In the field of computer software testing, different approaches have been developed to more accurately and completely test program function. For example, program modeling and model checking allow certain kinds of debugging analysis that may not otherwise be possible or practical in direct analysis of a program. Program models simplify certain aspects of programs to facilitate more complete testing of their overall behavior. Program models can be used to analyze programs as a whole, or, for larger programs, to analyze them one part at a time. When errors are found, changes can then be made to the program source code to correct the errors.
One kind of program modeling is predicate abstraction. Predicate abstraction models the behavior of a program using Boolean predicates, which represent conditions in the program being modeled (the “source program”) that can be evaluated as “true” or “false.” For example, the Boolean predicate (x>0) evaluates to “true” if the variable x has a positive value in a given program state, and evaluates to “false” otherwise. Predicates can be drawn from conditional statements and assertions in a source program, or from other sources. Predicate abstraction can be done automatically using an automatic predicate abstraction tool, with programmer analysis, or with some combination of tools and programmer analysis.
The product of predicate abstraction is typically a finite-state program (also referred to as a Boolean program) that models behavior of the source program. The finite-state program is an abstraction of the source program to the extent that properties satisfied in the finite-state program are satisfied in the source program.
The predicate abstraction process is complex. Typically, tools called theorem provers are used to determine whether a particular formula (derived from a source program) is implied by some Boolean combination over a set of predicates P. However, in prior predicate abstraction methods, the number of calls to a theorem prover needed to make a determination for a particular formula would increase exponentially as the number of predicates in P increased, making such methods inefficient and expensive in terms of computing resources. Other methods have used heuristics to reduce the number of calls to theorem provers in an attempt to gain efficiency by sacrificing precision.
In summary, predicate abstraction techniques and tools are described.
For example, using a symbolic decision procedure, a predicate abstraction for a computer program is generated based on a set of predicates representing observations of expected behavior of the computer program. The set of predicates may be generated by an automatic program analysis tool or may be provided a user based on the user's observations. The predicate abstraction process may employ binary decision diagrams.
Two or more symbolic decision procedures (e.g., for different kinds of program logic) can be combined to form a combined symbolic decision procedure for the source computer program, and combined symbolic decision procedure can be used to perform predicate abstraction for the computer program.
A data structure can be used to track derived predicates during predicate abstraction. For example, the data structure may comprise identifying information for predicates derived from an input set of predicates, and information indicating how the derived predicates were derived from the input set of predicates.
This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description and the accompanying drawings. This Summary is not intended to identify required features of the claimed subject matter or limit the scope of the claimed subject matter.
Described techniques and tools are directed to predicate abstraction for modeling and testing of computer software. For example, techniques and tools for performing predicate abstraction using symbolic decision procedures are described.
Various alternatives to the implementations described herein are possible. For example, techniques described with reference to flowchart diagrams can be altered by changing the ordering of stages shown in the flowcharts, by repeating or omitting certain stages, etc. As another example, described predicate abstraction tools can be modified relative to the examples described with reference to system diagrams by combining, adding, rearranging, or modifying system components. As another example, the implementations can be applied to other kinds of source code (e.g., other languages, data types, functions, interfaces, etc.), programming styles, and software designs (e.g., software designed for distributed computing, concurrent programs, etc.).
The various techniques and tools can be used in combination or independently. Different embodiments implement one or more of the described techniques and tools. Some techniques and tools described herein can be used in a predicate abstraction system, or in some other system not specifically limited to predicate abstraction.
I. Predicate Abstraction Techniques and Tools
Predicate abstraction is a technique for automatically creating finite abstract models of finite and infinite state systems. Predicate abstraction is based on observations over the state space of the program. These observations can be taken directly from the code (as they appear in conditionals) or provided by programmers or testers, or automatic analysis tools. Predicate abstraction makes it possible to increase the level of testing thoroughness through the addition of new observations.
Many errors that go undetected in conventional program testing are due to complex correlations between program predicates (which control the execution of statements) and program statements (which in turn affect the values of the predicates). A predicate is an expression that maps a program state to a Boolean value. For example, the predicate (x>0) indicates whether or not variable x has a positive value in a given state. Predicates can be drawn from the conditional statements and assertions in a program, as well as from implicit run-time “safety” checks (e.g., checking for array bound violations and division by zero) from automated analysis, from a programmer, or from some combination of human and automatic analysis. Predicates can be used, for example, to generate a Boolean program abstracted from a source program (e.g., a source program written in C/C++ or some other programming language).
