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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
6 constraints
7 $$
8 S_i : \Z^n \to 2^{\Z^d} : \vec s \mapsto
9 S_i(\vec s) =
10 \{\, \vec x \in \Z^d \mid \exists \vec z \in \Z^e :
11 A \vec x + B \vec s + D \vec z + \vec c \geq \vec 0 \,\}
14 with $A \in \Z^{m \times d}$,
15 $B \in \Z^{m \times n}$,
16 $D \in \Z^{m \times e}$
17 and $\vec c \in \Z^m$.
18 \end{definition}
20 \begin{definition}[Parameter Domain of a Set]
21 Let $S \in \Z^n \to 2^{\Z^d}$ be a set.
22 The {\em parameter domain} of $S$ is the set
23 $$\pdom S \coloneqq \{\, \vec s \in \Z^n \mid S(\vec s) \ne \emptyset \,\}.$$
24 \end{definition}
26 \begin{definition}[Polyhedral Relation]
27 A {\em polyhedral relation}\index{polyhedral relation}
28 $R$ is a finite union of basic relations
29 $R = \bigcup_i R_i$ of type
30 $\Z^n \to 2^{\Z^{d_1+d_2}}$,
31 each of which can be represented using affine
32 constraints
34 R_i = \vec s \mapsto
35 R_i(\vec s) =
36 \{\, \vec x_1 \to \vec x_2 \in \Z^{d_1} \times \Z^{d_2}
37 \mid \exists \vec z \in \Z^e :
38 A_1 \vec x_1 + A_2 \vec x_2 + B \vec s + D \vec z + \vec c \geq \vec 0 \,\}
41 with $A_i \in \Z^{m \times d_i}$,
42 $B \in \Z^{m \times n}$,
43 $D \in \Z^{m \times e}$
44 and $\vec c \in \Z^m$.
45 \end{definition}
47 \begin{definition}[Parameter Domain of a Relation]
48 Let $R \in \Z^n \to 2^{\Z^{d+d}}$ be a relation.
49 The {\em parameter domain} of $R$ is the set
50 $$\pdom R \coloneqq \{\, \vec s \in \Z^n \mid R(\vec s) \ne \emptyset \,\}.$$
51 \end{definition}
53 \begin{definition}[Domain of a Relation]
54 Let $R \in \Z^n \to 2^{\Z^{d+d}}$ be a relation.
55 The {\em domain} of $R$ is the polyhedral set
56 $$\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) \,\}
61 \end{definition}
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) \,\}
72 \end{definition}
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
80 S \circ R \coloneqq
81 \vec s \mapsto
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)
86 \,\}
89 \end{definition}
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
95 domain elements,
97 \diff R \coloneqq
98 \vec s \mapsto
99 \{\, \vec \delta \in \Z^{d} \mid \exists \vec x \to \vec y \in R :
100 \vec \delta = \vec y - \vec x
101 \,\}
103 \end{definition}
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
131 S(\vec s) =
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\}
136 is the set
138 H : \Z^n \to 2^{\Z^d} : \vec s \mapsto
139 S(\vec s) =
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
143 \,\right\}
146 with $\vec K_i$ the (component-wise) smallest non-negative integer vectors
147 such that $S \subseteq H$.
148 \end{definition}
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
152 is dropped.
154 \section{Parametric Integer Programming}
156 \subsection{Introduction}\label{s:intro}
158 Parametric integer programming \parencite{Feautrier88parametric}
159 is used to solve many problems within the context of the polyhedral model.
160 Here, we are mainly interested in dependence analysis \parencite{Fea91}
161 and in computing a unique representation for existentially quantified
162 variables. The latter operation has been used for counting elements
163 in sets involving such variables
164 \parencite{BouletRe98,Verdoolaege2005experiences} and lies at the core
165 of the internal representation of {\tt isl}.
167 Parametric integer programming was first implemented in \texttt{PipLib}.
168 An alternative method for parametric integer programming
169 was later implemented in {\tt barvinok} \cite{barvinok-0.22}.
170 This method is not based on Feautrier's algorithm, but on rational
171 generating functions \cite{Woods2003short} and was inspired by the
172 ``digging'' technique of \textcite{DeLoera2004Three} for solving
173 non-parametric integer programming problems.
175 In the following sections, we briefly recall the dual simplex
176 method combined with Gomory cuts and describe some extensions
177 and optimizations. The main algorithm is applied to a matrix
178 data structure known as a tableau. In case of parametric problems,
179 there are two tableaus, one for the main problem and one for
180 the constraints on the parameters, known as the context tableau.
181 The handling of the context tableau is described in \autoref{s:context}.
183 \subsection{The Dual Simplex Method}
185 Tableaus can be represented in several slightly different ways.
186 In {\tt isl}, the dual simplex method uses the same representation
187 as that used by its incremental LP solver based on the \emph{primal}
188 simplex method. The implementation of this LP solver is based
189 on that of {\tt Simplify} \parencite{Detlefs2005simplify}, which, in turn,
190 was derived from the work of \textcite{Nelson1980phd}.
191 In the original \parencite{Nelson1980phd}, the tableau was implemented
192 as a sparse matrix, but neither {\tt Simplify} nor the current
193 implementation of {\tt isl} does so.
195 Given some affine constraints on the variables,
196 $A \vec x + \vec b \ge \vec 0$, the tableau represents the relationship
197 between the variables $\vec x$ and non-negative variables
198 $\vec y = A \vec x + \vec b$ corresponding to the constraints.
199 The initial tableau contains $\begin{pmatrix}
200 \vec b & A
201 \end{pmatrix}$ and expresses the constraints $\vec y$ in the rows in terms
202 of the variables $\vec x$ in the columns. The main operation defined
203 on a tableau exchanges a column and a row variable and is called a pivot.
204 During this process, some coefficients may become rational.
205 As in the \texttt{PipLib} implementation,
206 {\tt isl} maintains a shared denominator per row.
207 The sample value of a tableau is one where each column variable is assigned
208 zero and each row variable is assigned the constant term of the row.
209 This sample value represents a valid solution if each constraint variable
210 is assigned a non-negative value, i.e., if the constant terms of
211 rows corresponding to constraints are all non-negative.
213 The dual simplex method starts from an initial sample value that
214 may be invalid, but that is known to be (lexicographically) no
215 greater than any solution, and gradually increments this sample value
216 through pivoting until a valid solution is obtained.
217 In particular, each pivot exchanges a row variable
218 $r = -n + \sum_i a_i \, c_i$ with negative
219 sample value $-n$ with a column variable $c_j$
220 such that $a_j > 0$. Since $c_j = (n + r - \sum_{i\ne j} a_i \, c_i)/a_j$,
221 the new row variable will have a positive sample value $n$.
222 If no such column can be found, then the problem is infeasible.
223 By always choosing the column that leads to the (lexicographically)
224 smallest increment in the variables $\vec x$,
225 the first solution found is guaranteed to be the (lexicographically)
226 minimal solution \cite{Feautrier88parametric}.
227 In order to be able to determine the smallest increment, the tableau
228 is (implicitly) extended with extra rows defining the original
229 variables in terms of the column variables.
230 If we assume that all variables are non-negative, then we know
231 that the zero vector is no greater than the minimal solution and
232 then the initial extended tableau looks as follows.
234 \begin{tikzpicture}
235 \matrix (m) [matrix of math nodes]
237 & {} & 1 & \vec c \\
238 \vec x && |(top)| \vec 0 & I \\
239 \vec r && \vec b & |(bottom)|A \\
241 \begin{pgfonlayer}{background}
242 \node (core) [inner sep=0pt,fill=black!20,right delimiter=),left delimiter=(,fit=(top)(bottom)] {};
243 \end{pgfonlayer}
244 \end{tikzpicture}
246 Each column in this extended tableau is lexicographically positive
247 and will remain so because of the column choice explained above.
248 It is then clear that the value of $\vec x$ will increase in each step.
249 Note that there is no need to store the extra rows explicitly.
250 If a given $x_i$ is a column variable, then the corresponding row
251 is the unit vector $e_i$. If, on the other hand, it is a row variable,
252 then the row already appears somewhere else in the tableau.
254 In case of parametric problems, the sign of the constant term
255 may depend on the parameters. Each time the constant term of a constraint row
256 changes, we therefore need to check whether the new term can attain
257 negative and/or positive values over the current set of possible
258 parameter values, i.e., the context.
259 If all these terms can only attain non-negative values, the current
260 state of the tableau represents a solution. If one of the terms
261 can only attain non-positive values and is not identically zero,
262 the corresponding row can be pivoted.
263 Otherwise, we pick one of the terms that can attain both positive
264 and negative values and split the context into a part where
265 it only attains non-negative values and a part where it only attains
266 negative values.
268 \subsection{Gomory Cuts}
270 The solution found by the dual simplex method may have
271 non-integral coordinates. If so, some rational solutions
272 (including the current sample value), can be cut off by
273 applying a (parametric) Gomory cut.
274 Let $r = b(\vec p) + \sp {\vec a} {\vec c}$ be the row
275 corresponding to the first non-integral coordinate of $\vec x$,
276 with $b(\vec p)$ the constant term, an affine expression in the
277 parameters $\vec p$, i.e., $b(\vec p) = \sp {\vec f} {\vec p} + g$.
278 Note that only row variables can attain
279 non-integral values as the sample value of the column variables is zero.
280 Consider the expression
281 $b(\vec p) - \ceil{b(\vec p)} + \sp {\fract{\vec a}} {\vec c}$,
282 with $\ceil\cdot$ the ceiling function and $\fract\cdot$ the
283 fractional part. This expression is negative at the sample value
284 since $\vec c = \vec 0$ and $r = b(\vec p)$ is fractional, i.e.,
285 $\ceil{b(\vec p)} > b(\vec p)$. On the other hand, for each integral
286 value of $r$ and $\vec c \ge 0$, the expression is non-negative
287 because $b(\vec p) - \ceil{b(\vec p)} > -1$.
288 Imposing this expression to be non-negative therefore does not
289 invalidate any integral solutions, while it does cut away the current
290 fractional sample value. To be able to formulate this constraint,
291 a new variable $q = \floor{-b(\vec p)} = - \ceil{b(\vec p)}$ is added
292 to the context. This integral variable is uniquely defined by the constraints
293 $0 \le -d \, b(\vec p) - d \, q \le d - 1$, with $d$ the common
294 denominator of $\vec f$ and $g$. In practice, the variable
295 $q' = \floor{\sp {\fract{-f}} {\vec p} + \fract{-g}}$ is used instead
296 and the coefficients of the new constraint are adjusted accordingly.
297 The sign of the constant term of this new constraint need not be determined
298 as it is non-positive by construction.
299 When several of these extra context variables are added, it is important
300 to avoid adding duplicates.
301 Recent versions of {\tt PipLib} also check for such duplicates.
303 \subsection{Negative Unknowns and Maximization}
305 There are two places in the above algorithm where the unknowns $\vec x$
306 are assumed to be non-negative: the initial tableau starts from
307 sample value $\vec x = \vec 0$ and $\vec c$ is assumed to be non-negative
308 during the construction of Gomory cuts.
309 To deal with negative unknowns, \textcite[Appendix A.2]{Fea91}
310 proposed to use a ``big parameter'', say $M$, that is taken to be
311 an arbitrarily large positive number. Instead of looking for the
312 lexicographically minimal value of $\vec x$, we search instead
313 for the lexicographically minimal value of $\vec x' = \vec M + \vec x$.
