/usr/share/acl2-6.3/interface-raw.lisp is in acl2-source 6.3-5.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
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8622 8623 8624 8625 8626 8627 8628 8629 8630 8631 8632 8633 8634 8635 8636 8637 8638 8639 8640 8641 8642 8643 8644 8645 8646 8647 8648 8649 8650 8651 8652 8653 8654 8655 8656 8657 8658 8659 8660 8661 8662 8663 8664 8665 8666 8667 8668 8669 8670 8671 8672 8673 8674 8675 8676 8677 8678 8679 8680 8681 8682 8683 8684 8685 8686 8687 8688 8689 8690 8691 8692 8693 8694 8695 8696 8697 8698 8699 8700 8701 8702 8703 8704 8705 8706 8707 8708 8709 8710 8711 8712 8713 8714 8715 8716 8717 8718 8719 8720 8721 8722 8723 8724 8725 8726 8727 8728 8729 8730 8731 8732 8733 8734 8735 8736 | ; ACL2 Version 6.3 -- A Computational Logic for Applicative Common Lisp
; Copyright (C) 2013, 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 78701 U.S.A.
(in-package "ACL2")
; This file, interface-raw.lisp, contains parts of ACL2 which we
; cannot code in ACL2 because they require constructs not in ACL2, such
; as calling the compiler.
; EVALUATION
; Essay on Evaluation in ACL2
; This essay is structured as follows. Terminology is explained below.
; A. Introduction
; B. Specification of the problem
; C. Sketch of correctness proof
; D. Why safe mode is necessary
; E. The template for oneification of function definitions
; F. Remarks
; Let us begin.
; A. Introduction
; Evaluation in ACL2, which takes place in the ACL2 loop and during theorem
; proving, is based on the way evaluation was done in Nqthm. The idea is to
; "oneify" the body of a definition by replacing functions by their so-called
; "executable counterparts," sometimes called "*1* functions." The primitives
; have *1* functions that reflect their logical definitions, so that for
; example (*1*car x), or more precisely (acl2_*1*_lisp::car x), returns nil
; when x is an atom -- except that an error occurs if we are checking guards
; (or are in so-called safe mode, as explained below). Defined functions have
; *1* function counterparts that are defined, roughly speaking, by replacing
; each function call in their bodies by a call of the corresponding *1*
; function.
; The evaluation mechanism in ACL2 changed radically in v1-8, when guards were
; removed from the logic. It has changed again in Version_2.6, due to a hole
; in the existing mechanism, as we explain in Part D of this Essay, below.
; B. Specification of the problem
; Our specification begins with the introduction of three notions of evaluation
; and three notions of macroexpansion. Evaluation is relative to an (implicit)
; environment, which binds variables to ACL2 values, and operates on ACL2 terms
; that are free of macro calls. If we want to discuss evaluation of terms that
; involve macro calls, we will compose macroexpansion and evaluation. This
; composition represents the way that both Common Lisp and the ACL2 loop
; evaluate forms. We also assume that there is no distinction between
; evaluation of compiled and interpreted code. Finally, we assume that for all
; of these sorts of evaluation and expansion, macros are expanded before
; function and macro bodies are stored; this is how things are done in the ACL2
; logic and with *1* functions, and it had better be equivalent to how a Common
; Lisp does its evaluation and expansion.
; We extend classes of function symbols to classes of terms in the obvious way:
; a :logic mode term is one whose function symbols are all :logic mode function
; symbols, and similarly for the notion of :common-lisp-compliant.
; Here then are the notions promised above.
; ACL2 logical evaluation: This procedure is an interpreter that computes
; using definitions in the logic and obvious properties of primitives (e.g.,
; (stringp "abc") returns t).
; ACL2 loop evaluation: This is the procedure used in the ACL2 loop, using
; so-called *1* functions (and higher-level routines such as raw-ev-fncall).
; Common Lisp evaluation: As the name implies, this procedure is the one used
; by Common Lisp.
; ACL2 logical macroexpansion: This is any procedure that carries out the
; usual macroexpansion algorithm (outside-in), but entirely using ACL2
; definitions, including those of :program mode functions. We assume that
; macros have already been similarly expanded in function bodies, before
; evaluation begins. Macro bodies are evaluated using ACL2 logical
; evaluation. This procedure is embodied in the ACL2 definition of the
; function translate.
; ACL2 loop macroexpansion: This is the procedure that ACL2 actually applies
; in order to create terms from user input. Ideally this procedure returns
; the same results as does ACL2 logical macroexpansion; the distinction here
; is between what an appropriate interpreter would return (ACL2 logical
; macroexpansion) and how ACL2 actually translates a term (ACL2 loop
; macroexpansion). ACL2 loop macroexpansion always takes place in safe mode.
; Common Lisp macroexpansion: This is how Common Lisp (actually, an arbitrary
; but fixed implementation) macroexpands forms.
; As an aside, we note the following fact that is useful in establishing the
; guarantees below, but whose proof we omit here.
; (*) If a :common-lisp-compliant function is applied to arguments that
; satisfy its guard (using Common Lisp evaluation), without error, then the
; result agrees with that produced by ACL2 logical evaluation.
; Now our top-level guarantees about evaluation and macroexpansion are as
; follows, where for brevity, "evaluation" of a given type is the composition
; of macroexpansion and evaluation for that type.
; (1) If ACL2 evaluates a :logic mode form without error, then the value
; returned equals the result of ACL2 logical (macroexpansion and) evaluation
; of that form.
; (2) If furthermore that evaluation in done with guard-checking on and the
; result of ACL2 logical macroexpansion is a :common-lisp-compliant term,
; then any non-erroneous Common Lisp evaluation returns that same value.
; C. Sketch of correctness proof
; We now outline a proof of these guarantees by breaking them into the
; following sequence of claims. We write "weakly implements" to mean that two
; procedures give equivalent results on given inputs when they both return
; without error, and we write "implements" if the condition can be weakened to
; assume only that the first procedure returns without error. That is, proc1
; implements proc2 iff proc1 weakly implements proc2 and whenever proc1 returns
; without error, then so does proc2. Above, "equivalent" means identical
; except as explained otherwise below. Implicit in this notion is that the
; input is appropriate for the procedures; for example, our notions of
; evaluation assume that all function symbols in the input are either ACL2
; primitive functions or have been defined as functions (not macros) in ACL2.
; A more rigorous argument would proceed by induction on the length of
; histories, showing that the properties in question hold when one extends the
; history with new function and macro definitions.
; (1a) ACL2 loop evaluation implements ACL2 logical evaluation on :logic mode
; terms and, provided safe mode is used, on arbitrary terms.
; (1b) ACL2 loop macroexpansion implements ACL2 logical macroexpansion.
; (2a) ACL2 loop evaluation in safe mode weakly implements Common Lisp
; evaluation. The same claim holds if the assumption of safe mode is
; replaced by the assumption that guard-checking is on, provided that the
; input form expands to a :common-lisp-compliant term.
; (2b) ACL2 loop macroexpansion weakly implements Common Lisp macroexpansion,
; where results r1 (from ACL2 loop macroexpansion) and r2 (from Common Lisp
; macroexpansion) are considered equivalent if for any environment, the ACL2
; loop evaluation of r1 with guard-checking on returns the same result as the
; Common Lisp evaluation of r2, provided both evaluations return without
; error.
; Sketch of proof that guarantees hold. Clearly (1) follows from (1a) and
; (1b), while (2) follows from (1b) and (2b). (1a) follows by inspection of
; the template presented below, using (*) above. (1b) follows from (1a) by
; computational induction on the macroexpansion, because ACL2 loop
; macroexpansion and ACL2 logical macroexpansion differ only in the use of loop
; or logical evaluation of macro bodies. The first part of (2a) is argued
; similarly to (1a), while the second part is actually quite trivial by
; inspection of the template below. Finally, (2b) follows from (2a) by a
; computational induction just as (1b) follows from (1a), with a bit of
; complication. When we encounter a call of a macro first introduced in ACL2
; (either during the boot-strap or by a user), then we evaluate the same macro
; body for ACL2 loop evaluation as for Common Lisp evaluation, except that this
; body has first been macroexpanded using ACL2 loop macroexpansion and Common
; Lisp macroexpansion, respectively. But these may be viewed as equivalent by
; the inductive hypothesis (where for purposes of this proof we pretend that
; macroexpansion of the body takes place as part of the process). In the other
; case, the macro already has a Common Lisp definition (as a function or
; macro), and we have arranged that (2) holds. For example, the ACL2 loop
; macroexpansion of (append x y z) is (binary-append x (binary-append y z)),
; and Common Lisp evaluation of the former clearly agrees with ACL2 loop
; evaluation of the latter. Q.E.D.
; D. Why safe mode is necessary
; The soundness of ACL2 potentially rests on the principle of not calling raw
; Lisp counterparts of functions with arguments outside their intended domains,
; as specified by their guards. Here we give three examples illustrating why
; we introduced safe mode in Version_2.6. The third one is a proof of nil!
; Example 1. In our first example below, the defun of bar should fail. It
; does indeed fail starting with Version_2.6, but not in Version_2.5 or (we
; believe) several versions before that. We discuss below how this can lead
; to unsoundness.
; (defmacro foo (x) (car x))
; (set-guard-checking nil)
; (defun bar (y)
; (declare (xargs :verify-guards t))
; (cons (foo y) y))
; :q
; (trace bar)
; (lp)
; Now, the result of evaluating (bar 3) looks as shown below. Notice that the
; Common Lisp function bar is called. If the Common Lisp evaluation of the
; form (car 'y) had returned 1 or 2 (say) instead of breaking, then the Common
; Lisp evaluation of (bar 3) would have returned (cons 1 3) or (cons 2 3),
; respectively. This evaluation could be reflected in theorems (equal (bar 3)
; i) [i=1,2] proved in books certified in two different Common Lisp
; implementations of ACL2. We could then prove nil by including both books
; into the same session. Lest one think that one needs different Lisp
; implementations to expose unsoundness, imagine a single Lisp in which (car
; 'y) sometimes returns 1 and sometimes returns 2.
; ACL2 >(bar 3)
; 1> (ACL2_*1*_ACL2::BAR 3)>
; 2> (BAR 3)>
;
; Error: Y is not of type LIST.
; Fast links are on: do (si::use-fast-links nil) for debugging
; Error signalled by CAR.
; Broken at COND. Type :H for Help.
; ACL2>>
; Here is what ACL2 Version_2.6 prints in an attempt to define function bar,
; above, with guard-checking off.
; ACL2 >(defun bar (y) (foo y))
;
;
; ACL2 Error in ( DEFUN BAR ...): The guard for the function symbol
; CAR, which is (OR (CONSP X) (EQUAL X NIL)), is violated by the arguments
; in the call (CAR 'Y). The guard is being checked because this function
; is a primitive and a "safe" mode is being used, perhaps for macroexpansion.
;
;
;
; ACL2 Error in ( DEFUN BAR ...): In the attempt to macroexpand the
; form (FOO Y), evaluation of the macro body caused an error.
;
;
; Summary
; Form: ( DEFUN BAR ...)
; Rules: NIL
; Warnings: None
; Time: 0.00 seconds (prove: 0.00, print: 0.00, other: 0.00)
;
; ******** FAILED ******** See :DOC failure ******** FAILED ********
; ACL2 >
; Example 2. Unlike the previous example, this one causes problems even when
; guard-checking is on. (Thanks to Pete Manolios for helping to construct this
; example, which is simpler than an earlier one we had.)
; (defun my-endp-0 ()
; (declare (xargs :mode :program))
; (endp 0))
; (defmacro bad-macro ()
; (my-endp-0))
; :q
; (trace my-endp-0 endp)
; (lp)
; (thm (equal (bad-macro) 1))
; Now look at the following Version_2.5 trace. It highlights a behavior of
; Version_2.5: when a :program mode function (here, my-endp-0) is
; called on arguments satisfying its guard (here, implicitly t), the
; corresponding raw Lisp function is invoked. Thus guards are not checked on
; its subroutines (here, endp). In this example, endp is being called on an
; argument not satisfying its guard. In the abstract, this is problematic
; because we use guards to restrict primitives to arguments for which the
; result is implementation independent. If the result of (endp 0) can depend
; on the implementation, we could prove nil as described in the preceding
; example.
; ACL2 !>(thm (equal (bad-macro) 1))
; 1> (ACL2_*1*_ACL2::MY-ENDP-0)>
; 2> (MY-ENDP-0)>
; 3> (ENDP 0)>
;
; Error: 0 is not of type LIST.
; Fast links are on: do (si::use-fast-links nil) for debugging
; Error signalled by SYSTEM::TRACE-CALL.
; Broken at COND. Type :H for Help.
; ACL2>>
; The example above may seem contrived (because it is!). However, our foray
; into this territory began on a rather similar but real example. In Allegro
; 6.0, the character (code-char (+ 128 65)) is upper case; in particular it is
; not equal to the result of applying char-downcase to it. However, this is
; not the case for Allegro 5.0.1. Since the result is
; implementation-dependent, it is natural to restrict the application of
; code-char to standard characters, using ACL2's guard mechanism. But the
; example above show that we can bypass such restrictions by using macros.
; Example 3. We can prove nil in Version_2.5 by certifying the following two
; books. The only cheats are that the first book needs to be certified after
; executing the following in the ACL2 loop:
; (set-guard-checking nil)
; First book, call it "ex":
; (in-package "ACL2")
;
; (defun my-eq (x y)
; (declare (xargs :guard t ; "bad" guard
; :mode :program))
; (eq x y))
;
; (defmacro bad-macro ()
; (my-eq '(a b) '(a b)))
;
; (set-verify-guards-eagerness 0)
;
; (local (verify-termination my-eq))
;
; (defun bad-fn ()
; (bad-macro))
;
; (defthm bad-thm
; (bad-fn)
; :rule-classes nil)
; Second book, which includes the one above::
; (in-package "ACL2")
;
; (local (include-book "ex"))
;
; (defthm very-bad
; nil
; :hints (("Goal" :use bad-thm))
; :rule-classes nil)
; In Version_2.6 we get an error when we try to certify the first book above
; ("ex"):
; ACL2 Error in ( DEFUN BAD-FN ...): The guard for the function symbol
; EQ, which is (IF (SYMBOLP X) T (SYMBOLP Y)), is violated by the arguments
; in the call (EQ '(A B) '(A B)). The guard is being checked because
; this function is a primitive and a "safe" mode is being used, perhaps
; for macroexpansion.
;
;
;
; ACL2 Error in ( DEFUN BAD-FN ...): In the attempt to macroexpand the
; form (BAD-MACRO), evaluation of the macro body caused an error.
; As the first message just above suggests, in Version_2.6 we prevent the bad
; behavior illustrated by the examples above by introducing a "safe mode" for
; use during macroexpansion, in which guards are checked on built-in functions.
; Finally, note that we do not attempt to fix the following "problem." That
; is, the behavior for the example below is unchanged from Version_2.5 to
; Version_2.6. The point is that for macroexpansion to behave properly, we
; really need only guarantee consistency between the logic and Common Lisp; it
; is acceptable if in some modes we get errors even when errors are not
; necessary.
