/* * Unix SMB/CIFS implementation. * RPC Pipe client / server routines * Almost completely rewritten by (C) Jeremy Allison 2005. * * 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. */ /* this module apparently provides an implementation of DCE/RPC over a * named pipe (IPC$ connection using SMBtrans). details of DCE/RPC * documentation are available (in on-line form) from the X-Open group. * * this module should provide a level of abstraction between SMB * and DCE/RPC, while minimising the amount of mallocs, unnecessary * data copies, and network traffic. * */ #include "includes.h" extern struct pipe_id_info pipe_names[]; extern struct current_user current_user; #undef DBGC_CLASS #define DBGC_CLASS DBGC_RPC_SRV static void free_pipe_ntlmssp_auth_data(struct pipe_auth_data *auth) { AUTH_NTLMSSP_STATE *a = auth->a_u.auth_ntlmssp_state; if (a) { auth_ntlmssp_end(&a); } auth->a_u.auth_ntlmssp_state = NULL; } /******************************************************************* Generate the next PDU to be returned from the data in p->rdata. Handle NTLMSSP. ********************************************************************/ static BOOL create_next_pdu_ntlmssp(pipes_struct *p) { RPC_HDR_RESP hdr_resp; uint32 ss_padding_len = 0; uint32 data_space_available; uint32 data_len_left; uint32 data_len; prs_struct outgoing_pdu; NTSTATUS status; DATA_BLOB auth_blob; RPC_HDR_AUTH auth_info; uint8 auth_type, auth_level; AUTH_NTLMSSP_STATE *a = p->auth.a_u.auth_ntlmssp_state; /* * If we're in the fault state, keep returning fault PDU's until * the pipe gets closed. JRA. */ if(p->fault_state) { setup_fault_pdu(p, NT_STATUS(DCERPC_FAULT_OP_RNG_ERROR)); return True; } memset((char *)&hdr_resp, '\0', sizeof(hdr_resp)); /* Change the incoming request header to a response. */ p->hdr.pkt_type = RPC_RESPONSE; /* Set up rpc header flags. */ if (p->out_data.data_sent_length == 0) { p->hdr.flags = RPC_FLG_FIRST; } else { p->hdr.flags = 0; } /* * Work out how much we can fit in a single PDU. */ data_len_left = prs_offset(&p->out_data.rdata) - p->out_data.data_sent_length; /* * Ensure there really is data left to send. */ if(!data_len_left) { DEBUG(0,("create_next_pdu_ntlmssp: no data left to send !\n")); return False; } data_space_available = sizeof(p->out_data.current_pdu) - RPC_HEADER_LEN - RPC_HDR_RESP_LEN - RPC_HDR_AUTH_LEN - NTLMSSP_SIG_SIZE; /* * The amount we send is the minimum of the available * space and the amount left to send. */ data_len = MIN(data_len_left, data_space_available); /* * Set up the alloc hint. This should be the data left to * send. */ hdr_resp.alloc_hint = data_len_left; /* * Work out if this PDU will be the last. */ if(p->out_data.data_sent_length + data_len >= prs_offset(&p->out_data.rdata)) { p->hdr.flags |= RPC_FLG_LAST; if (data_len_left % 8) { ss_padding_len = 8 - (data_len_left % 8); DEBUG(10,("create_next_pdu_ntlmssp: adding sign/seal padding of %u\n", ss_padding_len )); } } /* * Set up the header lengths. */ p->hdr.frag_len = RPC_HEADER_LEN + RPC_HDR_RESP_LEN + data_len + ss_padding_len + RPC_HDR_AUTH_LEN + NTLMSSP_SIG_SIZE; p->hdr.auth_len = NTLMSSP_SIG_SIZE; /* * Init the parse struct to point at the outgoing * data. */ prs_init( &outgoing_pdu, 0, p->mem_ctx, MARSHALL); prs_give_memory( &outgoing_pdu, (char *)p->out_data.current_pdu, sizeof(p->out_data.current_pdu), False); /* Store the header in the data stream. */ if(!smb_io_rpc_hdr("hdr", &p->hdr, &outgoing_pdu, 0)) { DEBUG(0,("create_next_pdu_ntlmssp: failed to marshall RPC_HDR.\n")); prs_mem_free(&outgoing_pdu); return False; } if(!smb_io_rpc_hdr_resp("resp", &hdr_resp, &outgoing_pdu, 0)) { DEBUG(0,("create_next_pdu_ntlmssp: failed to marshall RPC_HDR_RESP.\n")); prs_mem_free(&outgoing_pdu); return False; } /* Copy the data into the PDU. */ if(!prs_append_some_prs_data(&outgoing_pdu, &p->out_data.rdata, p->out_data.data_sent_length, data_len)) { DEBUG(0,("create_next_pdu_ntlmssp: failed to copy %u bytes of data.\n", (unsigned int)data_len)); prs_mem_free(&outgoing_pdu); return False; } /* Copy the sign/seal padding data. */ if (ss_padding_len) { char pad[8]; memset(pad, '\0', 8); if (!prs_copy_data_in(&outgoing_pdu, pad, ss_padding_len)) { DEBUG(0,("create_next_pdu_ntlmssp: failed to add %u bytes of pad data.\n", (unsigned int)ss_padding_len)); prs_mem_free(&outgoing_pdu); return False; } } /* Now write out the auth header and null blob. */ if (p->auth.auth_type == PIPE_AUTH_TYPE_NTLMSSP) { auth_type = RPC_NTLMSSP_AUTH_TYPE; } else { auth_type = RPC_SPNEGO_AUTH_TYPE; } if (p->auth.auth_level == PIPE_AUTH_LEVEL_PRIVACY) { auth_level = RPC_AUTH_LEVEL_PRIVACY; } else { auth_level = RPC_AUTH_LEVEL_INTEGRITY; } init_rpc_hdr_auth(&auth_info, auth_type, auth_level, ss_padding_len, 1 /* context id. */); if(!smb_io_rpc_hdr_auth("hdr_auth", &auth_info, &outgoing_pdu, 0)) { DEBUG(0,("create_next_pdu_ntlmssp: failed to marshall RPC_HDR_AUTH.\n")); prs_mem_free(&outgoing_pdu); return False; } /* Generate the sign blob. */ switch (p->auth.auth_level) { case PIPE_AUTH_LEVEL_PRIVACY: /* Data portion is encrypted. */ status = ntlmssp_seal_packet(a->ntlmssp_state, (unsigned char *)prs_data_p(&outgoing_pdu) + RPC_HEADER_LEN + RPC_HDR_RESP_LEN, data_len + ss_padding_len, (unsigned char *)prs_data_p(&outgoing_pdu), (size_t)prs_offset(&outgoing_pdu), &auth_blob); if (!NT_STATUS_IS_OK(status)) { data_blob_free(&auth_blob); prs_mem_free(&outgoing_pdu); return False; } break; case PIPE_AUTH_LEVEL_INTEGRITY: /* Data is signed. */ status = ntlmssp_sign_packet(a->ntlmssp_state, (unsigned char *)prs_data_p(&outgoing_pdu) + RPC_HEADER_LEN + RPC_HDR_RESP_LEN, data_len + ss_padding_len, (unsigned char *)prs_data_p(&outgoing_pdu), (size_t)prs_offset(&outgoing_pdu), &auth_blob); if (!NT_STATUS_IS_OK(status)) { data_blob_free(&auth_blob); prs_mem_free(&outgoing_pdu); return False; } break; default: prs_mem_free(&outgoing_pdu); return False; } /* Append the auth blob. */ if (!prs_copy_data_in(&outgoing_pdu, (char *)auth_blob.data, NTLMSSP_SIG_SIZE)) { DEBUG(0,("create_next_pdu_ntlmssp: failed to add %u bytes auth blob.\n", (unsigned int)NTLMSSP_SIG_SIZE)); data_blob_free(&auth_blob); prs_mem_free(&outgoing_pdu); return False; } data_blob_free(&auth_blob); /* * Setup the counts for this PDU. */ p->out_data.data_sent_length += data_len; p->out_data.current_pdu_len = p->hdr.frag_len; p->out_data.current_pdu_sent = 0; prs_mem_free(&outgoing_pdu); return True; } /******************************************************************* Generate the next PDU to be returned from the data in p->rdata. Return an schannel authenticated fragment. ********************************************************************/ static BOOL create_next_pdu_schannel(pipes_struct *p) { RPC_HDR_RESP hdr_resp; uint32 ss_padding_len = 0; uint32 data_len; uint32 data_space_available; uint32 data_len_left; prs_struct outgoing_pdu; uint32 data_pos; /* * If we're in the fault state, keep returning fault PDU's until * the pipe gets closed. JRA. */ if(p->fault_state) { setup_fault_pdu(p, NT_STATUS(DCERPC_FAULT_OP_RNG_ERROR)); return True; } memset((char *)&hdr_resp, '\0', sizeof(hdr_resp)); /* Change the incoming request header to a response. */ p->hdr.pkt_type = RPC_RESPONSE; /* Set up rpc header flags. */ if (p->out_data.data_sent_length == 0) { p->hdr.flags = RPC_FLG_FIRST; } else { p->hdr.flags = 0; } /* * Work out how much we can fit in a single PDU. */ data_len_left = prs_offset(&p->out_data.rdata) - p->out_data.data_sent_length; /* * Ensure there really is data left to send. */ if(!data_len_left) { DEBUG(0,("create_next_pdu_schannel: no data left to send !