314 The sample value $\vec x' = \vec 0$ of the initial tableau then
315 corresponds to $\vec x = -\vec M$, which is clearly not greater than
316 any potential solution. The sign of the constant term of a row
317 is determined lexicographically, with the coefficient of $M$ considered
318 first. That is, if the coefficient of $M$ is not zero, then its sign
319 is the sign of the entire term. Otherwise, the sign is determined
320 by the remaining affine expression in the parameters.
321 If the original problem has a bounded optimum, then the final sample
322 value will be of the form $\vec M + \vec v$ and the optimal value
323 of the original problem is then $\vec v$.
324 Maximization problems can be handled in a similar way by computing
325 the minimum of $\vec M - \vec x$.
327 When the optimum is unbounded, the optimal value computed for
328 the original problem will involve the big parameter.
329 In the original implementation of {\tt PipLib}, the big parameter could
330 even appear in some of the extra variables $\vec q$ created during
331 the application of a Gomory cut. The final result could then contain
332 implicit conditions on the big parameter through conditions on such
333 $\vec q$ variables. This problem was resolved in later versions
334 of {\tt PipLib} by taking $M$ to be divisible by any positive number.
335 The big parameter can then never appear in any $\vec q$ because
336 $\fract {\alpha M } = 0$. It should be noted, though, that an unbounded
337 problem usually (but not always)
338 indicates an incorrect formulation of the problem.
340 The original version of {\tt PipLib} required the user to ``manually''
341 add a big parameter, perform the reformulation and interpret the result
342 \parencite{Feautrier02}. Recent versions allow the user to simply
343 specify that the unknowns may be negative or that the maximum should
344 be computed and then these transformations are performed internally.
345 Although there are some application, e.g.,
346 that of \textcite{Feautrier92multi},
347 where it is useful to have explicit control over the big parameter,
348 negative unknowns and maximization are by far the most common applications
349 of the big parameter and we believe that the user should not be bothered
350 with such implementation issues.
351 The current version of {\tt isl} therefore does not
352 provide any interface for specifying big parameters. Instead, the user
353 can specify whether a maximum needs to be computed and no assumptions
354 are made on the sign of the unknowns. Instead, the sign of the unknowns
355 is checked internally and a big parameter is automatically introduced when
356 needed. For compatibility with {\tt PipLib}, the {\tt isl\_pip} tool
357 does explicitly add non-negativity constraints on the unknowns unless
358 the \verb+Urs_unknowns+ option is specified.
359 Currently, there is also no way in {\tt isl} of expressing a big
360 parameter in the output. Even though
361 {\tt isl} makes the same divisibility assumption on the big parameter
362 as recent versions of {\tt PipLib}, it will therefore eventually
363 produce an error if the problem turns out to be unbounded.
365 \subsection{Preprocessing}
367 In this section, we describe some transformations that are
368 or can be applied in advance to reduce the running time
369 of the actual dual simplex method with Gomory cuts.
371 \subsubsection{Feasibility Check and Detection of Equalities}
373 Experience with the original {\tt PipLib} has shown that Gomory cuts
374 do not perform very well on problems that are (non-obviously) empty,
375 i.e., problems with rational solutions, but no integer solutions.
376 In {\tt isl}, we therefore first perform a feasibility check on
377 the original problem considered as a non-parametric problem
378 over the combined space of unknowns and parameters.
379 In fact, we do not simply check the feasibility, but we also
380 check for implicit equalities among the integer points by computing
381 the integer affine hull. The algorithm used is the same as that
382 described in \autoref{s:GBR} below.
383 Computing the affine hull is fairly expensive, but it can
384 bring huge benefits if any equalities can be found or if the problem
385 turns out to be empty.
387 \subsubsection{Constraint Simplification}
389 If the coefficients of the unknown and parameters in a constraint
390 have a common factor, then this factor should be removed, possibly
391 rounding down the constant term. For example, the constraint
392 $2 x - 5 \ge 0$ should be simplified to $x - 3 \ge 0$.
393 {\tt isl} performs such simplifications on all sets and relations.
394 Recent versions of {\tt PipLib} also perform this simplification
395 on the input.
397 \subsubsection{Exploiting Equalities}\label{s:equalities}
399 If there are any (explicit) equalities in the input description,
400 {\tt PipLib} converts each into a pair of inequalities.
401 It is also possible to write $r$ equalities as $r+1$ inequalities
402 \parencite{Feautrier02}, but it is even better to \emph{exploit} the
403 equalities to reduce the dimensionality of the problem.
404 Given an equality involving at least one unknown, we pivot
405 the row corresponding to the equality with the column corresponding
406 to the last unknown with non-zero coefficient. The new column variable
407 can then be removed completely because it is identically zero,
408 thereby reducing the dimensionality of the problem by one.
409 The last unknown is chosen to ensure that the columns of the initial
410 tableau remain lexicographically positive. In particular, if
411 the equality is of the form $b + \sum_{i \le j} a_i \, x_i = 0$ with
412 $a_j \ne 0$, then the (implicit) top rows of the initial tableau
413 are changed as follows
415 \begin{tikzpicture}
416 \matrix [matrix of math nodes]
418 & {} & |(top)| 0 & I_1 & |(j)| & \\
419 j && 0 & & 1 & \\
420 && 0 & & & |(bottom)|I_2 \\
422 \node[overlay,above=2mm of j,anchor=south]{j};
423 \begin{pgfonlayer}{background}
424 \node (m) [inner sep=0pt,fill=black!20,right delimiter=),left delimiter=(,fit=(top)(bottom)] {};
425 \end{pgfonlayer}
426 \begin{scope}[xshift=4cm]
427 \matrix [matrix of math nodes]
429 & {} & |(top)| 0 & I_1 & \\
430 j && |(left)| -b/a_j & -a_i/a_j & \\
431 && 0 & & |(bottom)|I_2 \\
433 \begin{pgfonlayer}{background}
434 \node (m2) [inner sep=0pt,fill=black!20,right delimiter=),left delimiter=(,fit=(top)(bottom)(left)] {};
435 \end{pgfonlayer}
436 \end{scope}
437 \draw [shorten >=7mm,-to,thick,decorate,
438 decoration={snake,amplitude=.4mm,segment length=2mm,
439 pre=moveto,pre length=5mm,post length=8mm}]
440 (m) -- (m2);
441 \end{tikzpicture}
443 Currently, {\tt isl} also eliminates equalities involving only parameters
444 in a similar way, provided at least one of the coefficients is equal to one.
445 The application of parameter compression (see below)
446 would obviate the need for removing parametric equalities.
448 \subsubsection{Offline Symmetry Detection}\label{s:offline}
450 Some problems, notably those of \textcite{Bygde2010licentiate},
451 have a collection of constraints, say
452 $b_i(\vec p) + \sp {\vec a} {\vec x} \ge 0$,
453 that only differ in their (parametric) constant terms.
454 These constant terms will be non-negative on different parts
455 of the context and this context may have to be split for each
456 of the constraints. In the worst case, the basic algorithm may
457 have to consider all possible orderings of the constant terms.
458 Instead, {\tt isl} introduces a new parameter, say $u$, and
459 replaces the collection of constraints by the single
460 constraint $u + \sp {\vec a} {\vec x} \ge 0$ along with
461 context constraints $u \le b_i(\vec p)$.
462 Any solution to the new system is also a solution
463 to the original system since
464 $\sp {\vec a} {\vec x} \ge -u \ge -b_i(\vec p)$.
465 Conversely, $m = \min_i b_i(\vec p)$ satisfies the constraints
466 on $u$ and therefore extends a solution to the new system.
467 It can also be plugged into a new solution.
468 See \autoref{s:post} for how this substitution is currently performed
469 in {\tt isl}.
470 The method described in this section can only detect symmetries
471 that are explicitly available in the input.
472 See \autoref{s:online} for the detection
473 and exploitation of symmetries that appear during the course of
474 the dual simplex method.
476 Note that the replacement of the $b_i(\vec p)$ by $u$ may lose
477 information if the parameters that occur in $b_i(\vec p)$ also
478 occur in other constraints. The replacement is therefore currently
479 only applied when all the parameters in all of the $b_i(\vec p)$
480 only occur in a single constraint, i.e., the one in which
481 the parameter is removed.
482 This is the case for the examples from \textcite{Bygde2010licentiate}
483 in \autoref{t:comparison}.
484 The version of {\tt isl} that was used during the experiments
485 of \autoref{s:pip:experiments} did not take into account
486 this single-occurrence constraint.
488 \subsubsection{Parameter Compression}\label{s:compression}
490 It may in some cases be apparent from the equalities in the problem
491 description that there can only be a solution for a sublattice
492 of the parameters. In such cases ``parameter compression''
493 \parencite{Meister2004PhD,Meister2008} can be used to replace
494 the parameters by alternative ``dense'' parameters.
495 For example, if there is a constraint $2x = n$, then the system
496 will only have solutions for even values of $n$ and $n$ can be replaced
497 by $2n'$. Similarly, the parameters $n$ and $m$ in a system with
498 the constraint $2n = 3m$ can be replaced by a single parameter $n'$
499 with $n=3n'$ and $m=2n'$.
500 It is also possible to perform a similar compression on the unknowns,
501 but it would be more complicated as the compression would have to
502 preserve the lexicographical order. Moreover, due to our handling
503 of equalities described above there should be
504 no need for such variable compression.
505 Although parameter compression has been implemented in {\tt isl},
506 it is currently not yet used during parametric integer programming.
508 \subsection{Postprocessing}\label{s:post}
510 The output of {\tt PipLib} is a quast (quasi-affine selection tree).
511 Each internal node in this tree corresponds to a split of the context
512 based on a parametric constant term in the main tableau with indeterminate
513 sign. Each of these nodes may introduce extra variables in the context
514 corresponding to integer divisions. Each leaf of the tree prescribes
515 the solution in that part of the context that satisfies all the conditions
516 on the path leading to the leaf.
517 Such a quast is a very economical way of representing the solution, but
518 it would not be suitable as the (only) internal representation of
519 sets and relations in {\tt isl}. Instead, {\tt isl} represents
520 the constraints of a set or relation in disjunctive normal form.
521 The result of a parametric integer programming problem is then also
522 converted to this internal representation. Unfortunately, the conversion
523 to disjunctive normal form can lead to an explosion of the size
524 of the representation.
525 In some cases, this overhead would have to be paid anyway in subsequent
526 operations, but in other cases, especially for outside users that just
527 want to solve parametric integer programming problems, we would like
528 to avoid this overhead in future. That is, we are planning on introducing
529 quasts or a related representation as one of several possible internal
530 representations and on allowing the output of {\tt isl\_pip} to optionally
531 be printed as a quast.
533 Currently, {\tt isl} also does not have an internal representation
534 for expressions such as $\min_i b_i(\vec p)$ from the offline
535 symmetry detection of \autoref{s:offline}.
536 Assume that one of these expressions has $n$ bounds $b_i(\vec p)$.
537 If the expression
538 does not appear in the affine expression describing the solution,
539 but only in the constraints, and if moreover, the expression
540 only appears with a positive coefficient, i.e.,
541 $\min_i b_i(\vec p) \ge f_j(\vec p)$, then each of these constraints
542 can simply be reduplicated $n$ times, once for each of the bounds.