; (defun mac-fn (x) (declare (xargs :guard (consp x))) x)
; (defmacro mac (x) (mac-fn x))
; (defun bar (x) (mac x)) ; fails
; :set-guard-checking nil
; (defun bar (x) (mac x)) ; succeeds
; E. The template for oneification of function definitions
; Before we present this template, we give a bit of history and show an
; example.
; The following example shows how *1* functions are handled in Version_2.5 and
; before. The ACL2 definition is:
; (defun foo (x)
; (declare (xargs :mode :logic :guard (true-listp x)))
; (if (endp x) 3 (+ 1 (foo (cdr x)))))
; Here is the executable counterpart in Version_2.5, in gcl:
; ACL2>(symbol-function 'ACL2_*1*_ACL2::FOO) ; in gcl, ACL2 Version_2.5
; (LISP:LAMBDA-BLOCK ACL2_*1*_ACL2::FOO (X)
; (LABELS ((ACL2_*1*_ACL2::FOO (X)
; (IF (ACL2_*1*_LISP::ENDP X) '3
; (ACL2_*1*_ACL2::BINARY-+ '1
; (ACL2_*1*_ACL2::FOO (ACL2_*1*_LISP::CDR X))))))
; (LET ((ACL2_*1*_ACL2::FOO (SYMBOL-CLASS 'FOO (W *THE-LIVE-STATE*)))
; (GUARD-CHECKING-ON
; (F-GET-GLOBAL 'GUARD-CHECKING-ON *THE-LIVE-STATE*)))
; (COND
; ((LET ((*HARD-ERROR-RETURNS-NILP*
; (OR *HARD-ERROR-RETURNS-NILP*
; (NOT GUARD-CHECKING-ON))))
; (IF (EQ ACL2_*1*_ACL2::FOO :IDEAL)
; (ACL2_*1*_ACL2::TRUE-LISTP X) (TRUE-LISTP X)))
; (IF (EQ ACL2_*1*_ACL2::FOO :IDEAL) (ACL2_*1*_ACL2::FOO X)
; (FOO X)))
; (GUARD-CHECKING-ON
; (THROW-RAW-EV-FNCALL
; (LIST 'EV-FNCALL-GUARD-ER 'FOO (LIST X) '(TRUE-LISTP X)
; '(NIL))))
; (T (ACL2_*1*_ACL2::FOO X))))))
; Notice the inefficiency of needlessly checking guards in Version_2.5 in the
; :ideal case when guard-checking is off. We fix that problem in Version_2.6,
; but more importantly, we implement a "safe mode" to be used during
; macroexpansion, so that we can trust that ACL2 and Common Lisp agree when
; they are supposed to, thus avoiding the sort of problem illustrated above
; (function bar and macro mac). We make this idea precise in our discussion of
; "Guarantees", above.
; ACL2>(symbol-function 'ACL2_*1*_ACL2::FOO) ; in gcl, ACL2 Version_2.6
; (LISP:LAMBDA-BLOCK ACL2_*1*_ACL2::FOO (X)
; (LABELS ((ACL2_*1*_ACL2::FOO (X)
; (IF (ACL2_*1*_LISP::ENDP X) '3
; (ACL2_*1*_ACL2::BINARY-+ '1
; (ACL2_*1*_ACL2::FOO (ACL2_*1*_LISP::CDR X))))))
; (COND
; ((TRUE-LISTP X) (RETURN-FROM ACL2_*1*_ACL2::FOO (FOO X)))
; ((F-GET-GLOBAL 'GUARD-CHECKING-ON *THE-LIVE-STATE*)
; (RETURN-FROM ACL2_*1*_ACL2::FOO
; (THROW-RAW-EV-FNCALL
; (LIST 'EV-FNCALL-GUARD-ER 'FOO (LIST X) '(TRUE-LISTP X)
; '(NIL))))))
; (ACL2_*1*_ACL2::FOO X)))
; Next, we present a basic template (outline, really) for defining executable
; counterparts. Note that as in the code for Version_2.5, we may optimize away
; consideration of the guard when the guard is t (either implicitly or
; explicitly). Furthermore, we do some optimization when the symbol-class of
; the function is :common-lisp-compliant, as we do in Version_2.5 for :program
; vs. :logic mode.
; The template below uses some abbreviations <...>, which are defined below the
; template. See also oneify-cltl-code for more details, special cases, and
; optimizations. There we also handle the guarded-primitive-p case, which
; pertains to built-in defined functions that need to be responsible for
; checking their guards in safe-mode. That does not however deal with true
; primitives, which are not defined. For those, safe-mode is handled with
; calls of gv in their defun-*1* definitions.
; Finally, this template is only approximate and not necessarily up-to-date.
; It is intended to give a sense of how oneify-cltl-code works; see the code
; for up-to-date comments. You may be better off simply by tracing
; oneify-cltl-code with hiding of the wrld argument, for example with
; (trace! (oneify-cltl-code :entry t :native t))
; -- and then executing each of the following test cases. Follow each of these
; with (trace$ foo) to see oneification for allowing tracing of recursive calls
; when guard-checking is :none. Then execute :u before the next defun. Oh,
; and try guard violations too.
; (defun foo (x)
; (declare (xargs :guard t))
; (if (natp x) (if (zp x) 0 (* x (foo (1- x)))) 0))
; (defun foo (x)
; (declare (xargs :guard t :verify-guards nil))
; (if (natp x) (if (zp x) 0 (* x (foo (1- x)))) 0))
; (defun foo (x)
; (declare (xargs :guard t :mode :program))
; (if (natp x) (if (zp x) 0 (* x (foo (1- x)))) 0))
;
; (defun foo (x)
; (declare (xargs :guard (natp x)))
; (if (zp x) 0 (* x (foo (1- x)))))
; (defun foo (x)
; (declare (xargs :guard (natp x) :mode :program))
; (if (zp x) 0 (* x (foo (1- x)))))
; (defun foo (x)
; (declare (xargs :guard (natp x) :verify-guards nil))
; (if (zp x) 0 (* x (foo (1- x)))))
;
; ; This one reports a guard violation with guard-checking set to :all but not
; ; when it is set to t.
; (defun foo (x)
; (declare (xargs :guard (evenp x) :verify-guards nil))
; (if (zp x) 0 (* x (foo (1- x)))))
;
; (defun foo (x)
; (if (zp x) 0 (* x (foo (1- x)))))
; (defun <*1*fn> <formals>
; <wormhole-test-for-functions-with-user-stobjs>
; (let ((<class> (symbol-class '<fn> (w *the-live-state*))))
; (cond ((eq <class> :common-lisp-compliant)
; (cond
; ((or (equal <guard> *t*)
; (not (eq <guard-checking-on> :none))
; (acl2-system-namep name wrld))
; (cond (<guard> ; avoid <*1*guard> since guard is known compliant
; (cond (<live-stobjp-test> ; test can often be omitted
; (return-from <*1*fn> (<fn> . <formals>)))))
; (<guard-checking-on> <fail_guard>))
;
; ; Otherwise fall through to final call of *1* function.
;
; )
;
; ; The next case is not needed for our guarantees. Rather, it ensures that
; ; evaluation with guard checking on really does check guards at each function
; ; call.
;
; ((and <guard-checking-on>
; (not <*1*guard>))
; <fail_guard>)
; ((or (eq <guard-checking-on> :all)
; (and <safe>
; (eq <class> :program)))
; (return-from <*1*fn> *1*body))
; ((eq <class> :program)
; (return-from <*1*fn> (<fn> . <formals>)))
;
; ; If we fall through to here, then we compute in the logic, avoiding further
; ; guard checks in recursive calls (where a "special" declaration will take
; ; care of this if we are in a mutual-recursion nest).
;
; (maybe-warn-for-guard <fn>)))
;
; ; In the case (eq <class> :program), we conclude by laying down the call (<fn>
; ; . <formals>). Otherwise, we lay down the following code.
;
; (labels
;
; ; The following local definition of <*1*fn> executes calls of <fn> in the
; ; logic, without guard-checking (except for primitives under safe-mode; see
; ; below). Note that it is always legitimate for this local function to cause
; ; an error, so if we want to save space we can fail here, in particular for
; ; :program mode functions encountered during the boot-strap, at least outside
; ; (say) axioms.lisp -- although that would presumably eliminate the ability to
; ; call those functions in macro definitions.
;
; ((<*1*fn>
; <formals>
;
; ; Certain functions can take the live state as an argument, and yet do
; ; not ``properly'' handle it in their logic code. Consider for
; ; example (princ$ '(a b) *standard-co* state). With guard-checking
; ; off, and a live state, this form used to cause a hard error. The
; ; problem was that the logical body of princ$ (actually, its
; ; oneification) was being executed. Consider calling a function such
; ; as open-output-channels, which is really a call of nth, on a live
; ; state! We believe that our problem is solved by disallowing calls
; ; of certain built-in functions on a live state argument, when passing
; ; to their oneified bodies. These functions are those in
; ; *super-defun-wart-stobjs-in-alist*, since these are the ones that
; ; pass the state on as though it were a legitimate state object, i.e.,
; ; to functions that take non-state values as arguments.
;
; ; Other functions, such as those defined under defstobj, may have a stobj
; ; name as an argument but do not have an appropriate 'stobjs-in
; ; setting in the world, because we have not yet declared that the
; ; stobj name is a stobj. These latter functions are characterized by
; ; having a non-nil stobj-flag, said flag being the stobj name. We
; ; compute here the appropriate stobjs-in.
;
; <fail_if_live_stobj> ; laid down only in cases as described above
; *1*body))
; (*1*fn . formals)))))
;
; WHERE:
;
; <*1*guard>
; =
; oneification of guard
;
; <formals>
; =
; list of formals, e.g., (x1 ... xn)
;
; <guard-checking-on>
; =
; (f-get-global 'guard-checking-on *the-live-state*)
;
; <guard>
; =
; [guard of the function being defined]
;
; <fail_guard>
; =
; (throw-raw-ev-fncall
; (list 'ev-fncall-guard-er '<fn> (list x) '<guard> '(nil) nil))
;
; <fail_safe>
; =
; (throw-raw-ev-fncall
; (list 'ev-fncall-guard-er '<fn> (list x) '<guard> '(nil) t))
;
; <class>
; =
; <*1*fn>
;
; <*1*fn>
; =
; (*1*-symbol <fn>)
;
; <fn>
; =
; [function symbol being defined]
;
; <safe>
; =
; (f-get-global 'safe-mode *the-live-state*)
;
; <fail_if_live_stobj>
; =
; code for protecting against executing <*1*body> on live stobjs
;
; <live-stobjp-test>
; =
; test that all of the stobj parameters to the function are indeed the "live"
; stobjs. This is required because the Common Lisp code for stobj access and
; update functions assumes, starting in v2-8, that user-defined stobj parameters
; are live, a restriction enforced by the corresponding *1* functions before
; passing to Common Lisp.
;
; <wormhole-test-for-functions-with-user-stobjs>
; =
; a test that is generated to check if one is evaluating a function with
; user-defined stobjs in a wormhole (no wormhole test is performed if the
; function does not take user-defined stobjs as arguments). Only proper updates
; on state are allowed inside wormholes since the wormhole can properly "undo"
; these side effects upon completion. No such mechanism exists for user-defined
; stobjs and thus the test. Before v2-8, this wormhole test was performed in the
; stobj update primitives directly, but it is now performed in the *1* function
; as a matter of efficiency. The exclusion of read access of user-defined stobjs
; in wormholes simplifies the code to generate the *1* body and while technically
; unnecessary, does not seem to be a relevant over-restriction in practice.
; F. Remarks
; Remark 1. Notice that safe mode does not by itself force guard-checking in
; all cases, nor does soundness of safe mode require guard-checking as long as
; we do check guards when evaluating calls of functions that are built into
; Common Lisp. We ensure this in the macro gv, which is changed in Version_2.6
; to cause an error when in safe mode.
; Remark 2. Consider, in the body of *1*fn, the case that <guard-checking-on>
; holds. If we were to replace it with (or guard-checking-on program) then we
; would always check guards when in program mode, which would give backward
; compatability: this scheme would behave exactly as the scheme from
; Version_2.5 for and before did when the new scheme is used in other than safe
; mode. But we have decided that starting with Version_2.6, we will no longer
; check guards for :program mode functions when 'guard-checking-on has value
; nil (though starting with Version_3.0 you can get this effect when
; 'guard-checking-on has value :none). After all, even with guard-checking on
; in Version_2.5 you can get nasty Lisp breaks, since we slip directly into
; Common Lisp when a guard holds even though guards cannot be verified for
; :program mode functions.
; End of Essay on Evaluation in ACL2
; ONEIFICATION
; Here are the *1* functions. They should be kept in sync with
; *primitive-formals-and-guards*. We could probably get by with avoiding
; defining those in the list *oneify-primitives*, for example since want to
; avoid calling "slow" functions, e.g., *1*cons instead of cons. But we prefer
; to follow the simple rule that every function has a *1* counterpart, which is
; easy to remember. Moreover, in the case of IF we really do want to define
; *1*if to cause an error, because we insist that the oneification of if remain
; lazy.
; WARNING: Any hand-coded *1* definitions for other than the primitives, such
; as the one for mv-list (see below), must be handled in add-trip and
; compile-uncompiled-*1*-defuns (see the handling there of mv-list).
; We must hand-code the *1* functions for mv-list and return-last, because
; otherwise they will simply call mv-list and return-last (resp.), which can be
; wrong: in the case of return-last, we need the first argument to be a quotep
; for the raw-Lisp macro return-last to do more than lay down a progn.
(defun-*1* mv-list (input-arity x)
(declare (ignore input-arity))
x)
(defun-*1* return-last (fn x y)
(cond ((and (equal fn 'mbe1-raw)
(f-get-global 'safe-mode *the-live-state*))
; Since return-last is a special form, we can decide how we want to view it
; with respect to guards. We have decided to check its guard only when in safe
; mode, which is the minimal case needed in order to fix a soundness bug
; related to mbe; see note-4-3. The following log shows what happened in a
; preliminary implementation of that bug fix, in which oneify laid down a
; *1*return-last call unconditionally; note the unfortunate call of the :exec
; function, f2. Of course, that call is not the fault of the old version of
; *1*return-last, which is a function called after its arguments are already
; evaluated; there are other places (ev-rec and oneify) where we avoid even
; calling *1*return-last. But if we do get to this call, for example by way of
; expand-abbreviations calling ev-fncall, at least we can limit the equality
; check here to the case of safe-mode (which is presumably nil, for example,
; under expand-abbreviations).
; ACL2 !>(defn f1 (x) x)
; [[... output omitted ...]]
; F1
; ACL2 !>(defn f2 (x) x)
; [[... output omitted ...]];
; F2
; ACL2 !>(defun f (x) (mbe :logic (f1 x) :exec (f2 x)))
; [[... output omitted ...]]