In prior predicate abstraction methods, tools called theorem provers were used to determine whether a particular formula (derived from a source program) is implied by some boolean combination over a set of predicates P. However, in such prior methods, the number of calls to a theorem prover that were needed to make a determination for a particular formula would increase exponentially as the number of predicates in P increased, making such methods inefficient and expensive in terms of computing resources. Other methods have used heuristics to reduce the number of calls to theorem provers in an attempt to gain efficiency by sacrificing precision.
Described techniques and tools improve efficiency of predicate abstraction through the use of symbolic decision procedures. The use of symbolic decision procedures avoids the complexity of making an exponential number of theorem prover calls that characterizes earlier predicate abstraction methods without sacrificing precision. Described techniques and tools gain efficiency by exploiting properties of specific logics and tailoring the analysis of the formula to the needs of predicate abstraction. Described techniques and tools are distinct from other theorem-prover methods which suffer from exponential complexity and do not take into account the structure of the input formula in determining whether the formula was true or false when applied to the source program.
A. Decision Procedure Overview
A decision procedure is an algorithm that, given a formula of interest, or goal, g, can determine whether g is consistent (or inconsistent) with a given set of predicates P and a given set of inference rules R. Theorem provers used in predicate abstraction techniques are decision procedures, in that they can be used to decide whether a given formula holds or does not hold in a source program. For example, consider a decision procedure that returns the Boolean value “true” if goal g is consistent with P and R, and returns the Boolean value “false” otherwise. Assume that the goal g given as input to the decision procedure is a=c. If the set of predicates P consists of the predicates a=b and b=c, and one of the rules in R is the rule of transitivity (i.e., if x=y and y=z, then x=z), then the goal (a=c) is consistent with P and R, and the decision procedure returns “true.”
A saturation decision procedure is a decision procedure with a set of inference rules R that takes as input a set of predicates P and outputs the set of predicates P′ that can be derived from application of the rules R to P.
For example, assume that the goal g given as input to the decision procedure is a=d. If the set of predicates P consists of the predicates a=b and b=c, and R consists of the rule of transitivity, then the predicate a=c can be derived from P and is included in the set P′. However, after inputting P′ (where P′={a=b, b=c, a=c}), no new predicates are derived. The saturation decision procedure then determines that the goal (a=d ) is not in P′.
B. Predicate Abstraction via Symbolic Decision Procedures
In described techniques and tools, predicate abstraction is performed using symbolic decision procedures. Symbolic decision procedures use symbolic expressions to describe ranges or combinations of inputs. Because symbolic expressions can represent many different possible inputs in a single expression, symbolic decision procedures are able to analyze many possible inputs without requiring a call to a theorem prover for each input.
For example, a symbolic decision procedure can determine several ways in which g can be derived from (and is consistent with) predicates in P. For example, given a set of predicates P={a=b, b=c, a=d, d=c} and the goal a=c, a symbolic decision procedure can extract the possible ways in which a=c can be derived from the predicates in P (namely, from the predicates a=b and b=c, or from the predicates a=d and d=c).
Or, a symbolic decision procedure can determine subsets of predicates in P (if any) with which g is inconsistent. Given an input set of predicates P and a goal g, a symbolic decision procedure outputs one or more subsets P′ of predicates such that each subset P′ is inconsistent with g. For example, assuming a set of rules R that includes the transitivity rule in the symbolic decision procedure, if a subset P′={a=b, b=c}, and g is a≠c, then g is inconsistent with P′. The symbolic decision procedure returns the subset P′. The symbolic decision procedure also can return other subsets of P that are inconsistent with g. In other words, the output of the symbolic decision procedure represents the set of subsets of P that are inconsistent with g.
A reduction in computational complexity is made possible by the nature of symbolic decision procedures and a data structure maintained during predicate abstraction.
For example,
Combined symbolic decision procedures can be used to perform predicate abstraction on source programs having different logic theories. For example, a source program may have logic that deals with mathematic properties of integers (e.g., integer x is greater than, less than, or equal to integer y, etc.) and logic that deals with arrays (e.g., array element A[i] is equal to array element A[j] because the integer at index i and the integer at index j are equal to each other). In such cases, symbolic decision procedures having rules specific to each kind of logic can be combined, and the combined symbolic decision procedure can be used for predicate abstraction.
For example,
II. Detailed Examples
This section provides a detailed explanation of principles underlying described predicate abstraction techniques and tools, with reference to specific examples. Various implementations of the described techniques and tools are possible based on principles described in this section. In practice, implementations of the described techniques and tools can differ in some respects from the specific examples described in this section. For example, different inference rules can be used, and the techniques described can be applied to perform predicate abstraction on different kinds of source program logic (e.g., array theories, string theories, pointer theories, etc.).
