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other-processes.lisp
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other-processes.lisp
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; ACL2 Version 8.3 -- A Computational Logic for Applicative Common Lisp
; Copyright (C) 2020, Regents of the University of Texas
; This version of ACL2 is a descendent of ACL2 Version 1.9, Copyright
; (C) 1997 Computational Logic, Inc. See the documentation topic NOTE-2-0.
; This program is free software; you can redistribute it and/or modify
; it under the terms of the LICENSE file distributed with ACL2.
; This program is distributed in the hope that it will be useful,
; but WITHOUT ANY WARRANTY; without even the implied warranty of
; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
; LICENSE for more details.
; Written by: Matt Kaufmann and J Strother Moore
; email: [email protected] and [email protected]
; Department of Computer Science
; University of Texas at Austin
; Austin, TX 78712 U.S.A.
(in-package "ACL2")
; Our top-level function for generating variables attempts to feed
; genvar roots that generate names suggestive of the term being
; replaced by the variable. We now develop the code for generating
; these roots. It involves a recursive descent through a term. At
; the bottom, we see variable symbols, e.g., ABC123, and we wish to
; generate the root '("ABC" . 124).
(defun strip-final-digits1 (lst)
; See strip-final-digits.
(cond ((null lst) (mv "" 0))
((member (car lst) '(#\0 #\1 #\2 #\3 #\4 #\5 #\6 #\7 #\8 #\9))
(mv-let (str n)
(strip-final-digits1 (cdr lst))
(mv str (+ (let ((c (car lst)))
(case c
(#\0 0)
(#\1 1)
(#\2 2)
(#\3 3)
(#\4 4)
(#\5 5)
(#\6 6)
(#\7 7)
(#\8 8)
(otherwise 9)))
(* 10 n)))))
(t (mv (coerce (reverse lst) 'string) 0))))
(defun strip-final-digits (str)
; Given a string, such as "ABC123", we strip off the final digits in it,
; and compute the number they represent. We return two things,
; the string and the number, e.g., "ABC" and 123.
(strip-final-digits1 (reverse (coerce str 'list))))
; For non-variable, non-quote terms we try first the idea of
; generating a name based on the type of the term. The following
; constant associates with selected type sets the names of some
; variables that we find pleasing and suggestive of the type. When we
; generalize a term we look at its type and if it is a subtype of one
; of those listed we prefer to use the variables given. The first
; variable in each family is additionally used as the root for a
; gensym, should it come to that. This list can be extended
; arbitrarily without affecting soundness, as long as (a) the car of
; each pair below is a type set and (b) the cdr is a true-list of
; symbols. Arbitrary overlaps between the types and between the
; symbols are permitted.
;; Historical Comment from Ruben Gamboa:
;; I changed rational to real and complex-rational to complex in
;; the list below, since the new types are supersets of the old types,
;; so it should be harmless.
(defconst *var-families-by-type*
(list (cons *ts-integer* '(I J K L M N))
(cons #+:non-standard-analysis
*ts-real*
#-:non-standard-analysis
*ts-rational*
'(R S I J K L M N))
(cons #+:non-standard-analysis
*ts-complex*
#-:non-standard-analysis
*ts-complex-rational*
'(Z R S I J K L M N))
(cons *ts-cons* '(L LST))
(cons *ts-boolean* '(P Q R))
(cons *ts-symbol* '(A B C D E))
(cons *ts-string* '(S STR))
(cons *ts-character* '(C CH))))
; The following function is used to find the family of vars, given the
; type set of a term:
(defun assoc-ts-subsetp (ts alist)
; Like assoc except we compare with ts-subsetp.
(cond ((null alist) nil)
((ts-subsetp ts (caar alist)) (car alist))
(t (assoc-ts-subsetp ts (cdr alist)))))
; And here is how we look for an acceptable variable.
(defun first-non-member-eq (lst1 lst2)
; Return the first member of lst1 that is not a member-eq of lst2.
(cond ((null lst1) nil)
((member-eq (car lst1) lst2)
(first-non-member-eq (cdr lst1) lst2))
(t (car lst1))))
; If the above techniques don't lead to a choice we generate a string
; from the term by abbreviating the first symbol in the term. Here is
; how we abbreviate:
(defun abbreviate-hyphenated-string1 (str i maximum prev-c)
; We return a list of characters that, when coerced to a string,
; abbreviates string str from position i to (but not including) maximum.
; Currently, it returns the first character after each block of "hyphens"
; and the last character. Thus, "PITON-TEMP-STK" is abbreviated
; "PTSK".
; If prev-char is T it means we output the character we last saw.