; F
; ACL2 !>(trace$ f f1 f2)
; ((F) (F1) (F2))
; ACL2 !>(f 3)
; 1> (ACL2_*1*_ACL2::F 3)
; 2> (ACL2_*1*_ACL2::F2 3)
; 3> (F2 3)
; <3 (F2 3)
; <2 (ACL2_*1*_ACL2::F2 3)
; 2> (ACL2_*1*_ACL2::F1 3)
; 3> (F1 3)
; <3 (F1 3)
; <2 (ACL2_*1*_ACL2::F1 3)
; <1 (ACL2_*1*_ACL2::F 3)
; 3
; ACL2 !>
(if (equal x y)
y
(gv return-last (fn x y)
y)))
(t y)))
; We must hand-code the *1* function for wormhole-eval because if it were
; automatically generated it would look like this:
; (defun ACL2_*1*_ACL2::WORMHOLE-EVAL (qname qlambda free-vars)
; (wormhole-eval qname qlambda free-vars))
; (To see where this code would be generated, find the comment beginning
; "Optimization in a common case" in oneify-cltl-code.)
; But the body of the *1* defun above violates the requirement that the
; wormhole-eval macro always be applied to a quoted name and lambda expression.
; In particular, if the default optimized code above is generated and then
; given to raw lisp, a hard error results when the wormhole-eval macro tries to
; cadr into qname. So what should be here? Intuitively we ought to lay down
; code that checks that qlambda is a well-formed and appropriate lambda
; expression and then apply it to the wormhole status of the wormhole with the
; name qname. But in fact this *1* function should never be called except from
; within the theorem prover when we are evaluating wormhole-eval on quoted
; constants. Thus, we just return nil, it's logical value, without attempting
; to do any of the wormhole stuff.
(defun-*1* wormhole-eval (qname qlambda free-vars)
(declare (ignore qname qlambda free-vars))
nil)
; Keep the rest of these in sync with the completion-of-* axioms in
; axioms.lisp.
(defun-*1* acl2-numberp (x)
(numberp x))
(defun-*1* binary-* (x y)
(the number
(if (numberp x)
(if (numberp y)
(* x y)
(gv binary-* (x y) 0))
(gv binary-* (x y) 0))))
(defun-*1* binary-+ (x y)
(the number
(if (numberp x)
(if (numberp y)
(+ (the number x) (the number y))
(gv binary-+ (x y) x))
(gv binary-+ (x y)
(if (numberp y)
y
0)))))
(defun-*1* unary-- (x)
(the number
(if (numberp x)
(- x)
(gv unary-- (x) 0))))
(defun-*1* unary-/ (x)
(the number
(if (and (numberp x) (not (= x 0)))
(/ x)
(gv unary-/ (x) 0))))
(defun-*1* < (x y)
; If one regards (gv op args val) simply as val, then we can prove that
; the body below is equivalent to the let-expression used for val. Put
; another way, if we use << as the "familiar" less-than on the rationals
; then this definition of < is equivalent to
; (< x y) = (let ((x1 (if (acl2-numberp x) x 0))
; (y1 (if (acl2-numberp y) y 0)))
; (or (<< (realpart x1) (realpart y1))
; (and (= (realpart x1) (realpart y1))
; (<< (imagpart x1) (imagpart y1)))))
; The consideration of the case where both x and y are rational is just
; an optimization.
(if (and (rationalp x)
(rationalp y))
(< (the rational x) (the rational y))
(gv < (x y)
(let ((x1 (if (numberp x) x 0))
(y1 (if (numberp y) y 0)))
(or (< (realpart x1) (realpart y1))
(and (= (realpart x1) (realpart y1))
(< (imagpart x1) (imagpart y1))))))))
(defun-*1* apply (x y)
(error "We have called apply on ~s and ~s, but we thought we were rid of apply."
x y))
(defun-*1* bad-atom<= (x y)
(cond ((and (bad-atom x) (bad-atom y))
; The following should never happen.
(error "We have called (the executable counterpart of) bad-atom<= on ~
~s and ~s, but bad-atom<= has no Common Lisp definition."
x y))
(t (gv bad-atom<= (x y) nil))))
(defun-*1* car (x)
(cond
((consp x)
(car x))
((null x)
nil)
(t (gv car (x) nil))))
(defun-*1* cdr (x)
(cond
((consp x)
(cdr x))
((null x)
nil)
(t (gv cdr (x) nil))))
(defun-*1* char-code (x)
(if (characterp x)
(char-code x)
(gv char-code (x) 0)))
(defun-*1* characterp (x)
(characterp x))
(defun-*1* code-char (x)
(if (and (integerp x)
(>= x 0)
(< x 256))
(code-char x)
(gv code-char (x) (code-char 0))))
(defun-*1* complex (x y)
(complex (the rational (if (rationalp x) x (gv complex (x y) 0)))
(the rational (if (rationalp y) y (gv complex (x y) 0)))))
(defun-*1* complex-rationalp (x)
(complexp x))
;; RAG - I added this function to recognize the complex numbers.
#+:non-standard-analysis
(defun-*1* complexp (x)
(complexp x))
(defun-*1* coerce (x y)
(cond
((equal y 'list)
(if (stringp x)
(coerce x 'list)
(gv coerce (x y) nil)))
((character-listp x)
(if (equal y 'string)
(coerce x 'string)
(gv coerce (x y) (coerce x 'string))))
(t
(gv coerce (x y)
(coerce (make-character-list x) 'string)))))
(defun-*1* cons (x y)
(cons x y))
(defun-*1* consp (x)
(consp x))
(defun-*1* denominator (x)
(if (rationalp x)
(denominator x)
(gv denominator (x) 1)))
(defun-*1* equal (x y)
(equal x y))
#+:non-standard-analysis
(defun-*1* floor1 (x)
;; RAG - I added this function to evaluate the special floor1
;; function, which computes floor with a modulus of 1.
(if (rationalp x)
(floor x 1)
(gv floor1 (x) 0)))
(defun-*1* if (x y z)
(error "We just can't stand having a non-lazy IF around. But we attempted ~%~
to call the executable counterpart of IF on argument list ~s."
(list x y z)))
(defun-*1* imagpart (x)
(if (numberp x)
(imagpart x)
(gv imagpart (x) 0)))
(defun-*1* integerp (x)
(integerp x))
(defun-*1* intern-in-package-of-symbol (x y)
(if (and (stringp x)
(symbolp y))
(intern-in-package-of-symbol x y)
(gv intern-in-package-of-symbol (x y) nil)))
(defun-*1* pkg-imports (pkg)
(if (stringp pkg)
(pkg-imports pkg)
(gv pkg-witness (pkg) nil)))
(defun-*1* pkg-witness (pkg)
(if (stringp pkg)
(if (find-non-hidden-package-entry
pkg (known-package-alist *the-live-state*))
(let ((ans (intern *pkg-witness-name* pkg)))
; See comment in intern-in-package-of-symbol for an explanation of this trick.
ans)
(throw-raw-ev-fncall (list 'pkg-witness-er pkg)))
(gv pkg-witness (pkg) (intern *pkg-witness-name* "ACL2"))))
(defun-*1* numerator (x)
(if (rationalp x)
(numerator x)
(gv numerator (x) 0)))
(defun-*1* rationalp (x)
(rationalp x))
;; RAG - I added realp to recognize real numbers.
#+:non-standard-analysis
(defun-*1* realp (x)
(realp x))
(defun-*1* realpart (x)
(if (numberp x)
(realpart x)
(gv realpart (x) 0)))
(defun-*1* stringp (x)
(stringp x))
(defun-*1* symbol-name (x)
(if (symbolp x)
(symbol-name x)
(gv symbol-name (x) "")))
(defun-*1* symbol-package-name (x)
(if (symbolp x)
(progn (chk-bad-lisp-object x)
(symbol-package-name x))
(gv symbol-package-name (x) "")))
(defun-*1* symbolp (x)
(symbolp x))
;; RAG - I added *1*-defns for the non-standard predicates. Note,
;; however, that the non-standard predicates do NOT have an executable
;; counterpart. (Actually, that's too hasty. Standard-part could be
;; defined as "identity" and standardp could be "t".
;; Nothing can be done about i-large-integer, though.) So, these
;; functions simply throw an error [added by Matt...: -- or, they did
;; at one time. For efficiency it was useful to allow these to compute
;; on valid ACL2 objects (see bad-lisp-objectp); actually Ruben already
;; had made such changes].
#+:non-standard-analysis
(progn
(defun standardp (x)
(declare (ignore x))
t)
(defun-*1* standardp (x)
(declare (ignore x))
t)
(defun standard-part (x)
x)
(defun-*1* standard-part (x)
x)
(defun i-large-integer ()
(throw-raw-ev-fncall '(ev-fncall-null-body-er nil i-large-integer)))
(defun-*1* i-large-integer ()
(throw-raw-ev-fncall '(ev-fncall-null-body-er nil i-large-integer)))
)
(defun-one-output macroexpand1! (x)
(mv-let (erp val state)
(macroexpand1 x 'oneify *the-live-state*)
(declare (ignore erp state))
val))
(defvar *acl2-gentemp-counter* 0)
(defun-one-output acl2-gentemp (root)
(let ((acl2-pkg (find-package "ACL2")))
(loop
(let ((name (coerce (packn1 (list root *acl2-gentemp-counter*)) 'string)))
(if (not (find-symbol name acl2-pkg))
(return (let ((ans (intern name acl2-pkg)))
; See comment in intern-in-package-of-symbol for an explanation of this trick.
ans))
(incf *acl2-gentemp-counter*))))))
(mutual-recursion
(defun-one-output oneify-flet-bindings (alist fns w)
; We throw away all type declarations. If we were to keep a type declaration
; (satisfies fn), we would have to find it and convert it (at least in general)
; to (satisfies *1*fn). By ignoring such declarations, we may allow a function
; to avoid a guard violation that we might have expected, for example:
; (flet ((foo (x) (declare (type integer x)) x)) 'a)
; This is however perfectly OK, provided we are clear that flet type
; declarations are only relevant for guard verification, not guard checking.
(cond ((endp alist) nil)
(t (cons (let* ((def (car alist))
(dcls (append-lst
(strip-cdrs (remove-strings (butlast (cddr def)
1)))))
(ignore-vars (ignore-vars dcls))
(oneified-body (oneify (car (last def)) fns w)))
(list* (*1*-symbol (car def))
(cadr def)
(if ignore-vars
(list `(declare (ignore ,@ignore-vars))
oneified-body)
(list oneified-body))))
(oneify-flet-bindings (cdr alist) fns w)))))
(defun-one-output oneify (x fns w)
; Keep this function in sync with translate11. Errors have generally been
; removed, since we know they can't occur.
; Fns is a list of fns that have been flet-bound. It is important not to treat
; any of these as macros.
(cond
((or (atom x) (eq (car x) 'quote))
(cond ((keywordp x)
(kwote x))
((symbolp x)
; At one time we returned (defined-constant x w) here in the case that
; (legal-constantp1 x). But when the constant is replaced by its value, we can
; wind up with slow array accesses, since the constant and the written-out
; value need not be EQ.
x)
((atom x) (kwote x))
(t x)))
((not (symbolp (car x)))
(oneify
(list* 'let (listlis (cadr (car x))
(cdr x))
(cddr (car x)))
fns
w))
((eq (car x) 'return-last)
; Warning: Keep this in sync with stobj-let-fn and the handling of stobj-let in
; this function, in particular the case in which stobj-let-fn generates a call
; of prog2$.
(let* ((qfn (and (consp (cdr x))
(cadr x)))
(fn (or (and (consp qfn)
(eq (car qfn) 'quote)
(consp (cdr qfn))
(cadr qfn))
'progn)))
(cond ((eq fn 'ec-call1-raw)
; In the case of ec-call1-raw, we are already oneifying the last argument -- we
; don't want to call return-last on top of that, or we'll be attempting to take
; the *1*-symbol of the *1*-symbol!
(oneify (car (last x)) fns w))
((eq fn 'mbe1-raw)
; See the discussion in (defun-*1* return-last ...).
(let ((oneified-last (oneify (car (last x)) fns w)))
`(if (f-get-global 'safe-mode *the-live-state*)
(,(*1*-symbol 'return-last)
,qfn
,(oneify (caddr x) fns w)
,oneified-last)
,oneified-last)))
(t
; Since fn is not 'ec-call1-raw, the guard of return-last is automatically met
; for the arguments.
(let ((args (oneify-lst (cddr x) fns w)))
(cons fn args))))))
((or (member-eq (car x) *oneify-primitives*)
; Note that safe-mode for make-event will require addition of the following two
; lines:
; (member-eq (car x) (primitive-event-macros))
; (assoc-eq (car x) *super-defun-wart-table*)
(member-eq (car x) *macros-for-nonexpansion-in-raw-lisp*))
(let ((args (oneify-lst (cdr x) fns w)))
(cons (car x) args)))
((eq (car x) 'mv-let)
(let ((value-form (oneify (caddr x) fns w))
(body-form (oneify (car (last x)) fns w)))
`(mv-let ,(cadr x)
,value-form
; We leave the DECLAREs in place so that the compiler can see the
; IGNOREs at least.
,@(butlast (cdddr x) 1)
,body-form)))
; Feb 8, 1995. Once upon a time we had the following code here:
; ((eq (car x) 'the)
; (let ((value-form (oneify (caddr x) w)))
; `(the ,(cadr x) ,value-form)))
; But that led to garbage for a user defined function like
; (defun foo (x) (declare (xargs :verify-guards nil)) (the integer x))
; because (foo 3) = 3 but (foo t) would cause a hard error. We now
; just macroexpand the just like we would any other macro. We are not
; sure why we ever thought we could handle it any other way.
((eq (car x) 'flet) ; (flet ((fn1 ...) (fn2 ...) ...) declare-form* body)
(list 'flet
(oneify-flet-bindings (cadr x) fns w)
(oneify (car (last x)) (union-eq (strip-cars (cadr x)) fns) w)))
((eq (car x) 'translate-and-test)
(oneify (caddr x) fns w))
((eq (car x) 'with-local-stobj)
(mv-let (erp st mv-let-form creator)
(parse-with-local-stobj (cdr x))
(declare (ignore erp)) ; should be nil
(mv-let-for-with-local-stobj mv-let-form st creator fns w)))
((eq (car x) 'stobj-let)
; Stobj-let is rather complicated, so we prefer to take advantage of the logic
; code for that macro. However, bindings of live stobjs vars may be necessary
; so that when we call a traced function on a live stobj that was stobj-let
; bound, then stobj-print-symbol can print the "{instance}" suffix, as it
; should. The easiest way to code that seems to be to go ahead and use the
; logical macroexpansion of stobj-let, and then fix it up with suitable
; bindings.
(let ((temp (oneify (stobj-let-fn x)
fns w)))
(case-match temp
; Warning: Keep these cases in sync with stobj-let-fn.
(('let bindings . rest)
`(let* ,(append bindings
(the-maybe-live-var-bindings (strip-cars bindings)))
,@rest))
(('progn conjoined-no-dups-exprs
('let bindings . rest))
; Warning: Keep this case in sync with the definition of (prog2$ x y) as
; (return-last 'progn x y), and in sync with the handling of such a return-last
; form by oneify.