\n")); return False; } data_space_available = sizeof(p->out_data.current_pdu) - RPC_HEADER_LEN - RPC_HDR_RESP_LEN - RPC_HDR_AUTH_LEN - RPC_AUTH_SCHANNEL_SIGN_OR_SEAL_CHK_LEN; /* * The amount we send is the minimum of the available * space and the amount left to send. */ data_len = MIN(data_len_left, data_space_available); /* * Set up the alloc hint. This should be the data left to * send. */ hdr_resp.alloc_hint = data_len_left; /* * Work out if this PDU will be the last. */ if(p->out_data.data_sent_length + data_len >= prs_offset(&p->out_data.rdata)) { p->hdr.flags |= RPC_FLG_LAST; if (data_len_left % 8) { ss_padding_len = 8 - (data_len_left % 8); DEBUG(10,("create_next_pdu_schannel: adding sign/seal padding of %u\n", ss_padding_len )); } } p->hdr.frag_len = RPC_HEADER_LEN + RPC_HDR_RESP_LEN + data_len + ss_padding_len + RPC_HDR_AUTH_LEN + RPC_AUTH_SCHANNEL_SIGN_OR_SEAL_CHK_LEN; p->hdr.auth_len = RPC_AUTH_SCHANNEL_SIGN_OR_SEAL_CHK_LEN; /* * Init the parse struct to point at the outgoing * data. */ prs_init( &outgoing_pdu, 0, p->mem_ctx, MARSHALL); prs_give_memory( &outgoing_pdu, (char *)p->out_data.current_pdu, sizeof(p->out_data.current_pdu), False); /* Store the header in the data stream. */ if(!smb_io_rpc_hdr("hdr", &p->hdr, &outgoing_pdu, 0)) { DEBUG(0,("create_next_pdu_schannel: failed to marshall RPC_HDR.\n")); prs_mem_free(&outgoing_pdu); return False; } if(!smb_io_rpc_hdr_resp("resp", &hdr_resp, &outgoing_pdu, 0)) { DEBUG(0,("create_next_pdu_schannel: failed to marshall RPC_HDR_RESP.\n")); prs_mem_free(&outgoing_pdu); return False; } /* Store the current offset. */ data_pos = prs_offset(&outgoing_pdu); /* Copy the data into the PDU. */ if(!prs_append_some_prs_data(&outgoing_pdu, &p->out_data.rdata, p->out_data.data_sent_length, data_len)) { DEBUG(0,("create_next_pdu_schannel: failed to copy %u bytes of data.\n", (unsigned int)data_len)); prs_mem_free(&outgoing_pdu); return False; } /* Copy the sign/seal padding data. */ if (ss_padding_len) { char pad[8]; memset(pad, '\0', 8); if (!prs_copy_data_in(&outgoing_pdu, pad, ss_padding_len)) { DEBUG(0,("create_next_pdu_schannel: failed to add %u bytes of pad data.\n", (unsigned int)ss_padding_len)); prs_mem_free(&outgoing_pdu); return False; } } { /* * Schannel processing. */ char *data; RPC_HDR_AUTH auth_info; RPC_AUTH_SCHANNEL_CHK verf; data = prs_data_p(&outgoing_pdu) + data_pos; /* Check it's the type of reply we were expecting to decode */ init_rpc_hdr_auth(&auth_info, RPC_SCHANNEL_AUTH_TYPE, p->auth.auth_level == PIPE_AUTH_LEVEL_PRIVACY ? RPC_AUTH_LEVEL_PRIVACY : RPC_AUTH_LEVEL_INTEGRITY, ss_padding_len, 1); if(!smb_io_rpc_hdr_auth("hdr_auth", &auth_info, &outgoing_pdu, 0)) { DEBUG(0,("create_next_pdu_schannel: failed to marshall RPC_HDR_AUTH.\n")); prs_mem_free(&outgoing_pdu); return False; } schannel_encode(p->auth.a_u.schannel_auth, p->auth.auth_level, SENDER_IS_ACCEPTOR, &verf, data, data_len + ss_padding_len); if (!smb_io_rpc_auth_schannel_chk("", RPC_AUTH_SCHANNEL_SIGN_OR_SEAL_CHK_LEN, &verf, &outgoing_pdu, 0)) { prs_mem_free(&outgoing_pdu); return False; } p->auth.a_u.schannel_auth->seq_num++; } /* * Setup the counts for this PDU. */ p->out_data.data_sent_length += data_len; p->out_data.current_pdu_len = p->hdr.frag_len; p->out_data.current_pdu_sent = 0; prs_mem_free(&outgoing_pdu); return True; } /******************************************************************* Generate the next PDU to be returned from the data in p->rdata. No authentication done. ********************************************************************/ static BOOL create_next_pdu_noauth(pipes_struct *p) { RPC_HDR_RESP hdr_resp; uint32 data_len; uint32 data_space_available; uint32 data_len_left; prs_struct outgoing_pdu; /* * If we're in the fault state, keep returning fault PDU's until * the pipe gets closed. JRA. */ if(p->fault_state) { setup_fault_pdu(p, NT_STATUS(DCERPC_FAULT_OP_RNG_ERROR)); return True; } memset((char *)&hdr_resp, '\0', sizeof(hdr_resp)); /* Change the incoming request header to a response. */ p->hdr.pkt_type = RPC_RESPONSE; /* Set up rpc header flags. */ if (p->out_data.data_sent_length == 0) { p->hdr.flags = RPC_FLG_FIRST; } else { p->hdr.flags = 0; } /* * Work out how much we can fit in a single PDU. */ data_len_left = prs_offset(&p->out_data.rdata) - p->out_data.data_sent_length; /* * Ensure there really is data left to send. */ if(!data_len_left) { DEBUG(0,("create_next_pdu_noath: no data left to send !\n")); return False; } data_space_available = sizeof(p->out_data.current_pdu) - RPC_HEADER_LEN - RPC_HDR_RESP_LEN; /* * The amount we send is the minimum of the available * space and the amount left to send. */ data_len = MIN(data_len_left, data_space_available); /* * Set up the alloc hint. This should be the data left to * send. */ hdr_resp.alloc_hint = data_len_left; /* * Work out if this PDU will be the last. */ if(p->out_data.data_sent_length + data_len >= prs_offset(&p->out_data.rdata)) { p->hdr.flags |= RPC_FLG_LAST; } /* * Set up the header lengths. */ p->hdr.frag_len = RPC_HEADER_LEN + RPC_HDR_RESP_LEN + data_len; p->hdr.auth_len = 0; /* * Init the parse struct to point at the outgoing * data. */ prs_init( &outgoing_pdu, 0, p->mem_ctx, MARSHALL); prs_give_memory( &outgoing_pdu, (char *)p->out_data.current_pdu, sizeof(p->out_data.current_pdu), False); /* Store the header in the data stream. */ if(!smb_io_rpc_hdr("hdr", &p->hdr, &outgoing_pdu, 0)) { DEBUG(0,("create_next_pdu_noath: failed to marshall RPC_HDR.\n")); prs_mem_free(&outgoing_pdu); return False; } if(!smb_io_rpc_hdr_resp("resp", &hdr_resp, &outgoing_pdu, 0)) { DEBUG(0,("create_next_pdu_noath: failed to marshall RPC_HDR_RESP.\n")); prs_mem_free(&outgoing_pdu); return False; } /* Copy the data into the PDU. */ if(!prs_append_some_prs_data(&outgoing_pdu, &p->out_data.rdata, p->out_data.data_sent_length, data_len)) { DEBUG(0,("create_next_pdu_noauth: failed to copy %u bytes of data.\n", (unsigned int)data_len)); prs_mem_free(&outgoing_pdu); return False; } /* * Setup the counts for this PDU. */ p->out_data.data_sent_length += data_len; p->out_data.current_pdu_len = p->hdr.frag_len; p->out_data.current_pdu_sent = 0; prs_mem_free(&outgoing_pdu); return True; } /******************************************************************* Generate the next PDU to be returned from the data in p->rdata. ********************************************************************/ BOOL create_next_pdu(pipes_struct *p) { switch(p->auth.auth_level) { case PIPE_AUTH_LEVEL_NONE: case PIPE_AUTH_LEVEL_CONNECT: /* This is incorrect for auth level connect. Fixme. JRA */ return create_next_pdu_noauth(p); default: switch(p->auth.auth_type) { case PIPE_AUTH_TYPE_NTLMSSP: case PIPE_AUTH_TYPE_SPNEGO_NTLMSSP: return create_next_pdu_ntlmssp(p); case PIPE_AUTH_TYPE_SCHANNEL: return create_next_pdu_schannel(p); default: break; } } DEBUG(0,("create_next_pdu: invalid internal auth level %u / type %u", (unsigned int)p->auth.auth_level, (unsigned int)p->auth.auth_type)); return False; } /******************************************************************* Process an NTLMSSP authentication response. If this function succeeds, the user has been authenticated and their domain, name and calling workstation stored in the pipe struct. *******************************************************************/ static BOOL pipe_ntlmssp_verify_final(pipes_struct *p, DATA_BLOB *p_resp_blob) { DATA_BLOB reply; NTSTATUS status; AUTH_NTLMSSP_STATE *a = p->auth.a_u.auth_ntlmssp_state; DEBUG(5,("pipe_ntlmssp_verify_final: pipe %s checking user details\n", p->name)); ZERO_STRUCT(reply); memset(p->user_name, '\0', sizeof(p->user_name)); memset(p->pipe_user_name, '\0', sizeof(p->pipe_user_name)); memset(p->domain, '\0', sizeof(p->domain)); memset(p->wks, '\0', sizeof(p->wks)); /* Set up for non-authenticated user. */ TALLOC_FREE(p->pipe_user.nt_user_token); p->pipe_user.ut.ngroups = 0; SAFE_FREE( p->pipe_user.ut.groups); /* this has to be done as root in order to verify the password */ become_root(); status = auth_ntlmssp_update(a, *p_resp_blob, &reply); unbecome_root(); /* Don't generate a reply. */ data_blob_free(&reply); if (!NT_STATUS_IS_OK(status)) { return False; } /* Finally - if the pipe negotiated integrity (sign) or privacy (seal) ensure the underlying NTLMSSP flags are also set. If not we should refuse the bind. */ if (p->auth.auth_level == PIPE_AUTH_LEVEL_INTEGRITY) { if (!