; If prev-char is NIL it means the character we last saw was a "hyphen".
; Otherwise, prev-char is the previous character. "Hyphen" here means
; any one of several commonly used "word separators" in symbols.
; This function can be changed arbitrarily as long as it returns a
; list of characters.
(cond
((< i maximum)
(let ((c (char str i)))
(cond
((member c '(#\- #\_ #\. #\/ #\+))
(abbreviate-hyphenated-string1 str (1+ i) maximum nil))
((null prev-c)
(cons c (abbreviate-hyphenated-string1 str (1+ i) maximum t)))
(t (abbreviate-hyphenated-string1 str (1+ i) maximum c)))))
((characterp prev-c) (list prev-c))
(t nil)))
(defun abbreviate-hyphenated-string (str)
; The function scans a string and collects the first and last character
; and every character immediately after a block of "hyphens" as defined
; above.
(let ((lst (abbreviate-hyphenated-string1 str 0 (length str) nil)))
(coerce
(cond ((or (null lst)
(member (car lst) *suspiciously-first-numeric-chars*))
(cons #\V lst))
(t lst))
'string)))
; Just as strip-final-digits produces the genvar root for a variable,
; the following function produces the genvar root for a nonvariable term.
(defun generate-variable-root1 (term avoid-lst type-alist ens wrld)
; Term is a nonvariable, non-quote term. This function returns two
; results, str and n, such that (str . n) is a "root" for genvar.
; In fact, it tries to return a root that when fed to genvar will
; create a variable symbol that is suggestive of term and which does
; not occur in avoid-lst. But the function is correct as long as it
; returns any root, which could be any string.
(mv-let
(ts ttree)
(type-set term t nil type-alist ens wrld nil nil nil)
; Note: We don't really know that the guards have been checked and we
; don't split on the 'assumptions we have forced. But our only use of
; type set here is heuristic. This also explains why we just use the
; global enabled structure and ignore the ttree.
(declare (ignore ttree))
(let* ((family (cdr (assoc-ts-subsetp ts *var-families-by-type*)))
(var (first-non-member-eq family avoid-lst)))
(cond (var
; If the type set of term is one of those for which we have a var family
; and some member of that family does not occur in avoid-lst, then we will
; use the symbol-name of var as the root from which to generate a
; variable symbol for term. This will almost certainly result in the
; generation of the symbol var by genvar. The only condition under which
; this won't happen is if var is an illegal variable symbol, in which case
; genvar will suffix it with some sufficiently large natural.
(mv (symbol-name var) nil))
(family
; If we have a family for this type of term but all the members are
; to be avoided, we'll genvar from the first member of the family and
; we might as well start suffixing immediately (from 0) because we
; know the unsuffixed var is in avoid-lst.
(mv (symbol-name (car family)) 0))
(t
; Otherwise, we will genvar from an abbreviated version of the "first
; symbol" in term.
(mv (abbreviate-hyphenated-string
(symbol-name
(cond ((variablep term) 'z) ; never happens
((fquotep term) 'z) ; never happens
((flambda-applicationp term) 'z)
(t (ffn-symb term)))))
nil))))))
; And here we put them together with one last convention. The
; root for (CAR ...) is just the root for ..., except we force
; there to be a suffix. Thus, the root for (CAR X4) is going to be
; ("X" . 5).
(defun generate-variable-root (term avoid-lst type-alist ens wrld)
(cond
((variablep term)
(mv-let (str n)
(strip-final-digits (symbol-name term))
(mv str (1+ n))))
((fquotep term) (mv "CONST" 0))
((eq (ffn-symb term) 'car)
(mv-let (str n)
(generate-variable-root (fargn term 1) avoid-lst type-alist ens
wrld)
(mv str (or n 0))))
((eq (ffn-symb term) 'cdr)
(mv-let (str n)
(generate-variable-root (fargn term 1) avoid-lst type-alist ens
wrld)
(mv str (or n 0))))
(t (generate-variable-root1 term avoid-lst type-alist ens wrld))))
(defun generate-variable (term avoid-lst type-alist ens wrld)
; We generate a legal variable symbol that does not occur in avoid-lst. We use
; term, type-alist, ens, and wrld in a heuristic way to suggest a preferred
; name for the symbol. Generally speaking, the symbol we generate will be used
; to replace term in some conjecture, so we try to generate a symbol that we
; think "suggests" term.
(mv-let (str n)
(generate-variable-root term avoid-lst type-alist ens wrld)
(genvar (find-pkg-witness term) str n avoid-lst)))
(defun generate-variable-lst (term-lst avoid-lst type-alist ens wrld)
; And here we generate a list of variable names sequentially, one for
; each term in term-lst.