543 Otherwise, a conversion to disjunctive normal form
544 leads to $n$ cases, each described as $u = b_i(\vec p)$ with constraints
545 $b_i(\vec p) \le b_j(\vec p)$ for $j > i$
547 $b_i(\vec p) < b_j(\vec p)$ for $j < i$.
548 Note that even though this conversion leads to a size increase
549 by a factor of $n$, not detecting the symmetry could lead to
550 an increase by a factor of $n!$ if all possible orderings end up being
551 considered.
553 \subsection{Context Tableau}\label{s:context}
555 The main operation that a context tableau needs to provide is a test
556 on the sign of an affine expression over the elements of the context.
557 This sign can be determined by solving two integer linear feasibility
558 problems, one with a constraint added to the context that enforces
559 the expression to be non-negative and one where the expression is
560 negative. As already mentioned by \textcite{Feautrier88parametric},
561 any integer linear feasibility solver could be used, but the {\tt PipLib}
562 implementation uses a recursive call to the dual simplex with Gomory
563 cuts algorithm to determine the feasibility of a context.
564 In {\tt isl}, two ways of handling the context have been implemented,
565 one that performs the recursive call and one, used by default, that
566 uses generalized basis reduction.
567 We start with some optimizations that are shared between the two
568 implementations and then discuss additional details of each of them.
570 \subsubsection{Maintaining Witnesses}\label{s:witness}
572 A common feature of both integer linear feasibility solvers is that
573 they will not only say whether a set is empty or not, but if the set
574 is non-empty, they will also provide a \emph{witness} for this result,
575 i.e., a point that belongs to the set. By maintaining a list of such
576 witnesses, we can avoid many feasibility tests during the determination
577 of the signs of affine expressions. In particular, if the expression
578 evaluates to a positive number on some of these points and to a negative
579 number on some others, then no feasibility test needs to be performed.
580 If all the evaluations are non-negative, we only need to check for the
581 possibility of a negative value and similarly in case of all
582 non-positive evaluations. Finally, in the rare case that all points
583 evaluate to zero or at the start, when no points have been collected yet,
584 one or two feasibility tests need to be performed depending on the result
585 of the first test.
587 When a new constraint is added to the context, the points that
588 violate the constraint are temporarily removed. They are reconsidered
589 when we backtrack over the addition of the constraint, as they will
590 satisfy the negation of the constraint. It is only when we backtrack
591 over the addition of the points that they are finally removed completely.
592 When an extra integer division is added to the context,
593 the new coordinates of the
594 witnesses can easily be computed by evaluating the integer division.
595 The idea of keeping track of witnesses was first used in {\tt barvinok}.
597 \subsubsection{Choice of Constant Term on which to Split}
599 Recall that if there are no rows with a non-positive constant term,
600 but there are rows with an indeterminate sign, then the context
601 needs to be split along the constant term of one of these rows.
602 If there is more than one such row, then we need to choose which row
603 to split on first. {\tt PipLib} uses a heuristic based on the (absolute)
604 sizes of the coefficients. In particular, it takes the largest coefficient
605 of each row and then selects the row where this largest coefficient is smaller
606 than those of the other rows.
608 In {\tt isl}, we take that row for which non-negativity of its constant
609 term implies non-negativity of as many of the constant terms of the other
610 rows as possible. The intuition behind this heuristic is that on the
611 positive side, we will have fewer negative and indeterminate signs,
612 while on the negative side, we need to perform a pivot, which may
613 affect any number of rows meaning that the effect on the signs
614 is difficult to predict. This heuristic is of course much more
615 expensive to evaluate than the heuristic used by {\tt PipLib}.
616 More extensive tests are needed to evaluate whether the heuristic is worthwhile.
618 \subsubsection{Dual Simplex + Gomory Cuts}
620 When a new constraint is added to the context, the first steps
621 of the dual simplex method applied to this new context will be the same
622 or at least very similar to those taken on the original context, i.e.,
623 before the constraint was added. In {\tt isl}, we therefore apply
624 the dual simplex method incrementally on the context and backtrack
625 to a previous state when a constraint is removed again.
626 An initial implementation that was never made public would also
627 keep the Gomory cuts, but the current implementation backtracks
628 to before the point where Gomory cuts are added before adding
629 an extra constraint to the context.
630 Keeping the Gomory cuts has the advantage that the sample value
631 is always an integer point and that this point may also satisfy
632 the new constraint. However, due to the technique of maintaining
633 witnesses explained above,
634 we would not perform a feasibility test in such cases and then
635 the previously added cuts may be redundant, possibly resulting
636 in an accumulation of a large number of cuts.
638 If the parameters may be negative, then the same big parameter trick
639 used in the main tableau is applied to the context. This big parameter
640 is of course unrelated to the big parameter from the main tableau.
641 Note that it is not a requirement for this parameter to be ``big'',
642 but it does allow for some code reuse in {\tt isl}.
643 In {\tt PipLib}, the extra parameter is not ``big'', but this may be because
644 the big parameter of the main tableau also appears
645 in the context tableau.
647 Finally, it was reported by \textcite{Galea2009personal}, who
648 worked on a parametric integer programming implementation
649 in {\tt PPL} \parencite{PPL},
650 that it is beneficial to add cuts for \emph{all} rational coordinates
651 in the context tableau. Based on this report,
652 the initial {\tt isl} implementation was adapted accordingly.
654 \subsubsection{Generalized Basis Reduction}\label{s:GBR}
656 The default algorithm used in {\tt isl} for feasibility checking
657 is generalized basis reduction \parencite{Cook1991implementation}.
658 This algorithm is also used in the {\tt barvinok} implementation.
659 The algorithm is fairly robust, but it has some overhead.
660 We therefore try to avoid calling the algorithm in easy cases.
661 In particular, we incrementally keep track of points for which
662 the entire unit hypercube positioned at that point lies in the context.
663 This set is described by translates of the constraints of the context
664 and if (rationally) non-empty, any rational point
665 in the set can be rounded up to yield an integer point in the context.
667 A restriction of the algorithm is that it only works on bounded sets.
668 The affine hull of the recession cone therefore needs to be projected
669 out first. As soon as the algorithm is invoked, we then also
670 incrementally keep track of this recession cone. The reduced basis
671 found by one call of the algorithm is also reused as initial basis
672 for the next call.
674 Some problems lead to the
675 introduction of many integer divisions. Within a given context,
676 some of these integer divisions may be equal to each other, even
677 if the expressions are not identical, or they may be equal to some
678 affine combination of other variables.
679 To detect such cases, we compute the affine hull of the context
680 each time a new integer division is added. The algorithm used
681 for computing this affine hull is that of \textcite{Karr1976affine},
682 while the points used in this algorithm are obtained by performing
683 integer feasibility checks on that part of the context outside
684 the current approximation of the affine hull.
685 The list of witnesses is used to construct an initial approximation
686 of the hull, while any extra points found during the construction
687 of the hull is added to this list.
688 Any equality found in this way that expresses an integer division
689 as an \emph{integer} affine combination of other variables is
690 propagated to the main tableau, where it is used to eliminate that
691 integer division.
693 \subsection{Experiments}\label{s:pip:experiments}
695 \autoref{t:comparison} compares the execution times of {\tt isl}
696 (with both types of context tableau)
697 on some more difficult instances to those of other tools,
698 run on an Intel Xeon W3520 @ 2.66GHz.
699 These instances are available in the \lstinline{testsets/pip} directory
700 of the {\tt isl} distribution.
701 Easier problems such as the
702 test cases distributed with {\tt Pip\-Lib} can be solved so quickly
703 that we would only be measuring overhead such as input/output and conversions
704 and not the running time of the actual algorithm.
705 We compare the following versions:
706 {\tt piplib-1.4.0-5-g0132fd9},
707 {\tt barvinok-0.32.1-73-gc5d7751},
708 {\tt isl-0.05.1-82-g3a37260}
709 and {\tt PPL} version 0.11.2.
711 The first test case is the following dependence analysis problem
712 originating from the Phideo project \parencite{Verhaegh1995PhD}
713 that was communicated to us by Bart Kienhuis:
714 \begin{lstlisting}[flexiblecolumns=true,breaklines=true]{}
715 lexmax { [j1,j2] -> [i1,i2,i3,i4,i5,i6,i7,i8,i9,i10] : 1 <= i1,j1 <= 8 and 1 <= i2,i3,i4,i5,i6,i7,i8,i9,i10 <= 2 and 1 <= j2 <= 128 and i1-1 = j1-1 and i2-1+2*i3-2+4*i4-4+8*i5-8+16*i6-16+32*i7-32+64*i8-64+128*i9-128+256*i10-256=3*j2-3+66 };
716 \end{lstlisting}
717 This problem was the main inspiration
718 for some of the optimizations in \autoref{s:GBR}.
719 The second group of test cases are projections used during counting.
720 The first nine of these come from \textcite{Seghir2006minimizing}.
721 The remaining two come from \textcite{Verdoolaege2005experiences} and
722 were used to drive the first, Gomory cuts based, implementation
723 in {\tt isl}.
724 The third and final group of test cases are borrowed from
725 \textcite{Bygde2010licentiate} and inspired the offline symmetry detection
726 of \autoref{s:offline}. Without symmetry detection, the running times
727 are 11s and 5.9s.
728 All running times of {\tt barvinok} and {\tt isl} include a conversion
729 to disjunctive normal form. Without this conversion, the final two
730 cases can be solved in 0.07s and 0.21s.
731 The {\tt PipLib} implementation has some fixed limits and will
732 sometimes report the problem to be too complex (TC), while on some other
733 problems it will run out of memory (OOM).
734 The {\tt barvinok} implementation does not support problems
735 with a non-trivial lineality space (line) nor maximization problems (max).
736 The Gomory cuts based {\tt isl} implementation was terminated after 1000
737 minutes on the first problem. The gbr version introduces some
738 overhead on some of the easier problems, but is overall the clear winner.
740 \begin{table}
741 \begin{center}
742 \begin{tabular}{lrrrrr}
743 & {\tt PipLib} & {\tt barvinok} & {\tt isl} cut & {\tt isl} gbr & {\tt PPL} \\
744 \hline
745 \hline
746 % bart.pip
747 Phideo & TC & 793m & $>$999m & 2.7s & 372m \\
748 \hline
749 e1 & 0.33s & 3.5s & 0.08s & 0.11s & 0.18s \\
750 e3 & 0.14s & 0.13s & 0.10s & 0.10s & 0.17s \\
751 e4 & 0.24s & 9.1s & 0.09s & 0.11s & 0.70s \\
752 e5 & 0.12s & 6.0s & 0.06s & 0.14s & 0.17s \\
753 e6 & 0.10s & 6.8s & 0.17s & 0.08s & 0.21s \\
754 e7 & 0.03s & 0.27s & 0.04s & 0.04s & 0.03s \\
755 e8 & 0.03s & 0.18s & 0.03s & 0.04s & 0.01s \\
756 e9 & OOM & 70m & 2.6s & 0.94s & 22s \\
757 vd & 0.04s & 0.10s & 0.03s & 0.03s & 0.03s \\
758 bouleti & 0.25s & line & 0.06s & 0.06s & 0.15s \\
759 difficult & OOM & 1.3s & 1.7s & 0.33s & 1.4s \\
760 \hline
761 cnt/sum & TC & max & 2.2s & 2.2s & OOM \\
762 jcomplex & TC & max & 3.7s & 3.9s & OOM \\
763 \end{tabular}
764 \caption{Comparison of Execution Times}
765 \label{t:comparison}
766 \end{center}
767 \end{table}
769 \subsection{Online Symmetry Detection}\label{s:online}
771 Manual experiments on small instances of the problems of
772 \textcite{Bygde2010licentiate} and an analysis of the results
773 by the approximate MPA method developed by \textcite{Bygde2010licentiate}
774 have revealed that these problems contain many more symmetries
775 than can be detected using the offline method of \autoref{s:offline}.
