/usr/share/acl2-7.2dfsg/prove.lisp is in acl2-source 7.2dfsg-3.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
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9222 9223 9224 9225 9226 9227 9228 9229 9230 9231 9232 9233 9234 9235 9236 9237 9238 9239 9240 9241 9242 9243 9244 9245 9246 9247 9248 9249 9250 9251 9252 9253 9254 9255 9256 9257 9258 9259 9260 9261 9262 9263 9264 9265 9266 9267 9268 9269 9270 9271 9272 9273 9274 9275 9276 9277 9278 9279 9280 9281 9282 9283 9284 9285 9286 9287 9288 9289 9290 9291 9292 9293 9294 9295 9296 9297 9298 9299 9300 9301 9302 9303 9304 9305 9306 9307 9308 9309 9310 9311 9312 9313 9314 9315 9316 9317 9318 9319 9320 9321 9322 9323 9324 | ; ACL2 Version 7.2 -- A Computational Logic for Applicative Common Lisp
; Copyright (C) 2016, 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: Kaufmann@cs.utexas.edu and Moore@cs.utexas.edu
; Department of Computer Science
; University of Texas at Austin
; Austin, TX 78712 U.S.A.
(in-package "ACL2")
; Section: PREPROCESS-CLAUSE
; The preprocessor is the first clause processor in the waterfall when
; we enter from prove. It contains a simple term rewriter that expands
; certain "abbreviations" and a gentle clausifier.
; We first develop the simple rewriter, called expand-abbreviations.
; Rockwell Addition: We are now concerned with lambdas, where we
; didn't used to treat them differently. This extra argument will
; show up in several places during a compare-windows.
(mutual-recursion
(defun abbreviationp1 (lambda-flg vars term2)
; This function returns t if term2 is not an abbreviation of term1
; (where vars is the bag of vars in term1). Otherwise, it returns the
; excess vars of vars. If lambda-flg is t we look out for lambdas and
; do not consider something an abbreviation if we see a lambda in it.
; If lambda-flg is nil, we treat lambdas as though they were function
; symbols.
(cond ((variablep term2)
(cond ((null vars) t) (t (cdr vars))))
((fquotep term2) vars)
((and lambda-flg
(flambda-applicationp term2))
t)
((member-eq (ffn-symb term2) '(if not implies)) t)
(t (abbreviationp1-lst lambda-flg vars (fargs term2)))))
(defun abbreviationp1-lst (lambda-flg vars lst)
(cond ((null lst) vars)
(t (let ((vars1 (abbreviationp1 lambda-flg vars (car lst))))
(cond ((eq vars1 t) t)
(t (abbreviationp1-lst lambda-flg vars1 (cdr lst))))))))
)
(defun abbreviationp (lambda-flg vars term2)
; Consider the :REWRITE rule generated from (equal term1 term2). We
; say such a rule is an "abbreviation" if term2 contains no more
; variable occurrences than term1 and term2 does not call the
; functions IF, NOT or IMPLIES or (if lambda-flg is t) any LAMBDA.
; Vars, above, is the bag of vars from term1. We return non-nil iff
; (equal term1 term2) is an abbreviation.
(not (eq (abbreviationp1 lambda-flg vars term2) t)))
(mutual-recursion
(defun all-vars-bag (term ans)
(cond ((variablep term) (cons term ans))
((fquotep term) ans)
(t (all-vars-bag-lst (fargs term) ans))))
(defun all-vars-bag-lst (lst ans)
(cond ((null lst) ans)
(t (all-vars-bag-lst (cdr lst)
(all-vars-bag (car lst) ans)))))
)
(defun find-abbreviation-lemma (term geneqv lemmas ens wrld)
; Term is a function application, geneqv is a generated equivalence
; relation and lemmas is the 'lemmas property of the function symbol
; of term. We find the first (enabled) abbreviation lemma that
; rewrites term maintaining geneqv. A lemma is an abbreviation if it
; is not a meta-lemma, has no hypotheses, has no loop-stopper, and has
; an abbreviationp for the conclusion.
; If we win we return t, the rune of the :CONGRUENCE rule used, the
; lemma, and the unify-subst. Otherwise we return four nils.
(cond ((null lemmas) (mv nil nil nil nil))
((and (enabled-numep (access rewrite-rule (car lemmas) :nume) ens)
(eq (access rewrite-rule (car lemmas) :subclass) 'abbreviation)
(geneqv-refinementp (access rewrite-rule (car lemmas) :equiv)
geneqv
wrld))
(mv-let
(wonp unify-subst)
(one-way-unify (access rewrite-rule (car lemmas) :lhs) term)
(cond (wonp (mv t
(geneqv-refinementp
(access rewrite-rule (car lemmas) :equiv)
geneqv
wrld)
(car lemmas)
unify-subst))
(t (find-abbreviation-lemma term geneqv (cdr lemmas)
ens wrld)))))
(t (find-abbreviation-lemma term geneqv (cdr lemmas)
ens wrld))))
(mutual-recursion
(defun expand-abbreviations-with-lemma (term geneqv pequiv-info
fns-to-be-ignored-by-rewrite
rdepth step-limit ens wrld state
ttree)
(mv-let
(wonp cr-rune lemma unify-subst)
(find-abbreviation-lemma term geneqv
(getpropc (ffn-symb term) 'lemmas nil wrld)
ens
wrld)
(cond
(wonp
(with-accumulated-persistence
(access rewrite-rule lemma :rune)
((the (signed-byte 30) step-limit) term ttree)
t
(expand-abbreviations
(access rewrite-rule lemma :rhs)
unify-subst
geneqv
pequiv-info
fns-to-be-ignored-by-rewrite
(adjust-rdepth rdepth) step-limit ens wrld state
(push-lemma cr-rune
(push-lemma (access rewrite-rule lemma :rune)
ttree)))))
(t (mv step-limit term ttree)))))
(defun expand-abbreviations (term alist geneqv pequiv-info
fns-to-be-ignored-by-rewrite
rdepth step-limit ens wrld state ttree)
; This function is essentially like rewrite but is more restrictive in its use
; of rules. We rewrite term/alist maintaining geneqv and pequiv-info, avoiding
; the expansion or application of lemmas to terms whose fns are in
; fns-to-be-ignored-by-rewrite. We return a new term and a ttree (accumulated
; onto our argument) describing the rewrite. We only apply "abbreviations"
; which means we expand lambda applications and non-rec fns provided they do
; not duplicate arguments or introduce IFs, etc. (see abbreviationp), and we
; apply those unconditional :REWRITE rules with the same property.
; It used to be written:
; Note: In a break with Nqthm and the first four versions of ACL2, in
; Version 1.5 we also expand IMPLIES terms here. In fact, we expand
; several members of *expandable-boot-strap-non-rec-fns* here, and
; IFF. The impetus for this decision was the forcing of impossible
; goals by simplify-clause. As of this writing, we have just added
; the idea of forcing rounds and the concommitant notion that forced
; hypotheses are proved under the type-alist extant at the time of the
; force. But if the simplifer sees IMPLIES terms and rewrites their
; arguments, it does not augment the context, e.g., in (IMPLIES hyps
; concl) concl is rewritten without assuming hyps and thus assumptions
; forced in concl are context free and often impossible to prove. Now
; while the user might hide propositional structure in other functions
; and thus still suffer this failure mode, IMPLIES is the most common
; one and by opening it now we make our context clearer. See the note
; below for the reason we expand other
; *expandable-boot-strap-non-rec-fns*.
; This is no longer true. We now expand the IMPLIES from the original theorem
; in preprocess-clause before expand-abbreviations is called, and do not expand
; any others here. These changes in the handling of IMPLIES (as well as
; several others) are caused by the introduction of assume-true-false-if. See
; the mini-essay at assume-true-false-if.
(cond
((zero-depthp rdepth)
(rdepth-error
(mv step-limit term ttree)
t))
((time-limit5-reached-p ; nil, or throws
"Out of time in preprocess (expand-abbreviations).")
(mv step-limit nil nil))
(t
(let ((step-limit (decrement-step-limit step-limit)))
(cond
((variablep term)
(let ((temp (assoc-eq term alist)))
(cond (temp (mv step-limit (cdr temp) ttree))
(t (mv step-limit term ttree)))))
((fquotep term) (mv step-limit term ttree))
((and (eq (ffn-symb term) 'return-last)
; We avoid special treatment for return-last when the first argument is progn,
; since the user may have intended the first argument to be rewritten in that
; case; for example, the user might want to see a message printed when the term
; (prog2$ (cw ...) ...) is encountered. But it is useful in the other cases,
; in particular for calls of return-last generated by calls of mbe, to avoid
; spending time simplifying the next-to-last argument.
(not (equal (fargn term 1) ''progn)))
(expand-abbreviations (fargn term 3)
alist geneqv pequiv-info
fns-to-be-ignored-by-rewrite rdepth
step-limit ens wrld state
(push-lemma
(fn-rune-nume 'return-last nil nil wrld)
ttree)))
((eq (ffn-symb term) 'hide)
(mv step-limit
(sublis-var alist term)
ttree))
(t
(mv-let
(deep-pequiv-lst shallow-pequiv-lst)
(pequivs-for-rewrite-args (ffn-symb term) geneqv pequiv-info wrld ens)
(sl-let
(expanded-args ttree)
(expand-abbreviations-lst (fargs term)
alist
1 nil deep-pequiv-lst shallow-pequiv-lst
geneqv (ffn-symb term)
(geneqv-lst (ffn-symb term) geneqv ens wrld)
fns-to-be-ignored-by-rewrite
(adjust-rdepth rdepth) step-limit
ens wrld state ttree)
(let* ((fn (ffn-symb term))
(term (cons-term fn expanded-args)))
; If term does not collapse to a constant, fn is still its ffn-symb.
(cond
((fquotep term)
; Term collapsed to a constant. But it wasn't a constant before, and so
; it collapsed because cons-term executed fn on constants. So we record
; a use of the executable counterpart.
(mv step-limit
term
(push-lemma (fn-rune-nume fn nil t wrld) ttree)))
((member-equal fn fns-to-be-ignored-by-rewrite)
(mv step-limit (cons-term fn expanded-args) ttree))
((and (all-quoteps expanded-args)
(enabled-xfnp fn ens wrld)
(or (flambda-applicationp term)
(not (getpropc fn 'constrainedp nil wrld))))
(cond ((flambda-applicationp term)
(expand-abbreviations
(lambda-body fn)
(pairlis$ (lambda-formals fn) expanded-args)
geneqv pequiv-info
fns-to-be-ignored-by-rewrite
(adjust-rdepth rdepth) step-limit ens wrld state ttree))
((programp fn wrld)
; Why is the above test here? We do not allow :program mode fns in theorems.
; However, the prover can be called during definitions, and in particular we
; wind up with the call (SYMBOL-BTREEP NIL) when trying to admit the following
; definition.
; (defun symbol-btreep (x)
; (if x
; (and (true-listp x)
; (symbolp (car x))
; (symbol-btreep (caddr x))
; (symbol-btreep (cdddr x)))
; t))
(mv step-limit (cons-term fn expanded-args) ttree))
(t
(mv-let
(erp val latches)
(pstk
(ev-fncall fn (strip-cadrs expanded-args) state nil t
nil))
(declare (ignore latches))
(cond
(erp
; We following a suggestion from Matt Wilding and attempt to simplify the term
; before applying HIDE.
(let ((new-term1 (cons-term fn expanded-args)))
(sl-let (new-term2 ttree)
(expand-abbreviations-with-lemma
new-term1 geneqv pequiv-info
fns-to-be-ignored-by-rewrite
rdepth step-limit ens wrld state ttree)
(cond
((equal new-term2 new-term1)
(mv step-limit
(mcons-term* 'hide new-term1)
(push-lemma (fn-rune-nume 'hide nil nil wrld)
ttree)))
(t (mv step-limit new-term2 ttree))))))
(t (mv step-limit
(kwote val)
(push-lemma (fn-rune-nume fn nil t wrld)
ttree))))))))
((flambdap fn)
(cond ((abbreviationp nil
(lambda-formals fn)
(lambda-body fn))
(expand-abbreviations
(lambda-body fn)
(pairlis$ (lambda-formals fn) expanded-args)
geneqv pequiv-info
fns-to-be-ignored-by-rewrite
(adjust-rdepth rdepth) step-limit ens wrld state ttree))
(t
; Once upon a time (well into v1-9) we just returned (mv term ttree)
; here. But then Jun Sawada pointed out some problems with his proofs
; of some theorems of the form (let (...) (implies (and ...) ...)).
; The problem was that the implies was not getting expanded (because
; the let turns into a lambda and the implication in the body is not
; an abbreviationp, as checked above). So we decided that, in such
; cases, we would actually expand the abbreviations in the body
; without expanding the lambda itself, as we do below. This in turn
; often allows the lambda to expand via the following mechanism.
; Preprocess-clause calls expand-abbreviations and it expands the
; implies into IFs in the body without opening the lambda. But then
; preprocess-clause calls clausify-input which does another
; expand-abbreviations and this time the expansion is allowed. We do
; not imagine that this change will adversely affect proofs, but if
; so, well, the old code is shown on the first line of this comment.
(sl-let (body ttree)
(expand-abbreviations
(lambda-body fn)
nil
geneqv
nil ; pequiv-info
fns-to-be-ignored-by-rewrite
(adjust-rdepth rdepth) step-limit ens wrld state
ttree)
; Rockwell Addition:
; Once upon another time (through v2-5) we returned the fcons-term
; shown in the t clause below. But Rockwell proofs indicate that it
; is better to eagerly expand this lambda if the new body would make
; it an abbreviation.
(cond
((abbreviationp nil
(lambda-formals fn)
body)
(expand-abbreviations
body
(pairlis$ (lambda-formals fn) expanded-args)
geneqv pequiv-info
fns-to-be-ignored-by-rewrite
(adjust-rdepth rdepth) step-limit ens wrld state
ttree))
(t
(mv step-limit
(mcons-term (list 'lambda (lambda-formals fn)
body)
expanded-args)
ttree)))))))
((member-eq fn '(iff synp mv-list return-last wormhole-eval force
case-split double-rewrite))
; The list above is an arbitrary subset of *expandable-boot-strap-non-rec-fns*.
; Once upon a time we used the entire list here, but Bishop Brock complained
; that he did not want EQL opened. So we have limited the list to just the
; propositional function IFF and the no-ops.
; Note: Once upon a time we did not expand any propositional functions
; here. Indeed, one might wonder why we do now? The only place
; expand-abbreviations was called was from within preprocess-clause.
; And there, its output was run through clausify-input and then
; remove-trivial-clauses. The latter called tautologyp on each clause
; and that, in turn, expanded all the functions above (but discarded
; the expansion except for purposes of determining tautologyhood).
; Thus, there is no real case to make against expanding these guys.
; For sanity, one might wish to keep the list above in sync with
; that in tautologyp, where we say about it: "The list is in fact
; *expandable-boot-strap-non-rec-fns* with NOT deleted and IFF added.
; The main idea here is to include non-rec functions that users
; typically put into the elegant statements of theorems." But now we
; have deleted IMPLIES from this list, to support the assume-true-false-if
; idea, but we still keep IMPLIES in the list for tautologyp because
; if we can decide it's a tautology by expanding, all the better.
(with-accumulated-persistence
(fn-rune-nume fn nil nil wrld)
((the (signed-byte 30) step-limit) term ttree)
t
(expand-abbreviations (body fn t wrld)
(pairlis$ (formals fn wrld) expanded-args)
geneqv pequiv-info
fns-to-be-ignored-by-rewrite
(adjust-rdepth rdepth)
step-limit ens wrld state
(push-lemma (fn-rune-nume fn nil nil wrld)
ttree))))
; Rockwell Addition: We are expanding abbreviations. This is new treatment
; of IF, which didn't used to receive any special notice.
((eq fn 'if)
; There are no abbreviation (or rewrite) rules hung on IF, so coming out
; here is ok.
(let ((a (car expanded-args))
(b (cadr expanded-args))
(c (caddr expanded-args)))
(cond
((equal b c) (mv step-limit b ttree))
((quotep a)
(mv step-limit
(if (eq (cadr a) nil) c b)
ttree))
((and (equal geneqv *geneqv-iff*)
(equal b *t*)
(or (equal c *nil*)
(ffn-symb-p c 'HARD-ERROR)))
; Some users keep HARD-ERROR disabled so that they can figure out
; which guard proof case they are in. HARD-ERROR is identically nil
; and we would really like to eliminate the IF here. So we use our
; knowledge that HARD-ERROR is nil even if it is disabled. We don't
; even put it in the ttree, because for all the user knows this is
; primitive type inference.
(mv step-limit a ttree))
(t (mv step-limit
(mcons-term 'if expanded-args)
ttree)))))
; Rockwell Addition: New treatment of equal.
((and (eq fn 'equal)
(equal (car expanded-args) (cadr expanded-args)))
(mv step-limit *t* ttree))
(t
(expand-abbreviations-with-lemma
term geneqv pequiv-info
fns-to-be-ignored-by-rewrite rdepth step-limit ens
wrld state ttree))))))))))))
(defun expand-abbreviations-lst (lst alist bkptr rewritten-args-rev
deep-pequiv-lst shallow-pequiv-lst
parent-geneqv parent-fn geneqv-lst
fns-to-be-ignored-by-rewrite rdepth
step-limit ens wrld state ttree)
(cond
((null lst) (mv step-limit (reverse rewritten-args-rev) ttree))
(t (mv-let
(child-geneqv child-pequiv-info)
(geneqv-and-pequiv-info-for-rewrite
parent-fn bkptr rewritten-args-rev lst alist
parent-geneqv
(car geneqv-lst)
deep-pequiv-lst
shallow-pequiv-lst
wrld)
(sl-let (term1 new-ttree)
(expand-abbreviations (car lst) alist
child-geneqv child-pequiv-info
fns-to-be-ignored-by-rewrite
rdepth step-limit ens wrld state ttree)
(expand-abbreviations-lst (cdr lst) alist
(1+ bkptr)
(cons term1 rewritten-args-rev)
deep-pequiv-lst shallow-pequiv-lst
parent-geneqv parent-fn
(cdr geneqv-lst)
fns-to-be-ignored-by-rewrite
rdepth step-limit ens wrld
state new-ttree))))))
)
(defun and-orp (term bool)
; We return t or nil according to whether term is a disjunction
; (if bool is t) or conjunction (if bool is nil).
(case-match term
(('if & c2 c3)
(if bool
(or (equal c2 *t*) (equal c3 *t*))
(or (equal c2 *nil*) (equal c3 *nil*))))))
(defun find-and-or-lemma (term bool lemmas ens wrld)
; Term is a function application and lemmas is the 'lemmas property of
; the function symbol of term. We find the first enabled and-or
; (wrt bool) lemma that rewrites term maintaining iff.
; If we win we return t, the :CONGRUENCE rule name, the lemma, and the
; unify-subst. Otherwise we return four nils.
(cond ((null lemmas) (mv nil nil nil nil))
((and (enabled-numep (access rewrite-rule (car lemmas) :nume) ens)
(or (eq (access rewrite-rule (car lemmas) :subclass) 'backchain)
(eq (access rewrite-rule (car lemmas) :subclass) 'abbreviation))
(null (access rewrite-rule (car lemmas) :hyps))
(null (access rewrite-rule (car lemmas) :heuristic-info))
(geneqv-refinementp (access rewrite-rule (car lemmas) :equiv)
*geneqv-iff*
wrld)
(and-orp (access rewrite-rule (car lemmas) :rhs) bool))
(mv-let
(wonp unify-subst)
(one-way-unify (access rewrite-rule (car lemmas) :lhs) term)
(cond (wonp (mv t
(geneqv-refinementp
(access rewrite-rule (car lemmas) :equiv)
*geneqv-iff*
wrld)
(car lemmas)
unify-subst))
(t (find-and-or-lemma term bool (cdr lemmas) ens wrld)))))
(t (find-and-or-lemma term bool (cdr lemmas) ens wrld))))
(defun expand-and-or (term bool fns-to-be-ignored-by-rewrite ens wrld state
ttree step-limit)
; We expand the top-level fn symbol of term provided the expansion produces a
; conjunction -- when bool is nil -- or a disjunction -- when bool is t. We
; return four values: the new step-limit, wonp, the new term, and a new ttree.
; This fn is a No-Change Loser.
; Note that preprocess-clause calls expand-abbreviations; but also
; preprocess-clause calls clausify-input, which calls expand-and-or, which
; calls expand-abbreviations. But this is not redundant, as expand-and-or
; calls expand-abbreviations after expanding function definitions and using
; rewrite rules when the result is a conjunction or disjunction (depending on
; bool) -- even when the rule being applied is not an abbreviation rule. Below
; are event sequences that illustrate this extra work being done. In both
; cases, evaluation of (getpropc 'foo 'lemmas) shows that we are expanding with
; a rewrite-rule structure that is not of subclass 'abbreviation.
; (defstub bar (x) t)
; (defun foo (x) (and (bar (car x)) (bar (cdr x))))
; (trace$ expand-and-or expand-abbreviations clausify-input preprocess-clause)
; (thm (foo x) :hints (("Goal" :do-not-induct :otf)))
; (defstub bar (x) t)
; (defstub foo (x) t)
; (defaxiom foo-open (equal (foo x) (and (bar (car x)) (bar (cdr x)))))
; (trace$ expand-and-or expand-abbreviations clausify-input preprocess-clause)
; (thm (foo x) :hints (("Goal" :do-not-induct :otf)))
(cond ((variablep term) (mv step-limit nil term ttree))
((fquotep term) (mv step-limit nil term ttree))
((member-equal (ffn-symb term) fns-to-be-ignored-by-rewrite)
(mv step-limit nil term ttree))
((flambda-applicationp term)
(cond ((and-orp (lambda-body (ffn-symb term)) bool)
(sl-let
(term ttree)
(expand-abbreviations
(subcor-var (lambda-formals (ffn-symb term))
(fargs term)
(lambda-body (ffn-symb term)))
nil
*geneqv-iff*
nil
fns-to-be-ignored-by-rewrite
(rewrite-stack-limit wrld) step-limit ens wrld state ttree)
(mv step-limit t term ttree)))
(t (mv step-limit nil term ttree))))
(t
(let ((def-body (def-body (ffn-symb term) wrld)))
(cond
((and def-body
(null (access def-body def-body :recursivep))
(null (access def-body def-body :hyp))
(enabled-numep (access def-body def-body :nume)
ens)
(and-orp (access def-body def-body :concl)
bool))
(sl-let
(term ttree)
(with-accumulated-persistence
(access def-body def-body :rune)
((the (signed-byte 30) step-limit) term ttree)
t
(expand-abbreviations
(subcor-var (access def-body def-body
:formals)
(fargs term)
(access def-body def-body :concl))
nil
*geneqv-iff*
nil
fns-to-be-ignored-by-rewrite
(rewrite-stack-limit wrld)
step-limit ens wrld state
(push-lemma? (access def-body def-body :rune)
ttree)))
(mv step-limit t term ttree)))
(t (mv-let
(wonp cr-rune lemma unify-subst)
(find-and-or-lemma
term bool
(getpropc (ffn-symb term) 'lemmas nil wrld)
ens wrld)
(cond
(wonp
(sl-let
(term ttree)
(with-accumulated-persistence
(access rewrite-rule lemma :rune)
((the (signed-byte 30) step-limit) term ttree)
t
(expand-abbreviations
(sublis-var unify-subst
(access rewrite-rule lemma :rhs))
nil
*geneqv-iff*
nil
fns-to-be-ignored-by-rewrite
(rewrite-stack-limit wrld)
step-limit ens wrld state
(push-lemma cr-rune
(push-lemma (access rewrite-rule lemma
:rune)
ttree))))
(mv step-limit t term ttree)))
(t (mv step-limit nil term ttree))))))))))
(defun clausify-input1 (term bool fns-to-be-ignored-by-rewrite ens wrld state
ttree step-limit)
; We return three things: a new step-limit, a clause, and a ttree. If bool is
; t, the (disjunction of the literals in the) clause is equivalent to term. If
; bool is nil, the clause is equivalent to the negation of term. This function
; opens up some nonrec fns and applies some rewrite rules. The final ttree
; contains the symbols and rules used.
(cond
((equal term (if bool *nil* *t*)) (mv step-limit nil ttree))
((ffn-symb-p term 'if)
(let ((t1 (fargn term 1))
(t2 (fargn term 2))
(t3 (fargn term 3)))
(cond
(bool
(cond
((equal t3 *t*)
(sl-let (cl1 ttree)
(clausify-input1 t1 nil
fns-to-be-ignored-by-rewrite
ens wrld state ttree step-limit)
(sl-let (cl2 ttree)
(clausify-input1 t2 t
fns-to-be-ignored-by-rewrite
ens wrld state ttree step-limit)
(mv step-limit (disjoin-clauses cl1 cl2) ttree))))
((equal t2 *t*)
(sl-let (cl1 ttree)
(clausify-input1 t1 t
fns-to-be-ignored-by-rewrite
ens wrld state ttree step-limit)
(sl-let (cl2 ttree)
(clausify-input1 t3 t
fns-to-be-ignored-by-rewrite
ens wrld state ttree step-limit)
(mv step-limit (disjoin-clauses cl1 cl2) ttree))))
(t (mv step-limit (list term) ttree))))
((equal t3 *nil*)
(sl-let (cl1 ttree)
(clausify-input1 t1 nil
fns-to-be-ignored-by-rewrite
ens wrld state ttree step-limit)
(sl-let (cl2 ttree)
(clausify-input1 t2 nil
fns-to-be-ignored-by-rewrite
ens wrld state ttree step-limit)
(mv step-limit (disjoin-clauses cl1 cl2) ttree))))
((equal t2 *nil*)
(sl-let (cl1 ttree)
(clausify-input1 t1 t
fns-to-be-ignored-by-rewrite
ens wrld state ttree step-limit)
(sl-let (cl2 ttree)
(clausify-input1 t3 nil
fns-to-be-ignored-by-rewrite
ens wrld state ttree step-limit)
(mv step-limit (disjoin-clauses cl1 cl2) ttree))))
(t (mv step-limit (list (dumb-negate-lit term)) ttree)))))
(t (sl-let (wonp term ttree)
(expand-and-or term bool fns-to-be-ignored-by-rewrite
ens wrld state ttree step-limit)
(cond (wonp
(clausify-input1 term bool fns-to-be-ignored-by-rewrite
ens wrld state ttree step-limit))
(bool (mv step-limit (list term) ttree))
(t (mv step-limit
(list (dumb-negate-lit term))
ttree)))))))
(defun clausify-input1-lst (lst fns-to-be-ignored-by-rewrite ens wrld state
ttree step-limit)
; This function is really a subroutine of clausify-input. It just
; applies clausify-input1 to every element of lst, accumulating the ttrees.
; It uses bool=t.
(cond ((null lst) (mv step-limit nil ttree))
(t (sl-let (clause ttree)
(clausify-input1 (car lst) t fns-to-be-ignored-by-rewrite
ens wrld state ttree step-limit)
(sl-let (clauses ttree)
(clausify-input1-lst (cdr lst)
fns-to-be-ignored-by-rewrite
ens wrld state ttree
step-limit)
(mv step-limit
(conjoin-clause-to-clause-set clause clauses)
ttree))))))
(defun clausify-input (term fns-to-be-ignored-by-rewrite ens wrld state ttree
step-limit)
; This function converts term to a set of clauses, expanding some non-rec
; functions when they produce results of the desired parity (i.e., we expand
; AND-like functions in the hypotheses and OR-like functions in the
; conclusion.) AND and OR themselves are, of course, already expanded into
; IFs, but we will expand other functions when they generate the desired IF
; structure. We also apply :REWRITE rules deemed appropriate. We return three
; results: a new step-limit, the set of clauses, and a ttree documenting the
; expansions.
(sl-let (neg-clause ttree)
(clausify-input1 term nil fns-to-be-ignored-by-rewrite ens
wrld state ttree step-limit)
; Neg-clause is a clause that is equivalent to the negation of term. That is,
; if the literals of neg-clause are lit1, ..., litn, then (or lit1 ... litn)
; <-> (not term). Therefore, term is the negation of the clause, i.e., (and
; (not lit1) ... (not litn)). We will form a clause from each (not lit1) and
; return the set of clauses, implicitly conjoined.
(clausify-input1-lst (dumb-negate-lit-lst neg-clause)
fns-to-be-ignored-by-rewrite
ens wrld state ttree step-limit)))
(defun expand-some-non-rec-fns-in-clauses (fns clauses wrld)
; Warning: fns should be a subset of functions that
; This function expands the non-rec fns listed in fns in each of the clauses
; in clauses. It then throws out of the set any trivial clause, i.e.,
; tautologies. It does not normalize the expanded terms but just leaves
; the expanded bodies in situ. See the comment in preprocess-clause.
(cond
((null clauses) nil)
(t (let ((cl (expand-some-non-rec-fns-lst fns (car clauses) wrld)))
(cond
((trivial-clause-p cl wrld)
(expand-some-non-rec-fns-in-clauses fns (cdr clauses) wrld))
(t (cons cl
(expand-some-non-rec-fns-in-clauses fns (cdr clauses)
wrld))))))))
(defun no-op-histp (hist)
; We say a history, hist, is a "no-op history" if it is empty or its most
; recent entry is a to-be-hidden preprocess-clause or apply-top-hints-clause
; (possibly followed by a settled-down-clause).
(or (null hist)
(and hist
(member-eq (access history-entry (car hist) :processor)
'(apply-top-hints-clause preprocess-clause))
(tag-tree-occur 'hidden-clause
t
(access history-entry (car hist) :ttree)))
(and hist
(eq (access history-entry (car hist) :processor)
'settled-down-clause)
(cdr hist)
(member-eq (access history-entry (cadr hist) :processor)
'(apply-top-hints-clause preprocess-clause))
(tag-tree-occur 'hidden-clause
t
(access history-entry (cadr hist) :ttree)))))
(mutual-recursion
; This pair of functions is copied from expand-abbreviations and
; heavily modified. The idea implemented by the caller of this
; function is to expand all the IMPLIES terms in the final literal of
; the goal clause. This pair of functions actually implements that
; expansion. One might think to use expand-some-non-rec-fns with
; first argument '(IMPLIES). But this function is different in two
; respects. First, it respects HIDE. Second, it expands the IMPLIES
; inside of lambda bodies. The basic idea is to mimic what
; expand-abbreviations used to do, before we added the
; assume-true-false-if idea.
(defun expand-any-final-implies1 (term wrld)
(cond
((variablep term)
term)
((fquotep term)
term)
((eq (ffn-symb term) 'hide)
term)
(t
(let ((expanded-args (expand-any-final-implies1-lst (fargs term)
wrld)))
(let* ((fn (ffn-symb term))
(term (cons-term fn expanded-args)))
(cond ((flambdap fn)
(let ((body (expand-any-final-implies1 (lambda-body fn)
wrld)))
; Note: We could use a make-lambda-application here, but if the
; original lambda used all of its variables then so does the new one,
; because IMPLIES uses all of its variables and we're not doing any
; simplification. This remark is not soundness related; there is no
; danger of introducing new variables, only the inefficiency of
; keeping a big actual which is actually not used.
(fcons-term (make-lambda (lambda-formals fn) body)
expanded-args)))
((eq fn 'IMPLIES)
(subcor-var (formals 'implies wrld)
expanded-args
(body 'implies t wrld)))
(t term)))))))
(defun expand-any-final-implies1-lst (term-lst wrld)
(cond ((null term-lst)
nil)
(t
(cons (expand-any-final-implies1 (car term-lst) wrld)
(expand-any-final-implies1-lst (cdr term-lst) wrld)))))
)
(defun expand-any-final-implies (cl wrld)
; Cl is a clause (a list of ACL2 terms representing a goal) about to
; enter preprocessing. If the final term contains an 'IMPLIES, we
; expand those IMPLIES here. This change in the handling of IMPLIES
; (as well as several others) is caused by the introduction of
; assume-true-false-if. See the mini-essay at assume-true-false-if.
; Note that we fail to report the fact that we used the definition
; of IMPLIES.
; Note also that we do not use expand-some-non-rec-fns here. We want
; to preserve the meaning of 'HIDE and expand an 'IMPLIES inside of
; a lambda.
(cond ((null cl) ; This should not happen.
nil)
((null (cdr cl))
(list (expand-any-final-implies1 (car cl) wrld)))
(t
(cons (car cl)
(expand-any-final-implies (cdr cl) wrld)))))
(defun rw-cache-state (wrld)
(let ((pair (assoc-eq t (table-alist 'rw-cache-state-table wrld))))
(cond (pair (cdr pair))
(t *default-rw-cache-state*))))
(defmacro make-rcnst (ens wrld state &rest args)
; (Make-rcnst ens w state) will make a rewrite-constant that is the result of
; filling in *empty-rewrite-constant* with a few obviously necessary values,
; such as the global-enabled-structure as the :current-enabled-structure. Then
; it additionally loads user supplied values specified by alternating
; keyword/value pairs to override what is otherwise created. E.g.,
; (make-rcnst ens w state :expand-lst lst)
; will make a rewrite-constant that is like the default one except that it will
; have lst as the :expand-lst.
; Note: Wrld and ens are used in the "default" setting of certain fields.
; Warning: wrld could be evaluated several times. So it should be an
; inexpensive expression, such as a variable or (w state).
`(change rewrite-constant
(change rewrite-constant
*empty-rewrite-constant*
:current-enabled-structure ,ens
:oncep-override (match-free-override ,wrld)
:case-split-limitations (case-split-limitations ,wrld)
:forbidden-fns (forbidden-fns ,wrld ,state)
:nonlinearp (non-linearp ,wrld)
:backchain-limit-rw (backchain-limit ,wrld :rewrite)
:rw-cache-state (rw-cache-state ,wrld))
,@args))
; We now finish the development of tau-clause... To recap our story so far: In
; the file tau.lisp we defined everything we need to implement tau-clause
; except for its connection to type-alist and the linear pot-lst. Now we can
; define tau-clause.
(defun cheap-type-alist-and-pot-lst (cl ens wrld state)
; Given a clause cl, we build a type-alist and linear pot-lst with all of the
; literals in cl assumed false. The pot-lst is built with the cheap-linearp
; flag on, which means we do not rewrite terms before turning them into polys
; and we add no linear lemmas. We insure that the type-alist has no
; assumptions or forced hypotheses. FYI: Just to be doubly sure that we are
; not ignoring assumptions and forced hypotheses, you will note that in
; relieve-dependent-hyps, after calling type-set, we check that no such entries
; are in the returned ttree. We return (mv contradictionp type-alist pot-lst)
(mv-let (contradictionp type-alist ttree)
(type-alist-clause cl nil nil nil ens wrld nil nil)
(cond
((or (tagged-objectsp 'assumption ttree)
(tagged-objectsp 'fc-derivation ttree))
(mv (er hard 'cheap-type-alist-and-pot-lst
"Assumptions and/or fc-derivations were found in the ~
ttree constructed by CHEAP-TYPE-ALIST-AND-POT-LST. This ~
is supposedly impossible!")
nil nil))
(contradictionp
(mv t nil nil))
(t (mv-let (new-step-limit provedp pot-lst)
(setup-simplify-clause-pot-lst1
cl nil type-alist
(make-rcnst ens wrld state
:force-info 'weak
:cheap-linearp t)
wrld state *default-step-limit*)
(declare (ignore new-step-limit))
(cond
(provedp
(mv t nil nil))
(t (mv nil type-alist pot-lst))))))))
(defconst *tau-ttree*
(add-to-tag-tree 'lemma
'(:executable-counterpart tau-system)
nil))
(defun tau-clausep (clause ens wrld state calist)
; This function returns (mv flg ttree), where if flg is t then clause is true.
; The ttree, when non-nil, is just the *tau-ttree*.
; If the executable-counterpart of tau is disabled, this function is a no-op.
(cond
((enabled-numep *tau-system-xnume* ens)
(mv-let
(contradictionp type-alist pot-lst)
(cheap-type-alist-and-pot-lst clause ens wrld state)
(cond
(contradictionp
(mv t *tau-ttree* calist))
(t
(let ((triples (merge-sort-car-<
(annotate-clause-with-key-numbers clause
(len clause)
0 wrld))))
(mv-let
(flg calist)
(tau-clause1p triples nil type-alist pot-lst
ens wrld calist)
(cond
((eq flg t)
(mv t *tau-ttree* calist))
(t (mv nil nil calist)))))))))
(t (mv nil nil calist))))
(defun tau-clausep-lst-rec (clauses ens wrld ans ttree state calist)
; We return (mv clauses' ttree) where clauses' are provably equivalent to
; clauses under the tau rules and ttree is either the tau ttree or nil
; depending on whether anything changed. Note that this function knows that if
; tau-clause returns non-nil ttree it is *tau-ttree*: we just OR the ttrees
; together, not CONS-TAG-TREES them!
(cond
((endp clauses)
(mv (revappend ans nil) ttree calist))
(t (mv-let
(flg1 ttree1 calist)
(tau-clausep (car clauses) ens wrld state calist)
(prog2$
; If the time-tracker call below is changed, update :doc time-tracker
; accordingly.
(time-tracker :tau :print?)
(tau-clausep-lst-rec (cdr clauses) ens wrld
(if flg1
ans
(cons (car clauses) ans))
(or ttree1 ttree)
state calist))))))
(defun tau-clausep-lst (clauses ens wrld ans ttree state calist)
; If the time-tracker calls below are changed, update :doc time-tracker
; accordingly.
(prog2$ (time-tracker :tau :start!)
(mv-let
(clauses ttree calist)
(tau-clausep-lst-rec clauses ens wrld ans ttree state calist)
(prog2$ (time-tracker :tau :stop)
(mv clauses ttree calist)))))
(defun prettyify-clause-simple (cl)
; This variant of prettyify-clause does not call untranslate.
(cond ((null cl) nil)
((null (cdr cl)) cl)
((null (cddr cl))
(fcons-term* 'implies
(dumb-negate-lit (car cl))
(cadr cl)))
(t (fcons-term* 'implies
(conjoin (dumb-negate-lit-lst (butlast cl 1)))
(car (last cl))))))
(defun preprocess-clause (cl hist pspv wrld state step-limit)
; This is the first "real" clause processor (after a little remembered
; apply-top-hints-clause) in the waterfall. Its arguments and values are the
; standard ones, except that it takes a step-limit and returns a new step-limit
; in the first position. We expand abbreviations and clausify the clause cl.
; For mainly historic reasons, expand-abbreviations and clausify-input operate
; on terms. Thus, our first move is to convert cl into a term.
(let ((rcnst (access prove-spec-var pspv :rewrite-constant)))
(mv-let
(built-in-clausep ttree)
(cond
((or (eq (car (car hist)) 'simplify-clause)
(eq (car (car hist)) 'settled-down-clause))
; If the hist shows that cl has just come from simplification, there is no
; need to check that it is built in, because the simplifier does that.
(mv nil nil))
(t
(built-in-clausep 'preprocess-clause
cl
(access rewrite-constant
rcnst
:current-enabled-structure)
(access rewrite-constant
rcnst
:oncep-override)
wrld
state)))
; Ttree is known to be 'assumption free.
(cond
(built-in-clausep
(mv step-limit 'hit nil ttree pspv))
(t
; Here is where we expand the "original" IMPLIES in the conclusion but
; leave any IMPLIES in the hypotheses. These IMPLIES are thought to
; have been introduced by :USE hints.
(let ((term (disjoin (expand-any-final-implies cl wrld))))
(sl-let (term ttree)
(expand-abbreviations term nil
*geneqv-iff* nil
(access rewrite-constant
rcnst
:fns-to-be-ignored-by-rewrite)
(rewrite-stack-limit wrld)
step-limit
(access rewrite-constant
rcnst
:current-enabled-structure)
wrld state nil)
(sl-let (clauses ttree)
(clausify-input term
(access rewrite-constant
rcnst
:fns-to-be-ignored-by-rewrite)
(access rewrite-constant
rcnst
:current-enabled-structure)
wrld
state
ttree
step-limit)
;;; (let ((clauses
;;; (expand-some-non-rec-fns-in-clauses
;;; '(iff implies)
;;; clauses
;;; wrld)))
; Previous to Version_2.6 we had written:
; ; Note: Once upon a time (in Version 1.5) we called "clausify-clause-set" here.
; ; That function called clausify on each element of clauses and unioned the
; ; results together, in the process naturally deleting tautologies as does
; ; expand-some-non-rec-fns-in-clauses above. But Version 1.5 caused Bishop a
; ; lot of pain because many theorems would explode into case analyses, each of
; ; which was then dispatched by simplification. The reason we used a full-blown
; ; clausify in Version 1.5 was that in was also into that version that we
; ; introduced forcing rounds and the liberal use of force-flg = t. But if we
; ; are to force that way, we must really get all of our hypotheses out into the
; ; open so that they can contribute to the type-alist stored in each assumption.
