Access Control and Protection CS155 Lecture 2 Tal Garfinkel
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Access Control and Protection CS155 Lecture 2 Tal Garfinkel
Todays Agenda Lots of new language/models for talking about security systems – Capabilities, ACL’s, DTE – How do we talk about existing systems – What to consider in a new design? Discussion of how some existing systems work e.g. unix access controls
Overview Access control: What and Why Abstract Models of Access Control The Unix Access Control Model Capabilities Beyond the Unix Model Multilevel Security
What goes into system security? Authentication (password/crypto/etc.) – – Authorization (Acess control) – – Who are you? this is a big part of CS255 What are you allowed to do. Focus is policy Enforcement Mechanism - How its policy implemented/enforced Today we are mostly interested in #2, will touch on #3 Note: split between policy and mechanism sometimes a false dichotomy.
Night Club Example Authentication – ID Check Access Control – Over 18 - allowed in – Over 21 - allowed to drink – On VIP List - allowed to access VIP area Enforcement Mechanism – Walls, Doors, Locks, Bouncers
Night Club Example: More Interesting Phenomena Tickets – Name or anonymous? – Date What if you want to leave and come back – Hand stamp or bracelet
Why this Tangent? We can find logical models to study these systems? We can use these models to design new systems? Security systems are everywhere, looking at the real world key to building your intuition.
What do we use this for? Express information access policies. – Who can access my files, who can’t, how. Sandboxing: Minimize damage inflicted by malicous program. Privilege Seperation: Allow programs to be written to minimize damage in case of failure. – Think about compartments in a ship Defense-in-Depth - programmers make mistakes,protection systems fail, redundancy always a good thing!!
Basic Design Space All security architectures are Isolation Controlled Sharing Just Isolation – Unplug the network cable! (airgap provides almost perfect isolation). – Segment your network physically Put red tape on one set of wires and machines, black tape on another, blue on another. Make sure colors always match! – Military exploits this approach to separate classified, secret, topsecret networks. Most of us need to share stuff what do we want from sharing?
Challenge of Controlled Sharing All of Saltzer and Schroder’s principles are vital,these two are hard. 1. Principle of Least privilege Make controls granular enough and apply them to enforce them to minimize harm. 2. Psychological acceptability Get as close to the users mental model (be it the programmer, user or admin) as possible. Reconciling these two is a fundamental challenge.
Operating Systems: Our focus today Most heavily studied area for access control First computers where single user/no network Timesharing systems introduced need for access control – studied heavily in the 70’s and 80’s. Still an open research area, why? – First 20 years: restrict what a user can do with data, focus on military problems, thought problem was malicous users – Last 10: Malicous applications the primary problem. Another answer: Right Access control policy dictated by Usage models, Threat Model, Applications -- we still have lots to learn about how programs are built, how people use them.
Access Control vs. IDS and AV Soundness (can I make a definite allow/deny decision) – Difference between access control and intrusion detection – An IDS makes a probablistic statement i.e. this action is probably bad - allows catching a broader range of behaviors, at the cost of enforcement. – An IDS that is 100% accurate should be doing enforcement, it is then an IPS (access control system) Completeness (do I catch every bad action) – Access control vs. AV – Access control systems should (in theory enforce some property) -- e.g enforce these rules on information flow. – AV systems often rely more on un-sound blacklist approach, hard to make strict statements about what your getting In the real world, distinctions often unclear – Your AV product may do some access control
Abstract Models of Access Control
Subjects and Objects Subjects – can be processes, modules, roles Objects – can be files, processes, etc. Authentication often used to bootstrap subjects, but not necessary. – e.g. process assumes identity of one subject, then another.