A fundamental operation in predicate abstraction can be summarized as follows. Given a set of predicates P describing some set of properties of the system state, and a formula e, compute the weakest Boolean formula FP(e) over the predicates P that implies e. (The dual of this problem, which is to compute the strongest Boolean formula GP(e) that is implied by e, can be expressed as FP(e).)
In the detailed examples provided in this section, a symbolic decision procedure (“SDP”) for a theory T (SDPT) takes sets of predicates G and E and symbolically executes a decision procedure for T on G′ ∪{e|e ε E}, for all the subsets G′ of G. The result of SDPT is a shared expression (represented by a directed acyclic graph) that implicitly represents the answer to a predicate abstraction query. The shared expression (an expression where common sub-expressions can be shared) represents those subsets G′⊂G, for which G′ ∪{e|e ε E} is unsatisfiable. We show that such a procedure can be used to compute FP (e) for performing predicate abstraction.
The detailed examples provided in this section present symbolic decision procedures for the logic of Equality and Uninterpreted Functions (EUF) and Difference logic (DIF) and show that these procedures run in polynomial and pseudo-polynomial time, respectively (rather than exponential time), and therefore produce compact shared expressions. A method to construct SDPs for simple mixed theories (including EUF+DIF) is provided that uses an extension of the Nelson-Oppen combination method. Binary decision diagrams (BDDs) are used to construct FP(e) from the shared representations efficiently in practice. An evaluation on predicate abstraction benchmarks from device driver verification in the SLAM toolkit is provided, and shows improvement over other predicate abstraction methods.
The function and predicate symbols can either be “uninterpreted” or can be defined by a particular theory. For instance, the theory of integer linear arithmetic defines the function-symbol “+” to be the addition function over integers and “<” to be the comparison predicate over integers. If an expression involves function or predicate symbols from multiple theories, then it is said to be an expression over “mixed” theories. A formula F is said to be “satisfiable” if it is possible to assign values to the various symbols in the formula from the domains associated with the theories to make the formula true. A formula is “valid” if F is not satisfiable. We say a formula A “implies” a formula B (AB) if and only if (A) B is valid.
A “shared expression” is a directed acyclic graph (DAG) representation of an expression where common subexpressions can be shared, by using names to refer to common subexpressions. For example, the intermediate variable t refers to the expression e1 in the shared expression “let t=e1 in (e2t) (e3t)”.
A predicate is an atomic formula or its negation. (The phrase “predicate symbol” (rather than the word “predicate” alone) is used to refer to symbols like “<”.) If G is a set of predicates, then we define {tilde over (G)}≐{g|g ε G}, to be the set containing the negations of the predicates in G. The word “predicate” in this context is used in a general sense to refer to any atomic formula or its negation and should not be confused to mean only the set of predicates that are used in predicate abstraction.
Given a set of predicates P≐{p1, . . . , pn} and a formula e, the main operation in predicate abstraction involves constructing the weakest Boolean formula FP(e) over P such that FP(e)e. The expression FP(e) can be expressed as the set of all the minterms over P that imply e:
FP(e)={c|c is a minterm over P and c implies e} (1)
These properties follow very easily from the definition of FP. We know that FP(e)e, by the definition of FP(e). By contrapositive rule, eFP(e). But FP(e)e. Therefore, FP(e)FP(e). To prove the second equation, we prove that (i) FP(e1e2)(FP(e1)FP(e2)), and (ii) (FP(e1l)FP(e2))FP(e1e2). Since e1^e2) ei (for i ε {1, 2}), FP(e1e2)) FP(ei). Therefore FP(e1e2)(FP(e1)FP(e2)). On the other hand, FP(e1)e1 and FP(e2)e2, FP(e1)FP(e2)e1e2. Since FP(e1e2) is the weakest expression that implies e1e2, FP(e1)FP(e2)FP(e1e2). To prove the third equation, note that FP(e1)FP(e2)e1e2 and FP(e1e2) is the weakest expression that implies e1e2.
The operation FP(e) does not distribute over disjunctions. Consider the example where P≐{x≠5} and e=x<5x>5. In this case, FP(e)=x≠5. However FP(x<5)=“false” and FP(x>5)=“false” and thus (Fp(x<5)FP(x>5)) is not the same as FP(e).