; ; For example, in Version 1.4 the concl of (IMPLIES hyps concl) was rewritten
; ; first without the hyps being manifest in the type-alist since IMPLIES is a
; ; function. Not until the IMPLIES was opened did the hyps become "governers"
; ; in this sense. In Version 1.5 we decided to throw caution to the wind and
; ; just clausify the clausified input. Well, it bit us as mentioned above and
; ; we are now backing off to simply expanding the non-rec fns that might
; ; contribute hyps. But we leave the expansions in place rather than normalize
; ; them out so that simplification has one shot on a small set (usually
; ; singleton set) of clauses.
; But the comment above is now irrelevant to the current situation.
; Before commenting on the current situation, however, we point out that
; in (admittedly light) testing the original call to
; expand-some-non-rec-fns-in-clauses in its original context acted as
; the identity. This seems reasonable because 'iff and 'implies were
; expanded in expand-abbreviations.
; We now expand the 'implies from the original theorem (but not the
; implies from a :use hint) in the call to expand-any-final-implies.
; This performs the expansion whose motivations are mentioned in the
; old comments above, but does not interfere with the conclusions
; of a :use hint. See the mini-essay
; Mini-Essay on Assume-true-false-if and Implies
; or
; How Strengthening One Part of a Theorem Prover Can Weaken the Whole.
; in type-set-b for more details on this latter criterion.
(let ((tau-completion-alist
(access prove-spec-var pspv :tau-completion-alist)))
(mv-let
(clauses1 ttree1 new-tau-completion-alist)
(if (or (null hist)
; If (null (cdr hist)) and (null (cddr hist)) are tested in this disjunction,
; then tau is tried during the first three simplifications and then again when
; the clause settles down. Call this the ``more aggressive'' approach. If
; they are not tested, tau is tried only on the first simplification and upon
; settling down. Call this ``less aggressive.'' There are, of course, proofs
; where the more aggressive use of tau speeds things up. But of course it
; slows down many more proofs. Overall, experiments on the regression suggest
; that the more aggressive approach slows total reported book certification
; time down by about 1.5% compared to the less agressive approach. However, we
; think it might be worth it as more tau-based proofs scripts are developed.
(null (cdr hist))
(null (cddr hist))
(eq (car (car hist)) 'settled-down-clause))
(let ((ens (access rewrite-constant
rcnst
:current-enabled-structure)))
(if (enabled-numep *tau-system-xnume* ens)
(tau-clausep-lst clauses
ens
wrld
nil
nil
state
tau-completion-alist)
(mv clauses nil tau-completion-alist)))
(mv clauses nil tau-completion-alist))
(let ((pspv (if (equal tau-completion-alist
new-tau-completion-alist)
pspv
(change prove-spec-var pspv
:tau-completion-alist
new-tau-completion-alist))))
(cond
((equal clauses1 (list cl))
; In this case, preprocess-clause has made no changes to the clause.
(mv step-limit 'miss nil nil nil))
((and (consp clauses1)
(null (cdr clauses1))
(no-op-histp hist)
(equal (prettyify-clause-simple
(car clauses1))
(access prove-spec-var pspv
:user-supplied-term)))
; In this case preprocess-clause has produced a singleton set of clauses whose
; only element is the translated user input. For example, the user might have
; invoked defthm on (implies p q) and preprocess has managed to to produce the
; singleton set of clauses containing {(not p) q}. This is a valuable step in
; the proof of course. However, users complain when we report that (IMPLIES P
; Q) -- the displayed goal -- is reduced to (IMPLIES P Q) -- the
; prettyification of the output.
; We therefore take special steps to hide this transformation from the
; user without changing the flow of control through the waterfall. In
; particular, we will insert into the ttree the tag
; 'hidden-clause with (irrelevant) value t. In subsequent places
; where we print explanations and clauses to the user we will look for
; this tag.
; At one point we called prettify-clause below instead of
; prettify-clause-simple, and compared the (untranslated) result to the
; (untranslated) displayed-goal of the pspv. But we have decided to avoid the
; expense of untranslating, especially since often the potentially-confusing
; printing will never take place! Let's elaborate. Suppose that the input
; user-level term t1 translates to termp tt1, and suppose that the result of
; preprocessing the clause set (list (list tt1)) is a single clause for which
; prettify-clause-simple returns the (translated) term tt1. Then we are in
; this case and we set 'hidden-clause in the returned ttree. However, suppose
; that instead prettyify-clause-simple returns tt2 not equal to tt1, although
; tt2 nevertheless untranslates (perhaps surprisingly) to t1. Then we are not
; in this case, and Goal' will print exactly as goal. This is unfortunate, but
; we have seen (back in 2003!) that kind of invisible transformation happen for
; other than Goal:
; Subgoal 3
; (IMPLIES (AND (< I -1)
; (ACL2-NUMBERP J)
; ...)
; ...)
;
; By case analysis we reduce the conjecture to
;
; Subgoal 3'
; (IMPLIES (AND (< I -1)
; (ACL2-NUMBERP J)
; ...)
; ...)
; As of this writing we do not handle this sort of situation, not even -- after
; Version_7.0, when we started using prettyify-clause-simple to avoid the cost
; of untranslation, instead of prettyify-clause -- for the case considered
; here, transitioning from Goal to Goal' by preprocess-clause. Perhaps we will
; do such a check for all preprocess-clause transformations, but only when
; actually printing output (so as to avoid the overhead of untranslation).
(mv step-limit
'hit
clauses1
(add-to-tag-tree
'hidden-clause t
(cons-tag-trees ttree1 ttree))
pspv))
(t (mv step-limit
'hit
clauses1
(cons-tag-trees ttree1 ttree)
pspv))))))))))))))
; And here is the function that reports on a successful preprocessing.
(defun tilde-*-preprocess-phrase (ttree)
; This function is like tilde-*-simp-phrase but knows that ttree was
; constructed by preprocess-clause and hence is based on abbreviation
; expansion rather than full-fledged rewriting.
; Warning: The function apply-top-hints-clause-msg1 knows
; that if the (car (cddddr &)) of the result is nil then nothing but
; case analysis was done!
(mv-let (message-lst char-alist)
(tilde-*-simp-phrase1
(extract-and-classify-lemmas ttree '(implies not iff) nil)
; Note: The third argument to extract-and-classify-lemmas is the list
; of forced runes, which we assume to be nil in preprocessing. If
; this changes, see the comment in fertilize-clause-msg1.
t)
(list* "case analysis"
"~@*"
"~@* and "
"~@*, "
message-lst
char-alist)))
(defun tilde-*-raw-preprocess-phrase (ttree punct)
; See tilde-*-preprocess-phrase. Here we print for a non-nil value of state
; global 'raw-proof-format.
(let ((runes (all-runes-in-ttree ttree nil)))
(mv-let (message-lst char-alist)
(tilde-*-raw-simp-phrase1
runes
nil ; forced-runes
punct
'(implies not iff) ; ignore-lst
"" ; phrase
nil)
(list* (concatenate 'string "case analysis"
(case punct
(#\, ",")
(#\. ".")
(otherwise "")))
"~@*"
"~@* and "
"~@*, "
message-lst
char-alist))))
(defun preprocess-clause-msg1 (signal clauses ttree pspv state)
; This function is one of the waterfall-msg subroutines. It has the
; standard arguments of all such functions: the signal, clauses, ttree
; and pspv produced by the given processor, in this case
; preprocess-clause. It produces the report for this step.
(declare (ignore signal pspv))
(let ((raw-proof-format (f-get-global 'raw-proof-format state)))
(cond ((tag-tree-occur 'hidden-clause t ttree)
; If this preprocess clause is to be hidden, e.g., because it transforms
; (IMPLIES P Q) to {(NOT P) Q}, we print no message. Note that this is
; just part of the hiding. Later in the waterfall, when some other processor
; has successfully hit our output, that output will be printed and we
; need to stop that printing too.
state)
((and raw-proof-format
(null clauses))
(fms "But preprocess reduces the conjecture to T, by ~*0~|"
(list (cons #\0 (tilde-*-raw-preprocess-phrase ttree #\.)))
(proofs-co state)
state
(term-evisc-tuple nil state)))
((null clauses)
(fms "But we reduce the conjecture to T, by ~*0.~|"
(list (cons #\0 (tilde-*-preprocess-phrase ttree)))
(proofs-co state)
state
(term-evisc-tuple nil state)))
(raw-proof-format
(fms "Preprocess reduces the conjecture to ~#1~[~x2~/the ~
following~/the following ~n3 conjectures~], by ~*0~|"
(list (cons #\0 (tilde-*-raw-preprocess-phrase ttree #\.))
(cons #\1 (zero-one-or-more clauses))
(cons #\2 t)
(cons #\3 (length clauses)))
(proofs-co state)
state
(term-evisc-tuple nil state)))
(t
(fms "By ~*0 we reduce the conjecture to~#1~[~x2.~/~/ the ~
following ~n3 conjectures.~]~|"
(list (cons #\0 (tilde-*-preprocess-phrase ttree))
(cons #\1 (zero-one-or-more clauses))
(cons #\2 t)
(cons #\3 (length clauses)))
(proofs-co state)
state
(term-evisc-tuple nil state))))))
; Section: PUSH-CLAUSE and The Pool
; At the opposite end of the waterfall from the preprocessor is push-clause,
; where we actually put a clause into the pool. We develop it now.
(defun more-than-simplifiedp (hist)
; Return t if hist contains a process besides simplify-clause (and its
; mates settled-down-clause and preprocess-clause), where we don't count
; certain top-level hints: :OR, or top-level hints that create hidden clauses.
(cond ((null hist) nil)
((member-eq (caar hist) '(settled-down-clause
simplify-clause
preprocess-clause))
(more-than-simplifiedp (cdr hist)))
((eq (caar hist) 'apply-top-hints-clause)
(if (or (tagged-objectsp 'hidden-clause
(access history-entry (car hist) :ttree))
(tagged-objectsp ':or
(access history-entry (car hist) :ttree)))
(more-than-simplifiedp (cdr hist))
t))
(t t)))
(defun delete-assoc-eq-lst (lst alist)
(declare (xargs :guard (if (symbol-listp lst)
(alistp alist)
(symbol-alistp alist))))
(if (consp lst)
(delete-assoc-eq-lst (cdr lst)
(delete-assoc-eq (car lst) alist))
alist))
(defun delete-assumptions-1 (recs only-immediatep)
; See comment for delete-assumptions. This function returns (mv changedp
; new-recs), where if changedp is nil then new-recs equals recs.
(cond ((endp recs) (mv nil nil))
(t (mv-let (changedp new-cdr-recs)
(delete-assumptions-1 (cdr recs) only-immediatep)
(cond ((cond
((eq only-immediatep 'non-nil)
(access assumption (car recs) :immediatep))
((eq only-immediatep 'case-split)
(eq (access assumption (car recs) :immediatep)
'case-split))
((eq only-immediatep t)
(eq (access assumption (car recs) :immediatep)
t))
(t t))
(mv t new-cdr-recs))
(changedp
(mv t
(cons (car recs) new-cdr-recs)))
(t (mv nil recs)))))))
(defun delete-assumptions (ttree only-immediatep)
; We delete the assumptions in ttree. We give the same interpretation to
; only-immediatep as in collect-assumptions.
(let ((objects (tagged-objects 'assumption ttree)))
(cond (objects
(mv-let
(changedp new-objects)
(delete-assumptions-1 objects only-immediatep)
(cond ((null changedp) ttree)
(new-objects
(extend-tag-tree
'assumption
new-objects
(remove-tag-from-tag-tree! 'assumption ttree)))
(t (remove-tag-from-tag-tree! 'assumption ttree)))))
(t ttree))))
#+acl2-par
(defun save-and-print-acl2p-checkpoint (cl-id prettyified-clause
old-pspv-pool-lst forcing-round
state)
; We almost note that we are changing the global state of the program by
; returning a modified state. However, we manually ensure that this global
; change is thread-safe by calling with-acl2p-checkpoint-saving-lock, and so
; instead, we give ourselves the Okay to call f-put-global@par.
(declare (ignorable cl-id prettyified-clause state))
(let* ((new-pair (cons cl-id prettyified-clause))
(newp
(with-acl2p-checkpoint-saving-lock
(cond
((member-equal new-pair (f-get-global 'acl2p-checkpoints-for-summary
state))
nil)
(t
(prog2$
(f-put-global@par 'acl2p-checkpoints-for-summary
(cons new-pair
(f-get-global
'acl2p-checkpoints-for-summary state))
state)
t))))))
(and
newp
(with-output-lock
(progn$
(cw "~%~%([ An ACL2(p) key checkpoint:~%~%~s0~%"
(string-for-tilde-@-clause-id-phrase cl-id))
(cw "~x0" prettyified-clause)
; Parallelism no-fix: we are encountering a problem that we've known about from
; within the first few months of looking at parallelizing the waterfall. When
; two sibling subgoals both push for induction, the second push doesn't know
; about the first proof's push in parallel mode. So, the number of the second
; proof (e.g., *1.2) gets printed as if the first push hasn't happened (e.g.,
; *1.2 gets mistakenly called *1.1). Rather than fix this (the problem is
; inherent to the naming scheme of ACL2), we punt and say what the name _could_
; be (e.g., we print *1.1 for what's really *1.2). The following non-theorem
; showcases this problem. See :doc topic set-waterfall-printing.
; (thm (equal (append (car (cons x x)) y z) (append x x y)))
; The sentence in the following cw call concerning the halting of the proof
; attempt is motivated by the following example -- which is relevant because
; ACL2(p) with :limited waterfall-printing does not print a message that says
; the :do-not-induct hint causes the proof to abort.
; (thm (equal (append x (append y z)) (append (append x y) z))
; :hints (("Goal" :do-not-induct t)))
(cw "~%~%The above subgoal may cause a goal to be pushed for proof by ~
induction. The pushed goal's new name might be ~@0. Note that ~
we may instead decide (either now or later) to prove the original ~
conjecture by induction. Also note that if a hint indicates that ~
this subgoal or the original conjecture should not be proved by ~
induction, the proof attempt will halt.~%~%])~%~%"
(tilde-@-pool-name-phrase
forcing-round
old-pspv-pool-lst)))))))
#+acl2-par
(defun find-the-first-checkpoint (h checkpoint-processors)
; "H" is the history reversed, which really means h is in the order that the
; entries were added. E.g. the history entry for subgoal 1.2 is before the
; entry for 1.1.4. To remind us that this is not the "standard ACL2 history"
; (which is often in the other order), we name the variable "h" instead of
; "hist."
(cond ((atom h) ; occurs when we are at the top-level goal
nil)
((atom (cdr h))
(car h)) ; maybe this should also be an error
((member (access history-entry (cadr h) :processor)
checkpoint-processors)
(car h))
; Parallelism blemish: we haven't thought through how specious entries affect
; this function. The following code is left as a hint at what might be needed.
; ((or (and (consp (access history-entry (cadr h) :processor))
; (equal (access history-entry (cadr h) :processor)
; 'specious))
(t (find-the-first-checkpoint (cdr h) checkpoint-processors))))
#+acl2-par
(defun acl2p-push-clause-printing (cl hist pspv wrld state)
(cond
((null cl)
; The following non-theorem illustrates the case where we generate the clause
; nil, and instead of printing the associated key checkpoint, we inform the
; user that nil was generated from that checkpoint.
; (thm (equal (append (car (cons x x)) y z) (append x x y)))
(cw "~%~%A goal of ~x0 has been generated! Obviously, the proof attempt ~
has failed.~%"
cl))
(t
(let* ((hist-entry
(find-the-first-checkpoint
(reverse hist)
(f-get-global 'checkpoint-processors state)))
(checkpoint-clause
(or (access history-entry hist-entry :clause)
; We should be able to add an assertion that, if the hist-entry is nil (and
; thus, the :clause field of hist-entry is also nil), cl always has the same
; printed representation as the original conjecture. However, since we do not
; have access to the original conjecture in this function, we avoid such an
; assertion.
cl))
(cl-id (access history-entry hist-entry :cl-id))
(cl-id (if cl-id cl-id *initial-clause-id*))
(forcing-round (access clause-id cl-id :forcing-round))
(old-pspv-pool-lst
(pool-lst (cdr (access prove-spec-var pspv :pool))))
(prettyified-clause (prettyify-clause checkpoint-clause
(let*-abstractionp state)
wrld)))
(save-and-print-acl2p-checkpoint cl-id prettyified-clause
old-pspv-pool-lst forcing-round
state)))))
(defun@par push-clause (cl hist pspv wrld state)
; Roughly speaking, we drop cl into the pool of pspv and return.
; However, we sometimes cause the waterfall to abort further
; processing (either to go straight to induction or to fail) and we
; also sometimes choose to push a different clause into the pool. We
; even sometimes miss and let the waterfall fall off the end of the
; ledge! We make this precise in the code below.
; The pool is actually a list of pool-elements and is treated as a
; stack. The clause-set is a set of clauses and is almost always a
; singleton set. The exception is when it contains the clausification
; of the user's initial conjecture.
; The expected tags are:
; 'TO-BE-PROVED-BY-INDUCTION - the clause set is to be given to INDUCT
; 'BEING-PROVED-BY-INDUCTION - the clause set has been given to INDUCT and
; we are working on its subgoals now.
; Like all clause processors, we return four values: the signal,
; which is either 'hit, 'miss or 'abort, the new set of clauses, in this
; case nil, the ttree for whatever action we take, and the new
; value of pspv (containing the new pool).
; Warning: Generally speaking, this function either 'HITs or 'ABORTs.
; But it is here that we look out for :DO-NOT-INDUCT name hints. For
; such hints we want to act like a :BY name-clause-id was present for
; the clause. But we don't know the clause-id and the :BY handling is
; so complicated we don't want to reproduce it. So what we do instead
; is 'MISS and let the waterfall fall off the ledge to the nil ledge.
; See waterfall0. This function should NEVER return a 'MISS unless
; there is a :DO-NOT-INDUCT name hint present in the hint-settings,
; since waterfall0 assumes that it falls off the ledge only in that
; case.
(declare (ignorable state wrld)) ; actually ignored in #-acl2-par
(prog2$
; Every branch of the cond below, with the exception of when cl is null,
; results in an ACL2(p) key checkpoint. As such, it is reasonable to print the
; checkpoint at the very beginning of this function.
; Acl2p-push-clause-printing contains code that handles the case where cl is
; nil.
; Parallelism blemish: create a :doc topic on ACL2(p) checkpoints and reference
; it in the above comment.
(parallel-only@par (acl2p-push-clause-printing cl hist pspv wrld state))
(let ((pool (access prove-spec-var pspv :pool))
(do-not-induct-hint-val
(cdr (assoc-eq :do-not-induct
(access prove-spec-var pspv :hint-settings)))))
(cond
((null cl)
; The empty clause was produced. Stop the waterfall by aborting. Produce the
; ttree that explains the abort. Drop the clause set containing the empty
; clause into the pool so that when we look for the next goal we see it and
; quit.
(mv 'abort
nil
(add-to-tag-tree! 'abort-cause 'empty-clause nil)
(change prove-spec-var pspv
:pool (cons (make pool-element
:tag 'TO-BE-PROVED-BY-INDUCTION
:clause-set '(nil)
:hint-settings nil)
pool))))
((and (or (and (not (access prove-spec-var pspv :otf-flg))
(eq do-not-induct-hint-val t))
(eq do-not-induct-hint-val :otf-flg-override))
(not (assoc-eq :induct (access prove-spec-var pspv
:hint-settings))))
; We need induction but can't use it. Stop the waterfall by aborting. Produce
; the ttree that expains the abort. Drop the clause set containing the empty
; clause into the pool so that when we look for the next goal we see it and
; quit. Note that if :otf-flg is specified, then we skip this case because we
; do not want to quit just yet. We will see the :do-not-induct value again in
; prove-loop1 when we return to the goal we are pushing.
(mv 'abort
nil
(add-to-tag-tree! 'abort-cause
(if (eq do-not-induct-hint-val :otf-flg-override)
'do-not-induct-otf-flg-override
'do-not-induct)
nil)
(change prove-spec-var pspv
:pool (cons (make pool-element
:tag 'TO-BE-PROVED-BY-INDUCTION
:clause-set '(nil)
:hint-settings nil)
pool))))
((and do-not-induct-hint-val
(not (member-eq do-not-induct-hint-val '(t :otf :otf-flg-override)))
(not (assoc-eq :induct
(access prove-spec-var pspv :hint-settings))))
; In this case, we have seen a :DO-NOT-INDUCT name hint (where name isn't t)
; that is not overridden by an :INDUCT hint. We would like to give this clause
; a :BY. We can't do it here, as explained above. So we will 'MISS instead.
(mv 'miss nil nil nil))
((and (not (access prove-spec-var pspv :otf-flg))
(not (eq do-not-induct-hint-val :otf))
(or
(and (null pool) ;(a)
(more-than-simplifiedp hist)
(not (assoc-eq :induct (access prove-spec-var pspv
:hint-settings))))
(and pool ;(b)
(not (assoc-eq 'being-proved-by-induction pool))
(not (assoc-eq :induct (access prove-spec-var pspv
:hint-settings))))))
; We have not been told to press Onward Thru the Fog and
; either (a) this is the first time we've ever pushed anything and we have
; applied processes other than simplification to it and we have not been
; explicitly instructed to induct for this formula, or (b) we have already put
; at least one goal into the pool but we have not yet done our first induction
; and we are not being explicitly instructed to induct for this formula.
; Stop the waterfall by aborting. Produce the ttree explaining the abort.
; Drop the clausification of the user's input into the pool in place of
; everything else in the pool.
; Note: We once reverted to the output of preprocess-clause in prove. However,
; preprocess (and clausify-input) applies unconditional :REWRITE rules and we
; want users to be able to type exactly what the system should go into
; induction on. The theorem that preprocess-clause screwed us on was HACK1.
; It screwed us by distributing * and GCD.
(mv 'abort
nil
(add-to-tag-tree! 'abort-cause 'revert nil)
(change prove-spec-var pspv
; Before Version_2.6 we did not modify the tag-tree here. The result was that
; assumptions created by forcing before reverting to the original goal still
; generated forcing rounds after the subsequent proof by induction. When this
; bug was discovered we added code below to use delete-assumptions to remove
; assumptions from the tag-tree. Note that we are not modifying the
; 'accumulated-ttree in state, so these assumptions still reside there; but
; since that ttree is only used for reporting rules used and is intended to
; reflect the entire proof attempt, this decision seems reasonable.
; Version_2.6 was released on November 29, 2001. On January 18, 2002, we
; received email from Francisco J. Martin-Mateos reporting a soundness bug,
; with an example that is included after the definition of push-clause. The
; problem turned out to be that we did not remove :use and :by tagged values
; from the tag-tree here. The result was that if the early part of a
; successful proof attempt had involved a :use or :by hint but then the early
; part was thrown away and we reverted to the original goal, the :use or :by
; tagged value remained in the tag-tree. When the proof ultimately succeeded,
; this tagged value was used to update (global-val
; 'proved-functional-instances-alist (w state)), which records proved
; constraints so that subsequent proofs can avoid proving them again. But
; because the prover reverted to the original goal rather than taking advantage
; of the :use hint, those constraints were not actually proved in this case and
; might not be valid!
; So, we have decided that rather than remove assumptions and :by/:use tags
; from the :tag-tree of pspv, we would just replace that tag-tree by the empty
; tag-tree. We do not want to get burned by a third such problem!
:tag-tree nil
:pool (list (make pool-element
:tag 'TO-BE-PROVED-BY-INDUCTION
:clause-set
; At one time we clausified here. But some experiments suggested that the
; prover can perhaps do better by simply doing its thing on each induction
; goal, starting at the top of the waterfall. So, now we pass the same clause
; to induction as it would get if there were a hint of the form ("Goal" :induct
; term), where term is the user-supplied-term.
(list (list
(access prove-spec-var pspv
:user-supplied-term)))
; Below we set the :hint-settings for the input clause, doing exactly what
; find-applicable-hint-settings does. Unfortunately, we haven't defined that
; function yet. Fortunately, it's just a simple assoc-equal. In addition,
; that function goes on to compute a second value we don't need here. So
; rather than go to the bother of moving its definition up to here we just open
; code the part we need. We also remove top-level hints that were supposed to
; apply before we got to push-clause.
:hint-settings
(delete-assoc-eq-lst
(cons ':reorder *top-hint-keywords*)
; We could also delete :induct, but we know it's not here!
(cdr
(assoc-equal
*initial-clause-id*
(access prove-spec-var pspv
:orig-hints)))))))))
#+acl2-par
((and (serial-first-form-parallel-second-form@par nil t)
(not (access prove-spec-var pspv :otf-flg))
(not (eq do-not-induct-hint-val :otf))
(null pool)
;; (not (more-than-simplifiedp hist)) ; implicit to the cond
(not (assoc-eq :induct (access prove-spec-var pspv
:hint-settings))))
(mv 'hit
nil
(add-to-tag-tree! 'abort-cause 'maybe-revert nil)
(change prove-spec-var pspv
; Parallelism blemish: there may be a bug in ACL2(p) related to the comment
; above (in this function's definition) that starts with "Before Version_2.6 we
; did not modify the tag-tree here." To fix this (likely) bug, don't reset the
; tag-tree here -- just remove the ":tag-tree nil" -- and instead do it when we
; convert a maybe-to-be-proved-by-induction to a to-be-proved-by-induction.
:tag-tree nil
:pool
(append
(list
(list 'maybe-to-be-proved-by-induction
(make pool-element
:tag 'TO-BE-PROVED-BY-INDUCTION
:clause-set (list cl)
:hint-settings (access prove-spec-var pspv
:hint-settings))
(make pool-element
:tag 'TO-BE-PROVED-BY-INDUCTION
:clause-set
; See above comment that starts with "At one time we clausified here."
(list (list
(access prove-spec-var pspv
:user-supplied-term)))
; See above comment that starts with "Below we set the :hint-settings for..."
:hint-settings
(delete-assoc-eq-lst
(cons ':reorder *top-hint-keywords*)
; We could also delete :induct, but we know it's not here!
(cdr
(assoc-equal
*initial-clause-id*
(access prove-spec-var pspv
:orig-hints)))))))
pool))))
(t (mv 'hit
nil
nil
(change prove-spec-var pspv
:pool
(cons
(make pool-element
:tag 'TO-BE-PROVED-BY-INDUCTION
:clause-set (list cl)
:hint-settings (access prove-spec-var pspv
:hint-settings))
pool))))))))
; Below is the soundness bug example reported by Francisco J. Martin-Mateos.
; ;;;============================================================================
;
; ;;;
; ;;; A bug in ACL2 (2.5 and 2.6). Proving "0=1".
; ;;; Francisco J. Martin-Mateos
; ;;; email: Francisco-Jesus.Martin@cs.us.es
; ;;; Dpt. of Computer Science and Artificial Intelligence
; ;;; University of SEVILLE
; ;;;
; ;;;============================================================================
;
; ;;; I've found a bug in ACL2 (2.5 and 2.6). The following events prove that
; ;;; "0=1".
;
; (in-package "ACL2")
;
; (encapsulate
; (((g1) => *))
;
; (local
; (defun g1 ()
; 0))
;
; (defthm 0=g1
; (equal 0 (g1))
; :rule-classes nil))
;
; (defun g1-lst (lst)
; (cond ((endp lst) (g1))
; (t (g1-lst (cdr lst)))))
;
; (defthm g1-lst=g1
; (equal (g1-lst lst) (g1)))
;
; (encapsulate
; (((f1) => *))
;
; (local
; (defun f1 ()
; 1)))
;
; (defun f1-lst (lst)
; (cond ((endp lst) (f1))
; (t (f1-lst (cdr lst)))))
;
; (defthm f1-lst=f1
; (equal (f1-lst lst) (f1))
; :hints (("Goal"
; :use (:functional-instance g1-lst=g1
; (g1 f1)
; (g1-lst f1-lst)))))
;
; (defthm 0=f1
; (equal 0 (f1))
; :rule-classes nil
; :hints (("Goal"
; :use (:functional-instance 0=g1
; (g1 f1)))))
;
; (defthm 0=1
; (equal 0 1)
; :rule-classes nil
; :hints (("Goal"
; :use (:functional-instance 0=f1
; (f1 (lambda () 1))))))
;
; ;;; The theorem F1-LST=F1 is not proved via functional instantiation but it
; ;;; can be proved via induction. So, the constraints generated by the
; ;;; functional instantiation hint has not been proved. But when the theorem
; ;;; 0=F1 is considered, the constraints generated in the functional
; ;;; instantiation hint are bypassed because they ".. have been proved when
; ;;; processing the event F1-LST=F1", and the theorem is proved !!!. Finally,
; ;;; an instance of 0=F1 can be used to prove 0=1.
;
; ;;;============================================================================
; We now develop the functions for reporting what push-clause did. Except,
; pool-lst has already been defined, in support of proof-trees.
(defun push-clause-msg1-abort (cl-id ttree pspv state)
; Ttree has exactly one object associated with the tag 'abort-cause.
(let ((temp (tagged-object 'abort-cause ttree))
(cl-id-phrase (tilde-@-clause-id-phrase cl-id))
(gag-mode (gag-mode)))
(case temp
(empty-clause
(if gag-mode
(msg "A goal of NIL, ~@0, has been generated! Obviously, the ~
proof attempt has failed.~|"
cl-id-phrase)
""))
((do-not-induct do-not-induct-otf-flg-override)
(msg "Normally we would attempt to prove ~@0 by induction. However, a ~
:DO-NOT-INDUCT hint was supplied to abort the proof attempt.~|"
cl-id-phrase
(if (eq temp 'do-not-induct)
t
:otf-flg-override)))
(otherwise
(msg "Normally we would attempt to prove ~@0 by induction. However, ~
we prefer in this instance to focus on the original input ~
conjecture rather than this simplified special case. We ~
therefore abandon our previous work on this conjecture and ~
reassign the name ~@1 to the original conjecture. (See :DOC ~
otf-flg.)~#2~[~/ [Note: Thanks again for the hint.]~]~|"
cl-id-phrase
(tilde-@-pool-name-phrase
(access clause-id cl-id :forcing-round)
(pool-lst
(cdr (access prove-spec-var pspv
:pool))))
(if (and (not gag-mode)
(access prove-spec-var pspv
:hint-settings))
1
0))))))
(defun push-clause-msg1 (cl-id signal clauses ttree pspv state)
; Push-clause was given a clause and produced a signal and ttree. We
; are responsible for printing out an explanation of what happened.
; We look at the ttree to determine what happened. We return state.
(declare (ignore clauses))
(cond ((eq signal 'abort)
(fms "~@0"
(list (cons #\0 (push-clause-msg1-abort cl-id ttree pspv state)))
(proofs-co state)
state
nil))
(t
(fms "Name the formula above ~@0.~|"
(list (cons #\0 (tilde-@-pool-name-phrase
(access clause-id cl-id :forcing-round)
(pool-lst
(cdr (access prove-spec-var pspv
:pool))))))
(proofs-co state)
state
nil))))
; Section: Use and By hints
(defun clause-set-subsumes-1 (init-subsumes-count cl-set1 cl-set2 acc)
; We return t if the first set of clauses subsumes the second in the sense that
; for every member of cl-set2 there exists a member of cl-set1 that subsumes
; it. We return '? if we don't know (but this can only happen if
; init-subsumes-count is non-nil); see the comment in subsumes.
(cond ((null cl-set2) acc)
(t (let ((temp (some-member-subsumes init-subsumes-count
cl-set1 (car cl-set2) nil)))
(and temp ; thus t or maybe, if init-subsumes-count is non-nil, ?
(clause-set-subsumes-1 init-subsumes-count
cl-set1 (cdr cl-set2) temp))))))
(defun clause-set-subsumes (init-subsumes-count cl-set1 cl-set2)
; This function is intended to be identical, as a function, to
; clause-set-subsumes-1 (with acc set to t). The first two disjuncts are
; optimizations that may often apply.
(or (equal cl-set1 cl-set2)
(and cl-set1
cl-set2
(null (cdr cl-set2))
(subsetp-equal (car cl-set1) (car cl-set2)))
(clause-set-subsumes-1 init-subsumes-count cl-set1 cl-set2 t)))
(defun preprocess-clause? (cl hist pspv wrld state step-limit)
(cond ((member-eq 'preprocess-clause
(assoc-eq :do-not (access prove-spec-var pspv
:hint-settings)))
(mv step-limit 'miss nil nil nil))
(t (preprocess-clause cl hist pspv wrld state step-limit))))
(defun apply-use-hint-clauses (temp clauses pspv wrld state step-limit)
; Note: There is no apply-use-hint-clause. We just call this function
; on a singleton list of clauses.
; Temp is the result of assoc-eq :use in a pspv :hint-settings and is
; non-nil. We discuss its shape below. But this function applies the
; given :use hint to each clause in clauses and returns (mv 'hit
; new-clauses ttree new-pspv).
; Temp is of the form (:USE lmi-lst (hyp1 ... hypn) constraint-cl k
; event-names new-entries) where each hypi is a theorem and
; constraint-cl is a clause that expresses the conjunction of all k
; constraints. Lmi-lst is the list of lmis that generated these hyps.
; Constraint-cl is (probably) of the form {(if constr1 (if constr2 ...
; (if constrk t nil)... nil) nil)}. We add each hypi as a hypothesis
; to each goal clause, cl, and in addition, create one new goal for
; each constraint. Note that we discard the extended goal clause if
; it is a tautology. Note too that the constraints generated by the
; production of the hyps are conjoined into a single clause in temp.
; But we hit that constraint-cl with preprocess-clause to pick out its
; (non-tautologial) cases and that code will readily unpack the if
; structure of a typical conjunct. We remove the :use hint from the
; hint-settings so we don't fire the same :use again on the subgoals.
; We return (mv new-step-limit 'hit new-clauses ttree new-pspv).
; The ttree returned has at most two tags. The first is :use and has
; ((lmi-lst hyps constraint-cl k event-names new-entries)
; . non-tautp-applications) as its value, where non-tautp-applications
; is the number of non-tautologous clauses we got by adding the hypi
; to each clause. However, it is possible the :use tag is not
; present: if clauses is nil, we don't report a :use. The optional
; second tag is the ttree produced by preprocess-clause on the
; constraint-cl. If the preprocess-clause is to be hidden anyway, we
; ignore its tree (but use its clauses).
(let* ((hyps (caddr temp))
(constraint-cl (cadddr temp))
(new-pspv (change prove-spec-var pspv
:hint-settings
(remove1-equal temp
(access prove-spec-var
pspv
:hint-settings))))
(A (disjoin-clause-segment-to-clause-set (dumb-negate-lit-lst hyps)
clauses))
(non-tautp-applications (length A)))
; In this treatment, the final set of goal clauses will the union of
; sets A and C. A stands for the "application clauses" (obtained by
; adding the use hyps to each clause) and C stands for the "constraint
; clauses." Non-tautp-applications is |A|.
(cond
((null clauses)
; In this case, there is no point in generating the constraints! We
; anticipate this happening if the user provides both a :use and a
; :cases hint and the :cases hint (which is applied first) proves the
; goal completely. If that were to happen, clauses would be output of
; the :cases hint and pspv would be its output pspv, from which the
; :cases had been deleted. So we just delete the :use hint from that
; pspv and call it quits, without reporting a :use hint at all.
(mv step-limit 'hit nil nil new-pspv))
(t
(sl-let
(signal C ttree irrel-pspv)
(preprocess-clause? constraint-cl nil pspv wrld state step-limit)
(declare (ignore irrel-pspv))
(cond
((eq signal 'miss)
(mv step-limit
'hit
(conjoin-clause-sets
A
(conjoin-clause-to-clause-set constraint-cl
nil))
(add-to-tag-tree! :use
(cons (cdr temp)
non-tautp-applications)
nil)
new-pspv))
((or (tag-tree-occur 'hidden-clause
t
ttree)
(and C
(null (cdr C))
constraint-cl
(null (cdr constraint-cl))
(equal (prettyify-clause-simple (car C))
(car constraint-cl))))
(mv step-limit
'hit
(conjoin-clause-sets A C)
(add-to-tag-tree! :use
(cons (cdr temp)
non-tautp-applications)
nil)
new-pspv))
(t (mv step-limit
'hit
(conjoin-clause-sets A C)
(add-to-tag-tree! :use
(cons (cdr temp)
non-tautp-applications)
(add-to-tag-tree! 'preprocess-ttree
ttree
nil))
new-pspv))))))))
(defun apply-cases-hint-clause (temp cl pspv wrld)
; Temp is the value associated with :cases in a pspv :hint-settings
; and is non-nil. It is thus of the form (:cases term1 ... termn).
; For each termi we create a new clause by adding its negation to the
; goal clause, cl, and in addition, we create a final goal by adding
; all termi. As with a :use hint, we remove the :cases hint from the
; hint-settings so that the waterfall doesn't loop!
; We return (mv 'hit new-clauses ttree new-pspv).
(let ((new-clauses
(remove-trivial-clauses
(conjoin-clause-to-clause-set
(disjoin-clauses
(cdr temp)
cl)
(split-on-assumptions
; We reverse the term-list so the user can see goals corresponding to the
; order of the terms supplied.
(dumb-negate-lit-lst (reverse (cdr temp)))
cl
nil))
wrld)))
(mv 'hit
new-clauses
(add-to-tag-tree! :cases (cons (cdr temp) new-clauses) nil)
(change prove-spec-var pspv
:hint-settings
(remove1-equal temp
(access prove-spec-var
pspv
:hint-settings))))))
(defun non-term-listp-msg (x w)
; Perhaps ~Y01 should be ~y below. If someone complains about a large term
; being printed, consider making that change.
(declare (xargs :guard t))
(cond
((atom x)
(assert$
x
"that fails to satisfy true-listp."))
((not (termp (car x) w))
(msg "that contains the following non-termp (see :DOC term):~|~% ~Y01"
(car x)
nil))
(t (non-term-listp-msg (cdr x) w))))
(defun non-term-list-listp-msg (l w)
; Perhaps ~Y01 should be ~y below. If someone complains about a large term
; being printed, consider making that change.
(declare (xargs :guard t))
(cond
((atom l)
(assert$
l
"which fails to satisfy true-listp."))
((not (term-listp (car l) w))
(msg "which has a member~|~% ~Y01~|~%~@2"
(car l)
nil
(non-term-listp-msg (car l) w)))
(t (non-term-list-listp-msg (cdr l) w))))
(defun eval-clause-processor (clause term stobjs-out verified-p pspv ctx state)
; Verified-p is either nil, t, or a well-formedness-guarantee of the form
; ((name fn thm-name1) . arity-alist).
; Should we do our evaluation in safe-mode? For a relevant discussion, see the
; comment in protected-eval about safe-mode.
; Keep in sync with eval-clause-processor@par.
(revert-world-on-error
(let ((original-wrld (w state))
(cl-term (subst-var (kwote clause) 'clause term)))
(protect-system-state-globals
(pprogn
(mv-let
(erp trans-result state)
(ev-for-trans-eval cl-term (all-vars cl-term) stobjs-out ctx state
; See chk-evaluator-use-in-rule for a discussion of how we restrict the use of
; evaluators in rules of class :meta or :clause-processor, so that we can use
; aok = t here.
t)
(cond
(erp (mv (msg "Evaluation failed for the :clause-processor hint.")
nil
state))
(t
(assert$
(equal (car trans-result) stobjs-out)
(let* ((result (cdr trans-result))
(eval-erp (and (cdr stobjs-out) (car result)))
(val (if (cdr stobjs-out) (cadr result) result)))
(cond ((stringp eval-erp)
(mv (msg "~s0" eval-erp) nil state))
((tilde-@p eval-erp) ; a message
(mv (msg "Error in clause-processor hint:~|~% ~@0"
eval-erp)
nil
state))
(eval-erp
(mv (msg "Error in clause-processor hint:~|~% ~Y01"
term
nil)
nil
state))
(t
(pprogn
(set-w! original-wrld state)
(cond
((equal val (list clause)) ; avoid checks below
(value val))
(t
(let* ((user-says-skip-termp-checkp
(skip-meta-termp-checks
(ffn-symb term) original-wrld))
(well-formedness-guarantee
(if (consp verified-p)
verified-p
nil))
(not-skipped
(and (not user-says-skip-termp-checkp)
(not well-formedness-guarantee)))
(bad-arities
(if (and well-formedness-guarantee
(not user-says-skip-termp-checkp))
(collect-bad-fn-arity-pairs
(cdr well-formedness-guarantee)
original-wrld)
nil)))
(cond
(bad-arities
(let ((name (nth 0 (car well-formedness-guarantee)))
(fn (nth 1 (car well-formedness-guarantee)))
(thm-name1
(nth 2 (car well-formedness-guarantee))))
(mv (msg
"The clause processor correctness theorem ~
~x0 has a now-invalid well-formedness ~
guarantee. Its clause processor ~x1 was ~
proved in ~x2 to return a TERM-LIST-LISTP ~
under the assumption that certain function ~
symbols had certain arities. But that ~
assumption is now invalid. The following ~
alist pairs function symbols with their ~
assumed arities: ~X34. These arities were ~
valid when ~x0 and ~x2 were proved but ~
have since changed (presumably by ~
redefinition). We cannot trust the ~
well-formedness guarantee."
name
fn
thm-name1
bad-arities
nil)
nil state)))
((and not-skipped
(not (term-list-listp val original-wrld)))
(mv (msg
"The :CLAUSE-PROCESSOR hint~|~% ~Y01~%did ~
not evaluate to a list of clauses, but ~
instead to~|~% ~Y23~%~@4"
term nil
val nil
(non-term-list-listp-msg
val original-wrld))
nil
state))
((and not-skipped
(forbidden-fns-in-term-list-list
val
(access rewrite-constant
(access prove-spec-var pspv
:rewrite-constant)
:forbidden-fns)))
(mv (msg
"The :CLAUSE-PROCESSOR ~
hint~|~%~Y01~%evaluated to a list of ~
clauses~|~%~y2~%that contains a call of the ~
function symbol~#3~[, ~&3, which is~/s ~&3, ~
which are~] forbidden in that context. See ~
:DOC clause-processor and :DOC ~
set-skip-meta-termp-checks and :DOC ~
well-formedness-guarantee."
term nil val
(forbidden-fns-in-term-list-list
val
(access rewrite-constant
(access prove-spec-var pspv
:rewrite-constant)
:forbidden-fns)))
nil
state))
(t (value val)))))))))))))))))))
#+acl2-par
(defun eval-clause-processor@par (clause term stobjs-out verified-p pspv ctx
state)
; Keep in sync with eval-clause-processor.