776 In this section, we present an online detection mechanism that has
777 not been implemented yet, but that has shown promising results
778 in manual applications.
780 Let us first consider what happens when we do not perform offline
781 symmetry detection. At some point, one of the
782 $b_i(\vec p) + \sp {\vec a} {\vec x} \ge 0$ constraints,
783 say the $j$th constraint, appears as a column
784 variable, say $c_1$, while the other constraints are represented
785 as rows of the form $b_i(\vec p) - b_j(\vec p) + c$.
786 The context is then split according to the relative order of
787 $b_j(\vec p)$ and one of the remaining $b_i(\vec p)$.
788 The offline method avoids this split by replacing all $b_i(\vec p)$
789 by a single newly introduced parameter that represents the minimum
790 of these $b_i(\vec p)$.
791 In the online method the split is similarly avoided by the introduction
792 of a new parameter. In particular, a new parameter is introduced
793 that represents
794 $\left| b_j(\vec p) - b_i(\vec p) \right|_+ =
795 \max(b_j(\vec p) - b_i(\vec p), 0)$.
797 In general, let $r = b(\vec p) + \sp {\vec a} {\vec c}$ be a row
798 of the tableau such that the sign of $b(\vec p)$ is indeterminate
799 and such that exactly one of the elements of $\vec a$ is a $1$,
800 while all remaining elements are non-positive.
801 That is, $r = b(\vec p) + c_j - f$ with $f = -\sum_{i\ne j} a_i c_i \ge 0$.
802 We introduce a new parameter $t$ with
803 context constraints $t \ge -b(\vec p)$ and $t \ge 0$ and replace
804 the column variable $c_j$ by $c' + t$. The row $r$ is now equal
805 to $b(\vec p) + t + c' - f$. The constant term of this row is always
806 non-negative because any negative value of $b(\vec p)$ is compensated
807 by $t \ge -b(\vec p)$ while and non-negative value remains non-negative
808 because $t \ge 0$.
810 We need to show that this transformation does not eliminate any valid
811 solutions and that it does not introduce any spurious solutions.
812 Given a valid solution for the original problem, we need to find
813 a non-negative value of $c'$ satisfying the constraints.
814 If $b(\vec p) \ge 0$, we can take $t = 0$ so that
815 $c' = c_j - t = c_j \ge 0$.
816 If $b(\vec p) < 0$, we can take $t = -b(\vec p)$.
817 Since $r = b(\vec p) + c_j - f \ge 0$ and $f \ge 0$, we have
818 $c' = c_j + b(\vec p) \ge 0$.
819 Note that these choices amount to plugging in
820 $t = \left|-b(\vec p)\right|_+ = \max(-b(\vec p), 0)$.
821 Conversely, given a solution to the new problem, we need to find
822 a non-negative value of $c_j$, but this is easy since $c_j = c' + t$
823 and both of these are non-negative.
825 Plugging in $t = \max(-b(\vec p), 0)$ can be performed as in
826 \autoref{s:post}, but, as in the case of offline symmetry detection,
827 it may be better to provide a direct representation for such
828 expressions in the internal representation of sets and relations
829 or at least in a quast-like output format.
831 \section{Coalescing}\label{s:coalescing}
833 See \textcite{Verdoolaege2015impact} for details on integer set coalescing.
835 \section{Transitive Closure}
837 \subsection{Introduction}
839 \begin{definition}[Power of a Relation]
840 Let $R \in \Z^n \to 2^{\Z^{d+d}}$ be a relation and
841 $k \in \Z_{\ge 1}$
842 a positive number, then power $k$ of relation $R$ is defined as
843 \begin{equation}
844 \label{eq:transitive:power}
845 R^k \coloneqq
846 \begin{cases}
847 R & \text{if $k = 1$}
849 R \circ R^{k-1} & \text{if $k \ge 2$}
851 \end{cases}
852 \end{equation}
853 \end{definition}
855 \begin{definition}[Transitive Closure of a Relation]
856 Let $R \in \Z^n \to 2^{\Z^{d+d}}$ be a relation,
857 then the transitive closure $R^+$ of $R$ is the union
858 of all positive powers of $R$,
860 R^+ \coloneqq \bigcup_{k \ge 1} R^k
863 \end{definition}
864 Alternatively, the transitive closure may be defined
865 inductively as
866 \begin{equation}
867 \label{eq:transitive:inductive}
868 R^+ \coloneqq R \cup \left(R \circ R^+\right)
870 \end{equation}
872 Since the transitive closure of a polyhedral relation
873 may no longer be a polyhedral relation \parencite{Kelly1996closure},
874 we can, in the general case, only compute an approximation
875 of the transitive closure.
876 Whereas \textcite{Kelly1996closure} compute underapproximations,
877 we, like \textcite{Beletska2009}, compute overapproximations.
878 That is, given a relation $R$, we will compute a relation $T$
879 such that $R^+ \subseteq T$. Of course, we want this approximation
880 to be as close as possible to the actual transitive closure
881 $R^+$ and we want to detect the cases where the approximation is
882 exact, i.e., where $T = R^+$.
884 For computing an approximation of the transitive closure of $R$,
885 we follow the same general strategy as \textcite{Beletska2009}
886 and first compute an approximation of $R^k$ for $k \ge 1$ and then project
887 out the parameter $k$ from the resulting relation.
889 \begin{example}
890 As a trivial example, consider the relation
891 $R = \{\, x \to x + 1 \,\}$. The $k$th power of this map
892 for arbitrary $k$ is
894 R^k = k \mapsto \{\, x \to x + k \mid k \ge 1 \,\}
897 The transitive closure is then
899 \begin{aligned}
900 R^+ & = \{\, x \to y \mid \exists k \in \Z_{\ge 1} : y = x + k \,\}
902 & = \{\, x \to y \mid y \ge x + 1 \,\}
904 \end{aligned}
906 \end{example}
908 \subsection{Computing an Approximation of $R^k$}
909 \label{s:power}
911 There are some special cases where the computation of $R^k$ is very easy.
912 One such case is that where $R$ does not compose with itself,
913 i.e., $R \circ R = \emptyset$ or $\domain R \cap \range R = \emptyset$.
914 In this case, $R^k$ is only non-empty for $k=1$ where it is equal
915 to $R$ itself.
917 In general, it is impossible to construct a closed form
918 of $R^k$ as a polyhedral relation.
919 We will therefore need to make some approximations.
920 As a first approximations, we will consider each of the basic
921 relations in $R$ as simply adding one or more offsets to a domain element
922 to arrive at an image element and ignore the fact that some of these
923 offsets may only be applied to some of the domain elements.
924 That is, we will only consider the difference set $\Delta\,R$ of the relation.
925 In particular, we will first construct a collection $P$ of paths
926 that move through
927 a total of $k$ offsets and then intersect domain and range of this
928 collection with those of $R$.
929 That is,
930 \begin{equation}
931 \label{eq:transitive:approx}
932 K = P \cap \left(\domain R \to \range R\right)
934 \end{equation}
935 with
936 \begin{equation}
937 \label{eq:transitive:path}
938 P = \vec s \mapsto \{\, \vec x \to \vec y \mid
939 \exists k_i \in \Z_{\ge 0}, \vec\delta_i \in k_i \, \Delta_i(\vec s) :
940 \vec y = \vec x + \sum_i \vec\delta_i
941 \wedge
942 \sum_i k_i = k > 0
943 \,\}
944 \end{equation}
945 and with $\Delta_i$ the basic sets that compose
946 the difference set $\Delta\,R$.
947 Note that the number of basic sets $\Delta_i$ need not be
948 the same as the number of basic relations in $R$.
949 Also note that since addition is commutative, it does not
950 matter in which order we add the offsets and so we are allowed
951 to group them as we did in \eqref{eq:transitive:path}.
953 If all the $\Delta_i$s are singleton sets
954 $\Delta_i = \{\, \vec \delta_i \,\}$ with $\vec \delta_i \in \Z^d$,
955 then \eqref{eq:transitive:path} simplifies to
956 \begin{equation}
957 \label{eq:transitive:singleton}
958 P = \{\, \vec x \to \vec y \mid
959 \exists k_i \in \Z_{\ge 0} :
960 \vec y = \vec x + \sum_i k_i \, \vec \delta_i
961 \wedge
962 \sum_i k_i = k > 0
963 \,\}
964 \end{equation}
965 and then the approximation computed in \eqref{eq:transitive:approx}
966 is essentially the same as that of \textcite{Beletska2009}.
967 If some of the $\Delta_i$s are not singleton sets or if
968 some of $\vec \delta_i$s are parametric, then we need
969 to resort to further approximations.
971 To ease both the exposition and the implementation, we will for
972 the remainder of this section work with extended offsets
973 $\Delta_i' = \Delta_i \times \{\, 1 \,\}$.
974 That is, each offset is extended with an extra coordinate that is
975 set equal to one. The paths constructed by summing such extended
976 offsets have the length encoded as the difference of their
977 final coordinates. The path $P'$ can then be decomposed into
978 paths $P_i'$, one for each $\Delta_i$,
979 \begin{equation}
980 \label{eq:transitive:decompose}
981 P' = \left(
982 (P_m' \cup \identity) \circ \cdots \circ
983 (P_2' \cup \identity) \circ
984 (P_1' \cup \identity)
985 \right) \cap
986 \{\,
987 \vec x' \to \vec y' \mid y_{d+1} - x_{d+1} = k > 0
988 \,\}
990 \end{equation}
991 with
993 P_i' = \vec s \mapsto \{\, \vec x' \to \vec y' \mid
994 \exists k \in \Z_{\ge 1}, \vec \delta \in k \, \Delta_i'(\vec s) :
995 \vec y' = \vec x' + \vec \delta
996 \,\}
999 Note that each $P_i'$ contains paths of length at least one.
1000 We therefore need to take the union with the identity relation
1001 when composing the $P_i'$s to allow for paths that do not contain
1002 any offsets from one or more $\Delta_i'$.
1003 The path that consists of only identity relations is removed
1004 by imposing the constraint $y_{d+1} - x_{d+1} > 0$.
1005 Taking the union with the identity relation means that
1006 that the relations we compose in \eqref{eq:transitive:decompose}
1007 each consist of two basic relations. If there are $m$
1008 disjuncts in the input relation, then a direct application
1009 of the composition operation may therefore result in a relation
1010 with $2^m$ disjuncts, which is prohibitively expensive.
1011 It is therefore crucial to apply coalescing (\autoref{s:coalescing})
1012 after each composition.
1014 Let us now consider how to compute an overapproximation of $P_i'$.
1015 Those that correspond to singleton $\Delta_i$s are grouped together
1016 and handled as in \eqref{eq:transitive:singleton}.
1017 Note that this is just an optimization. The procedure described
1018 below would produce results that are at least as accurate.
1019 For simplicity, we first assume that no constraint in $\Delta_i'$
1020 involves any existentially quantified variables.
1021 We will return to existentially quantified variables at the end
1022 of this section.