The above properties suggest that one can adopt a two-tier approach to compute FP (e) for any formula e:
1. Convert e into an equivalent Conjunctive Normal Form (CNF), which comprises a conjunction of clauses, i.e., e≡(cli).
2. For each clause cli≐(e1ie2i . . . emi), compute ri≐FP(cli) and return FP(e)≐(ri).
We focus here on computing FP(eiεEei) when ei is a predicate. Unless specified otherwise, we use e to denote (eiεEei), a disjunction of predicates in the set E in the sequel. For converting a formula to an equivalent CNF efficiently, we can use satisfiability (SAT) algorithms.
A. Predicate Abstraction Using Symbolic Decision Procedures (SDPs)
A set of predicates G (over theory T) is unsatisfiable if the formula (gεG g) is unsatisfiable. For a given theory T, the decision procedure for T takes a set of predicates G in the theory and checks if G is unsatisfiable. A theory is defined by a set of inference rules. An inference rule R is of the form:
which denotes that the predicate A can be derived from predicates A1, . . . , An in one step. Each theory has least one inference rule for deriving contradiction (⊥). We also use g:-g1, . . . , gk to denote that the predicate g (or ⊥, where g=⊥) can be derived from the predicates g1, . . . , gk using one of the inference rules in a single step.
1. Saturation-Based Decision Procedures
A saturation-based decision procedure for a theory T can be used to describe the meaning of a symbolic decision procedure for the theory T.
Consider a simple saturation-based procedure DPT (800) shown in
The parameter d≐derivDepthT (G) is a bound (that is determined solely by the set G for the theory T) such that if the loop at 820 is repeated for at least d steps, then DPT (G) returns UNSATISFIABLE if and only if G is unsatisfiable. If such a bound exists for any set of predicates G in the theory, then DPT procedure implements a decision procedure for T.
To show that a theory T is a saturation theory, it suffices to consider a decision procedure algorithm for T (e.g., AT) and show that DPT implements AT. This can be shown by deriving a bound on derivDepthT (G) for any set G in the theory.
2. Symbolic Decision Procedures
A symbolic decision procedure can yield a shared expression of FP(e) for predicate abstraction.
For a (saturation) theory T, a symbolic decision procedure for T (SDPT) takes sets of predicates G and E as inputs, and symbolically simulates DPT on G′∪{tilde over (E)}, for every subset G′⊂G. The output of SDPT (G, E) is a symbolic expression representing those subsets G′⊂G, such that G′∪{tilde over (E)} is unsatisfiable. Thus with |G|=n, a single run of SDPT symbolically executes 2n runs of DPT.
We introduce a set of Boolean variables BG≐{bg|g ε G}, one for each predicate in G. An assignment σ: BG→{true, false} over BG uniquely represents a subset G′≐{g|σ(bg)=true} of G.
Since SDP(G, E) has to execute DPT (G′∪{tilde over (E)}) on all G′⊂G, the number of steps to iterate the saturation loop equals the maximum derivDepthT (G′∪{tilde over (E)}) for any G′⊂G. For a set of predicates S, we define the bound maxDerivDepthT (S) as follows:
maxDerivDepthT(S)≐max{derivDepthT(S′)|S′⊂Sg
Terminating the loop at 920 of symbolic decision procedure SDPT(G, E) in
The following example shows that the saturation of the set of derived predicates in the SDPT algorithm is not a sufficient condition for termination. Consider an example where G contains a set of predicates that denotes an “almost” fully connected graph over vertices x1, . . . , xn. G contains an equality predicate between every pair of variables except the edge between x1 and xn. Let E≐{x1=xn}. After one iteration of the SDPT algorithm on this example, W will contain an equality between every pair of variables including x1 and xn since x1=xn can be derived from x1=xi, xi=xn, for every 1<i<n. Therefore, if the SDPT algorithm terminates once the set of predicates in W terminates, the procedure will terminate after two steps. Now, consider the subset G′={x1=x2, x2=x3, . . . , xi=xi+1, . . . , xn−1=xn} of G. For this subset of G, DPT (G′∪{tilde over (E)}) requires lg (n)>1 (for n>2) steps to derive the fact x1=xn. Therefore SDPT(G, E) does not simulate the action of DPT (G′∪{tilde over (E)}). More formally, eval(t[e], G′)=false, but G′∪{tilde over (E)} is unsatisfiable.