(cond
((and
; Note that potential conjunct (f-get-global 'waterfall-parallelism state) is
; not needed, since we are in an @par definition. Also note that a
; clause-processor returns (as per :doc clause-processor) either a list cl-list
; of clauses, or else (mv erp cl-list st_i1 ... st_in) where erp and cl-list
; are not stobjs and the st_ik are all stobjs. Since we want to rule out
; stobjs, we therefore check that stobjs-out is (nil) or (nil nil).
(not (or (equal stobjs-out '(nil))
(equal stobjs-out '(nil nil))))
(not (cdr (assoc-eq 'hacks-enabled
(table-alist 'waterfall-parallelism-table
(w state))))))
(mv (msg
"Clause-processors that do not return exactly one or two values are ~
not officially supported when waterfall parallelism is enabled. If ~
you wish to use such a clause-processor anyway, you can call ~x0. ~
See :DOC set-waterfall-parallelism-hacks-enabled for more ~
information. "
'(set-waterfall-parallelism-hacks-enabled t))
nil))
(t
(let ((wrld (w state))
(cl-term (subst-var (kwote clause) 'clause term)))
(mv-let
(erp trans-result)
; Parallelism blemish: we could consider making an ev@par, which calls ev-w,
; and tests that the appropriate preconditions for ev-w are upheld (like state
; not being in the alist).
(ev-w-for-trans-eval cl-term (all-vars cl-term) stobjs-out ctx state
; See chk-evaluator-use-in-rule for a discussion of how we restrict the use of
; evaluators in rules of class :meta or :clause-processor, so that we can use
; aok = t here.
t)
(cond
(erp (mv (msg "Evaluation failed for the :clause-processor hint.")
nil))
(t
(assert$
(equal (car trans-result) stobjs-out)
(let* ((result (cdr trans-result))
(eval-erp (and (cdr stobjs-out) (car result)))
(val (if (cdr stobjs-out) (cadr result) result)))
(cond ((stringp eval-erp)
(mv (msg "~s0" eval-erp) nil))
((tilde-@p eval-erp) ; a message
(mv (msg "Error in clause-processor hint:~|~% ~@0"
eval-erp)
nil))
(eval-erp
(mv (msg "Error in clause-processor hint:~|~% ~Y01"
term
nil)
nil))
((equal val (list clause)) ; avoid checks below
(value@par val))
(t
(let* ((user-says-skip-termp-checkp
(skip-meta-termp-checks
(ffn-symb term) wrld))
(well-formedness-guarantee
(if (consp verified-p)
verified-p
nil))
(not-skipped
(and (not user-says-skip-termp-checkp)
(not well-formedness-guarantee)))
(bad-arities (if (and well-formedness-guarantee
(not user-says-skip-termp-checkp))
(collect-bad-fn-arity-pairs
(cdr well-formedness-guarantee)
wrld)
nil)))
(cond
(bad-arities
(let ((name (nth 0 (car well-formedness-guarantee)))
(fn (nth 1 (car well-formedness-guarantee)))
(thm-name1 (nth 2 (car well-formedness-guarantee))))
(mv (msg
"The clause processor correctness theorem ~x0 ~
has a now-invalid well-formedness guarantee. ~
Its clause processor ~x1 was proved in ~x2 to ~
return a TERM-LIST-LISTP under the assumption ~
that certain function symbols had certain ~
arities. But that assumption is now invalid. ~
The following alist pairs function symbols ~
with their assumed arities: ~X34. These ~
arities were valid when ~x0 and ~x2 were ~
proved but have since changed (presumably by ~
redefinition). We cannot trust the ~
well-formedness guarantee."
name
fn
thm-name1
bad-arities
nil)
nil)))
((and not-skipped
(not (term-list-listp val wrld)))
(mv (msg
"The :CLAUSE-PROCESSOR hint~|~% ~Y01~%did not ~
evaluate to a list of clauses, but instead ~
to~|~% ~Y23~%~@4"
term nil
val nil
(non-term-list-listp-msg
val wrld))
nil))
((and not-skipped
(forbidden-fns-in-term-list-list
val
(access rewrite-constant
(access prove-spec-var pspv
:rewrite-constant)
:forbidden-fns)))
(mv (msg
"The :CLAUSE-PROCESSOR hint~|~%~Y01~%evaluated to ~
a list of clauses~|~%~y2~%that contains a call ~
of the function symbol~#3~[, ~&3, which is~/s ~
~&3, which are~] forbidden in that context. See ~
:DOC clause-processor and :DOC ~
set-skip-meta-termp-checks and :DOC ~
well-formedness-guarantee."
term nil val
(forbidden-fns-in-term-list-list
val
(access rewrite-constant
(access prove-spec-var pspv
:rewrite-constant)
:forbidden-fns)))
nil))
(t (value@par val)))))))))))))))
(defun apply-top-hints-clause1 (temp cl-id cl pspv wrld state step-limit)
; See apply-top-hints-clause. This handles the case that we found a
; hint-setting, temp, for a top hint other than :clause-processor or :or.
(case (car temp)
(:use ; temp is a non-nil :use hint.
(let ((cases-temp
(assoc-eq :cases
(access prove-spec-var pspv :hint-settings))))
(cond
((null cases-temp)
(apply-use-hint-clauses temp (list cl) pspv wrld state step-limit))
(t
; In this case, we have both :use and :cases hints. Our
; interpretation of this is that we split clause cl according to the
; :cases and then apply the :use hint to each case. By the way, we
; don't have to consider the possibility of our having a :use and :by
; or :bdd. That is ruled out by translate-hints.
(mv-let
(signal cases-clauses cases-ttree cases-pspv)
(apply-cases-hint-clause cases-temp cl pspv wrld)
(declare (ignore signal))
; We know the signal is 'HIT.
(sl-let
(signal use-clauses use-ttree use-pspv)
(apply-use-hint-clauses temp
cases-clauses
cases-pspv
wrld state step-limit)
(declare (ignore signal))
; Despite the names, use-clauses and use-pspv both reflect the work we
; did for cases. However, use-ttree was built from scratch as was
; cases-ttree and we must combine them.
(mv step-limit
'HIT
use-clauses
(cons-tag-trees use-ttree cases-ttree)
use-pspv)))))))
(:by
; If there is a :by hint then it is of one of the two forms (:by . name) or
; (:by lmi-lst thm constraint-cl k event-names new-entries). The first form
; indicates that we are to give this clause a bye and let the proof fail late.
; The second form indicates that the clause is supposed to be subsumed by thm,
; viewed as a set of clauses, but that we have to prove constraint-cl to obtain
; thm and that constraint-cl is really a conjunction of k constraints. Lmi-lst
; is a singleton list containing the lmi that generated this thm-cl.
(cond
((symbolp (cdr temp))
; So this is of the first form, (:by . name). We want the proof to fail, but
; not now. So we act as though we proved cl (we hit, produce no new clauses
; and don't change the pspv) but we return a tag-tree containing the tag
; :bye with the value (name . cl). At the end of the proof we must search
; the tag-tree and see if there are any :byes in it. If so, the proof failed
; and we should display the named clauses.
(mv step-limit
'hit
nil
(add-to-tag-tree! :bye (cons (cdr temp) cl) nil)
pspv))
(t
(let ((lmi-lst (cadr temp)) ; a singleton list
(thm (remove-guard-holders
; We often remove guard-holders without tracking their use in the tag-tree.
; Other times we record their use (but not here). This is analogous to our
; reporting of the use of (:DEFINITION NOT) in some cases but not in others
; (e.g., when we use strip-not).
(caddr temp)))
(constraint-cl (cadddr temp))
(sr-limit (car (access rewrite-constant
(access prove-spec-var pspv
:rewrite-constant)
:case-split-limitations)))
(new-pspv
(change prove-spec-var pspv
:hint-settings
(remove1-equal temp
(access prove-spec-var
pspv
:hint-settings)))))
; We remove the :by from the hint-settings. Why do we remove the :by?
; If we don't the subgoals we create from constraint-cl will also see
; the :by!
; We insist that thm-cl-set subsume cl -- more precisely, that cl be
; subsumed by some member of thm-cl-set.
; WARNING: See the warning about the processing in translate-by-hint.
(let* ((cl (remove-guard-holders-lst cl))
(cl (remove-equal *nil* cl))
(easy-winp
(cond ((null cl) ; very weird case!
(equal thm *nil*))
((null (cdr cl))
(equal (car cl) thm))
(t
(equal thm
(implicate
(conjoin (dumb-negate-lit-lst (butlast cl 1)))
(car (last cl)))))))
(cl1 (if (and (not easy-winp)
(ffnnamep-lst 'implies cl))
(expand-some-non-rec-fns-lst '(implies) cl wrld)
cl))
(cl-set (if (not easy-winp)
; Before Version_2.7 we only called clausify here when (and (null hist) cl1
; (null (cdr cl1))). But Robert Krug sent an example in which a :by hint was
; given on a subgoal that had been produced from "Goal" by destructor
; elimination. That subgoal was identical to the theorem given in the :by
; hint, and hence easy-winp is true; but before Version_2.7 we did not look for
; the easy win. So, what happened was that thm-cl-set was the result of
; clausifying the theorem given in the :by hint, but cl-set was a singleton
; containing cl1, which still has IF terms.
(clausify (disjoin cl1) nil t sr-limit)
(list cl1)))
(thm-cl-set (if easy-winp
(list (list thm))
; WARNING: Below we process the thm obtained from the lmi. In particular, we
; expand certain non-rec fns and we clausify it. For heuristic sanity, the
; processing done here should exactly duplicate that done above for cl-set.
; The reason is that we want it to be the case that if the user gives a :by
; hint that is identical to the goal theorem, the subsumption is guaranteed to
; succeed. If the processing of the goal theorem is slightly different than
; the processing of the hint, that guarantee is invalid.
(clausify (expand-some-non-rec-fns
'(implies) thm wrld)
nil
t
sr-limit)))
(val (list* (cadr temp) thm-cl-set (cdddr temp)))
(subsumes (and (not easy-winp) ; otherwise we don't care
(clause-set-subsumes nil
; We supply nil just above, rather than (say) *init-subsumes-count*, because
; the user will be able to see that if the subsumption check goes out to lunch
; then it must be because of the :by hint. For example, it takes 167,997,825
; calls of one-way-unify1 (more than 2^27, not far from the fixnum limit in
; many Lisps) to do the subsumption check for the following, yet in a feasible
; time (26 seconds on Allegro CL 7.0, on a 2.6GH Pentium 4). So we prefer not
; to set a limit.
; (defstub p (x) t)
; (defstub s (x1 x2 x3 x4 x5 x6 x7 x8) t)
; (defaxiom ax
; (implies (and (p x1) (p x2) (p x3) (p x4)
; (p x5) (p x6) (p x7) (p x8))
; (s x1 x2 x3 x4 x5 x6 x7 x8))
; :rule-classes nil)
; (defthm prop
; (implies (and (p x1) (p x2) (p x3) (p x4)
; (p x5) (p x6) (p x7) (p x8))
; (s x8 x7 x3 x4 x5 x6 x1 x2))
; :hints (("Goal" :by ax)))
thm-cl-set cl-set)))
(success (or easy-winp subsumes)))
; Before the full-blown subsumption check we ask if the two sets are identical
; and also if they are each singleton sets and the thm-cl-set's clause is a
; subset of the other clause. These are fast and commonly successful checks.
(cond
(success
; Ok! We won! To produce constraint-cl as our goal we first
; preprocess it as though it had come down from the top. See the
; handling of :use hints below for some comments on this. This code
; was copied from that historically older code.
(sl-let (signal clauses ttree irrel-pspv)
(preprocess-clause? constraint-cl nil pspv wrld
state step-limit)
(declare (ignore irrel-pspv))
(cond ((eq signal 'miss)
(mv step-limit
'hit
(conjoin-clause-to-clause-set
constraint-cl nil)
(add-to-tag-tree! :by val nil)
new-pspv))
((or (tag-tree-occur 'hidden-clause
t
ttree)
(and clauses
(null (cdr clauses))
constraint-cl
(null (cdr constraint-cl))
(equal (prettyify-clause-simple
(car clauses))
(car constraint-cl))))
; If preprocessing produced a single clause that prettyifies to the
; clause we had, then act as though it didn't do anything (but use its
; output clause set). This is akin to the 'hidden-clause
; hack of preprocess-clause, which, however, is intimately tied to the
; displayed-goal input to prove and not to the input to prettyify-
; clause. We look for the 'hidden-clause tag just in case.
(mv step-limit
'hit
clauses
(add-to-tag-tree! :by val nil)
new-pspv))
(t
(mv step-limit
'hit
clauses
(add-to-tag-tree!
:by val
(add-to-tag-tree! 'preprocess-ttree
ttree
nil))
new-pspv)))))
(t (mv step-limit
'error
(msg "When a :by hint is used to supply a lemma-instance ~
for a given goal-spec, the formula denoted by the ~
lemma-instance must subsume the goal. This did not ~
happen~@1! The lemma-instance provided was ~x0, ~
which denotes the formula ~p2 (when converted to a ~
set of clauses and then printed as a formula). This ~
formula was not found to subsume the goal clause, ~
~p3.~|~%Consider a :use hint instead ; see :DOC ~
hints."
(car lmi-lst)
; The following is not possible, because we are not putting a limit on the
; number of one-way-unify1 calls in our subsumption check (see above). But we
; leave this code here in case we change our minds on that.
(if (eq subsumes '?)
" because our subsumption heuristics were unable ~
to decide the question"
"")
(untranslate thm t wrld)
(prettyify-clause-set cl-set
(let*-abstractionp state)
wrld))
nil
nil))))))))
(:cases
; Then there is no :use hint present. See the comment in *top-hint-keywords*.
(prepend-step-limit
4
(apply-cases-hint-clause temp cl pspv wrld)))
(:bdd
(prepend-step-limit
4
(bdd-clause (cdr temp) cl-id cl
(change prove-spec-var pspv
:hint-settings
(remove1-equal temp
(access prove-spec-var
pspv
:hint-settings)))
wrld state)))
(t (mv step-limit
(er hard 'apply-top-hints-clause
"Implementation error: Missing case in apply-top-hints-clause.")
nil nil nil))))
(defun@par apply-top-hints-clause (cl-id cl hist pspv wrld ctx state step-limit)
; This is a standard clause processor of the waterfall. It is odd in that it
; is a no-op unless there is a :use, :by, :cases, :bdd, :clause-processor, or
; :or hint in the :hint-settings of pspv. If there is, we remove it and apply
; it. By implementing these hints via this special-purpose processor we can
; take advantage of the waterfall's already-provided mechanisms for handling
; multiple clauses and output.
; We return five values. The first is a new step-limit and the sixth is state.
; The second is a signal that is either 'hit, 'miss, or 'error. When the
; signal is 'miss, the remaining three values are irrelevant. When the signal
; is 'error, the third result is a pair of the form (str . alist) which allows
; us to give our caller an error message to print. In this case, the remaining
; two values are irrelevant. When the signal is 'hit, the third result is the
; list of new clauses, the fourth is a ttree that will become that component of
; the history-entry for this process, and the fifth is the modified pspv.
; We need cl-id passed in so that we can store it in the bddnote, in the case
; of a :bdd hint.
(declare (ignore hist))
(let ((temp (first-assoc-eq *top-hint-keywords*
(access prove-spec-var pspv
:hint-settings))))
(cond
((null temp) (mv@par step-limit 'miss nil nil nil state))
((eq (car temp) :or)
; If there is an :or hint then it is the only hint present and (in the
; translated form found here) it is of the form (:or . ((user-hint1
; . hint-settings1) ...(user-hintk . hint-settingsk))). We simply signal an
; or-hit and let the waterfall process the hints. We remove the :or hint from
; the :hint-settings of the pspv. (It may be tempting simply to set the
; :hint-settings to nil. But there may be other :hint-settings, say from a
; :do-not hint on a superior clause id.)
; The value, val, tagged with :or in the ttree is of the form (parent-cl-id NIL
; uhs-lst), where the parent-cl-id is the cl-id of the clause to which this :OR
; hint applies, the uhs-lst is the list of dotted pairs (... (user-hinti
; . hint-settingsi)...) and the NIL signifies that no branches have been
; created. Eventually we will replace the NIL in the ttree of each branch by
; an integer i indicating which branch. If that slot is occupied by an integer
; then user-hinti was applied to the corresponding clause. See
; change-or-hit-history-entry.
(mv@par step-limit
'or-hit
(list cl)
(add-to-tag-tree! :or
(list cl-id nil (cdr temp))
nil)
(change prove-spec-var pspv
:hint-settings
(delete-assoc-eq :or
(access prove-spec-var pspv
:hint-settings)))
state))
((eq (car temp) :clause-processor) ; special case as state can be returned
; Temp is of the form (clause-processor-hint . stobjs-out), as returned by
; translate-clause-processor-hint.
(mv-let@par
(erp new-clauses state)
(eval-clause-processor@par cl
(access clause-processor-hint (cdr temp)
:term)
(access clause-processor-hint (cdr temp)
:stobjs-out)
(access clause-processor-hint (cdr temp)
:verified-p)
pspv ctx state)
(cond (erp (mv@par step-limit 'error erp nil nil state))
(t (mv@par step-limit
'hit
new-clauses
(cond ((and new-clauses
(null (cdr new-clauses))
(equal (car new-clauses) cl))
(add-to-tag-tree! 'hidden-clause t nil))
(t (add-to-tag-tree!
:clause-processor
(cons (cdr temp) new-clauses)
nil)))
(change prove-spec-var pspv
:hint-settings
(remove1-equal temp
(access prove-spec-var
pspv
:hint-settings)))
state)))))
(t (sl-let
(signal clauses ttree new-pspv)
(apply-top-hints-clause1 temp cl-id cl pspv wrld state step-limit)
(mv@par step-limit signal clauses ttree new-pspv state))))))
(defun tilde-@-lmi-phrase (lmi-lst k event-names)
; Lmi-lst is a list of lmis. K is the number of constraints we have to
; establish. Event-names is a list of names of events that justify the
; omission of certain proof obligations, because they have already been proved
; on behalf of those events. We return an object suitable for printing via ~@
; that will print the phrase
; can be derived from ~&0 via instantiation and functional
; instantiation, provided we can establish the ~n1 constraints
; when event-names is nil, or else
; can be derived from ~&0 via instantiation and functional instantiation,
; bypassing constraints that have been proved when processing the events ...,
; [or: instead of ``the events,'' use ``events including'' when there
; is at least one unnamed event involved, such as a verify-guards
; event]
; provided we can establish the remaining ~n1 constraints
; Of course, the phrase is altered appropriately depending on the lmis
; involved. There are two uses of this phrase. When :by reports it
; says "As indicated by the hint, this goal is subsumed by ~x0, which
; CAN BE ...". When :use reports it says "We now add the hypotheses
; indicated by the hint, which CAN BE ...".
(let* ((seeds (lmi-seed-lst lmi-lst))
(lemma-names (filter-atoms t seeds))
(thms (filter-atoms nil seeds))
(techs (lmi-techs-lst lmi-lst)))
(cond ((null techs)
(cond ((null thms)
(msg "can be obtained from ~&0"
lemma-names))
((null lemma-names)
(msg "can be obtained from the ~
~#0~[~/constraint~/~n1 constraints~] generated"
(zero-one-or-more k)
k))
(t (msg "can be obtained from ~&0 and the ~
~#1~[~/constraint~/~n2 constraints~] ~
generated"
lemma-names
(zero-one-or-more k)
k))))
((null event-names)
(msg "can be derived from ~&0 via ~*1~#2~[~/, provided we can ~
establish the constraint generated~/, provided we can ~
establish the ~n3 constraints generated~]"
seeds
(list "" "~s*" "~s* and " "~s*, " techs)
(zero-one-or-more k)
k))
(t
(msg "can be derived from ~&0 via ~*1, bypassing constraints that ~
have been proved when processing ~#2~[events ~
including ~/previous events~/the event~#3~[~/s~]~ ~
~]~&3~#4~[~/, provided we can establish the constraint ~
generated~/, provided we can establish the ~n5 constraints ~
generated~]"
seeds
(list "" "~s*" "~s* and " "~s*, " techs)
; Recall that an event-name of 0 is really an indication that the event in
; question didn't actually have a name. See install-event.
(if (member 0 event-names)
(if (cdr event-names)
0
1)
2)
(if (member 0 event-names)
(remove 0 event-names)
event-names)
(zero-one-or-more k)
k)))))
(defun or-hit-msg (gag-mode-only-p cl-id ttree)
; We print the opening part of the :OR disjunction message, in which we alert
; the reader to the coming disjunctive branches. If the signal is 'OR-HIT,
; then clauses just the singleton list contain the same clause the :OR was
; attached to. But ttree contains an :or tag with value (parent-cl-id nil
; ((user-hint1 . hint-settings1)...)) indicating what is to be done to the
; clause. Eventually the nil we be replaced, on each branch, by the number of
; that branch. See change-or-hit-history-entry. The number of branches is the
; length of the third element. The parent-cl-id in the value is the same as
; the cl-id passed in.
(let* ((val (tagged-object :or ttree))
(branch-cnt (length (nth 2 val))))
(msg "The :OR hint for ~@0 gives rise to ~n1 disjunctive ~
~#2~[~/branch~/branches~]. Proving any one of these branches would ~
suffice to prove ~@0. We explore them in turn~#3~[~@4~/~].~%"
(tilde-@-clause-id-phrase cl-id)
branch-cnt
(zero-one-or-more branch-cnt)
(if gag-mode-only-p 1 0)
", describing their derivations as we go")))
(defun apply-top-hints-clause-msg1
(signal cl-id clauses speciousp ttree pspv state)
; This function is one of the waterfall-msg subroutines. It has the standard
; arguments of all such functions: the signal, clauses, ttree and pspv produced
; by the given processor, in this case preprocess-clause (except that for bdd
; processing, the ttree comes from bdd-clause, which is similar to
; simplify-clause, which explains why we also pass in the argument speciousp).
; It produces the report for this step.
; Note: signal and pspv are really ignored, but they don't appear to be when
; they are passed to simplify-clause-msg1 below, so we cannot declare them
; ignored here.
(cond ((tagged-objectsp :bye ttree)
; The object associated with the :bye tag is (name . cl). We are interested
; only in name here.
(fms "But we have been asked to pretend that this goal is ~
subsumed by the yet-to-be-proved ~x0.~|"
(list (cons #\0 (car (tagged-object :bye ttree))))
(proofs-co state)
state
nil))
((tagged-objectsp :by ttree)
(let* ((obj (tagged-object :by ttree))
; Obj is of the form (lmi-lst thm-cl-set constraint-cl k event-names
; new-entries).
(lmi-lst (car obj))
(thm-cl-set (cadr obj))
(k (car (cdddr obj)))
(event-names (cadr (cdddr obj)))
(ttree (tagged-object 'preprocess-ttree ttree)))
(fms "~#0~[But, as~/As~/As~] indicated by the hint, this goal is ~
subsumed by ~x1, which ~@2.~#3~[~/ By ~*4 we reduce the ~
~#5~[constraint~/~n6 constraints~] to ~#0~[T~/the following ~
conjecture~/the following ~n7 conjectures~].~]~|"
(list (cons #\0 (zero-one-or-more clauses))
(cons #\1 (prettyify-clause-set
thm-cl-set
(let*-abstractionp state)
(w state)))
(cons #\2 (tilde-@-lmi-phrase lmi-lst k event-names))
(cons #\3 (if (int= k 0) 0 1))
(cons #\4 (tilde-*-preprocess-phrase ttree))
(cons #\5 (if (int= k 1) 0 1))
(cons #\6 k)
(cons #\7 (length clauses)))
(proofs-co state)
state
(term-evisc-tuple nil state))))
((tagged-objectsp :use ttree)
(let* ((use-obj (tagged-object :use ttree))
; The presence of :use indicates that a :use hint was applied to one
; or more clauses to give the output clauses. If there is also a
; :cases tag in the ttree, then the input clause was split into to 2
; or more cases first and then the :use hint was applied to each. If
; there is no :cases tag, the :use hint was applied to the input
; clause alone. Each application of the :use hint adds literals to
; the target clause(s). This generates a set, A, of ``applications''
; but A need not be the same length as the set of clauses to which we
; applied the :use hint since some of those applications might be
; tautologies. In addition, the :use hint generated some constraints,
; C. The set of output clauses, say G, is (C U A). But C and A are
; not necessarily disjoint, e.g., some constraints might happen to be
; in A. Once upon a time, we reported on the number of non-A
; constraints, i.e., |C'|, where C' = C\A. Because of the complexity
; of the grammar, we do not reveal to the user all the numbers: how
; many non-tautological cases, how many hypotheses, how many
; non-tautological applications, how many constraints generated, how
; many after preprocessing the constraints, how many overlaps between
; C and A, etc. Instead, we give a fairly generic message. But we
; have left (as comments) the calculation of the key numbers in case
; someday we revisit this.
; The shape of the use-obj, which is the value of the :use tag, is
; ((lmi-lst (hyp1 ...) cl k event-names new-entries)
; . non-tautp-applications) where non-tautp-applications is the number
; of non-tautologies created by the one or more applications of the
; :use hint, i.e., |A|. (But we do not report this.)
(lmi-lst (car (car use-obj)))
(hyps (cadr (car use-obj)))
(k (car (cdddr (car use-obj)))) ;;; |C|
(event-names (cadr (cdddr (car use-obj))))
; (non-tautp-applications (cdr use-obj)) ;;; |A|
(preprocess-ttree
(tagged-object 'preprocess-ttree ttree))
; (len-A non-tautp-applications) ;;; |A|
(len-G (len clauses)) ;;; |G|
(len-C k) ;;; |C|
; (len-C-prime (- len-G len-A)) ;;; |C'|
(cases-obj (tagged-object :cases ttree))
; If there is a cases-obj it means we had a :cases and a :use; the
; form of cases-obj is (splitting-terms . case-clauses), where
; case-clauses is the result of splitting on the literals in
; splitting-terms. We know that case-clauses is non-nil. (Had it
; been nil, no :use would have been reported.) Note that if cases-obj
; is nil, i.e., there was no :cases hint applied, then these next two
; are just nil. But we'll want to ignore them if cases-obj is nil.
; (splitting-terms (car cases-obj))
; (case-clauses (cdr cases-obj))
)
(fms
"~#0~[But we~/We~] ~#x~[split the goal into the cases specified ~
by the :CASES hint and augment each case~/augment the goal~] ~
with the ~#1~[hypothesis~/hypotheses~] provided by the :USE ~
hint. ~#1~[The hypothesis~/These hypotheses~] ~@2~#3~[~/; the ~
constraint~#4~[~/s~] can be simplified using ~*5~]. ~#6~[This ~
reduces the goal to T.~/We are left with the following ~
subgoal.~/We are left with the following ~n7 subgoals.~]~%"
(list
(cons #\x (if cases-obj 0 1))
(cons #\0 (if (> len-G 0) 1 0)) ;;; |G|>0
(cons #\1 hyps)
(cons #\2 (tilde-@-lmi-phrase lmi-lst k event-names))
(cons #\3 (if (> len-C 0) 1 0)) ;;; |C|>0
(cons #\4 (if (> len-C 1) 1 0)) ;;; |C|>1
(cons #\5 (tilde-*-preprocess-phrase preprocess-ttree))
(cons #\6 (if (equal len-G 0) 0 (if (equal len-G 1) 1 2)))
(cons #\7 len-G))
(proofs-co state)
state
(term-evisc-tuple nil state))))
((tagged-objectsp :cases ttree)
(let* ((cases-obj (tagged-object :cases ttree))
; The cases-obj here is of the form (term-list . new-clauses), where
; new-clauses is the result of splitting on the literals in term-list.
; (splitting-terms (car cases-obj))
(new-clauses (cdr cases-obj)))
(cond
(new-clauses
(fms "We now split the goal into the cases specified by ~
the :CASES hint to produce ~n0 new non-trivial ~
subgoal~#1~[~/s~].~|"
(list (cons #\0 (length new-clauses))
(cons #\1 (if (cdr new-clauses) 1 0)))
(proofs-co state)
state
(term-evisc-tuple nil state)))
(t
(fms "But the resulting goals are all true by case reasoning."
nil
(proofs-co state)
state
nil)))))
((eq signal 'OR-HIT)
(fms "~@0"
(list (cons #\0 (or-hit-msg nil cl-id ttree)))
(proofs-co state) state nil))
((tagged-objectsp 'hidden-clause ttree)
state)
((tagged-objectsp :clause-processor ttree)
(let* ((clause-processor-obj (tagged-object :clause-processor ttree))
; The clause-processor-obj here is produced by apply-top-hints-clause, and is
; of the form (clause-processor-hint . new-clauses), where new-clauses is the
; result of splitting on the literals in term-list and hint is the translated
; form of a :clause-processor hint.
(verified-p-msg (cond ((access clause-processor-hint
(car clause-processor-obj)
:verified-p)
"verified")
(t "trusted")))
(new-clauses (cdr clause-processor-obj))
(cl-proc-fn (ffn-symb (access clause-processor-hint
(car clause-processor-obj)
:term))))
(cond
(new-clauses
(fms "We now apply the ~@0 :CLAUSE-PROCESSOR function ~x1 to ~
produce ~n2 new subgoal~#3~[~/s~].~|"
(list (cons #\0 verified-p-msg)
(cons #\1 cl-proc-fn)
(cons #\2 (length new-clauses))
(cons #\3 (if (cdr new-clauses) 1 0)))
(proofs-co state)
state
(term-evisc-tuple nil state)))
(t
(fms "But the ~@0 :CLAUSE-PROCESSOR function ~x1 replaces this goal ~
by T.~|"
(list (cons #\0 verified-p-msg)
(cons #\1 cl-proc-fn))
(proofs-co state)
state
nil)))))
(t
; Normally we expect (tagged-object 'bddnote ttree) in this case, but it is
; possible that forward-chaining after trivial equivalence removal proved
; the clause, without actually resorting to bdd processing.
(simplify-clause-msg1 signal cl-id clauses speciousp ttree pspv
state))))
(defun previous-process-was-speciousp (hist)
; NOTE: This function has not been called since Version_2.5. However,
; we reference the comment below in a comment in settled-down-clause,
; so for now we keep this comment, if for no other other reason than
; historical.
; Context: We are about to print cl-id and clause in waterfall-msg.
; Then we will print the message associated with the first entry in
; hist, which is the entry for the processor which just hit clause and
; for whom we are reporting. However, if the previous entry in the
; history was specious, then the cl-id and clause were printed when
; the specious hit occurred and we should not reprint them. Thus, our
; job here is to decide whether the previous process in the history
; was specious.
; There are complications though, introduced by the existence of
; settled-down-clause. In the first place, settled-down-clause ALWAYS
; produces a set of clauses containing the input clause and so ought
; to be considered specious every time it hits! We avoid that in
; waterfall-step and never mark a settled-down-clause as specious, so
; we can assoc for them. More problematically, consider the
; possibility that the first simplification -- the one before the
; clause settled down -- was specious. Recall that the
; pre-settled-down-clause simplifications are weak. Thus, it is
; imaginable that after settling down, other simplifications may
; happen and allow a non-specious simplification. Thus,
; settled-down-clause actually does report its "hit" (and thus add its
; mark to the history so as to enable the subsequent simplify-clause
; to pull out the stops) following even specious simplifications.
; Thus, we must be prepared here to see a non-specious
; settled-down-clause which followed a specious simplification.
; Note: It is possible that the first entry on hist is specious. That
; is, if the process on behalf of which we are about to print is in
; fact specious, it is so marked right now in the history. But that
; is irrelevant to our question. We don't care if the current guy
; specious, we want to know if his "predecessor" was. For what it is
; worth, as of this writing, it is thought to be impossible for two
; adjacent history entries to be marked 'SPECIOUS. Only
; simplify-clause, we think, can produce specious hits. Whenever a
; specious simplify-clause occurs, it is treated as a 'miss and we go
; on to the next process, which is not simplify-clause. Note that if
; elim could produce specious 'hits, then we might get two in a row.
; Observe also that it is possible for two successive simplifies to be
; specious, but that they are separated by a non-specious
; settled-down-clause. (Our code doesn't rely on any of this, but it
; is sometimes helpful to be able to read such thoughts later as a
; hint of what we were thinking when we made some terrible coding
; mistake and so this might illuminate some error we're making today.)
(cond ((null hist) nil)
((null (cdr hist)) nil)
((consp (access history-entry (cadr hist) :processor)) t)
((and (eq (access history-entry (cadr hist) :processor)
'settled-down-clause)
(consp (cddr hist))
(consp (access history-entry (caddr hist) :processor)))
t)
(t nil)))
; Section: WATERFALL
; The waterfall is a simple finite state machine (whose individual
; state transitions are very complicated). Abstractly, each state
; contains a "processor" and two neighbor states, the "hit" state and
; the "miss" state. Roughly speaking, when we are in a state we apply
; its processor to the input clause and obtain either a "hit" signal
; (and some new clauses) or "miss" signal. We then transit to the
; appropriate state and continue.
; However, the "hit" state for every state is that point in the falls,
; where 'apply-top-hints-clause is the processor.
; apply-top-hints-clause <------------------+
; | |
; preprocess-clause ----------------------->|
; | |
; simplify-clause ------------------------->|
; | |
; settled-down-clause---------------------->|
; | |
; ... |
; | |
; push-clause ----------------------------->+
; WARNING: Waterfall1-lst knows that 'preprocess-clause follows
; 'apply-top-hints-clause!
; We therefore represent a state s of the waterfall as a pair whose car
; is the processor for s and whose cdr is the miss state for s. The hit
; state for every state is the constant state below, which includes, by
; successive cdrs, every state below it in the falls.
; Because the word "STATE" has a very different meaning in ACL2 than we have
; been using thus far in this discussion, we refer to the "states" of the
; waterfall as "ledges" and basically name them by the processors on each.
(defconst *preprocess-clause-ledge*
'(apply-top-hints-clause
preprocess-clause
simplify-clause
settled-down-clause
eliminate-destructors-clause
fertilize-clause
generalize-clause
eliminate-irrelevance-clause
push-clause))
; Observe that the cdr of the 'simplify-clause ledge, for example, is the
; 'settled-down-clause ledge, etc. That is, each ledge contains the
; ones below it.
; Note: To add a new processor to the waterfall you must add the
; appropriate entry to the *preprocess-clause-ledge* and redefine
; waterfall-step and waterfall-msg, below.
; If we are on ledge p with input cl and pspv, we apply processor p to
; our input and obtain signal, some cli, and pspv'. If signal is
; 'abort, we stop and return pspv'. If signal indicates a hit, we
; successively process each cli, starting each at the top ledge, and
; accumulating the successive pspvs starting from pspv'. If any cli
; aborts, we abort; otherwise, we return the final pspv. If signal is
; 'miss, we fall to the next lower ledge with cl and pspv. If signal
; is 'error, we return abort and propagate the error message upwards.
; Before we resume development of the waterfall, we introduce functions in
; support of gag-mode.
(defmacro initialize-pspv-for-gag-mode (pspv)
`(if (gag-mode)
(change prove-spec-var ,pspv
:gag-state
*initial-gag-state*)
,pspv))
; For debug only:
; (progn
;
; (defun show-gag-info-pushed (pushed state)
; (if (endp pushed)
; state
; (pprogn (let ((cl-id (caar pushed)))
; (fms "~@0 (~@1) pushed for induction.~|"
; (list (cons #\0 (tilde-@-pool-name-phrase
; (access clause-id cl-id :forcing-round)
; (cdar pushed)))
; (cons #\1 (tilde-@-clause-id-phrase cl-id)))
; *standard-co* state nil))
; (show-gag-info-pushed (cdr pushed) state))))
;
; (defun show-gag-info (info state)
; (pprogn (fms "~@0:~%~Q12~|~%"
; (list (cons #\0 (tilde-@-clause-id-phrase
; (access gag-info info :clause-id)))
; (cons #\1 (access gag-info info :clause))
; (cons #\2 nil))
; *standard-co* state nil)
; (show-gag-info-pushed (access gag-info info :pushed)
; state)))
;
; (defun show-gag-stack (stack state)
; (if (endp stack)
; state
; (pprogn (show-gag-info (car stack) state)
; (show-gag-stack (cdr stack) state))))
;
; (defun show-gag-state (cl-id gag-state state)
; (let* ((top-stack (access gag-state gag-state :top-stack))
; (sub-stack (access gag-state gag-state :sub-stack))
; (clause-id (access gag-state gag-state :active-cl-id))
; (printed-p (access gag-state gag-state
; :active-printed-p)))
; (pprogn (fms "********** Gag state from handling ~@0 (active ~
; clause id: ~#1~[<none>~/~@2~])~%"
; (list (cons #\0 (tilde-@-clause-id-phrase cl-id))
; (cons #\1 (if clause-id 1 0))
; (cons #\2 (and clause-id (tilde-@-clause-id-phrase
; clause-id))))
; *standard-co* state nil)
; (fms "****** Top-stack:~%" nil *standard-co* state nil)
; (show-gag-stack top-stack state)
; (fms "****** Sub-stack:~%" nil *standard-co* state nil)
; (show-gag-stack sub-stack state)
; (fms "****** Active-printed-p: ~x0"
; (list (cons #\0 (access gag-state gag-state
; :active-printed-p)))
; *standard-co* state nil)
; (fms "****** Forcep: ~x0"
; (list (cons #\0 (access gag-state gag-state
; :forcep)))
; *standard-co* state nil)
; (fms "******************************~|" nil *standard-co* state
; nil))))
;
; (defun maybe-show-gag-state (cl-id pspv state)
; (if (and (f-boundp-global 'gag-debug state)
; (f-get-global 'gag-debug state))
; (show-gag-state cl-id
; (access prove-spec-var pspv :gag-state)
; state)
; state))
; )
(defun waterfall-update-gag-state (cl-id clause proc signal ttree pspv
state)
; We are given a clause-id, cl-id, and a corresponding clause. Processor proc
; has operated on this clause and returned the given signal (either 'abort or a
; hit indicator), ttree, and pspv. We suitably extend the gag-state of
; the pspv and produce a message to print before any normal prover output that
; is allowed under gag-mode.
; Thus, we return (mv gagst msg), where gagst is either nil or a new gag-state
; obtained by updating the :gag-state field of pspv, and msg is a message to be
; printed or else nil. If msg is not nil, then its printer is expected to
; insert a newline before printing msg.
(let* ((msg-p (not (output-ignored-p 'prove state)))
(gagst0 (access prove-spec-var pspv :gag-state))
(pool-lst (access clause-id cl-id :pool-lst))
(forcing-round (access clause-id cl-id :forcing-round))
(stack (cond (pool-lst (access gag-state gagst0 :sub-stack))
(t (access gag-state gagst0 :top-stack))))
(active-cl-id (access gag-state gagst0 :active-cl-id))
(abort-p (eq signal 'abort))
(push-or-bye-p (or (eq proc 'push-clause)
(and (eq proc 'apply-top-hints-clause)
(eq signal 'hit)
(tagged-objectsp :bye ttree))))
(new-active-p ; true if we are to push a new gag-info frame
(and (null active-cl-id)
(null (cdr pool-lst)) ; not in a sub-induction
(or push-or-bye-p ; even if the next test fails
(member-eq proc (f-get-global 'checkpoint-processors
state)))))
(new-frame (and new-active-p
(make gag-info
:clause-id cl-id
:clause clause
:pushed nil)))
(new-stack (cond (new-active-p (cons new-frame stack))
(t stack)))
(gagst (cond (new-active-p (cond (pool-lst
(change gag-state gagst0
:sub-stack new-stack
:active-cl-id cl-id))
(t
(change gag-state gagst0
:top-stack new-stack
:active-cl-id cl-id))))
(t gagst0)))
(new-forcep (and (not abort-p)
(not (access gag-state gagst :forcep))
(tagged-objectsp 'assumption ttree)))
(gagst (cond (new-forcep (change gag-state gagst :forcep t))
(t gagst)))
(forcep-msg (and new-forcep
msg-p
(msg "Forcing Round ~x0 is pending (caused first by ~
~@1)."