1023 Without existentially quantified variables, we can classify
1024 the constraints of $\Delta_i'$ as follows
1025 \begin{enumerate}
1026 \item non-parametric constraints
1027 \begin{equation}
1028 \label{eq:transitive:non-parametric}
1029 A_1 \vec x + \vec c_1 \geq \vec 0
1030 \end{equation}
1031 \item purely parametric constraints
1032 \begin{equation}
1033 \label{eq:transitive:parametric}
1034 B_2 \vec s + \vec c_2 \geq \vec 0
1035 \end{equation}
1036 \item negative mixed constraints
1037 \begin{equation}
1038 \label{eq:transitive:mixed}
1039 A_3 \vec x + B_3 \vec s + \vec c_3 \geq \vec 0
1040 \end{equation}
1041 such that for each row $j$ and for all $\vec s$,
1043 \Delta_i'(\vec s) \cap
1044 \{\, \vec \delta' \mid B_{3,j} \vec s + c_{3,j} > 0 \,\}
1045 = \emptyset
1047 \item positive mixed constraints
1049 A_4 \vec x + B_4 \vec s + \vec c_4 \geq \vec 0
1051 such that for each row $j$, there is at least one $\vec s$ such that
1053 \Delta_i'(\vec s) \cap
1054 \{\, \vec \delta' \mid B_{4,j} \vec s + c_{4,j} > 0 \,\}
1055 \ne \emptyset
1057 \end{enumerate}
1058 We will use the following approximation $Q_i$ for $P_i'$:
1059 \begin{equation}
1060 \label{eq:transitive:Q}
1061 \begin{aligned}
1062 Q_i = \vec s \mapsto
1063 \{\,
1064 \vec x' \to \vec y'
1065 \mid {} & \exists k \in \Z_{\ge 1}, \vec f \in \Z^d :
1066 \vec y' = \vec x' + (\vec f, k)
1067 \wedge {}
1070 A_1 \vec f + k \vec c_1 \geq \vec 0
1071 \wedge
1072 B_2 \vec s + \vec c_2 \geq \vec 0
1073 \wedge
1074 A_3 \vec f + B_3 \vec s + \vec c_3 \geq \vec 0
1075 \,\}
1077 \end{aligned}
1078 \end{equation}
1079 To prove that $Q_i$ is indeed an overapproximation of $P_i'$,
1080 we need to show that for every $\vec s \in \Z^n$, for every
1081 $k \in \Z_{\ge 1}$ and for every $\vec f \in k \, \Delta_i(\vec s)$
1082 we have that
1083 $(\vec f, k)$ satisfies the constraints in \eqref{eq:transitive:Q}.
1084 If $\Delta_i(\vec s)$ is non-empty, then $\vec s$ must satisfy
1085 the constraints in \eqref{eq:transitive:parametric}.
1086 Each element $(\vec f, k) \in k \, \Delta_i'(\vec s)$ is a sum
1087 of $k$ elements $(\vec f_j, 1)$ in $\Delta_i'(\vec s)$.
1088 Each of these elements satisfies the constraints in
1089 \eqref{eq:transitive:non-parametric}, i.e.,
1091 \left[
1092 \begin{matrix}
1093 A_1 & \vec c_1
1094 \end{matrix}
1095 \right]
1096 \left[
1097 \begin{matrix}
1098 \vec f_j \\ 1
1099 \end{matrix}
1100 \right]
1101 \ge \vec 0
1104 The sum of these elements therefore satisfies the same set of inequalities,
1105 i.e., $A_1 \vec f + k \vec c_1 \geq \vec 0$.
1106 Finally, the constraints in \eqref{eq:transitive:mixed} are such
1107 that for any $\vec s$ in the parameter domain of $\Delta$,
1108 we have $-\vec r(\vec s) \coloneqq B_3 \vec s + \vec c_3 \le \vec 0$,
1109 i.e., $A_3 \vec f_j \ge \vec r(\vec s) \ge \vec 0$
1110 and therefore also $A_3 \vec f \ge \vec r(\vec s)$.
1111 Note that if there are no mixed constraints and if the
1112 rational relaxation of $\Delta_i(\vec s)$, i.e.,
1113 $\{\, \vec x \in \Q^d \mid A_1 \vec x + \vec c_1 \ge \vec 0\,\}$,
1114 has integer vertices, then the approximation is exact, i.e.,
1115 $Q_i = P_i'$. In this case, the vertices of $\Delta'_i(\vec s)$
1116 generate the rational cone
1117 $\{\, \vec x' \in \Q^{d+1} \mid \left[
1118 \begin{matrix}
1119 A_1 & \vec c_1
1120 \end{matrix}
1121 \right] \vec x' \,\}$ and therefore $\Delta'_i(\vec s)$ is
1122 a Hilbert basis of this cone \parencite[Theorem~16.4]{Schrijver1986}.
1124 Note however that, as pointed out by \textcite{DeSmet2010personal},
1125 if there \emph{are} any mixed constraints, then the above procedure may
1126 not compute the most accurate affine approximation of
1127 $k \, \Delta_i(\vec s)$ with $k \ge 1$.
1128 In particular, we only consider the negative mixed constraints that
1129 happen to appear in the description of $\Delta_i(\vec s)$, while we
1130 should instead consider \emph{all} valid such constraints.
1131 It is also sufficient to consider those constraints because any
1132 constraint that is valid for $k \, \Delta_i(\vec s)$ is also
1133 valid for $1 \, \Delta_i(\vec s) = \Delta_i(\vec s)$.
1134 Take therefore any constraint
1135 $\spv a x + \spv b s + c \ge 0$ valid for $\Delta_i(\vec s)$.
1136 This constraint is also valid for $k \, \Delta_i(\vec s)$ iff
1137 $k \, \spv a x + \spv b s + c \ge 0$.
1138 If $\spv b s + c$ can attain any positive value, then $\spv a x$
1139 may be negative for some elements of $\Delta_i(\vec s)$.
1140 We then have $k \, \spv a x < \spv a x$ for $k > 1$ and so the constraint
1141 is not valid for $k \, \Delta_i(\vec s)$.
1142 We therefore need to impose $\spv b s + c \le 0$ for all values
1143 of $\vec s$ such that $\Delta_i(\vec s)$ is non-empty, i.e.,
1144 $\vec b$ and $c$ need to be such that $- \spv b s - c \ge 0$ is a valid
1145 constraint of $\Delta_i(\vec s)$. That is, $(\vec b, c)$ are the opposites
1146 of the coefficients of a valid constraint of $\Delta_i(\vec s)$.
1147 The approximation of $k \, \Delta_i(\vec s)$ can therefore be obtained
1148 using three applications of Farkas' lemma. The first obtains the coefficients
1149 of constraints valid for $\Delta_i(\vec s)$. The second obtains
1150 the coefficients of constraints valid for the projection of $\Delta_i(\vec s)$
1151 onto the parameters. The opposite of the second set is then computed
1152 and intersected with the first set. The result is the set of coefficients
1153 of constraints valid for $k \, \Delta_i(\vec s)$. A final application
1154 of Farkas' lemma is needed to obtain the approximation of
1155 $k \, \Delta_i(\vec s)$ itself.
1157 \begin{example}
1158 Consider the relation
1160 n \to \{\, (x, y) \to (1 + x, 1 - n + y) \mid n \ge 2 \,\}
1163 The difference set of this relation is
1165 \Delta = n \to \{\, (1, 1 - n) \mid n \ge 2 \,\}
1168 Using our approach, we would only consider the mixed constraint
1169 $y - 1 + n \ge 0$, leading to the following approximation of the
1170 transitive closure:
1172 n \to \{\, (x, y) \to (o_0, o_1) \mid n \ge 2 \wedge o_1 \le 1 - n + y \wedge o_0 \ge 1 + x \,\}
1175 If, instead, we apply Farkas's lemma to $\Delta$, i.e.,
1176 \begin{verbatim}
1177 D := [n] -> { [1, 1 - n] : n >= 2 };
1178 CD := coefficients D;
1180 \end{verbatim}
1181 we obtain
1182 \begin{verbatim}
1183 { rat: coefficients[[c_cst, c_n] -> [i2, i3]] : i3 <= c_n and
1184 i3 <= c_cst + 2c_n + i2 }
1185 \end{verbatim}
1186 The pure-parametric constraints valid for $\Delta$,
1187 \begin{verbatim}
1188 P := { [a,b] -> [] }(D);
1189 CP := coefficients P;
1191 \end{verbatim}
1193 \begin{verbatim}
1194 { rat: coefficients[[c_cst, c_n] -> []] : c_n >= 0 and 2c_n >= -c_cst }
1195 \end{verbatim}
1196 Negating these coefficients and intersecting with \verb+CD+,
1197 \begin{verbatim}
1198 NCP := { rat: coefficients[[a,b] -> []]
1199 -> coefficients[[-a,-b] -> []] }(CP);
1200 CK := wrap((unwrap CD) * (dom (unwrap NCP)));
1202 \end{verbatim}
1203 we obtain
1204 \begin{verbatim}
1205 { rat: [[c_cst, c_n] -> [i2, i3]] : i3 <= c_n and
1206 i3 <= c_cst + 2c_n + i2 and c_n <= 0 and 2c_n <= -c_cst }
1207 \end{verbatim}
1208 The approximation for $k\,\Delta$,
1209 \begin{verbatim}
1210 K := solutions CK;
1212 \end{verbatim}
1213 is then
1214 \begin{verbatim}
1215 [n] -> { rat: [i0, i1] : i1 <= -i0 and i0 >= 1 and i1 <= 2 - n - i0 }
1216 \end{verbatim}
1217 Finally, the computed approximation for $R^+$,
1218 \begin{verbatim}
1219 T := unwrap({ [dx,dy] -> [[x,y] -> [x+dx,y+dy]] }(K));
1220 R := [n] -> { [x,y] -> [x+1,y+1-n] : n >= 2 };
1221 T := T * ((dom R) -> (ran R));
1223 \end{verbatim}
1225 \begin{verbatim}
1226 [n] -> { [x, y] -> [o0, o1] : o1 <= x + y - o0 and
1227 o0 >= 1 + x and o1 <= 2 - n + x + y - o0 and n >= 2 }
1228 \end{verbatim}
1229 \end{example}
1231 Existentially quantified variables can be handled by
1232 classifying them into variables that are uniquely
1233 determined by the parameters, variables that are independent
1234 of the parameters and others. The first set can be treated
1235 as parameters and the second as variables. Constraints involving
1236 the other existentially quantified variables are removed.
1238 \begin{example}
1239 Consider the relation
1242 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 \,\}
1245 The difference set of this relation is
1247 \Delta = \Delta \, R =
1248 n \to \{\, x \mid \exists \, \alpha_0, \alpha_1: 7\alpha_0 = -2 + n \wedge 5\alpha_1 = -1 + x \wedge x \ge 6 \,\}
1251 The existentially quantified variables can be defined in terms
1252 of the parameters and variables as
1254 \alpha_0 = \floor{\frac{-2 + n}7}
1255 \qquad
1256 \text{and}
1257 \qquad
1258 \alpha_1 = \floor{\frac{-1 + x}5}
1261 $\alpha_0$ can therefore be treated as a parameter,
1262 while $\alpha_1$ can be treated as a variable.
1263 This in turn means that $7\alpha_0 = -2 + n$ can be treated as
1264 a purely parametric constraint, while the other two constraints are
1265 non-parametric.