; See also generate-variable-lst-simple, which only requires the first two of
; the formals above.
(cond ((null term-lst) nil)
(t
(let ((var (generate-variable (car term-lst) avoid-lst
type-alist ens wrld)))
(cons var (generate-variable-lst (cdr term-lst)
(cons var avoid-lst)
type-alist ens wrld))))))
; That completes the code for generating new variable names.
; An elim-rule, as declared below, denotes a theorem of the form
; (implies hyps (equal lhs rhs)), where rhs is a variable symbol and
; lhs involves the terms destructor-terms, each of which is of the
; form (dfn v1 ... vn), where the vi are distinct variables and {v1
; ... vn} are all the variables in the formula. We call rhs the
; "crucial variable". It is the one we will "puff up" to eliminate
; the destructor terms. For example, in (CONSP X) -> (CONS (CAR X)
; (CDR X)) = X, X is the crucial variable and puffing it up to (CONS A
; B) we can eliminate (CAR X) and (CDR X). We store an elim-rule
; under the function symbol, dfn, of each destructor term. The rule
; we store for (dfn v1 ... vn) has that term as the car of destructor-
; terms and has crucial-position j where (nth j '(v1 ... vn)) = rhs.
; (Thus, the crucial-position is the position in the args at which the
; crucial variable occurs and for these purposes we enumerate the args
; from 0 (as by nth) rather than from 1 (as by fargn).)
; The following is now defined in rewrite.lisp.
; (defrec elim-rule
; (((nume . crucial-position) . (destructor-term . destructor-terms))
; (hyps . equiv)
; (lhs . rhs)
; . rune) nil)
(defun occurs-nowhere-else (var args c i)
; Index the elements of args starting at i. Scan all args except the
; one with index c and return nil if var occurs in one of them and t
; otherwise.
(cond ((null args) t)
((int= c i)
(occurs-nowhere-else var (cdr args) c (1+ i)))
((dumb-occur var (car args)) nil)
(t (occurs-nowhere-else var (cdr args) c (1+ i)))))
(defun first-nomination (term votes nominations)
; See nominate-destructor-candidate for an explanation.
(cons (cons term (cons term votes))
nominations))
(defun second-nomination (term votes nominations)
; See nominate-destructor-candidate for an explanation.
(cond ((null nominations) nil)
((equal term (car (car nominations)))
(cons (cons term
(union-equal votes (cdr (car nominations))))
(cdr nominations)))
(t (cons (car nominations)
(second-nomination term votes (cdr nominations))))))
(defun some-hyp-probably-nilp (hyps type-alist ens wrld)
; The name of this function is meant to limit its use to heuristics.
; In fact, if this function says some hyp is probably nil then in fact
; some hyp is known to be nil under the given type-alist, wrld and
; some forced 'assumptions.
; Since the function actually ignores 'assumptions generated, its use
; must be limited to heuristic situations. When it says "yes, some
; hyp is probably nil" we choose not to pursue the establishment of
; those hyps.
(cond
((null hyps) nil)
(t (mv-let
(knownp nilp ttree)
(known-whether-nil
(car hyps) type-alist ens (ok-to-force-ens ens)
nil ; dwp
wrld nil)
(declare (ignore ttree))
(cond ((and knownp nilp) t)
(t (some-hyp-probably-nilp (cdr hyps) type-alist ens wrld)))))))
(mutual-recursion
(defun sublis-expr (alist term)
; Alist is of the form ((a1 . b1) ... (ak . bk)) where the ai and bi are
; all terms. We substitute bi for each occurrence of ai in term.
; Thus, if the ai are distinct variables, this function is equivalent to
; sublis-var. We do not look for ai's properly inside of quoted objects.
; Thus,
; (sublis-expr '(('3 . x)) '(f '3)) = '(f x)
; but
; (sublis-expr '(('3 . x)) '(f '(3 . 4))) = '(f '(3 . 4)).
(let ((temp (assoc-equal term alist)))
(cond (temp (cdr temp))
((variablep term) term)
((fquotep term) term)
(t (cons-term (ffn-symb term)
(sublis-expr-lst alist (fargs term)))))))
(defun sublis-expr-lst (alist lst)
(cond ((null lst) nil)
(t (cons (sublis-expr alist (car lst))
(sublis-expr-lst alist (cdr lst))))))
)
(defun nominate-destructor-candidate
(term eliminables type-alist clause ens wrld votes nominations)
; This function recognizes candidates for destructor elimination. It
; is assumed that term is a non-variable, non-quotep term. To be a
; candidate the term must not be a lambda application and the function
; symbol of the term must have an enabled destructor elimination rule.