Elementary Forms Authentication Authorization – e.g. safes Whitelists/Blacklists (Single object, multiple Subjects) – Examples: Spam prevention – Blacklists: Default on (fail open) Hard to reason about who can access system – Whitelists: Default off (fail closed) Have to deal with adding whitelist entries Challenges Hard to manage if rapidly changing set of principles Both can grow quite large
Access Control Matrix Instantaneous protection state of a system Dynamically Changing! How can we extend this model? Objects A alice 0 subjects bob 1 charlie 0 dave 1 B 0 1 0 1 C 1 0 1 0 D 0 1 0 1
Adding Access Rights Access Rights – e.g. Simple: Read, Write – e.g. Complex: execute, change ownership Objects A alice r subjects bob r charlie dave B C D r/w r r/w r w - r/w w
Grouping Subjects – Groups e.g. staff {alice,dave}, students {bob, charlie} Objects – Types e.g. system file {A,B}, user file {C,D} Can have compound names – e.g. in AFS talg:friends, system:backup
ACL’s What if I break my matrix down by columns? – Each object has a set of user, right tuples – A { bob, r/w , alice,w } Properties – Good for many applications (file systems) – Can grow quite large
Capabilities What if I break my matrix down by rows – Alice { A,r/w , B,w , C,r } Properties – Natural model for delegation (rights coupled to object) Each tuple can be viewed as a handle to an object
Protection Domains Users don’t exist – Machines, processes, modules,do Protection domain is an abstract object that can have – – – – A namespace (e.g. view of the file system) A userid or group ID A set of objects it holds (capability list) A set of rights it holds (permissions) How does protection get enforced? – Language type systems, hardware MMU (Processes, virtual machines), compilers (SFI) – Not our primary interest today
The Reference Monitor An abstract model of protection – – In practice should offer: – – – Sometimes quite close to implementation e.g. SELinux (Flask Architecture) Complete mediation Be Tamper proof Be small enough to understand (verify) Important Idea: Computer systems are BIG and Complex, Security relavent part often SMALL, extract that part out that deals with security so that we can understand/verify it.
Unix Access Control Basics, limitations, extensions
Unix Resource Files Includes devices, IPC (domain sockets, named pipes, mmap shared memory) Network TCP/UDP port address space Other – Sys V IPC has its own name space – ability to load kernel modules
Unix Identities Each process has set of identities used to make access control decisions. – Conceptually uid/euid, gid/egid most important – In practice, a bunch of other details, see reading. euid used for access control decisions – Allows process to drop and resume privilege temporarily Changing uid/euid allows dropping privilege permanently.
File system access control user group other “-rwxrwxrwx “-rw------ “-r-sr-xr-x talg root talg vimrc” wheel chpass” New files created according to “umask” setuid bit for executables - changes uid to uid of file owner on exec() of file. Execute on directory implies access to directory.
What can you do with identities Lots of hard coded rules Highest privilege uid is root (uid 0), has most privilege, – Access privileged ports, override file permissions, load kernel modules, etc. – Once you have root, you own the system – this is a source of many problems. Process with a given euid can send signals to other processes with that uid, ptrace() those processes, etc. – Basically no protection between processes with same uid. Good news – Works decently well on multi-user system where programs are not malicous -shortcomings can be fixed with file system ACL’s Bad News – Very difficult/sometimes impossible to contain damage of malicous root process – Lots of stuff needs root – Users can’t protect themselves from bad apps, i.e. apps totally trusted!!
Dropping privilege Only available to root To prevent programmer errors – Assume role of less privileged user for most operations (seteuid) Let OS do its job – – – – Only keep privilege long enough to do what you need. Temporary, program can resume root privilege at will Essential for some things in unix (e.g. race free file open) NEVER try to impersonate another user as root! You will fail To prevent malicous code from inflicting damage – Drop privilege permanantly (often accompanied by fork()). – Works well if there is a before-time (with privilege)/after-time(without privilege) model. e.g. daemons that need root to listen to privileged port.
Seperating Time of Check and Time of Use - A Really Bad Thing Example: access() system call. int access(const char *path, int mode); #From the man page: #Access() is a potential security hole and should never be used. Problem: as soon as you get a result from access(), its invalid. Permissions could have changed. – Checking Permission/obtaining resource must be atomic! Solution: Never use access(), instead look up programming guidelines for your OS. Hint: Never make up your own solution!
Capabilities They are cool
Confused Deputy Problem 1. 2. 3. Pay-to-play compiler service (its an old problem) Compiler service takes file and compiles it for user User hands compiler path for compilers own billing file Compiler overwrites billing file Compiler was a confused deputy - acting on behalf of user. Solutions: – – – Drop privilege to that of user to open file (more error prone, common source of bugs) Have user pass capability to compiler (less error prone). Capability advocates love to point this out as reason to use capabilities.
