1 \section{Sets and Relations}
3 \begin{definition}[Polyhedral Set]
4 A {\em polyhedral set}\index{polyhedral set} $S$ is a finite union of basic sets
5 $S = \bigcup_i S_i$, each of which can be represented using affine
8 S_i : \Z^n \to 2^{\Z^d} : \vec s \mapsto
10 \{\, \vec x \in \Z^d \mid \exists \vec z \in \Z^e :
11 A \vec x + B \vec s + D \vec z + \vec c \geq \vec 0 \,\}
14 with $A \in \Z^{m \times d}$,
15 $B \in \Z^{m \times n}$,
16 $D \in \Z^{m \times e}$
17 and $\vec c \in \Z^m$.
20 \begin{definition}[Parameter Domain of a Set]
21 Let $S \in \Z^n \to 2^{\Z^d}$ be a set.
22 The {\em parameter domain} of $S$ is the set
23 $$\pdom S \coloneqq \{\, \vec s \in \Z^n \mid S(\vec s) \ne \emptyset \,\}.$$
26 \begin{definition}[Polyhedral Relation]
27 A {\em polyhedral relation}\index{polyhedral relation}
28 $R$ is a finite union of basic relations
29 $R = \bigcup_i R_i$ of type
30 $\Z^n \to 2^{\Z^{d_1+d_2}}$,
31 each of which can be represented using affine
36 \{\, \vec x_1 \to \vec x_2 \in \Z^{d_1} \times \Z^{d_2}
37 \mid \exists \vec z \in \Z^e :
38 A_1 \vec x_1 + A_2 \vec x_2 + B \vec s + D \vec z + \vec c \geq \vec 0 \,\}
41 with $A_i \in \Z^{m \times d_i}$,
42 $B \in \Z^{m \times n}$,
43 $D \in \Z^{m \times e}$
44 and $\vec c \in \Z^m$.
47 \begin{definition}[Parameter Domain of a Relation]
48 Let $R \in \Z^n \to 2^{\Z^{d+d}}$ be a relation.
49 The {\em parameter domain} of $R$ is the set
50 $$\pdom R \coloneqq \{\, \vec s \in \Z^n \mid R(\vec s) \ne \emptyset \,\}.$$
53 \begin{definition}[Domain of a Relation]
54 Let $R \in \Z^n \to 2^{\Z^{d+d}}$ be a relation.
55 The {\em domain} of $R$ is the polyhedral set
56 $$\domain R \coloneqq \vec s \mapsto
57 \{\, \vec x_1 \in \Z^{d_1} \mid \exists \vec x_2 \in \Z^{d_2} :
58 (\vec x_1, \vec x_2) \in R(\vec s) \,\}
63 \begin{definition}[Range of a Relation]
64 Let $R \in \Z^n \to 2^{\Z^{d+d}}$ be a relation.
65 The {\em range} of $R$ is the polyhedral set
67 \range R \coloneqq \vec s \mapsto
68 \{\, \vec x_2 \in \Z^{d_2} \mid \exists \vec x_1 \in \Z^{d_1} :
69 (\vec x_1, \vec x_2) \in R(\vec s) \,\}
74 \begin{definition}[Composition of Relations]
75 Let $R \in \Z^n \to 2^{\Z^{d_1+d_2}}$ and
76 $S \in \Z^n \to 2^{\Z^{d_2+d_3}}$ be two relations,
77 then the composition of
78 $R$ and $S$ is defined as
82 \{\, \vec x_1 \to \vec x_3 \in \Z^{d_1} \times \Z^{d_3}
83 \mid \exists \vec x_2 \in \Z^{d_2} :
84 \vec x_1 \to \vec x_2 \in R(\vec s) \wedge
85 \vec x_2 \to \vec x_3 \in S(\vec s)
91 \begin{definition}[Difference Set of a Relation]
92 Let $R \in \Z^n \to 2^{\Z^{d+d}}$ be a relation.
93 The difference set ($\Delta \, R$) of $R$ is the set
94 of differences between image elements and the corresponding
99 \{\, \vec \delta \in \Z^{d} \mid \exists \vec x \to \vec y \in R :
100 \vec \delta = \vec y - \vec x
105 \section{Simple Hull}\label{s:simple hull}
107 It is sometimes useful to have a single
108 basic set or basic relation that contains a given set or relation.
109 For rational sets, the obvious choice would be to compute the
110 (rational) convex hull. For integer sets, the obvious choice
111 would be the integer hull.
112 However, {\tt isl} currently does not support an integer hull operation
113 and even if it did, it would be fairly expensive to compute.
114 The convex hull operation is supported, but it is also fairly
115 expensive to compute given only an implicit representation.
117 Usually, it is not required to compute the exact integer hull,
118 and an overapproximation of this hull is sufficient.
119 The ``simple hull'' of a set is such an overapproximation
120 and it is defined as the (inclusion-wise) smallest basic set
121 that is described by constraints that are translates of
122 the constraints in the input set.
