DOS ATTACKS bY tCp_sU|C|DE FOREWORD .A. INTRODUCTION .A.1. WHAT IS A DENIAL OF SERVICE ATTACK? . A.2. WHY WOULD SOMEONE CRASH A SYSTEM? .A.2.1. INTRODUCTION . A.2.2. SUB-CULTURAL STATUS . A.2.3. TO GAIN ACCESS .A.2.4. REVENGE .A.2.5. POLITICAL REASONS .A.2.6. ECONOMICAL REASONS .A.2.7. NASTINESS .A.3. ARE SOME OPERATING SYSTEMS MORE SECURE? .B. SOME BASIC TARGETS FOR AN ATTACK .B.1. SWAP SPACE . B.2. BANDWIDTH . B.3. KERNEL TABLES . B.4. RAM .B.5. DISKS . B.6. CACHES . B.7. INETD . C. ATTACKING FROM THE OUTSIDE . C.1. TAKING ADVANTAGE OF FINGER . C.2. UDP AND SUNOS 4.1.3. .C.3. FREEZING UP X-WINDOWS . C.4. MALICIOUS USE OF UDP SERVICES . C.5. ATTACKING WITH LYNX CLIENTS . C.6. MALICIOUS USE OF telnet . C.7. MALICIOUS USE OF telnet UNDER SOLARIS 2.4 . C.8. HOW TO DISABLE ACCOUNTS . C.9. LINUX AND TCP TIME, DAYTIME . C.10. HOW TO DISABLE SERVICES . C.11. PARAGON OS BETA R1.4 . C.12. NOVELLS NETWARE FTP . C.13. ICMP REDIRECT ATTACKS . C.14. BROADCAST STORMS . C.15. EMAIL BOMBING AND SPAMMING . C.16. TIME AND KERBEROS . C.17. THE DOT DOT BUG . C.18. SUNOS KERNEL PANIC . C.19. HOSTILE APPLETS . C.20. VIRUS . C.21. ANONYMOUS FTP ABUSE . C.22. SYN FLOODING . C.23. PING FLOODING . C.24. CRASHING SYSTEMS WITH PING FROM WINDOWS 95 MACHINES C.25. MALICIOUS USE OF SUBNET MASK REPLY MESSAGE . C.26. FLEXlm . C.27. BOOTING WITH TRIVIAL FTP D. ATTACKING FROM THE INSIDE . D.1. KERNEL PANIC UNDER SOLARIS 2.3 . D.2. CRASHING THE X-SERVER . D.3. FILLING UP THE HARD DISK . D.4. MALICIOUS USE OF eval . D.5. MALICIOUS USE OF fork() . D.6. CREATING FILES THAT IS HARD TO REMOVE . D.7. DIRECTORY NAME LOOKUPCACHE . D.8. CSH ATTACK . D.9. CREATING FILES IN /tmp . D.10. USING RESOLV_HOST_CONF . D.11. SUN 4.X AND BACKGROUND JOBS . D.12. CRASHING DG/UX WITH ULIMIT . D.13. NETTUNE AND HP-UX . . A. INTRODUCTION A.1. WHAT IS A DENIAL OF SERVICE ATTACK? Denial of service is about without permission knocking off services, for example through crashing the whole system. This kind of attacks are easy to launch and it is hard to protect a system against them. The basic problem is that Unix assumes that users on the system or on other systems will be well behaved. . A.2. WHY WOULD SOMEONE CRASH A SYSTEM? A.2.1. INTRODUCTION Why would someone crash a system? I can think of several reasons that I have presentated more precisely in a section for each reason, but for short: .1. Sub-cultural status. .2. To gain access. .3. Revenge. .4. Political reasons. .5. Economical reasons. .6. Nastiness. I think that number one and six are the more common today, but that number four and five will be the more common ones in the future. . A.2.2. SUB-CULTURAL STATUS After all information about syn flooding a bunch of such attacks were launched around Sweden. The very most of these attacks were not a part of a IP-spoof attack, it was "only" a denial of service attack. Why? I think that hackers attack systems as a sub-cultural pseudo career and I think that many denial of service attacks, and here in the example syn flooding, were performed for these reasons. I also think that many hackers begin their carrer with denial of service attacks. . A.2.3. TO GAIN ACCESS Sometimes could a denial of service attack be a part of an attack to gain access at a system. At the moment I can think of these reasons and specific holes: .1. Some older X-lock versions could be crashed with a method from the denial of service family leaving the system open. Physical access was needed to use the work space after. .2. Syn flooding could be a part of a IP-spoof attack method. .3. Some program systems could have holes under the startup, that could be used to gain root, for example SSH (secure shell). .4. Under an attack it could be usable to crash other machines in the network or to deny certain persons the ability to access the system. .5. Also could a system being booted sometimes be subverted, especially rarp-boots. If we know which port the machine listen to (69 could be a good guess) under the boot we can send false packets to it and almost totally control the boot. . A.2.4. REVENGE A denial of service attack could be a part of a revenge against a user or an administrator. . A.2.5. POLITICAL REASONS Sooner or later will new or old organizations understand the potential of destroying computer systems and find tools to do it. For example imaginate the Bank A loaning company B money to build a factory threating the environment. The organization C therefor crash A:s computer system, maybe with help from an employee. The attack could cost A a great deal of money if the timing is right. . A.2.6. ECONOMICAL REASONS Imaginate the small company A moving into a business totally dominated by company B. A and B customers