File descriptor passing: the poor mans capability system File descriptors are capabilities Ability to delegate files by passing descriptors over a unix domain socket (sendmsg(), recvmsg()) Supports privilege seperation – One process runs as root, opens a unix domain socketpair. – Forks() another process, drops privilege – More privilege process can pass descriptors to less privilege process, also do other stuff e.g. manage crypto keys. – Can apply this paradigm ad naseum i.e. multiple unprivileged processes. Trade-offs – Positive: Great way to make more robust software – Negative: sometimes very hard to do after the fact (don’t believe the hype), requires pretty clueful programmers up front.
Capabilities have lots of nice properties Natural model for delegation – Just pass handle to object No ambient privilege – Access control explicit not implicit Separate access checking from use – E.g. fd open() vs. read(fd), write(fd) – Useful design pattern for ammoritizing the cost of permission checks Powerful extensibility in languages that support capabilities natively – Wrap one object in another object.
Still More Cryptographic Capabilities – Nonce as index into table (stateful) – { permissions , objectid, MAC(msg)} (stateless) – No OS support need, good for distributed systems Limitations of capabilities – No easy means of revocation – Can’t easily control delegation in a pure model (mostly a red herring) – Doesn’t always suit your problem
Some Real World Access Control Mechanisms Or, overcoming the shortcomings of the original Unix model.
Dangers of bad access control model Too much privilege! – Original Unix architecture suffers severly – Windows world even worse – Once ISV’s (developers) expect this, very hard to go back! Wrong granularity – To coarse grain too much privilege – To fine grain too many knobs, no one knows how to use it (SELinux struggles with this, its gotten better, but still not for the faint of heart) – Compromise Protection Profiles, Roles, etc. - use fine grain permissions to build up common case profiles.
File system ACL’s Basic Problem – I want to do a project with a new group, how do I share files with only them without involving my sysadmin? Ghetto style – – – – Create a directory accessible but not readable by everyone Make directory (or files) in that directory with secret name Hand out name as a capability Gross and many limitations ACL’s a better soluation – User created groups, user setable list of groups/users on files/directories Almost everywhere now – AFS, NTFS, NFSv4, FreeBSD, Solaris, ZFS, etc.
Chroot() Basic idea: Allow process to change file system root: e.g. chroot(“/home/apache/base”); Variety of sharp edges due to power of root user, ptrace(), etc. BSD Jail tries to fix this. Fundamental problem, limited controlled sharing. Still, a useful primitive Richer primitive in plan9, a research OS. / etc bin home apache base etc bin
Posix “Capabilities” Paritioning power of root – CAP DAC OVERRIDE: ignore normal file permissions – CAP CHOWN: allow arbitrary chown – CAP SYS NET BIND SERVICE: allow bind of TCP/UPD sockets below port 1024 – CAP NET RAW: allow raw socket access (can create arbitrary ethernet frames) Improvement on setuid – Doesn’t help with files – Fixed granularity
Sandboxing Systems Examples: AppArmor (SuSe), Systrace, Janus
SELinux Adding MAC to Linux Flexible policy architecture – DTE, RBAC, MLS Default uses combination of RBAC and DTE Checks applied if existing unix model succeeds e.g. if access fails, additional checks not invoked Most folks never use MLS
Domain and Type Enforcement Generalization of Access Control Matrix Processes have a domain Objects (generally files) have a type. – Stored in extended file attribute – Type set at system configuration time. Example: assign -u /home user t assign -u /var spool t Entry point to domain is generally a binary e.g. (exec /usr/bin/lpd domain lpd t) App can request a domain transition to drop privilege Nice compared to path base model in that more robust to file rename(), can be less prone to problems due to symlinks, etc.
RBAC Yet another generalization of our access control matrix – Add yet another label to processes – Instead of uid, access control decisions based on role – e.g. Bob acting as backup manager vs. bob acting as printing manager.