123 This means that the simple hull is relatively cheap to compute
124 and that the number of constraints in the simple hull is no
125 larger than the number of constraints in the input.
126 \begin{definition}[Simple Hull of a Set]
127 The {\em simple hull} of a set
128 $S = \bigcup_{1 \le i \le v} S_i$, with
130 S : \Z^n \to 2^{\Z^d} : \vec s \mapsto
132 \left\{\, \vec x \in \Z^d \mid \exists \vec z \in \Z^e :
133 \bigvee_{1 \le i \le v}
134 A_i \vec x + B_i \vec s + D_i \vec z + \vec c_i \geq \vec 0 \,\right\}
138 H : \Z^n \to 2^{\Z^d} : \vec s \mapsto
140 \left\{\, \vec x \in \Z^d \mid \exists \vec z \in \Z^e :
141 \bigwedge_{1 \le i \le v}
142 A_i \vec x + B_i \vec s + D_i \vec z + \vec c_i + \vec K_i \geq \vec 0
146 with $\vec K_i$ the (component-wise) smallest non-negative integer vectors
147 such that $S \subseteq H$.
149 The $\vec K_i$ can be obtained by solving a number of
150 LP problems, one for each element of each $\vec K_i$.
151 If any LP problem is unbounded, then the corresponding constraint
154 \section{Coalescing}\label{s:coalescing}
156 See \shortciteN{Verdoolaege2009isl}, for now.
157 More details will be added later.
159 \section{Transitive Closure}
161 \subsection{Introduction}
163 \begin{definition}[Power of a Relation]
164 Let $R \in \Z^n \to 2^{\Z^{d+d}}$ be a relation and
166 a positive number, then power $k$ of relation $R$ is defined as
168 \label{eq:transitive:power}
171 R & \text{if $k = 1$}
173 R \circ R^{k-1} & \text{if $k \ge 2$}
179 \begin{definition}[Transitive Closure of a Relation]
180 Let $R \in \Z^n \to 2^{\Z^{d+d}}$ be a relation,
181 then the transitive closure $R^+$ of $R$ is the union
182 of all positive powers of $R$,
184 R^+ \coloneqq \bigcup_{k \ge 1} R^k
188 Alternatively, the transitive closure may be defined
191 \label{eq:transitive:inductive}
192 R^+ \coloneqq R \cup \left(R \circ R^+\right)
196 Since the transitive closure of a polyhedral relation
197 may no longer be a polyhedral relation \shortcite{Kelly1996closure},
198 we can, in the general case, only compute an approximation
199 of the transitive closure.
200 Whereas \shortciteN{Kelly1996closure} compute underapproximations,
201 we, like \shortciteN{Beletska2009}, compute overapproximations.
202 That is, given a relation $R$, we will compute a relation $T$
203 such that $R^+ \subseteq T$. Of course, we want this approximation
204 to be as close as possible to the actual transitive closure
205 $R^+$ and we want to detect the cases where the approximation is
206 exact, i.e., where $T = R^+$.
208 For computing an approximation of the transitive closure of $R$,
209 we follow the same general strategy as \shortciteN{Beletska2009}
210 and first compute an approximation of $R^k$ for $k \ge 1$ and then project
211 out the parameter $k$ from the resulting relation.
214 As a trivial example, consider the relation
215 $R = \{\, x \to x + 1 \,\}$. The $k$th power of this map
218 R^k = k \mapsto \{\, x \to x + k \mid k \ge 1 \,\}
221 The transitive closure is then
224 R^+ & = \{\, x \to y \mid \exists k \in \Z_{\ge 1} : y = x + k \,\}
226 & = \{\, x \to y \mid y \ge x + 1 \,\}
232 \subsection{Computing an Approximation of $R^k$}
235 There are some special cases where the computation of $R^k$ is very easy.
236 One such case is that where $R$ does not compose with itself,
237 i.e., $R \circ R = \emptyset$ or $\domain R \cap \range R = \emptyset$.
238 In this case, $R^k$ is only non-empty for $k=1$ where it is equal
241 In general, it is impossible to construct a closed form
242 of $R^k$ as a polyhedral relation.
243 We will therefore need to make some approximations.
244 As a first approximations, we will consider each of the basic
245 relations in $R$ as simply adding one or more offsets to a domain element
246 to arrive at an image element and ignore the fact that some of these
247 offsets may only be applied to some of the domain elements.
248 That is, we will only consider the difference set $\Delta\,R$ of the relation.
249 In particular, we will first construct a collection $P$ of paths
251 a total of $k$ offsets and then intersect domain and range of this
252 collection with those of $R$.
255 \label{eq:transitive:approx}
256 K = P \cap \left(\domain R \to \range R\right)
261 \label{eq:transitive:path}
262 P = \vec s \mapsto \{\, \vec x \to \vec y \mid
263 \exists k_i \in \Z_{\ge 0} :
264 \vec y = \vec x + \sum_i k_i \, \Delta_i(\vec s)
269 and with $\Delta_i$ the basic sets that compose
270 the difference set $\Delta\,R$.