; Furthermore, the crucial argument position of the term must be
; occupied by a variable symbol that is a member of the eliminables,
; that occurs only in equiv-hittable positions within the clause,
; and that occurs nowhere else in the arguments of the term, or else
; the crucial argument position must be occupied by a term that itself
; is recursively a candidate. (Note that if the crucial argument is
; an eliminable term then when we eliminate it we will introduce a
; suitable distinct var into the crucial argument of this term and
; hence it will be eliminable.) Finally, the instantiated hypotheses
; of the destructor elimination rule must not be known nil under the
; type-alist.
; Votes and nominations are accumulators. Votes is a list of terms
; that contain term and will be candidates if term is eliminated.
; Nominations are explained below.
; If term is a candidate we either "nominate" it, by adding a
; "nomination" for term to the running accumulator nominations, or
; else we "second" a prior nomination for it. A nomination of a term
; is a list of the form (dterm . votes) where dterm is the innermost
; eliminable candidate in term and votes is a list of all the terms
; that will be eliminable if dterm is eliminated. To "second" a
; nomination is simply to add yourself as a vote.
; For example, if X is eliminable then (CAR (CAR (CAR X))) is a
; candidate. If nominations is initially nil then at the conclusion
; of this function it will be
; (((CAR X) (CAR X) (CAR (CAR X)) (CAR (CAR (CAR X))))).
; We always return a nominations list.
(cond
((flambda-applicationp term) nominations)
(t (let ((rule (getpropc (ffn-symb term) 'eliminate-destructors-rule nil
wrld)))
(cond
((or (null rule)
(not (enabled-numep (access elim-rule rule :nume) ens)))
nominations)
(t (let ((crucial-arg (nth (access elim-rule rule :crucial-position)
(fargs term))))
(cond
((variablep crucial-arg)
; Next we wish to determine that every occurrence of the crucial
; argument -- outside of the destructor nests themselves -- is equiv
; hittable. For example, for car-cdr-elim, where we have A as the
; crucial arg (meaning term, above, is (CAR A) or (CDR A)), we wish to
; determine that every A in the clause is equal-hittable, except those
; A's occurring inside the (CAR A) and (CDR A) destructors. Suppose
; the clause is p(A,(CAR A),(CDR A)). The logical explanation of what
; elim does is to replace the A's not in the destructor nests by (CONS
; (CAR A) (CDR A)) and then generalize (CAR A) to HD and (CDR A) to
; TL. This will produce p((CONS HD TL), HD, TL). Observe that we do
; not actually hit the A's inside the CAR and CDR. So we do not
; require that they be equiv-hittable. (This situation actually
; arises in the elim rule for sets, where equiv tests equality on the
; canonicalizations. In this setting, equiv is not a congruence for
; the destructors.) So the question then is how do we detect that all
; the ``naked'' A's are equiv-hittable? We ``ought'' to generalize
; away the instantiated destructor terms and then ask whether all the
; A's are equiv-hittable. But we do not want to pay the price of
; generating n distinct new variable symbols. So we just replace
; every destructor term by NIL. This creates a ``pseudo-clause;'' the
; ``terms'' in it are not really legal -- NIL is not a variable
; symbol. We only use this pseudo-clause to answer the question of
; whether the crucial variable, which certainly isn't NIL, is
; equiv-hittable in every occurrence.
(let* ((alist (pairlis$
(fargs
(access elim-rule rule :destructor-term))
(fargs term)))
(inst-destructors
(sublis-var-lst
alist
(cons (access elim-rule rule :destructor-term)
(access elim-rule rule :destructor-terms))))
(pseudo-clause (sublis-expr-lst
(pairlis$ inst-destructors nil)
clause)))
(cond
((not (every-occurrence-equiv-hittablep-in-clausep
(access elim-rule rule :equiv)
crucial-arg
pseudo-clause ens wrld))
nominations)
((assoc-equal term nominations)
(second-nomination term votes nominations))
((member crucial-arg eliminables)
(cond
((occurs-nowhere-else crucial-arg
(fargs term)
(access elim-rule rule
:crucial-position)
0)
(let* ((inst-hyps
(sublis-var-lst alist
(access elim-rule rule :hyps))))
(cond
((some-hyp-probably-nilp inst-hyps
type-alist ens wrld)
nominations)
(t (first-nomination term votes nominations)))))
(t nominations)))
(t nominations))))
(t (nominate-destructor-candidate crucial-arg
eliminables
type-alist
clause
ens
wrld
(cons term votes)
nominations))))))))))
(mutual-recursion
(defun nominate-destructor-candidates
(term eliminables type-alist clause ens wrld nominations)
; We explore term and accumulate onto nominations all the nominations.