make the orders by computers and depends heavily on that the order is done in a specific time (A and B could be stock trading companies). If A and B can't perform the order the customers lose money and change company. As a part of a business strategy A pays a computer expert a sum of money to get him to crash B:s computer systems a number of times. A year later A is the dominating company. . A.2.7. NASTINESS I know a person that found a workstation where the user had forgotten to logout. He sat down and wrote a program that made a kill -9 -1 at a random time at least 30 minutes after the login time and placed a call to the program from the profile file. That is nastiness. . A.3. ARE SOME OPERATING SYSTEMS MORE SECURE? This is a hard question to answer and I don't think that it will give anything to compare different Unix platforms. You can't say that one Unix is more secure against denial of service, it is all up to the administrator. A comparison between Windows 95 and NT on one side and Unix on the other could however be interesting. Unix systems are much more complex and have hundreds of built in programs, services... This always open up many ways to crash the system from the inside. In the normal Windows NT and 95 network were is few ways to crash the system. Although were is methods that always will work. That gives us that no big different between Microsoft and Unix can be seen regardning the inside attacks. But there is a couple of points left: - Unix have much more tools and programs to discover an attack and monitoring the users. To watch what another user is up to under windows is very hard. - The average Unix administrator probably also have much more experience than the average Microsoft administrator. The two last points gives that Unix is more secure against inside denial of service attacks. A comparison between Microsoft and Unix regarding outside attacks are much more difficult. However I would like to say that the average Microsoft system on the Internet are more secure against outside attacks, because they normally have much less services. . B. SOME BASIC TARGETS FOR AN ATTACK B.1. SWAP SPACE Most systems have several hundred Mbytes of swap space to service client requests. The swap space is typical used for forked child processes which have a short life time. The swap space will therefore almost never in a normal cause be used heavily. A denial of service could be based on a method that tries to fill up the swap space. B.2. BANDWIDTH If the bandwidth is to high the network will be useless. Most denial of service attack influence the bandwidth in some way. B.3. KERNEL TABLES It is trivial to overflow the kernel tables which will cause serious problems on the system. Systems with write through caches and small write buffers is especially sensitive. Kernel memory allocation is also a target that is sensitive. The kernel have a kernelmap limit, if the system reach this limit it can not allocate more kernel memory and must be rebooted. The kernel memory is not only used for RAM, CPU:s, screens and so on, it it also used for ordinaries processes. Meaning that any system can be crashed and with a mean (or in some sense good) algorithm pretty fast. For Solaris 2.X it is measured and reported with the sar command how much kernel memory the system is using, but for SunOS 4.X there is no such command. Meaning that under SunOS 4.X you don't even can get a warning. If you do use Solaris you should write sar -k 1 to get the information. netstat -k can also be used and shows how much memory the kernel have allocated in the subpaging. . B.4. RAM A denial of service attack that allocates a large amount of RAM can make a great deal of problems. NFS and mail servers are actually extremely sensitive because they do not need much RAM and therefore often don't have much RAM. An attack at a NFS server is trivial. The normal NFS client will do a great deal of caching, but a NFS client can be anything including the program you wrote yourself... . B.5. DISKS A classic attack is to fill up the hard disk, but an attack at the disks can be so much more. For example can an overloaded disk be misused in many ways. . B.6. CACHES A denial of service attack involving caches can be based on a method to block the cache or to avoid the cache. These caches are found on Solaris 2.X: Directory name lookup cache: Associates the name of a file with a vnode. Inode cache: Cache information read from disk in case it is needed again. Rnode cache: Holds information about the NFS filesystem. Buffer cache: Cache inode indirect blocks and cylinders to realed disk I/O. . B.7. INETD Well once inetd crashed all other services running through inetd no longer will