During the execution, the algorithm constructs a set of shared expressions with the variables over BG as the leaves and temporary variables t[•] to name intermediate expressions. We use t[(g, i)] to denote the expression for the predicate g after the iteration i of the loop at 920. We use t[(g, TM)] to denote the top-most expression for g in the shared expression. Below, we briefly describe phases of SDPT:
We now define the evaluation of a (shared) expression with respect to a subset G′⊂G.
A proof of Theorem 1 follows.
To prove Theorem 1, we first describe an intermediate lemma about SDPT. To disambiguate between the data structures used in DPT and SDPT, we use WS and W′S (corresponding to symbolic) to denote W and W′ respectively for the SDP algorithm. Moreover, it is also clear that W′ (respectively W′S) at the iteration i is the same as W (respectively WS) after i−1 iterations.
To prove part (2) of the lemma, we will consider two cases depending on whether a predicate g was present in W before the mth iteration:
Consider the situation where both SDPT(G, E) and DPT (G′∪{tilde over (E)}) have executed the loop in process block 920 for i=maxDerivDepthT (G∪{tilde over (E)}). We will consider two cases depending on whether ⊥ can be derived in DPT(G′∪{tilde over (E)}) in step process block 930.
Suppose after i iterations, there is a set {g1, . . . , gk}⊂W, such that ⊥:-g1, . . . , gk. This implies that G′∪{tilde over (E)} is unsatisfiable. By Lemma 1, we know that eval(t[(gj, TM)], G′)=true for each gj ε {g1, . . . , gk}, and therefore eval(t[e], G′)=true.
On the other hand, let eval(t[e], G′)=true. This implies that there exists a set {g1, . . . , gk}⊂WS, such that ⊥:-g1, . . . , gk and eval(t[(gj, TM)], G′)=true for each gj ε {g1, . . . , gk}. By Lemma 1, we know that {g1, . . . , gk} ε W, for the DPT procedure, too. This means that DPT (G′∪{tilde over (E)}) will return unsatisfiable.
This completes the proof of Theorem 1.
Hence t[e] is a shared expression for FP (e), where e denotes eiεE ei. An explicit representation of FP (e) can be obtained by first computing t[e]≐SDPT (P∪{tilde over (P)}, E) and then enumerating the cubes over P that make t[e] true.
Below, we instantiate T to be the EUF and DIF theories and show that SDPT exists for such theories. For each theory, we only need to determine the value of maxDerivDepthT (G) for any set of predicates G.
3. SDP for Equality and Uninterpreted Functions
The terms in this logic can either be variables or application of an uninterpreted function symbol to a list of terms. A predicate in this theory is t1˜t2, where ti is a term and ˜ ε {=, ≠}. For a set G of EUF predicates, G= and G≠ denote the set of equality and disequality predicates in G, respectively.
Let terms(φ) denote the set of syntactically distinct terms in an expression (a term or a formula) φ. For example, terms(f(h(x))) is {x, h(x),f(h(x))}. For a set of predicates G, terms(G) denotes the union of the set of terms in any g ε G.
A decision procedure for EUF can be obtained by the congruence closure algorithm 1000 described in
For a set of predicates G, let m=|terms(G)|. We can show that if we iterate the loop at 820 of
Proof. We first determine the derivDepthT (G) for any set of predicates in this theory. Given a set of EUF predicates G, and two terms t1 and t2 in terms(G), we need to determine the maximum number of iterations in process block 820 of DPT(G) (
Recall that the congruence closure algorithm (described in
One way to maintain an equivalence class C≐{t1l, . . . , tn} is to keep an equality ti=tj between every pair of terms in C. At any point in the congruence closure algorithm, the set of equivalence classes corresponds to a set of equalities C=over terms. Then EC(u)=EC(v) can be implemented by checking if u=V ε C=. This representation allows us to build SDPT for this theory. Let us implement the C′=≐merge(C=, t1, t2) operation that takes in the current set of equivalence classes C=, two terms t1 and t2 that are merged and returns the set of equalities C′=denoting the new set of equivalence classes. This can be implemented using the step shown in process block 820 of the DPT algorithm as follows:
Observe that this decision procedure DPT for EUF does not need to derive a predicate t1=t2 from G, if both t1 and t2 do not belong to terms(G). Otherwise, if one generates t1=t2, then the infinite sequence of predicates f(t1)=f(t2); f(f(t1))=f(f(t2)), . . . can be generated without ever converging.
Again, since maxDerivDepthT (G) is the maximum derivDepthT (G′) for any subset G′⊂G, and any G′ can have at most m terms, maxDerivDepthT (G) is bounded by 3 m. We also believe that a more refined counting argument can reduce it to 2 m, because two equivalent classes can be merged simultaneously in the DPT algorithm.