(a->ntlmssp_state->neg_flags & NTLMSSP_NEGOTIATE_SIGN)) { DEBUG(0,("pipe_ntlmssp_verify_final: pipe %s : packet integrity requested " "but client declined signing.\n", p->name )); return False; } } if (p->auth.auth_level == PIPE_AUTH_LEVEL_PRIVACY) { if (!(a->ntlmssp_state->neg_flags & NTLMSSP_NEGOTIATE_SEAL)) { DEBUG(0,("pipe_ntlmssp_verify_final: pipe %s : packet privacy requested " "but client declined sealing.\n", p->name )); return False; } } fstrcpy(p->user_name, a->ntlmssp_state->user); fstrcpy(p->pipe_user_name, a->server_info->unix_name); fstrcpy(p->domain, a->ntlmssp_state->domain); fstrcpy(p->wks, a->ntlmssp_state->workstation); DEBUG(5,("pipe_ntlmssp_verify_final: OK: user: %s domain: %s workstation: %s\n", p->user_name, p->domain, p->wks)); /* * Store the UNIX credential data (uid/gid pair) in the pipe structure. */ p->pipe_user.ut.uid = a->server_info->uid; p->pipe_user.ut.gid = a->server_info->gid; /* * Copy the session key from the ntlmssp state. */ data_blob_free(&p->session_key); p->session_key = data_blob(a->ntlmssp_state->session_key.data, a->ntlmssp_state->session_key.length); if (!p->session_key.data) { return False; } p->pipe_user.ut.ngroups = a->server_info->n_groups; if (p->pipe_user.ut.ngroups) { if (!(p->pipe_user.ut.groups = memdup(a->server_info->groups, sizeof(gid_t) * p->pipe_user.ut.ngroups))) { DEBUG(0,("failed to memdup group list to p->pipe_user.groups\n")); return False; } } if (a->server_info->ptok) { p->pipe_user.nt_user_token = dup_nt_token(NULL, a->server_info->ptok); } else { DEBUG(1,("Error: Authmodule failed to provide nt_user_token\n")); p->pipe_user.nt_user_token = NULL; return False; } return True; } /******************************************************************* The switch table for the pipe names and the functions to handle them. *******************************************************************/ struct rpc_table { struct { const char *clnt; const char *srv; } pipe; struct api_struct *cmds; int n_cmds; }; static struct rpc_table *rpc_lookup; static int rpc_lookup_size; /******************************************************************* This is the "stage3" NTLMSSP response after a bind request and reply. *******************************************************************/ BOOL api_pipe_bind_auth3(pipes_struct *p, prs_struct *rpc_in_p) { RPC_HDR_AUTH auth_info; uint32 pad; DATA_BLOB blob; ZERO_STRUCT(blob); DEBUG(5,("api_pipe_bind_auth3: decode request. %d\n", __LINE__)); if (p->hdr.auth_len == 0) { DEBUG(0,("api_pipe_bind_auth3: No auth field sent !\n")); goto err; } /* 4 bytes padding. */ if (!prs_uint32("pad", rpc_in_p, 0, &pad)) { DEBUG(0,("api_pipe_bind_auth3: unmarshall of 4 byte pad failed.\n")); goto err; } /* * Decode the authentication verifier response. */ if(!smb_io_rpc_hdr_auth("", &auth_info, rpc_in_p, 0)) { DEBUG(0,("api_pipe_bind_auth3: unmarshall of RPC_HDR_AUTH failed.\n")); goto err; } if (auth_info.auth_type != RPC_NTLMSSP_AUTH_TYPE) { DEBUG(0,("api_pipe_bind_auth3: incorrect auth type (%u).\n", (unsigned int)auth_info.auth_type )); return False; } blob = data_blob(NULL,p->hdr.auth_len); if (!prs_copy_data_out((char *)blob.data, rpc_in_p, p->hdr.auth_len)) { DEBUG(0,("api_pipe_bind_auth3: Failed to pull %u bytes - the response blob.\n", (unsigned int)p->hdr.auth_len )); goto err; } /* * The following call actually checks the challenge/response data. * for correctness against the given DOMAIN\user name. */ if (!pipe_ntlmssp_verify_final(p, &blob)) { goto err; } data_blob_free(&blob); p->pipe_bound = True; return True; err: data_blob_free(&blob); free_pipe_ntlmssp_auth_data(&p->auth); p->auth.a_u.auth_ntlmssp_state = NULL; return False; } /******************************************************************* Marshall a bind_nak pdu. *******************************************************************/ static BOOL setup_bind_nak(pipes_struct *p) { prs_struct outgoing_rpc; RPC_HDR nak_hdr; uint16 zero = 0; /* Free any memory in the current return data buffer. */ prs_mem_free(&p->out_data.rdata); /* * Marshall directly into the outgoing PDU space. We * must do this as we need to set to the bind response * header and are never sending more than one PDU here. */ prs_init( &outgoing_rpc, 0, p->mem_ctx, MARSHALL); prs_give_memory( &outgoing_rpc, (char *)p->out_data.current_pdu, sizeof(p->out_data.current_pdu), False); /* * Initialize a bind_nak header. */ init_rpc_hdr(&nak_hdr, RPC_BINDNACK, RPC_FLG_FIRST | RPC_FLG_LAST, p->hdr.call_id, RPC_HEADER_LEN + sizeof(uint16), 0); /* * Marshall the header into the outgoing PDU. */ if(!smb_io_rpc_hdr("", &nak_hdr, &outgoing_rpc, 0)) { DEBUG(0,("setup_bind_nak: marshalling of RPC_HDR failed.\n")); prs_mem_free(&outgoing_rpc); return False; } /* * Now add the reject reason. */ if(!prs_uint16("reject code", &outgoing_rpc, 0, &zero)) { prs_mem_free(&outgoing_rpc); return False; } p->out_data.data_sent_length = 0; p->out_data.current_pdu_len = prs_offset(&outgoing_rpc); p->out_data.current_pdu_sent = 0; if (p->auth.auth_data_free_func) { (*p->auth.auth_data_free_func)(&p->auth); } p->auth.auth_level = PIPE_AUTH_LEVEL_NONE; p->auth.auth_type = PIPE_AUTH_TYPE_NONE; p->pipe_bound = False; return True; } /******************************************************************* Marshall a fault pdu. *******************************************************************/ BOOL setup_fault_pdu(pipes_struct *p, NTSTATUS status) { prs_struct outgoing_pdu; RPC_HDR fault_hdr; RPC_HDR_RESP hdr_resp; RPC_HDR_FAULT fault_resp; /* Free any memory in the current return data buffer. */ prs_mem_free(&p->out_data.rdata); /* * Marshall directly into the outgoing PDU space. We * must do this as we need to set to the bind response * header and are never sending more than one PDU here. */ prs_init( &outgoing_pdu, 0, p->mem_ctx, MARSHALL); prs_give_memory( &outgoing_pdu, (char *)p->out_data.current_pdu, sizeof(p->out_data.current_pdu), False); /* * Initialize a fault header. */ init_rpc_hdr(&fault_hdr, RPC_FAULT, RPC_FLG_FIRST | RPC_FLG_LAST | RPC_FLG_NOCALL, p->hdr.call_id, RPC_HEADER_LEN + RPC_HDR_RESP_LEN + RPC_HDR_FAULT_LEN, 0); /* * Initialize the HDR_RESP and FAULT parts of the PDU. */ memset((char *)&hdr_resp, '\0', sizeof(hdr_resp)); fault_resp.status = status; fault_resp.reserved = 0; /* * Marshall the header into the outgoing PDU. */ if(!smb_io_rpc_hdr("", &fault_hdr, &outgoing_pdu, 0)) { DEBUG(0,("setup_fault_pdu: marshalling of RPC_HDR failed.\n")); prs_mem_free(&outgoing_pdu); return False; } if(!smb_io_rpc_hdr_resp("resp", &hdr_resp, &outgoing_pdu, 0)) { DEBUG(0,("setup_fault_pdu: failed to marshall RPC_HDR_RESP.\n")); prs_mem_free(&outgoing_pdu); return False; } if(!smb_io_rpc_hdr_fault("fault", &fault_resp, &outgoing_pdu, 0)) { DEBUG(0,("setup_fault_pdu: failed to marshall RPC_HDR_FAULT.