(cond ((variablep term) nominations)
((fquotep term) nominations)
(t (nominate-destructor-candidates-lst
(fargs term)
eliminables
type-alist
clause
ens
wrld
(nominate-destructor-candidate term
eliminables
type-alist
clause
ens
wrld
nil
nominations)))))
(defun nominate-destructor-candidates-lst
(terms eliminables type-alist clause ens wrld nominations)
(cond ((null terms) nominations)
(t (nominate-destructor-candidates-lst
(cdr terms)
eliminables
type-alist
clause
ens
wrld
(nominate-destructor-candidates (car terms)
eliminables
type-alist
clause
ens
wrld
nominations)))))
)
; We next turn to the problem of choosing which candidate we will eliminate.
; We want to eliminate the most complicated one. We measure them with
; max-level-no, which is also used by the defuns principle to store the
; level-no of each fn. Max-level-no was originally defined here, but it is
; mutually recursive with get-level-no, a function we call earlier in the ACL2
; sources, in sort-approved1-rating1.
(defun sum-level-nos (lst wrld)
; Lst is a list of non-variable, non-quotep terms. We sum the
; level-no of the function symbols of the terms. For the level no of
; a lambda expression we use the max level no of its body, just as
; would be done if a non-recursive function with the same body were
; being applied.
(cond ((null lst) 0)
(t (+ (if (flambda-applicationp (car lst))
(max-level-no (lambda-body (ffn-symb (car lst))) wrld)
(or (getpropc (ffn-symb (car lst)) 'level-no
nil wrld)
0))
(sum-level-nos (cdr lst) wrld)))))
(defun pick-highest-sum-level-nos (nominations wrld dterm max-score)
; Nominations is a list of pairs of the form (dterm . votes), where
; votes is a list of terms. The "score" of a dterm is the
; sum-level-nos of its votes. We scan nominations and return a dterm
; with maximal score, assuming that dterm and max-score are the
; winning dterm and its score seen so far.
(cond
((null nominations) dterm)
(t (let ((score (sum-level-nos (cdr (car nominations)) wrld)))
(cond
((> score max-score)
(pick-highest-sum-level-nos (cdr nominations) wrld
(caar nominations) score))
(t
(pick-highest-sum-level-nos (cdr nominations) wrld
dterm max-score)))))))
(defun select-instantiated-elim-rule (clause type-alist eliminables ens wrld)
; Clause is a clause to which we wish to apply destructor elimination.
; Type-alist is the type-alist obtained by assuming all literals of cl nil.
; Eliminables is the list of legal "crucial variables" which can be
; "puffed up" to do an elim. For example, to eliminate (CAR X), X
; must be puffed up to (CONS A B). X is the crucial variable in (CAR
; X). Upon entry to the destructor elimination process we consider
; all the variables eliminable (except the ones historically
; introduced by elim). But once we get going within the elim process,
; the only eliminable variables are the ones we introduce ourselves
; (because they won't be eliminable by subsequent processes since they
; were introduced by elim).
; If there is at least one nomination for an elim, we choose the one
; with maximal score and return an instantiated version of the
; elim-rule corresponding to it. Otherwise we return nil.
(let ((nominations
(nominate-destructor-candidates-lst clause
eliminables
type-alist
clause
ens
wrld
nil)))
(cond
((null nominations) nil)
(t
(let* ((dterm (pick-highest-sum-level-nos nominations wrld nil -1))
(rule (getpropc (ffn-symb dterm) 'eliminate-destructors-rule
nil wrld))
(alist (pairlis$ (fargs (access elim-rule rule :destructor-term))
(fargs dterm))))
(change elim-rule rule
:hyps (sublis-var-lst alist (access elim-rule rule :hyps))
:lhs (sublis-var alist (access elim-rule rule :lhs))
:rhs (sublis-var alist (access elim-rule rule :rhs))
:destructor-term
(sublis-var alist (access elim-rule rule :destructor-term))
:destructor-terms
(sublis-var-lst
alist
(access elim-rule rule :destructor-terms))))))))
; We now take a break from elim and develop the code for the generalization
; that elim uses. We want to be able to replace terms by variables
; (sublis-expr, above), we want to be able to restrict the new variables by
; noting type-sets of the terms replaced, and we want to be able to use
; generalization rules provided in the database.
(defun type-restriction-segment (cl terms vars type-alist ens wrld)
; Warning: This function calls clausify using the sr-limit from the world, not
; from the rewrite-constant. Do not call this function from the simplifier
; without thinking about passing in the sr-limit.