271 Note that the number of basic sets $\Delta_i$ need not be
272 the same as the number of basic relations in $R$.
273 Also note that since addition is commutative, it does not
274 matter in which order we add the offsets and so we are allowed
275 to group them as we did in \eqref{eq:transitive:path}.
277 If all the $\Delta_i$s are singleton sets
278 $\Delta_i = \{\, \vec \delta_i \,\}$ with $\vec \delta_i \in \Z^d$,
279 then \eqref{eq:transitive:path} simplifies to
281 \label{eq:transitive:singleton}
282 P = \{\, \vec x \to \vec y \mid
283 \exists k_i \in \Z_{\ge 0} :
284 \vec y = \vec x + \sum_i k_i \, \vec \delta_i
289 and then the approximation computed in \eqref{eq:transitive:approx}
290 is essentially the same as that of \shortciteN{Beletska2009}.
291 If some of $\Delta_i$s are not singleton sets or if
292 some of $\vec \delta_i$s are parametric, then we need
293 to resort to further approximations.
295 To ease both the exposition and the implementation, we will for
296 the remainder of this section work with extended offsets
297 $\Delta_i' = \Delta_i \times \{\, 1 \,\}$.
298 That is, each offset is extended with an extra coordinate that is
299 set equal to one. The paths constructed by summing such extended
300 offsets have the length encoded as the difference of their
301 final coordinates. The path $P'$ can then be decomposed into
302 paths $P_i'$, one for each $\Delta_i$,
304 \label{eq:transitive:decompose}
306 (P_m' \cup \identity) \circ \cdots \circ
307 (P_2' \cup \identity) \circ
308 (P_1' \cup \identity)
311 \vec x' \to \vec y' \mid y_{d+1} - x_{d+1} = k > 0
317 P_i' = \vec s \mapsto \{\, \vec x' \to \vec y' \mid
318 \exists k \in \Z_{\ge 1} :
319 \vec y' = \vec x' + k \, \Delta_i'(\vec s)
323 Note that each $P_i'$ contains paths of length at least one.
324 We therefore need to take the union with the identity relation
325 when composing the $P_i'$s to allow for paths that do not contain
326 any offsets from one or more $\Delta_i'$.
327 The path that consists of only identity relations is removed
328 by imposing the constraint $y_{d+1} - x_{d+1} > 0$.
329 Taking the union with the identity relation means that
330 that the relations we compose in \eqref{eq:transitive:decompose}
331 each consist of two basic relations. If there are $m$
332 disjuncts in the input relation, then a direct application
333 of the composition operation may therefore result in a relation
334 with $2^m$ disjuncts, which is prohibitively expensive.
335 It is therefore crucial to apply coalescing (\autoref{s:coalescing})
336 after each composition.
338 Let us now consider how to compute an overapproximation of $P_i'$.
339 Those that correspond to singleton $\Delta_i$s are grouped together
340 and handled as in \eqref{eq:transitive:singleton}.
341 Note that this is just an optimization. The procedure described
342 below would produce results that are at least as accurate.
343 For simplicity, we first assume that no constraint in $\Delta_i'$
344 involves any existentially quantified variables.
345 We will return to existentially quantified variables at the end
347 Without existentially quantified variables, we can classify
348 the constraints of $\Delta_i'$ as follows
350 \item non-parametric constraints
352 \label{eq:transitive:non-parametric}
353 A_1 \vec x + \vec c_1 \geq \vec 0
355 \item purely parametric constraints
357 \label{eq:transitive:parametric}
358 B_2 \vec s + \vec c_2 \geq \vec 0
360 \item negative mixed constraints
362 \label{eq:transitive:mixed}
363 A_3 \vec x + B_3 \vec s + \vec c_3 \geq \vec 0
365 such that for each row $j$ and for all $\vec s$,
367 \Delta_i'(\vec s) \cap
368 \{\, \vec x' \to \vec y' \mid B_{3,j} \vec s + c_{3,j} > 0 \,\}
371 \item positive mixed constraints
373 A_4 \vec x + B_4 \vec s + \vec c_4 \geq \vec 0
375 such that for each row $j$, there is at least one $\vec s$ such that
377 \Delta_i'(\vec s) \cap
378 \{\, \vec x' \to \vec y' \mid B_{4,j} \vec s + c_{4,j} > 0 \,\}
382 We will use the following approximation $Q_i$ for $P_i'$:
384 \label{eq:transitive:Q}
389 \mid {} & \exists k \in \Z_{\ge 1}, \vec f \in \Z^d :
390 \vec y' = \vec x' + (\vec f, k)
394 A_1 \vec f + k \vec c_1 \geq \vec 0
396 B_2 \vec s + \vec c_2 \geq \vec 0
398 A_3 \vec f + B_3 \vec s + \vec c_3 \geq \vec 0
403 To prove that $Q_i$ is indeed an overapproximation of $P_i'$,
404 we need to show that for every $\vec s \in \Z^n$, for every
405 $k \in \Z_{\ge 1}$ and for every $\vec f \in k \, \Delta_i(\vec s)$
407 $(\vec f, k)$ satisfies the constraints in \eqref{eq:transitive:Q}.
