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Presentation Layer Security

Presentation Layer Security. Lecture 7 Supakorn Kungpisdan supakorn@mut.ac.th. Roadmap. Introduction to Presentation Layer NetBIOS and SMB NetBIOS and Enumeration Sniffing Encrypted Traffic. Introduction to Presentation Layer. Presentation layer deals primarily with data representation

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Presentation Layer Security

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  1. Presentation Layer Security Lecture 7 Supakorn Kungpisdan supakorn@mut.ac.th NETE4630

  2. Roadmap • Introduction to Presentation Layer • NetBIOS and SMB • NetBIOS and Enumeration • Sniffing Encrypted Traffic NETE4630

  3. Introduction to Presentation Layer • Presentation layer deals primarily with data representation • If one host supports Extended Binary-coded Decimal Interchange Code (EBCDIC) for character sets and another supports ASCII, the presentation layer converts data according to each hosts’ needs • Other functionalities include data compression, data encryption, and manipulating XML objects NETE4630

  4. CIFS (or SMB) • Common Internet File System (CIFS), aka Server Message Block (SMB), is a network protocol for file sharing on a LAN, running at app/presentation layer • A client-server protocol • Rely on other protocols for transport • Most commonly used is NetBIOS over TCP (NBT) • MS Oses use CIFS for remote file operations (mapping network drives), browsing (via Network Neighborhood), authentication (NT, Win2000, 2003), and remote printer services • Unix Oses also implement CIFS via the Samba program NETE4630

  5. NetBIOS and SMB VS OSI NETE4630

  6. CIFS History • In 1984, IBM wrote NetBIOS, an API allowing basic network communications between hosts on a small subnet, but it required a transport protocol • The following year, IBM released a transport protocol that makes NetBIOS come to life • Both of them are merged into NetBIOS Enhanced User Interface (NetBEUI) • Later, NetBIOS was implemented using various transport protocols e.g. DECnet, IPX/SPF, and TCP/IP NETE4630

  7. CIFS History (cont.) • Soon after, MS and Intel created the 1st rendition of the SMB/CIFS file sharing protocol titled “Core Protocol” • MS and Intel chose NetBIOS to deliver the upper protocol CIFS packets • CIFS using NetBIOS over TCP became standard network file sharing mechanism for MS Oses • Several operations have been added to CIFS overtime: • File access • File and record locking • Safe file caching • File change notification • Protocol negotiation • Extended file attribute handling • Batched requests • Unicode support NETE4630

  8. NetBIOS • NetBIOS runs over many transport protocols, but recently TCP/IP is the most common transport protocol used • Main NetBIOS services: • Name service • Session service • Datagram service NETE4630

  9. NetBIOS Name Service • NetBIOS names are human readable names assigned to computers on a network • Commonly seen in Windows in Network Neighborhood • Serve the same purpose as the DNS system in TCP/IP, but different in the method • Operate on UDP port 137 NETE4630

  10. NetBIOS Name Services (cont.) • Broadcast and/or server based • Name registration and lookups can be accomplished by broadcasting to the LAN and/or using a central NetBIOS name server (NBNS or WINS) • Broadcast only (b-node) • NBNS only (p-node) • Broadcast first then NBNS (m-node) • NBNS first then broadcast (h-node) • Dynamic registration • With NetBIOS, when a computer boots, it registers its name/IP combination dynamically NETE4630

  11. NetBIOS Name Services (cont.) • Two most common NetBIOS name service are name registration and name query • Name registration associates a NetBIOS name with an IP • Name query determines the IP address associated with an given name NETE4630

  12. Name Registration (b-node) 1 1 2 1 1 • Broadcast name registration packet containing name and IP over UDP port 137 three times (waiting 250 ms each) • If a host has already registered the name, it sends back a defense packet back 2 NETE4630

  13. Name Registration (p-node) 1 2 • Unicast name registration packet over UDP port 137 directly to NBNS three times (waiting 250 ms each) • If the name is already registered, NBNS sends back a defense packet back 1 2 WINS server NETE4630

  14. Name Query (b-node) 1 1 2 1 1 • Broadcast name query request containing name over UDP port 137 three times (waiting 5 s each) • If a host has already registered the name, it sends back a defense packet back 2 NETE4630