`(progn ,conjoined-no-dups-exprs
(let* ,(append bindings
(the-maybe-live-var-bindings
(strip-cars bindings)))
,@rest)))
(& (interface-er "Implementation error: unexpected form of stobj-let ~
encountered by ~
oneify!.~|~%Input:~|~y0~%Output:~|~y1~%Please ~
contact the ACL2 implementors."
x temp)))))
((member-eq (car x) '(let #+acl2-par plet))
(let* (#+acl2-par (granularity-decl (and (eq (car x) 'plet)
(eq (car (cadr x)) 'declare)
(cadr x)))
(args #+acl2-par (if granularity-decl (cddr x) (cdr x))
#-acl2-par (cdr x))
(bindings (car args))
(post-bindings (cdr args))
(value-forms (oneify-lst (strip-cadrs bindings) fns w))
(body-form (oneify (car (last post-bindings)) fns w)))
`(,(car x)
#+acl2-par
,@(and granularity-decl
`((declare (granularity
,(oneify (cadr (cadr (cadr x))) fns w)))))
,(listlis (strip-cars bindings)
value-forms)
,@(butlast post-bindings 1)
,body-form)))
#+acl2-par
((member-eq (car x) '(pand por pargs))
(if (declare-granularity-p (cadr x))
(list* (car x)
`(declare (granularity ,(oneify (cadr (cadr (cadr x))) fns w)))
(oneify-lst (cddr x) fns w))
(cons (car x)
(oneify-lst (cdr x) fns w))))
((eq (car x) 'throw-or-attach) ; already handled in oneify-cltl-code
(interface-er
"Implementation error: Unexpected call of throw-or-attach in oneify:~%~x0"
x))
((and (getprop (car x) 'macro-body nil 'current-acl2-world w)
(not (member-eq (car x) fns)))
(oneify (macroexpand1! x) fns w))
((eq (car x) 'wormhole-eval)
; We know that in a well-formed term (wormhole-eval x y z), x is a quoted
; constant naming the wormhole, y is a quoted lambda of either the form (lambda
; (whs) body) or (lambda () body) that will be applied to the wormhole status,
; and z is some well-formed (irrelevant) term. The oneify of a quote is
; itself, so we don't have to do anything to x. But with y, we oneify the
; lambda body. The ``call'' of wormhole-eval laid down below is a reference to
; the macro definition for that symbol in raw Lisp.
(let* ((qname (cadr x))
(qlambda (caddr x))
(formals (cadr (cadr qlambda)))
(body (caddr (cadr qlambda))))
(list 'wormhole-eval
qname
(list 'quote (list 'lambda formals (oneify body fns w)))
*nil*)))
(t
(let ((arg-forms (oneify-lst (cdr x) fns w)))
(cons (*1*-symbol (car x)) arg-forms)))))
(defun-one-output oneify-lst (lst fns w)
(cond ((atom lst) nil)
(t (let ((x (oneify (car lst) fns w))
(y (oneify-lst (cdr lst) fns w)))
(cons x y)))))
)
(defun-one-output select-stobj (name stobjs terms)
(cond ((endp stobjs) nil)
((eq name (car stobjs)) (car terms))
(t (select-stobj name (cdr stobjs) (cdr terms)))))
(defun-one-output super-defstobj-wart-stobjs-in (formals stobj-flag)
(cond ((endp formals) nil)
((eq (car formals) stobj-flag)
(cons stobj-flag
(super-defstobj-wart-stobjs-in (cdr formals) stobj-flag)))
(t (cons nil
(super-defstobj-wart-stobjs-in (cdr formals) stobj-flag)))))
(defun-one-output oneify-fail-form (er-type fn formals guard super-stobjs-in
wrld extra)
; Warning: If you change this code, see the comment about "When changing
; oneify-fail-form" in oneify-cltl-code.
`(throw-raw-ev-fncall
(list ',er-type
',fn
(list ,@formals)
',guard
',(or super-stobjs-in
(stobjs-in fn wrld)
(if formals
(er hard 'oneify-cltl-code
"I didn't think this could happen, but for fn = ~x0 ~
stobjs-in is nil and formals isn't."
fn)
nil))
,extra)))
(defun-one-output get-declared-stobjs (edcls)
; Keep this in sync with get-declared-stobj-names (which does checking and
; returns a value triple).
(if (endp edcls)
nil
(union-eq (and (eq (caar edcls) 'xargs)
(let ((stobjs (cadr (assoc-keyword :STOBJS (cdar edcls)))))
(cond ((symbol-listp stobjs) stobjs)
((and stobjs (symbolp stobjs)) (list stobjs))
(t nil))))
(get-declared-stobjs (cdr edcls)))))
(defun-one-output warn-for-guard-body (fn)
(assert$ (boundp '*raw-guard-warningp*)
(setq *raw-guard-warningp* nil))
(let ((state *the-live-state*))
(warning$ 'top-level "Guards"
"Guard-checking will be inhibited on recursive calls of the ~
executable counterpart (i.e., in the ACL2 logic) of ~x0. To ~
check guards on all recursive calls:~% (set-guard-checking ~
:all)~%To leave behavior unchanged except for inhibiting this ~
message:~% (set-guard-checking :nowarn)"
fn)))
(defun-one-output create-live-user-stobjp-test (stobjs)
(if (endp stobjs)
t
(let* ((stj (car stobjs))
(rst (create-live-user-stobjp-test (cdr stobjs)))
(tst `(live-stobjp ,stj)))
(cond ((eq stj 'state) rst)
((eq rst t) tst)
(t `(and ,tst ,rst))))))
(defun oneify-cltl-code (defun-mode def stobj-flag wrld
&optional trace-rec-for-none)
; Warning: Keep this in sync with intro-udf-lst2 for the case that defun-mode
; is nil (i.e., the non-executable case).
; This function is called when add-trip encounters a 'cltl-command triple,
; which is laid down by install-event after the triple for the symbol-class is
; laid down. Thus, the symbol-class for the function at hand has already been
; stored. Stobj-flag is the name of the stobj (whether from defstobj or
; defabsstobj), if any, that the given definition supports.
; See the template above for detailed comments, which however are not
; necessarily kept fully up-to-date.
(when (and stobj-flag (null (cadr def)))
; We want to know if (car def) is a stobj creator, but it is premature to call
; stobj-creatorp using wrld because the necessary properties have not yet been
; laid down. So we use the test above. Keep this null test in sync with the
; one in stobj-creatorp.
(return-from oneify-cltl-code
`(,(*1*-symbol (car def)) nil
(throw-raw-ev-fncall ; as in oneify-fail-form
(list 'ev-fncall-creator-er ',(car def))))))
(when (null defun-mode)
; We have a non-executable function, where def is generated by intro-udf-lst2.
; Suppose an attachment is to be invoked. In the :non-executable :program case
; (i.e., ``proxy'' case, as in defproxy), we pass control to the *1* function
; for the attachment, since :skip-checks t is specified not to do any checking
; in this case (see :DOC defproxy). Otherwise, we proceed as though all checks
; have been made (again, see :DOC defproxy), in particular going straight to
; the raw Lisp function if we see that the guard is t, since then the guard of
; the attachment is also presumably true.
(return-from oneify-cltl-code
(case-match def
((fn formals ('declare ('xargs ':non-executable ':program))
('throw-or-attach fn formals))
`(,(*1*-symbol fn)
,formals
(throw-or-attach ,fn ,formals t)))
((fn formals ('declare ('xargs ':guard guard))
('throw-or-attach fn formals))
`(,(*1*-symbol fn)
,formals
,(cond ((or (eq guard t)
(equal guard *t*))
(car (last def)))
(t
`(throw-or-attach ,fn ,formals t)))))
((fn formals
('throw-or-attach fn formals)) ; implicit :guard of t
(prog2$ formals ; avoid compiler warning
`(,(*1*-symbol fn) ,@(cdr def))))
((fn formals
('throw-without-attach 'nil fn formals))
(prog2$ formals ; avoid compiler warning
`(,(*1*-symbol fn) ,@(cdr def))))
(& (interface-er
"Implementation error: Oneify-cltl-code encountered ~
non-executable definition, ~x0, that was not what we ~
would expect to be generated by intro-udf-lst2."
def)))))
(let* ((dcls
(append-lst (strip-cdrs (remove-strings (butlast (cddr def) 1)))))
(split-types (get-unambiguous-xargs-flg1/edcls1
:split-types
*unspecified-xarg-value*
dcls
"irrelevant-error-string"))
(guards (get-guards1
dcls
(cond ((or (equal split-types
*unspecified-xarg-value*) ; default
(eq split-types nil))
'(guards types))
(t (assert$ (eq split-types t)
; By the time we get here, we have already done our checks for the defun,
; including the check that split-types above is not an error message, and is
; Boolean. So if the assertion just above fails, then something has gone
; terribly wrong!
'(guards))))
wrld))
(guard (cond ((null guards) t)
((null (cdr guards)) (car guards))
(t (cons 'and guards))))
(guard-is-t (and (or (eq guard t)
(equal guard *t*))
; If stobj-flag is true, normally the guard will not be t because it will
; include a corresponding stobj recognizer call. But the guard could be t in
; the case of a function exported by a defabsstobj, where the guard is derived
; from the :logic function specified for that export. We want to avoid the
; optimization of defining the *1* function to call the raw Lisp function in
; this case, so that appropriate live stobj checks can be made.
(not (and stobj-flag
; But is it an abstract concrete stobj?
(getprop stobj-flag 'absstobj-info nil
'current-acl2-world wrld)))))
(fn (car def))
(*1*fn (*1*-symbol fn))
(cl-compliant-p-optimization
(and (eq (symbol-class fn wrld) :common-lisp-compliant)
(assert$ (eq defun-mode :logic) t)))
(formals (cadr def))
(boot-strap-p (global-val 'boot-strap-flg (w *the-live-state*))))
(cond
((or (and guard-is-t cl-compliant-p-optimization)
(and boot-strap-p ; optimization (well, except for :redef)
(member-eq fn
'(thm-fn
make-event-fn
certify-book-fn
; Keep the following in sync with primitive-event-macros.
defun-fn
;; #+:non-standard-analysis
;; defun-std ; defun-fn
defuns-fn ; mutual-recursion
;; defuns ; calls defuns-fn, above
defthm-fn
;; #+:non-standard-analysis
;; defthm-std ; calls defthm-fn, above
defaxiom-fn
defconst-fn
defstobj-fn defabsstobj-fn
defpkg-fn
deflabel-fn
defdoc-fn
deftheory-fn
defchoose-fn
verify-guards-fn
defmacro-fn
in-theory-fn
in-arithmetic-theory-fn
regenerate-tau-database-fn
push-untouchable-fn
remove-untouchable-fn
reset-prehistory-fn
set-body-fn
table-fn
progn-fn
encapsulate-fn
include-book-fn
add-include-book-dir-fn
delete-include-book-dir-fn
comp-fn
verify-termination-fn
verify-termination-boot-strap-fn
;; add-match-free-override ; should be fast enough
; Theory-invariant is included in *macros-for-nonexpansion-in-raw-lisp*. The
; remaining members of primitive-event-macros, after theory-invariant, are
; handled well enough already since we included table-fn above.
))))
; Optimization in a common case: avoid labels function. Note that if the guard
; is t then there are no stobjs except for the recognizer, whose raw Lisp code
; can handle non-live stobjs.
`(,*1*fn
,formals
,(cons fn formals)))
(t
(let* ((*1*guard (oneify guard nil wrld))
; We throw away most declararations and the doc string, keeping only ignore and
; ignorable declarations. Note that it is quite reasonable to ignore
; declarations when constructing ``slow'' functions.
(body (car (last def)))
(*1*body
; WARNING! We need to be very careful that we only use *1*body in an
; environment where *1*fn refers to the top-level function currently being
; defined. We should not use *1*body in the scope of a top-level flet or
; labels that rebinds *1*fn, since recursive calls there of *1*fn are
; presumably intended to refer to the top-level function, not the local
; function, so that guards can be checked etc. We can, however, use *1*body in
; the binding of such a local definition. We will be free to use *1*body in
; the body of the top-level definition of *1*fn in the case of :program mode
; because we promise not to introduce a top-level flet in that case.
(oneify body nil wrld))
(super-stobjs-in ; At a "leaf" of a stobj-based computation?
(if stobj-flag
; Then we are looking at a function introduced by a defstobj or defabsstobj
; event.
(let ((temp (super-defstobj-wart-stobjs-in formals
stobj-flag)))
(cond ((find-first-non-nil temp)
temp)
(t nil)))
; Else see if we are looking at a function that takes state but has logic code
; that does not handle a live state properly (and not just because of calls to
; lower-level functions with that problem).
(cdr (assoc-eq fn *super-defun-wart-stobjs-in-alist*))))
(ignore-vars
; If super-stobjs-in is non-nil, then we will lay down a call (oneify-fail-form
; ... :live-stobj) that refers to all the formals; hence ignore-vars should be
; nil if super-stobjs-in is non-nil. When changing oneify-fail-form, consider
; changing this code as well.
(and (not super-stobjs-in) (ignore-vars dcls)))
(ignorable-vars (ignorable-vars dcls))
(guard-checking-on-form
; Functions in the ev-rec nest have a gc-off parameter that we generally assume
; to correspond with the state global guard-checking-on used here, so that the
; logic-only and raw lisp code agree. See the comment in *ev-shortcut-okp*.
(cond (super-stobjs-in
'(let ((temp (f-get-global 'guard-checking-on
*the-live-state*)))
(cond ((or (eq temp :none) (eq temp nil))
; Calls of a stobj primitive that takes its stobj as an argument are always
; guard-checked. If that changes, consider also changing
; ev-fncall-rec-logical.
t)
(t temp))))
(t '(f-get-global 'guard-checking-on *the-live-state*))))
(skip-early-exit-code-when-none
(and (eq defun-mode :logic) ; :program handled elsewhere
; We generally skip some special "early exit" code when 'guard-checking-on has
; value :none. But it seems scary to allow :none to avoid raw Lisp for
; built-ins, even in :logic mode, because of efficiency. So when we are in the
; boot-strap, we do the early exit code (which can call the raw Lisp function)
; even if 'guard-checking-on has value :none. Exception: We want the-check to
; avoid guard errors when 'guard-checking-on has value :none.
(or (not boot-strap-p)
(eq fn 'the-check))))
(guard-checking-is-really-on-form
; This variable should only be used in the scope of the binding expression for
; early-exit-form.
(cond (super-stobjs-in
; The value of guard-checking-on has already been coerced from :none or nil to
; t, in guard-checking-on-form.
t)
(skip-early-exit-code-when-none
; As mentioned above, guard-checking-is-really-on-form is only used for
; defining early-exit-form. But evaluation of early-exit-form is skipped when
; 'guard-checking-on has value :none in the present case, where
; skip-early-exit-code-when-none is true.
guard-checking-on-form)
(t `(and ,guard-checking-on-form
(not (eq ,guard-checking-on-form :none))))))
(fail_guard ; form for reporting guard failure
(oneify-fail-form
'ev-fncall-guard-er fn formals guard super-stobjs-in wrld
(and super-stobjs-in
'(cond ((member-eq (f-get-global 'guard-checking-on
*the-live-state*)
'(nil :none))
:live-stobj)
(t
; Suppress "See :DOC set-guard-checking" printed by ev-fncall-guard-er-msg.