work. . C. ATTACKING FROM THE OUTSIDE C.1. TAKING ADVANTAGE OF FINGER Most fingerd installations support redirections to an other host. Ex: $finger @system.two.com@system.one.com finger will in the example go through system.one.com and on to system.two.com. As far as system.two.com knows it is system.one.com who is fingering. So this method can be used for hiding, but also for a very dirty denial of service attack. Lock at this: $ finger @@@ @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@host.we.attack All those @ signs will get finger to finger host.we.attack again and again and again... The effect on host.we.attack is powerful and the result is high bandwidth, short free memory and a hard disk with less free space, due to all child processes (compare with .D.5.). The solution is to install a fingerd which don't support redirections, for example GNU finger. You could also turn the finger service off, but I think that is just a bit to much. . C.2. UDP AND SUNOS 4.1.3. SunOS 4.1.3. is known to boot if a packet with incorrect information in the header is sent to it. This is the cause if the ip_options indicate a wrong size of the packet. The solution is to install the proper patch. .C.3. FREEZING UP X-WINDOWS If a host accepts a telnet session to the X-Windows port (generally somewhere between 6000 and 6025. In most cases 6000) could that be used to freeze up the X-Windows system. This can be made with multiple telnet connections to the port or with a program which sends multiple XOpenDisplay() to the port. The same thing can happen to Motif or Open Windows. The solution is to deny connections to the X-Windows port. . C.4. MALICIOUS USE OF UDP SERVICES It is simple to get UDP services (echo, time, daytime, chargen) to loop, due to trivial IP-spoofing. The effect can be high bandwidth that causes the network to become useless. In the example the header claim that the packet came from 127.0.0.1 (loopback) and the target is the echo port at system.we.attack. As far as system.we.attack knows is 127.0.0.1 system.we.attack and the loop has been establish. Ex: from-IP=127.0.0.1 to-IP=system.we.attack Packet type:UDP from UDP port 7 to UDP port 7 Note that the name system.we.attack looks like a DNS-name, but the target should always be represented by the IP-number. Quoted from proberts@clark.net (Paul D. Robertson) comment on comp.security.firewalls on matter of "Introduction to denial of service" " A great deal of systems don't put loopback on the wire, and simply emulate it. Therefore, this attack will only effect that machine in some cases. It's much better to use the address of a different machine on the same network. Again, the default services should be disabled in inetd.conf. Other than some hacks for mainframe IP stacks that don't support ICMP, the echo service isn't used by many legitimate programs, and TCP echo should be used instead of UDP where it is necessary. " . C.5. ATTACKING WITH LYNX CLIENTS A World Wide Web server will fork an httpd process as a respond to a request from a client, typical Netscape or Mosaic. The process lasts for less than one second and the load will therefore never show up if someone uses ps. In most causes it is therefore very safe to launch a denial of service attack that makes use of multiple W3 clients, typical lynx clients. But note that the netstat command could be used to detect the attack (thanks to Paul D. Robertson). Some httpd:s (for example http-gw) will have problems besides the normal high bandwidth, low memory... And the attack can in those causes get the server to loop (compare with .C.6.) . C.6. MALICIOUS USE OF telnet Study this little script: Ex: while : ; do telnet system.we.attack & done An attack using this script might eat some bandwidth, but it is nothing compared to the finger method or most other methods. Well the point is that some pretty common firewalls and httpd:s thinks that the attack is a loop and turn them self down, until the administrator sends kill -HUP. This is a simple high risk vulnerability that should be checked and if present fixed. . C.7. MALICIOUS USE OF telnet UNDER SOLARIS 2.4 If the attacker makes a telnet connections to the Solaris 2.4 host and quits using: Ex: Control-} quit then will inetd keep going "forever". Well a couple of hundred... The solution is to install the proper patch. . C.8. HOW TO DISABLE ACCOUNTS Some systems disable an account after N number of bad logins, or waits N seconds. You can use this feature to lock out specific users from the system. . C.9. LINUX AND TCP TIME, DAYTIME Inetd under Linux is known to crash if to many SYN packets sends to daytime (port 13) and/or time (port 37). The solution is to install the proper