  15. Name Query (p-node) 1 2 • Unicast name query request over UDP port 137 directly to NBNS three times (waiting 250 ms each) • If the name is already registered, NBNS sends back a defense packet back 1 2 WINS server NETE4630

  16. NetBIOS Session Service • From RFC1001, “A session is a reliable message exchange, conducted between pair of NetBIOS applications. Session is full-duplex, sequenced, and reliable” • CIFS uses the session service to send and receive all upper layer commands, including file and printer operations • The first step in any CIFS communications is to establish a NetBIOS session between client and server NETE4630

  17. Session Service Primitives • Call: Initiate a NetBIOS session • Create TCP connection and send a NetBIOS call packet containing the client’s NetBIOS name and the server’s NetBIOS name • Listen: Wait for a NetBIOS call command • Mapped a server waiting on TCP port 139 • Hang up: end a NetBIOS session • Mapped into TCP by initiating a TCP teardown sequence • Send: send a message over a NetBIOS session • Receive: receive a message from a NetBIOS session • Session status: obtain information about session NETE4630

  18. NetBIOS Datagram Service • From RFC1001, “The datagram service is unreliable, non-sequenced, connectionless service” • Used by NetBIOS application as a fast, broadcast-capable, low-overhead method of transferring data • Implemented on UDP port 138 • All NetBIOS datagram packets adds a header containing NetBIOS name and whether or not the NetBIOS datagram was fragmented to be sent via UDP • CIFS protocol standard does not implement NetBIOS datagram server, but CIFS implementations typically use it for browsing NETE4630

  19. CIFS Properties • CIFS allows file sharing between network nodes • Client/server + request/response • Allow multiple simultaneous requests be assigning multiplex id (MID) to each request • The server replies with the same MID • Command based • Each packet contains a command field indicating the packet purpose e.g. login, open a file, read from a file, or write to a file • CIFS packet contains a 1-byte command field allowing 100+ commands available NETE4630

  20. CIFS Properties (cont.) • Protocol dialects/negotiation • Allow different variants (dialects) of CIFS to communicate • When client wishes to access files on a remote server, client sends a negotiate protocol packet containing a list of dialect strings that it is capable of understanding. • The server sends back the response containing which dialect it wishes to communicate NETE4630

  21. SMB Variants (Dialects) Ref: http://samba.anu.edu.au/cifs/docs/what-is-smb.html NETE4630

  22. CIFS Properties (cont.) • User/share level security • User level security • A client wishing to access the share must provide a username and a password • Used in windows 2000 onwards • Share level security • The share itself requires only a password, but no username is required • Used in windows 95 and 98 NETE4630

  23. CIFS Properties (cont.) • Encryption • Password entered is sent in an encrypted format to server • NTLM and LM • Command batching • Many CIFS packets are capable of piggybacking other CIFS packets to reduce latency and better utilizing network bandwidth • This technique is referred as ANDX batching NETE4630

  24. CIFS Properties (cont.) • Opportunitistic locking (oplock) • When a CIFS packet specifies to open file, an oplock can be requested • If granted by server, no other entities can access the file NETE4630

  25. CIFS Packet Header NETE4630

  26. CIFS Operations • Two common CIFS client/server packet exchanges • Client initiates contact with a server • Client requires to open a file and read from it NETE4630

  27. Initial Contact, Login, and Tree Connect Establish NetBIOS session Server Client Positive NetBIOS session acknowledgement Negotiate CIFS dialect Choose CIFS dialect from request list User login Indicate User IF or returns error if bad password Connect to particular resource Indicate Tree ID or error if share name does not exist NETE4630

  28. File Open and Read Server Client Open a file Indicate File ID, or error code if problem Read from a file Return file data requested NETE4630

  29. SMB and SAMBA • SAMBA is a project established to provide free implementations of the SMB protocol for various platforms. • The SAMBA project has had to "reverse engineer" the protocols and continues to work in this manner in order to keep the software free. • Despite having released a version of SMB to the X-Open organization, Microsoft continues to develop the protocol as a proprietary protocol and details of some of the more recent versions have not been made freely available. NETE4630

  30. Null User Overview • At the core of the Windows authentication scheme lies the 'User' administrative unit. • When we create users, we assign them rights, privileges, and policy restrictions to define what they can and can't do on our networks. • But in addition to the standard User, Windows supports a special type of user called the 'Null' user, which is basically a pseudo-account that has no username or password, but is allowed to access certain information on the network • Some MS OSes and services used to require that you utilize the null user in order to operate properly NETE4630