\n")); prs_mem_free(&outgoing_pdu); return False; } p->out_data.data_sent_length = 0; p->out_data.current_pdu_len = prs_offset(&outgoing_pdu); p->out_data.current_pdu_sent = 0; prs_mem_free(&outgoing_pdu); return True; } #if 0 /******************************************************************* Marshall a cancel_ack pdu. We should probably check the auth-verifier here. *******************************************************************/ BOOL setup_cancel_ack_reply(pipes_struct *p, prs_struct *rpc_in_p) { prs_struct outgoing_pdu; RPC_HDR ack_reply_hdr; /* Free any memory in the current return data buffer. */ prs_mem_free(&p->out_data.rdata); /* * Marshall directly into the outgoing PDU space. We * must do this as we need to set to the bind response * header and are never sending more than one PDU here. */ prs_init( &outgoing_pdu, 0, p->mem_ctx, MARSHALL); prs_give_memory( &outgoing_pdu, (char *)p->out_data.current_pdu, sizeof(p->out_data.current_pdu), False); /* * Initialize a cancel_ack header. */ init_rpc_hdr(&ack_reply_hdr, RPC_CANCEL_ACK, RPC_FLG_FIRST | RPC_FLG_LAST, p->hdr.call_id, RPC_HEADER_LEN, 0); /* * Marshall the header into the outgoing PDU. */ if(!smb_io_rpc_hdr("", &ack_reply_hdr, &outgoing_pdu, 0)) { DEBUG(0,("setup_cancel_ack_reply: marshalling of RPC_HDR failed.\n")); prs_mem_free(&outgoing_pdu); return False; } p->out_data.data_sent_length = 0; p->out_data.current_pdu_len = prs_offset(&outgoing_pdu); p->out_data.current_pdu_sent = 0; prs_mem_free(&outgoing_pdu); return True; } #endif /******************************************************************* Ensure a bind request has the correct abstract & transfer interface. Used to reject unknown binds from Win2k. *******************************************************************/ BOOL check_bind_req(struct pipes_struct *p, RPC_IFACE* abstract, RPC_IFACE* transfer, uint32 context_id) { char *pipe_name = p->name; int i=0; fstring pname; fstrcpy(pname,"\\PIPE\\"); fstrcat(pname,pipe_name); DEBUG(3,("check_bind_req for %s\n", pname)); /* we have to check all now since win2k introduced a new UUID on the lsaprpc pipe */ for ( i=0; pipe_names[i].client_pipe; i++ ) { DEBUG(10,("checking %s\n", pipe_names[i].client_pipe)); if ( strequal(pipe_names[i].client_pipe, pname) && (abstract->version == pipe_names[i].abstr_syntax.version) && (memcmp(&abstract->uuid, &pipe_names[i].abstr_syntax.uuid, sizeof(struct GUID)) == 0) && (transfer->version == pipe_names[i].trans_syntax.version) && (memcmp(&transfer->uuid, &pipe_names[i].trans_syntax.uuid, sizeof(struct GUID)) == 0) ) { struct api_struct *fns = NULL; int n_fns = 0; PIPE_RPC_FNS *context_fns; if ( !(context_fns = SMB_MALLOC_P(PIPE_RPC_FNS)) ) { DEBUG(0,("check_bind_req: malloc() failed!\n")); return False; } /* save the RPC function table associated with this bind */ get_pipe_fns(i, &fns, &n_fns); context_fns->cmds = fns; context_fns->n_cmds = n_fns; context_fns->context_id = context_id; /* add to the list of open contexts */ DLIST_ADD( p->contexts, context_fns ); break; } } if(pipe_names[i].client_pipe == NULL) { return False; } return True; } /******************************************************************* Register commands to an RPC pipe *******************************************************************/ NTSTATUS rpc_pipe_register_commands(int version, const char *clnt, const char *srv, const struct api_struct *cmds, int size) { struct rpc_table *rpc_entry; if (!clnt || !srv || !cmds) { return NT_STATUS_INVALID_PARAMETER; } if (version != SMB_RPC_INTERFACE_VERSION) { DEBUG(0,("Can't register rpc commands!\n" "You tried to register a rpc module with SMB_RPC_INTERFACE_VERSION %d" ", while this version of samba uses version %d!\n", version,SMB_RPC_INTERFACE_VERSION)); return NT_STATUS_OBJECT_TYPE_MISMATCH; } /* TODO: * * we still need to make sure that don't register the same commands twice!!! * * --metze */ /* We use a temporary variable because this call can fail and rpc_lookup will still be valid afterwards. It could then succeed if called again later */ rpc_lookup_size++; rpc_entry = SMB_REALLOC_ARRAY_KEEP_OLD_ON_ERROR(rpc_lookup, struct rpc_table, rpc_lookup_size); if (NULL == rpc_entry) { rpc_lookup_size--; DEBUG(0, ("rpc_pipe_register_commands: memory allocation failed\n")); return NT_STATUS_NO_MEMORY; } else { rpc_lookup = rpc_entry; } rpc_entry = rpc_lookup + (rpc_lookup_size - 1); ZERO_STRUCTP(rpc_entry); rpc_entry->pipe.clnt = SMB_STRDUP(clnt); rpc_entry->pipe.srv = SMB_STRDUP(srv); rpc_entry->cmds = SMB_REALLOC_ARRAY(rpc_entry->cmds, struct api_struct, rpc_entry->n_cmds + size); if (!rpc_entry->cmds) { return NT_STATUS_NO_MEMORY; } memcpy(rpc_entry->cmds + rpc_entry->n_cmds, cmds, size * sizeof(struct api_struct)); rpc_entry->n_cmds += size; return NT_STATUS_OK; } /******************************************************************* Handle a SPNEGO krb5 bind auth. *******************************************************************/ static BOOL pipe_spnego_auth_bind_kerberos(pipes_struct *p, prs_struct *rpc_in_p, RPC_HDR_AUTH *pauth_info, DATA_BLOB *psecblob, prs_struct *pout_auth) { return False; } /******************************************************************* Handle the first part of a SPNEGO bind auth. *******************************************************************/ static BOOL pipe_spnego_auth_bind_negotiate(pipes_struct *p, prs_struct *rpc_in_p, RPC_HDR_AUTH *pauth_info, prs_struct *pout_auth) { DATA_BLOB blob; DATA_BLOB secblob; DATA_BLOB response; DATA_BLOB chal; char *OIDs[ASN1_MAX_OIDS]; int i; NTSTATUS status; BOOL got_kerberos_mechanism = False; AUTH_NTLMSSP_STATE *a = NULL; RPC_HDR_AUTH auth_info; ZERO_STRUCT(secblob); ZERO_STRUCT(chal); ZERO_STRUCT(response); /* Grab the SPNEGO blob. */ blob = data_blob(NULL,p->hdr.auth_len); if (!prs_copy_data_out((char *)blob.data, rpc_in_p, p->hdr.auth_len)) { DEBUG(0,("pipe_spnego_auth_bind_negotiate: Failed to pull %u bytes - the SPNEGO auth header.\n", (unsigned int)p->hdr.auth_len )); goto err; } if (blob.data[0] != ASN1_APPLICATION(0)) { goto err; } /* parse out the OIDs and the first sec blob */ if (!parse_negTokenTarg(blob, OIDs, &secblob)) { DEBUG(0,("pipe_spnego_auth_bind_negotiate: Failed to parse the security blob.\n")); goto err; } if (strcmp(OID_KERBEROS5, OIDs[0]) == 0 || strcmp(OID_KERBEROS5_OLD, OIDs[0]) == 0) { got_kerberos_mechanism = True; } for (i=0;OIDs[i];i++) { DEBUG(3,("pipe_spnego_auth_bind_negotiate: Got OID %s\n", OIDs[i])); SAFE_FREE(OIDs[i]); } DEBUG(3,("pipe_spnego_auth_bind_negotiate: Got secblob of size %lu\n", (unsigned long)secblob.length)); if ( got_kerberos_mechanism && ((lp_security()==SEC_ADS) || lp_use_kerberos_keytab()) ) { BOOL ret = pipe_spnego_auth_bind_kerberos(p, rpc_in_p, pauth_info, &secblob, pout_auth); data_blob_free(&secblob); data_blob_free(&blob); return ret; } if (p->auth.auth_type == PIPE_AUTH_TYPE_SPNEGO_NTLMSSP && p->auth.a_u.auth_ntlmssp_state) { /* Free any previous auth type. */ free_pipe_ntlmssp_auth_data(&p->auth); } /* Initialize the NTLM engine. */ status = auth_ntlmssp_start(&a); if (!NT_STATUS_IS_OK(status)) { goto err; } /* * Pass the first security blob of data to it. * This can return an error or NT_STATUS_MORE_PROCESSING_REQUIRED * which means we need another packet to complete the bind. */ status = auth_ntlmssp_update(a, secblob, &chal); if (!NT_STATUS_EQUAL(status, NT_STATUS_MORE_PROCESSING_REQUIRED)) { DEBUG(3,("pipe_spnego_auth_bind_negotiate: auth_ntlmssp_update failed.\n")); goto err; } /* Generate the response blob we need for step 2 of the bind. */ response = spnego_gen_auth_response(&chal, status, OID_NTLMSSP); /* Copy the blob into the pout_auth parse struct */ init_rpc_hdr_auth(&auth_info, RPC_SPNEGO_AUTH_TYPE, pauth_info->auth_level, RPC_HDR_AUTH_LEN, 1); if(!smb_io_rpc_hdr_auth("", &auth_info, pout_auth, 0)) { DEBUG(0,("pipe_spnego_auth_bind_negotiate: marshalling of RPC_HDR_AUTH failed.\n")); goto err; } if (!prs_copy_data_in(pout_auth, (char *)response.data, response.length)) { DEBUG(0,("pipe_spnego_auth_bind_negotiate: marshalling of data blob failed.