1266 The corresponding $Q$~\eqref{eq:transitive:Q} is therefore
1268 \begin{aligned}
1269 n \to \{\, (x,z) \to (y,w) \mid
1270 \exists\, \alpha_0, \alpha_1, k, f : {} &
1271 k \ge 1 \wedge
1272 y = x + f \wedge
1273 w = z + k \wedge {} \\
1275 7\alpha_0 = -2 + n \wedge
1276 5\alpha_1 = -k + x \wedge
1277 x \ge 6 k
1278 \,\}
1280 \end{aligned}
1282 Projecting out the final coordinates encoding the length of the paths,
1283 results in the exact transitive closure
1285 R^+ =
1286 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 \,\}
1289 \end{example}
1291 The fact that we ignore some impure constraints clearly leads
1292 to a loss of accuracy. In some cases, some of this loss can be recovered
1293 by not considering the parameters in a special way.
1294 That is, instead of considering the set
1296 \Delta = \diff R =
1297 \vec s \mapsto
1298 \{\, \vec \delta \in \Z^{d} \mid \exists \vec x \to \vec y \in R :
1299 \vec \delta = \vec y - \vec x
1300 \,\}
1302 we consider the set
1304 \Delta' = \diff R' =
1305 \{\, \vec \delta \in \Z^{n+d} \mid \exists
1306 (\vec s, \vec x) \to (\vec s, \vec y) \in R' :
1307 \vec \delta = (\vec s - \vec s, \vec y - \vec x)
1308 \,\}
1311 The first $n$ coordinates of every element in $\Delta'$ are zero.
1312 Projecting out these zero coordinates from $\Delta'$ is equivalent
1313 to projecting out the parameters in $\Delta$.
1314 The result is obviously a superset of $\Delta$, but all its constraints
1315 are of type \eqref{eq:transitive:non-parametric} and they can therefore
1316 all be used in the construction of $Q_i$.
1318 \begin{example}
1319 Consider the relation
1321 % [n] -> { [x, y] -> [1 + x, 1 - n + y] | n >= 2 }
1322 R = n \to \{\, (x, y) \to (1 + x, 1 - n + y) \mid n \ge 2 \,\}
1325 We have
1327 \diff R = n \to \{\, (1, 1 - n) \mid n \ge 2 \,\}
1329 and so, by treating the parameters in a special way, we obtain
1330 the following approximation for $R^+$:
1332 n \to \{\, (x, y) \to (x', y') \mid n \ge 2 \wedge y' \le 1 - n + y \wedge x' \ge 1 + x \,\}
1335 If we consider instead
1337 R' = \{\, (n, x, y) \to (n, 1 + x, 1 - n + y) \mid n \ge 2 \,\}
1339 then
1341 \diff R' = \{\, (0, 1, y) \mid y \le -1 \,\}
1343 and we obtain the approximation
1345 n \to \{\, (x, y) \to (x', y') \mid n \ge 2 \wedge x' \ge 1 + x \wedge y' \le x + y - x' \,\}
1348 If we consider both $\diff R$ and $\diff R'$, then we obtain
1350 n \to \{\, (x, y) \to (x', y') \mid n \ge 2 \wedge y' \le 1 - n + y \wedge x' \ge 1 + x \wedge y' \le x + y - x' \,\}
1353 Note, however, that this is not the most accurate affine approximation that
1354 can be obtained. That would be
1356 n \to \{\, (x, y) \to (x', y') \mid y' \le 2 - n + x + y - x' \wedge n \ge 2 \wedge x' \ge 1 + x \,\}
1359 \end{example}
1361 \subsection{Checking Exactness}
1363 The approximation $T$ for the transitive closure $R^+$ can be obtained
1364 by projecting out the parameter $k$ from the approximation $K$
1365 \eqref{eq:transitive:approx} of the power $R^k$.
1366 Since $K$ is an overapproximation of $R^k$, $T$ will also be an
1367 overapproximation of $R^+$.
1368 To check whether the results are exact, we need to consider two
1369 cases depending on whether $R$ is {\em cyclic}, where $R$ is defined
1370 to be cyclic if $R^+$ maps any element to itself, i.e.,
1371 $R^+ \cap \identity \ne \emptyset$.
1372 If $R$ is acyclic, then the inductive definition of
1373 \eqref{eq:transitive:inductive} is equivalent to its completion,
1374 i.e.,
1376 R^+ = R \cup \left(R \circ R^+\right)
1378 is a defining property.
1379 Since $T$ is known to be an overapproximation, we only need to check
1380 whether
1382 T \subseteq R \cup \left(R \circ T\right)
1385 This is essentially Theorem~5 of \textcite{Kelly1996closure}.
1386 The only difference is that they only consider lexicographically
1387 forward relations, a special case of acyclic relations.
1389 If, on the other hand, $R$ is cyclic, then we have to resort
1390 to checking whether the approximation $K$ of the power is exact.
1391 Note that $T$ may be exact even if $K$ is not exact, so the check
1392 is sound, but incomplete.
1393 To check exactness of the power, we simply need to check
1394 \eqref{eq:transitive:power}. Since again $K$ is known
1395 to be an overapproximation, we only need to check whether
1397 \begin{aligned}
1398 K'|_{y_{d+1} - x_{d+1} = 1} & \subseteq R'
1400 K'|_{y_{d+1} - x_{d+1} \ge 2} & \subseteq R' \circ K'|_{y_{d+1} - x_{d+1} \ge 1}
1402 \end{aligned}
1404 where $R' = \{\, \vec x' \to \vec y' \mid \vec x \to \vec y \in R
1405 \wedge y_{d+1} - x_{d+1} = 1\,\}$, i.e., $R$ extended with path
1406 lengths equal to 1.
1408 All that remains is to explain how to check the cyclicity of $R$.
1409 Note that the exactness on the power is always sound, even
1410 in the acyclic case, so we only need to be careful that we find
1411 all cyclic cases. Now, if $R$ is cyclic, i.e.,
1412 $R^+ \cap \identity \ne \emptyset$, then, since $T$ is
1413 an overapproximation of $R^+$, also
1414 $T \cap \identity \ne \emptyset$. This in turn means
1415 that $\Delta \, K'$ contains a point whose first $d$ coordinates
1416 are zero and whose final coordinate is positive.
1417 In the implementation we currently perform this test on $P'$ instead of $K'$.
1418 Note that if $R^+$ is acyclic and $T$ is not, then the approximation
1419 is clearly not exact and the approximation of the power $K$
1420 will not be exact either.
1422 \subsection{Decomposing $R$ into strongly connected components}
1424 If the input relation $R$ is a union of several basic relations
1425 that can be partially ordered
1426 then the accuracy of the approximation may be improved by computing
1427 an approximation of each strongly connected components separately.
1428 For example, if $R = R_1 \cup R_2$ and $R_1 \circ R_2 = \emptyset$,
1429 then we know that any path that passes through $R_2$ cannot later
1430 pass through $R_1$, i.e.,
1431 \begin{equation}
1432 \label{eq:transitive:components}
1433 R^+ = R_1^+ \cup R_2^+ \cup \left(R_2^+ \circ R_1^+\right)
1435 \end{equation}
1436 We can therefore compute (approximations of) transitive closures
1437 of $R_1$ and $R_2$ separately.
1438 Note, however, that the condition $R_1 \circ R_2 = \emptyset$
1439 is actually too strong.
1440 If $R_1 \circ R_2$ is a subset of $R_2 \circ R_1$
1441 then we can reorder the segments
1442 in any path that moves through both $R_1$ and $R_2$ to
1443 first move through $R_1$ and then through $R_2$.
1445 This idea can be generalized to relations that are unions
1446 of more than two basic relations by constructing the
1447 strongly connected components in the graph with as vertices
1448 the basic relations and an edge between two basic relations
1449 $R_i$ and $R_j$ if $R_i$ needs to follow $R_j$ in some paths.
1450 That is, there is an edge from $R_i$ to $R_j$ iff
1451 \begin{equation}
1452 \label{eq:transitive:edge}
1453 R_i \circ R_j
1454 \not\subseteq
1455 R_j \circ R_i
1457 \end{equation}
1458 The components can be obtained from the graph by applying
1459 Tarjan's algorithm \parencite{Tarjan1972}.
1461 In practice, we compute the (extended) powers $K_i'$ of each component
1462 separately and then compose them as in \eqref{eq:transitive:decompose}.
1463 Note, however, that in this case the order in which we apply them is
1464 important and should correspond to a topological ordering of the
1465 strongly connected components. Simply applying Tarjan's
1466 algorithm will produce topologically sorted strongly connected components.
1467 The graph on which Tarjan's algorithm is applied is constructed on-the-fly.
1468 That is, whenever the algorithm checks if there is an edge between
1469 two vertices, we evaluate \eqref{eq:transitive:edge}.
1470 The exactness check is performed on each component separately.
1471 If the approximation turns out to be inexact for any of the components,
1472 then the entire result is marked inexact and the exactness check
1473 is skipped on the components that still need to be handled.
1475 It should be noted that \eqref{eq:transitive:components}
1476 is only valid for exact transitive closures.
1477 If overapproximations are computed in the right hand side, then the result will
1478 still be an overapproximation of the left hand side, but this result
1479 may not be transitively closed. If we only separate components based
1480 on the condition $R_i \circ R_j = \emptyset$, then there is no problem,
1481 as this condition will still hold on the computed approximations
1482 of the transitive closures. If, however, we have exploited
1483 \eqref{eq:transitive:edge} during the decomposition and if the
1484 result turns out not to be exact, then we check whether
1485 the result is transitively closed. If not, we recompute
1486 the transitive closure, skipping the decomposition.
1487 Note that testing for transitive closedness on the result may
1488 be fairly expensive, so we may want to make this check
1489 configurable.
1491 \begin{figure}
1492 \begin{center}
1493 \begin{tikzpicture}[x=0.5cm,y=0.5cm,>=stealth,shorten >=1pt]
1494 \foreach \x in {1,...,10}{
1495 \foreach \y in {1,...,10}{
1496 \draw[->] (\x,\y) -- (\x,\y+1);
1499 \foreach \x in {1,...,20}{
1500 \foreach \y in {5,...,15}{
1501 \draw[->] (\x,\y) -- (\x+1,\y);