patch. . C.10. HOW TO DISABLE SERVICES Most Unix systems disable a service after N sessions have been open in a given time. Well most systems have a reasonable default (lets say 800 - 1000), but not some SunOS systems that have the default set to 48... The solutions is to set the number to something reasonable. . C.11. PARAGON OS BETA R1.4 If someone redirects an ICMP (Internet Control Message Protocol) packet to a paragon OS beta R1.4 will the machine freeze up and must be rebooted. An ICMP redirect tells the system to override routing tables. Routers use this to tell the host that it is sending to the wrong router. The solution is to install the proper patch. . C.12. NOVELLS NETWARE FTP Novells Netware FTP server is known to get short of memory if multiple ftp sessions connects to it. . C.13. ICMP REDIRECT ATTACKS Gateways uses ICMP redirect to tell the system to override routing tables, that is telling the system to take a better way. To be able to misuse ICMP redirection we must know an existing connection (well we could make one for ourself, but there is not much use for that). If we have found a connection we can send a route that loses it connectivity or we could send false messages to the host if the connection we have found don't use cryptation. Ex: (false messages to send) DESTINATION UNREACHABLE TIME TO LIVE EXCEEDED PARAMETER PROBLEM PACKET TOO BIG The effect of such messages is a reset of the connection. The solution could be to turn ICMP redirects off, not much proper use of the service. . C.14. BROADCAST STORMS This is a very popular method in networks there all of the hosts are acting as gateways. There are many versions of the attack, but the basic method is to send a lot of packets to all hosts in the network with a destination that don't exist. Each host will try to forward each packet so the packets will bounce around for a long time. And if new packets keep coming the network will soon be in trouble. Services that can be misused as tools in this kind of attack is for example ping, finger and sendmail. But most services can be misused in some way or another. . C.15. EMAIL BOMBING AND SPAMMING In an email bombing attack the attacker will repeatedly send identical email messages to an address. The effect on the target is high bandwidth, a hard disk with less space and so on... Email spamming is about sending mail to all (or rather many) of the users of a system. The point of using spamming instead of bombing is that some users will try to send a replay and if the address is false will the mail bounce back. In that cause have one mail transformed to three mails. The effect on the bandwidth is obvious. There is no way to prevent email bombing or spamming. However have a look at CERT:s paper "Email bombing and spamming". . C.16. TIME AND KERBEROS If not the the source and target machine is closely aligned will the ticket be rejected, that means that if not the protocol that set the time is protected it will be possible to set a kerberos server of function. . C.17. THE DOT DOT BUG Windows NT file sharing system is vulnerable to the under Windows 95 famous dot dot bug (dot dot like ..). Meaning that anyone can crash the system. If someone sends a "DIR ..\" to the workstation will a STOP messages appear on the screen on the Windows NT computer. Note that it applies to version 3.50 and 3.51 for both workstation and server version. The solution is to install the proper patch. . C.18. SUNOS KERNEL PANIC Some SunOS systems (running TIS?) will get a kernel panic if a getsockopt() is done after that a connection has been reset. The solution could be to install Sun patch 100804. . C.19. HOSTILE APPLETS A hostile applet is any applet that attempts to use your system in an inappropriate manner. The problems in the java language could be sorted in two main groups: 1) Problems due to bugs. 2) Problems due to features in the language. In group one we have for example the java bytecode verifier bug, which makes is possible for an applet to execute any command that the user can execute. Meaning that all the attack methods described in .D.X. could be executed through an applet. The java bytecode verifier bug was discovered in late March 1996 and no patch have yet been available (correct me if I'am wrong!!!). Note that two other bugs could be found in group one, but they are both fixed in Netscape 2.01 and JDK 1.0.1. Group two are more interesting and one large problem found is the fact that java can connect to the ports. Meaning that all the methods described in .C.X. can be performed by an applet. More information and examples could be found at address: http://www.math.gatech.edu/~mladue/HostileArticle.html If you need a high level