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Daniel jackson static analysis symposium ·santa barbara · june 2k logic,model s& analysis.

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Presentation on theme: "Daniel jackson static analysis symposium ·santa barbara · june 2k logic,model s& analysis."— Presentation transcript:

1 daniel jackson static analysis symposium ·santa barbara · june 2k logic,model s& analysis

2 2 my green eggs and ham ·two languages in any analysis ·first order relational logic ·models in their own right

3 3 plan of talk ·Alloy, a RISC notation ·models of software ·analysis reduced to SAT ·finding bugs with constraints

4 4 an example model CeilingsAndFloors { domain { Man, Platform } state { ceiling, floor : Man -> Platform! } // one man’s ceiling is another man’s floor inv { all m: Man | some n: Man - m | m.ceiling = n.floor } // one man’s floor is another man’s ceiling assert { all m: Man | some n: Man - m | m.floor = n.ceiling } }

5 5 kernel: type decls d decls, x typexps, t types d ::= v : x x ::= t | t -> t | t => x sample decls File, Dir, Root : Object dir : Object => Name -> Object entries : Object -> DirEntry name : DirEntry -> Name contents : DirEntry -> Object parent : Object -> Object scalars are singleton sets funcs are first-order (t1 => t2 -> t3) equiv to (t1 x t2 -> t3) missing: (t1 -> t2) -> t3

6 6 kernel: expressions f formulas, e exps, v vars e ::= e + e | e & e | e - eset ops | ~ e | + e relational ops | e. eimage | e [v]application | {v : t | f}comprehension | v sample exprs Root.~parent & File d.entries.contents n.dir [d] navigatio n

7 7 kernel: formulas f ::= e in esubset | f && f | !f logic ops | all v : t | fquantification sample formulas File+Dir-Root in Root.+~parent all d: DirEntry | ! d in d.contents.entries in used for subset and membership

8 8 shorthands declarations ·domain {d} declares d : _d ·use sets on RHS ·multiplicities: +  1, ?  1, ! 1 domain {Object, DirEntry, Name} state { partition File, Dir : Object Root: Dir ! entries: Dir ! -> DirEntry name: DirEntry -> Name ! contents: DirEntry -> Object ! parent (~children) : Object -> Dir ? }

9 9 more shorthands quantifiers sole v: t | f  some w: t | { v: t | f } in w all x | f  all x : d | f where d is inferred domain Q e  Q v | v in e sample invariants // object has at most one parent all o | sole o.parent // root has no parents no Root.parent // all other directories have one parent all d: Dir - Root | one d.parent

10 10 sample model: intentional naming INS ·Balakrishnan et al, SOSP 1999 ·naming scheme based on specs why we picked INS ·naming vital to infrastructure ·INS more flexible than Jini, COM, etc what we did ·analyzed lookup operation ·based model on SOSP paper & Java code

11 11 intentional naming attribute/value pairs  city: cambridge  hierarchical specs  city: cambridge, building: ne43, room: 524   service: camera, resolution: hi   service: printer, postscript: level2  lookup ·database maps spec to set of records ·query is set of specs ·lookup returns records meeting all specs

12 12 building camera service ne43 query n1 n0 building camera service ne43printer database tree representation n0 n1 n0

13 13 strategy model database & queries ·characterize by constraints ·generate samples check properties ·obvious no record returned when no attributes match ·claims “wildcards are equivalent to omissions” ·essential additions to DB don’t reduce query results discuss and refine …

14 14 alloy model: state model INS { domain {Attribute, Value, Record} state { Root : fixed Value! valQ : Attribute? -> Value? attQ : Value? -> Attribute valDB : Attribute? -> Value attDB : Value? -> Attribute rec : Value + -> Record lookup : Value -> Record }

15 15 alloy model: constraints // Root is not the value of an attribute inv Q1 {no Root.~valQ} // if query and DB share a leaf value, lookup returns its records inv Lookup1 {all v | no v.attQ || no v.attDB -> v.lookup = v.rec} // adding a record doesn’t reduce results assert LookupOK7 {AddRecord -> Root.lookup in Root.lookup'}

16 16 checking assertions select scope run check counter? fix model slow? real? incr scope prop fails prop holds YY N N Y N 3 attrs, vals, recs

17 17 results 12 assertions checked ·when query is subtree, ok ·found known bugs in paper ·found bugs in fixes too ·monotonicity violated

18 18 counterexample type mono n1 service printer databasequery service printer type mono size A4 n1 n0 size A4

19 19 time & effort costs  2 weeks modelling, ~70 + 50 lines Alloy cf. 1400 + 900 lines code  all bugs found in < 10 secs with scope of 4 2 records, 2 attrs, 3 values usually enough cf. a year of use  exhausts scope of 5 in 30 secs max space of approx 10^20 cases

20 20 other modelling experiences microsoft COM (Sullivan) ·automated & simplified: 99 lines ·no encapsulation air traffic control (Zhang) ·collaborative arrival planner ·ghost planes at US/Canada border PANS phone (Zave) ·multiplexing + conferencing ·light gets stuck

21 21 why modelling improves designs rapid experimentation articulating essence simplifying design  catching showstopper bugs