(1+ (access clause-id cl-id :forcing-round))
(tilde-@-clause-id-phrase cl-id)))))
(cond
(push-or-bye-p
(let* ((top-ci (assert$ (consp new-stack)
(car new-stack)))
(old-pushed (access gag-info top-ci :pushed))
(top-goal-p (equal cl-id *initial-clause-id*))
(print-p
; We avoid gag's key checkpoint message if we are in a sub-induction or if we
; are pushing the initial goal for proof by induction. The latter case is
; handled similarly in the call of waterfall1-lst under waterfall.
(not (or (access gag-state gagst :active-printed-p)
(cdr pool-lst)
top-goal-p)))
(gagst (cond (print-p (change gag-state gagst
:active-printed-p t))
(t gagst)))
(top-stack (access gag-state gagst0 :top-stack))
(msg0 (cond
((and print-p msg-p)
(assert$
(null old-pushed)
(msg "~@0~|~%~@1~|~Q23~|~%"
(gag-start-msg
(and pool-lst
(assert$
(consp top-stack)
(access gag-info (car top-stack)
:clause-id)))
(and pool-lst
(tilde-@-pool-name-phrase
forcing-round
pool-lst)))
(tilde-@-clause-id-phrase
(access gag-info top-ci :clause-id))
(prettyify-clause
(access gag-info top-ci :clause)
(let*-abstractionp state)
(w state))
(term-evisc-tuple nil state))))
(t nil))))
(cond
(abort-p
(mv (cond ((equal (tagged-objects 'abort-cause ttree)
'(revert))
(change gag-state gagst :abort-stack new-stack))
((equal (tagged-objects 'abort-cause ttree)
'(empty-clause))
(change gag-state gagst :abort-stack 'empty-clause))
(t gagst))
(and msg-p
(msg "~@0~@1"
(or msg0 "")
(push-clause-msg1-abort cl-id ttree pspv state)))))
(t (let* ((old-pspv-pool-lst
(pool-lst (cdr (access prove-spec-var pspv :pool))))
(newer-stack
(and (assert$
(or (cdr pool-lst) ;sub-induction; no active chkpt
(equal (access gag-state gagst
:active-cl-id)
(access gag-info top-ci
:clause-id)))
(if (eq proc 'push-clause)
(cons (change gag-info top-ci
:pushed
(cons (cons cl-id old-pspv-pool-lst)
old-pushed))
(cdr new-stack))
new-stack)))))
(mv (cond (pool-lst
(change gag-state gagst :sub-stack
newer-stack))
(t
(change gag-state gagst :top-stack
newer-stack)))
(and
msg-p
(or msg0 forcep-msg (gag-mode))
(msg "~@0~#1~[~@2~|~%~/~]~@3"
(or msg0 "")
(if forcep-msg 0 1)
forcep-msg
(cond
((null (gag-mode))
"")
(t
(let ((msg-finish
(cond ((or pool-lst ; pushed for sub-induction
(null active-cl-id))
".")
(t (msg ":~|~Q01."
(prettyify-clause
clause
(let*-abstractionp state)
(w state))
(term-evisc-tuple nil state))))))
(cond
((eq proc 'push-clause)
(msg "~@0 (~@1) is pushed for proof by ~
induction~@2"
(tilde-@-pool-name-phrase
forcing-round
old-pspv-pool-lst)
(if top-goal-p
"the initial Goal, a key checkpoint"
(tilde-@-clause-id-phrase cl-id))
msg-finish))
(t
(msg "~@0 is subsumed by a goal yet to be ~
proved~@1"
(tilde-@-clause-id-phrase cl-id)
msg-finish))))))))))))))
(t (assert$ (not abort-p) ; we assume 'abort is handled above
(mv (cond ((or new-active-p new-forcep)
gagst)
(t nil))
forcep-msg))))))
#+acl2-par
(defun waterfall-update-gag-state@par (cl-id clause proc signal ttree pspv state)
(declare (ignore cl-id clause proc signal ttree pspv state))
; Parallelism blemish: consider causing an error when the user tries to enable
; gag mode. At the moment I'm unsure of the effects of returning two nils in
; this case.
(mv nil nil))
(defun@par record-gag-state (gag-state state)
(declare (ignorable gag-state state))
(serial-first-form-parallel-second-form@par
(f-put-global 'gag-state gag-state state)
nil))
(defun@par gag-state-exiting-cl-id (signal cl-id pspv state)
; If cl-id is the active clause-id for the current gag-state, then we
; deactivate it. We also eliminate the corresponding stack frame, if any,
; provided no goals were pushed for proof by induction.
(declare (ignorable signal cl-id pspv state))
(serial-first-form-parallel-second-form@par
(let* ((gagst0 (access prove-spec-var pspv :gag-state))
(active-cl-id (access gag-state gagst0 :active-cl-id)))
(cond ((equal cl-id active-cl-id)
(let* ((pool-lst (access clause-id cl-id :pool-lst))
(stack (cond (pool-lst
(access gag-state gagst0 :sub-stack))
(t
(access gag-state gagst0 :top-stack))))
(ci (assert$ (consp stack)
(car stack)))
(current-cl-id (access gag-info ci :clause-id))
(printed-p (access gag-state gagst0 :active-printed-p))
(gagst1 (cond (printed-p (change gag-state gagst0
:active-cl-id nil
:active-printed-p nil))
(t (change gag-state gagst0
:active-cl-id nil))))
(gagst2 (cond
((eq signal 'abort)
(cond
((equal (tagged-objects
'abort-cause
(access prove-spec-var pspv :tag-tree))
'(revert))
(change gag-state gagst1 ; save abort info
:active-cl-id nil
:active-printed-p nil
:forcep nil
:sub-stack nil
:top-stack
(list
(make gag-info
:clause-id *initial-clause-id*
:clause (list '<Goal>)
:pushed
(list (cons *initial-clause-id*
'(1)))))))
(t gagst1)))
((and (equal cl-id current-cl-id)
(null (access gag-info ci
:pushed)))
(cond (pool-lst
(change gag-state gagst1
:sub-stack (cdr stack)))
(t
(change gag-state gagst1
:top-stack (cdr stack)))))
(t gagst1))))
(pprogn
(record-gag-state gagst2 state)
(cond (printed-p
(io? prove nil state nil
(pprogn
(increment-timer 'prove-time state)
(cond ((gag-mode)
(fms "~@0"
(list (cons #\0 *gag-suffix*))
(proofs-co state) state nil))
(t state))
(increment-timer 'print-time state))))
(t state))
(mv (change prove-spec-var pspv
:gag-state gagst2)
state))))
(t (mv pspv state))))
(mv@par pspv state)))
(defun remove-pool-lst-from-gag-state (pool-lst gag-state state)
#-acl2-par
(declare (ignore state))
(cond
#+acl2-par
((f-get-global 'waterfall-parallelism state)
; This function contains an assertion that fails when executing the waterfall
; in parallel. The assertion fails because parallelism mode doesn't save the
; data required to make gag-mode work, and the assertion tests the gag-mode
; state for being in a reasonable condition.
; Based upon a simple test using :mini-proveall, it appears that switching
; gag-mode on and off, and switching between different waterfall parallelism
; modes does not result in a system breakage.
(mv nil nil))
(t
; The proof attempt for the induction goal represented by pool-lst has been
; completed. We return two values, (mv gagst cl-id), as follows. Gagst is the
; result of removing pool-lst from the given gag-state. Cl-id is nil unless
; pool-lst represents the final induction goal considered that was generated
; under a key checkpoint, in which case cl-id is the clause-id of that key
; checkpoint.
(let* ((sub-stack (access gag-state gag-state :sub-stack))
(stack (or sub-stack (access gag-state gag-state
:top-stack))))
(assert$ (consp stack)
(let* ((ci (car stack))
(pushed (access gag-info ci :pushed))
(pop-car-p (null (cdr pushed))))
(assert$
(and (consp pushed)
(equal (cdar pushed) pool-lst)
(not (access gag-state gag-state
:active-cl-id)))
(let ((new-stack
(if pop-car-p
(cdr stack)
(cons (change gag-info ci
:pushed
(cdr pushed))
(cdr stack)))))
(mv (cond (sub-stack
(change gag-state gag-state
:sub-stack new-stack))
(t
(change gag-state gag-state
:top-stack new-stack)))
(and pop-car-p
(access gag-info ci :clause-id)))))))))))
(defun pop-clause-update-gag-state-pop (pool-lsts gag-state msgs msg-p state)
; Pool-lsts is in reverse chronological order.
(cond
((endp pool-lsts)
(mv gag-state msgs))
(t
(mv-let
(gag-state msgs)
(pop-clause-update-gag-state-pop (cdr pool-lsts) gag-state msgs msg-p
state)
(mv-let (gagst cl-id)
(remove-pool-lst-from-gag-state (car pool-lsts) gag-state state)
(mv gagst
(if (and msg-p cl-id)
(cons (msg "~@0"
(tilde-@-clause-id-phrase cl-id))
msgs)
msgs)))))))
(defun gag-mode-jppl-flg (gag-state)
(let ((stack (or (access gag-state gag-state :sub-stack)
(access gag-state gag-state :top-stack))))
(cond (stack
(let* ((pushed (access gag-info (car stack) :pushed))
(pool-lst (and pushed (cdar pushed))))
; Notice that pool-lst is nil if pushed is nil, as can happen when we abort due
; to encountering an empty clause.
(and (null (cdr pool-lst)) ; sub-induction goal was not printed
pool-lst)))
(t nil))))
; That completes basic support for gag-mode. We now resume mainline
; development of the waterfall.
; The waterfall also manages the output, by case switching on the processor.
; The function waterfall-msg1 handles the printing of the formula and the
; output for those processes that hit.
(defmacro splitter-output ()
`(and (f-get-global 'splitter-output state)
(not (member-eq 'prove
(f-get-global 'inhibit-output-lst state)))))
(defmacro set-splitter-output (val)
`(f-put-global 'splitter-output ,val state))
(defun waterfall-msg1 (processor cl-id signal clauses new-hist msg ttree pspv
state)
(with-output-lock
(let ((gag-mode (gag-mode)))
(pprogn
; (maybe-show-gag-state cl-id pspv state) ; debug
(cond
; Suppress printing for :OR splits; see also other comments with this header.
; ((and (eq signal 'OR-HIT)
; gag-mode)
; (fms "~@0~|~%~@1~|"
; (list (cons #\0 (or msg ""))
; (cons #\1 (or-hit-msg t cl-id ttree)))
; (proofs-co state) state nil))
((and msg (gag-mode))
(fms "~@0~|" (list (cons #\0 msg)) (proofs-co state) state nil))
(t state))
(cond
((or (gag-mode)
(f-get-global 'raw-proof-format state))
(print-splitter-rules-summary cl-id clauses ttree (proofs-co state)
state))
(t state))
(cond
(gag-mode state)
(t
(case
processor
(apply-top-hints-clause
; Note that the args passed to apply-top-hints-clause, and to
; simplify-clause-msg1 below, are nonstandard. This is what allows the
; simplify message to detect and report if the just performed simplification
; was specious.
(apply-top-hints-clause-msg1
signal cl-id clauses
(consp (access history-entry (car new-hist)
:processor))
ttree pspv state))
(preprocess-clause
(preprocess-clause-msg1 signal clauses ttree pspv state))
(simplify-clause
(simplify-clause-msg1 signal cl-id clauses
(consp (access history-entry (car new-hist)
:processor))
ttree pspv state))
(settled-down-clause
(settled-down-clause-msg1 signal clauses ttree pspv state))
(eliminate-destructors-clause
(eliminate-destructors-clause-msg1 signal clauses ttree
pspv state))
(fertilize-clause
(fertilize-clause-msg1 signal clauses ttree pspv state))
(generalize-clause
(generalize-clause-msg1 signal clauses ttree pspv state))
(eliminate-irrelevance-clause
(eliminate-irrelevance-clause-msg1 signal clauses ttree
pspv state))
(otherwise
(push-clause-msg1 cl-id signal clauses ttree pspv state)))))))))
(defmacro io?-prove-cw (vars body &rest keyword-args)
; This macro is a version of io?-prove that prints to the comment window using
; wormholes.
; Keep in sync with io?-prove.
`(io? prove t state ,vars
(if (gag-mode) state ,body)
,@keyword-args))
#+acl2-par
(defmacro io?-prove@par (&rest rst)
; This macro is the approved way to produce proof output with
; waterfall-parallelism enabled.
`(io?-prove-cw ,@rst))
(defun waterfall-print-clause-body (cl-id clause state)
(with-output-lock
(pprogn
(increment-timer 'prove-time state)
(fms "~@0~|~q1.~|"
(list (cons #\0 (tilde-@-clause-id-phrase cl-id))
(cons #\1 (prettyify-clause
clause
(let*-abstractionp state)
(w state))))
(proofs-co state)
state
(term-evisc-tuple nil state))
(increment-timer 'print-time state))))
(defmacro waterfall-print-clause-id-fmt1-call (cl-id)
; Keep in sync with waterfall-print-clause-id-fmt1-call@par.
`(mv-let (col state)
(fmt1 "~@0~|"
(list (cons #\0
(tilde-@-clause-id-phrase ,cl-id)))
0 (proofs-co state) state nil)
(declare (ignore col))
state))
#+acl2-par
(defmacro waterfall-print-clause-id-fmt1-call@par (cl-id)
; Keep in sync with waterfall-print-clause-id-fmt1-call.
`(with-output-lock
(mv-let (col state)
(fmt1 "~@0~|"
(list (cons #\0
(tilde-@-clause-id-phrase ,cl-id)))
0 (proofs-co state) state nil)
(declare (ignore col state))
nil)))
(defmacro waterfall-print-clause-id (cl-id)
`(pprogn
(increment-timer 'prove-time state)
(waterfall-print-clause-id-fmt1-call ,cl-id)
(increment-timer 'print-time state)))
#+acl2-par
(defmacro waterfall-print-clause-id@par (cl-id)
; Parallelism wart: wormhole printing isn't reliable. (When this wart is
; removed, then remove the references to it in
; unsupported-waterfall-parallelism-features and
; waterfall1-wrapper@par-before.) We lock wormholes at a very high level, so
; we thought they might be thread safe. However, in practice, when we enable
; printing through wormholes, there are problems symptomatic of race
; conditions. We think these problems are related to the ld-special variables.
; Specifically, a thread tries to read from the prompt upon entering the
; wormhole, even if there isn't supposed to be any interaction with the prompt.
; A possible solution to this problem might involve implementing all of the
; ld-specials with global variables (as opposed to propsets), and then
; rebinding those global variables in each worker thread. Long story short:
; wormholes might be thread-safe, but we have lots of reasons to believe they
; aren't.
; Therefore, we have different versions of the present macro for the
; #+acl2-loop-only and #-acl2-loop-only cases. To see why, first note that
; waterfall-print-clause-id-fmt1-call does printing, hence returns state. As
; such, the #+acl2-loop-only code (where state is not available) performs the
; printing inside a wormhole. However, because of the parallelism wart above,
; we avoid the wormhole call in the #-acl2-loop-only case, which is the
; actually executed inside the prover.
#+acl2-loop-only
`(wormhole 'comment-window-io
'(lambda (whs)
(set-wormhole-entry-code whs :ENTER))
(list ,cl-id)
'(mv-let (col state)
(waterfall-print-clause-id-fmt1-call ,cl-id)
(declare (ignore col))
(value :q))
:ld-error-action :return! ; might cause problems
:ld-verbose nil
:ld-pre-eval-print nil
:ld-prompt nil)
#-acl2-loop-only
`(waterfall-print-clause-id-fmt1-call@par ,cl-id))
(defproxy print-clause-id-okp (*) => *)
(defun print-clause-id-okp-builtin (cl-id)
(declare (ignore cl-id)
(xargs :guard (clause-id-p cl-id)))
t)
(defattach (print-clause-id-okp print-clause-id-okp-builtin)
:skip-checks t)
(defun@par waterfall-print-clause (suppress-print cl-id clause state)
(cond ((or suppress-print (equal cl-id *initial-clause-id*))
(state-mac@par))
((serial-first-form-parallel-second-form@par
nil
(member-equal (f-get-global 'waterfall-printing state)
'(:limited :very-limited)))
(state-mac@par))
(t (pprogn@par
(if (and (or (gag-mode)
(member-eq 'prove
(f-get-global 'inhibit-output-lst state)))
(f-get-global 'print-clause-ids state)
(print-clause-id-okp cl-id))
(waterfall-print-clause-id@par cl-id)
(state-mac@par))
(io?-prove@par
(cl-id clause)
(waterfall-print-clause-body cl-id clause state))))))
#+acl2-par
(defun some-parent-is-checkpointp (hist state)
(cond ((endp hist)
nil)
((member (access history-entry (car hist) :processor)
(f-get-global 'checkpoint-processors state))
t)
(t (some-parent-is-checkpointp (cdr hist) state))))
(defun@par waterfall-msg
(processor cl-id clause signal clauses new-hist ttree pspv state)
; This function prints the report associated with the given processor on some
; input clause, clause, with output signal, clauses, ttree, and pspv. The code
; below consists of two distinct parts. First we print the message associated
; with the particular processor. Then we return three results: a "jppl-flg", a
; new pspv with the gag-state updated, and the state.
; The jppl-flg is either nil or a pool-lst. When non-nil, the jppl-flg means
; we just pushed a clause into the pool and assigned it the name that is the
; value of the flag. "Jppl" stands for "just pushed pool list". This flag is
; passed through the waterfall and eventually finds its way to the pop-clause
; after the waterfall, where it is used to control the optional printing of the
; popped clause. If the jppl-flg is non-nil when we pop, it means we need not
; re-display the clause because it was just pushed and we can refer to it by
; name.
; This function increments timers. Upon entry, the accumulated time is charged
; to 'prove-time. The time spent in this function is charged to 'print-time.
(declare (ignorable new-hist clauses))
(pprogn@par
(increment-timer@par 'prove-time state)
(serial-only@par
(io? proof-tree nil state
(pspv signal new-hist clauses processor ttree cl-id)
(pprogn
(increment-proof-tree
cl-id ttree processor (length clauses) new-hist signal pspv state)
(increment-timer 'proof-tree-time state))))
(mv-let
(gagst msg)
(waterfall-update-gag-state@par cl-id clause processor signal ttree pspv
state)
(declare (ignorable msg))
(mv-let@par
(pspv state)
(cond (gagst (pprogn@par (record-gag-state@par gagst state)
(mv@par (change prove-spec-var pspv :gag-state
gagst)
state)))
(t (mv@par pspv state)))
(pprogn@par
(serial-first-form-parallel-second-form@par
(io? prove nil state
(pspv ttree new-hist clauses signal cl-id processor msg)
(waterfall-msg1 processor cl-id signal clauses new-hist msg ttree
pspv state))
; Parallelism wart: consider replacing print-splitter-rules-summary below. A
; version of printing that does not involve wormholes will be required. See
; book parallel/proofs/stress-waterfall-parallelism.lsp. Note that it is
; unclear to Rager whether the :limited (or nil) version of waterfall-printing
; should print splitter-rules. :Limited waterfall-printing should probably
; follow whatever gag-mode does.
; We could similarly comment out the :full case just below, since it also uses
; wormholes. But we prefer to leave it, noting that :full is primarily used by
; developers.
(cond ((equal (f-get-global 'waterfall-printing state) :full)
(io? prove t
state
(pspv ttree new-hist clauses signal cl-id processor msg)
(waterfall-msg1 processor cl-id signal clauses new-hist msg
ttree pspv state)))
(t 'nothing-to-print
; (io? prove t
; state
; (cl-id ttree clauses)
; (print-splitter-rules-summary
; cl-id clauses ttree (proofs-co state) state))
)))
(increment-timer@par 'print-time state)
(mv@par (cond ((eq processor 'push-clause)
; Keep the following in sync with the corresponding call of pool-lst in
; waterfall0-or-hit. See the comment there.
(pool-lst (cdr (access prove-spec-var pspv :pool))))
(t nil))
pspv
state))))))
; The waterfall is responsible for storing the ttree produced by each
; processor in the pspv. That is done with:
(defun put-ttree-into-pspv (ttree pspv)
(change prove-spec-var pspv
:tag-tree (cons-tag-trees ttree
(access prove-spec-var pspv :tag-tree))))
(defun set-cl-ids-of-assumptions1 (recs cl-id)
(cond ((endp recs) nil)
(t (cons (change assumption (car recs)
:assumnotes
(list (change assumnote
(car (access assumption (car recs)
:assumnotes))
:cl-id cl-id)))
(set-cl-ids-of-assumptions1 (cdr recs) cl-id)))))
(defun set-cl-ids-of-assumptions (ttree cl-id)
; We scan the tag-tree ttree, looking for 'assumptions. Recall that each has a
; :assumnotes field containing exactly one assumnote record, which contains a
; :cl-id field. We assume that :cl-id field is empty. We put cl-id into it.
; We return a copy of ttree.
(let ((recs (tagged-objects 'assumption ttree)))
(cond (recs (extend-tag-tree
'assumption
(set-cl-ids-of-assumptions1 recs cl-id)
(remove-tag-from-tag-tree! 'assumption ttree)))
(t ttree))))
; We now develop the code for proving the assumptions that are forced during
; the first part of the proof. These assumptions are all carried in the ttree
; on 'assumption tags. (Delete-assumptions was originally defined just below
; collect-assumptions, but has been moved up since it is used in push-clause.)
(defun collect-assumptions1 (recs only-immediatep ans)
(cond ((endp recs) ans)
(t (collect-assumptions1
(cdr recs)
only-immediatep
(cond ((cond
((eq only-immediatep 'non-nil)
(access assumption (car recs) :immediatep))
((eq only-immediatep 'case-split)
(eq (access assumption (car recs) :immediatep)
'case-split))
((eq only-immediatep t)
(eq (access assumption (car recs) :immediatep)
t))
(t t))
(add-to-set-equal (car recs) ans))
(t ans))))))
(defun collect-assumptions (ttree only-immediatep)
; We collect the assumptions in ttree and accumulate them onto ans.
; Only-immediatep determines exactly which assumptions we collect:
; * 'non-nil -- only collect those with :immediatep /= nil
; * 'case-split -- only collect those with :immediatep = 'case-split
; * t -- only collect those with :immediatep = t
; * nil -- collect ALL assumptions
(collect-assumptions1 (tagged-objects 'assumption ttree) only-immediatep
nil))
; We are now concerned with trying to shorten the type-alists used to
; govern assumptions. We have two mechanisms. One is
; ``disguarding,'' the throwing out of any binding whose term
; requires, among its guard clauses, the truth of the term we are
; trying to prove. The second is ``disvaring,'' the throwing out of
; any binding that does not mention any variable linked to term.
; First, disguarding... We must first define the fundamental process
; of generating the guard clauses for a term. This "ought" to be in
; the vicinity of our definition of defun and verify-guards. But we
; need it now.
; NOTE: Conjoin-clause-sets+ and some other relevant functions were once
; defined here, but have been moved to history-management.lisp in order to
; support the definition of termination-theorem-clauses and
; guard-clauses-for-clique.
; And now disvaring...
(defun linked-variables1 (vars direct-links changedp direct-links0)
; We union into vars those elements of direct-links that overlap its
; current value. When we have done them all we ask if anything
; changed and if so, start over at the beginning of direct-links.
(cond
((null direct-links)
(cond (changedp (linked-variables1 vars direct-links0 nil direct-links0))
(t vars)))
((and (intersectp-eq (car direct-links) vars)
(not (subsetp-eq (car direct-links) vars)))
(linked-variables1 (union-eq (car direct-links) vars)
(cdr direct-links)
t direct-links0))
(t (linked-variables1 vars (cdr direct-links) changedp direct-links0))))
(defun linked-variables (vars direct-links)
; Vars is a list of variables. Direct-links is a list of lists of
; variables, e.g., '((X Y) (Y Z) (A B) (M)). Let's say that one
; variable is "directly linked" to another if they both appear in one
; of the lists in direct-links. Thus, above, X and Y are directly
; linked, as are Y and Z, and A and B. This function returns the list
; of all variables that are linked (directly or transitively) to those
; in vars. Thus, in our example, if vars is '(X) the answer is '(X Y
; Z), up to order of appearance.
; Note on Higher Order Definitions and the Inconvenience of ACL2:
; Later in these sources we will define the "mate and merge" function,
; m&m, which computes certain kinds of transitive closures. We really
; wish we had that function now, because this function could use it
; for the bulk of this computation. But we can't define it here
; without moving up some of the data structures associated with
; induction. Rather than rip our code apart, we define a simple
; version of m&m that does the job.
; This suggests that we really ought to support the idea of defining a
; function before all of its subroutines are defined -- a feature that
; ultimately involves the possibility of implicit mutual recursion.
; It should also be noted that the problem with moving m&m is not so
; much with the code for the mate and merge process as it is with the
; pseudo functional argument it takes. M&m naturally is a higher
; order function that compute the transitive closure of an operation
; supplied to it. Because ACL2 is first order, our m&m doesn't really
; take a function but rather a symbol and has a finite table mapping
; symbols to functions (m&m-apply). It is only that table that we
; can't move up to here! So if ACL2 were higher order, we could
; define m&m now and everything would be neat. Of course, if ACL2
; were higher order, we suspect some other aspects of our coding
; (perhaps efficiency and almost certainly theorem proving power)
; would be degraded.
(linked-variables1 vars direct-links nil direct-links))
; Part of disvaring a type-alist to is keep type-alist entries about
; constrained constants. This goes to a problem that Eric Smith noted.
; He had constrained (thebit) to be 0 or 1 and had a type-alist entry
; stating that (thebit) was not 0. In a forcing round he needed that
; (thebit) was 1. But disvaring had thrown out of the type-alist the
; entry for (thebit) because it did not mention any of the relevant
; variables. So, in a change for Version_2.7 we now keep entries that
; mention constrained constants. We considered the idea of keeping
; entries that mention any constrained function, regardless of arity.
; But that seems like overkill. Had Eric constrained (thebit x) to
; be 0 or 1 and then had a hypothesis that it was not 0, it seems
; unlikely that the forcing round would need to know (thebit x) is 1
; if x is not among the relevant vars. That is, one assumes that if a
; constrained function has arguments then the function's behavior on
; those arguments does not determine the function's behavior on other
; arguments. This need not be the case. One can constrain (thebit x)
; so that if it is 0 on some x then it is 0 on all x.
; (implies (equal (thebit x) 0) (equal (thebit y) 0))
; But this seems unlikely.
(mutual-recursion
(defun contains-constrained-constantp (term wrld)
(cond ((variablep term) nil)
((fquotep term) nil)
((flambda-applicationp term)
(or (contains-constrained-constantp-lst (fargs term) wrld)
(contains-constrained-constantp (lambda-body (ffn-symb term))
wrld)))
((and (getpropc (ffn-symb term) 'constrainedp nil wrld)
(null (getpropc (ffn-symb term) 'formals t wrld)))
t)
(t (contains-constrained-constantp-lst (fargs term) wrld))))
(defun contains-constrained-constantp-lst (lst wrld)
(cond ((null lst) nil)
(t (or (contains-constrained-constantp (car lst) wrld)
(contains-constrained-constantp-lst (cdr lst) wrld))))))
; So now we can define the notion of ``disvaring'' a type-alist.
(defun disvar-type-alist1 (vars type-alist wrld)
(cond ((null type-alist) nil)
((or (intersectp-eq vars (all-vars (caar type-alist)))
(contains-constrained-constantp (caar type-alist) wrld))
(cons (car type-alist)
(disvar-type-alist1 vars (cdr type-alist) wrld)))
(t (disvar-type-alist1 vars (cdr type-alist) wrld))))
(defun collect-all-vars (lst)
(cond ((null lst) nil)
(t (cons (all-vars (car lst)) (collect-all-vars (cdr lst))))))
(defun disvar-type-alist (type-alist term wrld)
; We throw out of type-alist any binding that does not involve a
; variable linked by type-alist to those in term. Thus, if term
; involves only the variables X and Y and type-alist binds a term that
; links Y to Z (and nothing else is linked to X, Y, or Z), then the
; resulting type-alist only binds terms containing X, Y, and/or Z.
; We actually keep entries about constrained constants.
; As we did for ``disguard'' we apologize for (but stand by) the
; non-word ``disvar.''
(let* ((vars (all-vars term))
(direct-links (collect-all-vars (strip-cars type-alist)))
(vars* (linked-variables vars direct-links)))
(disvar-type-alist1 vars* type-alist wrld)))
; Finally we can define the notion of ``unencumbering'' a type-alist.
; But as pointed out below, we no longer use this notion.
(defun unencumber-type-alist (type-alist term rewrittenp wrld)
; We wish to prove term under type-alist. If rewrittenp is non-nil,
; it is also a term, namely the unrewritten term from which we
; obtained term. Generally, term (actually its unrewritten version)
; is some conjunct from a guard. In many cases we expect term to be
; something very simple like (RATIONALP X). But chances are high that
; type- alist talks about many other variables and many irrelevant
; terms. We wish to throw out irrelevant bindings from type-alist and
; return a new type-alist that is weaker but, we believe, as
; sufficient as the original for proving term. We call this
; ``unencumbering'' the type-alist.
; The following paragraph is inaccurate because we no longer use
; disguarding.
; Historical Comment:
; We apply two different techniques. The first is ``disguarding.''
; Roughly, the idea is to throw out the binding of any term that
; requires the truth of term in its guard. Since we are trying to
; prove term true we will assume it false. If a hypothesis in the
; type-alist requires term to get past the guard, we'll never do it.
; This is not unlikely since term is (probably) a forced guard from
; the very clause from which type-alist was created.
; End of Historical Comment
; The second technique, applied after disguarding, is to throw out any
; binding of a term that is not linked to the variables used by term.
; For example, if term is (RATIONALP X) then we won't keep a
; hypothesis about (PRIMEP Y) unless some kept hypothesis links X and
; Y. This is called ``disvaring'' and is applied after diguarding
; because the terms thrown out by disguarding are likely to link
; variables in a bogus way. For example, (< X Y) would link X and Y,
; but is thrown out by disguarding since it requires (RATIONALP X).
; While disvaring, we actually keep type-alist entries about constrained
; constants.
(declare (ignore rewrittenp))
(disvar-type-alist
type-alist
term
wrld))
(defun unencumber-assumption (assn wrld)
; We no longer unencumber assumptions. An example from Jared Davis prompted
; this change, in which he had contradictory hypotheses for which the
; contradiction was not yet evident after a round of simplification, leading to
; premature forcing -- and the contradiction was in hypotheses about variables
; irrelevant to what was forced, and hence was lost in the forcing round! Here
; is a much simpler example of that phenomenon.
; (defstub p1 (x) t)
; (defstub p2 (x) t)
; (defstub p3 (x) t)
; (defstub p4 (x) t)
;
; (defaxiom p1->p2
; (implies (p1 x)
; (p2 x)))
;
; (defun foo (x y)
; (implies x y))
;
; (defaxiom p3->p4{forced}
; (implies (force (p3 x))
; (p4 x)))
;
; ; When we unencumber the type-alist upon forcing, the following THM fails with
; ; the following forcing round. The problem is that the hypothesis about x is
; ; dropped because it is deemed (by unencumber-type-alist) to be irrelevant to
; ; the sole variable y of the forced hypothesis.
;
; ; We now undertake Forcing Round 1.
; ;
; ; [1]Goal
; ; (P3 Y).
;
; (thm (if (not (foo (p1 x) (p2 x)))
; (p4 y)
; t)
; :hints (("Goal" :do-not '(preprocess)
; :in-theory (disable foo))))
;
; ; But with unencumber-assumption defined to return its first argument, the THM
; ; produces a forced goal that includes the contradictory hypotheses:
;
; ; [1]Goal
; ; (IMPLIES (NOT (FOO (P1 X) (P2 X)))
; ; (P3 Y)).
;
; (thm (if (not (foo (p1 x) (p2 x)))
; (p4 y)
; t)
; :hints (("Goal" :do-not '(preprocess)
; :in-theory (disable foo))))
; Old comment and code:
; Given an assumption we try to unencumber (i.e., shorten) its
; :type-alist. We return an assumption that may be proved in place of
; assn and is supposedly simpler to prove.
; (change assumption assn
; :type-alist
; (unencumber-type-alist (access assumption assn :type-alist)
; (access assumption assn :term)
; (access assumption assn :rewrittenp)
; wrld))
(declare (ignore wrld))
assn)
(defun unencumber-assumptions (assumptions wrld ans)
; This is just a glorified list reverse function! At one time we actually did
; unencumber assumptions, but now, unencumber-assumption is defined simply to
; return nil, as explained in a comment in its definition. A more elegant fix
; is to redefine the present function to return assumptions unchanged, to avoid
; consing up a reversed list. However, we continue to reverse the input
; assumptions, for backward compatibility (otherwise forcing round goal names
; will change). Reversing a small list is cheap, so this is not a big deal.
; Old comments:
; We unencumber every assumption in assumptions and return the
; modified list, accumulated onto ans.
; Note: This process is mentioned in :DOC forcing-round. So if we change it,
; update the documentation.
(cond
((null assumptions) ans)
(t (unencumber-assumptions
(cdr assumptions) wrld
(cons (unencumber-assumption (car assumptions) wrld)
ans)))))
; We are now concerned, for a while, with the idea of deleting from a
; set of assumptions those implied by others. We call this
; assumption-subsumption. Each assumption can be thought of as a goal
; of the form type-alist -> term. Observe that if you have two
; assumptions with the same term, then the first implies the second if
; the type-alist of the second implies the type-alist of the first.
; That is,
; (thm (implies (implies ta2 ta1)
; (implies (implies ta1 term) (implies ta2 term))))
; First we develop the idea that one type-alist implies another.
(defun dumb-type-alist-implicationp1 (type-alist1 type-alist2 seen)
(cond ((null type-alist1) t)
((member-equal (caar type-alist1) seen)
(dumb-type-alist-implicationp1 (cdr type-alist1) type-alist2 seen))
(t (let ((ts1 (cadar type-alist1))
(ts2 (or (cadr (assoc-equal (caar type-alist1) type-alist2))
*ts-unknown*)))
(and (ts-subsetp ts1 ts2)
(dumb-type-alist-implicationp1 (cdr type-alist1)
type-alist2
(cons (caar type-alist1) seen)))))))
(defun dumb-type-alist-implicationp2 (type-alist1 type-alist2)
(cond ((null type-alist2) t)
(t (and (assoc-equal (caar type-alist2) type-alist1)
(dumb-type-alist-implicationp2 type-alist1
(cdr type-alist2))))))
(defun dumb-type-alist-implicationp (type-alist1 type-alist2)
; NOTE: This function is intended to be dumb but fast. One can
; imagine that we should be concerned with the types deduced by
; type-set under these type-alists. For example, instead of asking
; whether every term bound in type-alist1 is bound to a bigger type
; set in type-alist2, we should perhaps ask whether the term has a
; bigger type-set under type-alist2. Similarly, if we find a term
; bound in type-alist2 we should make sure that its type-set under
; type-alist1 is smaller. If we need the smarter function we'll write
; it. That's why we call this one "dumb."
; We say type-alist1 implies type-alist2 if (1) for every
; "significant" entry in type-alist1, (term ts1 . ttree1) it is the
; case that either term is not bound in type-alist2 or term is bound
; to some ts2 in type-alist2 and (ts-subsetp ts1 ts2), and (2) every
; term bound in type-alist2 is bound in type-alist1. The case where
; term is not bound in type-alist2 can be seen as the natural
; treatment of the equivalent situation in which term is bound to
; *ts-unknown* in type-set2. An entry (term ts . ttree) is
; "significant" if it is the first binding of term in the alist.
; We can treat a type-alist as a conjunction of assumptions about the
; terms it binds. Each relevant entry gives rise to an assumption
; about its term. Call the conjunction the "assumptions" encoded in
; the type-alist. If type-alist1 implies type-alist2 then the
; assumptions of the first imply those of the second. Consider an
; assumption of the first. It restricts its term to some type. But
; the corresponding assumption about term in the second type-alist
; restricts term to a larger type. Thus, each assumption of the first
; type-alist implies the corresponding assumption of the second.
; The end result of all of this is that if you need to prove some
; condition, say g, under type-alist1 and also under type-alist2, and
; you can determine that type-alist1 implies type-alist2, then it is
; sufficient to prove g under type-alist2.
; Here is an example. Let type-alist1 be
; ((x *ts-t*) (y *ts-integer*) (z *ts-symbol*))
; and type-alist2 be
; ((x *ts-boolean*)(y *ts-rational*)).
; Observe that type-alist1 implies type-alist2: *ts-t* is a subset of
; *ts- boolean*, *ts-integer* is a subset of *ts-rational*, and
; *ts-symbol* is a subset of *ts-unknown*, and there are no terms
; bound in type-alist2 that aren't bound in type-alist1. If we needed
; to prove g under both of these type-alists, it would suffice to
; prove it under type-alist2 (the weaker) because we must ultimately
; prove g under type-alist2 and the proof of g under type-alist1
; follows from that for free.
; Observe also that if we added to type-alist2 the binding (u
; *ts-cons*) then condition (1) of our definition still holds but (2)
; does not. Further, if we mistakenly regarded type-alist2 as the
; weaker then proving (consp u) under type-alist2 would not ensure a
; proof of (consp u) under type-alist1.
(and (dumb-type-alist-implicationp1 type-alist1 type-alist2 nil)
(dumb-type-alist-implicationp2 type-alist1 type-alist2)))
; Now we arrange to partition a bunch of assumptions into pots
; according to their :terms, so we can do the type-alist implication
; work just on those assumptions that share a :term.
(defun partition-according-to-assumption-term (assumptions alist)
; We partition assumptions into pots, where the assumptions in a
; single pot all share the same :term. The result is an alist whose
; keys are the :terms and whose values are the assumptions which have
; those terms.
(cond ((null assumptions) alist)
(t (partition-according-to-assumption-term
(cdr assumptions)
(put-assoc-equal
(access assumption (car assumptions) :term)
(cons (car assumptions)
(cdr (assoc-equal
(access assumption (car assumptions) :term)
alist)))
alist)))))
; So now imagine we have a bunch of assumptions that share a term. We
; want to delete from the set any whose type-alist implies any one
; kept. See dumb-keep-assumptions-with-weakest-type-alists.
(defun exists-assumption-with-weaker-type-alist (assumption assumptions i)
; If there is an assumption, assn, in assumptions whose type-alist is
; implied by that of the given assumption, we return (mv pos assn),
; where pos is the position in assumptions of the first such assn. We
; assume i is the position of the first assumption in assumptions.
; Otherwise we return (mv nil nil).
(cond
((null assumptions) (mv nil nil))
((dumb-type-alist-implicationp
(access assumption assumption :type-alist)
(access assumption (car assumptions) :type-alist))
(mv i (car assumptions)))
(t (exists-assumption-with-weaker-type-alist assumption
(cdr assumptions)
(1+ i)))))
(defun add-assumption-with-weak-type-alist (assumption assumptions ans)
; We add assumption to assumptions, deleting any member of assumptions
; whose type-alist implies that of the given assumption. When we
; delete an assumption we union its :assumnotes field into that of the
; assumption we are adding. We accumulate our answer onto ans to keep
; this tail recursive; we presume that there will be a bunch of
; assumptions when this stuff gets going.
(cond
((null assumptions) (cons assumption ans))
((dumb-type-alist-implicationp
(access assumption (car assumptions) :type-alist)
(access assumption assumption :type-alist))
(add-assumption-with-weak-type-alist
(change assumption assumption
:assumnotes
(union-equal (access assumption assumption :assumnotes)
(access assumption (car assumptions) :assumnotes)))
(cdr assumptions)
ans))
(t (add-assumption-with-weak-type-alist assumption
(cdr assumptions)
(cons (car assumptions) ans)))))
(defun dumb-keep-assumptions-with-weakest-type-alists (assumptions kept)
; We return that subset of assumptions with the property that for
; every member, a, of assumptions there is one, b, among those
; returned such that (dumb-type-alist-implicationp a b). Thus, we keep
; all the ones with the weakest hypotheses. If we can prove all the
; ones kept, then we can prove them all, because each one thrown away
; has even stronger hypotheses than one of the ones we'll prove.