\n")); goto err; } p->auth.a_u.auth_ntlmssp_state = a; p->auth.auth_data_free_func = &free_pipe_ntlmssp_auth_data; p->auth.auth_type = PIPE_AUTH_TYPE_SPNEGO_NTLMSSP; data_blob_free(&blob); data_blob_free(&secblob); data_blob_free(&chal); data_blob_free(&response); /* We can't set pipe_bound True yet - we need an RPC_ALTER_CONTEXT response packet... */ return True; err: data_blob_free(&blob); data_blob_free(&secblob); data_blob_free(&chal); data_blob_free(&response); p->auth.a_u.auth_ntlmssp_state = NULL; return False; } /******************************************************************* Handle the second part of a SPNEGO bind auth. *******************************************************************/ static BOOL pipe_spnego_auth_bind_continue(pipes_struct *p, prs_struct *rpc_in_p, RPC_HDR_AUTH *pauth_info, prs_struct *pout_auth) { RPC_HDR_AUTH auth_info; DATA_BLOB spnego_blob; DATA_BLOB auth_blob; DATA_BLOB auth_reply; DATA_BLOB response; AUTH_NTLMSSP_STATE *a = p->auth.a_u.auth_ntlmssp_state; ZERO_STRUCT(spnego_blob); ZERO_STRUCT(auth_blob); ZERO_STRUCT(auth_reply); ZERO_STRUCT(response); if (p->auth.auth_type != PIPE_AUTH_TYPE_SPNEGO_NTLMSSP || !a) { DEBUG(0,("pipe_spnego_auth_bind_continue: not in NTLMSSP auth state.\n")); goto err; } /* Grab the SPNEGO blob. */ spnego_blob = data_blob(NULL,p->hdr.auth_len); if (!prs_copy_data_out((char *)spnego_blob.data, rpc_in_p, p->hdr.auth_len)) { DEBUG(0,("pipe_spnego_auth_bind_continue: Failed to pull %u bytes - the SPNEGO auth header.\n", (unsigned int)p->hdr.auth_len )); goto err; } if (spnego_blob.data[0] != ASN1_CONTEXT(1)) { DEBUG(0,("pipe_spnego_auth_bind_continue: invalid SPNEGO blob type.\n")); goto err; } if (!spnego_parse_auth(spnego_blob, &auth_blob)) { DEBUG(0,("pipe_spnego_auth_bind_continue: invalid SPNEGO blob.\n")); goto err; } /* * The following call actually checks the challenge/response data. * for correctness against the given DOMAIN\user name. */ if (!pipe_ntlmssp_verify_final(p, &auth_blob)) { goto err; } data_blob_free(&spnego_blob); data_blob_free(&auth_blob); /* Generate the spnego "accept completed" blob - no incoming data. */ response = spnego_gen_auth_response(&auth_reply, NT_STATUS_OK, OID_NTLMSSP); /* Copy the blob into the pout_auth parse struct */ init_rpc_hdr_auth(&auth_info, RPC_SPNEGO_AUTH_TYPE, pauth_info->auth_level, RPC_HDR_AUTH_LEN, 1); if(!smb_io_rpc_hdr_auth("", &auth_info, pout_auth, 0)) { DEBUG(0,("pipe_spnego_auth_bind_continue: marshalling of RPC_HDR_AUTH failed.\n")); goto err; } if (!prs_copy_data_in(pout_auth, (char *)response.data, response.length)) { DEBUG(0,("pipe_spnego_auth_bind_continue: marshalling of data blob failed.\n")); goto err; } data_blob_free(&auth_reply); data_blob_free(&response); p->pipe_bound = True; return True; err: data_blob_free(&spnego_blob); data_blob_free(&auth_blob); data_blob_free(&auth_reply); data_blob_free(&response); free_pipe_ntlmssp_auth_data(&p->auth); p->auth.a_u.auth_ntlmssp_state = NULL; return False; } /******************************************************************* Handle an schannel bind auth. *******************************************************************/ static BOOL pipe_schannel_auth_bind(pipes_struct *p, prs_struct *rpc_in_p, RPC_HDR_AUTH *pauth_info, prs_struct *pout_auth) { RPC_HDR_AUTH auth_info; RPC_AUTH_SCHANNEL_NEG neg; RPC_AUTH_VERIFIER auth_verifier; BOOL ret; struct dcinfo *pdcinfo; uint32 flags; if (!smb_io_rpc_auth_schannel_neg("", &neg, rpc_in_p, 0)) { DEBUG(0,("pipe_schannel_auth_bind: Could not unmarshal SCHANNEL auth neg\n")); return False; } /* * The neg.myname key here must match the remote computer name * given in the DOM_CLNT_SRV.uni_comp_name used on all netlogon pipe * operations that use credentials. */ become_root(); ret = secrets_restore_schannel_session_info(p->mem_ctx, neg.myname, &pdcinfo); unbecome_root(); if (!ret) { DEBUG(0, ("pipe_schannel_auth_bind: Attempt to bind using schannel without successful serverauth2\n")); return False; } p->auth.a_u.schannel_auth = TALLOC_P(p->pipe_state_mem_ctx, struct schannel_auth_struct); if (!p->auth.a_u.schannel_auth) { TALLOC_FREE(pdcinfo); return False; } memset(p->auth.a_u.schannel_auth->sess_key, 0, sizeof(p->auth.a_u.schannel_auth->sess_key)); memcpy(p->auth.a_u.schannel_auth->sess_key, pdcinfo->sess_key, sizeof(pdcinfo->sess_key)); TALLOC_FREE(pdcinfo); p->auth.a_u.schannel_auth->seq_num = 0; /* * JRA. Should we also copy the schannel session key into the pipe session key p->session_key * here ? We do that for NTLMSSP, but the session key is already set up from the vuser * struct of the person who opened the pipe. I need to test this further. JRA. */ init_rpc_hdr_auth(&auth_info, RPC_SCHANNEL_AUTH_TYPE, pauth_info->auth_level, RPC_HDR_AUTH_LEN, 1); if(!smb_io_rpc_hdr_auth("", &auth_info, pout_auth, 0)) { DEBUG(0,("pipe_schannel_auth_bind: marshalling of RPC_HDR_AUTH failed.\n")); return False; } /*** SCHANNEL verifier ***/ init_rpc_auth_verifier(&auth_verifier, "\001", 0x0); if(!smb_io_rpc_schannel_verifier("", &auth_verifier, pout_auth, 0)) { DEBUG(0,("pipe_schannel_auth_bind: marshalling of RPC_AUTH_VERIFIER failed.\n")); return False; } prs_align(pout_auth); flags = 5; if(!prs_uint32("flags ", pout_auth, 0, &flags)) { return False; } DEBUG(10,("pipe_schannel_auth_bind: schannel auth: domain [%s] myname [%s]\n", neg.domain, neg.myname)); /* We're finished with this bind - no more packets. */ p->auth.auth_data_free_func = NULL; p->auth.auth_type = PIPE_AUTH_TYPE_SCHANNEL; p->pipe_bound = True; return True; } /******************************************************************* Handle an NTLMSSP bind auth. *******************************************************************/ static BOOL pipe_ntlmssp_auth_bind(pipes_struct *p, prs_struct *rpc_in_p, RPC_HDR_AUTH *pauth_info, prs_struct *pout_auth) { RPC_HDR_AUTH auth_info; DATA_BLOB blob; DATA_BLOB response; NTSTATUS status; AUTH_NTLMSSP_STATE *a = NULL; ZERO_STRUCT(blob); ZERO_STRUCT(response); /* Grab the NTLMSSP blob. */ blob = data_blob(NULL,p->hdr.auth_len); if (!prs_copy_data_out((char *)blob.data, rpc_in_p, p->hdr.auth_len)) { DEBUG(0,("pipe_ntlmssp_auth_bind: Failed to pull %u bytes - the NTLM auth header.\n", (unsigned int)p->hdr.auth_len )); goto err; } if (strncmp((char *)blob.data, "NTLMSSP", 7) != 0) { DEBUG(0,("pipe_ntlmssp_auth_bind: Failed to read NTLMSSP in blob\n")); goto err; } /* We have an NTLMSSP blob. */ status = auth_ntlmssp_start(&a); if (!NT_STATUS_IS_OK(status)) { DEBUG(0,("pipe_ntlmssp_auth_bind: auth_ntlmssp_start failed: %s\n", nt_errstr(status) )); goto err; } status = auth_ntlmssp_update(a, blob, &response); if (!NT_STATUS_EQUAL(status, NT_STATUS_MORE_PROCESSING_REQUIRED)) { DEBUG(0,("pipe_ntlmssp_auth_bind: auth_ntlmssp_update failed: %s\n", nt_errstr(status) )); goto err; } data_blob_free(&blob); /* Copy the blob into the pout_auth parse struct */ init_rpc_hdr_auth(&auth_info, RPC_NTLMSSP_AUTH_TYPE, pauth_info->auth_level, RPC_HDR_AUTH_LEN, 1); if(!smb_io_rpc_hdr_auth("", &auth_info, pout_auth, 0)) { DEBUG(0,("pipe_ntlmssp_auth_bind: marshalling of RPC_HDR_AUTH failed.\n")); goto err; } if (!prs_copy_data_in(pout_auth, (char *)response.data, response.length)) { DEBUG(0,("pipe_ntlmssp_auth_bind: marshalling of data blob failed.\n")); goto err; } p->auth.a_u.auth_ntlmssp_state = a; p->auth.auth_data_free_func = &free_pipe_ntlmssp_auth_data; p->auth.auth_type = PIPE_AUTH_TYPE_NTLMSSP; data_blob_free(&blob); data_blob_free(&response); DEBUG(10,("pipe_ntlmssp_auth_bind: NTLMSSP auth started\n")); /* We can't set pipe_bound True yet - we need an RPC_AUTH3 response packet... */ return True; err: data_blob_free(&blob); data_blob_free(&response); free_pipe_ntlmssp_auth_data(&p->auth); p->auth.a_u.auth_ntlmssp_state = NULL; return False; } /******************************************************************* Respond to a pipe bind request. *******************************************************************/ BOOL api_pipe_bind_req(pipes_struct *p, prs_struct *rpc_in_p) { RPC_HDR_BA hdr_ba; RPC_HDR_RB hdr_rb; RPC_HDR_AUTH auth_info; uint16 assoc_gid; fstring ack_pipe_name; prs_struct out_hdr_ba; prs_struct out_auth; prs_struct outgoing_rpc; int i = 0; int auth_len = 0; unsigned int auth_type = RPC_ANONYMOUS_AUTH_TYPE; /* No rebinds on a bound pipe - use alter context. */ if (p->pipe_bound) { DEBUG(2,("api_pipe_bind_req: rejecting bind request on bound pipe %s.