; Cl is a clause. Terms is a list of terms and is in 1:1
; correspondence with vars, which is a list of vars. Type-alist is
; the result of assuming false every literal of cl. This function
; returns three results. The first is a list of literals that can be
; disjoined to cl without altering the validity of cl. The second is
; a subset of vars. The third is an extension of ttree. Technically
; speaking, this function may return any list of terms with the
; property that every term in it is false (under the assumptions in
; type-alist) and any subset of vars, provided the ttree returned is
; an extension of ttree and justifies the falsity of the terms
; returned. The final ttree must be 'assumption-free and is if the
; initial ttree is also.
; As for motivation, we are about to generalize cl by replacing each
; term in terms by the corresponding var in vars. It is sound, of
; course, to restrict the new variable to have whatever properties the
; corresponding term has. This function is responsible for selecting
; the restrictions we want to place on each variable, based on
; type-set reasoning alone. Thus, if t is known to have properties h1
; & ... & hk, then we can include (not h1), ..., (not hk) in our first
; answer to restrict the variable introduced for t. We will include
; the corresponding var in our second answer to indicate that we have
; a type restriction on that variable.
; We do not want our type restrictions to cause the new clause to
; explode into cases. Therefore, we adopt the following heuristic.
; We convert the type set of each term t into a term (hyp t) known to
; be true of t. We negate (hyp t) and clausify the result. If that
; produces a single clause (segment) then that segment is added to our
; answer. Otherwise, we add no restriction. There are probably
; better ways to do this than to call the full-blown
; convert-type-set-to-term and clausify. But this is simple, elegant,
; and lets us take advantage of improvements to those two utilities.
(cond
((null terms) (mv nil nil nil))
(t
(mv-let
(ts ttree1)
(type-set (car terms) nil nil type-alist ens wrld nil nil nil)
(mv-let
(term ttree1)
(convert-type-set-to-term (car terms) ts ens wrld ttree1)
(let ((clauses (clausify (dumb-negate-lit term) nil t
; Notice that we obtain the sr-limit from the world; see Warning above.
(sr-limit wrld))))
(mv-let
(lits restricted-vars ttree)
(type-restriction-segment cl
(cdr terms)
(cdr vars)
type-alist ens wrld)
(cond ((null clauses)
; If the negation of the type restriction term clausifies to the empty set
; of clauses, then the term is nil. Since we get to assume it, we're done.
; But this can only happen if the type-set of the term is empty. We don't think
; this will happen, but we test for it nonetheless, and toss a nil hypothesis
; into our answer literals if it happens.
(mv (add-to-set-equal *nil* lits)
(cons (car vars) restricted-vars)
(cons-tag-trees ttree1 ttree)))
((and (null (cdr clauses))
(not (null (car clauses))))
; If there is only one clause and it is not the empty clause, we'll
; assume everything in it. (If the clausify above produced '(NIL)
; then the type restriction was just *t* and we ignore it.) It is
; possible that the literals we are about to assume are already in cl.
; If so, we are not fooled into thinking we've restricted the new var.
(cond
((subsetp-equal (car clauses) cl)
(mv lits restricted-vars ttree))
(t (mv (disjoin-clauses (car clauses) lits)
(cons (car vars) restricted-vars)
(cons-tag-trees ttree1 ttree)))))
(t
; There may be useful type information we could extract, but we don't.
; It is always sound to exit here, giving ourselves no additional
; assumptions.
(mv lits restricted-vars ttree))))))))))
(mutual-recursion
(defun subterm-one-way-unify (pat term)
; This function searches pat for a non-variable non-quote subterm s such that
; (one-way-unify s term) returns t and a unify-subst. If it finds one, it
; returns t and the unify-subst. Otherwise, it returns two nils.
(cond ((variablep pat) (mv nil nil))
((fquotep pat) (mv nil nil))
(t (mv-let (ans alist)
(one-way-unify pat term)
(cond (ans (mv ans alist))
(t (subterm-one-way-unify-lst (fargs pat) term)))))))
(defun subterm-one-way-unify-lst (pat-lst term)
(cond
((null pat-lst) (mv nil nil))
(t (mv-let (ans alist)
(subterm-one-way-unify (car pat-lst) term)
(cond (ans (mv ans alist))
(t (subterm-one-way-unify-lst (cdr pat-lst) term)))))))
)
; The following is now defined in rewrite.lisp.