1504 \end{tikzpicture}
1505 \end{center}
1506 \caption{The relation from \autoref{ex:closure4}}
1507 \label{f:closure4}
1508 \end{figure}
1509 \begin{example}
1510 \label{ex:closure4}
1511 Consider the relation in example {\tt closure4} that comes with
1512 the Omega calculator~\parencite{Omega_calc}, $R = R_1 \cup R_2$,
1513 with
1515 \begin{aligned}
1516 R_1 & = \{\, (x,y) \to (x,y+1) \mid 1 \le x,y \le 10 \,\}
1518 R_2 & = \{\, (x,y) \to (x+1,y) \mid 1 \le x \le 20 \wedge 5 \le y \le 15 \,\}
1520 \end{aligned}
1522 This relation is shown graphically in \autoref{f:closure4}.
1523 We have
1525 \begin{aligned}
1526 R_1 \circ R_2 &=
1527 \{\, (x,y) \to (x+1,y+1) \mid 1 \le x \le 9 \wedge 5 \le y \le 10 \,\}
1529 R_2 \circ R_1 &=
1530 \{\, (x,y) \to (x+1,y+1) \mid 1 \le x \le 10 \wedge 4 \le y \le 10 \,\}
1532 \end{aligned}
1534 Clearly, $R_1 \circ R_2 \subseteq R_2 \circ R_1$ and so
1536 \left(
1537 R_1 \cup R_2
1538 \right)^+
1540 \left(R_2^+ \circ R_1^+\right)
1541 \cup R_1^+
1542 \cup R_2^+
1545 \end{example}
1547 \begin{figure}
1548 \newcounter{n}
1549 \newcounter{t1}
1550 \newcounter{t2}
1551 \newcounter{t3}
1552 \newcounter{t4}
1553 \begin{center}
1554 \begin{tikzpicture}[>=stealth,shorten >=1pt]
1555 \setcounter{n}{7}
1556 \foreach \i in {1,...,\value{n}}{
1557 \foreach \j in {1,...,\value{n}}{
1558 \setcounter{t1}{2 * \j - 4 - \i + 1}
1559 \setcounter{t2}{\value{n} - 3 - \i + 1}
1560 \setcounter{t3}{2 * \i - 1 - \j + 1}
1561 \setcounter{t4}{\value{n} - \j + 1}
1562 \ifnum\value{t1}>0\ifnum\value{t2}>0
1563 \ifnum\value{t3}>0\ifnum\value{t4}>0
1564 \draw[thick,->] (\i,\j) to[out=20] (\i+3,\j);
1565 \fi\fi\fi\fi
1566 \setcounter{t1}{2 * \j - 1 - \i + 1}
1567 \setcounter{t2}{\value{n} - \i + 1}
1568 \setcounter{t3}{2 * \i - 4 - \j + 1}
1569 \setcounter{t4}{\value{n} - 3 - \j + 1}
1570 \ifnum\value{t1}>0\ifnum\value{t2}>0
1571 \ifnum\value{t3}>0\ifnum\value{t4}>0
1572 \draw[thick,->] (\i,\j) to[in=-20,out=20] (\i,\j+3);
1573 \fi\fi\fi\fi
1574 \setcounter{t1}{2 * \j - 1 - \i + 1}
1575 \setcounter{t2}{\value{n} - 1 - \i + 1}
1576 \setcounter{t3}{2 * \i - 1 - \j + 1}
1577 \setcounter{t4}{\value{n} - 1 - \j + 1}
1578 \ifnum\value{t1}>0\ifnum\value{t2}>0
1579 \ifnum\value{t3}>0\ifnum\value{t4}>0
1580 \draw[thick,->] (\i,\j) to (\i+1,\j+1);
1581 \fi\fi\fi\fi
1584 \end{tikzpicture}
1585 \end{center}
1586 \caption{The relation from \autoref{ex:decomposition}}
1587 \label{f:decomposition}
1588 \end{figure}
1589 \begin{example}
1590 \label{ex:decomposition}
1591 Consider the relation on the right of \textcite[Figure~2]{Beletska2009},
1592 reproduced in \autoref{f:decomposition}.
1593 The relation can be described as $R = R_1 \cup R_2 \cup R_3$,
1594 with
1596 \begin{aligned}
1597 R_1 &= n \mapsto \{\, (i,j) \to (i+3,j) \mid
1598 i \le 2 j - 4 \wedge
1599 i \le n - 3 \wedge
1600 j \le 2 i - 1 \wedge
1601 j \le n \,\}
1603 R_2 &= n \mapsto \{\, (i,j) \to (i,j+3) \mid
1604 i \le 2 j - 1 \wedge
1605 i \le n \wedge
1606 j \le 2 i - 4 \wedge
1607 j \le n - 3 \,\}
1609 R_3 &= n \mapsto \{\, (i,j) \to (i+1,j+1) \mid
1610 i \le 2 j - 1 \wedge
1611 i \le n - 1 \wedge
1612 j \le 2 i - 1 \wedge
1613 j \le n - 1\,\}
1615 \end{aligned}
1617 The figure shows this relation for $n = 7$.
1618 Both
1619 $R_3 \circ R_1 \subseteq R_1 \circ R_3$
1621 $R_3 \circ R_2 \subseteq R_2 \circ R_3$,
1622 which the reader can verify using the {\tt iscc} calculator:
1623 \begin{verbatim}
1624 R1 := [n] -> { [i,j] -> [i+3,j] : i <= 2 j - 4 and i <= n - 3 and
1625 j <= 2 i - 1 and j <= n };
1626 R2 := [n] -> { [i,j] -> [i,j+3] : i <= 2 j - 1 and i <= n and
1627 j <= 2 i - 4 and j <= n - 3 };
1628 R3 := [n] -> { [i,j] -> [i+1,j+1] : i <= 2 j - 1 and i <= n - 1 and
1629 j <= 2 i - 1 and j <= n - 1 };
1630 (R1 . R3) - (R3 . R1);
1631 (R2 . R3) - (R3 . R2);
1632 \end{verbatim}
1633 $R_3$ can therefore be moved forward in any path.
1634 For the other two basic relations, we have both
1635 $R_2 \circ R_1 \not\subseteq R_1 \circ R_2$
1637 $R_1 \circ R_2 \not\subseteq R_2 \circ R_1$
1638 and so $R_1$ and $R_2$ form a strongly connected component.
1639 By computing the power of $R_3$ and $R_1 \cup R_2$ separately
1640 and composing the results, the power of $R$ can be computed exactly
1641 using \eqref{eq:transitive:singleton}.
1642 As explained by \textcite{Beletska2009}, applying the same formula
1643 to $R$ directly, without a decomposition, would result in
1644 an overapproximation of the power.
1645 \end{example}
1647 \subsection{Partitioning the domains and ranges of $R$}
1649 The algorithm of \autoref{s:power} assumes that the input relation $R$
1650 can be treated as a union of translations.
1651 This is a reasonable assumption if $R$ maps elements of a given
1652 abstract domain to the same domain.
1653 However, if $R$ is a union of relations that map between different
1654 domains, then this assumption no longer holds.
1655 In particular, when an entire dependence graph is encoded
1656 in a single relation, as is done by, e.g.,
1657 \textcite[Section~6.1]{Barthou2000MSE}, then it does not make
1658 sense to look at differences between iterations of different domains.
1659 Now, arguably, a modified Floyd-Warshall algorithm should
1660 be applied to the dependence graph, as advocated by
1661 \textcite{Kelly1996closure}, with the transitive closure operation
1662 only being applied to relations from a given domain to itself.
1663 However, it is also possible to detect disjoint domains and ranges
1664 and to apply Floyd-Warshall internally.
1666 \LinesNumbered
1667 \begin{algorithm}
1668 \caption{The modified Floyd-Warshall algorithm of
1669 \protect\textcite{Kelly1996closure}}
1670 \label{a:Floyd}
1671 \SetKwInput{Input}{Input}
1672 \SetKwInput{Output}{Output}
1673 \Input{Relations $R_{pq}$, $0 \le p, q < n$}
1674 \Output{Updated relations $R_{pq}$ such that each relation
1675 $R_{pq}$ contains all indirect paths from $p$ to $q$ in the input graph}
1677 \BlankLine
1678 \SetAlgoVlined
1679 \DontPrintSemicolon
1681 \For{$r \in [0, n-1]$}{
1682 $R_{rr} \coloneqq R_{rr}^+$ \nllabel{l:Floyd:closure}\;
1683 \For{$p \in [0, n-1]$}{
1684 \For{$q \in [0, n-1]$}{
1685 \If{$p \ne r$ or $q \ne r$}{
1686 $R_{pq} \coloneqq R_{pq} \cup \left(R_{rq} \circ R_{pr}\right)
1687 \cup \left(R_{rq} \circ R_{rr} \circ R_{pr}\right)$
1688 \nllabel{l:Floyd:update}
1693 \end{algorithm}
1695 Let the input relation $R$ be a union of $m$ basic relations $R_i$.
1696 Let $D_{2i}$ be the domains of $R_i$ and $D_{2i+1}$ the ranges of $R_i$.
1697 The first step is to group overlapping $D_j$ until a partition is
1698 obtained. If the resulting partition consists of a single part,
1699 then we continue with the algorithm of \autoref{s:power}.
1700 Otherwise, we apply Floyd-Warshall on the graph with as vertices
1701 the parts of the partition and as edges the $R_i$ attached to
1702 the appropriate pairs of vertices.
1703 In particular, let there be $n$ parts $P_k$ in the partition.
1704 We construct $n^2$ relations
1706 R_{pq} \coloneqq \bigcup_{i \text{ s.t. } \domain R_i \subseteq P_p \wedge
1707 \range R_i \subseteq P_q} R_i
1710 apply \autoref{a:Floyd} and return the union of all resulting
1711 $R_{pq}$ as the transitive closure of $R$.
1712 Each iteration of the $r$-loop in \autoref{a:Floyd} updates
1713 all relations $R_{pq}$ to include paths that go from $p$ to $r$,
1714 possibly stay there for a while, and then go from $r$ to $q$.
1715 Note that paths that ``stay in $r$'' include all paths that
1716 pass through earlier vertices since $R_{rr}$ itself has been updated
1717 accordingly in previous iterations of the outer loop.
1718 In principle, it would be sufficient to use the $R_{pr}$
1719 and $R_{rq}$ computed in the previous iteration of the
1720 $r$-loop in Line~\ref{l:Floyd:update}.
1721 However, from an implementation perspective, it is easier
1722 to allow either or both of these to have been updated
1723 in the same iteration of the $r$-loop.
1724 This may result in duplicate paths, but these can usually
1725 be removed by coalescing (\autoref{s:coalescing}) the result of the union
1726 in Line~\ref{l:Floyd:update}, which should be done in any case.
1727 The transitive closure in Line~\ref{l:Floyd:closure}
1728 is performed using a recursive call. This recursive call
1729 includes the partitioning step, but the resulting partition will
1730 usually be a singleton.
1731 The result of the recursive call will either be exact or an
1732 overapproximation. The final result of Floyd-Warshall is therefore
1733 also exact or an overapproximation.
1735 \begin{figure}
1736 \begin{center}
1737 \begin{tikzpicture}[x=1cm,y=1cm,>=stealth,shorten >=3pt]
1738 \foreach \x/\y in {0/0,1/1,3/2} {
1739 \fill (\x,\y) circle (2pt);
1741 \foreach \x/\y in {0/1,2/2,3/3} {
1742 \draw (\x,\y) circle (2pt);
1744 \draw[->] (0,0) -- (0,1);
1745 \draw[->] (0,1) -- (1,1);
1746 \draw[->] (2,2) -- (3,2);
1747 \draw[->] (3,2) -- (3,3);
1748 \draw[->,dashed] (2,2) -- (3,3);
1749 \draw[->,dotted] (0,0) -- (1,1);
1750 \end{tikzpicture}
1751 \end{center}
1752 \caption{The relation (solid arrows) on the right of Figure~1 of
1753 \protect\textcite{Beletska2009} and its transitive closure}
1754 \label{f:COCOA:1}
1755 \end{figure}
1756 \begin{example}
1757 Consider the relation on the right of Figure~1 of
1758 \textcite{Beletska2009},
1759 reproduced in \autoref{f:COCOA:1}.
1760 This relation can be described as
1762 \begin{aligned}
1763 \{\, (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 {} \\
1764 & (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) \,\}
1766 \end{aligned}
1768 Note that the domain of the upward relation overlaps with the range
1769 of the rightward relation and vice versa, but that the domain
1770 of neither relation overlaps with its own range or the domain of
1771 the other relation.
1772 The domains and ranges can therefore be partitioned into two parts,
1773 $P_0$ and $P_1$, shown as the white and black dots in \autoref{f:COCOA:1},
1774 respectively.