; (These comments assume that kept is initially nil and that all of
; the assumptions have the same :term.) Whenever we throw out a in
; favor of b, we union into b's :assumnotes those of a.
(cond
((null assumptions) kept)
(t (mv-let
(i assn)
(exists-assumption-with-weaker-type-alist (car assumptions) kept 0)
(cond
(i (dumb-keep-assumptions-with-weakest-type-alists
(cdr assumptions)
(update-nth
i
(change assumption assn
:assumnotes
(union-equal
(access assumption (car assumptions) :assumnotes)
(access assumption assn :assumnotes)))
kept)))
(t (dumb-keep-assumptions-with-weakest-type-alists
(cdr assumptions)
(add-assumption-with-weak-type-alist (car assumptions)
kept nil))))))))
; And now we can write the top-level function for dumb-assumption-subsumption.
(defun dumb-assumption-subsumption1 (partitions ans)
; Having partitioned the original assumptions into pots by :term, we
; now simply clean up the cdr of each pot -- which is the list of all
; assumptions with the given :term -- and append the results of all
; the pots together.
(cond
((null partitions) ans)
(t (dumb-assumption-subsumption1
(cdr partitions)
(append (dumb-keep-assumptions-with-weakest-type-alists
(cdr (car partitions))
nil)
ans)))))
(defun dumb-assumption-subsumption (assumptions)
; We throw out of assumptions any assumption implied by any of the others. Our
; notion of "implies" here is quite weak, being a simple comparison of
; type-alists. Briefly, we partition the set of assumptions into pots by :term
; and then, within each pot throw out any assumption whose type-alist is
; stronger than some other in the pot. When we throw some assumption out in
; favor of another we combine its :assumnotes into that of the one we keep, so
; we can report the cases for which each final assumption accounts.
(dumb-assumption-subsumption1
(partition-according-to-assumption-term assumptions nil)
nil))
; Now we move on to the problem of converting an unemcumbered and subsumption
; cleansed assumption into a clause to prove.
(defun clausify-type-alist (type-alist cl ens w seen ttree)
; Consider a type-alist such as
; `((x ,*ts-cons*) (y ,*ts-integer*) (z ,(ts-union *ts-rational* *ts-symbol*)))
; and some term, such as (p x y z). We wish to construct a clause
; that represents the goal of proving the term under the assumption of
; the type-alist. A suitable clause in this instance is
; (implies (and (consp x)
; (integerp y)
; (or (rationalp z) (symbolp z)))
; (p x y z))
; We return (mv clause ttree), where clause is the clause constructed.
; Note that we convert each pair in the type-alist to a provably equivalent
; term (i.e., we use convert-type-set-to-term1 with flg = t), since we are
; trying to prove the resulting clause. See also the comment about tau in
; convert-type-set-to-term1.
(cond ((null type-alist) (mv cl ttree))
((member-equal (caar type-alist) seen)
(clausify-type-alist (cdr type-alist) cl ens w seen ttree))
(t (mv-let (term ttree)
(convert-type-set-to-term1 (caar type-alist)
(cadar type-alist)
t ; flg; see above
ens w ttree)
(clausify-type-alist (cdr type-alist)
(cons (dumb-negate-lit term) cl)
ens w
(cons (caar type-alist) seen)
ttree)))))
(defun clausify-assumption (assumption ens wrld)
; We convert the assumption assumption into a clause.
; Note: If you ever change this so that the assumption :term is not the last
; literal of the clause, change the printer process-assumptions-msg1.
(clausify-type-alist
(access assumption assumption :type-alist)
(list (access assumption assumption :term))
ens
wrld
nil
nil))
(defun clausify-assumptions (assumptions ens wrld pairs ttree)
; We clausify every assumption in assumptions. We return (mv pairs ttree),
; where pairs is a list of pairs, each of the form (assumnotes . clause) where
; the assumnotes are the corresponding field of the clausified assumption.
(cond
((null assumptions) (mv pairs ttree))
(t (mv-let (clause ttree1)
(clausify-assumption (car assumptions) ens wrld)
(clausify-assumptions
(cdr assumptions)
ens wrld
(cons (cons (access assumption (car assumptions) :assumnotes)
clause)
pairs)
(cons-tag-trees ttree1 ttree))))))
(defun strip-assumption-terms (lst)
; Given a list of assumptions, return the set of their terms.
(cond ((endp lst) nil)
(t (add-to-set-equal (access assumption (car lst) :term)
(strip-assumption-terms (cdr lst))))))
(defun add-splitters-to-ttree1 (assumnotes tag ttree)
(cond ((endp assumnotes) ttree)
(t (add-splitters-to-ttree1
(cdr assumnotes)
tag
(add-to-tag-tree tag
(access assumnote (car assumnotes) :rune)
ttree)))))
(defun add-splitters-to-ttree (immediatep tag assumptions ttree)
(cond ((endp assumptions) ttree)
(t (add-splitters-to-ttree
immediatep
tag
(cdr assumptions)
(cond
((eq immediatep
(access assumption (car assumptions) :immediatep))
(add-splitters-to-ttree1
(access assumption (car assumptions) :assumnotes)
tag ttree))
(t ttree))))))
(defun maybe-add-splitters-to-ttree (splitter-output immediatep tag
assumptions ttree)
(cond (splitter-output
(add-splitters-to-ttree immediatep tag assumptions ttree))
(t ttree)))
(defun extract-and-clausify-assumptions (cl ttree only-immediatep ens wrld
splitter-output)
; WARNING: This function is overloaded. Only-immediatep can take only only two
; values in this function: 'non-nil or nil. The interpretation is as in
; collect-assumptions. Cl is irrelevant if only-immediatep is nil. We always
; return four results. But when only-immediatep = 'non-nil, the first and part
; of the third result are irrelevant. We know that only-immediatep = 'non-nil
; is used only in waterfall-step to do CASE-SPLITs and immediate FORCEs. We
; know that only-immediatep = nil is used for forcing-round applications and in
; the proof checker. When CASE-SPLIT type assumptions are collected with
; only-immediatep = nil, then they are given the semantics of FORCE rather
; than CASE-SPLIT. This could happen in the proof checker, but it is thought
; not to happen otherwise.
; In the case that only-immediatep is nil: we strip all assumptions out of
; ttree, obtaining an assumption-free ttree, ttree'. We then cleanup the
; assumptions, by removing subsumed ones. (Formerly we also unencumbered their
; type-alists of presumed irrelevant bindings first, but we no longer do so;
; see unencumber-assumption.) We then convert each kept assumption into a
; clause encoding the implication from the cleaned up type-alist to the
; assumed term. We pair each clause with the :assumnotes of the assumptions
; for which it accounts, to produce a list of pairs, which is among the things
; we return. Each pair is of the form (assumnotes . clause). We return four
; results, (mv n a pairs ttree'), where n is the number of assumptions in the
; tree, a is the cleaned up assumptions we have to prove, whose length is the
; same as the length of pairs.
; In the case that only-immediatep is 'non-nil: we strip out of ttree only
; those assumptions with non-nil :immediatep flags. As before, we generate a
; clause for each, but those with :immediatep = 'case-split we handle
; differently now: the clause for such an assumption is the one that encodes
; the implication from the negation of cl to the assumed term, rather than the
; one involving the type-alist of the assumption. The assumnotes paired with
; such a clause is nil. We do not really care about the assumnotes in
; case-splits or immediatep = t cases (e.g., they are ignored by the
; waterfall-step processing). The final ttree, ttree', may still contain
; non-immediatep assumptions.
; To keep the definition simpler, we split into just the two cases outlined
; above.
(cond
((eq only-immediatep nil)
(let* ((raw-assumptions (collect-assumptions ttree only-immediatep))
(cleaned-assumptions (dumb-assumption-subsumption
(unencumber-assumptions raw-assumptions
wrld nil))))
(mv-let
(pairs ttree1)
(clausify-assumptions cleaned-assumptions ens wrld nil nil)
; We check below that ttree1 is 'assumption free, so that when we add it to the
; result of cleansing 'assumptions from ttree we get an assumption-free ttree.
; If ttree1 contains assumptions we believe it must be because the bottom-most
; generator of those ttrees, namely convert-type-set-to-term, was changed to
; force assumptions. But if that happens, we will have to rethink a lot here.
; How can we ensure that we get rid of all assumptions if we make assumptions
; while trying to express our assumptions as clauses?
(mv (length raw-assumptions)
cleaned-assumptions
pairs
(cons-tag-trees
(cond
((tagged-objectsp 'assumption ttree1)
(er hard 'extract-and-clausify-assumptions
"Convert-type-set-to-term apparently returned a ttree that ~
contained an 'assumption tag. This violates the ~
assumption in this function."))
(t ttree1))
(delete-assumptions ttree only-immediatep))))))
((eq only-immediatep 'non-nil)
(let* ((case-split-assumptions (collect-assumptions ttree 'case-split))
(assumed-terms (strip-assumption-terms case-split-assumptions))
(case-split-clauses (split-on-assumptions assumed-terms cl nil))
(case-split-pairs (pairlis2 nil case-split-clauses))
(raw-assumptions (collect-assumptions ttree t))
(cleaned-assumptions (dumb-assumption-subsumption
(unencumber-assumptions raw-assumptions
wrld nil))))
(mv-let
(pairs ttree1)
(clausify-assumptions cleaned-assumptions ens wrld nil nil)
; We check below that ttree1 is 'assumption free, so that when we add it to the
; result of cleansing 'assumptions from ttree we get an assumption-free ttree.
; If ttree1 contains assumptions we believe it must be because the bottom-most
; generator of those ttrees, namely convert-type-set-to-term, was changed to
; force assumptions. But if that happens, we will have to rethink a lot here.
; How can we ensure that we get rid of all assumptions if we make assumptions
; while trying to express our assumptions as clauses?
(mv 'ignored
assumed-terms
(append case-split-pairs pairs)
(maybe-add-splitters-to-ttree
splitter-output
'case-split
'splitter-case-split
case-split-assumptions
(maybe-add-splitters-to-ttree
splitter-output
t
'splitter-immed-forced
raw-assumptions
(cons-tag-trees
(cond
((tagged-objectsp 'assumption ttree1)
(er hard 'extract-and-clausify-assumptions
"Convert-type-set-to-term apparently returned a ttree ~
that contained an 'assumption tag. This violates the ~
assumption in this function."))
(t ttree1))
(delete-assumptions ttree 'non-nil))))))))
(t (mv 0 nil
(er hard 'extract-and-clausify-assumptions
"We only implemented two cases for only-immediatep: 'non-nil ~
and nil. But you now call it on ~p0."
only-immediatep)
nil))))
; Finally, we put it all together in the primitive function that
; applies a processor to a clause.
(defun@par waterfall-step1 (processor cl-id clause hist pspv wrld state
step-limit)
; Note that apply-top-hints-clause is handled in waterfall-step.
(case processor
(simplify-clause
(pstk
(simplify-clause clause hist pspv wrld state step-limit)))
(preprocess-clause
(pstk
(preprocess-clause clause hist pspv wrld state step-limit)))
(otherwise
(prepend-step-limit
4
(case processor
(settled-down-clause
(pstk
(settled-down-clause clause hist pspv wrld state)))
(eliminate-destructors-clause
(pstk
(eliminate-destructors-clause clause hist pspv wrld state)))
(fertilize-clause
(pstk
(fertilize-clause cl-id clause hist pspv wrld state)))
(generalize-clause
(pstk
(generalize-clause clause hist pspv wrld state)))
(eliminate-irrelevance-clause
(pstk
(eliminate-irrelevance-clause clause hist pspv wrld state)))
(otherwise
(pstk
(push-clause@par clause hist pspv wrld state))))))))
(defun@par process-backtrack-hint (cl-id clause clauses processor new-hist
new-pspv ctx wrld state)
; A step of the indicated clause with cl-id through the waterfall, via
; waterfall-step, has tentatively returned the indicated clauses, new-hist, and
; new-pspv. If the original pspv contains a :backtrack hint-setting, we replace
; the hint-settings with the computed hint that it specifies.
(let ((backtrack-hint (cdr (assoc-eq :backtrack
(access prove-spec-var new-pspv
:hint-settings)))))
(cond
(backtrack-hint
(assert$
(eq (car backtrack-hint) 'eval-and-translate-hint-expression)
(mv-let@par
(erp val state)
(eval-and-translate-hint-expression@par
(cdr backtrack-hint) ; tuple of the form (name-tree flg term)
cl-id clause wrld
:OMITTED ; stable-under-simplificationp, unused in :backtrack hints
new-hist new-pspv clauses processor
:OMITTED ; keyword-alist, unused in :backtrack hints
'backtrack (override-hints wrld) ctx state)
(cond (erp (mv@par t nil nil state))
((assert$ (listp val)
(eq (car val) :computed-hint-replacement))
(mv@par nil
(cddr val)
(assert$ (consp (cdr val))
(case (cadr val)
((t) (list backtrack-hint))
((nil) nil)
(otherwise (cadr val))))
state))
(t (mv@par nil val nil state))))))
(t (mv@par nil nil nil state)))))
; Before we can can complete the definition of waterfall-step, we need support
; for rw-cache operations (see the Essay on Rw-cache) at the pspv level.
(defun set-rw-cache-state-in-pspv (pspv val)
(declare (xargs :guard (member-eq val *legal-rw-cache-states*)))
(change prove-spec-var pspv
:rewrite-constant
(change rewrite-constant
(access prove-spec-var pspv :rewrite-constant)
:rw-cache-state val)))
(defun maybe-set-rw-cache-state-disabled (pspv)
(cond ((eq (access rewrite-constant
(access prove-spec-var pspv :rewrite-constant)
:rw-cache-state)
t)
(set-rw-cache-state-in-pspv pspv :disabled))
(t pspv)))
(defun maybe-set-rw-cache-state-enabled (pspv)
(cond ((eq (access rewrite-constant
(access prove-spec-var pspv :rewrite-constant)
:rw-cache-state)
:disabled)
(set-rw-cache-state-in-pspv pspv t))
(t pspv)))
(defun accumulate-rw-cache-into-pspv (processor ttree pspv)
; This function is called during waterfall-step before modifying the pspv, in
; order to accumulate the rw-cache of ttree into the ttree of pspv. This need
; only happen when the processor can put significant entries into the rw-cache,
; so this function is a no-op unless the processor is simplify-clause. This
; need not happen when simplify-clause produces a hit, since the ttree will
; accumulated into the pspv elsewhere (so that runes are reported, forcing
; takes place, etc.); so it should suffice to call this function when there is
; a miss. If the ttree is empty or if the rw-cache is not active, there is
; nothing to accumulate. Also, as we clear the rw-cache for every call of
; rewrite-atm, there is no need to accumulate when the rw-cache-state is
; :atom.
(cond ((and (eq processor 'simplify-clause)
ttree
(eq (access rewrite-constant
(access prove-spec-var pspv :rewrite-constant)
:rw-cache-state)
t))
(let ((new-ttree-or-nil
(accumulate-rw-cache? nil ttree (access prove-spec-var pspv
:tag-tree))))
(cond (new-ttree-or-nil
(change prove-spec-var pspv
:tag-tree
new-ttree-or-nil))
(t pspv))))
(t pspv)))
(defun erase-rw-cache-from-pspv (pspv)
; Erase all rw-cache tagged objects from the ttree of pspv. We could call
; erase-rw-cache, but since we have the opportunity to call
; remove-tag-from-tag-tree! to save assoc-eq calls, we do so.
(let ((ttree (access prove-spec-var pspv :tag-tree)))
(cond ((tagged-objectsp 'rw-cache-any-tag ttree)
(change prove-spec-var pspv
:tag-tree (remove-tag-from-tag-tree
'rw-cache-nil-tag
(remove-tag-from-tag-tree!
'rw-cache-any-tag
ttree))))
((tagged-objectsp 'rw-cache-nil-tag ttree)
(change prove-spec-var pspv
:tag-tree (remove-tag-from-tag-tree!
'rw-cache-nil-tag
ttree)))
(t pspv))))
(defconst *simplify-clause-ledge*
(member-eq 'simplify-clause *preprocess-clause-ledge*))
(defconst *simplify-clause-ledge-complement*
(set-difference-eq *preprocess-clause-ledge*
*simplify-clause-ledge*))
(defun@par waterfall-step-cleanup (processor cl-id clause hist wrld state
signal clauses ttree pspv new-pspv
step-limit)
; Signal here can be either some form of HIT (hit, hit-rewrite,
; hit-rewrite2, or-hit) or ABORT.
; Imagine that the indicated waterfall processor produced some form of
; hit and returned signal, clauses, ttree, and new-pspv. We have to
; do certain cleanup on these things (e.g., add cl-id to all the
; assumnotes) and we do all that cleanup here.
; The actual cleanup is
; (1) add the cl-id to each assumnote in ttree
; (2) accumulate the modified ttree into state
; (3) extract the assumptions we are to handle immediately
; (4) compute the resulting case splits and modify clauses appropriately
; (5) make a new history entry
; (6) adjust signal to account for a specious application
; The result is (mv signal' clauses' ttree' hist' pspv' state) where
; each of the primed things are (possibly) modifications of their
; input counterparts.
; Here is blow-by-blow description of the cleanup.
; We update the :cl-id field (in the :assumnote) of every 'assumption.
; We accumulate the modified ttree into state.
(declare (ignorable cl-id step-limit state))
(let ((ttree (set-cl-ids-of-assumptions ttree cl-id)))
; We extract the assumptions we are to handle immediately.
(mv-let
(n assumed-terms pairs ttree)
(extract-and-clausify-assumptions
clause
ttree
'non-nil ; collect CASE-SPLIT and immediate FORCE assumptions
(access rewrite-constant
(access prove-spec-var new-pspv :rewrite-constant)
:current-enabled-structure)
wrld
(access rewrite-constant
(access prove-spec-var new-pspv :rewrite-constant)
:splitter-output))
(declare (ignore n))
; Note below that we throw away the cars of the pairs, which are
; typically assumnotes. We keep only the clauses themselves.
; We perform the required splitting, augmenting the previously
; generated clauses with the assumed terms.
(let* ((split-clauses (strip-cdrs pairs))
(clauses
(if (and (null split-clauses)
(null assumed-terms)
(member-eq processor
'(preprocess-clause
apply-top-hints-clause)))
clauses
(remove-trivial-clauses
(union-equal split-clauses
(disjoin-clause-segment-to-clause-set
(dumb-negate-lit-lst assumed-terms)
clauses))
wrld)))
(ttree (cond ((cdr clauses) ttree)
(t (remove-tag-from-tag-tree 'splitter-if-intro
ttree))))
; We create the history entry for this step. We have to be careful about
; specious hits to prevent a loop described below.
(new-hist
(cons (make history-entry
:signal signal ; indicating the type of "hit"
:processor
; We here detect specious behavior. The basic idea is that a hit
; is specious if the input clause is among the output clauses. But
; there are two exceptions: when the process is settled-down-clause or
; apply-top-hints-clause, such apparently specious output is ok.
; We mark a specious hit by setting the :processor of the history-entry
; to the cons (SPECIOUS . processor).
(if (and (not (member-eq
processor
'(settled-down-clause
; The obvious example of apparently specious behavior by
; apply-top-hints-clause that is not really specious is when it signals
; an OR-HIT and returns the input clause (to be processed by further hints).
; But the inclusion of apply-top-hints-clause in this list of exceptions
; was originally made in Version_2.7 because of :by hints. Consider
; what happens when a :by hint produces a subgoal that is identical to the
; current goal. If the subgoal is labeled as 'SPECIOUS, then we will 'MISS
; below. This was causing the waterfall to apply the :by hint a second time,
; resulting in output such as the following:
; As indicated by the hint, this goal is subsumed by (EQUAL (F1 X) (F0 X)),
; which can be derived from LEMMA1 via functional instantiation, provided
; we can establish the constraint generated.
;
; As indicated by the hint, this goal is subsumed by (EQUAL (F1 X) (F0 X)),
; which can be derived from LEMMA1 via functional instantiation, provided
; we can establish the constraint generated.
; The following example reproduces the above output. The top-level hints
; (i.e., *top-hint-keywords*) should never be 'SPECIOUS anyhow, because the
; user will more than likely prefer to see the output before the proof
; (probably) fails.
; (defstub f0 (x) t)
; (defstub f1 (x) t)
; (defstub f2 (x) t)
;
; (defaxiom lemma1
; (equal (f2 x) (f1 x)))
;
; (defthm main
; (equal (f1 x) (f0 x))
; :hints (("Goal" :by (:functional-instance lemma1 (f2 f1) (f1 f0)))))
apply-top-hints-clause)))
(member-equal clause clauses))
(cons 'SPECIOUS processor)
processor)
:clause clause
:ttree ttree
:cl-id ; only needed for #+acl2-par, but harmless
cl-id)
hist)))
(mv-let@par
(erp ttree state)
(accumulate-ttree-and-step-limit-into-state@par ttree step-limit state)
(declare (ignore erp))
(cond
((consp (access history-entry ; (SPECIOUS . processor)
(car new-hist) :processor))
(mv@par 'MISS nil ttree new-hist
(accumulate-rw-cache-into-pspv processor ttree pspv)
state))
(t (mv@par signal clauses ttree new-hist
(cond
((or (member-eq processor *simplify-clause-ledge-complement*)
(eq processor 'settled-down-clause))
(put-ttree-into-pspv ttree new-pspv))
((eq processor 'simplify-clause)
(put-ttree-into-pspv ttree
(maybe-set-rw-cache-state-enabled
new-pspv)))
(t
(put-ttree-into-pspv (erase-rw-cache ttree)
(maybe-set-rw-cache-state-disabled
(erase-rw-cache-from-pspv new-pspv)))))
state))))))))
(defun@par waterfall-step (processor cl-id clause hist pspv wrld ctx state
step-limit)
; Processor is one of the known waterfall processors. This function applies
; processor and returns seven results: step-limit, signal, clauses, new-hist,
; new-pspv, jppl-flg, and state.
; All processor functions take as input a clause, its hist, a pspv, wrld, and
; state. They all deliver four values (but apply-top-hints-clause,
; preprocess-clause, and simplify-clause also take a step-limit input and
; deliver a new step-limit as an additional value, in the first position): a
; signal, some clauses, a ttree, and a new pspv. The signal delivered by such
; processors is one of 'error, 'miss, 'abort, or else indicates a "hit" via the
; signals 'hit, 'hit-rewrite, 'hit-rewrite2 and 'or-hit. We identify the first
; three kinds of hits. 'Or-hits indicate that a set of disjunctive branches
; has been produced.
; If the returned signal is 'error or 'miss, we immediately return with that
; signal. But if the signal is a "hit" or 'abort (which in this context means
; "the processor did something but it has demanded the cessation of the
; waterfall process"), we add a new history entry to hist, store the ttree into
; the new pspv, print the message associated with this processor, and then
; return.
; When a processor "hit"s, we check whether it is a specious hit, i.e., whether
; the input is a member of the output. If so, the history entry for the hit is
; marked specious by having the :processor field '(SPECIOUS . processor).
; However, we report the step as a 'miss, passing back the extended history to
; be passed. Specious processors have to be recorded in the history so that
; waterfall-msg can detect that they have occurred and not reprint the formula.
; Mild Retraction: Actually, settled-down-clause always produces
; specious-appearing output but we never mark it as 'SPECIOUS because we want
; to be able to assoc for settled-down-clause and we know it's specious anyway.
; We typically return (mv step-limit signal clauses new-hist new-pspv jppl-flg
; state).
; Signal Meaning
; 'error Halt the entire proof attempt with an error. We
; print out the error message to the returned state.
; In this case, clauses, new-hist, new-pspv, and jppl-flg
; are all irrelevant (and nil).
; 'miss The processor did not apply or was specious. Clauses,
; and jppl-flg are irrelevant and nil, but new-hist has the
; specious processor recorded in it, and new-pspv records
; rw-cache modifications to the :tag-tree of the input pspv.
; State is unchanged.
; 'abort Like a "hit", except that we are not to continue with
; the waterfall. We are to use the new pspv as the
; final pspv produced by the waterfall.
; 'hit The processor applied and produced the new set of
; 'hit-rewrite clauses returned. The appropriate new history and
; 'hit-rewrite2 new pspv are returned. Jppl-flg is either nil
; (indicating that the processor was not push-clause)
; or is a pool lst (indicating that a clause was pushed
; and assigned that lst). The jppl-flg of the last executed
; processor should find its way out of the waterfall so
; that when we get out and pop a clause we know if we
; just pushed it. Finally, the message describing the
; transformation has been printed to state.
; 'or-hit The processor applied and has requested a disjunctive
; split determined by hints. The results are actually
; the same as for 'hit. The processor did not actually
; produce the case split because some of the hints
; (e.g., :in-theory) are related to the environment
; in which we are to process the clause rather than the
; clause itself.
; 'top-of-waterfall-hint
; A :backtrack hint was applicable, and suitable results are
; returned for handling it.
(sl-let@par
(erp signal clauses ttree new-pspv state)
(catch-time-limit5@par
(cond ((eq processor 'apply-top-hints-clause) ; this case returns state
(apply-top-hints-clause@par cl-id clause hist pspv wrld ctx state
step-limit))
(t
(sl-let
(signal clauses ttree new-pspv)
(waterfall-step1@par processor cl-id clause hist pspv wrld state
step-limit)
(mv@par step-limit signal clauses ttree new-pspv state)))))
(cond
(erp ; from out-of-time or clause-processor failure; treat as 'error signal
(mv-let@par (erp2 val state)
(er@par soft ctx "~@0" erp)
(declare (ignore erp2 val))
(pprogn@par
(assert$
(null ttree)
(mv-let@par
(erp3 val state)
(accumulate-ttree-and-step-limit-into-state@par
(add-to-tag-tree! 'abort-cause
(if (equal erp *interrupt-string*)
'interrupt
'time-limit-reached)
nil)
step-limit
state)
(declare (ignore val))
(assert$ (null erp3)
(state-mac@par))))
(mv@par step-limit 'error nil nil nil nil state))))
(t
(pprogn@par ; account for bddnote in case we do not have a hit
(cond ((and (eq processor 'apply-top-hints-clause)
(member-eq signal '(error miss))
ttree) ; a bddnote; see bdd-clause
(error-in-parallelism-mode@par
; Parallelism blemish: we disable the following addition of BDD notes to the
; state. Until a user requests it, we don't see a need to implement this.
(state-mac@par)
(f-put-global 'bddnotes
(cons ttree
(f-get-global 'bddnotes state))
state)))
(t (state-mac@par)))
(mv-let@par
(signal clauses new-hist new-pspv jppl-flg state)
(cond ((eq signal 'error)
; As of this writing, the only processor which might cause an error is
; apply-top-hints-clause. But processors can't actually cause errors in the
; error/value/state sense because they don't return state and so can't print
; their own error messages. We therefore make the convention that if they
; signal error then the "clauses" value they return is in fact a pair
; (fmt-string . alist) suitable for giving error1. Moreover, in this case
; ttree is an alist assigning state global variables to values.
(mv-let@par (erp val state)
(error1@par ctx (car clauses) (cdr clauses) state)
(declare (ignore erp val))
(mv@par 'error nil nil nil nil state)))
((eq signal 'miss)
(mv@par 'miss nil hist
(accumulate-rw-cache-into-pspv processor ttree pspv)
nil state))
(t
(mv-let@par
(signal clauses ttree new-hist new-pspv state)
(waterfall-step-cleanup@par processor cl-id clause hist wrld
state signal clauses ttree pspv
new-pspv step-limit)
(mv-let@par
(erp new-hint-settings new-hints state)
(cond
((or (eq signal 'miss) ; presumably specious
(eq processor 'settled-down-clause)) ; not user-visible
(mv@par nil nil nil state))
(t (process-backtrack-hint@par cl-id clause clauses processor
new-hist new-pspv ctx wrld
state)))
(cond
(erp
(mv@par 'error nil nil nil nil state))
(new-hint-settings
(mv@par 'top-of-waterfall-hint
new-hint-settings
processor
:pspv-for-backtrack
new-hints
state))
(t
(mv-let@par
(jppl-flg new-pspv state)
(waterfall-msg@par processor cl-id clause signal clauses
new-hist ttree new-pspv state)
(mv@par signal clauses new-hist new-pspv jppl-flg
state))))))))
(mv@par step-limit signal clauses new-hist new-pspv jppl-flg
state)))))))
; Section: FIND-APPLICABLE-HINT-SETTINGS
; Here we develop the code that recognizes that some user-supplied
; hint settings are applicable and we develop the routine to use
; hints. It all comes together in waterfall1.
(defun@par find-applicable-hint-settings1
(cl-id clause hist pspv ctx hints hints0 wrld stable-under-simplificationp
override-hints state)
; See translate-hints1 for "A note on the taxonomy of translated hints", which
; explains hint settings. Relevant background is also provided by :doc topic
; hints-and-the-waterfall, which links to :doc override-hints (also providing
; relevant background).
; We scan down hints looking for the first one that matches cl-id and clause.
; If we find none, we return nil. Otherwise, we return a pair consisting of
; the corresponding hint-settings and hints0 modified as directed by the hint
; that was applied. By "match" here, of course, we mean either
; (a) the hint is of the form (cl-id . hint-settings), or
; (b) the hint is of the form (eval-and-translate-hint-expression name-tree flg
; term) where term evaluates to a non-erroneous non-nil value when ID is bound
; to cl-id, CLAUSE to clause, WORLD to wrld, STABLE-UNDER-SIMPLIFICATIONP to
; stable-under-simplificationp, HIST to hist, PSPV to pspv, CTX to ctx, and
; STATE to state. In this case the corresponding hint-settings is the
; translated version of what the term produced. We know that term is
; single-threaded in state and returns an error triple.
; This function is responsible for interpreting computed hints, including the
; meaning of the :computed-hint-replacement keyword. It also deals
; appropriately with override-hints. Note that override-hints is
; (override-hints wrld).
; Stable-under-simplificationp is t when the clause has been found not to
; change when simplified. In particular, it is t if we are about to transition
; to destructor elimination.
; Optimization: By convention, when this function is called with
; stable-under-simplificationp = t, we know that the function returned nil when
; called earlier with the change: stable-under-simplificationp = nil. That is,
; if we know the clause is stable under simplification, then we have already
; tried and failed to find an applicable hint for it before we knew it was
; stable. So when stable-under-simplificationp is t, we avoid some work and
; just eval those hints that might be sensitive to
; stable-under-simplificationp. The flg component of (b)-style hints indicates
; whether the term contains the free variable stable-under-simplificationp.
(cond ((null hints)
(cond ((or (null override-hints) ; optimization for common case
stable-under-simplificationp) ; avoid loop
(value@par nil))
(t ; no applicable hint-settings, so apply override-hints to nil
(er-let*@par
((new-keyword-alist
(apply-override-hints@par
override-hints cl-id clause hist pspv ctx wrld
stable-under-simplificationp
:OMITTED ; clause-list
:OMITTED ; processor
nil ; keyword-alist
state))
(pair (cond (new-keyword-alist
(translate-hint@par
'override-hints ; name-tree
(cons (string-for-tilde-@-clause-id-phrase
cl-id)
new-keyword-alist)
nil ; hint-type
ctx wrld state))
(t (value@par nil)))))
(value@par (cond (pair (cons (cdr pair) hints0))
(t nil)))))))
((eq (car (car hints)) 'eval-and-translate-hint-expression)
(cond
((and stable-under-simplificationp
(not (caddr (car hints)))) ; flg
(find-applicable-hint-settings1@par
cl-id clause hist pspv ctx (cdr hints) hints0 wrld
stable-under-simplificationp override-hints state))
(t
(er-let*@par
((hint-settings
; The following call applies the override-hints to the computed hint.
(eval-and-translate-hint-expression@par
(cdr (car hints))
cl-id clause wrld
stable-under-simplificationp hist pspv
:OMITTED ; clause-list
:OMITTED ; processor
:OMITTED ; keyword-alist
nil
override-hints
ctx state)))
(cond
((null hint-settings)
(find-applicable-hint-settings1@par
cl-id clause hist pspv ctx (cdr hints) hints0 wrld
stable-under-simplificationp override-hints state))
((eq (car hint-settings) :COMPUTED-HINT-REPLACEMENT)
(value@par
(cond
((eq (cadr hint-settings) nil)
(cons (cddr hint-settings)
(remove1-equal (car hints) hints0)))
((eq (cadr hint-settings) t)
(cons (cddr hint-settings)
hints0))
(t (cons (cddr hint-settings)
(append (cadr hint-settings)
(remove1-equal (car hints) hints0)))))))
(t (value@par (cons hint-settings
(remove1-equal (car hints) hints0)))))))))
((and (not stable-under-simplificationp)
(consp (car hints))
(equal (caar hints) cl-id))
(cond ((null override-hints)
(value@par (cons (cdar hints)
(remove1-equal (car hints) hints0))))
; Override-hints is (override-hints wrld). If override-hints is non-nil, then
; we originally translated the hint as (list* cl-id (:KEYWORD-ALIST
; . keyword-alist) (:NAME-TREE . name-tree) . hint-settings. We apply the
; override-hints to get a new keyword-alist. If the keyword-alist has not
; changed, then hint-settings is still the correct translation. Otherwise, we
; need to translate the new keyword-alist. The result could be a computed
; hint, in which case we simply replace the hint with that computed hint and
; call this function recursively. But if the result is not a computed hint,
; then it is a fully-translated hint with the same clause-id, and we have our
; result.
((not (let ((hint-settings (cdar hints)))
(and (consp hint-settings)
(consp (car hint-settings))
(eq (car (car hint-settings))
:KEYWORD-ALIST)
(consp (cdr hint-settings))
(consp (cadr hint-settings))
(eq (car (cadr hint-settings))
:NAME-TREE))))
(er@par soft ctx
"Implementation error: With override-hints present, we ~
expected an ordinary translated hint-settings to start ~
with ((:KEYWORD-ALIST . keyword-alist) (:NAME-TREE . ~
name-tree)) but instead the translated hint-settings was ~
~x0. Please contact the ACL2 implementors."
(cdar hints)))
(t
(let* ((full-hint-settings (cdar hints))
(keyword-alist (cdr (car full-hint-settings)))
(name-tree (cdr (cadr full-hint-settings)))
(hint-settings (cddr full-hint-settings)))
(er-let*@par
((new-keyword-alist
(apply-override-hints@par
override-hints cl-id clause hist pspv ctx wrld
stable-under-simplificationp
:OMITTED ; clause-list
:OMITTED ; processor
keyword-alist
state))
(hint-settings
(cond
((equal new-keyword-alist keyword-alist)
(value@par hint-settings))
((null new-keyword-alist) ; optimization
(value@par nil))
(t (er-let*@par
((pair (translate-hint@par
name-tree
(cons (string-for-tilde-@-clause-id-phrase
cl-id)
new-keyword-alist)
nil ; hint-type
ctx wrld state)))
(assert$ (equal (car pair) cl-id)
(value@par (cdr pair))))))))
(value@par (cond ((null new-keyword-alist)
nil)
(t (cons hint-settings
(remove1-equal (car hints)
hints0))))))))))
(t (find-applicable-hint-settings1@par
cl-id clause hist pspv ctx (cdr hints) hints0 wrld
stable-under-simplificationp override-hints state))))
(defun@par find-applicable-hint-settings (cl-id clause hist pspv ctx hints wrld
stable-under-simplificationp
state)
; First, we find the applicable hint-settings (with
; find-applicable-hint-settings1) from the explicit and computed hints. Then,
; we modify those hint-settings by using the override-hints; see :DOC
; override-hints.
(find-applicable-hint-settings1@par cl-id clause hist pspv ctx hints hints
wrld stable-under-simplificationp
(override-hints wrld)
state))
(defun@par thanks-for-the-hint (goal-already-printed-p hint-settings state)
; This function prints the note that we have noticed the hint. We have to
; decide whether the clause to which this hint was attached was printed out
; above or below us. We return state. Goal-already-printed-p is either t,
; nil, or a pair (cons :backtrack processor) where processor is a member of
; *preprocess-clause-ledge*.
(declare (ignorable state))
(cond ((cdr (assoc-eq :no-thanks hint-settings))
(mv@par (delete-assoc-eq :no-thanks hint-settings) state))
((alist-keys-subsetp hint-settings '(:backtrack))
(mv@par hint-settings state))
(t
(pprogn@par
(cond
((serial-first-form-parallel-second-form@par
nil
(member-equal (f-get-global 'waterfall-printing state)
'(:limited :very-limited)))
(state-mac@par))
(t
(io?-prove@par
(goal-already-printed-p)
(fms "[Note: A hint was supplied for our processing of the goal ~
~#0~[above~/below~/above, provided by a :backtrack hint ~
superseding ~@1~]. Thanks!]~%"
(list
(cons
#\0
(case goal-already-printed-p
((t) 0)
((nil) 1)
(otherwise 2)))
(cons
#\1
(and (consp goal-already-printed-p)
(case (cdr goal-already-printed-p)
(apply-top-hints-clause
"the use of a :use, :by, :cases, :bdd, ~
:clause-processor, or :or hint")
(preprocess-clause
"preprocessing (the use of simple rules)")
(simplify-clause
"simplification")
(eliminate-destructors-clause
"destructor elimination")
(fertilize-clause
"the heuristic use of equalities")
(generalize-clause
"generalization")
(eliminate-irrelevance-clause
"elimination of irrelevance")
(push-clause
"the use of induction")
(otherwise
(er hard 'thanks-for-the-hint
"Implementation error: Unrecognized ~
processor, ~x0."
(cdr goal-already-printed-p)))))))
(proofs-co state)
state
nil))))
(mv@par hint-settings state)))))
; We now develop the code for warning users about :USEing enabled
; :REWRITE and :DEFINITION rules.
(defun lmi-name-or-rune (lmi)
; See also lmi-seed, which is similar except that it returns a base symbol
; where we are happy to return a rune, and when it returns a term we return
; nil. The symbols returned by this function are those for which we want to
; provide a warning about using an enabled rule; see enabled-lmi-names.
(cond ((atom lmi) lmi)
((member-eq (car lmi) '(:theorem
; There is no reason to warn about using a termination or guard theorem. (See
; comment above about the purpose being to provide a warning.)
:termination-theorem
:termination-theorem!
:guard-theorem
; Through Version_7.1 we warned when using a functional instance of an enabled
; rule. As Eric Smith has pointed out, this is rarely appropriate.
:functional-instance))
nil)
((eq (car lmi) :instance)
(lmi-name-or-rune (cadr lmi)))
(t lmi)))
(defun enabled-lmi-names1 (ens pairs)
; Pairs is the runic-mapping-pairs for some symbol, and hence each of
; its elements looks like (nume . rune). We collect the enabled
; :definition and :rewrite runes from pairs.
(cond
((null pairs) nil)
((and (or (eq (cadr (car pairs)) :definition)
(eq (cadr (car pairs)) :rewrite))
(enabled-numep (car (car pairs)) ens))
(add-to-set-equal (cdr (car pairs))
(enabled-lmi-names1 ens (cdr pairs))))
(t (enabled-lmi-names1 ens (cdr pairs)))))
(defun enabled-lmi-names (ens lmi-lst wrld)
(cond
((null lmi-lst) nil)
(t (let ((x (lmi-name-or-rune (car lmi-lst))))
; x is either nil, a name, or a rune
(cond
((null x)
(enabled-lmi-names ens (cdr lmi-lst) wrld))
((symbolp x)
(union-equal (enabled-lmi-names1
ens
(getpropc x 'runic-mapping-pairs nil wrld))
(enabled-lmi-names ens (cdr lmi-lst) wrld)))
((enabled-runep x ens wrld)
(add-to-set-equal x (enabled-lmi-names ens (cdr lmi-lst) wrld)))
(t (enabled-lmi-names ens (cdr lmi-lst) wrld)))))))
(defun@par maybe-warn-for-use-hint (pspv cl-id ctx wrld state)
(cond
((warning-disabled-p "Use")
(state-mac@par))
(t
(let ((enabled-lmi-names
(enabled-lmi-names
(access rewrite-constant
(access prove-spec-var pspv :rewrite-constant)
:current-enabled-structure)
(cadr (assoc-eq :use
(access prove-spec-var pspv :hint-settings)))
wrld)))
(cond
(enabled-lmi-names
(warning$@par ctx ("Use")
"It is unusual to :USE an enabled :REWRITE or :DEFINITION rule, so ~
you may want to consider disabling ~&0 in the hint provided for ~
~@1. See :DOC using-enabled-rules."
enabled-lmi-names
(tilde-@-clause-id-phrase cl-id)))
(t (state-mac@par)))))))
(defun@par maybe-warn-about-theory-simple (ens1 ens2 ctx wrld state)
; We may use this function instead of maybe-warn-about-theory when we know that
; ens1 contains a compressed theory array (and so does ens2, but that should
; always be the case).