A few words on Policy Languages Policy language at heart of rationale for access control – Look at policy spec instead of entire program/system – Clarity/simplicity key Even ACLs have a policy language Different requirements than programming language – Often non-expert users – Must be right the first time! Tension between flexibility/expressiveness and simplicity – Compare ACL’s, to AppArmor to SELinux
Sample SELinux TE Policy for FTPD ############################### ## # # Rules for the ftpd t domain # type ftp port t, port type; type ftp data port t, port type; daemon domain(ftpd, , auth chkpwd') type etc ftpd t, file type, sysadmfile; can network(ftpd t) can ypbind(ftpd t) allow ftpd t self:unix dgram socket create socket perms; allow ftpd t self:unix stream socket create socket perms; tcap setcap}; allow ftpd t self:process {ge allow ftpd t self:fifo file rw file perms; allow ftpd t bin t:dir search; can exec(ftpd t, bin t) allow ftpd t { sysctl t sysctl kernel t }:dir search; allow ftpd t sysctl kernel t:file { getattr read }; allow ftpd t urandom device t:chr file { getattr read }; ifdef( crond.te', system crond entry(ftpd exec t, ftpd t) can exec(ftpd t, { sbin t shell exec t }) ') allow ftpd t ftp data port t:tcp socket name bind; ifdef( ftpd daemon', define( ftpd is daemon', ') ') dnl end ftpd daemon ifdef( ftpd is daemon', rw dir create file(ftpd t, var lock t) allow ftpd t ftp port t:tcp socket name bind; allow ftpd t self:unix dgram socket { sendto }; can tcp connect(userdomain, ftpd t) ', ifdef( inetd.te', domain auto trans(inetd t, ftpd exec t, ftpd t) ifdef( tcpd.te', domain auto trans(tcpd t, ftpd exec t, ftpd t)') # Use sockets inherited from inetd. allow ftpd t inetd t:fd use; allow ftpd t inetd t:tcp socket rw stream socket perms; # Send SIGCHLD to inetd on death. allow ftpd t inetd t:process sigchld; ') dnl end inetd.te ')dnl end (else) ftp is daemon ifdef( ftp shm', allow ftpd t tmpfs t:file { read write }; allow ftpd t { tmpfs t initrc t }:shm { read write unix read unix write associate }; ') # Use capabilities. allow ftpd t ftpd t:capability { net bind service setuid setgid fowner fsetid chown sys resource sys c # Append to /var/log/wtmp. allow ftpd t wtmp t:file { getattr append };
Whole System Containers Solaris Zones, OS Level Virtual Machines Given application completely private view of OS Great for isolation, no sharing model. Same camp as virtual machines – the right tool for some jobs – large topic in its own right
Multilevel Security
Classical military model Vertical classification levels – Confidential Secret Top Secret Horizontal compartments – Nuclear, SIGINT, Biowar, etc. User has a level, can’t read above that level (violates secrecy), can’t write below that level (leaks data). Process can begin with – Upperbound (read),lowerbound (write) – Lower bound raised every time information read from above.
Bell-Lapadula No read up, no write down Top Secret, {Nuclear,Biowar} Top Secret, Nuclear Top Secret, Biowar Top Secret Secret, Nuclear Secret, biowar Secret confidential
MLS in the world Classification level added by tagging files – Just like DTE Everything tends to flow up – Ends up being very cumbersome in practice Declassification – Don’t know how to automate this, human in the loop – Becomes a bottle neck in critical situations (e.g.9/11) Almost no one uses this in practice Tagging data with sensitive labels a cool idea, maybe could be used to help protect your personal data from malware – Ongoing research area.
Biba-Integrity Model Cool Observation: Integrity the opposite of secrecy -- low integrity data flowing upwards leads to system compromise. Biba Rules – No read down – No write up Again, tends to be kind of unwieldly, can make sense for some systems.
The Confinement Problem In real life, really really hard to prevent to colaborating processes from communicating (say in order to write down). – Often due to timing channels Communication path called a “covert channel” Real world systems that care (very very few) try to limit bandwidth. Lampsons “Notes on the confinement Problem” a must read.
Closing thoughts
Most of you will go off to companies to write code Many attacks seen in the wild could have been rendered moot if software used access controls properly. Learn the access control system of your language runtime and OS – Learn their strengths and pitfalls. Build systems according to saltzer and schroders principles. – Be conservative in your design, assume things will fail, attempt to minize harm . Building things right requires a bit more effort. Fixing things later requires far more – sometimes impossible or impractical.