The run time and size of expression generated by SDPT depend both on maxDerivDepthT (G) for the theory and also on the maximum number of predicates in W at any point during the algorithm. The maximum number of predicates in W can be at most m(m−1)/2, considering equality between every pair of terms. The disequalities are never used except for generating contradictions. It also can be verified that the size of S(g) (used at 920 in
4. SDP for Difference Logic
Difference logic is a simple yet useful fragment of linear arithmetic, where predicates are of the form xy+c, where x,y are variables, ε {<, ≦} and c is a real constant. Any equality x=y+c is represented as a conjunction of x≦y+c and y≦x−c. The variables x and y are interpreted over real numbers. The function symbol “+” and the predicate symbols {<, ≦} are the interpreted symbols of this theory.
Given a set G of difference logic predicates, we can construct a graph where the vertices of the graph are the variables in G and there is a directed edge in the graph from x to y, labeled with (, c) if x y+c ε G. We will use a predicate and an edge interchangeably in this section.
and either (i) all the edges in the cycle are≦edges and d<0, or (ii) at least one edge is an<edge and d≦0.
It is well known that a set of difference predicates G is unsatisfiable if and only the graph constructed from the predicates has a simple illegal cycle. Alternately, if we add an edge (c) between x and y for every simple path from x to y of weight c ( determined by the labels of the edges in the path), then we only need to check for simple cycles of length two in the resultant graph. This corresponds to the rules (C) and (D) in
For a set of predicates G, a predicate corresponding to a simple path in the graph of G can be derived within lg(m) iterations at 820 of
Proof. It is not hard to see that if there is a simple path xx1+c1; x1 2x2+c2, . . . , xn−1ny+cn in the original graph of G, then after lg(m) iterations, there is a predicate x′y+C in W; where
and ′ is < if at least one of i is < and ≦ otherwise. This is because if there is a simple path between x and y through edges in G with length (number of edges from G) between 2i−1 and 2i, then the algorithm DPT generates a predicate for the path during iteration i.
However, DPT can produce a predicate xy+c, even though none of the simple paths between x and y add up to this predicate. These facts are generated by the non-simple paths that go around cycles one or more times. Consider the set G≐{x<y+1,y<x−2, x<z−1, . . . }. In this case we can produce the fact y<z−3 from y<x−2, x<z−1 and then x<z−2 from y<z−3,x<y+1.
To prove the correctness of the DPT algorithm, we will show these additional facts can be safely generated. Consider two cases:
(1) Suppose there is an illegal cycle in the graph. In that case, after lg(m) steps, we will have two facts xy+c and yx+d in W such that they form an illegal cycle. Thus DPT returns unsatisfiable.
Note that we do not need any inference rule to weaken a predicate, X<Y+D:−X<Y+C, with C<D. This is because we use the predicates generated only to detect illegal cycles. If a predicate x<y+c does not form an illegal cycle, then neither does any weaker predicate x<y+d, where d≧c.
Complexity of SDPT. Let cmax be the absolute value of the largest constant in the set G. We can ignore any derived predicate of the form xy+c from the set W where the absolute value of C is greater than (m−1)*cmax. This is because the maximum weight of any simple path between x and y can be at most (m−1)*cmax. Again, let const(g) be the absolute value of the constant in a predicate g. The maximum weight on any simple path has to be a combination of these weights.
Thus, the absolute value of the constant is bound by:
The maximum number of derived predicates in W can be 2*m2*(2*C+1), where a predicate can be either ≦ or <, with m2 possible variable pairs and the absolute value of the constant is bound by C. This is a pseudo-polynomial bound as it depends on the value of the constants in the input.
However, many program verification queries use a subset of difference logic where each predicate is of the form xy or xc. For this case, the maximum number of predicates generated can be 2*m*(m−1+k), where k is the number of different constants in the input.
B. Combining SDPs for Saturation Theories
In this section, we provide a method to construct a symbolic decision procedure for the combination of saturation theories T1 and T2, given SDP for T1 and T2. The combination in this example is based on an extension of the Nelson-Oppen (N-O) framework that constructs a decision procedure for the theory T1∪T2 using the decision procedures of T1 and T2.
We assume that the theories T1 and T2 have disjoint signatures (i.e., they do not share any function symbol), and each theory Ti is convex and stably infinite. (We need these restrictions only to exploit the N-O combination result.)