(let ((force-xnume-en1 (enabled-numep *force-xnume* ens1))
(imm-xnume-en1 (enabled-numep *immediate-force-modep-xnume* ens1)))
(maybe-warn-about-theory@par ens1 force-xnume-en1 imm-xnume-en1 ens2
ctx wrld state)))
(defun@par maybe-warn-about-theory-from-rcnsts (rcnst1 rcnst2 ctx ens wrld
state)
(declare (ignore ens))
(let ((ens1 (access rewrite-constant rcnst1 :current-enabled-structure))
(ens2 (access rewrite-constant rcnst2 :current-enabled-structure)))
(cond
((equal (access enabled-structure ens1 :array-name)
(access enabled-structure ens2 :array-name))
; We want to avoid printing a warning in those cases where we have not really
; created a new enabled structure. In this case, the enabled structures could
; still in principle be different, in which case we are missing some possible
; warnings. In practice, this function is only called when ens2 is either
; identical to ens1 or is created from ens1 by a call of
; load-theory-into-enabled-structure that creates a new array name, in which
; case the eql test above will fail.
; Warning: Through Version_4.1 we compared :array-name-suffix fields. But now
; that the waterfall can be parallelized, the suffix might not change when we
; install a new theory array; consider load-theory-into-enabled-structure in
; the case that its incrmt-array-name-info argument is a clause-id.
(state-mac@par))
(t
; The new theory is being constructed from the user's hint and the ACL2 world.
; The most coherent thing to do is contruct the warning in an analogous manner,
; which is why we use ens below rather than ens1.
(maybe-warn-about-theory-simple@par ens1 ens2 ctx wrld state)))))
; Essay on OR-HIT Messages
; When we generate an OR-HIT, we print a message saying it has
; happened and that we will sweep across the disjuncts and consider
; each in turn. That message is printed in
; apply-top-hints-clause-msg1.
; As we sweep, we print three kinds of messages:
; a: ``here is the next disjunct to consider''
; b: ``this disjunct has succeeded and we won't consider the others''
; c: ``we've finished the sweep and now we choose the best result''
; Each is printed by a waterfall-or-hit-msg- function, labeled a, b,
; or c.
(defun waterfall-or-hit-msg-a (cl-id user-hinti d-cl-id i branch-cnt state)
; We print out the message associated with one disjunctive branch. The special
; case of when there is exactly one branch is handled by
; apply-top-hints-clause-msg1.
(cond
((gag-mode)
; Suppress printing for :OR splits; see also other comments with this header.
; In the case where we are only printing for gag-mode, we want to keep the
; message short. Our message relies on the disjunctive goal name starting with
; the word "Subgoal" so that the English is sensible.
; (fms "---~|Considering disjunctive ~@0 of ~@1.~|"
; (list (cons #\0 (tilde-@-clause-id-phrase d-cl-id))
; (cons #\1 (tilde-@-clause-id-phrase cl-id)))
; (proofs-co state)
; state
; nil)
state)
(t
(fms "---~%~@0~%( same formula as ~@1 ).~%~%The ~n2 disjunctive branch ~
(of ~x3) for ~@1 can be created by applying the hint:~%~y4.~%"
(list (cons #\0 (tilde-@-clause-id-phrase d-cl-id))
(cons #\1 (tilde-@-clause-id-phrase cl-id))
(cons #\2 (list i))
(cons #\3 branch-cnt)
(cons #\4 (cons (string-for-tilde-@-clause-id-phrase d-cl-id)
user-hinti)))
(proofs-co state)
state
nil))))
(defun waterfall-or-hit-msg-b (cl-id d-cl-id branch-cnt state)
; We print out the message that d-cl-id (and thus cl-id) has succeeded
; and that we will cut off the search through the remaining branches.
(cond ((gag-mode)
; Suppress printing for :OR splits; see also other comments with this header.
state)
(t
(fms "---~%~@0 has succeeded! All of its subgoals have been proved ~
(modulo any forced assumptions). Recall that it was one of ~
~n1 disjunctive branches generated by the :OR hint to prove ~
~@2. We therefore abandon work on the other branches.~%"
(list (cons #\0 (tilde-@-clause-id-phrase d-cl-id))
(cons #\1 branch-cnt)
(cons #\2 (tilde-@-clause-id-phrase cl-id)))
(proofs-co state)
state
nil))))
(defun tilde-*-or-hit-summary-phrase1 (summary)
(cond
((endp summary) nil)
(t (let ((cl-id (car (car summary)))
(subgoals (cadr (car summary)))
(difficulty (caddr (car summary))))
(cons (msg "~@0~t1 ~c2 ~c3~%"
(tilde-@-clause-id-phrase cl-id)
20
(cons subgoals 5)
(cons difficulty 10))
(tilde-*-or-hit-summary-phrase1 (cdr summary)))))))
(defun tilde-*-or-hit-summary-phrase (summary)
; Each element of summary is of the form (cl-id n d), where n is the
; number of subgoals pushed by the processing of cl-id and d is their
; combined difficulty. We prepare a ~* message that will print as
; a series of lines:
; disjunct subgoals estimated difficulty
; cl-id1 n d
(list "" "~@*" "~@*" "~@*"
(tilde-*-or-hit-summary-phrase1 summary)))
(defun waterfall-or-hit-msg-c (parent-cl-id results revert-d-cl-id cl-id summary
state)
; This message is printed when we have swept all the disjunctive
; branches and have chosen cl-id as the one to pursue. If results is
; empty, then cl-id and summary are all irrelevent (and probably nil).
(cond
((null results)
(cond
(revert-d-cl-id
(fms "---~%None of the branches we tried for ~@0 led to a plausible set ~
of subgoals, and at least one, ~@1, led to the suggestion that we ~
focus on the original conjecture. We therefore abandon our ~
previous work on this conjecture and reassign the name *1 to the ~
original conjecture. (See :DOC otf-flg.)~%"
(list (cons #\0 (tilde-@-clause-id-phrase parent-cl-id))
(cons #\1 (tilde-@-clause-id-phrase revert-d-cl-id)))
(proofs-co state)
state
nil))
(t
(fms "---~%None of the branches we tried for ~@0 led to a plausible set ~
of subgoals. The proof attempt has failed.~|"
(list (cons #\0 (tilde-@-clause-id-phrase parent-cl-id)))
(proofs-co state)
state
nil))))
((endp (cdr results))
(fms "---~%Even though we saw a disjunctive split for ~@0, it ~
turns out there is only one viable branch to pursue, the ~
one named ~@1.~%"
(list (cons #\0 (tilde-@-clause-id-phrase parent-cl-id))
(cons #\1 (tilde-@-clause-id-phrase cl-id)))
(proofs-co state)
state
nil))
(t (let* ((temp (assoc-equal cl-id summary))
(n (cadr temp))
(d (caddr temp)))
(fms "---~%After simplifying every branch of the disjunctive ~
split for ~@0 we choose to pursue the branch named ~@1, ~
which gave rise to ~x2 *-named formula~#3~[s~/~/s~] ~
with total estimated difficulty of ~x4. The complete ~
list of branches considered is shown below.~%~%~
clause id subgoals estimated~%~
~ pushed difficulty~%~*5"
(list (cons #\0 (tilde-@-clause-id-phrase parent-cl-id))
(cons #\1 (tilde-@-clause-id-phrase cl-id))
(cons #\2 n)
(cons #\3 (zero-one-or-more n))
(cons #\4 d)
(cons #\5 (tilde-*-or-hit-summary-phrase summary)))
(proofs-co state)
state
nil)))))
; Next we define a notion of the difficulty of a term and then grow it
; to define the difficulty of a clause and of a clause set. The
; difficulty of a term is (almost) the sum of all the level numbers of
; the functions in the term, plus the number of function applications.
; That is, suppose f and g have level-nos of i and j. Then the
; difficulty of (f (g x)) is i+j+2. However, the difficulty of (NOT
; (g x)) is just i+1 because we pretend the NOT (and its function
; application) is invisible.
(mutual-recursion
(defun term-difficulty1 (term wrld n)
(cond ((variablep term) n)
((fquotep term) n)
((flambda-applicationp term)
(term-difficulty1-lst (fargs term) wrld
(term-difficulty1 (lambda-body term)
wrld (1+ n))))
((eq (ffn-symb term) 'not)
(term-difficulty1 (fargn term 1) wrld n))
(t (term-difficulty1-lst (fargs term) wrld
(+ 1
(get-level-no (ffn-symb term) wrld)
n)))))
(defun term-difficulty1-lst (lst wrld n)
(cond ((null lst) n)
(t (term-difficulty1-lst (cdr lst) wrld
(term-difficulty1 (car lst) wrld n)))))
)
(defun term-difficulty (term wrld)
(term-difficulty1 term wrld 0))
; The difficulty of a clause is the sum of the complexities of the
; literals. Note that we cannot have literals of difficulty 0 (except
; for something trivial like (NOT P)), so this measure will assign
; lower difficulty to shorter clauses, all other things being equal.
(defun clause-difficulty (cl wrld)
(term-difficulty1-lst cl wrld 0))
; The difficulty of a clause set is similar.
(defun clause-set-difficulty (cl-set wrld)
(cond ((null cl-set) 0)
(t (+ (clause-difficulty (car cl-set) wrld)
(clause-set-difficulty (cdr cl-set) wrld)))))
; The difficulty of a pspv is the sum of the difficulties of the
; TO-BE-PROVED-BY-INDUCTION clause-sets in the pool of the pspv down
; (and not counting) the element element0.
(defun pool-difficulty (element0 pool wrld)
(cond ((endp pool) 0)
((equal (car pool) element0) 0)
((not (eq (access pool-element (car pool) :tag)
'TO-BE-PROVED-BY-INDUCTION))
0)
(t (+ (clause-set-difficulty
(access pool-element (car pool) :clause-set)
wrld)
(pool-difficulty element0 (cdr pool) wrld)))))
(defun how-many-to-be-proved (element0 pool)
; We count the number of elements tagged TO-BE-PROVED-BY-INDUCTION in
; pool until we get to element0.
(cond ((endp pool) 0)
((equal (car pool) element0) 0)
((not (eq (access pool-element (car pool) :tag)
'TO-BE-PROVED-BY-INDUCTION))
0)
(t (+ 1 (how-many-to-be-proved element0 (cdr pool))))))
(defun pick-best-pspv-for-waterfall0-or-hit1
(results element0 wrld ans ans-difficulty summary)
; Results is a non-empty list of elements, each of which is of the
; form (cl-id . pspv) where pspv is a pspv corresponding to the
; complete waterfall processing of a single disjunct (of conjuncts).
; Inside the :pool of the pspv are a bunch of
; TO-BE-PROVED-BY-INDUCTION pool-elements. We have to decide which of
; the pspv's is the "best" one, i.e., the one to which we will commit
; to puruse by inductions. We choose the one that has the least
; difficulty. We measure the difficulty of the pool-elements until we
; get to element0.
; Ans is the least difficult result so far, or nil if we have not seen
; any yet. Ans-difficulty is the difficulty of ans (or nil). Note
; that ans is of the form (cl-id . pspv).
; We accumulate into summary some information that is used to report
; what we find. For each element of results we collect (cl-id n d),
; where n is the number of subgoals pushed by the cl-id processing and
; d is their combined difficulty. We return (mv choice summary),
; where choice is the final ans (cl-id . pspv).
(cond
((endp results)
(mv ans summary))
(t (let* ((cl-id (car (car results)))
(pspv (cdr (car results)))
(new-difficulty (pool-difficulty
element0
(access prove-spec-var pspv :pool)
wrld))
(new-summary (cons (list cl-id
(how-many-to-be-proved
element0
(access prove-spec-var pspv :pool))
new-difficulty)
summary)))
(if (or (null ans)
(< new-difficulty ans-difficulty))
(pick-best-pspv-for-waterfall0-or-hit1 (cdr results)
element0
wrld
(car results)
new-difficulty
new-summary)
(pick-best-pspv-for-waterfall0-or-hit1 (cdr results)
element0
wrld
ans
ans-difficulty
new-summary))))))
(defun pick-best-pspv-for-waterfall0-or-hit (results pspv0 wrld)
; Results is a non-empty list of elements, each of which is of the
; form (cl-id . pspv) where pspv is a pspv corresponding to the
; complete waterfall processing of a single disjunct (of conjuncts).
; Inside the :pool of the pspv are a bunch of
; TO-BE-PROVED-BY-INDUCTION pool-elements. We have to decide which of
; the pspv's is the "best" one, i.e., the one to which we will commit
; to puruse by inductions. We choose the one that has the least
; difficulty.
; We return (mv (cl-id . pspv) summary) where cl-id and pspv are the
; clause id and pspv of the least difficult result in results and
; summary is a list that summarizes all the results, namely a list of
; the form (cl-id n difficulty), where cl-id is the clause id of a
; disjunct, n is the number of subgoals the processing of that
; disjunct pushed into the pool, and difficulty is the difficulty of
; those subgoals.
(pick-best-pspv-for-waterfall0-or-hit1
results
; We pass in the first element of the original pool as element0. This
; may be a BEING-PROVED-BY-INDUCTION element but is typically a
; TO-BE-PROVED-BY-INDUCTION element. In any case, we don't consider
; it or anything after it as we compute the difficulty.
(car (access prove-spec-var pspv0 :pool))
wrld
nil ; ans - none yet
nil ; ans-difficulty - none yet
nil ; summary
))
(defun change-or-hit-history-entry (i hist cl-id)
; The first entry in hist is a history-entry of the form
; (make history-entry
; :signal 'OR-HIT
; :processor 'APPLY-TOP-HINTS-CLAUSE
; :clause clause
; :ttree ttree)
; where ttree contains an :OR tag with the value, val,
; (parent-cl-id NIL ((user-hint1 . hint-settings1) ...))
; We smash the NIL to i. This indicates that along this branch of the
; history, we are dealing with user-hinti. Note that numbering starts
; at 1.
; While apply-top-hints-clause generates a ttree with a :or tagged
; object containing a nil, this function is used to replace that nil
; in the history of every branch by the particular i generating the
; branch.
; In the histories maintained by uninterrupted runs, you should never
; see an :OR tag with a nil in that slot. (Note carefully the use of
; the word "HISTORIES" above! It is possible to see ttrees with :OR
; tagged objects containing nil instead of a branch number. They get
; collected into the ttree inside the pspv that is following a clause
; around. But it is silly to inspect that ttree to find out the
; history of the clause, since you need the history for that.)
; The basic rule is that in a history recovered from an uninterupted
; proof attempt the entries with :signal OR-HIT will have a ttree with
; a tag :OR on an object (parent-cl-id i uhs-lst).
(let* ((val (tagged-object :or
(access history-entry (car hist) :ttree)))
(parent-cl-id (nth 0 val))
(uhs-lst (nth 2 val)))
(cons (make history-entry
:signal 'OR-HIT
:processor 'apply-top-hints-clause
:clause (access history-entry (car hist) :clause)
:ttree (add-to-tag-tree! :or
(list parent-cl-id
i
uhs-lst)
nil)
:cl-id ; only needed for #+acl2-par, but harmless
cl-id)
(cdr hist))))
(defun@par pair-cl-id-with-hint-setting (cl-id hint-settings)
; Background: An :OR hint takes a list of n translated hint settings,
; at a clause with a clause id. It essentially copies the clause n
; times, gives it a new clause id (with a "Dk" suffix), and arranges
; for the waterfall to apply each hint settings to one such copy of
; the clause. The way it arranges that is to change the hints in the
; pspv so that the newly generated "Dk" clause ids are paired with
; their respective hints. But computed hints are different! A
; computed hint isn't paired with a clause id. It has it built into
; the form somewhere. Now generally the user created the form and we
; assume the user saw the subgoal with the "Dk" id of interest and
; entered it into his form. But we generate some computed hint forms
; -- namely custom keyword hints. And we're responsible for tracking
; the new clause ids to which they apply.
; Hint-settings is a translated hint-settings. That is, it is either
; a dotted alist pairing common hint keywords to their translated
; values or it is a computed hint form starting with
; eval-and-translate-hint-expression. In the former case, we produce
; (cl-id . hint-settings). In the latter case, we look for the
; possibility that the term we are to eval is a call of the
; custom-keyword-hint-interpreter and if so smash its cl-id field.
(cond
((eq (car hint-settings) 'eval-and-translate-hint-expression)
(cond
((custom-keyword-hint-in-computed-hint-form hint-settings)
(put-cl-id-of-custom-keyword-hint-in-computed-hint-form@par
hint-settings cl-id))
(t hint-settings)))
(t (cons cl-id hint-settings))))
(defun apply-reorder-hint-front (indices len clauses acc)
(cond ((endp indices) acc)
(t (apply-reorder-hint-front
(cdr indices) len clauses
(cons (nth (- len (car indices)) clauses)
acc)))))
(defun apply-reorder-hint-back (indices current-index clauses acc)
(cond ((endp clauses) acc)
(t (apply-reorder-hint-back indices (1- current-index) (cdr clauses)
(if (member current-index indices)
acc
(cons (car clauses) acc))))))
(defun filter-> (lst max)
(cond ((endp lst) nil)
((> (car lst) max)
(cons (car lst)
(filter-> (cdr lst) max)))
(t (filter-> (cdr lst) max))))
(defun@par apply-reorder-hint (pspv clauses ctx state)
(let* ((hint-settings (access prove-spec-var pspv :hint-settings))
(hint-setting (assoc-eq :reorder hint-settings))
(indices (cdr hint-setting))
(len (length clauses)))
(cond (indices
(cond
((filter-> indices len)
(mv-let@par (erp val state)
(er@par soft ctx
"The following subgoal indices given by a :reorder ~
hint exceed the number of subgoals, which is ~x0: ~
~ ~&1."
len (filter-> indices len))
(declare (ignore val))
(mv@par erp nil nil state)))
(t
(mv@par nil
hint-setting
(reverse (apply-reorder-hint-back
indices len clauses
(apply-reorder-hint-front indices len clauses
nil)))
state))))
(t (mv@par nil nil clauses state)))))
; This completes the preliminaries for hints and we can get on with the
; waterfall itself soon. But first we provide additional rw-cache support (see
; the Essay on Rw-cache).
#+acl2-par
(defun pspv-equal-except-for-tag-tree-and-pool (x y)
; Warning: Keep this in sync with prove-spec-var. The only fields not
; addressed here should be the :tag-tree and :pool fields.
(and (equal (access prove-spec-var x :rewrite-constant)
(access prove-spec-var y :rewrite-constant))
(equal (access prove-spec-var x :induction-hyp-terms)
(access prove-spec-var y :induction-hyp-terms))
(equal (access prove-spec-var x :induction-concl-terms)
(access prove-spec-var y :induction-concl-terms))
(equal (access prove-spec-var x :hint-settings)
(access prove-spec-var y :hint-settings))
(equal (access prove-spec-var x :gag-state)
(access prove-spec-var y :gag-state))
(equal (access prove-spec-var x :user-supplied-term)
(access prove-spec-var y :user-supplied-term))
(equal (access prove-spec-var x :displayed-goal)
(access prove-spec-var y :displayed-goal))
(equal (access prove-spec-var x :orig-hints)
(access prove-spec-var y :orig-hints))
(equal (access prove-spec-var x :otf-flg)
(access prove-spec-var y :otf-flg))
; One can uncomment the following equal test to witness that the comparison is
; indeed actually occurring and causing a hard error upon failure.
; (equal (access prove-spec-var x :tag-tree)
; (access prove-spec-var y :tag-tree))
))
#+acl2-par
(defun list-extensionp-aux (rev-base rev-extension)
(assert$
(<= (length rev-base) (length rev-extension))
(if (atom rev-base)
t
(and (equal (car rev-base)
(car rev-extension))
(list-extensionp-aux (cdr rev-base)
(cdr rev-extension))))))
#+acl2-par
(defun list-extensionp (base extension)
(cond ((> (length base) (length extension))
nil)
(t
(list-extensionp-aux (reverse base)
(reverse extension)))))
#+acl2-par
(defun find-list-extensions (base extension acc)
(if (or (endp extension)
(equal extension base))
(reverse acc)
(find-list-extensions base (cdr extension) (cons (car extension) acc))))
#+acl2-par
(defun combine-pspv-pools (base x y debug-pspv)
(prog2$
(if debug-pspv
(with-output-lock
(cw "Combining base: ~x0 with x: ~%~x1 and with y: ~%~x2~%" base x y))
nil)
(append (find-list-extensions base y nil)
(find-list-extensions base x nil)
base)))
#+acl2-par
(defun combine-pspv-tag-trees (x y)
; We reverse the arguments, because y was generated after x in time (in the
; serial case). And since accumulating into a tag-tree is akin to pushing onto
; the front of a list, y is the first argument to the "cons".
(cons-tag-trees-rw-cache y x))
#+acl2-par
(defun print-pspvs (base x y debug-pspv)
(if debug-pspv
(progn$
(cw "Base is:~% ~x0~%" base)
(cw "X is:~% ~x0~%" X)
(cw "Y is:~% ~x0~%" Y))
nil))
#+acl2-par
(defun combine-prove-spec-vars (base x y ctx debug-pspv signal1 signal2)
; X and Y should be extensions of the base. That is, every member of base
; should be in both x and y. Also, note that switching the order of x and y
; returns a result that means something different. The order with which we
; combine pspv's matters.
(assert$
; We check that the signals aren't abort. This way we know that we are in case
; (1), as described in "Essay on prove-spec-var pool modifications". We also
; know that this assertion is always true from just examining the code.
(and (not (equal signal1 'abort))
(not (equal signal2 'abort)))
(cond
; We first test to make sure that the pspv's were only changed in the two
; fields that we know how to combine.
((not (pspv-equal-except-for-tag-tree-and-pool x y))
(prog2$
(print-pspvs base x y debug-pspv)
(er hard ctx
"Implementation error: waterfall1 returns the pspv changed in a way ~
other than the :tag-tree and :pool fields.")))
(t
(change prove-spec-var x
:tag-tree
(combine-pspv-tag-trees
(access prove-spec-var x :tag-tree)
(access prove-spec-var y :tag-tree))
:pool
(combine-pspv-pools
(access prove-spec-var base :pool)
(access prove-spec-var x :pool)
(access prove-spec-var y :pool)
debug-pspv))))))
; The following form may be helpful for tracing waterfall1-lst in an effort to
; understand how the pspv's :pool is modified.
; (trace$
; (waterfall1-lst
; :entry (list 'waterfall1-lst
; 'clauses=
; clauses
; 'pspv-pool=
; (access prove-spec-var pspv :pool))
; :exit (list 'waterfall1-lst
; 'signal=
; (cadr values)
; 'pspv-pool=
; (access prove-spec-var (caddr values) :pool))))
#+acl2-par
(defun speculative-execution-valid (x y)
; This function aids in determining whether a speculative evaluation of the
; waterfall is valid. Typically, X is the pspv given to the current call of
; waterfall1-lst, and Y is the pspv returned from calling waterfall1 on the
; first clause.
; For now, if anything but the tag-tree or pool is different, we want to
; immediately return nil, because we don't know how to handle the combining of
; such pspv's.
(assert$ (pspv-equal-except-for-tag-tree-and-pool x y)
t))
#+acl2-par
(defun abort-will-occur-in-pool (pool)
; Returns t if the given pool requires that we abort the current set of subgoal
; proof attempts and revert to prove the original conjecture by induction. The
; function must only consider the case where 'maybe-to-be-proved-by-induction
; tags are present, because push-clause[@par] handles all other cases.
; If you change this function, evaluate the following form. If the result is
; an error, then either modify the form below or fix the change.
; (assert$
; (and
; (not (abort-will-occur-in-pool '((maybe-to-be-proved-by-induction sub orig))))
; (abort-will-occur-in-pool '((maybe-to-be-proved-by-induction sub orig)
; (to-be-proved-by-induction)
; (to-be-proved-by-induction)))
; (not (abort-will-occur-in-pool '((to-be-proved-by-induction))))
; (not (abort-will-occur-in-pool '((to-be-proved-by-induction)
; (maybe-to-be-proved-by-induction sub orig))))
; (not (abort-will-occur-in-pool '((maybe-to-be-proved-by-induction sub orig))))
; (not (abort-will-occur-in-pool '((to-be-proved-by-induction)
; (to-be-proved-by-induction)
; (to-be-proved-by-induction))))
; (abort-will-occur-in-pool '((maybe-to-be-proved-by-induction sub orig)
; (to-be-proved-by-induction)
; (to-be-proved-by-induction)
; (maybe-to-be-proved-by-induction sub2 orig2)))
; (abort-will-occur-in-pool '((to-be-proved-by-induction a)
; (maybe-to-be-proved-by-induction sub orig)
; (to-be-proved-by-induction b)
; (to-be-proved-by-induction c)
; (maybe-to-be-proved-by-induction sub2 orig2))))
; "abort-will-occur-in-pool tests passed")
(cond ((atom pool)
nil)
((and (equal (caar pool) 'maybe-to-be-proved-by-induction)
(consp (cdr pool)))
t)
(t (abort-will-occur-in-pool (cdr pool)))))
#+acl2-par
(defrec maybe-to-be-proved-by-induction
; Important Note: This record is laid out this way so that we can use assoc-eq
; on the pspv pool to detect the presence of a maybe-to-be-proved-by-induction
; tag. Do not move the key field!
(key subgoal original)
t)
#+acl2-par
(defun convert-maybes-to-tobe-subgoals (pool)
; This function converts all 'maybe-to-be-proved-by-induction records to
; 'to-be-proved-by-induction pool-elements. Since this function is only called
; in the non-abort case, it uses the :subgoal field of the record.
(cond ((atom pool)
nil)
((equal (caar pool) 'maybe-to-be-proved-by-induction)
(cons (access maybe-to-be-proved-by-induction (car pool) :subgoal)
(convert-maybes-to-tobe-subgoals (cdr pool))))
(t (cons (car pool)
(convert-maybes-to-tobe-subgoals (cdr pool))))))
#+acl2-par
(defun convert-maybes-to-tobes (pool)
; This function converts a pool that contains 'maybe-to-be-proved-by-induction
; records to a pool that either (1) aborts and proves the :original conjecture
; or (2) replaces all such clauses with their :subgoal
; 'to-be-proved-by-induction pool-element. This function outsources all
; thinking about whether we are in an abort case to the function
; abort-will-occur-in-pool.
; If you change this function, evaluate the following form. If the result is
; an error, then either modify the form below or fix the change.
; (assert$
; (and
; (equal (convert-maybes-to-tobes '((maybe-to-be-proved-by-induction sub orig)))
; '(sub))
; (equal
; (convert-maybes-to-tobes '((maybe-to-be-proved-by-induction sub orig)
; (to-be-proved-by-induction)
; (to-be-proved-by-induction)))
; '(orig))
; (equal
; (convert-maybes-to-tobes '((to-be-proved-by-induction)))
; '((to-be-proved-by-induction)))
; (equal (convert-maybes-to-tobes '((to-be-proved-by-induction)
; (maybe-to-be-proved-by-induction sub orig)))
; '((to-be-proved-by-induction)
; sub))
; (equal (convert-maybes-to-tobes '((maybe-to-be-proved-by-induction sub orig)))
; '(sub))
; (equal (convert-maybes-to-tobes '((maybe-to-be-proved-by-induction sub orig)
; (to-be-proved-by-induction)
; (to-be-proved-by-induction)
; (maybe-to-be-proved-by-induction sub2 orig2)))
; '(orig))
; (equal (convert-maybes-to-tobes '((to-be-proved-by-induction a)
; (maybe-to-be-proved-by-induction sub orig)
; (to-be-proved-by-induction b)
; (to-be-proved-by-induction c)
; (maybe-to-be-proved-by-induction sub2
; orig2)))
; '(orig))
; (equal (convert-maybes-to-tobes
; '((maybe-to-be-proved-by-induction sub1 orig)
; (to-be-proved-by-induction a)
; (maybe-to-be-proved-by-induction sub2 orig)
; (to-be-proved-by-induction b)
; (to-be-proved-by-induction c)
; (maybe-to-be-proved-by-induction sub3 orig)))
; '(orig))
; )
; "convert-maybes-to-tobes tests worked."
; )
(cond ((atom pool)
nil)
((abort-will-occur-in-pool pool)
(list (access maybe-to-be-proved-by-induction
; It doesn't matter whether we use the first 'maybe-to-be-proved-by-induction
; tag to cause an abort, because the :original field will be the same for all
; of them.
(assoc-eq 'maybe-to-be-proved-by-induction pool)
:original)))
(t (convert-maybes-to-tobe-subgoals pool))))
#+acl2-par
(defun convert-maybes-to-tobes-in-pspv (pspv)
(change prove-spec-var pspv
:pool
(convert-maybes-to-tobes (access prove-spec-var pspv :pool))))
; This completes the preliminaries for hints and we can get on with the
; waterfall itself soon. But first we provide additional rw-cache support (see
; the Essay on Rw-cache).
(defun erase-rw-cache-any-tag-from-pspv (pspv)
; We maintain the invariant that the "nil" cache is contained in the "any"
; cache.
(let ((ttree (access prove-spec-var pspv :tag-tree)))
(cond ((tagged-objectsp 'rw-cache-any-tag ttree)
(change prove-spec-var pspv
:tag-tree (rw-cache-enter-context ttree)))
(t pspv))))
(defun restore-rw-cache-state-in-pspv (new-pspv old-pspv)
(let* ((old-rcnst (access prove-spec-var old-pspv :rewrite-constant))
(old-rw-cache-state (access rewrite-constant old-rcnst
:rw-cache-state))
(new-rcnst (access prove-spec-var new-pspv :rewrite-constant))
(new-rw-cache-state (access rewrite-constant new-rcnst
:rw-cache-state)))
(cond ((eq old-rw-cache-state new-rw-cache-state) new-pspv)
(t (change prove-spec-var new-pspv
:rewrite-constant
(change rewrite-constant new-rcnst
:rw-cache-state old-rw-cache-state))))))
#+(and acl2-par (not acl2-loop-only))
(defvar *waterfall-parallelism-timings-ht-alist* nil
"Association list of hashtables, where the key is the name of a theorem
attempted with a defthm, and the value is a hashtable mapping from
clause-ids to the time it took to prove that clause.")
#+(and acl2-par (not acl2-loop-only))
(defvar *waterfall-parallelism-timings-ht* nil
"This variable supports the :resource-and-timing-based mode for waterfall
parallelism. It can contain the hashtable that associates
waterfall-parallelism timings with each clause-id. This variable should
always be nil unless ACL2(p) is in the middle of attempting a proof
initiated by the user with a defthm.")
#+acl2-par
(defun setup-waterfall-parallelism-ht-for-name (name)
#-acl2-loop-only
(let ((curr-ht (assoc-eq name *waterfall-parallelism-timings-ht-alist*)))
(cond ((null curr-ht)
(let ((new-ht (make-hash-table :test 'equal :size (expt 2 13)
; Parallelism blemish: CCL locks these hashtable operations automatically
; because of the argument :shared t below. However in SBCL and LispWorks, we
; should really lock these hashtable operations ourselves. Note that the SBCL
; documentation at http://www.sbcl.org/manual/Hash-Table-Extensions.html
; describes a keyword, :synchronized, that is like CCL's :shared but is labeled
; as "experimental". At any rate, we are willing to take our chances for now
; with SBCL and Lispworks.
#+ccl :shared #+ccl t)))
(setf *waterfall-parallelism-timings-ht-alist*
(acons name
new-ht
(take 4 *waterfall-parallelism-timings-ht-alist*)))
(setf *waterfall-parallelism-timings-ht* new-ht)))
(t (setf *waterfall-parallelism-timings-ht* (cdr curr-ht)))))
name)
#+acl2-par
(defun clear-current-waterfall-parallelism-ht ()
#-acl2-loop-only
(setf *waterfall-parallelism-timings-ht* nil)
t)
#+acl2-par
(defun flush-waterfall-parallelism-hashtables ()
#-acl2-loop-only
(progn
(setf *waterfall-parallelism-timings-ht-alist* nil)
(setf *waterfall-parallelism-timings-ht* nil))
t)
#+(and acl2-par (not acl2-loop-only))
(defun save-waterfall-timings-for-cl-id (key value)
(when *waterfall-parallelism-timings-ht*
(setf (gethash key *waterfall-parallelism-timings-ht*)
value))
value)
#+(and acl2-par (not acl2-loop-only))
(defun lookup-waterfall-timings-for-cl-id (key)
(mv-let (val found)
(cond (*waterfall-parallelism-timings-ht*
(gethash key *waterfall-parallelism-timings-ht*))
(t (mv nil nil)))
(declare (ignore found))
(or val 0)))
(defmacro waterfall1-wrapper (form)
; We create a non-@par version of waterfall1-wrapper that is the identity, so
; we can later have an @par version that does something important for the
; parallel case. In the #-acl2-par case, or the serial case,
; waterfall1-wrapper will have no effect, returning its argument unchanged.
; For a discussion about such matters, see the long comment in *@par-mappings*.
form)
#+(and acl2-par (not acl2-loop-only))
(defparameter *acl2p-starting-proof-time* 0.0d0)
#+acl2-par
(defun waterfall1-wrapper@par-before (cl-id state)
(case (f-get-global 'waterfall-printing state)
(:limited
(and (print-clause-id-okp cl-id)
(with-output-lock
; Parallelism blemish: Kaufmann suggests that we need to skip printing
; clause-ids that have already been printed. Note that using the printing of
; clause-ids to show that the prover is still making progress is no longer the
; default setting (see :doc set-waterfall-printing). This is a low-priority
; blemish, because as of 2012-07, the main ACL2 users use the :very-limited
; setting for waterfall-printing -- this setting only prints periods, not
; clause-ids. Example:
; (set-waterfall-parallelism :pseudo-parallel)
; (set-waterfall-printing :limited)
; (thm (implies (equal x y) (equal u v)))
; Parallelism blemish: here, and at many other ACL2(p)-specific places, consider
; using observation-cw or printing that can be inhibited, instead of cw. We
; have not tried this so far because observation-cw calls wormhole, which is
; problematic (see the comment in waterfall-print-clause-id@par).
#+acl2-loop-only
nil
#-acl2-loop-only
(format t "At time ~,6f sec, starting: ~a~%"
(/ (- (get-internal-real-time)
*acl2p-starting-proof-time*)
internal-time-units-per-second)
(string-for-tilde-@-clause-id-phrase cl-id)))))
(:very-limited
(with-output-lock
(cw ".")))
(otherwise nil)))
#+acl2-par
(defun waterfall1-wrapper@par-after (cl-id start-time state)
#+acl2-loop-only
(declare (ignore start-time cl-id))
#-acl2-loop-only
(save-waterfall-timings-for-cl-id
cl-id
(- (get-internal-real-time) ; end time
start-time))
(cond ((f-get-global 'waterfall-printing-when-finished state)
(cond ((equal (f-get-global 'waterfall-printing state) :very-limited)
(with-output-lock (cw ",")))
((equal (f-get-global 'waterfall-printing state) :limited)
(with-output-lock
#+acl2-loop-only
nil
#-acl2-loop-only
(format t "At time ~,6f sec, finished: ~a~%"
(/ (- (get-internal-real-time)
*acl2p-starting-proof-time*)
internal-time-units-per-second)
(string-for-tilde-@-clause-id-phrase cl-id))))
(t nil)))
(t nil)))
#+acl2-par
(defmacro waterfall1-wrapper@par (&rest form)
`(let ((start-time
#+acl2-loop-only 'ignored-value
#-acl2-loop-only (get-internal-real-time)))
(prog2$
(waterfall1-wrapper@par-before cl-id state)
(mv-let@par
(step-limit signal pspv jppl-flg state)
,@form
(prog2$ (waterfall1-wrapper@par-after cl-id start-time state)
(mv@par step-limit signal pspv jppl-flg state))))))
#+acl2-par
(defun increment-waterfall-parallelism-counter (abbreviated-symbol)
(case abbreviated-symbol
((resource-and-timing-parallel)
#-acl2-loop-only
(incf *resource-and-timing-based-parallelizations*)
'parallel)
((resource-and-timing-serial)
#-acl2-loop-only
(incf *resource-and-timing-based-serializations*)
'serial)
((resource-parallel)
#-acl2-loop-only
(incf *resource-based-parallelizations*)
'parallel)
((resource-serial)
#-acl2-loop-only
(incf *resource-based-serializations*)
'serial)
(otherwise
(er hard 'increment-waterfall-parallelism-counter
"Illegal value ~x0 was given to ~
increment-waterfall-parallelism-counter"
abbreviated-symbol))))
#+acl2-par
(defun halves-with-length (clauses)
; Returns (mv first-half second-half len), where clauses is split into the
; indicated halves (maintaining the order of the input list), and len is the
; length of the first half.
(declare (xargs :guard (true-listp clauses)))
(let* ((len (length clauses))
(split-point (ceiling (/ len 2) 1))
(first-half (take split-point clauses))
(second-half (nthcdr split-point clauses)))
(mv first-half second-half split-point)))
(mutual-recursion@par
(defun@par waterfall1
(ledge cl-id clause hist pspv hints suppress-print ens wrld ctx state
step-limit)
; ledge - In general in this mutually recursive definition, the
; formal "ledge" is any one of the waterfall ledges. But
; by convention, in this function, waterfall1, it is
; always either the 'apply-top-hints-clause ledge or
; the next one, 'preprocess-clause. Waterfall1 is the
; place in the waterfall that hints are applied.
; Waterfall0 is the straightforward encoding of the
; waterfall, except that every time it sends clauses back
; to the top, it send them to waterfall1 so that hints get
; used again.
; cl-id - the clause id for clause.
; clause - the clause to process
; hist - the history of clause
; pspv - an assortment of special vars that any clause processor might
; change
; hints - an alist mapping clause-ids to hint-settings.
; wrld - the current world
; state - the usual state
; step-limit - the new step-limit.
; We return 5 values. The first is a new step-limit. The second is a "signal"
; and is one of 'abort, 'error, or 'continue. The last three returned values
; are the final values of pspv, the jppl-flg for this trip through the falls,
; and state. The 'abort signal is used by our recursive processing to
; implement aborts from below. When an abort occurs, the clause processor that
; caused the abort sets the pspv and state as it wishes the top to see them.
; When the signal is 'error, the error message has been printed. The returned
; pspv is irrelevant (and typically nil).
(mv-let@par
(erp pair state)
(find-applicable-hint-settings@par cl-id clause hist pspv ctx hints
wrld nil state)
; If no error occurs and pair is non-nil, then pair is of the form
; (hint-settings . hints') where hint-settings is the hint-settings
; corresponding to cl-id and clause and hints' is hints with the appropriate
; element removed.
(cond
(erp
; This only happens if some hint function caused an error, e.g., by
; generating a hint that would not translate. The error message has been
; printed and pspv is irrelevant. We pass the error up.
(mv@par step-limit 'error nil nil state))
(t (sl-let@par
(signal new-pspv jppl-flg state)
(cond
((null pair) ; There was no hint.
(pprogn@par
; In the #+acl2-par version of the waterfall, with global waterfall-printing
; set to :limited, the need to print the clause on a checkpoint is taken care
; of inside waterfall-msg@par.
(waterfall-print-clause@par suppress-print cl-id clause
state)
(waterfall0@par ledge cl-id clause hist pspv hints ens wrld ctx
state step-limit)))
(t (waterfall0-with-hint-settings@par
(car pair)
ledge cl-id clause hist pspv (cdr pair) suppress-print ens wrld
ctx state step-limit)))
(let ((pspv (cond ((null pair)
(restore-rw-cache-state-in-pspv new-pspv pspv))
(t new-pspv))))
(mv-let@par
(pspv state)
(cond ((or (eq signal 'miss)
(eq signal 'error))
(mv@par pspv state))
(t (gag-state-exiting-cl-id@par signal cl-id pspv state)))
(mv@par step-limit signal pspv jppl-flg state))))))))
(defun@par waterfall0-with-hint-settings
(hint-settings ledge cl-id clause hist pspv hints goal-already-printedp
ens wrld ctx state step-limit)
; We ``install'' the hint-settings given and call waterfall0 on the
; rest of the arguments.
(mv-let@par
(hint-settings state)
(thanks-for-the-hint@par goal-already-printedp hint-settings state)
(pprogn@par
(waterfall-print-clause@par goal-already-printedp cl-id clause state)
(mv-let@par
(erp new-pspv-1 state)
(load-hint-settings-into-pspv@par t hint-settings pspv cl-id wrld ctx
state)
(cond
(erp (mv@par step-limit 'error pspv nil state))
(t
(pprogn@par
(maybe-warn-for-use-hint@par new-pspv-1 cl-id ctx wrld state)
(maybe-warn-about-theory-from-rcnsts@par
(access prove-spec-var pspv :rewrite-constant)
(access prove-spec-var new-pspv-1 :rewrite-constant)
ctx ens wrld state)
; If there is no :INDUCT hint, then the hint-settings can be handled by
; modifying the clause and the pspv we use subsequently in the falls.