408 If $\Delta_i(\vec s)$ is non-empty, then $\vec s$ must satisfy
409 the constraints in \eqref{eq:transitive:parametric}.
410 Each element $(\vec f, k) \in k \, \Delta_i'(\vec s)$ is a sum
411 of $k$ elements $(\vec f_j, 1)$ in $\Delta_i'(\vec s)$.
412 Each of these elements satisfies the constraints in
413 \eqref{eq:transitive:non-parametric}, i.e.,
428 The sum of these elements therefore satisfies the same set of inequalities,
429 i.e., $A_1 \vec f + k \vec c_1 \geq \vec 0$.
430 Finally, the constraints in \eqref{eq:transitive:mixed} are such
431 that for any $\vec s$ in the parameter domain of $\Delta$,
432 we have $-\vec r(\vec s) \coloneqq B_3 \vec s + \vec c_3 \le \vec 0$,
433 i.e., $A_3 \vec f_j \ge \vec r(\vec s) \ge \vec 0$
434 and therefore also $A_3 \vec f \ge \vec r(\vec s)$.
435 Note that if there are no mixed constraints and if the
436 rational relaxation of $\Delta_i(\vec s)$, i.e.,
437 $\{\, \vec x \in \Q^d \mid A_1 \vec x + \vec c_1 \ge \vec 0\,\}$,
438 has integer vertices, then the approximation is exact, i.e.,
439 $Q_i = P_i'$. In this case, the vertices of $\Delta'_i(\vec s)$
440 generate the rational cone
441 $\{\, \vec x' \in \Q^{d+1} \mid \left[
445 \right] \vec x' \,\}$ and therefore $\Delta'_i(\vec s)$ is
446 a Hilbert basis of this cone \shortcite[Theorem~16.4]{Schrijver1986}.
448 Existentially quantified variables can be handled by
449 classifying them into variables that are uniquely
450 determined by the parameters, variables that are independent
451 of the parameters and others. The first set can be treated
452 as parameters and the second as variables. Constraints involving
453 the other existentially quantified variables are removed.
456 Consider the relation
459 n \to \{\, x \to y \mid \exists \, \alpha_0, \alpha_1: 7\alpha_0 = -2 + n \wedge 5\alpha_1 = -1 - x + y \wedge y \ge 6 + x \,\}
462 The difference set of this relation is
464 \Delta = \Delta \, R =
465 n \to \{\, x \mid \exists \, \alpha_0, \alpha_1: 7\alpha_0 = -2 + n \wedge 5\alpha_1 = -1 + x \wedge x \ge 6 \,\}
468 The existentially quantified variables can be defined in terms
469 of the parameters and variables as
471 \alpha_0 = \floor{\frac{-2 + n}7}
475 \alpha_1 = \floor{\frac{-1 + x}5}
478 $\alpha_0$ can therefore be treated as a parameter,
479 while $\alpha_1$ can be treated as a variable.
480 This in turn means that $7\alpha_0 = -2 + n$ can be treated as
481 a purely parametric constraint, while the other two constraints are
483 The corresponding $Q$~\eqref{eq:transitive:Q} is therefore
486 n \to \{\, (x,z) \to (y,w) \mid
487 \exists\, \alpha_0, \alpha_1, k, f : {} &
490 w = z + k \wedge {} \\
492 7\alpha_0 = -2 + n \wedge
493 5\alpha_1 = -k + x \wedge
499 Projecting out the final coordinates encoding the length of the paths,
500 results in the exact transitive closure
503 n \to \{\, x \to y \mid \exists \, \alpha_0, \alpha_1: 7\alpha_1 = -2 + n \wedge 6\alpha_0 \ge -x + y \wedge 5\alpha_0 \le -1 - x + y \,\}
508 \subsection{Checking Exactness}
510 The approximation $T$ for the transitive closure $R^+$ can be obtained
511 by projecting out the parameter $k$ from the approximation $K$
512 \eqref{eq:transitive:approx} of the power $R^k$.
513 Since $K$ is an overapproximation of $R^k$, $T$ will also be an
514 overapproximation of $R^+$.
515 To check whether the results are exact, we need to consider two
516 cases depending on whether $R$ is {\em cyclic}, where $R$ is defined
517 to be cyclic if $R^+$ maps any element to itself, i.e.,
518 $R^+ \cap \identity \ne \emptyset$.
519 If $R$ is acyclic, then the inductive definition of
520 \eqref{eq:transitive:inductive} is equivalent to its completion,
523 R^+ = R \cup \left(R \circ R^+\right)
525 is a defining property.
526 Since $T$ is known to be an overapproximation, we only need to check
529 T \subseteq R \cup \left(R \circ T\right)
532 This is essentially Theorem~5 of \shortciteN{Kelly1996closure}.
533 The only difference is that they only consider lexicographically
534 forward relations, a special case of acyclic relations.
