/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright (c) 2007, 2010, Oracle and/or its affiliates. All rights reserved. * Copyright 2017 Nexenta Systems, Inc. All rights reserved. */ /* * Notes on the virtual circuit (VC) values in the SMB Negotiate * response and SessionSetupAndx request. * * A virtual circuit (VC) represents a connection between a client and a * server using a reliable, session oriented transport protocol, such as * NetBIOS or TCP/IP. Originally, each SMB session was restricted to a * single underlying transport connection, i.e. a single NetBIOS session, * which limited performance for raw data transfers. * * The intention behind multiple VCs was to improve performance by * allowing parallelism over each NetBIOS session. For example, raw data * could be transmitted using a different VC from other types of SMB * requests to remove the interleaving restriction while a raw transfer * is in progress. So the MaxNumberVcs field was added to the negotiate * response to make the number of VCs configurable and to allow servers * to specify how many they were prepared to support per session * connection. This turned out to be difficult to manage and, with * technology improvements, it has become obsolete. * * Servers should set the MaxNumberVcs value in the Negotiate response * to 1. Clients should probably ignore it. If a server receives a * SessionSetupAndx with a VC value of 0, it should close all other * VCs to that client. If it receives a non-zero VC, it should leave * other VCs in tact. * */ /* * SMB: negotiate * * Client Request Description * ============================ ======================================= * * UCHAR WordCount; Count of parameter words = 0 * USHORT ByteCount; Count of data bytes; min = 2 * struct { * UCHAR BufferFormat; 0x02 -- Dialect * UCHAR DialectName[]; ASCII null-terminated string * } Dialects[]; * * The Client sends a list of dialects that it can communicate with. The * response is a selection of one of those dialects (numbered 0 through n) * or -1 (hex FFFF) indicating that none of the dialects were acceptable. * The negotiate message is binding on the virtual circuit and must be * sent. One and only one negotiate message may be sent, subsequent * negotiate requests will be rejected with an error response and no action * will be taken. * * The protocol does not impose any particular structure to the dialect * strings. Implementors of particular protocols may choose to include, * for example, version numbers in the string. * * If the server does not understand any of the dialect strings, or if PC * NETWORK PROGRAM 1.0 is the chosen dialect, the response format is * * Server Response Description * ============================ ======================================= * * UCHAR WordCount; Count of parameter words = 1 * USHORT DialectIndex; Index of selected dialect * USHORT ByteCount; Count of data bytes = 0 * * If the chosen dialect is greater than core up to and including * LANMAN2.1, the protocol response format is * * Server Response Description * ============================ ======================================= * * UCHAR WordCount; Count of parameter words = 13 * USHORT DialectIndex; Index of selected dialect * USHORT SecurityMode; Security mode: * bit 0: 0 = share, 1 = user * bit 1: 1 = use challenge/response * authentication * USHORT MaxBufferSize; Max transmit buffer size (>= 1024) * USHORT MaxMpxCount; Max pending multiplexed requests * USHORT MaxNumberVcs; Max VCs between client and server * USHORT RawMode; Raw modes supported: * bit 0: 1 = Read Raw supported * bit 1: 1 = Write Raw supported * ULONG SessionKey; Unique token identifying this session * SMB_TIME ServerTime; Current time at server * SMB_DATE ServerDate; Current date at server * USHORT ServerTimeZone; Current time zone at server * USHORT EncryptionKeyLength; MBZ if this is not LM2.1 * USHORT Reserved; MBZ * USHORT ByteCount Count of data bytes * UCHAR EncryptionKey[]; The challenge encryption key * STRING PrimaryDomain[]; The server's primary domain * * MaxBufferSize is the size of the largest message which the client can * legitimately send to the server * * If bit0 of the Flags field is set in the negotiate response, this * indicates the server supports the SMB_COM_LOCK_AND_READ and * SMB_COM_WRITE_AND_UNLOCK client requests. * * If the SecurityMode field indicates the server is running in user mode, * the client must send appropriate SMB_COM_SESSION_SETUP_ANDX requests * before the server will allow the client to access resources. If the * SecurityMode fields indicates the client should use challenge/response * authentication, the client should use the authentication mechanism * specified in section 2.10. * * Clients should submit no more than MaxMpxCount distinct unanswered SMBs * to the server when using multiplexed reads or writes (see sections 5.13 * and 5.25) * * Clients using the "MICROSOFT NETWORKS 1.03" dialect use a different * form of raw reads than documented here, and servers are better off * setting RawMode in this response to 0 for such sessions. * * If the negotiated dialect is "DOS LANMAN2.1" or "LANMAN2.1", then * PrimaryDomain string should be included in this response. * * If the negotiated dialect is NT LM 0.12, the response format is * * Server Response Description * ========================== ========================================= * * UCHAR WordCount; Count of parameter words = 17 * USHORT DialectIndex; Index of selected dialect * UCHAR SecurityMode; Security mode: * bit 0: 0 = share, 1 = user * bit 1: 1 = encrypt passwords * USHORT MaxMpxCount; Max pending multiplexed requests * USHORT MaxNumberVcs; Max VCs between client and server * ULONG MaxBufferSize; Max transmit buffer size * ULONG MaxRawSize; Maximum raw buffer size * ULONG SessionKey; Unique token identifying this session * ULONG Capabilities; Server capabilities * ULONG SystemTimeLow; System (UTC) time of the server (low). * ULONG SystemTimeHigh; System (UTC) time of the server (high). * USHORT ServerTimeZone; Time zone of server (min from UTC) * UCHAR EncryptionKeyLength; Length of encryption key. * USHORT ByteCount; Count of data bytes * UCHAR EncryptionKey[]; The challenge encryption key * UCHAR OemDomainName[]; The name of the domain (in OEM chars) * * In addition to the definitions above, MaxBufferSize is the size of the * largest message which the client can legitimately send to the server. * If the client is using a connectionless protocol, MaxBufferSize must be * set to the smaller of the server's internal buffer size and the amount * of data which can be placed in a response packet. * * MaxRawSize specifies the maximum message size the server can send or * receive for SMB_COM_WRITE_RAW or SMB_COM_READ_RAW. * * Connectionless clients must set Sid to 0 in the SMB request header. * * Capabilities allows the server to tell the client what it supports. * The bit definitions defined in smb.h. Bit 0x2000 used to be set in * the negotiate response capabilities but it caused problems with * Windows 2000. It is probably not valid, it doesn't appear in the * CIFS spec. * * 4.1.1.1 Errors * * SUCCESS/SUCCESS * ERRSRV/ERRerror */ #include #include #include #include #include static const smb_xlate_t smb_dialect[] = { { DIALECT_UNKNOWN, "DIALECT_UNKNOWN" }, { PC_NETWORK_PROGRAM_1_0, "PC NETWORK PROGRAM 1.0" }, { PCLAN1_0, "PCLAN1.0" }, { MICROSOFT_NETWORKS_1_03, "MICROSOFT NETWORKS 1.03" }, { MICROSOFT_NETWORKS_3_0, "MICROSOFT NETWORKS 3.0" }, { LANMAN1_0, "LANMAN1.0" }, { LM1_2X002, "LM1.2X002" }, { DOS_LM1_2X002, "DOS LM1.2X002" }, { DOS_LANMAN2_1, "DOS LANMAN2.1" }, { LANMAN2_1, "LANMAN2.1" }, { Windows_for_Workgroups_3_1a, "Windows for Workgroups 3.1a" }, { NT_LM_0_12, "NT LM 0.12" }, { DIALECT_SMB2002, "SMB 2.002" }, { DIALECT_SMB2XXX, "SMB 2.???" }, }; static int smb_ndialects = sizeof (smb_dialect) / sizeof (smb_dialect[0]); /* * Maximum buffer size for DOS: chosen to be the same as NT. * Do not change this value, DOS is very sensitive to it. */ #define SMB_DOS_MAXBUF 0x1104 /* * The DOS TCP rcvbuf is set to 8700 because DOS 6.1 seems to have problems * with other values. DOS 6.1 seems to depend on a window value of 8700 to * send the next set of data. If we return a window value of 40KB, after * sending 8700 bytes of data, it will start the next set of data from 40KB * instead of 8.7k. Why 8.7k? We have no idea; it is the value that NT uses. * September 2000. * * IR104720 Increased smb_nt_tcp_rcvbuf from 40KB to just under 1MB to allow * for a larger TCP window sizei based on observations of Windows 2000 and * performance testing. March 2003. */ static uint32_t smb_dos_tcp_rcvbuf = 8700; static uint32_t smb_nt_tcp_rcvbuf = 1048560; /* scale factor of 4 */ /* * Maximum number of simultaneously pending SMB requests allowed on * one connection. This is like "credits" in SMB2, but SMB1 uses a * fixed limit, having no way to request an increase like SMB2 does. * Note: Some older clients only handle the low byte of this value, * so this value should be less than 256. */ static uint16_t smb_maxmpxcount = 64; static int smb_xlate_dialect(const char *); /* * "Capabilities" offered by SMB1 Negotiate Protocol. * See smb.h for descriptions. * * CAP_RAW_MODE, CAP_MPX_MODE are obsolete. * UNICODE support is required for long share names, * long file names and streams. * * For testing, one can patch this, i.e. remove the high bit to * temporarily disable extended security, etc. */ uint32_t smb1srv_capabilities = CAP_UNICODE | CAP_LARGE_FILES | CAP_NT_SMBS | CAP_RPC_REMOTE_APIS | CAP_STATUS32 | CAP_LEVEL_II_OPLOCKS | CAP_LOCK_AND_READ | CAP_NT_FIND | CAP_DFS | CAP_INFOLEVEL_PASSTHRU | CAP_LARGE_READX | CAP_LARGE_WRITEX | CAP_EXTENDED_SECURITY; /* * SMB Negotiate gets special handling. This is called directly by * the reader thread (see smbsr_newrq_initial) with what _should_ be * an SMB1 Negotiate. Only the "\ffSMB" header has been checked * when this is called, so this needs to check the SMB command, * if it's Negotiate execute it, then send the reply, etc. * * Since this is called directly from the reader thread, we * know this is the only thread currently using this session. * This has to duplicate some of what smb1sr_work does as a * result of bypassing the normal dispatch mechanism. * * The caller always frees this request. * * Return value is 0 for success, and anything else will * terminate the reader thread (drop the connection). */ int smb1_newrq_negotiate(smb_request_t *sr) { smb_sdrc_t sdrc; uint16_t pid_hi, pid_lo; /* * Decode the header */ if (smb_mbc_decodef(&sr->command, SMB_HEADER_ED_FMT, &sr->smb_com, &sr->smb_rcls, &sr->smb_reh, &sr->smb_err, &sr->smb_flg, &sr->smb_flg2, &pid_hi, sr->smb_sig, &sr->smb_tid, &pid_lo, &sr->smb_uid, &sr->smb_mid) != 0) return (-1); if (sr->smb_com != SMB_COM_NEGOTIATE) return (-1); sr->smb_pid = (pid_hi << 16) | pid_lo; /* * Reserve space for the reply header. */ (void) smb_mbc_encodef(&sr->reply, "#.", SMB_HEADER_LEN); sr->first_smb_com = sr->smb_com; if (smb_mbc_decodef(&sr->command, "b", &sr->smb_wct) != 0) return (-1); (void) MBC_SHADOW_CHAIN(&sr->smb_vwv, &sr->command, sr->command.chain_offset, sr->smb_wct * 2); if (smb_mbc_decodef(&sr->command, "#.w", sr->smb_wct*2, &sr->smb_bcc)) return (-1); (void) MBC_SHADOW_CHAIN(&sr->smb_data, &sr->command, sr->command.chain_offset, sr->smb_bcc); sr->command.chain_offset += sr->smb_bcc; if (sr->command.chain_offset > sr->command.max_bytes) return (-1); /* Store pointers for later */ sr->cur_reply_offset = sr->reply.chain_offset; sdrc = smb_pre_negotiate(sr); if (sdrc == SDRC_SUCCESS) sdrc = smb_com_negotiate(sr); smb_post_negotiate(sr); if (sdrc != SDRC_NO_REPLY) smbsr_send_reply(sr); if (sdrc == SDRC_DROP_VC) return (-1); return (0); } smb_sdrc_t smb_pre_negotiate(smb_request_t *sr) { smb_kmod_cfg_t *skc; smb_arg_negotiate_t *negprot; int dialect; int pos; int rc = 0; skc = &sr->session->s_cfg; negprot = smb_srm_zalloc(sr, sizeof (smb_arg_negotiate_t)); negprot->ni_index = -1; sr->sr_negprot = negprot; for (pos = 0; smbsr_decode_data_avail(sr); pos++) { if (smbsr_decode_data(sr, "%L", sr, &negprot->ni_name) != 0) { smbsr_error(sr, 0, ERRSRV, ERRerror); rc = -1; break; } if ((dialect = smb_xlate_dialect(negprot->ni_name)) < 0) continue; /* * Conditionally recognize the SMB2 dialects. */ if (dialect >= DIALECT_SMB2002 && skc->skc_max_protocol < SMB_VERS_2_BASE) continue; /* * We may not support SMB1; skip those dialects if true. */ if (dialect < DIALECT_SMB2002 && skc->skc_min_protocol > SMB_VERS_1) continue; if (dialect == DIALECT_SMB2002 && skc->skc_min_protocol > SMB_VERS_2_002) continue; if (negprot->ni_dialect < dialect) { negprot->ni_dialect = dialect; negprot->ni_index = pos; } } DTRACE_SMB_START(op__Negotiate, smb_request_t *, sr); return ((rc == 0) ? SDRC_SUCCESS : SDRC_ERROR); } void smb_post_negotiate(smb_request_t *sr) { smb_arg_negotiate_t *negprot = sr->sr_negprot; DTRACE_SMB_DONE(op__Negotiate, smb_request_t *, sr); bzero(negprot, sizeof (smb_arg_negotiate_t)); } smb_sdrc_t smb_com_negotiate(smb_request_t *sr) { smb_session_t *session = sr->session; smb_arg_negotiate_t *negprot = sr->sr_negprot; uint16_t secmode; uint32_t sesskey; char *nbdomain; uint8_t *wcbuf; int wclen; smb_msgbuf_t mb; int rc; if (session->s_state != SMB_SESSION_STATE_ESTABLISHED) { /* The protocol has already been negotiated. */ smbsr_error(sr, 0, ERRSRV, ERRerror); return (SDRC_ERROR); } if (negprot->ni_index < 0) { cmn_err(CE_NOTE, "clnt %s no supported dialect", sr->session->ip_addr_str); smbsr_error(sr, 0, ERRSRV, ERRerror); return (SDRC_DROP_VC); } /* * Special case for negotiating SMB2 from SMB1. The client * includes the "SMB 2..." dialects in the SMB1 negotiate, * and if SMB2 is enabled, we choose one of those and then * send an SMB2 reply to that SMB1 request. Yes, it's very * strange, but this SMB1 request can have an SMB2 reply! * To accomplish this, we let the SMB2 code send the reply * and return the special code SDRC_NO_REPLY to the SMB1 * dispatch logic so it will NOT send an SMB1 reply. * (Or possibly send an SMB1 error reply.) */ if (negprot->ni_dialect >= DIALECT_SMB2002) { rc = smb1_negotiate_smb2(sr); ASSERT(rc == SDRC_NO_REPLY || rc == SDRC_DROP_VC || rc == SDRC_ERROR); return (rc); } session->srv_secmode = NEGOTIATE_ENCRYPT_PASSWORDS | NEGOTIATE_USER_SECURITY; secmode = session->srv_secmode; sesskey = session->sesskey; negprot->ni_servertime.tv_sec = gethrestime_sec(); negprot->ni_servertime.tv_nsec = 0; negprot->ni_tzcorrection = sr->sr_gmtoff / 60; negprot->ni_maxmpxcount = smb_maxmpxcount; negprot->ni_keylen = SMB_CHALLENGE_SZ; bcopy(&session->challenge_key, negprot->ni_key, SMB_CHALLENGE_SZ); nbdomain = sr->sr_cfg->skc_nbdomain; negprot->ni_capabilities = smb1srv_capabilities; switch (negprot->ni_dialect) { case PC_NETWORK_PROGRAM_1_0: /* core */ (void) ksocket_setsockopt(session->sock, SOL_SOCKET, SO_RCVBUF, (const void *)&smb_dos_tcp_rcvbuf, sizeof (smb_dos_tcp_rcvbuf), CRED()); rc = smbsr_encode_result(sr, 1, 0, "bww", 1, negprot->ni_index, 0); break; case Windows_for_Workgroups_3_1a: case PCLAN1_0: case MICROSOFT_NETWORKS_1_03: case MICROSOFT_NETWORKS_3_0: case LANMAN1_0: case LM1_2X002: case DOS_LM1_2X002: (void) ksocket_setsockopt(session->sock, SOL_SOCKET, SO_RCVBUF, (const void *)&smb_dos_tcp_rcvbuf, sizeof (smb_dos_tcp_rcvbuf), CRED()); sr->smb_flg |= SMB_FLAGS_LOCK_AND_READ_OK; rc = smbsr_encode_result(sr, 13, VAR_BCC, "bwwwwwwlYww2.w#c", 13, /* wct */ negprot->ni_index, /* dialect index */ secmode, /* security mode */ SMB_DOS_MAXBUF, /* max buffer size */ 1, /* max MPX */ 1, /* max VCs */ 0, /* read/write raw */ sesskey, /* session key */ negprot->ni_servertime.tv_sec, /* server date/time */ negprot->ni_tzcorrection, (uint16_t)negprot->ni_keylen, /* encryption key length */ /* reserved field handled 2. */ VAR_BCC, (int)negprot->ni_keylen, negprot->ni_key); /* encryption key */ break; case DOS_LANMAN2_1: case LANMAN2_1: (void) ksocket_setsockopt(session->sock, SOL_SOCKET, SO_RCVBUF, (const void *)&smb_dos_tcp_rcvbuf, sizeof (smb_dos_tcp_rcvbuf), CRED()); sr->smb_flg |= SMB_FLAGS_LOCK_AND_READ_OK; rc = smbsr_encode_result(sr, 13, VAR_BCC, "bwwwwwwlYww2.w#cs", 13, /* wct */ negprot->ni_index, /* dialect index */ secmode, /* security mode */ SMB_DOS_MAXBUF, /* max buffer size */ 1, /* max MPX */ 1, /* max VCs */ 0, /* read/write raw */ sesskey, /* session key */ negprot->ni_servertime.tv_sec, /* server date/time */ negprot->ni_tzcorrection, (uint16_t)negprot->ni_keylen, /* encryption key length */ /* reserved field handled 2. */ VAR_BCC, (int)negprot->ni_keylen, negprot->ni_key, /* encryption key */ nbdomain); break; case NT_LM_0_12: (void) ksocket_setsockopt(session->sock, SOL_SOCKET, SO_RCVBUF, (const void *)&smb_nt_tcp_rcvbuf, sizeof (smb_nt_tcp_rcvbuf), CRED()); /* * Allow SMB signatures if using encrypted passwords */ if ((secmode & NEGOTIATE_ENCRYPT_PASSWORDS) && sr->sr_cfg->skc_signing_enable) { secmode |= NEGOTIATE_SECURITY_SIGNATURES_ENABLED; if (sr->sr_cfg->skc_signing_required) secmode |= NEGOTIATE_SECURITY_SIGNATURES_REQUIRED; session->srv_secmode = secmode; } /* * Does the client want Extended Security? * (and if we have it enabled) * If so, handle as if a different dialect. */ if ((sr->smb_flg2 & SMB_FLAGS2_EXT_SEC) != 0 && (negprot->ni_capabilities & CAP_EXTENDED_SECURITY) != 0) goto NT_LM_0_12_ext_sec; /* Else deny knowledge of extended security. */ sr->smb_flg2 &= ~SMB_FLAGS2_EXT_SEC; negprot->ni_capabilities &= ~CAP_EXTENDED_SECURITY; /* * nbdomain is not expected to be aligned. * Use temporary buffer to avoid alignment padding */ wclen = smb_wcequiv_strlen(nbdomain) + sizeof (smb_wchar_t); wcbuf = smb_srm_zalloc(sr, wclen); smb_msgbuf_init(&mb, wcbuf, wclen, SMB_MSGBUF_UNICODE); if (smb_msgbuf_encode(&mb, "U", nbdomain) < 0) { smb_msgbuf_term(&mb); smbsr_error(sr, 0, ERRSRV, ERRerror); return (SDRC_ERROR); } rc = smbsr_encode_result(sr, 17, VAR_BCC, "bwbwwllllTwbw#c#c", 17, /* wct */ negprot->ni_index, /* dialect index */ secmode, /* security mode */ negprot->ni_maxmpxcount, /* max MPX */ 1, /* max VCs */ (DWORD)smb_maxbufsize, /* max buffer size */ 0xFFFF, /* max raw size */ sesskey, /* session key */ negprot->ni_capabilities, &negprot->ni_servertime, /* system time */ negprot->ni_tzcorrection, negprot->ni_keylen, /* encryption key length */ VAR_BCC, (int)negprot->ni_keylen, negprot->ni_key, /* encryption key */ wclen, wcbuf); /* nbdomain (unicode) */ smb_msgbuf_term(&mb); break; NT_LM_0_12_ext_sec: /* * This is the "Extended Security" variant of * dialect NT_LM_0_12. */ rc = smbsr_encode_result(sr, 17, VAR_BCC, "bwbwwllllTwbw#c#c", 17, /* wct */ negprot->ni_index, /* dialect index */ secmode, /* security mode */ negprot->ni_maxmpxcount, /* max MPX */ 1, /* max VCs */ (DWORD)smb_maxbufsize, /* max buffer size */ 0xFFFF, /* max raw size */ sesskey, /* session key */ negprot->ni_capabilities, &negprot->ni_servertime, /* system time */ negprot->ni_tzcorrection, 0, /* encryption key length (MBZ) */ VAR_BCC, UUID_LEN, sr->sr_cfg->skc_machine_uuid, sr->sr_cfg->skc_negtok_len, sr->sr_cfg->skc_negtok); break; default: rc = smbsr_encode_result(sr, 1, 0, "bww", 1, -1, 0); break; } if (rc != 0) return (SDRC_ERROR); /* * Save the agreed dialect. Note that the state is also * used to detect and reject attempts to re-negotiate. */ session->dialect = negprot->ni_dialect; session->s_state = SMB_SESSION_STATE_NEGOTIATED; /* Allow normal SMB1 requests now. */ session->newrq_func = smb1sr_newrq; return (SDRC_SUCCESS); } static int smb_xlate_dialect(const char *dialect) { const smb_xlate_t *dp; int i; for (i = 0; i < smb_ndialects; ++i) { dp = &smb_dialect[i]; if (strcmp(dp->str, dialect) == 0) return (dp->code); } return (-1); }