1 / 16

Join Algorithms for the Theory of Uninterpreted Functions

Join Algorithms for the Theory of Uninterpreted Functions. Sumit Gulwani Ashish Tiwari George Necula UC-Berkeley SRI UC-Berkeley. Definition: Join in theory T. E = Join T ( E 1 , E 2 ) iff E 1 ) T E and E 2 ) T E

reuel
Download Presentation

Join Algorithms for the Theory of Uninterpreted Functions

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Join Algorithms for the Theory of Uninterpreted Functions Sumit Gulwani Ashish Tiwari George Necula UC-Berkeley SRI UC-Berkeley

  2. Definition: Join in theory T E = JoinT(E1,E2) iff • E1)T E and E2)T E • If (E1)T g) and (E2)T g), then E )T g E1, E2, E: conjunction of ground facts in theory T g: ground fact in theory T E is the strongest conjunction of ground facts that is implied by both E1 and E2 in theory T

  3. Example of Joins • LE: Linear Arithmetic with Equality JoinLE(x=1 Æ y=4, x=3 Æ y=2) = x+y=5 • LI: Linear Arithmetic with Inequalities JoinLI(x=1 Æ y=4, x=3 Æ y=2) = x+y=5 Æ 1·x·3 • UF: Uninterpreted Functions JoinUF(x=a Æ y=F(a), x=b Æ y=F(b)) = y=F(x)

  4. Motivation: Program Analysis using Abstract Interpretation False True • Disadvantages of using decision procedure: • Exponential # of paths • Loop invariants required • Cannot discover invariants • Abstract Interpretation avoids these problems • Join Algorithm required to merge facts at join points * x := a; y := F(a); x := b; y := F(x); True False * u := F(a); v := F(a); u := F(x); v := y; assert (u=v); assert (v=F(a));

  5. Join for Uninterpreted Functions is not easy Join(F(a)=a Æ F(b)=b Æ G(a)=G(b), a=b) = GFi(a)=GFi(b) The result of join is not finitely representable using standard data-structures like EDAGs

  6. Relatively Complete Join: Definition Recall, Join(E1,E2): strongest conjunction of ground facts g s.t. E1)T g and E2)T g RCJoin(E1,E2,K): strongest conjunction of ground facts g s.t. E1)T g and E2)T g and Terms(g) 2 K Example E1:F(a)=a Æ F(b)=b Æ G(a)=G(b) E2: a=b K: { GF(a),GF(b) } RCJoin(E1,E2,K): GF(a) = GF(b)

  7. Relatively Complete Join: Algorithm RCJoin(E1,E2,K): • Let D1=EDAG(E1) and D2=EDAG(E2) • Extend D1 and D2 to represent K • Congruence close D1 and D2 • Let D=product construction of D1 and D2 Output D

  8. F G G F a b Step 1: Constructing EDAGs E1: F(a)=a Æ F(b)=b Æ G(a)=G(b) E2: a=b K: { GF(a),GF(b) } a b D1 = EDAG(E1) D2 = EDAG(E2) • Nodes represent terms • Dotted edges represent equalities

  9. G G F G G F F F a b Step 2: Extending EDAGs E1: F(a)=a Æ F(b)=b Æ G(a)=G(b) E2: a=b K: { GF(a),GF(b) } a b D1 = EDAG(E1) D2 = EDAG(E2) • Add extra nodes to EDAGs s.t. terms in K are represented

  10. G G F G G F F F a b Step 3: Congruence Closure E1: F(a)=a Æ F(b)=b Æ G(a)=G(b) E2: a=b K: { GF(a),GF(b) } a b D1 = EDAG(E1) D2 = EDAG(E2) • F(n) = F(m) if n=m

  11. 30 60 G G 6 5 2 3 F G G F 20 50 F F 1 4 a b 10 40 Step 4: Product Construction (Intuition) E1: F(a)=a Æ F(b)=b Æ G(a)=G(b) E2: a=b K: { GF(a),GF(b) } C6 Å C30: { GF(a), GF(b)} a b D1 = EDAG(E1) D2 = EDAG(E2) C1: {a, Fa, F2(a), …} C4: {b, Fb, F2(b), …} C6: {G(a), GF(a), … G(b), GF(b), …} C10: {a, b} C20: {F(a), F(b)} C30: {GF(a), GF(b)}

  12. 30 60 G G 6 5 2 3 F G G F 20 50 F F 1 4 a b 10 40 Step 4: Product Construction (Algorithm) E1: F(a)=a Æ F(b)=b Æ G(a)=G(b) E2: a=b K: { GF(a),GF(b) } [3,30] [6,60] G G [2,20] [5,50] F F [1,10] [4,40] a b a b D1 = EDAG(E1) D2 = EDAG(E2) D • [n,m] 2 D if n:vÆm:v, or n:F(n1)Æm:F(m1) Æ[n1,m1] 2 D • [n1,m1] = [n2,m2] if n1=n2 and m1=m2

  13. Future Work: Join Algorithm for other theories For example, theory of commutative functions (CF) • Useful in modeling floating point operations • More challenging than uninterpreted functions (UF) E1: x=a Æ y=b E2: x=b Æ y=a JoinUF(E1,E2) = true JoinCF(E1,E2) = F(C[a],C[b]) = F(C[b], C[a])

  14. Future Work: Combining Join Algorithms For example, theory of linear arithmetic and uninterpreted functions (LA+UF) E1: x=a Æ y=b E2: x=b Æ y=a JoinUF(E1,E2) = true JoinLA(E1,E2) = x+y=a+b JoinLA+UF(E1,E2) = F(x+c)+F(y+c) = F(a+c)+F(b+c) Æ .….

  15. Future Work: Context-sensitive Join Algorithms Join(E1,E2) Æ E = Join(E1ÆE, E2ÆE) • Useful in interprocedural analysis • This is a representation issue. • Representing result of join using conjunction of ground facts is not context-sensitive. E1: x=a Æ y=F(a) E2: x=b Æ y=F(b) JoinUF(E1,E2) Æ a=b = y=F(x) Æ a=b JoinUF(E1Æ a=b,E2Æ a=b) = y=F(x) Æ x=a=b

  16. Conclusion • Join Algorithms are useful in program analysis. They are generalization of decision procedure. JoinT(E, g) = g iff E )T g E: conjunction of ground facts in theory T g: ground fact in theory T • We showed a relatively complete join algorithm for uninterpreted functions. • Join algorithms open up several interesting problems.

More Related