; (defrec generalize-rule (nume formula . rune) nil)
(defun apply-generalize-rule (gen-rule term ens)
; Gen-rule is a generalization rule, and hence has a name and a
; formula component. Term is a term which we are intending to
; generalize by replacing it with a new variable. We return two
; results. The first is either t or nil indicating whether gen-rule
; provides a useful restriction on the generalization of term. If the
; first result is nil, so is the second. Otherwise, the second result
; is an instantiation of the formula of gen-rule in which term appears.
; Our heuristic for deciding whether to use gen-rule is: (a) the rule
; must be enabled, (b) term must unify with a non-variable subterm of
; the formula of the rule, (c) the unifying substitution must leave no
; free vars in that formula, and (d) the function symbol of term must
; not occur in the instantiation of the formula except in the
; occurrences of term itself.
(cond
((not (enabled-numep (access generalize-rule gen-rule :nume) ens))
(mv nil nil))
(t (mv-let
(ans unify-subst)
(subterm-one-way-unify (access generalize-rule gen-rule :formula)
term)
(cond
((null ans)
(mv nil nil))
((free-varsp (access generalize-rule gen-rule :formula)
unify-subst)
(mv nil nil))
(t (let ((inst-formula (sublis-var unify-subst
(access generalize-rule
gen-rule
:formula))))
(cond ((ffnnamep (ffn-symb term)
(subst-expr 'x term inst-formula))
(mv nil nil))
(t (mv t inst-formula))))))))))
(defun generalize-rule-segment1 (generalize-rules term ens)
; Given a list of :GENERALIZE rules and a term we return two results:
; the list of instantiated negated formulas of those applicable rules
; and the runes of all applicable rules. The former list is suitable
; for splicing into a clause to add the formulas as hypotheses.
(cond
((null generalize-rules) (mv nil nil))
(t (mv-let (ans formula)
(apply-generalize-rule (car generalize-rules) term ens)
(mv-let (formulas runes)
(generalize-rule-segment1 (cdr generalize-rules)
term ens)
(cond (ans (mv (add-literal (dumb-negate-lit formula)
formulas nil)
(cons (access generalize-rule
(car generalize-rules)
:rune)
runes)))
(t (mv formulas runes))))))))
(defun generalize-rule-segment (terms vars ens wrld)
; Given a list of terms and a list of vars in 1:1 correspondence, we
; return two results. The first is a clause segment containing the
; instantiated negated formulas derived from every applicable
; :GENERALIZE rule for each term in terms. This segment can be spliced
; into a clause to restrict the range of a generalization of terms.
; The second answer is an alist pairing some of the vars in vars to
; the runes of all :GENERALIZE rules in wrld that are applicable to the
; corresponding term in terms. The second answer is of interest only
; to output routines.
(cond
((null terms) (mv nil nil))
(t (mv-let (segment1 runes1)
(generalize-rule-segment1 (global-val 'generalize-rules wrld)
(car terms) ens)
(mv-let (segment2 alist)
(generalize-rule-segment (cdr terms) (cdr vars) ens wrld)
(cond
((null runes1) (mv segment2 alist))
(t (mv (disjoin-clauses segment1 segment2)
(cons (cons (car vars) runes1) alist)))))))))
(defun generalize1 (cl type-alist terms vars ens wrld)
; Cl is a clause. Type-alist is a type-alist obtained by assuming all
; literals of cl false. Terms and vars are lists of terms and
; variables, respectively, in 1:1 correspondence. We assume no var in
; vars occurs in cl. We generalize cl by substituting vars for the
; corresponding terms. We restrict the variables by using type-set
; information about the terms and by using :GENERALIZE rules in wrld.
; We return four results. The first is the new clause. The second
; is a list of the variables for which we added type restrictions.
; The third is an alist pairing some variables with the runes of
; generalization rules used to restrict them. The fourth is a ttree
; justifying our work; it is 'assumption-free.
(mv-let (tr-seg restricted-vars ttree)
(type-restriction-segment cl terms vars type-alist ens wrld)
(mv-let (gr-seg alist)
(generalize-rule-segment terms vars ens wrld)
(mv (sublis-expr-lst (pairlis$ terms vars)
(disjoin-clauses tr-seg
(disjoin-clauses gr-seg
cl)))
restricted-vars
alist
ttree))))
; This completes our brief flirtation with generalization. We now
; have enough machinery to finish coding destructor elimination.
; However, it might be noted that generalize1 is the main subroutine
; of the generalize-clause waterfall processor.
(defun apply-instantiated-elim-rule (rule cl type-alist avoid-vars ens wrld)
; This function takes an instantiated elim-rule, rule, and applies it to a
; clause cl. Avoid-vars is a list of variable names to avoid when we generate
; new ones. See eliminate-destructors-clause for an explanation of that.