:no-extra)))))
(fail_safe ; form for reporting guard or safe mode failure
(oneify-fail-form 'ev-fncall-guard-er fn formals guard
super-stobjs-in wrld t))
(safe-form
; Functions in the ev-rec nest have a safe-mode parameter that we generally
; assume to agree with the state global safe-mode, so that the logic-only and
; raw lisp code agree. See the comment in *ev-shortcut-okp*.
'(f-get-global 'safe-mode *the-live-state*))
(super-stobjs-chk
(if stobj-flag
(let ((first-non-nil (find-first-non-nil super-stobjs-in)))
`(live-stobjp ,first-non-nil))
`(live-state-p
,(select-stobj 'state super-stobjs-in formals))))
(declared-stobjs (if stobj-flag
(list stobj-flag)
(get-declared-stobjs dcls)))
(user-stobj-is-arg (and declared-stobjs
(not (equal declared-stobjs '(state)))))
(live-stobjp-test (create-live-user-stobjp-test declared-stobjs))
(declare-stobj-special
; Without a special declaration for the live stobj, a defstobj or defabsstobj
; event will introduce *1* functions in add-trip, via a defuns trip, before the
; defstobj or defabsstobj trip introduces the live stobj variable as special.
; This might not be a big deal unless we compile, by which time (at the end of
; processing the defstobj or defabsstobj trip) the live stobj variable has been
; introduced with defparameter, thus globally declaring it special. However,
; CCL complains because compilation is done when the *1* function is first
; introduced. It seems appropriate to declare the live stobj variable special
; as soon as it is referenced, in such *1* functions, even though CCL might be
; the only Lisp that could need this done.
(and stobj-flag
`(declare (special ,(the-live-var stobj-flag)))))
(guarded-primitive-p
; We want to check guards on the "leaves" of a computation in safe-mode, for
; example, on a call of EQ. Evaluation in the ACL2 logic can only diverge from
; evaluation in (raw) Common Lisp when a guard is violated on a function that
; is already defined in Common Lisp. A function considered here that is at
; risk for such divergence has a non-T guard, is being defined in the
; boot-strap, and is not in the ACL2 package (which is unknown to Common Lisp).
; So as we generate code here, we restrict the additional guard-check in
; safe-mode to such functions.
(and (not guard-is-t) ; we are trusting guards on the primitives!
boot-strap-p
(not (member-equal (symbol-package-name fn)
'("ACL2" "ACL2-PC")))))
(*1*fn-binding `(,*1*fn
,formals
,@(and declare-stobj-special
(list declare-stobj-special))
,@(and ignore-vars
`((declare (ignore ,@ignore-vars))))
,@(and ignorable-vars
`((declare (ignorable ,@ignorable-vars))))
,@(and super-stobjs-in
; If the form below is removed, we might expect to get a hard Lisp error from
; the following:
; (defstobj foo (arr :type (array t (10))))
; (set-guard-checking nil)
; (update-arri 20 4 foo)
; The problem would seem to be that an ill-guarded call of update-nth has
; replaced a copy of the stobj array by a list in (user-stobj-alist
; *the-live-state*), which produces a mismatch with *the-live-foo*.
; However, no such error occurs. At some point we may spend the energy to
; convince ourselves that it is safe to remove this code, but for now, it seems
; harmless enough to leave it here, since super-stobjs-chk is a fast test.
`((when ,super-stobjs-chk
,(oneify-fail-form
'ev-fncall-guard-er fn formals
guard super-stobjs-in wrld
:live-stobj))))
,*1*body))
(*1*-labels-form `(labels (,*1*fn-binding)
(,*1*fn ,@formals)))
(logic-recursive-p
(and (eq defun-mode :logic)
(ffnnamep-mod-mbe fn (body fn nil wrld))))
(labels-can-miss-guard
(and logic-recursive-p ; there is no labels form for :program
; If the function is common-lisp-compliant, then the only way we can fall
; through to the labels form is if guard-checking is nil or :none (not :all),
; in which case there is no reason to warn.
(not cl-compliant-p-optimization)
(not guard-is-t)))
(trace-rec-for-none
; If trace-rec-for-none is non-nil, then we guarantee that if
; 'guard-checking-on is set to :none, we will see all the recursive calls.
; This is useful for tracing. Extra code for this case is only necessary for
; :logic mode, since the only issue is the call of a labels function, which
; only occurs in :logic mode.
(and trace-rec-for-none
logic-recursive-p
(eq defun-mode :logic)))
(program-only (and (eq defun-mode :program) ; optimization
(member-eq fn
; If this test becomes an issue, we might consider reimplementing the
; program-only mechanism by way of :program-only xargs, which would place a
; property that we can look up. Careful though -- at this point we probably
; have not yet installed a world with all the new properties of fn.
(f-get-global
'program-fns-with-raw-code
*the-live-state*))))
(fail_program-only-safe
; At one time we put down a form here that throws to the tag 'raw-ev-fncall:
; (oneify-fail-form 'program-only-er fn formals guard
; super-stobjs-in wrld
; t)
; However, because that throw is caught (in the function raw-ev-fncall), it
; should be accounted for in the function ev-fncall-rec-logical. However, that
; function does not take state, which is unfortunate since the program-only
; case (under which we lay down this form) is based on state global
; 'program-fns-with-raw-code. We considered moving that global to the world,
; but were concerned about the effects that would have on ACL2s (see for
; example the use of program-fns-with-raw-code in
; workshops/2007/dillinger-et-al/code/hacker.lisp), and in general we'd have to
; add yet another event and deal with whether the event should be local to
; books. Instead, we have decided to cause a raw Lisp error, which is always
; legitimate (after all, Lisp might cause a resource error).
`(error "~%~a~%"
(fms-to-string
"~@0~%~@1"
(list (cons #\0 (program-only-er-msg
',fn (list ,@formals) t))
(cons #\1 "~%Note: If you have a reason to ~
prefer an ACL2 error here instead of ~
a hard Lisp error, please contact the ~
ACL2 implementors."))
:evisc-tuple
(abbrev-evisc-tuple *the-live-state*)
:fmt-control-alist
(list (cons 'fmt-hard-right-margin
(f-get-global 'fmt-hard-right-margin
*the-live-state*))
(cons 'fmt-soft-right-margin
(f-get-global 'fmt-soft-right-margin
*the-live-state*))))))
(early-exit-code
(let ((cl-compliant-code-guard-not-t
; We lay down code for the common-lisp-compliant case that checks the guard and
; acts accordingly: if the guard checks, then it returns the result of calling
; fn, and if not, then it fails if appropriate and otherwise falls through.
(and
(not guard-is-t) ; optimization for code below
; NOTE: we have to test for live stobjs before we evaluate the guard, since the
; Common Lisp guard may assume all stobjs are live. We actually only need
; stobjs to be live that occur in the guard in other than stobj recognizer
; calls; but we take the easy way out (except for a stobj-flag case below) and
; check that all stobjs are live before evaluating the raw Lisp guard. After
; all, the cost of that check is only some eq tests.
`(cond
,(cond
((eq live-stobjp-test t)
`(,guard
(return-from ,*1*fn (,fn ,@formals))))
(t
`((if ,live-stobjp-test
,(if stobj-flag
; Essay on Stobj Guard Attachments
; We disallow attachments during evaluation of guards on behalf of any stobj
; updater. The example below, which is a slight modification of one provided
; by Jared Davis, shows why this is important for defstobj. The idea is that
; in order to preserve the invariant that the stobj recognizer holds, it
; suffices that the initial stobj satisfies that recognizer and that the guard
; holds for each call of an updater. But suppose for example that an
; attachment is used in evaluating the guard for the first update. If later
; (perhaps after many more updates) we change that attachment, then that guard
; now may be false, and thus the recognizer may fail to hold after the first
; update and thus fail to hold currently. On the other hand, if such guard
; evaluation never involves attachments, then since the initial stobj provably
; satisfies the recognizer, then since each updater guard holds (in fact,
; provably holds), the resulting stobjs all satisfy the recognizer.
; The discussion above applies not only in the case of defstobj but also in the
; case of defabsstobj. Consider an abstract function exported from a
; defabsstobj event that updates a stobj. The avoidance of attachments
; guarantees that every abstract stobj update satisfies the abstract function's
; guard and hence, by the {preserved} theorems, results in an abstract stobj
; that satisfies the abstract predicate -- provably, since we are dealing with
; ground terms. Moreover, because of the {guard-thm} theorems we know that the
; concrete predicate provably holds as well, and hence won't be "revoked" as in
; the preceding paragraph.
; Why do we care about guards on concrete stobjs? For all we know, failure to
; respect those guards could result in corruption of the Lisp process. An
; obvious case would be if a stobj field is an array of bits, laid out
; compactly according to that spec, and we update with an arbitrary object
; (say, a cons). Although it seems that only a SATISFIES type declaration
; could result in a attachments being used for guard evaluation, we are
; conservative here. After all, adding a binding of *aokp* is cheap in the
; context of evaluating just the guard.
; Note that it is not sufficient to ensure for an abstract stobj that the
; corresponding concrete stobj always satisfies its recognizer. It is easy to
; imagine a defabsstobj :export field that specifies the identify function for
; its :logic component, returning the stobj unchanged, but for the :exec
; component makes an ill-guarded call to update the stobj, corrupting the Lisp
; imagine, before restoring the stobj. In raw Lisp, this could really happen
; because the export is a macro that calls the :exec function directly; the
; only guard that need be met before this happens is a variant of the :logic
; function's guard, at the level of *1* function of the export.
; Finally, here is the example promised above.
; (progn
; (defstub foop (x) t)
; (defun barp (x)
; (declare (xargs :guard t))
; (or (not x)
; (foop x)))
; (defstobj st
; (fld :type (satisfies barp)))
; (defthm barp-of-fld
; (implies (stp st)
; (barp (fld st))))
; (defun my-integerp (x)
; (declare (xargs :guard t))
; (integerp x)))
; (defattach foop my-integerp)
; (trace$ foop barp my-integerp)
; (update-fld 3 st) ; note that foop calls its attachment, my-integerp
; (defattach foop consp)
; (barp (fld st)) ; nil (ouch)
; (stp st) ; returns t, but is really (logically) nil
; The code just below ensures that the updater will be evaluated without
; attachments. It might needlessly ensure that other functions introduced by
; defstobj (for the given stobj-flag) are evaluated without attachments, for
; example if the getprop below returns nil because the necessary property has
; not yet been put into wrld. But as of this writing, the test seems to apply
; only to stobj updaters and resize functions.
(let ((stobjs-out
(getprop
fn
'stobjs-out
nil
'current-acl2-world
wrld)))
(cond
((and stobjs-out ; property is there
(all-nils stobjs-out))
guard)
(t `(let ((*aokp* nil))
,guard))))
guard)
,*1*guard)
,(assert$
; No user-stobj-based functions are primitives for which we need to give
; special consideration to safe-mode.
(not guarded-primitive-p)
`(cond (,live-stobjp-test
(return-from ,*1*fn
(,fn ,@formals))))))))
,@(cond (super-stobjs-in
`((t ,fail_guard)))
(guarded-primitive-p
`(((or ,guard-checking-is-really-on-form
,safe-form)
,fail_safe)))
(t
`((,guard-checking-is-really-on-form
,fail_guard))))))))
(if cl-compliant-p-optimization
(assert$ (not guard-is-t) ; already handled way above
(list cl-compliant-code-guard-not-t))
(let ((cond-clauses
`(,@(and (eq defun-mode :logic)
; If the guard is t, then we want to execute the raw Lisp code in the
; :common-lisp-compliant case even if guard-checking is :none. This
; early-exit-code is only executed when guard-checking is not :none, so
; we need to handle that special case (:none, guard t) elsewhere, and
; we do so in *1*-body-forms below.
(not guard-is-t)
`(((eq (symbol-class ',fn (w *the-live-state*))
:common-lisp-compliant)
,cl-compliant-code-guard-not-t)))
,@(and (not guard-is-t)
(cond
(super-stobjs-in
`(((not ,*1*guard)
,fail_guard)))
(guarded-primitive-p
`(((and (or ,safe-form
,guard-checking-is-really-on-form)
(not ,*1*guard))
,fail_safe)))
(t
`(((and ,guard-checking-is-really-on-form
(not ,*1*guard))
,fail_guard)))))
,@(cond
((eq defun-mode :program)
; In the boot-strap world we have :program mode functions whose definitions are
; different in raw Lisp from the logic, such as ev and get-global. If we allow
; :all or :none to serve their purposes for those functions, we can wind up
; with unpleasant guard violations. For example, wet (when we had it) expanded
; to a call of with-error-trace-fn, and if the idea of :all is applied then we
; get the following sequence of calls in the logic (i.e., using their *1*
; functions): with-error-trace-fn, trans-eval, ev, ev-rec, ev-fncall-rec,
; ev-fncall-rec-logical, w-of-any-state, and finally global-table. The last of
; these calls causes a guard violation since *the-live-state* is not a true
; list.
; Also, we want to make sure that built-in :program mode functions run fast,
; for example, defthm-fn.
; And finally, this is where we finish handling of safe-mode for
; guarded-primitive-p functions, specifically those in :program mode since if
; such a function is in :logic mode then either it is non-executable or
; :common-lisp-compliant (see check-none-ideal), hence is handled above.
(cond
(boot-strap-p
`((,safe-form
,(cond
(program-only
fail_program-only-safe)
(t
`(return-from ,*1*fn ,*1*body))))))
(t
(cond
(program-only
`((,safe-form
,fail_program-only-safe)
((member-eq ,guard-checking-on-form
'(:none :all))
(return-from ,*1*fn ,*1*body))))
; We will not be laying down a labels call, so we go ahead and stay in the *1*
; world here in the case of safe-mode.
(t `(((or (member-eq ,guard-checking-on-form
'(:none :all))
,safe-form)
(return-from ,*1*fn ,*1*body))))))))))))
(and cond-clauses
(list (cons 'cond cond-clauses)))))))
(main-body-before-final-call
; This is the code that is executed before we fall through: to the final labels
; function in the :logic mode case, but to the non-*1* call in the :program
; mode case.
(append
(and user-stobj-is-arg
`((when *wormholep*
(wormhole-er (quote ,fn) (list ,@formals)))))
(and (eq defun-mode :logic) ; else :program
guard-is-t
(assert$ ; compliant with guard t is handled early above
(not cl-compliant-p-optimization)
`((when (eq (symbol-class ',fn (w *the-live-state*))
:common-lisp-compliant)
(return-from ,*1*fn (,fn ,@formals))))))
(cond ((and skip-early-exit-code-when-none
early-exit-code) ; else nil; next case provides nil
(cond (super-stobjs-in early-exit-code) ; optimization
(t `((when (not (eq ,guard-checking-on-form :none))
,@early-exit-code)))))
(t early-exit-code))
(cond (trace-rec-for-none
`((return-from ,*1*fn ,*1*body)))
(labels-can-miss-guard
`((when (eq ,guard-checking-on-form :all)
(return-from ,*1*fn ,*1*body)))))
(and (and labels-can-miss-guard
(not trace-rec-for-none)) ; else skip labels form
`((when (and *raw-guard-warningp*
(eq ,guard-checking-on-form t))
(warn-for-guard-body ',fn))))))
(*1*-body-forms (cond ((eq defun-mode :program)
(append main-body-before-final-call
`((,fn ,@formals))))
(trace-rec-for-none
main-body-before-final-call)
(t
(append main-body-before-final-call
(list *1*-labels-form))))))
`(,*1*fn
,formals
,@(and declare-stobj-special (list declare-stobj-special))
; At one time we attempted to do some code-sharing using a macro call, by using
; *1*body-call in place of *1*body in the code above, where *1*body-call was
; defined as shown below. But with an ACL2 image built on Allegro, for (ld
; "books/rtl/rel4/support/merge.lisp") with (set-inhibit-output-lst '(prove
; proof-tree)) after (prof:start-profiler), it took 127.5 seconds to run such a
; modification of oneify-cltl-code, as opposed to 103.5 seconds. Granted, we
; chose this file because it was shown in some earlier experiments with
; macrolet to have a particularly bad slowdown over previous versions without
; macrolet. But still, we suffer the extra code for recursive :ideal-mode
; functions rather than generate macrolet forms. Below are the relevant
; bindings used in a previous version of this code, in case we decide to
; revisit this approach.