\n", p->pipe_srv_name)); return setup_bind_nak(p); } prs_init( &outgoing_rpc, 0, p->mem_ctx, MARSHALL); /* * Marshall directly into the outgoing PDU space. We * must do this as we need to set to the bind response * header and are never sending more than one PDU here. */ prs_give_memory( &outgoing_rpc, (char *)p->out_data.current_pdu, sizeof(p->out_data.current_pdu), False); /* * Setup the memory to marshall the ba header, and the * auth footers. */ if(!prs_init(&out_hdr_ba, 1024, p->mem_ctx, MARSHALL)) { DEBUG(0,("api_pipe_bind_req: malloc out_hdr_ba failed.\n")); prs_mem_free(&outgoing_rpc); return False; } if(!prs_init(&out_auth, 1024, p->mem_ctx, MARSHALL)) { DEBUG(0,("api_pipe_bind_req: malloc out_auth failed.\n")); prs_mem_free(&outgoing_rpc); prs_mem_free(&out_hdr_ba); return False; } DEBUG(5,("api_pipe_bind_req: decode request. %d\n", __LINE__)); /* * Try and find the correct pipe name to ensure * that this is a pipe name we support. */ for (i = 0; i < rpc_lookup_size; i++) { if (strequal(rpc_lookup[i].pipe.clnt, p->name)) { DEBUG(3, ("api_pipe_bind_req: \\PIPE\\%s -> \\PIPE\\%s\n", rpc_lookup[i].pipe.clnt, rpc_lookup[i].pipe.srv)); fstrcpy(p->pipe_srv_name, rpc_lookup[i].pipe.srv); break; } } if (i == rpc_lookup_size) { if (NT_STATUS_IS_ERR(smb_probe_module("rpc", p->name))) { DEBUG(3,("api_pipe_bind_req: Unknown pipe name %s in bind request.\n", p->name )); prs_mem_free(&outgoing_rpc); prs_mem_free(&out_hdr_ba); prs_mem_free(&out_auth); return setup_bind_nak(p); } for (i = 0; i < rpc_lookup_size; i++) { if (strequal(rpc_lookup[i].pipe.clnt, p->name)) { DEBUG(3, ("api_pipe_bind_req: \\PIPE\\%s -> \\PIPE\\%s\n", rpc_lookup[i].pipe.clnt, rpc_lookup[i].pipe.srv)); fstrcpy(p->pipe_srv_name, rpc_lookup[i].pipe.srv); break; } } if (i == rpc_lookup_size) { DEBUG(0, ("module %s doesn't provide functions for pipe %s!\n", p->name, p->name)); goto err_exit; } } /* decode the bind request */ if(!smb_io_rpc_hdr_rb("", &hdr_rb, rpc_in_p, 0)) { DEBUG(0,("api_pipe_bind_req: unable to unmarshall RPC_HDR_RB struct.\n")); goto err_exit; } /* name has to be \PIPE\xxxxx */ fstrcpy(ack_pipe_name, "\\PIPE\\"); fstrcat(ack_pipe_name, p->pipe_srv_name); DEBUG(5,("api_pipe_bind_req: make response. %d\n", __LINE__)); /* * Check if this is an authenticated bind request. */ if (p->hdr.auth_len) { /* * Decode the authentication verifier. */ if(!smb_io_rpc_hdr_auth("", &auth_info, rpc_in_p, 0)) { DEBUG(0,("api_pipe_bind_req: unable to unmarshall RPC_HDR_AUTH struct.\n")); goto err_exit; } auth_type = auth_info.auth_type; /* Work out if we have to sign or seal etc. */ switch (auth_info.auth_level) { case RPC_AUTH_LEVEL_INTEGRITY: p->auth.auth_level = PIPE_AUTH_LEVEL_INTEGRITY; break; case RPC_AUTH_LEVEL_PRIVACY: p->auth.auth_level = PIPE_AUTH_LEVEL_PRIVACY; break; default: DEBUG(0,("api_pipe_bind_req: unexpected auth level (%u).\n", (unsigned int)auth_info.auth_level )); goto err_exit; } } else { ZERO_STRUCT(auth_info); } assoc_gid = hdr_rb.bba.assoc_gid ? hdr_rb.bba.assoc_gid : 0x53f0; switch(auth_type) { case RPC_NTLMSSP_AUTH_TYPE: if (!pipe_ntlmssp_auth_bind(p, rpc_in_p, &auth_info, &out_auth)) { goto err_exit; } assoc_gid = 0x7a77; break; case RPC_SCHANNEL_AUTH_TYPE: if (!pipe_schannel_auth_bind(p, rpc_in_p, &auth_info, &out_auth)) { goto err_exit; } break; case RPC_SPNEGO_AUTH_TYPE: if (!pipe_spnego_auth_bind_negotiate(p, rpc_in_p, &auth_info, &out_auth)) { goto err_exit; } break; case RPC_ANONYMOUS_AUTH_TYPE: /* Unauthenticated bind request. */ /* We're finished - no more packets. */ p->auth.auth_type = PIPE_AUTH_TYPE_NONE; /* We must set the pipe auth_level here also. */ p->auth.auth_level = PIPE_AUTH_LEVEL_NONE; p->pipe_bound = True; break; default: DEBUG(0,("api_pipe_bind_req: unknown auth type %x requested.\n", auth_type )); goto err_exit; } /* * Create the bind response struct. */ /* If the requested abstract synt uuid doesn't match our client pipe, reject the bind_ack & set the transfer interface synt to all 0's, ver 0 (observed when NT5 attempts to bind to abstract interfaces unknown to NT4) Needed when adding entries to a DACL from NT5 - SK */ if(check_bind_req(p, &hdr_rb.rpc_context[0].abstract, &hdr_rb.rpc_context[0].transfer[0], hdr_rb.rpc_context[0].context_id )) { init_rpc_hdr_ba(&hdr_ba, RPC_MAX_PDU_FRAG_LEN, RPC_MAX_PDU_FRAG_LEN, assoc_gid, ack_pipe_name, 0x1, 0x0, 0x0, &hdr_rb.rpc_context[0].transfer[0]); } else { RPC_IFACE null_interface; ZERO_STRUCT(null_interface); /* Rejection reason: abstract syntax not supported */ init_rpc_hdr_ba(&hdr_ba, RPC_MAX_PDU_FRAG_LEN, RPC_MAX_PDU_FRAG_LEN, assoc_gid, ack_pipe_name, 0x1, 0x2, 0x1, &null_interface); p->pipe_bound = False; } /* * and marshall it. */ if(!smb_io_rpc_hdr_ba("", &hdr_ba, &out_hdr_ba, 0)) { DEBUG(0,("api_pipe_bind_req: marshalling of RPC_HDR_BA failed.\n")); goto err_exit; } /* * Create the header, now we know the length. */ if (prs_offset(&out_auth)) { auth_len = prs_offset(&out_auth) - RPC_HDR_AUTH_LEN; } init_rpc_hdr(&p->hdr, RPC_BINDACK, RPC_FLG_FIRST | RPC_FLG_LAST, p->hdr.call_id, RPC_HEADER_LEN + prs_offset(&out_hdr_ba) + prs_offset(&out_auth), auth_len); /* * Marshall the header into the outgoing PDU. */ if(!smb_io_rpc_hdr("", &p->hdr, &outgoing_rpc, 0)) { DEBUG(0,("api_pipe_bind_req: marshalling of RPC_HDR failed.\n")); goto err_exit; } /* * Now add the RPC_HDR_BA and any auth needed. */ if(!prs_append_prs_data( &outgoing_rpc, &out_hdr_ba)) { DEBUG(0,("api_pipe_bind_req: append of RPC_HDR_BA failed.\n")); goto err_exit; } if (auth_len && !prs_append_prs_data( &outgoing_rpc, &out_auth)) { DEBUG(0,("api_pipe_bind_req: append of auth info failed.\n")); goto err_exit; } /* * Setup the lengths for the initial reply. */ p->out_data.data_sent_length = 0; p->out_data.current_pdu_len = prs_offset(&outgoing_rpc); p->out_data.current_pdu_sent = 0; prs_mem_free(&out_hdr_ba); prs_mem_free(&out_auth); return True; err_exit: prs_mem_free(&outgoing_rpc); prs_mem_free(&out_hdr_ba); prs_mem_free(&out_auth); return setup_bind_nak(p); } /**************************************************************************** Deal with an alter context call. Can be third part of 3 leg auth request for SPNEGO calls. ****************************************************************************/ BOOL api_pipe_alter_context(pipes_struct *p, prs_struct *rpc_in_p) { RPC_HDR_BA hdr_ba; RPC_HDR_RB hdr_rb; RPC_HDR_AUTH auth_info; uint16 assoc_gid; fstring ack_pipe_name; prs_struct out_hdr_ba; prs_struct out_auth; prs_struct outgoing_rpc; int auth_len = 0; prs_init( &outgoing_rpc, 0, p->mem_ctx, MARSHALL); /* * Marshall directly into the outgoing PDU space. We * must do this as we need to set to the bind response * header and are never sending more than one PDU here. */ prs_give_memory( &outgoing_rpc, (char *)p->out_data.current_pdu, sizeof(p->out_data.current_pdu), False); /* * Setup the memory to marshall the ba header, and the * auth footers. */ if(!prs_init(&out_hdr_ba, 1024, p->mem_ctx, MARSHALL)) { DEBUG(0,("api_pipe_alter_context: malloc out_hdr_ba failed.\n")); prs_mem_free(&outgoing_rpc); return False; } if(!prs_init(&out_auth, 1024, p->mem_ctx, MARSHALL)) { DEBUG(0,("api_pipe_alter_context: malloc out_auth failed.