1. Combining Decision Procedures
Given two theories T1 and T2 and the decision procedures DPT1 and DPT2, the N-O framework constructs the decision procedure for T1∪T2, denoted as DPT1∪T2.
To decide an input set G, the first step in the procedure is to “purify” G into sets G1 and G2 such that Gi only contains symbols from theory Ti and G is satisfiable if and only if G1∪G2 is satisfiable. Consider a predicate g≐p(t1, . . . , tn) in G, where p is a theory T1 symbol. The predicate g is purified to G′ by replacing each sub-term tj whose top-level symbol does not belong to T1 with a fresh variable wj. The expression tj is then purified to t′j recursively. We add G′ to G1 and the “binding predicate” wj=t′j to the set G2. We denote the latter as a binding predicate because it binds the fresh variable wj to a term t′j. Let Vsh be the set of shared variables that appear in G1∩G2. A set of equalities A over variables in Vsh is maintained; Δ records the set of equalities implied by the facts from either theory. Initially, Δ={ }.
Each theory Ti then alternately decides if DPTi (Gi∪Δ) is unsatisfiable. If any theory reports as UNSATISFIABLE, the algorithm returns UNSATISFIABLE; otherwise, the theory Ti generates the new set of equalities over Vsh that are implied by Gi∪Δ. (We assume that each theory has an inference rule for deriving equality between variables in the theory, and DPT also returns a set of equality over variables.) These equalities are added to Δ and are communicated to the other theory. This process is continued until the set Δ does not change. In this case, the method returns SATISFIABLE. Let us denote this algorithm as DPT1∪T2.
There can be at most |Vsh| irredundant equalities over Vsh. Therefore, the N-O loop terminates after |Vsh| iterations for any input.
2. Combining SDPs
A method of constructing SDPT1∪T2 by combining SDPT1 and SDPT2 is now described. The SDPs for each theory are combined modularly, using an extension of the Nelson-Oppen framework. As before, the input to the method is the pair (G, E) and the output is an expression t[e]. The facts in E are also purified into sets E1 and E2 and the new binding predicates are added to either G1 or G2.
To symbolically encode the runs of the N-O procedure for G′∪{tilde over (E)}, for every G′⊂G. For any equality predicate δ over Vsh, we maintain an expression ψ_δ that records the different ways to derive δ (initialized to false). We also maintain an expression ψ_e to record the derivations of e (initialized to false).
The N-O loop operates like the case for constructing DPT1∪T2. The SDPTi for each theory Ti now takes (Gi∪Δ, Ei) as input, where Δ is the set of equalities over Vsh derived so far. In addition to computing the (shared) expression t[e] as before, SDPTi also returns the expression t[(δ, TM)], for each equality δ over Vsh that can be derived (see process block 920 of the SDPT algorithm (
The leaves of the expressions t[e] and t[(δ, TM)] are Gi∪Δ (since leaves for {tilde over (E)}i are replaced with true). We substitute the leaves for any δ ε Δ with the expression ψ_δ to incorporate the derivations of δ until this point. We also update ψ_δ←(ψ_δt[(δ, TM)]) to add the new derivations of δ. Similarly, we update ψ_e←(ψ_et[e]) with the new derivations.
The N-O loop iterates |Vsh| number of times to ensure that it has seen every derivation of a shared equality over Vsh from any set G′1∪G′2∪{tilde over (E)}1∪{tilde over (E)}2, where G′i⊂Gi.
After the N-O iteration terminates, ψ_e contains all the derivations of e from G. However, at this point, there are two kinds of predicates in the leaves of ψ_e; the purified predicates and the binding predicates. If G′ was the purified form of a predicate g ε G, we replace the leaf for G′ with bg. The leaves of the binding predicates are replaced with true, as the fresh variables in these predicates are really names for sub-terms in any predicate, and thus their presence does not affect the satisfiability of a formula. Let t[e] denote the final expression for ψ_e that is returned by SDPT1∪T2. Observe that the leaves of t[e] are variables in BG.
C. Example Implementation and Experimental Results
This section describes and implementation and experimental results of applying a symbolic decision procedure technique for the combination of EUF and DIF theories. To construct FP (e), a binary decision diagram (BDD) is built using the Colorado University Decision Diagram package for the expression t[e] (returned by SDPT(P∪{tilde over (P)},E)) and then enumerate the cubes from the BDD. Since the number of leaves of t[e] (alternately, the number of BDD variables) is bound by |P|, the size of the overall BDD is usually small, and is computed efficiently in practice. Moreover, by generating only the prime implicants of FP (e) from the BDD, we obtain a compact representation of FP (e). (For any Boolean formula φ over variables in V, prime implicants of φ is a set of cubes C≐{c1, . . . , cm} over V such that φcεCc and two or more cubes from C can't be combined to form a larger cube.)