536 If, on the other hand, $R$ is cyclic, then we have to resort
537 to checking whether the approximation $K$ of the power is exact.
538 Note that $T$ may be exact even if $K$ is not exact, so the check
539 is sound, but incomplete.
540 To check exactness of the power, we simply need to check
541 \eqref{eq:transitive:power}. Since again $K$ is known
542 to be an overapproximation, we only need to check whether
545 K'|_{y_{d+1} - x_{d+1} = 1} & \subseteq R'
547 K'|_{y_{d+1} - x_{d+1} \ge 2} & \subseteq R' \circ K'|_{y_{d+1} - x_{d+1} \ge 1}
551 where $R' = \{\, \vec x' \to \vec y' \mid \vec x \to \vec y \in R
552 \wedge y_{d+1} - x_{d+1} = 1\,\}$, i.e., $R$ extended with path
555 All that remains is to explain how to check the cyclicity of $R$.
556 Note that the exactness on the power is always sound, even
557 in the acyclic case, so we only need to be careful that we find
558 all cyclic cases. Now, if $R$ is cyclic, i.e.,
559 $R^+ \cap \identity \ne \emptyset$, then, since $T$ is
560 an overapproximation of $R^+$, also
561 $T \cap \identity \ne \emptyset$. This in turn means
562 that $\Delta \, K'$ contains a point whose first $d$ coordinates
563 are zero and whose final coordinate is positive.
564 In the implementation we currently perform this test on $P'$ instead of $K'$.
565 Note that if $R^+$ is acyclic and $T$ is not, then the approximation
566 is clearly not exact and the approximation of the power $K$
567 will not be exact either.
569 \subsection{Decomposing $R$ into strongly connected components}
571 If the input relation $R$ is a union of several basic relations
572 that can be partially ordered
573 then the accuracy of the approximation may be improved by computing
574 an approximation of each strongly connected components separately.
575 For example, if $R = R_1 \cup R_2$ and $R_1 \circ R_2 = \emptyset$,
576 then we know that any path that passes through $R_2$ cannot later
577 pass through $R_1$, i.e.,
579 R^+ = R_1^+ \cup R_2^+ \cup \left(R_2^+ \circ R_1^+\right)
582 We can therefore compute (approximations of) transitive closures
583 of $R_1$ and $R_2$ separately.
584 Note, however, that the condition $R_1 \circ R_2 = \emptyset$
585 is actually too strong.
586 If $R_1 \circ R_2$ is a subset of $R_2 \circ R_1$
587 then we can reorder the segments
588 in any path that moves through both $R_1$ and $R_2$ to
589 first move through $R_1$ and then through $R_2$.
591 This idea can be generalized to relations that are unions
592 of more than two basic relations by constructing the
593 strongly connected components in the graph with as vertices
594 the basic relations and an edge between two basic relations
595 $R_i$ and $R_j$ if $R_i$ needs to follow $R_j$ in some paths.
596 That is, there is an edge from $R_i$ to $R_j$ iff
598 \label{eq:transitive:edge}
604 The components can be obtained from the graph by applying
605 Tarjan's algorithm \shortcite{Tarjan1972}.
607 In practice, we compute the (extended) powers $K_i'$ of each component
608 separately and then compose them as in \eqref{eq:transitive:decompose}.
609 Note, however, that in this case the order in which we apply them is
610 important and should correspond to a topological ordering of the
611 strongly connected components. Simply applying Tarjan's
612 algorithm will produce topologically sorted strongly connected components.
613 The graph on which Tarjan's algorithm is applied is constructed on-the-fly.
614 That is, whenever the algorithm checks if there is an edge between
615 two vertices, we evaluate \eqref{eq:transitive:edge}.
616 The exactness check is performed on each component separately.
617 If the approximation turns out to be inexact for any of the components,
618 then the entire result is marked inexact and the exactness check
619 is skipped on the components that still need to be handled.
623 \begin{tikzpicture}[x=0.5cm,y=0.5cm,>=stealth,shorten >=1pt]
624 \foreach \x in {1,...,10}{
625 \foreach \y in {1,...,10}{
626 \draw[->] (\x,\y) -- (\x,\y+1);
629 \foreach \x in {1,...,20}{
630 \foreach \y in {5,...,15}{
631 \draw[->] (\x,\y) -- (\x+1,\y);