\n")); prs_mem_free(&outgoing_rpc); prs_mem_free(&out_hdr_ba); return False; } DEBUG(5,("api_pipe_alter_context: decode request. %d\n", __LINE__)); /* decode the alter context request */ if(!smb_io_rpc_hdr_rb("", &hdr_rb, rpc_in_p, 0)) { DEBUG(0,("api_pipe_alter_context: unable to unmarshall RPC_HDR_RB struct.\n")); goto err_exit; } /* secondary address CAN be NULL * as the specs say it's ignored. * It MUST be NULL to have the spoolss working. */ fstrcpy(ack_pipe_name,""); DEBUG(5,("api_pipe_alter_context: make response. %d\n", __LINE__)); /* * Check if this is an authenticated alter context request. */ if (p->hdr.auth_len != 0) { /* * Decode the authentication verifier. */ if(!smb_io_rpc_hdr_auth("", &auth_info, rpc_in_p, 0)) { DEBUG(0,("api_pipe_alter_context: unable to unmarshall RPC_HDR_AUTH struct.\n")); goto err_exit; } /* * Currently only the SPNEGO auth type uses the alter ctx * response in place of the NTLMSSP auth3 type. */ if (auth_info.auth_type == RPC_SPNEGO_AUTH_TYPE) { /* We can only finish if the pipe is unbound. */ if (!p->pipe_bound) { if (!pipe_spnego_auth_bind_continue(p, rpc_in_p, &auth_info, &out_auth)) { goto err_exit; } } else { goto err_exit; } } } else { ZERO_STRUCT(auth_info); } assoc_gid = hdr_rb.bba.assoc_gid ? hdr_rb.bba.assoc_gid : 0x53f0; /* * Create the bind response struct. */ /* If the requested abstract synt uuid doesn't match our client pipe, reject the bind_ack & set the transfer interface synt to all 0's, ver 0 (observed when NT5 attempts to bind to abstract interfaces unknown to NT4) Needed when adding entries to a DACL from NT5 - SK */ if(check_bind_req(p, &hdr_rb.rpc_context[0].abstract, &hdr_rb.rpc_context[0].transfer[0], hdr_rb.rpc_context[0].context_id )) { init_rpc_hdr_ba(&hdr_ba, RPC_MAX_PDU_FRAG_LEN, RPC_MAX_PDU_FRAG_LEN, assoc_gid, ack_pipe_name, 0x1, 0x0, 0x0, &hdr_rb.rpc_context[0].transfer[0]); } else { RPC_IFACE null_interface; ZERO_STRUCT(null_interface); /* Rejection reason: abstract syntax not supported */ init_rpc_hdr_ba(&hdr_ba, RPC_MAX_PDU_FRAG_LEN, RPC_MAX_PDU_FRAG_LEN, assoc_gid, ack_pipe_name, 0x1, 0x2, 0x1, &null_interface); p->pipe_bound = False; } /* * and marshall it. */ if(!smb_io_rpc_hdr_ba("", &hdr_ba, &out_hdr_ba, 0)) { DEBUG(0,("api_pipe_alter_context: marshalling of RPC_HDR_BA failed.\n")); goto err_exit; } /* * Create the header, now we know the length. */ if (prs_offset(&out_auth)) { auth_len = prs_offset(&out_auth) - RPC_HDR_AUTH_LEN; } init_rpc_hdr(&p->hdr, RPC_ALTCONTRESP, RPC_FLG_FIRST | RPC_FLG_LAST, p->hdr.call_id, RPC_HEADER_LEN + prs_offset(&out_hdr_ba) + prs_offset(&out_auth), auth_len); /* * Marshall the header into the outgoing PDU. */ if(!smb_io_rpc_hdr("", &p->hdr, &outgoing_rpc, 0)) { DEBUG(0,("api_pipe_alter_context: marshalling of RPC_HDR failed.\n")); goto err_exit; } /* * Now add the RPC_HDR_BA and any auth needed. */ if(!prs_append_prs_data( &outgoing_rpc, &out_hdr_ba)) { DEBUG(0,("api_pipe_alter_context: append of RPC_HDR_BA failed.\n")); goto err_exit; } if (auth_len && !prs_append_prs_data( &outgoing_rpc, &out_auth)) { DEBUG(0,("api_pipe_alter_context: append of auth info failed.\n")); goto err_exit; } /* * Setup the lengths for the initial reply. */ p->out_data.data_sent_length = 0; p->out_data.current_pdu_len = prs_offset(&outgoing_rpc); p->out_data.current_pdu_sent = 0; prs_mem_free(&out_hdr_ba); prs_mem_free(&out_auth); return True; err_exit: prs_mem_free(&outgoing_rpc); prs_mem_free(&out_hdr_ba); prs_mem_free(&out_auth); return setup_bind_nak(p); } /**************************************************************************** Deal with NTLMSSP sign & seal processing on an RPC request. ****************************************************************************/ BOOL api_pipe_ntlmssp_auth_process(pipes_struct *p, prs_struct *rpc_in, uint32 *p_ss_padding_len, NTSTATUS *pstatus) { RPC_HDR_AUTH auth_info; uint32 auth_len = p->hdr.auth_len; uint32 save_offset = prs_offset(rpc_in); AUTH_NTLMSSP_STATE *a = p->auth.a_u.auth_ntlmssp_state; unsigned char *data = NULL; size_t data_len; unsigned char *full_packet_data = NULL; size_t full_packet_data_len; DATA_BLOB auth_blob; *pstatus = NT_STATUS_OK; if (p->auth.auth_level == PIPE_AUTH_LEVEL_NONE || p->auth.auth_level == PIPE_AUTH_LEVEL_CONNECT) { return True; } if (!a) { *pstatus = NT_STATUS_INVALID_PARAMETER; return False; } /* Ensure there's enough data for an authenticated request. */ if ((auth_len > RPC_MAX_SIGN_SIZE) || (RPC_HEADER_LEN + RPC_HDR_REQ_LEN + RPC_HDR_AUTH_LEN + auth_len > p->hdr.frag_len)) { DEBUG(0,("api_pipe_ntlmssp_auth_process: auth_len %u is too large.\n", (unsigned int)auth_len )); *pstatus = NT_STATUS_INVALID_PARAMETER; return False; } /* * We need the full packet data + length (minus auth stuff) as well as the packet data + length * after the RPC header. * We need to pass in the full packet (minus auth len) to the NTLMSSP sign and check seal * functions as NTLMv2 checks the rpc headers also. */ data = (unsigned char *)(prs_data_p(rpc_in) + RPC_HDR_REQ_LEN); data_len = (size_t)(p->hdr.frag_len - RPC_HEADER_LEN - RPC_HDR_REQ_LEN - RPC_HDR_AUTH_LEN - auth_len); full_packet_data = p->in_data.current_in_pdu; full_packet_data_len = p->hdr.frag_len - auth_len; /* Pull the auth header and the following data into a blob. */ if(!prs_set_offset(rpc_in, RPC_HDR_REQ_LEN + data_len)) { DEBUG(0,("api_pipe_ntlmssp_auth_process: cannot move offset to %u.\n", (unsigned int)RPC_HDR_REQ_LEN + (unsigned int)data_len )); *pstatus = NT_STATUS_INVALID_PARAMETER; return False; } if(!smb_io_rpc_hdr_auth("hdr_auth", &auth_info, rpc_in, 0)) { DEBUG(0,("api_pipe_ntlmssp_auth_process: failed to unmarshall RPC_HDR_AUTH.\n")); *pstatus = NT_STATUS_INVALID_PARAMETER; return False; } auth_blob.data = (unsigned char *)prs_data_p(rpc_in) + prs_offset(rpc_in); auth_blob.length = auth_len; switch (p->auth.auth_level) { case PIPE_AUTH_LEVEL_PRIVACY: /* Data is encrypted. */ *pstatus = ntlmssp_unseal_packet(a->ntlmssp_state, data, data_len, full_packet_data, full_packet_data_len, &auth_blob); if (!NT_STATUS_IS_OK(*pstatus)) { return False; } break; case PIPE_AUTH_LEVEL_INTEGRITY: /* Data is signed. */ *pstatus = ntlmssp_check_packet(a->ntlmssp_state, data, data_len, full_packet_data, full_packet_data_len, &auth_blob); if (!NT_STATUS_IS_OK(*pstatus)) { return False; } break; default: *pstatus = NT_STATUS_INVALID_PARAMETER; return False; } /* * Return the current pointer to the data offset. */ if(!prs_set_offset(rpc_in, save_offset)) { DEBUG(0,("api_pipe_auth_process: failed to set offset back to %u\n", (unsigned int)save_offset )); *pstatus = NT_STATUS_INVALID_PARAMETER; return False; } /* * Remember the padding length. We must remove it from the real data * stream once the sign/seal is done. */ *p_ss_padding_len = auth_info.auth_pad_len; return True; } /**************************************************************************** Deal with schannel processing on an RPC request. ****************************************************************************/ BOOL api_pipe_schannel_process(pipes_struct *p, prs_struct *rpc_in, uint32 *p_ss_padding_len) { uint32 data_len; uint32 auth_len; uint32 save_offset = prs_offset(rpc_in); RPC_HDR_AUTH auth_info; RPC_AUTH_SCHANNEL_CHK schannel_chk; auth_len = p->hdr.auth_len; if (auth_len < RPC_AUTH_SCHANNEL_SIGN_OR_SEAL_CHK_LEN || auth_len > RPC_HEADER_LEN + RPC_HDR_REQ_LEN + RPC_HDR_AUTH_LEN + auth_len) { DEBUG(0,("Incorrect auth_len %u.\n", (unsigned int)auth_len )); return False; } /* * The following is that length of the data we must verify or unseal. * This doesn't include the RPC headers or the auth_len or the RPC_HDR_AUTH_LEN * preceeding the auth_data. */ if (p->hdr.frag_len < RPC_HEADER_LEN + RPC_HDR_REQ_LEN + RPC_HDR_AUTH_LEN + auth_len) { DEBUG(0,("Incorrect frag %u, auth %u.