22 22 how analyzer works what you learned in CS 101 ·3-SAT: first NP-c problem ·to show a problem is hard reduce SAT to it what we know now ·SAT is usually easy ·to show a problem is easy reduce it to SAT key to reduction ·consider finite scope: type   small scope hypothesis most interesting cases have illustrations in small scopes

23 23 architecture translate problem translate solution mapping boolean formula boolean solution SAT solver alloy problem alloy result scope

24 24 example problem a, b : S p : S -> T ! (a – b).p in (a.p – b.p) a model in a scope of 2 S = {S0, S1} T = {T0, T1} p = {(S0, T0), (S1, T0)} a = {S0} b = {S1} S0 S1 T0 T1 a b p

25 25 translation scheme represent ·set as vector of bool var a [a 0 a 1 ] b [b 0 b 1 ] ·relation as matrix p [p 00 p 01, p 10 p 11 ] translate ·set expr to vector of bool formula XT [a - b] i = XT [a] i   XT [b] i XT [a. b] i =  j. XT [a] j  XT [b] ji ·relational expr to matrix of bool formula ·formula to bool formulas a 0, b 1, p 00, p 10 S0 S1 T0 T1 a b p

26 26 translation a [a 0 a 1 ] b [b 0 b 1 ] p [p 00 p 01, p 10 p 11 ] a – b[a 0  b 0 a 1   b 1 ] (a – b).p[(a 0  b 0  p 00 )  (a 1   b 1  p 10 ) …] a.p[(a 0  p 00 )  (a 1  p 10 ) (a 0  p 01 )  (a 1  p 11 )] b.p[(b 0  p 00 )  (b 1  p 10 ) (b 0  p 01 )  (b 1  p 11 )] a.p – b.p[((a 0  p 00 )  (a 1  p 10 ))  ((b 0  p 00 )  (b 1  p 10 )) …] ! (a – b).p in (a.p – b.p)  (((a 0  b 0  p 00 )  (a 1  b 1  p 10 )  ((a 0  p 00 )  (a 1  p 10 ))  ((b 0  p 00 )  (b 1  p 10 ))))  …

27 27 tricks quantifiers ·could expand into conjunctions ·but how to make modular? ·translate formula into tree indexed on var avoiding blowup ·solvers expect CNF ·standard var intro tricks symmetry ·all our domains are uninterpreted ·many equivalent assignments ·add symmetry-breaking predicates

28 28 how (not) to delete class List {List next; Val val;} void static delete (List p, Val v) { List prev = null; while (p != NULL) if (p.val == v) { prev.next = p.next ; return; } else { prev = p ; p = p.next ; }

29 29 specifying delete basic spec p.*next’ = p.*next – {c | c.val = v} as Alloy model domain {List, Val} state { next : List -> List? val : List -> Val? p : List?, v : Val? } op MergeCode { … } op MergeSpec {p.*next’ = p.*next – {c | c.val = v}} assert {MergeCode -> MergeSpec}

30 30 hacking delete (1) counter #1: first cell has value v cond Mask {p.val != v} assert {MergeCode && Mask -> MergeSpec} p v val

31 31 hacking delete (2) counter #2: two cells with value v cond RI {all x | sole c: p.*next | c.val = x} assert {MergeCode && Mask && RI -> MergeSpec} assert {MergeCode && RI -> RI’} next v val p next

32 32 step 1: unroll control flow graph void static delete (List p, Val v) { List prev = null; while (p != NULL) if (p.val == v) { prev.next = p.next ; return; } else { prev = p ; p = p.next ; }

33 33 step 2: encode control flow E01 -> E12 || E13 E13 -> E34 || E36 E34 -> E45 E45 -> E52 E36 -> E67 E67 -> E78 E78 -> E82

34 34 step 3: encode dataflow E36 -> p3.val3 != v3 E45 -> prev4.next5 = p4.next4 E78 -> p8 = p7.next7

35 35 frame conditions must say what doesn’t change ·so add p6 = p7 but ·don’t need a different p at each node ·share vars across paths ·eliminates most frame conditions

36 36 sample results on Sagiv & Dor’s suite of small list procedures ·reverse, rotate, delete, insert, merge ·wrote partial specs (eg, set containment on cells) ·predefined specs for null deref, cyclic list creation anomalies found ·1 unrolling ·scope of 1 ·< 1 second specs checked ·3 unrollings ·scope of 3 ·< 12 seconds

37 37 promising? nice features ·expressive specs ·counterexample traces ·easily instrumented compositionality ·specs for missing code ·summarize code with formula analysis properties ·code formula same for all specs ·exploit advances in SAT

38 38 summary ·Alloy, a tiny logic of sets & relations ·declarative models, not abstract programs ·analysis based on SAT ·translating code to Alloy challenge ·checking key design properties ·global object model invariants ·looking at CTAS air-traffic control ·abstraction, shape analysis …?

39 39 related work checking against logic ·Sagiv, Reps & Wilhelm’s PSA ·Extended Static Checker using constraints ·Ernst, Kautz, Selman & co: planning ·Biere et al: linear temporal logic ·Podelski’s array bounds extracting models from code ·SLAM’s boolean programs ·Bandera’s automata

40 40 You do not like them. So you say. Try them! Try them! And you may. Try them and you may, I say. sdg.lcs.mit.edu/alloy

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