636 \caption{The relation from \autoref{ex:closure4}}
641 Consider the relation in example {\tt closure4} that comes with
642 the Omega calculator~\shortcite{Omega_calc}, $R = R_1 \cup R_2$,
646 R_1 & = \{\, (x,y) \to (x,y+1) \mid 1 \le x,y \le 10 \,\}
648 R_2 & = \{\, (x,y) \to (x+1,y) \mid 1 \le x \le 20 \wedge 5 \le y \le 15 \,\}
652 This relation is shown graphically in \autoref{f:closure4}.
657 \{\, (x,y) \to (x+1,y+1) \mid 1 \le x \le 9 \wedge 5 \le y \le 10 \,\}
660 \{\, (x,y) \to (x+1,y+1) \mid 1 \le x \le 10 \wedge 4 \le y \le 10 \,\}
664 Clearly, $R_1 \circ R_2 \subseteq R_2 \circ R_1$ and so
670 \left(R_2^+ \circ R_1^+\right)
684 \begin{tikzpicture}[>=stealth,shorten >=1pt]
686 \foreach \i in {1,...,\value{n}}{
687 \foreach \j in {1,...,\value{n}}{
688 \setcounter{t1}{2 * \j - 4 - \i + 1}
689 \setcounter{t2}{\value{n} - 3 - \i + 1}
690 \setcounter{t3}{2 * \i - 1 - \j + 1}
691 \setcounter{t4}{\value{n} - \j + 1}
692 \ifnum\value{t1}>0\ifnum\value{t2}>0
693 \ifnum\value{t3}>0\ifnum\value{t4}>0
694 \draw[thick,->] (\i,\j) to[out=20] (\i+3,\j);
696 \setcounter{t1}{2 * \j - 1 - \i + 1}
697 \setcounter{t2}{\value{n} - \i + 1}
698 \setcounter{t3}{2 * \i - 4 - \j + 1}
699 \setcounter{t4}{\value{n} - 3 - \j + 1}
700 \ifnum\value{t1}>0\ifnum\value{t2}>0
701 \ifnum\value{t3}>0\ifnum\value{t4}>0
702 \draw[thick,->] (\i,\j) to[in=-20,out=20] (\i,\j+3);
704 \setcounter{t1}{2 * \j - 1 - \i + 1}
705 \setcounter{t2}{\value{n} - 1 - \i + 1}
706 \setcounter{t3}{2 * \i - 1 - \j + 1}
707 \setcounter{t4}{\value{n} - 1 - \j + 1}
708 \ifnum\value{t1}>0\ifnum\value{t2}>0
709 \ifnum\value{t3}>0\ifnum\value{t4}>0
710 \draw[thick,->] (\i,\j) to (\i+1,\j+1);
716 \caption{The relation from \autoref{ex:decomposition}}
717 \label{f:decomposition}
720 \label{ex:decomposition}
721 Consider the relation on the right of \shortciteN[Figure~2]{Beletska2009},
722 reproduced in \autoref{f:decomposition}.
723 The relation can be described as $R = R_1 \cup R_2 \cup R_3$,
727 R_1 &= n \mapsto \{\, (i,j) \to (i+3,j) \mid
733 R_2 &= n \mapsto \{\, (i,j) \to (i,j+3) \mid
739 R_3 &= n \mapsto \{\, (i,j) \to (i+1,j+1) \mid
747 The figure shows this relation for $n = 7$.
749 $R_3 \circ R_1 \subseteq R_1 \circ R_3$
751 $R_3 \circ R_2 \subseteq R_2 \circ R_3$,
752 which the reader can verify using the {\tt iscc} calculator:
754 R1 := [n] -> { [i,j] -> [i+3,j] : i <= 2 j - 4 and i <= n - 3 and
755 j <= 2 i - 1 and j <= n };
756 R2 := [n] -> { [i,j] -> [i,j+3] : i <= 2 j - 1 and i <= n and
757 j <= 2 i - 4 and j <= n - 3 };
758 R3 := [n] -> { [i,j] -> [i+1,j+1] : i <= 2 j - 1 and i <= n - 1 and
759 j <= 2 i - 1 and j <= n - 1 };
760 (R1 . R3) - (R3 . R1);
761 (R2 . R3) - (R3 . R2);
763 $R_3$ can therefore be moved forward in any path.
764 For the other two basic relations, we have both
765 $R_2 \circ R_1 \not\subseteq R_1 \circ R_2$
767 $R_1 \circ R_2 \not\subseteq R_2 \circ R_1$
768 and so $R_1$ and $R_2$ form a strongly connected component.
769 By computing the power of $R_3$ and $R_1 \cup R_2$ separately
770 and composing the results, the power of $R$ can be computed exactly
771 using \eqref{eq:transitive:singleton}.
772 As explained by \shortciteN{Beletska2009}, applying the same formula
773 to $R$ directly, without a decomposition, would result in
774 an overapproximation of the power.
777 \subsection{Partitioning the domains and ranges of $R$}
779 The algorithm of \autoref{s:power} assumes that the input relation $R$
780 can be treated as a union of translations.
781 This is a reasonable assumption if $R$ maps elements of a given
782 abstract domain to the same domain.
783 However, if $R$ is a union of relations that map between different
784 domains, then this assumption no longer holds.
785 In particular, when an entire dependence graph is encoded
786 in a single relation, as is done by, e.g.,
787 \shortciteN[Section~6.1]{Barthou2000MSE}, then it does not make
788 sense to look at differences between iterations of different domains.
789 Now, arguably, a modified Floyd-Warshall algorithm should
790 be applied to the dependence graph, as advocated by
791 \shortciteN{Kelly1996closure}, with the transitive closure operation
792 only being applied to relations from a given domain to itself.