The results evaluate a symbolic decision procedure-based predicate abstraction method on a set of software verification benchmarks. The benchmarks are generated from the predicate abstraction step for constructing Boolean programs from C programs of Microsoft Windows device drivers in Microsoft's SLAM toolkit. The method is compared with two other methods for performing predicate abstraction. The DP-based method uses the decision procedure ZAPATO, developed by Microsoft Corporation, to enumerate the set of cubes that imply e. Various optimizations (e.g., considering cubes in increasing order of size) are used to prevent enumerating exponential number of cubes in practice. The method based on the UCLID system available from Carnegie Mellon University performs quantifier-elimination using incremental SAT-based methods.
To compare with the DP-based method, we generated 665 predicate abstraction queries from the verification of device-driver programs. Most of these queries had between 5 and 14 predicates in them and are fairly representative of queries in SLAM. The run time of DP-based method was 27904 seconds on a 3 GHz machine with 1 GB memory. The run time of the SDP-based method was 273 seconds. This gives a little more than 100× speedup on these examples, demonstrating that symbolic decision procedure-based techniques can scale much better than other decision procedure based methods.
To compare with a UCLID-based approach, different instances of a problem were generated where P is a set of equality predicates representing n diamonds connected in a chain and e is an equality a1=dn, as shown in
III. Computing Environment
The techniques and tools described herein can be implemented on any of a variety of computing devices and environments, including computers of various form factors (personal, workstation, server, handheld, laptop, tablet, or other mobile), distributed computing networks, and Web services, as a few general examples. The techniques and tools can be implemented in hardware circuitry, as well as in software executing within a computer or other computing environment, such as shown in
With reference to
A computing environment may have additional features. For example, the computing environment 1300 includes storage 1340, one or more input devices 1350, one or more output devices 1360, and one or more communication connections 1370. An interconnection mechanism (not shown) such as a bus, controller, or network interconnects the components of the computing environment 1300. Typically, operating system software (not shown) provides an operating environment for other software executing in the computing environment 1300, and coordinates activities of the components of the computing environment 1300.
The storage 1340 may be removable or non-removable, and includes magnetic disks, magnetic tapes or cassettes, CD-ROMs, CD-RWs, DVDs, or any other medium which can be used to store information and which can be accessed within the computing environment 1300. For example, the storage 1340 stores instructions for implementing software 1380.
The input device(s) 1350 may be a touch input device such as a keyboard, mouse, pen, or trackball, a voice input device, a scanning device, or another device that provides input to the computing environment 1300. The output device(s) 1360 may be a display, printer, speaker, CD-writer, or another device that provides output from the computing environment 1300.
The communication connection(s) 1370 enable communication over a communication medium to another computing entity. The communication medium conveys information such as computer-executable instructions, audio/video or other media information, or other data in a data signal. By way of example, and not limitation, communication media include wired or wireless techniques implemented with an electrical, optical, RF, infrared, acoustic, or other carrier.
Techniques and tools described herein can be described in the general context of computer-readable media. Computer-readable media are any available storage media that can be accessed within a computing environment. By way of example, and not limitation, with the computing environment 1300, computer-readable media include memory 1320, storage 1340, and combinations of any of the above.
Some techniques and tools herein can be described in the general context of computer-executable instructions, such as those included in program modules, being executed in a computing environment on a target real or virtual processor. Generally, program modules include functions, programs, libraries, objects, classes, components, data structures, etc. that perform particular tasks or implement particular abstract data types. The functionality of the program modules may be combined or split between program modules as desired. Computer-executable instructions may be executed within a local or distributed computing environment.
Having described and illustrated the principles of our innovations in the detailed description and the accompanying drawings, it will be recognized that the various embodiments can be modified in arrangement and detail without departing from such principles. It should be understood that the programs, processes, or methods described herein are not related or limited to any particular type of computing environment, unless indicated otherwise. Various types of general purpose or specialized computing environments may be used with or perform operations in accordance with the teachings described herein. Elements of embodiments shown in software may be implemented in hardware and vice versa.
In view of the many possible embodiments to which the principles of our invention may be applied, we claim as our invention all such embodiments as may come within the scope and spirit of the following claims and equivalents thereto.
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20070005633 A1 | Jan 2007 | US |