; (*1*body-call-shared-p
;
; ; We want to keep code size down by using macrolet to share the *1*body ;
; ; expression, but preferably not otherwise, to avoid overhead that we seem to ;
; ; have observed, at least in Allegro CL, for expanding (uncompiled) macrolet ;
; ; calls. The expression below should thus agree with the governing conditions ;
; ; for the occurrences of *1*body-call outside the labels function that will ;
; ; also occur in a corresponding labels function. The latter rules out the case ;
; ; (eq defun-mode :program). ;
;
; (ffnnamep fn (body fn nil wrld)))
; (*1*body-macro (and *1*body-call-shared-p
; (acl2-gentemp "*1*BODY-MACRO")))
; (*1*body-call (if *1*body-call-shared-p
; `(,*1*body-macro)
; *1*body))
;
; ;;; end of let* bindings .... and here is the replacement for ,@*1*-body-forms
; ;;; below:
;
; ,@(if *1*body-call-shared-p
; `((macrolet ((,*1*body-macro () ',*1*body))
; ,@*1*-body-forms))
; *1*-body-forms)
,@*1*-body-forms))))))
; PROMPTS
; New ACL2 users sometimes do not notice that they are outside the ACL2
; read-eval-print loop when in a break. We modify the prompts when we see how
; to do so, so that in a break we see "[RAW LISP]" in the prompt. For most
; lisps, this seems to require changing the prompt at the top-level too, not
; just in a break.
(defvar *saved-raw-prompt* nil)
(defvar *saved-raw-prompt-p* nil)
#+allegro
(progn
(defun-one-output install-new-raw-prompt ()
(cond ((not *saved-raw-prompt-p*)
(setq *saved-raw-prompt* tpl:*prompt*)
(setq tpl:*prompt*
(concatenate 'string *saved-raw-prompt* "[RAW LISP] "))
(setq *saved-raw-prompt-p* t))))
(defun-one-output install-old-raw-prompt ()
(cond (*saved-raw-prompt-p*
(setq tpl:*prompt* *saved-raw-prompt*)
(setq *saved-raw-prompt-p* nil)
(setq *saved-raw-prompt* nil) ; no longer needed; free storage
t))))
#+clisp
(progn
(defun-one-output install-new-raw-prompt ()
(cond ((not *saved-raw-prompt-p*)
(setq *saved-raw-prompt* custom::*prompt-body*)
(setq custom::*prompt-body* ; attempt to mimic clisp 2.33
(function
(lambda ()
(if (equal system::*home-package* *package*)
(format nil "[RAW LISP]")
(format nil "~a [RAW LISP]" (package-name *package*))))))
(setq *saved-raw-prompt-p* t))))
(defun-one-output install-old-raw-prompt ()
(cond (*saved-raw-prompt-p*
(setq custom::*prompt-body* *saved-raw-prompt*)
(setq *saved-raw-prompt-p* nil)
(setq *saved-raw-prompt* nil) ; no longer needed; free storage
t))))
#+cmu
(progn
(defun-one-output install-new-raw-prompt ()
(setq debug:*debug-prompt*
(function (lambda ()
(debug::debug-prompt)
(format t "[RAW LISP] ")
(force-output t)))))
(defun-one-output install-old-raw-prompt ()
(setq debug:*debug-prompt*
(function debug::debug-prompt))))
#+ccl
(progn
(defun-one-output install-new-raw-prompt ()
(cond ((not *saved-raw-prompt-p*)
(setq *saved-raw-prompt*
(symbol-function 'ccl::print-listener-prompt))
(let ((ccl:*warn-if-redefine-kernel* nil))
(setf (symbol-function 'ccl::print-listener-prompt)
(lambda (stream &rest args)
(declare (ignore stream))
(apply *saved-raw-prompt* *debug-io* args)
(format *debug-io* "[RAW LISP] "))))
(setq *saved-raw-prompt-p* t))))
(defun-one-output install-old-raw-prompt ()
(cond (*saved-raw-prompt-p*
(let ((ccl:*warn-if-redefine-kernel* nil))
(setf (symbol-function 'ccl::print-listener-prompt)
*saved-raw-prompt*))
(setq *saved-raw-prompt-p* nil)
(setq *saved-raw-prompt* nil) ; no longer needed; free storage
t))))
#+(and gcl (not cltl2))
; We are a bit sorry that we messed around at this low a level, and choose not
; to do so for ANSI GCL.
(progn
(defun-one-output install-new-raw-prompt ()
(cond ((not (and (eql si::*gcl-major-version* 2)
(eql si::*gcl-minor-version* 6)))
(cond (*lp-ever-entered-p*
(er hard 'install-new-raw-prompt
"Install-new-raw-prompt is only supported in GCL 2.6 and ~
its sub-versions. This appears to be a GCL ~s0.~s1."
si::*gcl-major-version*
si::*gcl-minor-version*))
(t (setq *saved-raw-prompt-p* t))))
((not *saved-raw-prompt-p*)
(setq si::*debug-prompt-suffix* "[RAW LISP]")
(setf *saved-raw-prompt* (symbol-function 'si::break-level))
(setf (symbol-function 'si::break-level)
(symbol-function 'si::break-level-for-acl2))
(setq *saved-raw-prompt-p* t))))
(defun-one-output install-old-raw-prompt ()
(cond (*saved-raw-prompt-p*
(setq si::*debug-prompt-suffix* "")
(setf (symbol-function 'si::break-level)
; Since we set si::*debug-prompt-suffix*, we really don't have to revert
; (symbol-function 'si::break-level) -- unless our patch,
; 'si::break-level-for-acl2 is out of sync with the current GCL's
; 'si::break-level. So we play it safe and revert.
*saved-raw-prompt*)
(setq *saved-raw-prompt-p* nil)
(setq *saved-raw-prompt* nil) ; no longer needed; free storage
t))))
#-(or allegro clisp cmu ccl (and gcl (not cltl2)))
(progn
(defun-one-output install-new-raw-prompt ()
nil)
(defun-one-output install-old-raw-prompt ()
nil)
)
; DYNAMICALLY MONITOR REWRITES ("dmr")
;;; User-settable dmr variables
; User settable to any positive number, indicating the number of pushes on the
; gstack before *dmr-file-name* is written.
; If you set this, consider also setting Emacs Lisp variable
; *acl2-timer-display-interval*.
(defvar *dmr-interval* 1000)
(defvar *dmr-interval-acl2-par-hack* 300000)
(defvar *dmr-interval-used*)
; This variable's positive integer value indicates the maximum indentation for
; each line in the display. Lines that otherwise would exceed this indentation
; are instead shown as
; {x} n. ....
; where x is the 0-based indentation depth.
(defvar *dmr-indent-max* 20)
; User settable, but then you need to set *acl2-monitor-buffer-name* and
; *dmr-file-name* in emacs file monitor.el. The main reason to change
; this would be if you are running emacs on a different machine than the one on
; which you are running ACL2.
(defvar *dmr-file-name*)
(defun dmr-file-name ()
(let ((user (or (getenv$-raw "USER")
(progn (format t "Warning: Unable to determine USER ~
environment variable for ~
dmr-file-name.~%Will treat USER as ~
SOME-USER. In emacs, evaluate:~%(setq ~
*dmr-file-name* ~
\"/tmp/acl2-dmr-SOME-USER\")~%")
"SOME-USER"))))
(concatenate 'string "/tmp/acl2-dmr-" user)))
;;; Code implementing dmr in ACL2
(defparameter *dmr-stream*
nil)
(defparameter *dmr-counter*
; For the sake of GCL, we may want to consider consider using a 0-dimensional
; fixnum array instead. If so, then consider whether *dmr-interval* should
; also be similarly changed.
0)
#+acl2-par
(defun dmr-acl2-par-hack-p ()
(f-get-global 'waterfall-parallelism *the-live-state*))
(defun dmr-stop-fn-raw ()
(when *dmr-stream*
(let ((str *dmr-stream*))
(setq *dmr-stream* nil)
(close str))))
(defun initialize-dmr-interval-used ()
(setq *dmr-interval-used*
#+acl2-par
(cond ((dmr-acl2-par-hack-p) *dmr-interval-acl2-par-hack*)
(t *dmr-interval*))
#-acl2-par
*dmr-interval*))
(defun dmr-start-fn-raw (state)
(initialize-dmr-interval-used)
(or (boundp '*dmr-file-name*)
(setq *dmr-file-name* (dmr-file-name)))
(setq *dmr-stream*
(open *dmr-file-name*
:if-exists
:supersede ; :overwrite doesn't open non-existent file in CCL
:direction :output
#+acl2-par :sharing
#+acl2-par :lock ; the default of :private is single-threaded
))
state)
(defvar *dmr-array*
(make-array 10000)) ; start with default length of cw-gstack
(defun reverse-into-dmr-array (lst)
(let ((len-1 (1- (length lst))))
(when (< (length *dmr-array*) len-1)
(setq *dmr-array*
(make-array (* 2 len-1))))
(loop for i from len-1 downto 0
as tail on lst
do (setf (aref *dmr-array* i) (car tail)))
len-1))
(defparameter *dmr-reusable-string*
(make-array '(0)
:element-type
; SBCL and non-ANSI GCL complain about setting the fill-pointer if we use
; 'base-char.
#+(or sbcl (and gcl (not cltl2))) 'character
#-(or sbcl (and gcl (not cltl2))) 'base-char
:fill-pointer 0
:adjustable t))
(defvar *dmr-indent*)
(defmacro dmr-increment-indent ()
'(setq *dmr-indent*
(+ 2 *dmr-indent*)))
(defun tilde-@-bkptr-string (calling-sys-fn called-sys-fn bkptr)
; Warning: Keep this in sync with tilde-@-bkptr-phrase.
; This function builds a ~@ phrase explaining how two adjacent frames
; are related, given the calling sys-fn, the called sys-fn and the
; bkptr supplied by the caller. See cw-gframe for the use of this
; phrase.
; WARNING: This function can have a side effect of setting
; *dmr-indent*. It would be cleaner to use multiple values instead; maybe some
; day when we have time (!) or if someone volunteers.
(case called-sys-fn
(rewrite
(cond ((integerp bkptr)
(cond ((eq calling-sys-fn 'rewrite-with-lemma)
(dmr-increment-indent)
(format nil " the atom of hypothesis ~s" bkptr))
((eq calling-sys-fn 'simplify-clause)
(format nil " the atom of literal ~s" bkptr))
(t (format nil " argument ~s" bkptr))))
((consp bkptr)
(dmr-increment-indent)
(format
nil
" the ~arhs of hypothesis ~s"
(if (eq (car bkptr) 'rhs2) "rewritten " "")
(cdr bkptr)))
((symbolp bkptr)
(case bkptr
(guard " the guard")
(body " the body")
(lambda-body " the lambda body")
(rewritten-body " the rewritten body")
(expansion " the expansion")
(equal-consp-hack-car " the equality of the cars")
(equal-consp-hack-cdr " the equality of the cdrs")
(rhs " the rhs of the conclusion")
(meta " the result of the metafunction")
(nth-update " the result of the nth/update rewriter")
(multiply-alists2 " the product of two polys")
(forced-assumption " a forced assumption")
(proof-checker " proof-checker top level")
(otherwise (er hard 'tilde-@-bkptr-string
"When ~x0 calls ~x1 we get an unrecognized ~
bkptr, ~x2."
calling-sys-fn called-sys-fn bkptr))))
(t (er hard 'tilde-@-bkptr-string
"When ~x0 calls ~x1 we get an unrecognized bkptr, ~x2."
calling-sys-fn called-sys-fn bkptr))))
((rewrite-with-lemma setup-simplify-clause-pot-lst simplify-clause
synp)
"")
(t (er hard 'tilde-@-bkptr-string
"When ~x0 calls ~x1 we get an unrecognized bkptr, ~x2."
calling-sys-fn called-sys-fn bkptr))))
(defvar *dmr-interp-state*
; This tells us whether we have already printed "argument(s)" when printing
; gframes with sys-fn = rewrite.
0)
(defun dmr-interp-fresh-rewrite-p (calling-sys-fn frame)
; Assumes that (access gframe frame :sys-fn) is rewrite.
(not (and (eq calling-sys-fn 'rewrite)
(integerp (access gframe frame :bkptr)))))
(defun dmr-prefix ()
(if (> *dmr-indent* *dmr-indent-max*)
(concatenate 'string
(aref1 'acl2-built-in-spaces-array
*acl2-built-in-spaces-array*
*dmr-indent-max*)
(format nil
"{~s} "
*dmr-indent*))
(aref1 'acl2-built-in-spaces-array
*acl2-built-in-spaces-array*
*dmr-indent*)))
(defun dmr-interp (i calling-sys-fn frame)
; Warning: Keep this in sync with cw-gframe.
; This prints a gframe, frame, which is known to be frame number i and
; was called by calling-sys-fn.
(let ((sys-fn (access gframe frame :sys-fn)))
(case sys-fn
(rewrite
(cond ((dmr-interp-fresh-rewrite-p calling-sys-fn frame)
(setq *dmr-interp-state* 0)
(let ((bkptr-string ; evaluate now, before printing
(tilde-@-bkptr-string calling-sys-fn
'rewrite
(access gframe frame :bkptr))))
(format nil
"~a~s. Rewriting (to ~a)~a"
(dmr-prefix)
i
(let ((obj (cddr (access gframe frame :args))))
(cond ((eq obj nil) "falsify")
((eq obj t) "establish")
(t "simplify")))
bkptr-string)))
((eq *dmr-interp-state* 0)
(setq *dmr-interp-state* 1)
(format nil "; argument(s) ~s" (access gframe frame :bkptr)))
(t
(format nil "|~s" (access gframe frame :bkptr)))))
(rewrite-with-lemma
(format
nil
"~a~s. Applying ~s~%"
(dmr-prefix)
i
(access rewrite-rule (cdr (access gframe frame :args)) :rune)))
(add-terms-and-lemmas
(let ((len (length (car (access gframe frame :args)))))
(format
nil
"~a~s. Applying linear arithmetic to ~a ~s term~a~%"
(dmr-prefix)
i
(let ((obj (cdr (access gframe frame :args))))
(cond ((eq obj nil) "falsify")
((eq obj t) "establish")
(t "simplify")))
len
(if (eql len 1) "" "s"))))
(non-linear-arithmetic
(let ((len (length (access gframe frame :args))))
(format
nil
"~a~s. Applying non-linear arithmetic to ~s var~a~%"
(dmr-prefix)
i
len
(if (eql len 1) "" "s"))))
(synp
(let ((synp-fn (access gframe frame :args)))
(dmr-increment-indent)
(format nil
"~a~s. Entering ~s for hypothesis ~s~%"
(dmr-prefix) i synp-fn (access gframe frame :bkptr))))
(setup-simplify-clause-pot-lst
(format nil "~a~s. Setting up the linear pot list~%" (dmr-prefix) i))
(otherwise
; Note that we leave it to pstk to handle simplify-clause.