793 However, it is also possible to detect disjoint domains and ranges
794 and to apply Floyd-Warshall internally.
798 \caption{The modified Floyd-Warshall algorithm of
799 \protect\shortciteN{Kelly1996closure}}
801 \SetKwInput{Input}{Input}
802 \SetKwInput{Output}{Output}
803 \Input{Relations $R_{pq}$, $0 \le p, q < n$}
804 \Output{Updated relations $R_{pq}$ such that each relation
805 $R_{pq}$ contains all indirect paths from $p$ to $q$ in the input graph}
811 \For{$r \in [0, n-1]$}{
812 $R_{rr} \coloneqq R_{rr}^+$ \nllabel{l:Floyd:closure}\;
813 \For{$p \in [0, n-1]$}{
814 \For{$q \in [0, n-1]$}{
815 \If{$p \ne r$ or $q \ne r$}{
816 $R_{pq} \coloneqq R_{pq} \cup \left(R_{rq} \circ R_{pr}\right)
817 \cup \left(R_{rq} \circ R_{rr} \circ R_{pr}\right)$
818 \nllabel{l:Floyd:update}
825 Let the input relation $R$ be a union of $m$ basic relations $R_i$.
826 Let $D_{2i}$ be the domains of $R_i$ and $D_{2i+1}$ the ranges of $R_i$.
827 The first step is to group overlapping $D_j$ until a partition is
828 obtained. If the resulting partition consists of a single part,
829 then we continue with the algorithm of \autoref{s:power}.
830 Otherwise, we apply Floyd-Warshall on the graph with as vertices
831 the parts of the partition and as edges the $R_i$ attached to
832 the appropriate pairs of vertices.
833 In particular, let there be $n$ parts $P_k$ in the partition.
834 We construct $n^2$ relations
836 R_{pq} \coloneqq \bigcup_{i \text{ s.t. } \domain R_i \subseteq P_p \wedge
837 \range R_i \subseteq P_q} R_i
840 apply \autoref{a:Floyd} and return the union of all resulting
841 $R_{pq}$ as the transitive closure of $R$.
842 Each iteration of the $r$-loop in \autoref{a:Floyd} updates
843 all relations $R_{pq}$ to include paths that go from $p$ to $r$,
844 possibly stay there for a while, and then go from $r$ to $q$.
845 Note that paths that ``stay in $r$'' include all paths that
846 pass through earlier vertices since $R_{rr}$ itself has been updated
847 accordingly in previous iterations of the outer loop.
848 In principle, it would be sufficient to use the $R_{pr}$
849 and $R_{rq}$ computed in the previous iteration of the
850 $r$-loop in Line~\ref{l:Floyd:update}.
851 However, from an implementation perspective, it is easier
852 to allow either or both of these to have been updated
853 in the same iteration of the $r$-loop.
854 This may result in duplicate paths, but these can usually
855 be removed by coalescing (\autoref{s:coalescing}) the result of the union
856 in Line~\ref{l:Floyd:update}, which should be done in any case.
857 The transitive closure in Line~\ref{l:Floyd:closure}
858 is performed using a recursive call. This recursive call
859 includes the partitioning step, but the resulting partition will
860 usually be a singleton.
861 The result of the recursive call will either be exact or an
862 overapproximation. The final result of Floyd-Warshall is therefore
863 also exact or an overapproximation.
867 \begin{tikzpicture}[x=1cm,y=1cm,>=stealth,shorten >=3pt]
868 \foreach \x/\y in {0/0,1/1,3/2} {
869 \fill (\x,\y) circle (2pt);
871 \foreach \x/\y in {0/1,2/2,3/3} {
872 \draw (\x,\y) circle (2pt);
874 \draw[->] (0,0) -- (0,1);
875 \draw[->] (0,1) -- (1,1);
876 \draw[->] (2,2) -- (3,2);
877 \draw[->] (3,2) -- (3,3);
878 \draw[->,dashed] (2,2) -- (3,3);
879 \draw[->,dotted] (0,0) -- (1,1);
882 \caption{The relation (solid arrows) on the right of Figure~1 of
883 \protect\shortciteN{Beletska2009} and its transitive closure}
887 Consider the relation on the right of Figure~1 of
888 \shortciteN{Beletska2009},
889 reproduced in \autoref{f:COCOA:1}.