1775 Initially, we have
1777 \begin{aligned}
1778 R_{00} & = \emptyset
1780 R_{01} & =
1781 \{\, (x, y) \to (x+1, y) \mid
1782 (x \ge 0 \wedge 3y \ge 2 + 2x \wedge x \le 2 \wedge 3y \le 3 + 2x) \,\}
1784 R_{10} & =
1785 \{\, (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) \,\}
1787 R_{11} & = \emptyset
1789 \end{aligned}
1791 In the first iteration, $R_{00}$ remains the same ($\emptyset^+ = \emptyset$).
1792 $R_{01}$ and $R_{10}$ are therefore also unaffected, but
1793 $R_{11}$ is updated to include $R_{01} \circ R_{10}$, i.e.,
1794 the dashed arrow in the figure.
1795 This new $R_{11}$ is obviously transitively closed, so it is not
1796 changed in the second iteration and it does not have an effect
1797 on $R_{01}$ and $R_{10}$. However, $R_{00}$ is updated to
1798 include $R_{10} \circ R_{01}$, i.e., the dotted arrow in the figure.
1799 The transitive closure of the original relation is then equal to
1800 $R_{00} \cup R_{01} \cup R_{10} \cup R_{11}$.
1801 \end{example}
1803 \subsection{Incremental Computation}
1804 \label{s:incremental}
1806 In some cases it is possible and useful to compute the transitive closure
1807 of union of basic relations incrementally. In particular,
1808 if $R$ is a union of $m$ basic maps,
1810 R = \bigcup_j R_j
1813 then we can pick some $R_i$ and compute the transitive closure of $R$ as
1814 \begin{equation}
1815 \label{eq:transitive:incremental}
1816 R^+ = R_i^+ \cup
1817 \left(
1818 \bigcup_{j \ne i}
1819 R_i^* \circ R_j \circ R_i^*
1820 \right)^+
1822 \end{equation}
1823 For this approach to be successful, it is crucial that each
1824 of the disjuncts in the argument of the second transitive
1825 closure in \eqref{eq:transitive:incremental} be representable
1826 as a single basic relation, i.e., without a union.
1827 If this condition holds, then by using \eqref{eq:transitive:incremental},
1828 the number of disjuncts in the argument of the transitive closure
1829 can be reduced by one.
1830 Now, $R_i^* = R_i^+ \cup \identity$, but in some cases it is possible
1831 to relax the constraints of $R_i^+$ to include part of the identity relation,
1832 say on domain $D$. We will use the notation
1833 ${\cal C}(R_i,D) = R_i^+ \cup \identity_D$ to represent
1834 this relaxed version of $R^+$.
1835 \textcite{Kelly1996closure} use the notation $R_i^?$.
1836 ${\cal C}(R_i,D)$ can be computed by allowing $k$ to attain
1837 the value $0$ in \eqref{eq:transitive:Q} and by using
1839 P \cap \left(D \to D\right)
1841 instead of \eqref{eq:transitive:approx}.
1842 Typically, $D$ will be a strict superset of both $\domain R_i$
1843 and $\range R_i$. We therefore need to check that domain
1844 and range of the transitive closure are part of ${\cal C}(R_i,D)$,
1845 i.e., the part that results from the paths of positive length ($k \ge 1$),
1846 are equal to the domain and range of $R_i$.
1847 If not, then the incremental approach cannot be applied for
1848 the given choice of $R_i$ and $D$.
1850 In order to be able to replace $R^*$ by ${\cal C}(R_i,D)$
1851 in \eqref{eq:transitive:incremental}, $D$ should be chosen
1852 to include both $\domain R$ and $\range R$, i.e., such
1853 that $\identity_D \circ R_j \circ \identity_D = R_j$ for all $j\ne i$.
1854 \textcite{Kelly1996closure} say that they use
1855 $D = \domain R_i \cup \range R_i$, but presumably they mean that
1856 they use $D = \domain R \cup \range R$.
1857 Now, this expression of $D$ contains a union, so it not directly usable.
1858 \textcite{Kelly1996closure} do not explain how they avoid this union.
1859 Apparently, in their implementation,
1860 they are using the convex hull of $\domain R \cup \range R$
1861 or at least an approximation of this convex hull.
1862 We use the simple hull (\autoref{s:simple hull}) of $\domain R \cup \range R$.
1864 It is also possible to use a domain $D$ that does {\em not\/}
1865 include $\domain R \cup \range R$, but then we have to
1866 compose with ${\cal C}(R_i,D)$ more selectively.
1867 In particular, if we have
1868 \begin{equation}
1869 \label{eq:transitive:right}
1870 \text{for each $j \ne i$ either }
1871 \domain R_j \subseteq D \text{ or } \domain R_j \cap \range R_i = \emptyset
1872 \end{equation}
1873 and, similarly,
1874 \begin{equation}
1875 \label{eq:transitive:left}
1876 \text{for each $j \ne i$ either }
1877 \range R_j \subseteq D \text{ or } \range R_j \cap \domain R_i = \emptyset
1878 \end{equation}
1879 then we can refine \eqref{eq:transitive:incremental} to
1881 R_i^+ \cup
1882 \left(
1883 \left(
1884 \bigcup_{\shortstack{$\scriptstyle\domain R_j \subseteq D $\\
1885 $\scriptstyle\range R_j \subseteq D$}}
1886 {\cal C} \circ R_j \circ {\cal C}
1887 \right)
1888 \cup
1889 \left(
1890 \bigcup_{\shortstack{$\scriptstyle\domain R_j \cap \range R_i = \emptyset$\\
1891 $\scriptstyle\range R_j \subseteq D$}}
1892 \!\!\!\!\!
1893 {\cal C} \circ R_j
1894 \right)
1895 \cup
1896 \left(
1897 \bigcup_{\shortstack{$\scriptstyle\domain R_j \subseteq D $\\
1898 $\scriptstyle\range R_j \cap \domain R_i = \emptyset$}}
1899 \!\!\!\!\!
1900 R_j \circ {\cal C}
1901 \right)
1902 \cup
1903 \left(
1904 \bigcup_{\shortstack{$\scriptstyle\domain R_j \cap \range R_i = \emptyset$\\
1905 $\scriptstyle\range R_j \cap \domain R_i = \emptyset$}}
1906 \!\!\!\!\!
1908 \right)
1909 \right)^+
1912 If only property~\eqref{eq:transitive:right} holds,
1913 we can use
1915 R_i^+ \cup
1916 \left(
1917 \left(
1918 R_i^+ \cup \identity
1919 \right)
1920 \circ
1921 \left(
1922 \left(
1923 \bigcup_{\shortstack{$\scriptstyle\domain R_j \subseteq D $}}
1924 R_j \circ {\cal C}
1925 \right)
1926 \cup
1927 \left(
1928 \bigcup_{\shortstack{$\scriptstyle\domain R_j \cap \range R_i = \emptyset$}}
1929 \!\!\!\!\!
1931 \right)
1932 \right)^+
1933 \right)
1936 while if only property~\eqref{eq:transitive:left} holds,
1937 we can use
1939 R_i^+ \cup
1940 \left(
1941 \left(
1942 \left(
1943 \bigcup_{\shortstack{$\scriptstyle\range R_j \subseteq D $}}
1944 {\cal C} \circ R_j
1945 \right)
1946 \cup
1947 \left(
1948 \bigcup_{\shortstack{$\scriptstyle\range R_j \cap \domain R_i = \emptyset$}}
1949 \!\!\!\!\!
1951 \right)
1952 \right)^+
1953 \circ
1954 \left(
1955 R_i^+ \cup \identity
1956 \right)
1957 \right)
1961 It should be noted that if we want the result of the incremental
1962 approach to be transitively closed, then we can only apply it
1963 if all of the transitive closure operations involved are exact.
1964 If, say, the second transitive closure in \eqref{eq:transitive:incremental}
1965 contains extra elements, then the result does not necessarily contain
1966 the composition of these extra elements with powers of $R_i$.
1968 \subsection{An {\tt Omega}-like implementation}
1970 While the main algorithm of \textcite{Kelly1996closure} is
1971 designed to compute and underapproximation of the transitive closure,
1972 the authors mention that they could also compute overapproximations.
1973 In this section, we describe our implementation of an algorithm
1974 that is based on their ideas.
1975 Note that the {\tt Omega} library computes underapproximations
1976 \parencite[Section 6.4]{Omega_lib}.
1978 The main tool is Equation~(2) of \textcite{Kelly1996closure}.
1979 The input relation $R$ is first overapproximated by a ``d-form'' relation
1981 \{\, \vec i \to \vec j \mid \exists \vec \alpha :
1982 \vec L \le \vec j - \vec i \le \vec U
1983 \wedge
1984 (\forall p : j_p - i_p = M_p \alpha_p)
1985 \,\}
1988 where $p$ ranges over the dimensions and $\vec L$, $\vec U$ and
1989 $\vec M$ are constant integer vectors. The elements of $\vec U$
1990 may be $\infty$, meaning that there is no upper bound corresponding
1991 to that element, and similarly for $\vec L$.
1992 Such an overapproximation can be obtained by computing strides,
1993 lower and upper bounds on the difference set $\Delta \, R$.
1994 The transitive closure of such a ``d-form'' relation is
1995 \begin{equation}
1996 \label{eq:omega}
1997 \{\, \vec i \to \vec j \mid \exists \vec \alpha, k :
1998 k \ge 1 \wedge
1999 k \, \vec L \le \vec j - \vec i \le k \, \vec U
2000 \wedge
2001 (\forall p : j_p - i_p = M_p \alpha_p)
2002 \,\}
2004 \end{equation}
2005 The domain and range of this transitive closure are then
2006 intersected with those of the input relation.
2007 This is a special case of the algorithm in \autoref{s:power}.
2009 In their algorithm for computing lower bounds, the authors
2010 use the above algorithm as a substep on the disjuncts in the relation.
2011 At the end, they say
2012 \begin{quote}
2013 If an upper bound is required, it can be calculated in a manner
2014 similar to that of a single conjunct [sic] relation.
2015 \end{quote}
2016 Presumably, the authors mean that a ``d-form'' approximation
2017 of the whole input relation should be used.
2018 However, the accuracy can be improved by also trying to
2019 apply the incremental technique from the same paper,
2020 which is explained in more detail in \autoref{s:incremental}.
2021 In this case, ${\cal C}(R_i,D)$ can be obtained by
2022 allowing the value zero for $k$ in \eqref{eq:omega},
2023 i.e., by computing
2025 \{\, \vec i \to \vec j \mid \exists \vec \alpha, k :
2026 k \ge 0 \wedge
2027 k \, \vec L \le \vec j - \vec i \le k \, \vec U
2028 \wedge
2029 (\forall p : j_p - i_p = M_p \alpha_p)
2030 \,\}
2033 In our implementation we take as $D$ the simple hull
2034 (\autoref{s:simple hull}) of $\domain R \cup \range R$.
2035 To determine whether it is safe to use ${\cal C}(R_i,D)$,
2036 we check the following conditions, as proposed by
2037 \textcite{Kelly1996closure}:
2038 ${\cal C}(R_i,D) - R_i^+$ is not a union and for each $j \ne i$
2039 the condition
2041 \left({\cal C}(R_i,D) - R_i^+\right)
2042 \circ
2044 \circ
2045 \left({\cal C}(R_i,D) - R_i^+\right)
2049 holds.