; An instantiated :ELIM rule has hyps, lhs, rhs, and destructor-terms, all
; instantiated so that the car of the destructor terms occurs somewhere in the
; clause. To apply such an instantiated :ELIM rule to a clause we assume the
; hyps (adding their negations to cl), we generalize away the destructor terms
; occurring in the clause and in the lhs of the rule, and then we substitute
; that generalized lhs for the rhs into the generalized cl to obtain the final
; clause. The generalization step above may involve adding additional
; hypotheses to the clause and using generalization rules in wrld.
; We return three things. The first is the clause described above, which
; implies cl when the hyps of the rule are known to be true, the second is the
; set of elim variables we have just introduced into it, and the third is a
; list describing this application of the rune of the rule, as explained below.
; The list returned as the third value will become an element in the
; 'elim-sequence list in the ttree of the history entry for this elimination
; process. The "elim-sequence element" we return has the form:
; (rune rhs lhs alist restricted-vars var-to-runes-alist ttree)
; and means "use rune to replace rhs by lhs, generalizing as specified by alist
; (which maps destructors to variables), restricting the restricted-vars
; variables by type (as justified by ttree) and restricting the
; var-to-runes-alist variables by the named generalize rules." The ttree is
; 'assumption-free.
(let* ((rune (access elim-rule rule :rune))
(hyps (access elim-rule rule :hyps))
(lhs (access elim-rule rule :lhs))
(rhs (access elim-rule rule :rhs))
(dests (access elim-rule rule :destructor-terms))
(negated-hyps (dumb-negate-lit-lst hyps)))
(mv-let
(contradictionp type-alist0 ttree0)
(type-alist-clause negated-hyps nil nil type-alist ens wrld
nil nil)
; Before Version_2.9.3, we just punted when contradictionp is true here, and
; this led to infinite loops reported by Sol Swords and then (shortly
; thereafter) Doug Harper, who both sent examples. Our initial fix was to punt
; without going into the infinite loop, but then we implemented the current
; scheme in which we simply perform the elimination without generating clauses
; for the impossible "pathological" cases corresponding to falsity of each of
; the instantiated :elim rule's hypotheses. Both fixes avoid the infinite loop
; in both examples. We kept the present fix because at the time it actually
; proved the latter example (shown here) without induction:
; (include-book "ihs/@logops" :dir :system)
; (thm (implies (integerp (* 1/2 n)) (equal (mod n 2) 0)))
; However, the fix was buggy. When we fixed those bugs after Version_3.6.1,
; the thm above no longer proved; but we still avoided the infinite loop. That
; loop is easily seen in the following example sent by Eric Smith, which proved
; from Versions 2.9.3 through 3.6.1 by exploiting that bug and looped in
; Versions before 2.9.3:
; (defthmd true-listp-of-cdr
; (implies (true-listp (cdr x))
; (true-listp x))
; :hints (("Goal" :in-theory (disable true-listp))))
(let* ((type-alist (if contradictionp type-alist type-alist0))
(cl-with-hyps (disjoin-clauses negated-hyps cl))
(elim-vars (generate-variable-lst dests
(all-vars1-lst cl-with-hyps
avoid-vars)
type-alist ens wrld))
(alist (pairlis$ dests elim-vars))
(generalized-lhs (sublis-expr alist lhs)))
(cond
(contradictionp
; The negation of the clause implies that the type-alist holds, and thus one of
; the negated-hyps holds. Then since contradictionp is true, the conjunction
; of the hyps implies the clause. That is, *true-clause* implies cl when the
; hyps of the rule are known to be true.
(mv *true-clause*
nil ; actual-elim-vars
(list rune rhs
generalized-lhs
alist
nil ; restricted-vars
nil ; var-to-runes-alist
ttree0)))
(t
(let* ((cl-with-hyps (disjoin-clauses negated-hyps cl))
(elim-vars (generate-variable-lst dests
(all-vars1-lst cl-with-hyps
avoid-vars)
type-alist ens wrld)))
(mv-let (generalized-cl-with-hyps
restricted-vars
var-to-runes-alist
ttree)
(generalize1 cl-with-hyps type-alist dests elim-vars ens wrld)
(let* ((final-cl
(subst-var-lst generalized-lhs
rhs
generalized-cl-with-hyps))
(actual-elim-vars
(intersection-eq elim-vars
(all-vars1-lst final-cl nil))))
(mv final-cl
actual-elim-vars
(list rune rhs generalized-lhs alist
restricted-vars
var-to-runes-alist
(cons-tag-trees ttree0 ttree))))))))))))
(defun eliminate-destructors-clause1 (cl eliminables avoid-vars ens wrld