890 This relation can be described as
893 \{\, (x, y) \to (x_2, y_2) \mid {} & (3y = 2x \wedge x_2 = x \wedge 3y_2 = 3 + 2x \wedge x \ge 0 \wedge x \le 3) \vee {} \\
894 & (x_2 = 1 + x \wedge y_2 = y \wedge x \ge 0 \wedge 3y \ge 2 + 2x \wedge x \le 2 \wedge 3y \le 3 + 2x) \,\}
898 Note that the domain of the upward relation overlaps with the range
899 of the rightward relation and vice versa, but that the domain
900 of neither relation overlaps with its own range or the domain of
902 The domains and ranges can therefore be partitioned into two parts,
903 $P_0$ and $P_1$, shown as the white and black dots in \autoref{f:COCOA:1},
911 \{\, (x, y) \to (x+1, y) \mid
912 (x \ge 0 \wedge 3y \ge 2 + 2x \wedge x \le 2 \wedge 3y \le 3 + 2x) \,\}
915 \{\, (x, y) \to (x_2, y_2) \mid (3y = 2x \wedge x_2 = x \wedge 3y_2 = 3 + 2x \wedge x \ge 0 \wedge x \le 3) \,\}
921 In the first iteration, $R_{00}$ remains the same ($\emptyset^+ = \emptyset$).
922 $R_{01}$ and $R_{10}$ are therefore also unaffected, but
923 $R_{11}$ is updated to include $R_{01} \circ R_{10}$, i.e.,
924 the dashed arrow in the figure.
925 This new $R_{11}$ is obviously transitively closed, so it is not
926 changed in the second iteration and it does not have an effect
927 on $R_{01}$ and $R_{10}$. However, $R_{00}$ is updated to
928 include $R_{10} \circ R_{01}$, i.e., the dotted arrow in the figure.
929 The transitive closure of the original relation is then equal to
930 $R_{00} \cup R_{01} \cup R_{10} \cup R_{11}$.
933 \subsection{An {\tt Omega}-like implementation}
935 While the main algorithm of \shortciteN{Kelly1996closure} is
936 designed to compute and underapproximation of the transitive closure,
937 the authors mention that they could also compute overapproximations.
938 In this section, we describe our implementation of an algorithm
939 that is based on their ideas.
940 Note that the {\tt Omega} library computes underapproximations
941 \shortcite[Section 6.4]{Omega_lib}.
943 The main tool is Equation~(2) of \shortciteN{Kelly1996closure}.
944 The input relation $R$ is first overapproximated by a ``d-form'' relation
946 \{\, \vec i \to \vec j \mid \exists \vec \alpha :
947 \vec L \le \vec j - \vec i \le \vec U
949 (\forall p : j_p - i_p = M_p \alpha_p)
953 where $p$ ranges over the dimensions and $\vec L$, $\vec U$ and
954 $\vec M$ are constant integer vectors. The elements of $\vec U$
955 may be $\infty$, meaning that there is no upper bound corresponding
956 to that element, and similarly for $\vec L$.
957 Such an overapproximation can be obtained by computing strides,
958 lower and upper bounds on the difference set $\Delta \, R$.
959 The transitive closure of such a ``d-form'' relation is
962 \{\, \vec i \to \vec j \mid \exists \vec \alpha, k :
964 k \, \vec L \le \vec j - \vec i \le k \, \vec U
966 (\forall p : j_p - i_p = M_p \alpha_p)
970 The domain and range of this transitive closure are then
971 intersected with those of the input relation.
972 This is a special case of the algorithm in \autoref{s:power}.
974 In their algorithm for computing lower bounds, the authors
975 use the above algorithm as a substep on the disjuncts in the relation.
978 If an upper bound is required, it can be calculated in a manner
979 similar to that of a single conjunct [sic] relation.
981 Presumably, the authors mean that a ``d-form'' approximation
982 of the whole input relation should be used.
983 However, the accuracy can be improved by also using the following
984 idea from the same paper. If $R$ is a union of $m$ basic maps,
989 and if we can find an $R_i$ such that for all other $R_j$ we have
992 R_i^* \circ R_j \circ R_i^*
994 can be represented as a single basic map, i.e., without a union,
995 then we can compute $R^+$ as
1000 R_i^* \circ R_j \circ R_i^*
1004 reducing the number of disjuncts in the argument of the transitive
1006 An overapproximation of $R_i^*$ can be obtained by
1007 allowing the value zero for $k$ in \eqref{eq:omega},
1010 \{\, \vec i \to \vec j \mid \exists \vec \alpha, k :
1012 k \, \vec L \le \vec j - \vec i \le k \, \vec U
1014 (\forall p : j_p - i_p = M_p \alpha_p)
1018 However, when we intersect domain and range of this relation
1019 with those of the input relation, then the result only contains
1020 the identity mapping on the intersection of domain and range.
1021 \shortciteN{Kelly1996closure} propose to intersect domain
1022 and range with then {\em union} of domain and range of the input
1023 relation instead and call the result $R_i^?$.
1024 Now, this union of domain and range of $R_i$ may not contain
1025 the domains and ranges of the whole of $R$.
1026 We can therefore not always replace
1027 $R_i^* \circ R_j \circ R_i^*$ by
1028 $R_i^? \circ R_j \circ R_i^?$.
1029 \shortciteN{Kelly1996closure} propose to check the following
1030 conditions to decide whether this replacement is justified:
1031 $R_i^? - R_i^+$ is not a union and for each $j \ne i$
1034 \left(R_i^? - R_i^+\right)
1038 \left(R_i^? - R_i^+\right)