(sl-let@par (signal new-pspv new-jppl-flg state)
(waterfall0@par (cond ((assoc-eq :induct hint-settings)
'(push-clause))
(t ledge))
cl-id
clause
hist
new-pspv-1
hints ens wrld ctx state step-limit)
(mv@par step-limit
signal
(restore-hint-settings-in-pspv new-pspv pspv)
new-jppl-flg state)))))))))
(defun@par waterfall0 (ledge cl-id clause hist pspv hints ens wrld ctx state
step-limit)
(sl-let@par
(signal clauses new-hist new-pspv new-jppl-flg state)
(cond
((null ledge)
; The only way that the ledge can be nil is if the push-clause at the
; bottom of the waterfall signalled 'MISS. This only happens if
; push-clause found a :DO-NOT-INDUCT name hint. That being the case,
; we want to act like a :BY name' hint was attached to that clause,
; where name' is the result of extending the supplied name with the
; clause id. This fancy call of waterfall-step is just a cheap way to
; get the standard :BY name' processing to happen. All it will do is
; add a :BYE (name' . clause) to the tag-tree of the new-pspv. We
; know that the signal returned will be a "hit". Because we had to smash
; the hint-settings to get this to happen, we'll have to restore them
; in the new-pspv.
(waterfall-step@par
'apply-top-hints-clause
cl-id clause hist
(change prove-spec-var pspv
:hint-settings
(list
(cons :by
(convert-name-tree-to-new-name
(cons (cdr (assoc-eq
:do-not-induct
(access prove-spec-var pspv :hint-settings)))
(string-for-tilde-@-clause-id-phrase cl-id))
wrld))))
wrld ctx state step-limit))
((eq (car ledge) 'eliminate-destructors-clause)
(mv-let@par (erp pair state)
(find-applicable-hint-settings@par ; stable-under-simplificationp=t
cl-id clause hist pspv ctx hints wrld t state)
(cond
(erp
; A hint generated an error. The error message has been printed and
; we pass the error up. The other values are all irrelevant.
#+acl2-par
(assert$
; At one time, the waterfall returned Context Message Pairs. This assertion
; was subsequently added to check that we no longer do so. Since it's an
; inexpensive check, we leave it here.
(not pair)
(mv@par step-limit 'error nil nil nil nil state))
#-acl2-par
(mv@par step-limit 'error nil nil nil nil state))
(pair
; A hint was found. The car of pair is the new hint-settings and the
; cdr of pair is the new value of hints. We need to arrange for
; waterfall0-with-hint-settings to be called. But we are inside
; mv-let binding signal, etc., above. We generate a fake ``signal''
; to get out of here and handle it below.
(mv@par step-limit
'top-of-waterfall-hint
(car pair) hist (cdr pair) nil state))
; Otherwise no hint was applicable. We do exactly the same thing we would have
; done had (car ledge) not been 'eliminate-destructors-clause, after checking
; whether we should make a desperate final attempt to simplify, with caching
; turned off. Keep these two calls of waterfall-step in sync!
((eq (access rewrite-constant
(access prove-spec-var pspv
:rewrite-constant)
:rw-cache-state)
t)
; We return an updated pspv, together with a bogus signal indicating that we
; are to make a "desperation" run through the simplifier with the rw-cache
; disabled. The nil values returned below will be ignored.
(mv@par step-limit
'top-of-waterfall-avoid-rw-cache
nil nil
(set-rw-cache-state-in-pspv
(erase-rw-cache-from-pspv pspv)
:disabled)
nil state))
((member-eq (car ledge)
(assoc-eq :do-not
(access prove-spec-var pspv
:hint-settings)))
(mv@par step-limit 'miss nil hist pspv nil state))
(t (waterfall-step@par (car ledge) cl-id clause hist pspv
wrld ctx state step-limit)))))
((member-eq (car ledge)
(assoc-eq :do-not (access prove-spec-var pspv :hint-settings)))
(mv@par step-limit 'miss nil hist pspv nil state))
(t (waterfall-step@par (car ledge) cl-id clause hist pspv wrld ctx state
step-limit)))
(cond
((eq signal 'OR-HIT)
; A disjunctive, hint-driven split has been requested by an :OR hint.
; Clauses is a singleton containing the clause to which we are to
; apply all of the hints. The hints themselves are recorded in the
; first entry of the new-hist, which necessarily has the form
; (make history-entry
; :signal 'OR-HIT
; :processor 'APPLY-TOP-HINTS-CLAUSE
; :clause clause
; :ttree ttree)
; where ttree contains an :OR tag with the value, val,
; (parent-cl-id NIL ((user-hint1 . hint-settings1) ...))
; Note that we are guaranteed here that (nth 1 val) is NIL. That is
; because that's what apply-top-hints-clause puts into its ttree.
; It will be replaced along every history by the appropriate i.
; We recover this crucial data first.
(let* ((val (tagged-object :or
(access history-entry
(car new-hist)
:ttree)))
; (parent-cl-id (nth 0 val)) ;;; same as our cl-id!
(uhs-lst (nth 2 val))
(branch-cnt (length uhs-lst)))
; Note that user-hinti is what the user wrote and hint-settingsi is
; the corresponding translation. For each i we are going to act just
; like the user supplied the given hint for the parent. Thus the
; waterfall will act like it saw parent n times, once for each
; user-hinti.
; For example, if the original :or hint was
; ("Subgoal 3" :OR ((:use lemma1 :in-theory (disable lemma1))
; (:use lemma2 :in-theory (disable lemma2))))
;
; then we will act just as though we saw "Subgoal 3" twice,
; once with the hint
; ("Subgoal 3" :use lemma1 :in-theory (disable lemma1))
; and then again with the hint
; ("Subgoal 3" :use lemma2 :in-theory (disable lemma2)).
; except that we give the two occurrences of "Subgoal 3" different
; names for sanity.
(waterfall0-or-hit@par
ledge cl-id
(assert$ (and (consp clauses) (null (cdr clauses)))
(car clauses))
new-hist new-pspv hints ens wrld ctx state
uhs-lst 1 branch-cnt nil nil step-limit)))
(t
(let ((new-pspv
(if (and (null ledge)
(not (eq signal 'error)))
; If signal is 'error, then new-pspv is nil (e.g., see the error
; behavior of waterfall step) and we wish to avoid manipulating a
; bogus pspv.
(restore-hint-settings-in-pspv new-pspv pspv)
new-pspv)))
(cond
((eq signal 'top-of-waterfall-hint)
; This fake signal just means that either we have found an applicable hint for
; a clause that was stable under simplification (stable-under-simplificationp =
; t), or that we have found an applicable :backtrack hint.
(mv-let
(hint-settings hints pspv goal-already-printedp)
(cond ((eq new-pspv :pspv-for-backtrack)
; The variable named clauses is holding the hint-settings.
(mv clauses
(append new-jppl-flg ; new-hints
hints)
; We will act as though we have just discovered the hint-settings and leave it
; up to waterfall0-with-hint-settings to restore the pspv if necessary after
; trying those hint-settings. Note that the rw-cache is restored (as part of
; the tag-tree, which is part of the rewrite-constant of the pspv).
(change prove-spec-var pspv :hint-settings
(delete-assoc-eq :backtrack
(access prove-spec-var pspv
:hint-settings)))
(cons :backtrack new-hist) ; see thanks-for-the-hint
))
(t
; The variables named clauses and new-pspv are holding the hint-settings and
; hints in this case. We reenter the top of the falls with the new hint
; setting and hints.
(mv clauses
new-pspv
pspv
t)))
(waterfall0-with-hint-settings@par
hint-settings
*preprocess-clause-ledge*
cl-id clause
; Through Version_6.4, simplify-clause contained an optimization that avoided
; resimplifying the clause if the most recent history entry is for
; settled-down-clause and (approximately) the induction hyp and concl terms
; don't occur in it. Here, we short-circuited that short-circuited by removing
; the settled-down-clause entry if it is the most recent. We no longer have
; that reason for removing the settled-down-clause entry, but it still seems
; reasonable to do so, i.e., to consider the clause not to have settled down
; when popping back to the top of the waterfall because of a hint. Moreover,
; we tried removing this modification to hist and found several regression
; failures.
(cond ((and (consp hist)
(eq (access history-entry (car hist) :processor)
'settled-down-clause))
(cdr hist))
(t hist))
pspv hints goal-already-printedp ens wrld ctx state step-limit)))
((eq signal 'top-of-waterfall-avoid-rw-cache)
; New-pspv already has the rw-cache disabled. Pop up to simplify-clause. The
; next waterfall-step, which will be a simplify-clause step unless a :do-not
; hint prohibits that, will re-enable the rw-cache.
(waterfall0@par *simplify-clause-ledge*
cl-id clause hist new-pspv hints ens wrld ctx state
step-limit))
((eq signal 'error)
(mv@par step-limit 'error nil nil state))
((eq signal 'abort)
(mv@par step-limit 'abort new-pspv new-jppl-flg state))
((eq signal 'miss)
(if ledge
(waterfall0@par (cdr ledge)
cl-id
clause
new-hist ; used because of specious entries
new-pspv
hints
ens
wrld
ctx
state
step-limit)
(mv@par step-limit
(er hard 'waterfall0
"The empty ledge signalled 'MISS! This can only ~
happen if we changed APPLY-TOP-HINTS-CLAUSE so that ~
when given a single :BY name hint it fails to hit.")
nil nil state)))
(t
; Signal is one of the flavors of 'hit, 'hit-rewrite, or 'hit-rewrite2.
(mv-let@par
(erp hint-setting clauses state)
(apply-reorder-hint@par pspv clauses ctx state)
(cond
(erp
(mv@par step-limit 'error nil nil state))
(t
(let ((new-pspv
(if (cddr clauses)
; We erase the "any" cache if there are at least two children, much as we erase
; it (more accurately, replace it by the smaller "nil" cache) when diving into
; a branch of an IF term. Actually, we needn't erase the "any" cache if the
; rw-cache is inactive. But rather than consider carefully when the cache
; becomes active and inactive due to hints, we simply go ahead and do the cheap
; erase operation here.
(erase-rw-cache-any-tag-from-pspv new-pspv)
new-pspv)))
(waterfall1-lst@par
(cond ((eq (car ledge) 'settled-down-clause)
'settled-down-clause)
((null clauses) 0)
((null (cdr clauses)) nil)
(t (length clauses)))
cl-id
clauses
new-hist
(if hint-setting
(change
prove-spec-var new-pspv
:hint-settings
(remove1-equal hint-setting
(access prove-spec-var
new-pspv
:hint-settings)))
new-pspv)
new-jppl-flg
hints
(eq (car ledge) 'settled-down-clause)
ens
wrld
ctx
state
step-limit))))))))))))
(defun@par waterfall0-or-hit (ledge cl-id clause hist pspv hints ens wrld ctx
state uhs-lst i branch-cnt revert-info
results step-limit)
; Cl-id is the clause id of clause, of course, and we are to disjunctively
; apply each of the hints in ush-lst to it. Uhs-lst is of the form
; (...(user-hinti . hint-settingsi)...) and branch-cnt is the length of that
; list initially, i.e., the maximum value of i.
; We map over uhs-lst and pursue each branch, giving each its own "D" clause id
; and changing the ttree in its history entry to indicate that it is branch i.
; We collect the results as we go into results. The results are each of the
; form (d-cl-id . new-pspv), where new-pspv is the pspv that results from
; processing the branch. If the :pool in any one of these new-pspv's is equal
; to that in pspv, then we have succeeded (nothing was pushed) and we stop.
; Otherwise, when we have considered all the hints in uhs-lst, we inspect
; results and choose the best (least difficult looking) one to pursue further.
; Revert-info is nil unless we have seen a disjunctive subgoal that generated a
; signal to abort and revert to the original goal. In that case, revert-info
; is a pair (revert-d-cl-id . pspv) where revert-d-cl-id identifies that
; disjunctive subgoal (the first one, in fact) and pspv is the corresponding
; pspv returned for that subgoal.
#+acl2-par
(declare (ignorable branch-cnt)) ; irrelevant in @par definition
(cond
((endp uhs-lst)
; Results is the result of doing all the elements of uhs-lst. If it is empty,
; all branches aborted. Otherwise, we have to choose between the results.
(cond
((endp results)
; In this case, every single disjunct aborted. That means each failed in one
; of three ways: (a) it set the goal to nil, (b) it needed induction but found
; a hint prohibiting it, or (c) it chose to revert to the original input. We
; will cause the whole proof to abort. We choose to revert if revert-d-cl-id
; is non-nil, indicating that (c) occurred for at least one disjunctive branch,
; namely one with a clause-id of revert-d-cl-id.
(pprogn@par
(serial-only@par
(io? prove nil state
(cl-id revert-info)
(waterfall-or-hit-msg-c cl-id nil (car revert-info) nil nil
state)))
(mv@par step-limit
'abort
(cond (revert-info (cdr revert-info))
(t
(change prove-spec-var pspv
:pool (cons (make pool-element
:tag 'TO-BE-PROVED-BY-INDUCTION
:clause-set '(nil)
:hint-settings nil)
(access prove-spec-var pspv :pool))
:tag-tree
(add-to-tag-tree 'abort-cause
'empty-clause
(access prove-spec-var pspv
:tag-tree)))))
(and revert-info
; Keep the following in sync with the corresponding call of pool-lst in
; waterfall-msg. That call assumes that the pspv was returned by push-clause,
; which is also the case here.
(pool-lst (cdr (access prove-spec-var (cdr revert-info)
:pool))))
state)))
(t (mv-let (choice summary)
(pick-best-pspv-for-waterfall0-or-hit results pspv wrld)
#+acl2-par
(declare (ignorable summary))
(pprogn@par
(serial-only@par
(io? proof-tree nil state
(choice cl-id)
(pprogn
(increment-timer 'prove-time state)
(install-disjunct-into-proof-tree cl-id (car choice) state)
(increment-timer 'proof-tree-time state))))
(serial-only@par
(io? prove nil state
(cl-id results choice summary)
(waterfall-or-hit-msg-c cl-id ; parent-cl-id
results
nil
(car choice) ; new goal cl-id
summary
state)))
(mv@par step-limit
'continue
(cdr choice) ; chosen pspv
; Through Version_3.3 we used a jppl-flg here instead of nil. But to the
; extent that this value controls whether we print the goal before starting
; induction, we prefer to print it: for the corresponding goal pushed for
; induction under one of the disjunctive subgoals, the connection might not be
; obvious to the user.
nil
state))))))
(t
(let* ((user-hinti (car (car uhs-lst)))
(hint-settingsi (cdr (car uhs-lst)))
(d-cl-id (make-disjunctive-clause-id cl-id (length uhs-lst)
(current-package state))))
#+acl2-par
(declare (ignorable user-hinti))
(pprogn@par
(serial-only@par
; Wormholes are known to be a problem in the @par version of the waterfall. As
; such, we skip the following call of waterfall-or-hit-msg-a (also for some
; similar calls further down), which we have determined through runs of the
; regression suite (specifically with community book
; arithmetic-5/lib/floor-mod/floor-mod-basic.lisp) to cause problems.
(io? prove nil state
(cl-id user-hinti d-cl-id i branch-cnt)
(pprogn
(increment-timer 'prove-time state)
(waterfall-or-hit-msg-a cl-id user-hinti d-cl-id i branch-cnt
state)
(increment-timer 'print-time state))))
(sl-let@par
(d-signal d-new-pspv d-new-jppl-flg state)
(waterfall1-wrapper@par
(waterfall1@par ledge
d-cl-id
clause
(change-or-hit-history-entry i hist cl-id)
pspv
(cons (pair-cl-id-with-hint-setting@par d-cl-id
hint-settingsi)
hints)
t ;;; suppress-print
ens
wrld ctx state step-limit))
(declare (ignore d-new-jppl-flg))
; Here, d-signal is one of 'error, 'abort or 'continue. We pass 'error up
; immediately and we filter 'abort out.
(cond
((eq d-signal 'error)
; Errors shouldn't happen and we stop with an error if one does.
(mv@par step-limit 'error nil nil state))
((eq d-signal 'abort)
; Aborts are normal -- the proof failed somehow; we just skip it and continue
; with its peers.
(waterfall0-or-hit@par
ledge cl-id clause hist pspv hints ens wrld ctx state
(cdr uhs-lst) (+ 1 i) branch-cnt
(or revert-info
(and (equal (tagged-objects 'abort-cause
(access prove-spec-var d-new-pspv
:tag-tree))
'(revert))
(cons d-cl-id d-new-pspv)))
results step-limit))
((equal (access prove-spec-var pspv :pool)
(access prove-spec-var d-new-pspv :pool))
; We won! The pool in the new pspv is the same as the pool in the old, which
; means all the subgoals generated in the branch were proved (modulo any forced
; assumptions, etc., in the :tag-tree). In this case we terminate the sweep
; across the disjuncts.
; Parallelism wart: you'll get a runtime error if pprogn@par forms are
; evaluated that have state returned by other than the last form, such as the
; call below of waterfall-or-hit-msg-b. Example: (WORMHOLE1 'COMMENT-WINDOW-IO
; 'NIL '(PPROGN (PRINC$ 17 *STANDARD-CO* STATE) 17) 'NIL)
(pprogn@par
(serial-only@par
(io? proof-tree nil state
(d-cl-id cl-id)
(pprogn
(increment-timer 'prove-time state)
(install-disjunct-into-proof-tree cl-id d-cl-id state)
(increment-timer 'proof-tree-time state))))
(serial-only@par
(io? prove nil state
(cl-id d-cl-id branch-cnt)
(pprogn
(increment-timer 'prove-time state)
(waterfall-or-hit-msg-b cl-id d-cl-id branch-cnt state)
(increment-timer 'print-time state))))
(mv@par step-limit
'continue
d-new-pspv
nil ; could probably use jppl-flg, but nil is always OK
state)))
(t
; Otherwise, we collect the result into results and continue with the others.
(waterfall0-or-hit@par
ledge cl-id clause hist pspv hints ens wrld ctx state
(cdr uhs-lst) (+ 1 i) branch-cnt
revert-info
(cons (cons d-cl-id d-new-pspv) results)
step-limit)))))))))
(defun waterfall1-lst (n parent-cl-id clauses hist pspv jppl-flg
hints suppress-print ens wrld ctx state step-limit)
; N is either 'settled-down-clause, nil, or an integer. 'Settled-
; down-clause means that we just executed settled-down-clause and so
; should pass the parent's clause id through as though nothing
; happened. Nil means we produced one child and so its clause-id is
; that of the parent with the primes field incremented by 1. An
; integer means we produced n children and they each get a clause-id
; derived by extending the parent's case-lst.
; Keep the main body of waterfall1-lst in sync with waterfall1-lst@par-serial
; and waterfall1-tree@par-parallel.
(cond
((null clauses) (mv step-limit 'continue pspv jppl-flg state))
(t (let ((cl-id
; Keep this binding in sync with the binding of cl-id in waterfall1-lst@par.
(cond
((and (equal parent-cl-id *initial-clause-id*)
(no-op-histp hist))
parent-cl-id)
((eq n 'settled-down-clause) parent-cl-id)
((null n)
(change clause-id parent-cl-id
:primes
(1+ (access clause-id
parent-cl-id
:primes))))
(t (change clause-id parent-cl-id
:case-lst
(append (access clause-id
parent-cl-id
:case-lst)
(list n))
:primes 0)))))
(sl-let
(signal new-pspv new-jppl-flg state)
(waterfall1 *preprocess-clause-ledge*
cl-id
(car clauses)
hist
pspv
hints
suppress-print
ens
wrld
ctx
state
step-limit)
(cond
((eq signal 'error)
(mv step-limit 'error nil nil state))
((eq signal 'abort)
(mv step-limit 'abort new-pspv new-jppl-flg state))
(t
(waterfall1-lst (cond ((eq n 'settled-down-clause) n)
((null n) nil)
(t (1- n)))
parent-cl-id
(cdr clauses)
hist
new-pspv
new-jppl-flg
hints
nil
ens
wrld
ctx
state
step-limit))))))))
#+acl2-par
(defun waterfall1-lst@par-serial (n parent-cl-id clauses hist pspv jppl-flg
hints suppress-print ens wrld ctx state
step-limit)
; Keep the main body of waterfall1-lst in sync with waterfall1-lst@par-serial,
; waterfall1-tree@par-parallel, and waterfall1-tree@par-pseudo-parallel. Keep
; the calculation of cl-id in sync with waterfall1-lst@par.
(cond
((null clauses) (mv@par step-limit 'continue pspv jppl-flg state))
(t (let ((cl-id (cond
((and (equal parent-cl-id *initial-clause-id*)
(no-op-histp hist))
parent-cl-id)
((eq n 'settled-down-clause) parent-cl-id)
((null n)
(change clause-id parent-cl-id
:primes
(1+ (access clause-id
parent-cl-id
:primes))))
(t (change clause-id parent-cl-id
:case-lst
(append (access clause-id
parent-cl-id
:case-lst)
(list n))
:primes 0)))))
(sl-let@par
(signal new-pspv new-jppl-flg state)
(waterfall1-wrapper@par
(waterfall1@par *preprocess-clause-ledge*
cl-id
(car clauses)
hist
pspv
hints
suppress-print
ens
wrld
ctx
state
step-limit))
(cond
((eq signal 'error) (mv@par step-limit 'error nil nil state))
((eq signal 'abort) (mv@par step-limit 'abort new-pspv new-jppl-flg state))
(t
(waterfall1-lst@par (cond ((eq n 'settled-down-clause) n)
((null n) nil)
(t (1- n)))
parent-cl-id
(cdr clauses)
hist
new-pspv
new-jppl-flg
hints
nil
ens
wrld
ctx
state
step-limit))))))))
#+acl2-par
(defun waterfall1-tree@par-pseudo-parallel (n parent-cl-id clauses hist pspv
jppl-flg hints suppress-print ens
wrld ctx state step-limit)
; Keep the main body of waterfall1-lst in sync with waterfall1-lst@par-serial,
; waterfall1-tree@par-parallel, and waterfall1-tree@par-pseudo-parallel. Keep
; the calculation of cl-id in sync with waterfall1-lst@par.
; Since waterfall1-tree@par-pseudo-parallel is just a refactoring of
; waterfall1-tree@par-parallel, I remove many comments from this defintion. So,
; see waterfall1-tree@par-parallel for a more complete set of comments.
(declare (ignorable ens))
(cond
((null clauses) (mv@par step-limit 'continue pspv jppl-flg state))
(t (let ((cl-id (cond
((and (equal parent-cl-id *initial-clause-id*)
(no-op-histp hist))
parent-cl-id)
((eq n 'settled-down-clause) parent-cl-id)
((null n)
(change clause-id parent-cl-id
:primes
(1+ (access clause-id
parent-cl-id
:primes))))
(t (change clause-id parent-cl-id
:case-lst
(append (access clause-id
parent-cl-id
:case-lst)
(list n))
:primes 0)))))
(mv-let
(first-half-clauses second-half-clauses len-first-half)
(halves-with-length clauses)
(mv-let@par
(step-limit1 signal1 pspv1 jppl-flg1 state)
(cond ((assert$ (consp clauses)
(null (cdr clauses))) ; just one clause, call waterfall1
(waterfall1-wrapper@par
(waterfall1@par *preprocess-clause-ledge*
cl-id
(car clauses)
hist
pspv
hints
suppress-print
ens
wrld
ctx
state
step-limit)))
(t
(waterfall1-lst@par (cond ((eq n 'settled-down-clause) n)
((null n) nil)
(t n)) ;(1- n)))
parent-cl-id
first-half-clauses
hist
pspv
jppl-flg
hints
nil
ens
wrld
ctx
state
step-limit)))
(if
; Conditions that must be true for the speculative call to be valid:
(and (not (eq signal1 'error))
(not (eq signal1 'abort))
(speculative-execution-valid pspv pspv1))
(mv-let
; Here, we perform the speculative call of waterfall1-lst@par, which is the
; recursion on the cdr of clauses. As such, this code matches the code at the
; end of waterfall1-lst.
(step-limit2 signal2 pspv2 jppl-flg2)
(waterfall1-lst@par (cond ((eq n 'settled-down-clause) n)
((null n) nil)
(t (- n len-first-half)))
parent-cl-id
second-half-clauses
hist
pspv
jppl-flg
hints
nil
ens
wrld
ctx
state
step-limit)
(cond ((eq signal2 'error)
(mv@par step-limit2 'error nil nil state))
((eq signal2 'abort)
(mv@par step-limit2 'abort pspv2 jppl-flg2
state))
(t
(let ((combined-step-limit (- (- step-limit
(- step-limit step-limit1))
(- step-limit step-limit2)))
(combined-prove-spec-vars
(combine-prove-spec-vars
pspv pspv1 pspv2 ctx
(f-get-global 'debug-pspv state)
signal1 signal2)))
(if (abort-will-occur-in-pool
(access prove-spec-var combined-prove-spec-vars :pool))
(prog2$
(with-output-lock
(cw "Normally we would attempt to prove two or ~
more of the previously printed subgoals by ~
induction. However, we prefer in this ~
instance to focus on the original input ~
conjecture rather than those simplified ~
special cases. We therefore abandon our ~
previous work on these conjectures and ~
reassign the name *1 to the original ~
conjecture."))
(mv@par combined-step-limit
'abort
combined-prove-spec-vars
jppl-flg2
state))
(mv@par combined-step-limit
signal2
combined-prove-spec-vars
jppl-flg2 state))))))
(cond
((eq signal1 'error) (mv@par step-limit1 'error nil nil state))
((eq signal1 'abort) (mv@par step-limit1 'abort pspv1 jppl-flg1
state))
(t ; we need to recompute the recursive call
(prog2$
(cond ((member-eq 'prove
(f-get-global 'inhibit-output-lst state))
nil)
(t (with-output-lock
(cw "Invalid speculation for children of subgoal ~
~x0~%"
(string-for-tilde-@-clause-id-phrase cl-id)))))
(waterfall1-lst@par (cond ((eq n 'settled-down-clause) n)
((null n) nil)
(t (- n len-first-half)))
parent-cl-id
second-half-clauses
hist
pspv1
jppl-flg1
hints
nil
ens
wrld
ctx
state step-limit1)))))))))))
#+acl2-par
(defun waterfall1-tree@par-parallel (n parent-cl-id clauses hist pspv jppl-flg
hints suppress-print ens wrld ctx state
step-limit)
; Keep the main body of waterfall1-lst in sync with waterfall1-lst@par-serial,
; waterfall1-tree@par-parallel, and waterfall1-tree@par-pseudo-parallel. Keep
; the calculation of cl-id in sync with waterfall1-lst@par.
; Once upon a time, we took a "list-based" approach to parallelizing the proofs
; of clauses. We now take a "tree-based" approach.
; Originally waterfall1-tree@par-parallel would "cdr" down the list of clauses
; and spawn a thread for each of those recursive calls. However, that approach
; required too many threads (we attempted to mitigate this problem with
; set-total-parallelism-work-limit, but it was just a bandage on a more glaring
; problem). As of April, 2012, we now take a "tree-based" approach and split
; the list of clauses into halves, and then call waterfall1-lst@par again,
; twice, each with its own half. We eventually call waterfall1-lst@par with a
; clause list of length 1, and then that clause is proven.
; Note that splitting the list like this is a reasonable thing to do -- we do
; not reorder any subgoals, and we increment the variable that keeps track of
; the current subgoal number (n) by the length of the first half of clauses.
(declare (ignorable ens))
(cond
((null clauses) (mv@par step-limit 'continue pspv jppl-flg state))
(t (let ((cl-id (cond
((and (equal parent-cl-id *initial-clause-id*)
(no-op-histp hist))
parent-cl-id)
((eq n 'settled-down-clause) parent-cl-id)
((null n)
(change clause-id parent-cl-id
:primes
(1+ (access clause-id
parent-cl-id
:primes))))
(t (change clause-id parent-cl-id
:case-lst
(append (access clause-id
parent-cl-id
:case-lst)
(list n))
:primes 0)))))
(mv-let
(first-half-clauses second-half-clauses len-first-half)
(halves-with-length clauses)
(spec-mv-let
; Here, we perform the speculative call of waterfall1-lst@par, which is the
; recursion on the cdr of clauses. As such, this code matches the code at the
; end of waterfall1-lst.
; Variable names that end with "1" (as in signal1) store results from proving
; the first half of the clauses (the part of the spec-mv-let that is always
; peformed), and variable names that end with "2" (as in signal2) store results
; from speculatively proving the second half of the clauses.
(step-limit2 signal2 pspv2 jppl-flg2)
(waterfall1-lst@par (cond ((eq n 'settled-down-clause) n)
((null n) nil)
(t (- n len-first-half)))
parent-cl-id
second-half-clauses
hist
pspv
jppl-flg
hints
nil
ens
wrld
ctx
state
step-limit)
(mv-let@par
(step-limit1 signal1 pspv1 jppl-flg1 state)
(cond ((assert$ (consp clauses)
(null (cdr clauses))) ; just one clause, call waterfall1
(waterfall1-wrapper@par
(waterfall1@par *preprocess-clause-ledge*
cl-id
(car clauses)
hist
pspv
hints
suppress-print
ens
wrld
ctx
state
step-limit)))
(t
(waterfall1-lst@par (cond ((eq n 'settled-down-clause) n)
((null n) nil)
(t n))
parent-cl-id
first-half-clauses
hist
pspv
jppl-flg
hints
nil
ens
wrld
ctx
state
step-limit)))
(if
; Conditions that must be true for the speculative call to be valid:
(and (not (eq signal1 'error))
(not (eq signal1 'abort))
(speculative-execution-valid pspv pspv1))
(cond ((eq signal2 'error)
(mv@par step-limit2 'error nil nil state))
((eq signal2 'abort)
; It is okay to just return pspv2, because if there is an abort, any clauses
; pushed for induction into pspv1 would be discarded anyway. See Essay on
; prove-spec-var pool modifications for further discussion.
(mv@par step-limit2 'abort pspv2 jppl-flg2 state))
(t
(let ((combined-step-limit (- (- step-limit
(- step-limit step-limit1))
(- step-limit step-limit2)))
(combined-prove-spec-vars
(combine-prove-spec-vars
pspv pspv1 pspv2 ctx
(f-get-global 'debug-pspv state)
signal1 signal2)))
(if (abort-will-occur-in-pool
(access prove-spec-var combined-prove-spec-vars :pool))
(prog2$
; Parallelism wart: maybe this call to cw should be inside waterfall instead of
; here. The potential problem with printing the message here is that printing
; can still occur after we say that we are "focus[sing] on the original
; conjecture".
; For example, suppose we are Subgoal 3.2.4, and we know we need to abort.
; Subgoal 3.3.4 could still be proving and print a checkpoint, even though this
; call of Subgoal 3.2.4 knows we need to abort. It is not until control
; returns to the waterfall1-lst@par call on Subgoal 3.3 that the 'abort from
; Subgoal 3.2.4 will be seen, and that we will then know that all such calls
; that might print have already returned (because Subgoal 3.3.4 must be
; finished before the call of waterfall1 on Subgoal 3.3 returns).
(with-output-lock
(cw "Normally we would attempt to prove two or ~
more of the previously printed subgoals by ~
induction. However, we prefer in this ~
instance to focus on the original input ~
conjecture rather than those simplified ~
special cases. We therefore abandon our ~
previous work on these conjectures and ~
reassign the name *1 to the original ~
conjecture."))
(mv@par combined-step-limit
'abort
; We do not adjust the pspv's pool here. Instead, we rely upon waterfall to
; correctly convert the 'maybe-to-be-proved-by-induction tag to a
; 'to-be-proved-by-induction and discard the other clauses.
combined-prove-spec-vars
jppl-flg2
state))
(mv@par combined-step-limit
signal2
combined-prove-spec-vars
jppl-flg2 state)))))
(cond
((eq signal1 'error) (mv@par step-limit1 'error nil nil state))
((eq signal1 'abort) (mv@par step-limit1 'abort pspv1
jppl-flg1 state))
(t ; we need to recompute the recursive call
(prog2$
; Parallelism wart: improve message just below (maybe even eliminate it?).
; Also, consider avoiding this direct use of inhibit-output-lst (it seemed that
; io? didn't work because we don't use state, as it requires).
; And finally, deal the same way with all cw printing done on behalf of the
; prover; consider searching for with-output-lock to find those.
; Parallelism wart: due to the definition of speculative-execution-valid, this
; code should no longer be reachable. We leave it for now because it is an
; example use of 'inhibit-output-lst (also see parallelism wart immediately
; above).
(cond ((member-eq 'prove
(f-get-global 'inhibit-output-lst state))
nil)
(t (with-output-lock
(cw "Invalid speculation for children of subgoal ~
~x0~%"
(string-for-tilde-@-clause-id-phrase cl-id)))))
(waterfall1-lst@par (cond ((eq n 'settled-down-clause) n)
((null n) nil)
(t (- n len-first-half)))
parent-cl-id
second-half-clauses
hist
pspv1
jppl-flg1
hints
nil
ens
wrld
ctx
state step-limit1))))))))))))
#+acl2-par
(defun waterfall1-lst@par (n parent-cl-id clauses hist pspv jppl-flg
hints suppress-print ens wrld ctx state step-limit)
; Keep the main body of waterfall1-lst in sync with waterfall1-lst@par-serial
; and waterfall1-tree@par-parallel. Keep the calculation of cl-id in sync with
; waterfall1-lst@par.
(let ((primes-subproof
(cond ((and (equal parent-cl-id *initial-clause-id*)
(no-op-histp hist))
nil)
((eq n 'settled-down-clause) nil)
((null n) t)
(t nil)))
(cl-id
; Keep this binding in sync with the binding of cl-id in waterfall1-lst.
(cond
((and (equal parent-cl-id *initial-clause-id*)
(no-op-histp hist))
parent-cl-id)
((eq n 'settled-down-clause) parent-cl-id)
((null n)
(change clause-id parent-cl-id
:primes
(1+ (access clause-id
parent-cl-id
:primes))))
(t (change clause-id parent-cl-id
:case-lst
(append (access clause-id
parent-cl-id
:case-lst)
(list n))
:primes 0)))))
(declare (ignorable primes-subproof cl-id))
(let ((call-type
(cond
(primes-subproof
'serial)
(t
(case (f-get-global 'waterfall-parallelism state)
((nil)
'serial)
((:full)
(cond #-acl2-loop-only
((not-too-many-futures-already-in-existence)
'parallel)
(t 'serial)))
((:pseudo-parallel)
'pseudo-parallel)
((:top-level)
(cond ((equal parent-cl-id '((0) NIL . 0))
'parallel)
(t 'serial)))
((:resource-and-timing-based)
; Here, and in the :resource-based branch below, we have an unusual functional
; discrepancy between code in the #+acl2-loop-only and #-acl2-loop-only cases.
; But the alternative we have considered would involve some complicated use of
; the acl2-oracle, which seems unjustified for this #+acl2-par code.
(cond #-acl2-loop-only
((and
; We could test to see whether doing the lookup or testing for resource
; availability is faster. It probably doesn't matter since they're both
; supposed to be "lock free." Since we control the lock-freeness for the
; resource availability test in the definition of futures-resources-available
; (as opposed to relying upon the underlying CCL implementation), we call that
; first.
(futures-resources-available)
(> (or (lookup-waterfall-timings-for-cl-id cl-id) 0)
(f-get-global 'waterfall-parallelism-timing-threshold
state)))
(increment-waterfall-parallelism-counter
'resource-and-timing-parallel))
(t
(increment-waterfall-parallelism-counter
'resource-and-timing-serial))))
((:resource-based)
; See comment above about discrepancy between #+acl2-loop-only and
; #-acl2-loop-only code.
(cond #-acl2-loop-only
((futures-resources-available)
(increment-waterfall-parallelism-counter
'resource-parallel))
(t (increment-waterfall-parallelism-counter
'resource-serial))))
(otherwise
(er hard 'waterfall1-lst@par
"Waterfall-parallelism type is not what it's supposed to ~
be. Please contact the ACL2 authors.")))))))
(case call-type
; There are three modes of execution available to the waterfall in ACL2(p). We
; describe each mode inline, below.
((serial)
; The serial mode cdrs down the list of clauses, just like waterfall1-lst.
(waterfall1-lst@par-serial n parent-cl-id clauses hist pspv jppl-flg
hints suppress-print ens wrld ctx state
step-limit))
((parallel)
; The parallel mode will call waterfall1-lst@par on the first half of clauses
; in the current thread and call waterfall1-lst@par on the second half of
; clauses in another thread. Once upon a time, we took a "list-based" approach
; to proving the list of clauses -- where we would prove the (car clauses) in
; the current thread and call (waterfall1-lst@par (cdr clauses)) in another
; thread. We now take a "tree-based" approach, hence the difference in name
; ("tree" vs. "lst").
(waterfall1-tree@par-parallel n parent-cl-id clauses hist pspv
jppl-flg hints suppress-print ens
wrld ctx state step-limit))
((pseudo-parallel)
; The psuedo-parallel mode is just like parallel mode, except both calls occur
; in the current thread.
(waterfall1-tree@par-pseudo-parallel n parent-cl-id clauses hist pspv
jppl-flg hints suppress-print ens
wrld ctx state step-limit))
(otherwise
(prog2$ (er hard 'waterfall1-lst@par
"Implementation error in waterfall1-lst@par. Please ~
contact the ACL2 authors.")
(mv@par nil nil nil nil state)))))))
)
; And here is the waterfall:
(defun waterfall (forcing-round pool-lst x pspv hints ens wrld ctx state
step-limit)
; Here x is a list of clauses, except that when we are beginning a forcing
; round other than the first, x is really a list of pairs (assumnotes .
; clause).
; Pool-lst is the pool-lst of the clauses and will be used as the first field
; in the clause-id's we generate for them. We return the five values: a new
; step-limit, an error flag, the final value of pspv, the jppl-flg, and the
; final state.
(let ((parent-clause-id
(cond ((and (= forcing-round 0)
(null pool-lst))
; Note: This cond is not necessary. We could just do the make clause-id
; below. We recognize this case just to avoid the consing.
*initial-clause-id*)
(t (make clause-id
:forcing-round forcing-round
:pool-lst pool-lst
:case-lst nil
:primes 0))))
(clauses
(cond ((and (not (= forcing-round 0))
(null pool-lst))
(strip-cdrs x))
(t x)))
(pspv (maybe-set-rw-cache-state-disabled (erase-rw-cache-from-pspv
pspv))))
(pprogn
(cond ((output-ignored-p 'proof-tree state)
state)
(t (initialize-proof-tree parent-clause-id x ctx state)))
(sl-let (signal new-pspv new-jppl-flg state)
#+acl2-par
(if (f-get-global 'waterfall-parallelism state)
(with-ensured-parallelism-finishing
(with-parallelism-hazard-warnings
(mv-let (step-limit signal new-pspv new-jppl-flg)
(waterfall1-lst@par (cond ((null clauses) 0)
((null (cdr clauses))
'settled-down-clause)
(t (length clauses)))
parent-clause-id
clauses nil
pspv nil hints
(and (eql forcing-round 0)
(null pool-lst)) ; suppress-print
ens wrld ctx state step-limit)
(mv step-limit
signal
(convert-maybes-to-tobes-in-pspv new-pspv)
new-jppl-flg
state))))
(sl-let (signal new-pspv new-jppl-flg state)
(waterfall1-lst (cond ((null clauses) 0)
((null (cdr clauses))
'settled-down-clause)
(t (length clauses)))
parent-clause-id
clauses nil
pspv nil hints
(and (eql forcing-round 0)
(null pool-lst)) ; suppress-print
ens wrld ctx state step-limit)
(mv step-limit signal new-pspv new-jppl-flg state)))
#-acl2-par
(waterfall1-lst (cond ((null clauses) 0)
((null (cdr clauses))
'settled-down-clause)
(t (length clauses)))
parent-clause-id
clauses nil
pspv nil hints
(and (eql forcing-round 0)
(null pool-lst)) ; suppress-print
ens wrld ctx state step-limit)
(cond ((eq signal 'error)
; If the waterfall signalled an error then it printed the message and we
; just pass the error up.
(mv step-limit t nil nil state))
(t
; Otherwise, the signal is either 'abort or 'continue. But 'abort here
; was meant as an internal signal only, used to get out of the recursion
; in waterfall1. We now simply fold those two signals together into the
; non-erroneous return of the new-pspv and final flg.
(mv step-limit nil new-pspv new-jppl-flg state)))))))
; After the waterfall has finished we have a pool of goals. We
; now develop the functions to extract a goal from the pool for
; induction. It is in this process that we check for subsumption
; among the goals in the pool.
(defun some-pool-member-subsumes (pool clause-set)
; We attempt to determine if there is a clause set in the pool that subsumes
; every member of the given clause-set. If we make that determination, we
; return the tail of pool that begins with that member. Otherwise, no such
; subsumption was found, perhaps because of the limitation in our subsumption
; check (see subsumes), and we return nil.