(er hard 'dmr-interp
"Unrecognized sys-fn, ~x0"
(access gframe frame :sys-fn))))))
(defvar *dmr-delete-string*
; WARNING: Keep this in sync with monitor.el.
"delete-from-here-to-end-of-buffer")
(defun dmr-string ()
#+acl2-par
(when (dmr-acl2-par-hack-p)
(return-from dmr-string
(print-interesting-parallelism-variables-str)))
(when (null *pstk-stack*)
(setq *dmr-counter* *dmr-interval-used*) ; will flush next time
(setq *saved-deep-gstack* nil)
(setq *deep-gstack* nil)
(return-from dmr-string *dmr-delete-string*))
(setf (fill-pointer *dmr-reusable-string*) 0)
(let* ((pstk-tokens (loop for x in *pstk-stack*
with result = nil
do (push (cond ((eq (car x) 'waterfall)
(car (nthcdr 8 x))) ; ctx
((eq (car x) 'ev-fncall)
(list (car x) (cadr x)))
(t (car x)))
result)
finally (return result))) ; reversed
(pstk-tokens-tail pstk-tokens)
(len-1 (reverse-into-dmr-array *deep-gstack*))
(calling-sys-fn 'start)
(*print-pretty* nil)
(counter 0)
(*dmr-indent* 3)
(no-newline-last-time nil))
(with-output-to-string
(s *dmr-reusable-string*)
(loop for token in pstk-tokens
do
(progn
(setq pstk-tokens-tail (cdr pstk-tokens-tail))
(cond
((member-eq token '(rewrite-atm setup-simplify-clause-pot-lst))
(return))
(t (princ (format nil " ~s. ~s~%" counter token)
s)
(incf counter)))))
(loop for i from 0 to len-1
do (let* ((frame (aref *dmr-array* i))
(sys-fn (access gframe frame :sys-fn)))
(when (not (eq sys-fn 'simplify-clause))
; First, print a newline if we didn't print one last time and we are not
; printing args for sys-fn = rewrite.
(setq no-newline-last-time (eq calling-sys-fn 'rewrite))
(when (and no-newline-last-time ; no newline last time
(or ; not printing args for rewrite
(not (eq sys-fn 'rewrite))
(dmr-interp-fresh-rewrite-p calling-sys-fn
frame)))
(terpri s))
(princ (dmr-interp counter calling-sys-fn frame)
s)
(incf counter))
(setq calling-sys-fn (access gframe frame :sys-fn))))
(when (eq calling-sys-fn 'rewrite) ; no newline last time
(terpri s))
(dmr-increment-indent)
(loop for token in pstk-tokens-tail
; We avoid printing ev-fncall-meta because such a call can invoke mfc-rw,
; creating lower gstack entries, resulting in several ev-fncall-meta tokens
; being printed here (at the bottom of the displayed stack) rather than
; interspersed in the display. Rather than track gstack/pstk interaction, we
; simply avoid printing ev-fncall-meta tokens, though pstk itself does flush
; the display out to file when entering ev-fncall-meta.
when (not (eq token 'ev-fncall-meta))
do
(progn (princ (if (eq token 'add-polynomial-inequalities)
(format nil "~a~s. ~s: ~s calls~%" (dmr-prefix)
counter token *add-polys-counter*)
(format nil "~a~s. ~s~%" (dmr-prefix) counter
token))
s)
(incf counter)))
(princ *dmr-delete-string* s)))
*dmr-reusable-string*)
(declaim (inline dmr-flush1))
(defun dmr-flush1 (&optional reset-counter)
(when *dmr-stream*
(file-position *dmr-stream* :start)
(princ (dmr-string) *dmr-stream*)
#-ccl
(force-output *dmr-stream*)
#+ccl ; fix for "Expected newpos" error (thanks, Gary Byers)
(ccl::without-interrupts
(force-output *dmr-stream*))
(setq *saved-deep-gstack* *deep-gstack*)
(when reset-counter
(setq *dmr-counter* 0))
t))
#+acl2-par
(defvar *dmr-lock* (make-lock))
(defun dmr-flush (&optional reset-counter)
#+acl2-par
(when (dmr-acl2-par-hack-p)
(return-from dmr-flush
(cond ((> *dmr-counter*
*dmr-interval-used*)
(setq *dmr-counter* 0)
(with-lock *dmr-lock* (dmr-flush1)))
(t
(setq *dmr-counter* (1+ *dmr-counter*))))))
(dmr-flush1 reset-counter))
(defun dmr-display ()
#+acl2-par
(when (dmr-acl2-par-hack-p)
(return-from dmr-display
(cond ((> *dmr-counter*
*dmr-interval-used*)
(setq *dmr-counter* 0)
(dmr-flush))
(t
(setq *dmr-counter* (1+ *dmr-counter*))))))
(dmr-flush))
(defun cw-gstack-short ()
(let* ((str (dmr-string))
(pos (search *dmr-delete-string* str)))
(princ (if pos (subseq str 0 pos) str) *terminal-io*)))
; INITIALIZATION OF CURRENT ACL2 WORLD
; Once upon a time (pre-V2.2) we had the following defvar here:
; (defvar *current-acl2-world-key* (make-symbol "*CURRENT-ACL2-WORLD-KEY*"))
; But compiling under cmulisp showed us that we refer to the value
; of this var earlier in the initialization process. So I have
; moved the defvar to axioms.lisp.
(eval-when #-cltl2 (load eval) #+cltl2 (:load-toplevel :execute)
(f-put-global 'current-acl2-world nil *the-live-state*)
(setf (get 'current-acl2-world 'acl2-world-pair)
(cons nil *current-acl2-world-key*)))
; EXTENDING AND RETRACTING PROPERTY LIST WORLDS
; We here sketch the entire world management scheme before diving into
; the details. The software archeologist might think these summaries
; were written just for his use but that is wrong. In fact, these are
; design sketches and refresher courses to bring to mind the salient
; details before getting back down to work. This particular one
; represents the attempt to get back into this frame of mind after
; several days of Christmas preparations, 1990. (Note: This essay has
; been updated since, to track changes such as the adoption, in April,
; 1994, of the restriction that reincarnated undone defpkgs must
; import only a subset of the old imports. That attack on the
; "unintern problem" was sketched as the "Alternative Design Proposal"
; in the December, 1990 essay but rejected as unnecessary as it was
; then thought that we handled reincarnation correctly by uninterning
; all symbols except in abort recovery. But :oops and the second pass
; of include books, etc., exposed the lie.)
; A property list "world" is a list of triples as created by putprop.
; Each triple is of the form (symb key . val). Such a list is
; accessed by getprop, which, logically speaking, scans down it
; looking for a given symb and key. Practically however, we allow a
; given world to be "installed" under any given symbolic name. What
; installation does is assemble into an alist all of the properties of
; each symb in the world and put that alist on the property list of
; the symbol, under some special key that is associated with the name
; of the installed world.
; If name has an 'acl2-world-pair property then name is the name of an
; installed world. The value of the property will be a pair, (alist .
; world-key), where alist is the (eq) world alist installed and
; world-key is a unique symbol associated with this world name and
; under which each symb's property alist is stored.
; The functions extend-world and retract-world will extend and retract
; a named world. Logically speaking, these two functions are identity
; functions. But practically speaking they smash Common Lisp property
; lists. Extend-world must be given a name and a world that is an
; extension (eq) of the one currently installed under the name and
; will install the new properties. An analogous remark holds for
; retract-world. We make these functions available to the ACL2
; programmer.
; We store our own property list world under the name 'current-acl2-
; world. How do we prevent the ACL2 programmer from smashing our
; properties? Well, extend-world (which is logically a no-op all the
; time) is even a no-op practically on the name 'current-acl2-world.
; To smash property lists you must call extend-world1 (not an ACL2
; function) and that function works on any name. Our ACL2 function
; set-w, which installs the current-acl2-world, calls extend-world1 in
; its #-acl2-loop-only code. Set-w is, of course, untouchable.
; We include special support for retraction, which of course is the
; basis of undoing. It would suffice, for extension and for getprop,
; if we could expedite the retrieval of the most recently put value of
; every symbol and key. Suppose the world in question is w, named
; name, and suppose it is installed under the property name world-key.
; Suppose the only three triples on w about symb are (symb key1 . b),
; (symb key1 . a), and (symb key2 . c), occurring in that order on w.
; Then for purposes of extension and getprop alone, we could store
; '((key1 . b) (key2 . c)) under symb's world-key property. But now
; suppose we wanted to retract back to where (symb key1 . a) was most
; recent. Then we would need to change the alist stored under symb's
; world-key to '((key1 . a) (key2 . c)) and to find the newly exposed
; value for key1 we would have to search w. This is what we did for
; the first 18 months of ACL2's development. This made :ubt suffer
; because when we undid a property -- especially a property on some
; symbol like binary-+ or cons -- we would have to scan all the back
; down the world to the primordial putprops to recover the newly
; exposed values. This was bad not so much because of the scan time
; but because of the swap time: the world is big and rarely
; referenced, so it tends to get paged out and then when you scan it
; you have to page it back in. This can take a minute or more.
; To avoid this we actually store a stack for each key. The stack is
; the list of all past values of the key, topped by the current value.
; An empty stack indicates that no putprop has occurred for that key
; (or, more accurately, that we have retracted back past the first
; putprop for that key).
; There is another twist to this scheme. To support the execution and
; compilation of ACL2 functions in raw Common Lisp, we interpret a
; certain putprop symb key, namely CLTL-COMMAND GLOBAL-VALUE, as a
; directive to smash the symbol-function, macro-function, or constant
; definition of certain symbols contained in the value. We only do
; this if we are installing 'current-acl2-world, of course. To
; support undoing of these smashes we maintain a stack of the past
; settings of those fields. This is the *undo-stack* of the symb.
; The situation here is complicated and more fully explained in the
; code below.
; The installation of worlds and error recovery are intimately con-
; nected to the problem of uninterning symbols on behalf of undone or
; reincarnated packages. When the CLTL-COMMAND defpkg is encountered,
; the program defpkg is called to create the package. Consider what
; would happen if defpkg were coded so as to unintern the symbols in
; the existing package and set the import list as per the new defini-
; tion (as, indeed, we once did, allowing the reincarnation of undone
; packages). In particular, consider the effect this would have on
; triples yet-to-be installed: if they mentioned symbols in the new
; package then those symbols would suddenly become uninterned. We
; once thought this was ok because symbols in newly defined packages
; couldn't yet exist in the yet-to-be installed world. But that is a
; bogus claim: if we are reinstalling a world after an error abort or
; even an :oops the world might contain symbols in the "just defined"
; package. This is what eventually drove us to implement the restric-
; tion described in :DOC package-reincarnation-import-restrictions.
; Because of the possiblity of user interrupts, it is possible that we
; can have effected some but not all of changes necessary to achieve a
; new state and then have the computation aborted. To handle this,
; extend-world1 and retract-world1 both save the current world alist
; before they begin to make any changes. If they are interrupted, the
; original configuration can be recovered by retracting back to nil
; and then extending to the saved current world. This is admittedly
; inefficient -- all 20,000 properties of a typical current-acl2-world
; might have to be stored again because we didn't bother to remember
; how much of the extension we had done when we were interrupted. On
; the other hand, it is truly simple and elegant and only comes into
; play with aborts during installation.
; Inspection of the lisp code for defpkg will reveal that it is
; sensitive to abort recovery in one other aspect. If we are in abort
; recovery and the "dual package" (the one used to house the lisp
; equivalents of state global variables) already exists, we do not
; unbind all the variables in it but simply leave it untouched. Since
; neither extending nor retracting changes state globals, the state
; global settings at the time of an abort are what they were when *w0*
; was saved. Hence, by doing nothing to the dual package we keep the
; installed world and the state globals in the same relationship.
; So much for the sketch of the world management business. We now get
; down to brass tacks.
(defun-one-output fmakunbound! (name)
(fmakunbound name)
(when (macro-function name)
(error "This Common Lisp implementation seems unable to unbind ~~%
macro-functions. Please let the ACL2 implementors know about ~%~
this problem.")))
(defun-one-output maybe-push-undo-stack (fn name &optional extra)
; See add-trip below for context. Fn is one of the raw Lisp function names
; secretly spawned by CLTL-COMMAND forms, e.g., DEFUN, DEFMACRO, DEFCONST,
; DEFPKG, DEFATTACH, or (for the HONS version) MEMOIZE or UNMEMOIZE. Name is
; generally the symbol or string that is being defined.
; Whenever we smash a CLTL cell we first save its current contents to permit
; redefinition and undoing. Toward this end we maintain a stack for each
; defined symbol, called the *undo-stack* property of the symbol. Very roughly
; speaking, the stack contains the previous values of the cells in question.
; Add-trip will push the old value onto the stack before storing the new and
; undo-trip will pop the stack and restore that old value. Ah, were it only
; that simple...
; There are complications. First, DEFPKG doesn't have a symbol associated with
; it explicitly, so we have to manufacture one for the *undo-stack*. We use
; the ``base symbol'' of the package (see chk-acceptable-defpkg). If the
; symbol-package-name string is "name" then the base symbol is the symbol
; ACL2::name-PACKAGE. (We use that symbol as a rule name associated with the
; defpkg axiom and so we already check that the name is new.) Second, DEFPKG
; makes the notion of "current contents" highly abstract because it not only
; creates a package but imports various symbols into it. So rather than use
; the *undo-stack* to save the "current contents" we use the stack to save a
; form that when evaluated will recreate the "current contents" of the cell in
; question. When a new value is stored (and the cell is already in use) we
; will manufacture a suitable form for recreating the old value and push it.
; Third, extra (formerly called ignorep because of its connection to the
; ignorep variable in add-trip) is either nil, 'reclassifying or '(defstobj
; . stobj). When it is 'reclassifying, we only save the *1* def for name.
; Otherwise, we save both defs.
(cond ((and (symbolp name)
(fboundp name)
(not (eq fn 'attachment)))
; We clear the 'acl2-trace-saved-fn property and reinstall the appropriate
; symbol-function if these have been messed with by tracing. We also do a raw
; Lisp untrace while we're at it, just to be careful. However, we skip all
; that for defattach, since defattach doesn't mess with symbol-functions -- it
; only messes with special variables.
(maybe-untrace! name t)))
(case fn
((defun defmacro)
; In Common Lisp, a symbol can be either a macro or function, but the
; symbol-function cell is used in both cases to store the associated code.
