UNMARSHALL); /* send data on \PIPE\. receive a response */ if (rpc_api_pipe(cli, &rpc_out, &rdata)) { RPC_HDR_BA hdr_ba; DEBUG(5, ("rpc_pipe_bind: rpc_api_pipe returned OK.\n")); if(!smb_io_rpc_hdr_ba("", &hdr_ba, &rdata, 0)) { DEBUG(0,("rpc_pipe_bind: Failed to unmarshall RPC_HDR_BA.\n")); prs_mem_free(&rdata); return False; } if(!check_bind_response(&hdr_ba, pipe_idx, &transfer)) { DEBUG(2,("rpc_pipe_bind: check_bind_response failed.\n")); prs_mem_free(&rdata); return False; } cli->max_xmit_frag = hdr_ba.bba.max_tsize; cli->max_recv_frag = hdr_ba.bba.max_rsize; /* * If we're doing NTLMSSP auth we need to send a reply to * the bind-ack to complete the 3-way challenge response * handshake. */ if (do_auth && !rpc_send_auth_reply(cli, &rdata, rpc_call_id)) { DEBUG(0,("rpc_pipe_bind: rpc_send_auth_reply failed.\n")); prs_mem_free(&rdata); return False; } } prs_mem_free(&rdata); return True; } /**************************************************************************** Open a session. ****************************************************************************/ BOOL cli_nt_session_open(struct cli_state *cli, const int pipe_idx) { int fnum; /* At the moment we can't have more than one pipe open over a cli connection. )-: */ SMB_ASSERT(cli->nt_pipe_fnum == 0); /* The pipe index must fall within our array */ SMB_ASSERT((pipe_idx >= 0) && (pipe_idx < PI_MAX_PIPES)); if (cli->capabilities & CAP_NT_SMBS) { if ((fnum = cli_nt_create(cli, &pipe_names[pipe_idx].client_pipe[5], DESIRED_ACCESS_PIPE)) == -1) { DEBUG(0,("cli_nt_session_open: cli_nt_create failed on pipe %s to machine %s. Error was %s\n", &pipe_names[pipe_idx].client_pipe[5], cli->desthost, cli_errstr(cli))); return False; } cli->nt_pipe_fnum = (uint16)fnum; } else { if ((fnum = cli_open(cli, pipe_names[pipe_idx].client_pipe, O_CREAT|O_RDWR, DENY_NONE)) == -1) { DEBUG(0,("cli_nt_session_open: cli_open failed on pipe %s to machine %s. Error was %s\n", pipe_names[pipe_idx].client_pipe, cli->desthost, cli_errstr(cli))); return False; } cli->nt_pipe_fnum = (uint16)fnum; /**************** Set Named Pipe State ***************/ if (!rpc_pipe_set_hnd_state(cli, pipe_names[pipe_idx].client_pipe, 0x4300)) { DEBUG(0,("cli_nt_session_open: pipe hnd state failed. Error was %s\n", cli_errstr(cli))); cli_close(cli, cli->nt_pipe_fnum); return False; } } /******************* bind request on pipe *****************/ if (!rpc_pipe_bind(cli, pipe_idx, global_myname(), False)) { DEBUG(2,("cli_nt_session_open: rpc bind to %s failed\n", get_pipe_name_from_index(pipe_idx))); cli_close(cli, cli->nt_pipe_fnum); return False; } /* * Setup the remote server name prefixed by \ and the machine account name. */ fstrcpy(cli->srv_name_slash, "\\\\"); fstrcat(cli->srv_name_slash, cli->desthost); strupper(cli->srv_name_slash); fstrcpy(cli->clnt_name_slash, "\\\\"); fstrcat(cli->clnt_name_slash, global_myname()); strupper(cli->clnt_name_slash); fstrcpy(cli->mach_acct, global_myname()); fstrcat(cli->mach_acct, "$"); strupper(cli->mach_acct); /* Remember which pipe we're talking to */ fstrcpy(cli->pipe_name, pipe_names[pipe_idx].client_pipe); return True; } /**************************************************************************** Open a session to the NETLOGON pipe using schannel. ****************************************************************************/ BOOL cli_nt_open_netlogon(struct cli_state *cli, const char *trust_password, int sec_chan) { NTSTATUS result; uint32 neg_flags = 0x000001ff; int fnum; if (lp_client_schannel() != False) neg_flags |= NETLOGON_NEG_SCHANNEL; if (!cli_nt_session_open(cli, PI_NETLOGON)) { return False; } if (!secrets_init()) { DEBUG(3,("Failed to init secrets.tdb\n")); return False; } result = cli_nt_setup_creds(cli, sec_chan, trust_password, &neg_flags, 2); if (!NT_STATUS_IS_OK(result)) { cli_nt_session_close(cli); return False; } if ((lp_client_schannel() == True) && ((neg_flags & NETLOGON_NEG_SCHANNEL) == 0)) { DEBUG(3, ("Server did not offer schannel\n")); cli_nt_session_close(cli); return False; } if ((lp_client_schannel() == False) || ((neg_flags & NETLOGON_NEG_SCHANNEL) == 0)) { return True; } /* Server offered schannel, so try it. */ cli->auth_info.seq_num = 0; memcpy(cli->auth_info.sess_key, cli->sess_key, sizeof(cli->auth_info.sess_key)); cli->saved_netlogon_pipe_fnum = cli->nt_pipe_fnum; if (cli->capabilities & CAP_NT_SMBS) { /* The secure channel connection must be opened on the same session (TCP connection) as the one the challenge was requested from. */ if ((fnum = cli_nt_create(cli, PIPE_NETLOGON_PLAIN, DESIRED_ACCESS_PIPE)) == -1) { DEBUG(0,("cli_nt_create failed to %s machine %s. " "Error was %s\n", PIPE_NETLOGON, cli->desthost, cli_errstr(cli))); return False; } cli->nt_pipe_fnum = (uint16)fnum; } else { if ((fnum = cli_open(cli, PIPE_NETLOGON, O_CREAT|O_RDWR, DENY_NONE)) == -1) { DEBUG(0,("cli_open failed on pipe %s to machine %s. " "Error was %s\n", PIPE_NETLOGON, cli->desthost, cli_errstr(cli))); return False; } cli->nt_pipe_fnum = (uint16)fnum; /**************** Set Named Pipe State ***************/ if (!rpc_pipe_set_hnd_state(cli, PIPE_NETLOGON, 0x4300)) { DEBUG(0,("Pipe hnd state failed. Error was %s\n", cli_errstr(cli))); cli_close(cli, cli->nt_pipe_fnum); return False; } } if (!rpc_pipe_bind(cli, PI_NETLOGON, global_myname(), True)) { DEBUG(2,("rpc bind to %s failed\n", PIPE_NETLOGON)); cli_close(cli, cli->nt_pipe_fnum); return False; } return True; } const char *cli_pipe_get_name(struct cli_state *cli) { return cli->pipe_name; } /**************************************************************************** close the session ****************************************************************************/ void cli_nt_session_close(struct cli_state *cli) { if (cli->saved_netlogon_pipe_fnum != 0) { cli_close(cli, cli->saved_netlogon_pipe_fnum); cli->saved_netlogon_pipe_fnum = 0; } cli_close(cli, cli->nt_pipe_fnum); cli->nt_pipe_fnum = 0; }