  31. Null User Overview (cont.) • Null user can enumerate account names and shares on domain controllers, member servers, and workstations alike. • Therefore this null user, a user with no credentials, can be used to glean a tremendous amount of information from your network without raising any eyebrows NETE4630

  32. Null User Overview (cont.) • Microsoft's System Management Server uses the null user to enumerate shares during discovery. • Even the mundane action of starting a NT workstation or server creates an initial null user logon to one of your domain controllers after its NetBIOS name is successfully registered (before you get the Ctrl + Alt + Delete logon prompt) • System account uses the null user to get to remote resources NETE4630

  33. NetBIOS Enumeration • Null sessions allow users to communicate via NetBIOS in order to query any server as the null user • If this occurs, user’s can enumerate shares, users, groups, permissions, policies. They can probably brute force their way into the network • Many tools can be used to enumerate different aspects of a Windows server NETE4630

  34. enum • enum is a console-based Win32 information enumeration utility. • Using null sessions, enum can retrieve userlists, machine lists, sharelists, namelists, group and member lists, password and LSA policy information. • enum is also capable of a rudimentary brute force dictionary attack on individual accounts. Ref: http://www.cotse.com/tools/netbios.htm NETE4630

  35. enum (cont.) Get user list Get password policy No limit number of logon attempts NETE4630

  36. enum (cont.) Dictionary attack NETE4630

  37. Exploiting the IPC$ Share • Windows have hidden administrative shares that have $ at the end (e.g. C$, ADMIN$, IPC$). The system tells itself to omit this share from any request for the enumeration of shares • Interprocess Communication (IPC$) share is necessary to make systems work properly • IPC$ is used for data sharing between processes • In old versions of Windows (esp NT), users can exploit the use of IPC$ and other hidden shares through a null session • Once connected, the user may utilize the net view and net use command to browse and connect to the hidden shares on a machine NETE4630

  38. Exploiting the IPC$ Share (cont.) NETE4630

  39. winfo verbose C:\winfo\winfo 192.168.1.1 –v -n Establish a null session before dump data NETE4630

  40. Other NetBIOS Issues • An attacker can generate a fake packet to deny a host joining the network • Many vulnerabilities have been fixed in new Windows OSes, but several organizations still have legacy systems • Thus, these types of NetBIOS vulnerability still exist NETE4630

  41. Sniffing Encrypted Traffic • Obfuscation • Some utilize encryption and others use one-way function • Make it difficult to intercept a transmission of a message and retrieve it content • Base64 encoding • Not suitable for data protection (confidentiality) • No shared key between encode and decode functions NETE4630

  42. Sniffing Encrypted Traffic (cont.) • XOR encryption • Use shared key, provide more protection NETE4630

  43. Sniffing Encrypted Traffic (cont.) • Message Digest • MD5 and SHA-1 • Not an encryption algorithm • The premise for using digests and hashes is to make it difficult for a collision to occur, computationally infeasible to reproduce identical digests/hashes from different input • Most commonly used to obfuscate passwords • Vulnerable to brute-force and rainbow table attacks NETE4630

  44. Kerberos NETE4630

  45. Attacking Kerberos • Communications between C and AS is derived from user’s password • Windows computes a one-way function (OWF) against the password to generate the key • If the hash value is known, we can run a dictionary attack against the key  Known ciphertext attack • Security of Kerberos depends on how strong the password is NETE4630

  46. Attacking Kerberos (cont.) Hashed password NETE4630

  47. Attacking Kerberos (cont.) • Run Kerbsniff, a command-line utility to capture AS-REQ value to a text file NETE4630

  48. Attacking Kerberos (cont.) • Run Kerbcrack on the hashed password to recover the password Input file Dictionary attack NETE4630

  49. Attacking Weak Protection Schemes • Many people said that data protection requires strong cryptographic algorithms that can resist a dictionary or brute-force attack • However, much of the problems lies in selecting weak passwords • Weak protection scheme reduces the effort an attacker must take once the hash value is known NETE4630

  50. John the Ripper Downloaded at http://www.openwall.com/john/ NETE4630

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