\n", (unsigned int)p->hdr.frag_len, (unsigned int)auth_len )); return False; } data_len = p->hdr.frag_len - RPC_HEADER_LEN - RPC_HDR_REQ_LEN - RPC_HDR_AUTH_LEN - auth_len; DEBUG(5,("data %d auth %d\n", data_len, auth_len)); if(!prs_set_offset(rpc_in, RPC_HDR_REQ_LEN + data_len)) { DEBUG(0,("cannot move offset to %u.\n", (unsigned int)RPC_HDR_REQ_LEN + data_len )); return False; } if(!smb_io_rpc_hdr_auth("hdr_auth", &auth_info, rpc_in, 0)) { DEBUG(0,("failed to unmarshall RPC_HDR_AUTH.\n")); return False; } if (auth_info.auth_type != RPC_SCHANNEL_AUTH_TYPE) { DEBUG(0,("Invalid auth info %d on schannel\n", auth_info.auth_type)); return False; } if(!smb_io_rpc_auth_schannel_chk("", RPC_AUTH_SCHANNEL_SIGN_OR_SEAL_CHK_LEN, &schannel_chk, rpc_in, 0)) { DEBUG(0,("failed to unmarshal RPC_AUTH_SCHANNEL_CHK.\n")); return False; } if (!schannel_decode(p->auth.a_u.schannel_auth, p->auth.auth_level, SENDER_IS_INITIATOR, &schannel_chk, prs_data_p(rpc_in)+RPC_HDR_REQ_LEN, data_len)) { DEBUG(3,("failed to decode PDU\n")); return False; } /* * Return the current pointer to the data offset. */ if(!prs_set_offset(rpc_in, save_offset)) { DEBUG(0,("failed to set offset back to %u\n", (unsigned int)save_offset )); return False; } /* The sequence number gets incremented on both send and receive. */ p->auth.a_u.schannel_auth->seq_num++; /* * Remember the padding length. We must remove it from the real data * stream once the sign/seal is done. */ *p_ss_padding_len = auth_info.auth_pad_len; return True; } /**************************************************************************** Return a user struct for a pipe user. ****************************************************************************/ struct current_user *get_current_user(struct current_user *user, pipes_struct *p) { if (p->pipe_bound && (p->auth.auth_type == PIPE_AUTH_TYPE_NTLMSSP || (p->auth.auth_type == PIPE_AUTH_TYPE_SPNEGO_NTLMSSP))) { memcpy(user, &p->pipe_user, sizeof(struct current_user)); } else { memcpy(user, ¤t_user, sizeof(struct current_user)); } return user; } /**************************************************************************** Find the set of RPC functions associated with this context_id ****************************************************************************/ static PIPE_RPC_FNS* find_pipe_fns_by_context( PIPE_RPC_FNS *list, uint32 context_id ) { PIPE_RPC_FNS *fns = NULL; PIPE_RPC_FNS *tmp = NULL; if ( !list ) { DEBUG(0,("find_pipe_fns_by_context: ERROR! No context list for pipe!\n")); return NULL; } for (tmp=list; tmp; tmp=tmp->next ) { if ( tmp->context_id == context_id ) break; } fns = tmp; return fns; } /**************************************************************************** Memory cleanup. ****************************************************************************/ void free_pipe_rpc_context( PIPE_RPC_FNS *list ) { PIPE_RPC_FNS *tmp = list; PIPE_RPC_FNS *tmp2; while (tmp) { tmp2 = tmp->next; SAFE_FREE(tmp); tmp = tmp2; } return; } /**************************************************************************** Find the correct RPC function to call for this request. If the pipe is authenticated then become the correct UNIX user before doing the call. ****************************************************************************/ BOOL api_pipe_request(pipes_struct *p) { BOOL ret = False; BOOL changed_user = False; PIPE_RPC_FNS *pipe_fns; if (p->pipe_bound && ((p->auth.auth_type == PIPE_AUTH_TYPE_NTLMSSP) || (p->auth.auth_type == PIPE_AUTH_TYPE_SPNEGO_NTLMSSP))) { if(!become_authenticated_pipe_user(p)) { prs_mem_free(&p->out_data.rdata); return False; } changed_user = True; } DEBUG(5, ("Requested \\PIPE\\%s\n", p->name)); /* get the set of RPC functions for this context */ pipe_fns = find_pipe_fns_by_context(p->contexts, p->hdr_req.context_id); if ( pipe_fns ) { set_current_rpc_talloc(p->mem_ctx); ret = api_rpcTNP(p, p->name, pipe_fns->cmds, pipe_fns->n_cmds); set_current_rpc_talloc(NULL); } else { DEBUG(0,("api_pipe_request: No rpc function table associated with context [%d] on pipe [%s]\n", p->hdr_req.context_id, p->name)); } if (changed_user) { unbecome_authenticated_pipe_user(); } return ret; } /******************************************************************* Calls the underlying RPC function for a named pipe. ********************************************************************/ BOOL api_rpcTNP(pipes_struct *p, const char *rpc_name, const struct api_struct *api_rpc_cmds, int n_cmds) { int fn_num; fstring name; uint32 offset1, offset2; /* interpret the command */ DEBUG(4,("api_rpcTNP: %s op 0x%x - ", rpc_name, p->hdr_req.opnum)); slprintf(name, sizeof(name)-1, "in_%s", rpc_name); prs_dump(name, p->hdr_req.opnum, &p->in_data.data); for (fn_num = 0; fn_num < n_cmds; fn_num++) { if (api_rpc_cmds[fn_num].opnum == p->hdr_req.opnum && api_rpc_cmds[fn_num].fn != NULL) { DEBUG(3,("api_rpcTNP: rpc command: %s\n", api_rpc_cmds[fn_num].name)); break; } } if (fn_num == n_cmds) { /* * For an unknown RPC just return a fault PDU but * return True to allow RPC's on the pipe to continue * and not put the pipe into fault state. JRA. */ DEBUG(4, ("unknown\n")); setup_fault_pdu(p, NT_STATUS(DCERPC_FAULT_OP_RNG_ERROR)); return True; } offset1 = prs_offset(&p->out_data.rdata); DEBUG(6, ("api_rpc_cmds[%d].fn == %p\n", fn_num, api_rpc_cmds[fn_num].fn)); /* do the actual command */ if(!api_rpc_cmds[fn_num].fn(p)) { DEBUG(0,("api_rpcTNP: %s: %s failed.\n", rpc_name, api_rpc_cmds[fn_num].name)); prs_mem_free(&p->out_data.rdata); return False; } if (p->bad_handle_fault_state) { DEBUG(4,("api_rpcTNP: bad handle fault return.\n")); p->bad_handle_fault_state = False; setup_fault_pdu(p, NT_STATUS(DCERPC_FAULT_CONTEXT_MISMATCH)); return True; } slprintf(name, sizeof(name)-1, "out_%s", rpc_name); offset2 = prs_offset(&p->out_data.rdata); prs_set_offset(&p->out_data.rdata, offset1); prs_dump(name, p->hdr_req.opnum, &p->out_data.rdata); prs_set_offset(&p->out_data.rdata, offset2); DEBUG(5,("api_rpcTNP: called %s successfully\n", rpc_name)); /* Check for buffer underflow in rpc parsing */ if ((DEBUGLEVEL >= 10) && (prs_offset(&p->in_data.data) != prs_data_size(&p->in_data.data))) { size_t data_len = prs_data_size(&p->in_data.data) - prs_offset(&p->in_data.data); char *data = SMB_MALLOC(data_len); DEBUG(10, ("api_rpcTNP: rpc input buffer underflow (parse error?)\n")); if (data) { prs_uint8s(False, "", &p->in_data.data, 0, (unsigned char *)data, (uint32)data_len); SAFE_FREE(data); } } return True; } /******************************************************************* *******************************************************************/ void get_pipe_fns( int idx, struct api_struct **fns, int *n_fns ) { struct api_struct *cmds = NULL; int n_cmds = 0; switch ( idx ) { #ifndef AVM_SMALLER case PI_LSARPC: lsa_get_pipe_fns( &cmds, &n_cmds ); break; case PI_LSARPC_DS: lsa_ds_get_pipe_fns( &cmds, &n_cmds ); break; case PI_SAMR: samr_get_pipe_fns( &cmds, &n_cmds ); break; case PI_NETLOGON: netlog_get_pipe_fns( &cmds, &n_cmds ); break; #endif /* AVM_SMALLER */ case PI_SRVSVC: srvsvc_get_pipe_fns( &cmds, &n_cmds ); break; case PI_WKSSVC: wkssvc_get_pipe_fns( &cmds, &n_cmds ); break; #ifndef AVM_SMALLER case PI_WINREG: reg_get_pipe_fns( &cmds, &n_cmds ); break; case PI_SPOOLSS: spoolss_get_pipe_fns( &cmds, &n_cmds ); break; case PI_NETDFS: netdfs_get_pipe_fns( &cmds, &n_cmds ); break; case PI_SVCCTL: svcctl_get_pipe_fns( &cmds, &n_cmds ); break; case PI_EVENTLOG: eventlog_get_pipe_fns( &cmds, &n_cmds ); break; case PI_NTSVCS: ntsvcs_get_pipe_fns( &cmds, &n_cmds ); break; #endif /* AVM_SMALLER */ #ifdef DEVELOPER case PI_ECHO: echo_get_pipe_fns( &cmds, &n_cmds ); break; #endif default: DEBUG(0,("get_pipe_fns: Unknown pipe index! [%d]\n", idx)); } *fns = cmds; *n_fns = n_cmds; return; }