of security you should use some sort of firewall for protection against java. As a user you could have java disable. . C.20. VIRUS Computer virus is written for the purpose of spreading and destroying systems. Virus is still the most common and famous denial of service attack method. It is a misunderstanding that virus writing is hard. If you know assembly language and have source code for a couple of virus it is easy. Several automatic toolkits for virus construction could also be found, for example: * Genvir. * VCS (Virus Construction Set). * VCL (Virus Construction Laboratory). * PS-MPC (Phalcon/Skism - Mass Produced Code Generator). * IVP (Instant Virus Production Kit). * G2 (G Squared). PS-MPC and VCL is known to be the best and can help the novice programmer to learn how to write virus. An automatic tool called MtE could also be found. MtE will transform virus to a polymorphic virus. The polymorphic engine of MtE is well known and should easily be catch by any scanner. . C.21. ANONYMOUS FTP ABUSE If an anonymous FTP archive have a writable area it could be misused for a denial of service attack similar with with .D.3. That is we can fill up the hard disk. Also can a host get temporarily unusable by massive numbers of FTP requests. For more information on how to protect an anonymous FTP site could CERT:s "Anonymous FTP Abuses" be a good start. . C.22. SYN FLOODING Both 2600 and Phrack have posted information about the syn flooding attack. 2600 have also posted exploit code for the attack. As we know the syn packet is used in the 3-way handshake. The syn flooding attack is based on an incomplete handshake. That is the attacker host will send a flood of syn packet but will not respond with an ACK packet. The TCP/IP stack will wait a certain amount of time before dropping the connection, a syn flooding attack will therefore keep the syn_received connection queue of the target machine filled. The syn flooding attack is very hot and it is easy to find more information about it, for example: [.1.] http://www.eecs.nwu.edu/~jmyers/bugtraq/1354.html Article by Christopher Klaus, including a "solution". [.2.] http://jya.com/floodd.txt 2600, Summer, 1996, pp. 6-11. FLOOD WARNING by Jason Fairlane [.3.] http://www.fc.net/phrack/files/p48/p48-14.html IP-spoofing Demystified by daemon9 / route / infinity for Phrack Magazine . C.23. PING FLOODING I haven't tested how big the impact of a ping flooding attack is, but it might be quite big. Under Unix we could try something like: ping -s host to send 64 bytes packets. If you have Windows 95, click the start button, select RUN, then type in: PING -T -L 256 xxx.xxx.xxx.xx. Start about 15 sessions. . C.24. CRASHING SYSTEMS WITH PING FROM WINDOWS 95 MACHINES If someone can ping your machine from a Windows 95 machine he or she might reboot or freeze your machine. The attacker simply writes: ping -l 65510 address.to.the.machine And the machine will freeze or reboot. Works for kernel 2.0.7 up to version 2.0.20. and 2.1.1. for Linux (crash). AIX4, OSF, HPUX 10.1, DUnix 4.0 (crash). OSF/1, 3.2C, Solaris 2.4 x86 (reboot). . C.25. MALICIOUS USE OF SUBNET MASK REPLY MESSAGE The subnet mask reply message is used under the reboot, but some hosts are known to accept the message any time without any check. If so all communication to or from the host us turned off, it's dead. The host should not accept the message any time but under the reboot. . C.26. FLEXlm Any host running FLEXlm can get the FLEXlm license manager daemon on any network to shutdown using the FLEXlm lmdown command. # lmdown -c /etc/licence.dat lmdown - Copyright (C) 1989, 1991 Highland Software, Inc. Shutting down FLEXlm on nodes: xxx Are you sure? [y/n]: y Shut down node xxx # . C.27. BOOTING WITH TRIVIAL FTP To boot diskless workstations one often use trivial ftp with rarp or bootp. If not protected an attacker can use tftp to boot the host. . D. ATTACKING FROM THE INSIDE D.1. KERNEL PANIC UNDER SOLARIS 2.3 Solaris 2.3 will get a kernel panic if this is executed: EX: $ndd /dev/udp udp_status The solution is to install the proper patch. . D.2. CRASHING THE X-SERVER If stickybit is not set in /tmp then can the file /tmp/.x11-unix/x0 be removed and the x-server will crash. Ex: $ rm /tmp/.x11-unix/x0 . D.3. FILLING UP THE HARD DISK If your hard disk space is not limited by a quota or if you can use /tmp then it`s possible for you to fill up the file system. Ex: while : ; mkdir .xxx cd .xxx done . D.4. MALICIOUS USE OF eval Some older systems will crash if eval '\!\!' is executed in the C-shell. Ex: % eval '\!\!' . D.5. MALICIOUS USE OF fork() If someone executes this C++ program the result will result in a crash on most systems. Ex: #include