(cond ((null pool) nil)
((eq (clause-set-subsumes *init-subsumes-count*
(access pool-element (car pool) :clause-set)
clause-set)
t)
pool)
(t (some-pool-member-subsumes (cdr pool) clause-set))))
(defun add-to-pop-history
(action cl-set pool-lst subsumer-pool-lst pop-history)
; Extracting a clause-set from the pool is called "popping". It is
; complicated by the fact that we do subsumption checking and other
; things. To report what happened when we popped, we maintain a "pop-history"
; which is used by the pop-clause-msg fn below. This function maintains
; pop-histories.
; A pop-history is a list that records the sequence of events that
; occurred when we popped a clause set from the pool. The pop-history
; is used only by the output routine pop-clause-msg.
; The pop-history is built from nil by repeated calls of this
; function. Thus, this function completely specifies the format. The
; elements in a pop-history are each of one of the following forms.
; All the "lst"s below are pool-lsts.
; (pop lst1 ... lstk) finished the proofs of the lstd goals
; (consider cl-set lst) induct on cl-set
; (subsumed-by-parent cl-set lst subsumer-lst)
; cl-set is subsumed by lstd parent
; (subsumed-below cl-set lst subsumer-lst)
; cl-set is subsumed by lstd peer
; (qed) pool is empty -- but there might be
; assumptions or :byes yet to deal with.
; and has the property that no two pop entries are adjacent. When
; this function is called with an action that does not require all of
; the arguments, nils may be provided.
; The entries are in reverse chronological order and the lsts in each
; pop entry are in reverse chronological order.
(cond ((eq action 'pop)
(cond ((and pop-history
(eq (caar pop-history) 'pop))
(cons (cons 'pop (cons pool-lst (cdar pop-history)))
(cdr pop-history)))
(t (cons (list 'pop pool-lst) pop-history))))
((eq action 'consider)
(cons (list 'consider cl-set pool-lst) pop-history))
((eq action 'qed)
(cons '(qed) pop-history))
(t (cons (list action cl-set pool-lst subsumer-pool-lst)
pop-history))))
(defun pop-clause1 (pool pop-history)
; We scan down pool looking for the next 'to-be-proved-by-induction
; clause-set. We mark it 'being-proved-by-induction and return six
; things: one of the signals 'continue, 'win, or 'lose, the pool-lst
; for the popped clause-set, the clause-set, its hint-settings, a
; pop-history explaining what we did, and a new pool.
(cond ((null pool)
; It looks like we won this one! But don't be fooled. There may be
; 'assumptions or :byes in the ttree associated with this proof and
; that will cause the proof to fail. But for now we continue to just
; act happy. This is called denial.
(mv 'win nil nil nil
(add-to-pop-history 'qed nil nil nil pop-history)
nil))
((eq (access pool-element (car pool) :tag) 'being-proved-by-induction)
(pop-clause1 (cdr pool)
(add-to-pop-history 'pop
nil
(pool-lst (cdr pool))
nil
pop-history)))
((equal (access pool-element (car pool) :clause-set)
'(nil))
; The empty set was put into the pool! We lose. We report the empty name
; and clause set, and an empty pop-history (so no output occurs). We leave
; the pool as is. So we'll go right out of pop-clause and up to the prover
; with the 'lose signal.
(mv 'lose nil nil nil nil pool))
(t
(let ((pool-lst (pool-lst (cdr pool)))
(sub-pool
(some-pool-member-subsumes (cdr pool)
(access pool-element (car pool)
:clause-set))))
(cond
((null sub-pool)
(mv 'continue
pool-lst
(access pool-element (car pool) :clause-set)
(access pool-element (car pool) :hint-settings)
(add-to-pop-history 'consider
(access pool-element (car pool)
:clause-set)
pool-lst
nil
pop-history)
(cons (change pool-element (car pool)
:tag 'being-proved-by-induction)
(cdr pool))))
((eq (access pool-element (car sub-pool) :tag)
'being-proved-by-induction)
(mv 'lose nil nil nil
(add-to-pop-history 'subsumed-by-parent
(access pool-element (car pool)
:clause-set)
pool-lst
(pool-lst (cdr sub-pool))
pop-history)
pool))
(t
(pop-clause1 (cdr pool)
(add-to-pop-history 'subsumed-below
(access pool-element (car pool)
:clause-set)
pool-lst
(pool-lst (cdr sub-pool))
pop-history))))))))
; Here we develop the functions for reporting on a pop.
(defun make-defthm-forms-for-byes (byes wrld)
; Each element of byes is of the form (name . clause) and we create
; a list of the corresponding defthm events.
(cond ((null byes) nil)
(t (cons (list 'defthm (caar byes)
(prettyify-clause (cdar byes) nil wrld)
:rule-classes nil)
(make-defthm-forms-for-byes (cdr byes) wrld)))))
(defun pop-clause-msg1 (forcing-round lst jppl-flg prev-action gag-state msg-p
state)
; Lst is a reversed pop-history. Since pop-histories are in reverse
; chronological order, lst is in chronological order. We scan down
; lst, printing out an explanation of each action. Prev-action is the
; most recently explained action in this scan, or else nil if we are
; just beginning. Jppl-flg, if non-nil, means that the last executed
; waterfall process was 'push-clause; the pool-lst of the clause pushed is
; in the value of jppl-flg.
(cond
((null lst)
(pprogn (increment-timer 'print-time state)
(mv gag-state state)))
(t
(let ((entry (car lst)))
(mv-let
(gag-state state)
(case-match
entry
(('pop . pool-lsts)
(mv-let
(gagst msgs)
(pop-clause-update-gag-state-pop pool-lsts gag-state nil msg-p
state)
(pprogn
(io? prove nil state
(prev-action pool-lsts forcing-round msgs)
(pprogn
(fms
(cond ((gag-mode)
(assert$ pool-lsts
"~*1 ~#0~[is~/are~] COMPLETED!~|"))
((null prev-action)
"That completes the proof~#0~[~/s~] of ~*1.~|")
(t "That, in turn, completes the proof~#0~[~/s~] of ~
~*1.~|"))
(list (cons #\0 pool-lsts)
(cons #\1
(list "" "~@*" "~@* and " "~@*, "
(tilde-@-pool-name-phrase-lst
forcing-round
(reverse pool-lsts)))))
(proofs-co state) state nil)
(cond
((and msgs (gag-mode))
(mv-let
(col state)
(fmt1 "Thus key checkpoint~#1~[~ ~*0 is~/s ~*0 are~] ~
COMPLETED!~|"
(list (cons #\0
(list "" "~@*" "~@* and " "~@*, "
(reverse msgs)))
(cons #\1 msgs))
0 (proofs-co state) state nil)
(declare (ignore col))
state))
(t state))))
(mv gagst state))))
(('qed)
; We used to print Q.E.D. here, but that is premature now that we know
; there might be assumptions or :byes in the pspv. We let
; process-assumptions announce the definitive completion of the proof.
(mv gag-state state))
(&
; Entry is either a 'consider or one of the two 'subsumed... actions. For all
; three we print out the clause we are working on. Then we print out the
; action specific stuff.
(let ((pool-lst (caddr entry)))
(mv-let
(gagst cl-id)
(cond ((eq (car entry) 'consider)
(mv gag-state nil))
(t (remove-pool-lst-from-gag-state pool-lst gag-state
state)))
(pprogn
(io? prove nil state
(prev-action forcing-round pool-lst entry cl-id jppl-flg
gag-state)
(let* ((cl-set (cadr entry))
(jppl-flg (if (gag-mode)
(gag-mode-jppl-flg gag-state)
jppl-flg))
(push-pop-flg
(and jppl-flg
(equal jppl-flg pool-lst))))
; The push-pop-flg is set if the clause just popped is the same as the one we
; just pushed. It and its name have just been printed. There's no need to
; identify it here unless we are in gag-mode and we are in a sub-induction,
; since in that case we never printed the formula. (We could take the attitude
; that the user doesn't deserve to see any sub-induction formulas in gag-mode;
; but we expect there to be very few of these anyhow, since probably they'll
; generally fail.)
(pprogn
(cond
(push-pop-flg state)
(t (fms (cond
((eq prev-action 'pop)
"We therefore turn our attention to ~@1, ~
which is~|~%~q0.~|")
((null prev-action)
"So we now return to ~@1, which is~|~%~q0.~|")
(t
"We next consider ~@1, which is~|~%~q0.~|"))
(list (cons #\0 (prettyify-clause-set
cl-set
(let*-abstractionp state)
(w state)))
(cons #\1 (tilde-@-pool-name-phrase
forcing-round pool-lst)))
(proofs-co state)
state
(term-evisc-tuple nil state))))
(case-match
entry
(('subsumed-below & & subsumer-pool-lst)
(pprogn
(fms "But the formula above is subsumed by ~@1, ~
which we'll try to prove later. We therefore ~
regard ~@0 as proved (pending the proof of ~
the more general ~@1).~|"
(list
(cons #\0
(tilde-@-pool-name-phrase
forcing-round pool-lst))
(cons #\1
(tilde-@-pool-name-phrase
forcing-round subsumer-pool-lst)))
(proofs-co state)
state nil)
(cond
((and cl-id (gag-mode))
(fms "~@0 COMPLETED!~|"
(list (cons #\0 (tilde-@-clause-id-phrase
cl-id)))
(proofs-co state) state nil))
(t state))))
(('subsumed-by-parent & & subsumer-pool-lst)
(fms "The formula above is subsumed by one of its ~
parents, ~@0, which we're in the process of ~
trying to prove by induction. When an ~
inductive proof pushes a subgoal for induction ~
that is less general than the original goal, ~
it may be a sign that either an inappropriate ~
induction was chosen or that the original goal ~
is insufficiently general. In any case, our ~
proof attempt has failed.~|"
(list
(cons #\0
(tilde-@-pool-name-phrase
forcing-round subsumer-pool-lst)))
(proofs-co state)
state nil))
(& ; (consider cl-set pool-lst)
state)))))
(mv gagst state))))))
(pop-clause-msg1 forcing-round (cdr lst) jppl-flg (caar lst) gag-state
msg-p state))))))
(defun pop-clause-msg (forcing-round pop-history jppl-flg pspv state)
; We print the messages explaining the pops we did.
; This function increments timers. Upon entry, the accumulated time is
; charged to 'prove-time. The time spent in this function is charged
; to 'print-time.
(pprogn
(increment-timer 'prove-time state)
(mv-let
(gag-state state)
(let ((gag-state0 (access prove-spec-var pspv :gag-state)))
(pop-clause-msg1 forcing-round
(reverse pop-history)
jppl-flg
nil
gag-state0
(not (output-ignored-p 'prove state))
state))
(pprogn (record-gag-state gag-state state)
(increment-timer 'print-time state)
(mv (change prove-spec-var pspv :gag-state gag-state)
state)))))
(defun subsumed-clause-ids-from-pop-history (forcing-round pop-history)
(cond
((endp pop-history)
nil)
((eq (car (car pop-history)) 'subsumed-below)
(cons (make clause-id
:forcing-round forcing-round
:pool-lst (caddr (car pop-history)) ; see add-to-pop-history
:case-lst nil
:primes 0)
(subsumed-clause-ids-from-pop-history forcing-round
(cdr pop-history))))
(t (subsumed-clause-ids-from-pop-history forcing-round (cdr pop-history)))))
(defun increment-proof-tree-pop-clause (forcing-round pop-history state)
(let ((old-proof-tree (f-get-global 'proof-tree state))
(dead-clause-ids
(subsumed-clause-ids-from-pop-history forcing-round pop-history)))
(if dead-clause-ids
(pprogn (f-put-global 'proof-tree
(prune-proof-tree forcing-round
dead-clause-ids
old-proof-tree)
state)
(print-proof-tree state))
state)))
(defun pop-clause (forcing-round pspv jppl-flg state)
; We pop the first available clause from the pool in pspv. We print
; out an explanation of what we do. If jppl-flg is non-nil
; then it means the last executed waterfall processor was 'push-clause
; and the pool-lst of the clause pushed is the value of jppl-flg.
; We return 7 results. The first is a signal: 'win, 'lose, or
; 'continue and indicates that we have finished successfully (modulo,
; perhaps, some assumptions and :byes in the tag-tree), arrived at a
; definite failure, or should continue. If the first result is
; 'continue, the second, third and fourth are the pool name phrase,
; the set of clauses to induct upon, and the hint-settings, if any.
; The remaining results are the new values of pspv and state.
(mv-let (signal pool-lst cl-set hint-settings pop-history new-pool)
(pop-clause1 (access prove-spec-var pspv :pool)
nil)
(mv-let
(new-pspv state)
(pop-clause-msg forcing-round pop-history jppl-flg pspv state)
(pprogn
(io? proof-tree nil state
(forcing-round pop-history)
(pprogn
(increment-timer 'prove-time state)
(increment-proof-tree-pop-clause forcing-round pop-history
state)
(increment-timer 'proof-tree-time state)))
(mv signal
pool-lst
cl-set
hint-settings
(change prove-spec-var new-pspv :pool new-pool)
state)))))
(defun tilde-@-assumnotes-phrase-lst (lst wrld)
; Warning :If you change this function, consider also changing
; tilde-@-assumnotes-phrase-lst-gag-mode.
; WARNING: Note that the phrase is encoded twelve times below, to put
; in the appropriate noise words and punctuation!
; Note: As of this writing it is believed that the only time the :rune of an
; assumnote is a fake rune, as in cases 1, 5, and 9 below, is when the
; assumnote is in the impossible assumption. However, we haven't coded this
; specially because such an assumption will be brought immediately to our
; attention in the forcing round by its *nil* :term.
(cond
((null lst) nil)
(t (cons
(cons
(cond ((null (cdr lst))
(cond ((and (consp (access assumnote (car lst) :rune))
(null (base-symbol (access assumnote (car lst) :rune))))
" ~@0~% by primitive type reasoning about~% ~q2.~|")
((eq (access assumnote (car lst) :rune) 'equal)
" ~@0~% by the linearization of~% ~q2.~|")
((symbolp (access assumnote (car lst) :rune))
" ~@0~% by assuming the guard for ~x1 in~% ~q2.~|")
(t " ~@0~% by applying ~x1 to~% ~q2.~|")))
((null (cddr lst))
(cond ((and (consp (access assumnote (car lst) :rune))
(null (base-symbol (access assumnote (car lst) :rune))))
" ~@0~% by primitive type reasoning about~% ~q2,~| and~|")
((eq (access assumnote (car lst) :rune) 'equal)
" ~@0~% by the linearization of~% ~q2,~| and~|")
((symbolp (access assumnote (car lst) :rune))
" ~@0~% by assuming the guard for ~x1 in~% ~q2,~| and~|")
(t " ~@0~% by applying ~x1 to~% ~q2,~| and~|")))
(t
(cond ((and (consp (access assumnote (car lst) :rune))
(null (base-symbol (access assumnote (car lst) :rune))))
" ~@0~% by primitive type reasoning about~% ~q2,~|")
((eq (access assumnote (car lst) :rune) 'equal)
" ~@0~% by the linearization of~% ~q2,~|")
((symbolp (access assumnote (car lst) :rune))
" ~@0~% by assuming the guard for ~x1 in~% ~q2,~|")
(t " ~@0~% by applying ~x1 to~% ~q2,~|"))))
(list
(cons #\0 (tilde-@-clause-id-phrase
(access assumnote (car lst) :cl-id)))
(cons #\1 (access assumnote (car lst) :rune))
(cons #\2 (untranslate (access assumnote (car lst) :target) nil wrld))))
(tilde-@-assumnotes-phrase-lst (cdr lst) wrld)))))
(defun tilde-*-assumnotes-column-phrase (assumnotes wrld)
; We create a tilde-* phrase that will print a column of assumnotes.
(list "" "~@*" "~@*" "~@*"
(tilde-@-assumnotes-phrase-lst assumnotes wrld)))
(defun tilde-@-assumnotes-phrase-lst-gag-mode (lst acc)
; Warning: If you change this function, consider also changing
; tilde-@-assumnotes-phrase-lst. See also that function definition.
(cond
((null lst)
(cond ((null acc) acc)
((null (cdr acc))
(list (msg "in~@0.~|" (car acc))))
(t (reverse (list* (msg "in~@0.~|" (car acc))
(msg "in~@0, and " (cadr acc))
(pairlis-x1 "in~@0, ~|"
(pairlis$ (pairlis-x1 #\0 (cddr acc))
nil)))))))
(t (tilde-@-assumnotes-phrase-lst-gag-mode
(cdr lst)
(let* ((cl-id-phrase
(tilde-@-clause-id-phrase
(access assumnote (car lst) :cl-id)))
(x
(cond ((and (consp (access assumnote (car lst) :rune))
(null (base-symbol (access assumnote (car lst)
:rune))))
(list " ~@0 by primitive type reasoning"
(cons #\0 cl-id-phrase)))
((eq (access assumnote (car lst) :rune) 'equal)
(list " ~@0 by linearization"
(cons #\0 cl-id-phrase)))
((symbolp (access assumnote (car lst) :rune))
(list " ~@0 by assuming the guard for ~x1"
(cons #\0 cl-id-phrase)
(cons #\1 (access assumnote (car lst) :rune))))
(t
(list " ~@0 by applying ~x1"
(cons #\0 cl-id-phrase)
(cons #\1 (access assumnote (car lst)
:rune)))))))
(add-to-set-equal x acc))))))
(defun tilde-*-assumnotes-column-phrase-gag-mode (assumnotes)
; We create a tilde-* phrase that will print a column of assumnotes.
(list "" "~@*" "~@*" "~@*"
(tilde-@-assumnotes-phrase-lst-gag-mode assumnotes nil)))
(defun process-assumptions-msg1 (forcing-round n pairs state)
; N is either nil (meaning the length of pairs is 1) or n is the length of
; pairs.
(cond
((null pairs) state)
(t (pprogn
(let ((cl-id-phrase
(tilde-@-clause-id-phrase
(make clause-id
:forcing-round (1+ forcing-round)
:pool-lst nil
:case-lst (if n (list n) nil)
:primes 0))))
(cond
((gag-mode)
(fms "~@0 was forced ~*1"
(list (cons #\0 cl-id-phrase)
(cons #\1 (tilde-*-assumnotes-column-phrase-gag-mode
(car (car pairs)))))
(proofs-co state) state
(term-evisc-tuple nil state)))
(t
(fms "~@0, below, will focus on~%~q1,~|which was forced in~%~*2"
(list (cons #\0 cl-id-phrase)
(cons #\1 (untranslate (car (last (cdr (car pairs))))
t (w state)))
(cons #\2 (tilde-*-assumnotes-column-phrase
(car (car pairs))
(w state))))
(proofs-co state) state
(term-evisc-tuple nil state)))))
(process-assumptions-msg1 forcing-round
(if n (1- n) nil)
(cdr pairs) state)))))
(defun process-assumptions-msg (forcing-round n0 n pairs state)
; This function is called when we have completed the given forcing-round and
; are about to begin the next one. Forcing-round is an integer, r. Pairs is a
; list of n pairs, each of the form (assumnotes . clause). It was generated by
; cleaning up n0 assumptions. We are about to pour all n clauses into the
; waterfall, where they will be given clause-ids of the form [r+1]Subgoal i,
; for i from 1 to n, or, if there is only one clause, [r+1]Goal.
; The list of assumnotes associated with each clause explain the need for the
; assumption. Each assumnote is a record of that class, containing the cl-id
; of the clause we were working on when we generated the assumption, the rune
; (a symbol as per force-assumption) generating the assumption, and the target
; term to which the rule was being applied. We print a table explaining the
; derivation of the new goals from the old ones and then announce the beginning
; of the next round.
(io? prove nil state
(n0 forcing-round n pairs)
(pprogn
(fms
"Modulo~#g~[ the following~/ one~/~]~#0~[~/ ~n1~]~#2~[~/ newly~] ~
forced goal~#0~[~/s~], that completes ~#2~[the proof of the input ~
Goal~/Forcing Round ~x3~].~#4~[~/ For what it is worth, the~#0~[~/ ~
~n1~] new goal~#0~[ was~/s were~] generated by cleaning up ~n5 ~
forced hypotheses.~] See :DOC forcing-round.~%"
(list (cons #\g (if (gag-mode) (if (cdr pairs) 2 1) 0))
(cons #\0 (if (cdr pairs) 1 0))
(cons #\1 n)
(cons #\2 (if (= forcing-round 0) 0 1))
(cons #\3 forcing-round)
(cons #\4 (if (= n0 n) 0 1))
(cons #\5 n0)
(cons #\6 (1+ forcing-round)))
(proofs-co state)
state
nil)
(process-assumptions-msg1 forcing-round
(if (= n 1) nil n)
pairs
state)
(fms "We now undertake Forcing Round ~x0.~%"
(list (cons #\0 (1+ forcing-round)))
(proofs-co state)
state
nil))))
(defun count-assumptions (ttree)
; The soundness of the system depends on this function returning 0 only if
; there are no assumptions.
(length (tagged-objects 'assumption ttree)))
(defun add-type-alist-runes-to-ttree1 (type-alist runes)
(cond ((endp type-alist)
runes)
(t (add-type-alist-runes-to-ttree1
(cdr type-alist)
(all-runes-in-ttree (cddr (car type-alist))
runes)))))
(defun add-type-alist-runes-to-ttree (type-alist ttree)
(let* ((runes0 (tagged-objects 'lemma ttree))
(runes1 (add-type-alist-runes-to-ttree1 type-alist runes0)))
(cond ((null runes1) ttree)
((null runes0) (extend-tag-tree 'lemma runes1 ttree))
(t (extend-tag-tree 'lemma
runes1
(remove-tag-from-tag-tree! 'lemma ttree))))))
(defun process-assumptions-ttree (assns ttree)
; Assns is a list of assumptions records. We extend ttree with all runes in
; assns.
(cond ((endp assns) ttree)
(t (process-assumptions-ttree
(cdr assns)
(add-type-alist-runes-to-ttree (access assumption (car assns)
:type-alist)
ttree)))))
(defun process-assumptions (forcing-round pspv wrld state)
; This function is called when prove-loop1 appears to have won the
; indicated forcing-round, producing pspv. We inspect the :tag-tree
; in pspv and determines whether there are forced 'assumptions in it.
; If so, the "win" reported is actually conditional upon the
; successful relieving of those assumptions. We create an appropriate
; set of clauses to prove, new-clauses, each paired with a list of
; assumnotes. We also return a modified pspv, new-pspv,
; just like pspv except with the assumptions stripped out of its
; :tag-tree. We do the output related to explaining all this to the
; user and return (mv new-clauses new-pspv state). If new-clauses is
; nil, then the proof is really done. Otherwise, we are obliged to
; prove new-clauses under new-pspv and should do so in another "round"
; of forcing.
(let ((n (count-assumptions (access prove-spec-var pspv :tag-tree))))
(pprogn
(cond
((= n 0)
(pprogn
; We normally print "Q.E.D." for a successful proof done in gag-mode even if
; proof output is inhibited. However, if summary output is also inhibited,
; then we guess that the user probably would prefer not to be bothered seeing
; the "Q.E.D.".
(if (and (saved-output-token-p 'prove state)
(member-eq 'prove (f-get-global 'inhibit-output-lst state))
(not (member-eq 'summary (f-get-global 'inhibit-output-lst
state))))
(fms "Q.E.D.~%" nil (proofs-co state) state nil)
state)
(io? prove nil state nil
(fms "Q.E.D.~%" nil (proofs-co state) state nil))))
(t
(io? prove nil state (n)
(fms "q.e.d. (given ~n0 forced ~#1~[hypothesis~/hypotheses~])~%"
(list (cons #\0 n)
(cons #\1 (if (= n 1) 0 1)))
(proofs-co state) state nil))))
(mv-let
(n0 assns pairs ttree1)
(extract-and-clausify-assumptions
nil ;;; irrelevant with only-immediatep = nil
(access prove-spec-var pspv :tag-tree)
nil ;;; all assumptions, not only-immediatep
; Note: We here obtain the enabled structure. Because the rewrite-constant of
; the pspv is restored after being smashed by hints, we know that this enabled
; structure is in fact the one in the pspv on which prove was called, which is
; the global enabled structure if prove was called by defthm.
(access rewrite-constant
(access prove-spec-var pspv
:rewrite-constant)
:current-enabled-structure)
wrld
(access rewrite-constant
(access prove-spec-var pspv
:rewrite-constant)
:splitter-output))
(cond
((= n0 0)
(mv nil pspv state))
(t
(pprogn
(process-assumptions-msg
forcing-round n0 (length assns) pairs state)
(mv pairs
(change prove-spec-var pspv
:tag-tree (process-assumptions-ttree assns ttree1)
; Note: In an earlier version of this code, we failed to set :otf-flg here and
; that caused us to backup and try to prove the original thm (i.e., "Goal") by
; induction.
:otf-flg t)
state))))))))
(defun do-not-induct-msg (forcing-round pool-lst state)
; We print a message explaining that because of :do-not-induct, we quit.
; This function increments timers. Upon entry, the accumulated time is
; charged to 'prove-time. The time spent in this function is charged
; to 'print-time.
(io? prove nil state
(forcing-round pool-lst)
(pprogn
(increment-timer 'prove-time state)
; It is probably a good idea to keep the following wording in sync with
; push-clause-msg1.
(fms "Normally we would attempt to prove ~@0 by induction. However, a ~
:DO-NOT-INDUCT hint was supplied to abort the proof attempt.~|"
(list (cons #\0
(tilde-@-pool-name-phrase
forcing-round
pool-lst)))
(proofs-co state)
state
nil)
(increment-timer 'print-time state))))
(defun prove-loop2 (forcing-round pool-lst clauses pspv hints ens wrld ctx
state step-limit)
; We are given some clauses to prove. Forcing-round and pool-lst are the first
; two fields of the clause-ids for the clauses. The pool of the prove spec
; var, pspv, in general contains some more clauses to work on, as well as some
; clauses tagged 'being-proved-by-induction. In addition, the pspv contains
; the proper settings for the induction-hyp-terms and induction-concl-terms.
; Actually, when we are beginning a forcing round other than the first, clauses
; is really a list of pairs (assumnotes . clause).
; We pour all the clauses over the waterfall. They tumble into the pool in
; pspv. If the pool is then empty, we are done. Otherwise, we pick one to
; induct on, do the induction and repeat.
; We return a tuple (mv new-step-limit error value state). Either we cause an
; error (i.e., return a non-nil error as the second result), or else the value
; result is the final tag-tree. That tag-tree might contain some byes,
; indicating that the proof has failed.
; WARNING: A non-erroneous return is not equivalent to success!
(sl-let (erp pspv jppl-flg state)
(pstk
(waterfall forcing-round pool-lst clauses pspv hints ens wrld
ctx state step-limit))
(cond
(erp (mv step-limit t nil state))
(t
(mv-let
(signal pool-lst clauses hint-settings pspv state)
(pstk
(pop-clause forcing-round pspv jppl-flg state))
(cond
((eq signal 'win)
(mv-let
(pairs new-pspv state)
(pstk
(process-assumptions forcing-round pspv wrld state))
(mv-let
(erp ttree state)
(accumulate-ttree-and-step-limit-into-state
(access prove-spec-var new-pspv :tag-tree)
step-limit
state)
(assert$
(null erp)
(cond ((null pairs)
(mv step-limit nil ttree state))
(t (prove-loop2 (1+ forcing-round)
nil
pairs
(initialize-pspv-for-gag-mode new-pspv)
hints ens wrld ctx state
step-limit)))))))
; The following case can probably be removed. It is probably left over from
; some earlier implementation of pop-clause. The earlier code for the case
; below returned (value (access prove-spec-var pspv :tag-tree)), this case, and
; was replaced by the hard error on 5/5/00.
((eq signal 'bye)
(mv
step-limit
t
(er hard ctx
"Surprising case in prove-loop2; please contact the ACL2 ~
implementors!")
state))
((eq signal 'lose)
(mv step-limit t nil state))
((and (cdr (assoc-eq :do-not-induct hint-settings))
(not (assoc-eq :induct hint-settings)))
; There is at least one goal left to prove, yet :do-not-induct is currently in
; force. How can that be? The user may have supplied :do-not-induct t while
; also supplying :otf-flg t. In that case, push-clause will return a "hit". We
; believe that the hint-settings current at this time will reflect the
; appropriate action if :do-not-induct t is intended here, i.e., the test above
; will put us in this case and we will abort the proof.
(pprogn (do-not-induct-msg forcing-round pool-lst state)
(mv step-limit t nil state)))
(t
(mv-let
(signal clauses pspv state)
(pstk
(induct forcing-round pool-lst clauses hint-settings pspv wrld
ctx state))
; We do not call maybe-warn-about-theory-from-rcnsts below, because we already
; made such a call before the goal was pushed for proof by induction.
(cond ((eq signal 'lose)
(mv step-limit t nil state))
(t (prove-loop2 forcing-round
pool-lst
clauses
pspv
hints
ens
wrld
ctx
state
step-limit)))))))))))
(defun prove-loop1 (forcing-round pool-lst clauses pspv hints ens wrld ctx
state)
(sl-let
(erp val state)
(catch-step-limit
(prove-loop2 forcing-round pool-lst clauses pspv hints ens wrld ctx
state
(initial-step-limit wrld state)))
(pprogn (f-put-global 'last-step-limit step-limit state)
(mv erp val state))))
(defun print-summary-on-error (state)
; This function is called only when a proof attempt causes an error rather than
; merely returning (mv non-nil val state); see prove-loop0. We formerly called
; this function pstack-and-gag-state, but now we also print the runes, and
; perhaps we will print additional information in the future.
; An alternative approach, which might avoid the need for this function, is
; represented by the handling of *acl2-time-limit* in our-abort. The idea
; would be to continue automatically from the interrupt, but with a flag saying
; that the proof should terminate immediately. Then any proof procedure that
; checks for this flag would return with some sort of error. If no such proof
; procedure is invoked, then a second interrupt would immediately take effect.
; An advantage of such an alternative approach is that it would use a normal
; control flow, updating suitable state globals so that a normal call of
; print-summary could be made. We choose, however, not to pursue this
; approach, since it might risk annoying users who find that they need to
; provide two interrupts, and because it seems inherently a bit tricky and
; perhaps easy to get wrong.
; We conclude with remarks for the case that waterfall parallelism is enabled.
; When the user has to interrupt a proof twice before it quits, the prover will
; call this function. Based on observation by Rager, the pstack tends to be
; long and irrelevant in this case. So, we disable the printing of the pstack
; when waterfall parallelism is enabled and waterfall-printing is something
; other than :full. We considered not involving the current value for
; waterfall-printing, but using the :full setting is a strange thing to begin
; with. So, we make the decision that if a user goes to the effort to use the
; :full waterfall-printing mode, that maybe they'd like to see the pstack after
; all.
; The below #+acl2-par change in definition also results in not printing
; gag-state under these conditions. However, this is effectively a no-op,
; because the parallel waterfall does not save anything to gag-state anyway.
(let ((chan (proofs-co state))
(acc-ttree (f-get-global 'accumulated-ttree state)))
(pprogn
(clear-event-data state)
(io? summary nil state (chan acc-ttree)
(pprogn
(newline chan state)
(print-rules-and-hint-events-summary acc-ttree state)))
(cond
#+acl2-par
((and (f-get-global 'waterfall-parallelism state)
(not (eql (f-get-global 'waterfall-printing state) :full)))
state)
(t
(pprogn
(newline chan state)
(princ$ "Here is the current pstack [see :DOC pstack]:" chan state)
(mv-let (erp val state)
(pstack)
(declare (ignore erp val))
(print-gag-state state))))))))
(defun prove-loop0 (clauses pspv hints ens wrld ctx state)
; Warning: This function assumes that *acl2-time-limit* has already been
; let-bound in raw Lisp by bind-acl2-time-limit.
; The perhaps unusual structure below is intended to invoke
; print-summary-on-error only when there is a hard error such as an interrupt.
; In the normal failure case, the pstack is not printed and the key checkpoint
; summary (from the gag-state) is printed after the summary.
(state-global-let*
((guard-checking-on nil) ; see the Essay on Guard Checking
(in-prove-flg t))
(mv-let (interrupted-p erp-val state)
(acl2-unwind-protect
"prove-loop"
(mv-let (erp val state)
(prove-loop1 0 nil clauses pspv hints ens wrld ctx
state)
(mv nil (cons erp val) state))
(print-summary-on-error state)
state)
(cond (interrupted-p (mv t nil state))
(t (mv (car erp-val) (cdr erp-val) state))))))
(defun prove-loop (clauses pspv hints ens wrld ctx state)
; We either cause an error or return a ttree. If the ttree contains
; :byes, the proof attempt has technically failed, although it has
; succeeded modulo the :byes.
#-acl2-loop-only
(setq *deep-gstack* nil) ; in case we never call initial-gstack
(prog2$ (clear-pstk)
(pprogn
(increment-timer 'other-time state)
(f-put-global 'bddnotes nil state)
(if (gag-mode)
(pprogn (f-put-global 'gag-state *initial-gag-state* state)
(f-put-global 'gag-state-saved nil state))
state)
(mv-let (erp ttree state)
(bind-acl2-time-limit ; make *acl2-time-limit* be let-bound
(prove-loop0 clauses pspv hints ens wrld ctx state))
(pprogn
(increment-timer 'prove-time state)
(cond
(erp (mv erp nil state))
(t (value ttree))))))))
(defmacro make-pspv (ens wrld state &rest args)
; This macro is similar to make-rcnst, which is a little easier to understand.
; (make-pspv ens w) will make a pspv that is just *empty-prove-spec-var* except
; that the rewrite constant is (make-rcnst ens w). More generally, you may use
; args to supply a list of alternating keyword/value pairs to override the
; default settings. E.g.,
; (make-pspv ens w :rewrite-constant rcnst :displayed-goal dg)
; will make a pspv that is like the empty one except for the two fields
; listed above.
; Note: Ens and wrld are only used in the default setting of the
; :rewrite-constant. If you supply a :rewrite-constant in args, then ens and
; wrld are actually irrelevant.
`(change prove-spec-var
(change prove-spec-var *empty-prove-spec-var*
:rewrite-constant (make-rcnst ,ens ,wrld ,state
:splitter-output
(splitter-output)))
,@args))
(defun chk-assumption-free-ttree (ttree ctx state)
; Let ttree be the ttree about to be returned by prove. We do not want this
; tree to contain any 'assumption tags because that would be a sign that an
; assumption got ignored. For similar reasons, we do not want it to contain
; any 'fc-derivation tags -- assumptions might be buried therein. This
; function checks these claimed invariants of the final ttree and causes an
; error if they are violated.
; This check is stronger than necessary, of course, since an fc-derivation
; object need not contain an assumption. See also contains-assumptionp for a
; slightly more expensive, but more precise, check.
; A predicate version of this function is assumption-free-ttreep and it should
; be kept in sync with this function, as should chk-assumption-free-ttree-1.
; While this function causes a hard error, its functionality is that of a soft
; error because it is so like our normal checkers.
(cond ((tagged-objectsp 'assumption ttree)
(mv t
(er hard ctx
"The 'assumption ~x0 was found in the final ttree!"
(car (tagged-objects 'assumption ttree)))
state))
((tagged-objectsp 'fc-derivation ttree)
(mv t
(er hard ctx
"The 'fc-derivation ~x0 was found in the final ttree!"
(car (tagged-objects 'fc-derivation ttree)))
state))
(t (value nil))))
#+(and write-arithmetic-goals (not acl2-loop-only))
(when (not (boundp '*arithmetic-goals-fns*))
(defconstant *arithmetic-goals-fns*
'(< = abs acl2-numberp binary-* binary-+ case-split complex-rationalp
denominator equal evenp expt fix floor force if iff ifix implies integerp
mod natp nfix not numerator oddp posp rationalp synp unary-- unary-/
zerop zip zp signum booleanp nonnegative-integer-quotient rem truncate
ash lognot binary-logand binary-logior binary-logxor)))
#+(and write-arithmetic-goals (not acl2-loop-only))
(when (not (boundp '*arithmetic-goals-filename*))
(defconstant *arithmetic-goals-filename*
; Be sure to delete ~/write-arithmetic-goals.lisp before starting a regression.
; (This is done by GNUmakefile.)
(let ((home (our-user-homedir-pathname)))
(cond (home
(merge-pathnames home "write-arithmetic-goals.lisp"))
(t (error "Unable to determine (user-homedir-pathname)."))))))
(defun prove (term pspv hints ens wrld ctx state)
; Term is a translated term. Hints is a list of pairs as returned by
; translate-hints.
; We try to prove term using the given hints and the rules in wrld.
; Note: Having prove use hints is a break from nqthm, where only
; prove-lemma used hints.
; This function returns the traditional three values of an error
; producing/output producing function. The first value is a Boolean
; that indicates whether an error occurred. We cause an error if we
; terminate without proving term. Hence, if the first result is nil,
; term was proved. The second is a ttree that describes the proof, if
; term is proved. The third is the final value of state.
; Commemorative Plaque:
; We began the creation of the ACL2 with an empty GNU Emacs buffer on
; August 14, 1989. The first few days were spent writing down the
; axioms for the most primitive functions. We then began writing
; experimental applicative code for macros such as cond and
; case-match. The first weeks were dizzying because of the confusion
; in our minds over what was in the logic and what was in the
; implementation. On November 3, 1989, prove was debugged and
; successfully did the associativity of append. During that 82 days
; we worked our more or less normal 8 hours, plus an hour or two on
; weekday nights. In general we did not work weekends, though there
; might have been two or three where an 8 hour day was put in. We
; worked separately, "contracting" with one another to do the various
; parts and meeting to go over the code. Bill Schelter was extremely
; helpful in tuning akcl for us. Several times we did massive
; rewrites as we changed the subset or discovered new programming
; styles. During that period Moore went to the beach at Rockport one
; weekend, to Carlsbad Caverns for Labor Day, to the University of
; Utah for a 4 day visit, and to MIT for a 4 day visit. Boyer taught
; at UT from September onwards. These details are given primarily to
; provide a measure of how much effort it was to produce this system.
; In all, perhaps we have spent 60 8 hour days each on ACL2, or about
; 1000 man hours. That of course ignores totally the fact that we
; have thought about little else during the past three months, whether
; coding or not.
; The system as it stood November 3, 1989, contained the complete
; nqthm rewriter and simplifier (including metafunctions, compound
; recognizers, linear and a trivial cut at congruence relations that
; did not connect to the user-interface) and induction. It did not
; include destructor elimination, cross-fertilization, generalization
; or the elimination of irrelevance. It did not contain any notion of
; hints or disabledp. The system contained full fledged
; implementations of the definitional principle (with guards and
; termination proofs) and defaxiom (which contains all of the code to
; generate and store rules). The system did not contain the
; constraint or functional instantiation events or books. We have not
; yet had a "code walk" in which we jointly look at every line. There
; are known bugs in prove (e.g., induction causes a hard error when no
; candidates are found).
; Matt Kaufmann officially joined the project in August, 1993. He had
; previously generated a large number of comments, engaged in a number of
; design discussions, and written some code.
; Bob Boyer requested that he be removed as a co-author of ACL2 in April, 1995,
; because, in his view, he has worked so much less on the project in the last
; few years than Kaufmann and Moore.
; End of Commemorative Plaque
; This function increments timers. Upon entry, the accumulated time is
; charged to 'other-time. The time spent in this function is divided
; between both 'prove-time and to 'print-time.
(cond
((ld-skip-proofsp state) (value nil))
(t
#+(and write-arithmetic-goals (not acl2-loop-only))
(when (ffnnames-subsetp term *arithmetic-goals-fns*)
(with-open-file (str *arithmetic-goals-filename*
:direction :output
:if-exists :append
:if-does-not-exist :create)
(let ((*print-pretty* nil)
(*package* (find-package-fast "ACL2"))
(*readtable* *acl2-readtable*)
(*print-escape* t)
*print-level*
*print-length*)
(prin1 term str)
(terpri str)
(force-output str))))
(progn$
(initialize-brr-stack state)
(initialize-fc-wormhole-sites)
(er-let* ((ttree1 (prove-loop (list (list term))
(change prove-spec-var pspv
:user-supplied-term term
:orig-hints hints)
hints ens wrld ctx state)))
(er-progn
(chk-assumption-free-ttree ttree1 ctx state)
(let ((byes (tagged-objects :bye ttree1)))
(cond
(byes
(pprogn
; The use of ~*1 below instead of just ~&1 forces each of the defthm forms
; to come out on a new line indented 5 spaces. As is already known with ~&1,
; it can tend to scatter the items randomly -- some on the left margin and others
; indented -- depending on where each item fits flat on the line first offered.
(io? prove nil state
(wrld byes)
(fms "To complete this proof you could try to admit the ~
following event~#0~[~/s~]:~|~%~*1~%See the discussion ~
of :by hints in :DOC hints regarding the ~
name~#0~[~/s~] displayed above."
(list (cons #\0 byes)
(cons #\1
(list ""
"~|~ ~q*."
"~|~ ~q*,~|and~|"
"~|~ ~q*,~|~%"
(make-defthm-forms-for-byes
byes wrld))))
(proofs-co state)
state
(term-evisc-tuple nil state)))
(silent-error state)))
(t (value ttree1))))))))))
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