; Therefore, if we are about to smash the symbol-function cell, e.g., in
; response to a DEFUN event, then we are obliged to remember whether it was
; previously defined as a macro.
; Notice that we are dealing properly here with :inlined stobj functions as
; well as defabsstobj raw Lisp macros. See also the comment about this in
; undo-trip.
(cond
((fboundp name)
(let ((oneified-name (*1*-symbol name))
(macro-p (macro-function name)))
(push `(progn
,@(and (not macro-p)
`((maybe-untrace! ',name) ; untrace new function
#+hons (maybe-unmemoize ',name)))
,@(if (eq extra 'reclassifying)
(assert$
(not macro-p)
`((setf (symbol-function ',oneified-name)
',(symbol-function oneified-name))))
`(,@(if (not (iff (eq fn 'defmacro) macro-p))
; Avoid errors in (at least) CCL, as in this example.
; (redef!)
; (defun foo (x) x)
; (defmacro foo (x) `(quote ,x))
; (u)
`((fmakunbound! ',name)))
,(cond (macro-p
`(setf (macro-function ',name)
',(macro-function name)))
(t
`(setf (symbol-function ',name)
',(symbol-function name))))
,(cond
((fboundp oneified-name)
`(setf (symbol-function ',oneified-name)
',(symbol-function oneified-name)))
(t `(fmakunbound! ',oneified-name))))))
(get name '*undo-stack*))))
(t (push `(progn (maybe-untrace! ',name) ; untrace new function
#+hons (maybe-unmemoize ',name)
(fmakunbound! ',name)
(fmakunbound! ',(*1*-symbol name)))
(get name '*undo-stack*)))))
(defconst
; Note: defstobj events use maybe-push-undo-stack with fn = 'defconst
; to save the values of the name, the live name and also of
; '*user-stobj-alist*!
(cond
((boundp name)
(push `(progn (setf (symbol-value ',name)
',(symbol-value name))
(setf (get ',name 'redundant-raw-lisp-discriminator)
',(get name 'redundant-raw-lisp-discriminator)))
(get name '*undo-stack*)))
(t (push `(progn (makunbound ',name)
(remprop ',name 'redundant-raw-lisp-discriminator))
(get name '*undo-stack*)))))
(defpkg
(let ((temp (find-non-hidden-package-entry
name
(known-package-alist *the-live-state*))))
(cond
(temp
(push `(defpkg ,name ',(package-entry-imports temp))
(get (packn (cons name '("-PACKAGE"))) '*undo-stack*))))))
(attachment
(let ((at-sym (attachment-symbol name)))
(push `(progn #+hons (push ',name *defattach-fns*)
,(set-attachment-symbol-form
name
; Note that at-sym is bound when name is introduced; see throw-or-attach-call.
(symbol-value at-sym)))
(get name '*undo-stack*))))
#+hons
(memoize
(push `(unmemoize-fn ',name)
(get name '*undo-stack*)))
#+hons
(unmemoize
(let* ((entry (gethash name *memoize-info-ht*))
(condition (access memoize-info-ht-entry entry :condition))
(inline (access memoize-info-ht-entry entry :inline))
(trace (access memoize-info-ht-entry entry :trace))
(commutative
(access memoize-info-ht-entry entry :commutative))
(forget
(access memoize-info-ht-entry entry :forget))
(memo-table-init-size
(access memoize-info-ht-entry entry :memo-table-init-size))
(aokp
(and (access memoize-info-ht-entry entry :ext-anc-attachments)
t))
(cl-defun (access memoize-info-ht-entry entry :cl-defun)))
(push `(memoize-fn ',name
:condition ',condition
:inline ',inline
:trace ',trace
,@(and commutative
`(:commutative t))
,@(and forget
`(:forget t))
,@(and memo-table-init-size
`(:memo-table-init-size
',memo-table-init-size))
,@(and aokp
`(:aokp ',aokp))
,@(and cl-defun
`(:cl-defun ',cl-defun)))
(get name '*undo-stack*))))
(otherwise
(er hard 'maybe-push-undo-stack
"Unrecognized CLTL-COMMAND spawn ~x0"
fn))))
(defun-one-output maybe-pop-undo-stack (name)
; See maybe-push-undo-stack.
(let* ((name (if (symbolp name)
name
(packn (cons name '("-PACKAGE")))))
(stk (get name '*undo-stack*)))
(cond
((null stk) nil)
(t (eval (car stk))
(setf (get name '*undo-stack*) (cdr stk))))))
(defun-one-output flush-undo-stack (name)
; We completely wipe out the undo-stack of name, after returning
; the relevant cell to its initial configuration.
(let* ((name (if (symbolp name) name (intern name "ACL2")))
(stk (get name '*undo-stack*)))
(cond (stk (eval (car (last stk)))))
(remprop name '*undo-stack*)))
; Now we define the two programs that manage the stacks of old
; property values.
; We start with pushing a new value onto the stack for a given key.
; Complicating things is our decision to order the keys in the alists by (a
; priori) frequency of access. The aim is to speed up getprop. We record
; the results of many experiments below.
; Recall that the current-acl2-world is implemented so that the logical
; properties are stored in an alist which is obtained via a raw lisp get of the
; property *current-acl2-world-key*. That alist is then searched with assoc
; :test #'eq. Of interest then are both the order of the properties
; encountered by the raw lisp get and the order of the keys encountered by the
; assoc :test #'eq.
; The basic experiment addressed one particular proof in the Nqthm package. To
; set the stage, the Nqthm package was loaded and then undone back through
; NQTHM-COUNT-SYMBOL-IS-COUNT-FN-UNPACK, a theorem whose reported proof time is
; 35.23 by the current Version 1.8. Then that theorem was proved again while a
; patch was in place inside of fgetprop. The patch collected together an alist
; recording the calls of fgetprop. In particular the alist entries were of the
; form (symb (key1 . cnt1) ... (keyk . cntk)) indicating that (fgetprop symb
; keyi <some-default> <current-acl2-world>) was called cnti times during the
; proof. We then wrote and compiled a program that swept the alist and
; repeated every call of fgetprop simply to allow us to measure the total time
; spent in fgetprop. There were a total of 102781 calls. To sweep the alist
; with a no-op function of the same arity as fgetprop required 0.25 seconds.
; We therefore consider that to be the overhead of the sweep itself. To sweep
; with fgetprop required 0.75 seconds, indicating that a "net" 0.50 seconds
; were actually spent in fgetprop on the actual calls in the sample theorem.
; (We will use "net" henceforth to mean the measured time minus 0.25.) This
; gives an expected "per call" time of 4.86E-6.
; For what it is worth, a noop that calls get has an overhead of 0.267 for
; a net of 0.017 or a per call time of 1.65E-7 seconds. Thus an fgetprop
; is about 30 times slower than a get (with the orderings created by the
; current Version 1.8).
; However, we have noticed that *current-acl2-world-key* is not always the
; first property encountered by the raw lisp get. Other properties sometimes
; covering it up include *UNDO-STACK*, *PREDEFINED* and SYSTEM:PNAME. We
; therefore moved *current-acl2-world-key* to the front of every symbol-plist.
; The net sweep time was then 0.30 (for a per call time of 18 gets).
; We now move on to ordering the keys seen by assoc :test #'eq. In prior
; experiments we had determined the frequency with which the various keys are
; accessed (during the entire Nqthm package proof). For what it is worth, here
; is the key list, in order from most frequently accessed to least:
; '(COARSENINGS GLOBAL-VALUE CONGRUENCES SYMBOL-CLASS TYPE-PRESCRIPTIONS
; LEMMAS RUNIC-MAPPING-PAIRS MULTIPLICITY STATE-IN
; RECURSIVEP DEF-BODIES CONSTRAINEDP LINEAR-LEMMAS
; FORMALS MACRO-BODY FORWARD-CHAINING-RULES STATE-OUT TABLE-ALIST
; GUARD MACRO-ARGS ELIMINATE-DESTRUCTORS-RULE CONST LEVEL-NO
; UNNORMALIZED-BODY THEOREM REDEFINED INDUCTION-MACHINE JUSTIFICATION
; INDUCTION-RULES CONTROLLER-ALIST QUICK-BLOCK-INFO
; We therefore reordered the alist so that the keys were stored with the most
; frequently accessed ones first. We added nil COARSENINGS and CONGRUENCES
; properties (and later, as described below, RECURSIVEP) to those function
; symbol property lists for which the value of the property was nil but the
; property was unrecorded. (This saves the time of cdring through the entire
; list to compute the most frequently seen two properties.) Technically, we
; extended and reordered the alist found in (get symb
; *current-acl2-world-key*), for each symbol with a *current-acl2-world- key*
; property and that property was always first on the symbol-plist.
; We then repeated the sweep in a net time of 0.22 seconds (per call = 13 gets).
; We then reversed the "optimal" ordering on the property lists and measured a
; net time of 0.31 (down from 0.30 from the random order of Version 1.8).
; Finally, we perturbed the property lists by adding 10 new property keys and
; values to the front of every (get symb *current-acl2-world-key*) and measured
; a net time of 0.50.
; From this experiment one can make the following conclusions: (a) In this
; theorem, fgetprop is reponsible for less than 2% of the proof time. Making
; fgetprop instantaneous would reduce the 35.23 seconds to 34.73 seconds.
; By ordering the properties (in both senses) we can speed fgetprop up from
; about 30 gets to about 13 gets, more than doubling its speed.
; The rest of this essay on experimental results discusses some detailed
; investigations that led to virtually no further improvement (see stats at the
; end of the essay). The lesson learned is that it may not be worth mucking
; around further with *current-acl2-world-key-ordering*.
; In July 2002, during the development of Version_2.7, we modifed the use of
; the fnstack (specifically, being-openedp) so that for recursive functions we
; look up the representative of a clique, thus avoiding the need to look
; through all members every clique for the function at hand. (A
; mutual-recursion nest with 4,786 defuns at AMD prompted this change.) As a
; result we saw a 1.8% slowdown in the regression suite, reduced to 0.9% with
; some optimizations. Presumably the slowdown was due to the more frequest use
; of the RECURSIVEP property. So we ran experiments using community books
; files books/certify-numbers.lisp and books/rtl/rel2/support/cert.lsp, though
; we aborted the latter partway through lop3.lisp (during the proof of
; BITN-LAM0, which seemed to be bogging down). The results using
; analyze-fgetprop-stats were as follows.
; books/certify-numbers.lisp:
;
; GLOBAL-VALUE 2474980
; COARSENINGS 2332094
; TYPE-PRESCRIPTIONS 1162730
; RUNIC-MAPPING-PAIRS 979110
; CONGRUENCES 769460
; RECURSIVEP 676128
; TABLE-ALIST 675429
; SYMBOL-CLASS 415118
; LEMMAS 381015
; MACRO-BODY 356823
; STOBJS-OUT 303906
; FORMALS 213447
; STOBJS-IN 161261
; STOBJ 101845
; GUARD 75749
; MACRO-ARGS 75221
; BODY ; changed later to def-bodies 68867
; CONSTRAINEDP 50190
; FORWARD-CHAINING-RULES 49839
; CONST 25601
; ELIMINATE-DESTRUCTORS-RULE 19922
; THEOREM 9234
; LINEAR-LEMMAS 9102
; ...
;
; books/rtl/rel2/support/cert.lsp (aborted as explained above):
;
; COARSENINGS 30087445
; GLOBAL-VALUE 28366962
; CONGRUENCES 27187188
; RUNIC-MAPPING-PAIRS 13934370
; TYPE-PRESCRIPTIONS 12058446
; RECURSIVEP 10080678
; TABLE-ALIST 4644946
; SYMBOL-CLASS 2742519
; LEMMAS 1978039
; STOBJS-OUT 1943646
; MACRO-BODY 1837674
; FORMALS 1185024
; STOBJS-IN 781274
; BODY ; changed later to def-bodies 585696
; STOBJ 509394
; GUARD 390584
; MACRO-ARGS 389694
; CONSTRAINEDP 332418
; FORWARD-CHAINING-RULES 211225
; CONST 145628
; ABSOLUTE-EVENT-NUMBER 93259
; LINEAR-LEMMAS 34780
; ...
; As a result, we revised the ordering of keys. We also noticed that although
; GLOBAL-VALUE is high on the list, most of that is accounted for by looking it
; up for symbols RECOGNIZER-ALIST and UNTOUCHABLES, which do not have other
; properties:
; books/certify-numbers.lisp:
;
; RECOGNIZER-ALIST 2056058
; GLOBAL-VALUE 2056058
; UNTOUCHABLES 261297
; GLOBAL-VALUE 261297
;
; books/rtl/rel2/support/cert.lsp (aborted as explained above):
;
; RECOGNIZER-ALIST 26193957
; GLOBAL-VALUE 26193957
; UNTOUCHABLES 1359647
; GLOBAL-VALUE 1359647
; The user times (in seconds) for running the regression suite using an Allegro
; 6.0 Linux development Version_2.7 were as follows, with successive
; "improvements" shown.
; 15359.38 ; original time
; 15637.45 ; 1.81% slowdown: first cut at new approach to fnstack for mutrec
; 15496.32 ; 0.89% slowdown: optimizations in being-openedp (made a macro)
; 15497.46 ; 0.90% slowdown: new *current-acl2-world-key-ordering*
; 15481.14 ; 0.79% slowdown: always put recursivep property on function symbols
; March 2006: Here are some new numbers, listing in each case down to about 2
; orders of magnitude below the most-used property. All were obtained with all
; outpu inhibited.
; ============================================================
;
; stats0 (books/certify-numbers.lisp):
;
; COARSENINGS 2527582
; GLOBAL-VALUE 2224181
; RUNIC-MAPPING-PAIRS 1188675
; TYPE-PRESCRIPTIONS 1074218
; CONGRUENCES 730666
; DEF-BODIES 685868
; TABLE-ALIST 642459
; SYMBOL-CLASS 400157
; LEMMAS 362209
;
; ============================================================
;
; stats1 (books/workshops/1999/compiler/proof1):
;
; COARSENINGS 1137397
; DEF-BODIES 705063
; GLOBAL-VALUE 587267
; TABLE-ALIST 360303
; TYPE-PRESCRIPTIONS 196192
; CONGRUENCES 194726
; SYMBOL-CLASS 177363
; LEMMAS 167682
; RUNIC-MAPPING-PAIRS 75828
; STOBJS-OUT 13381
; MACRO-BODY 10245
;
; ============================================================
;
; stats2 (:mini-proveall):
;
; COARSENINGS 87020
; GLOBAL-VALUE 58987
; RUNIC-MAPPING-PAIRS 54106
; TABLE-ALIST 32902
; DEF-BODIES 26496
; TYPE-PRESCRIPTIONS 24822
; CONGRUENCES 20367
; LEMMAS 17938
; SYMBOL-CLASS 15271
; FORWARD-CHAINING-RULES 4820
; FORMALS 1278
; MACRO-BODY 1216
; STOBJS-OUT 1199
; ELIMINATE-DESTRUCTORS-RULE 962
;
; ============================================================
;
; stats3 (osets/map):
;
; DEF-BODIES 288073
; RUNIC-MAPPING-PAIRS 262004
; COARSENINGS 235573
; GLOBAL-VALUE 171724
; FORMALS 84780
; TABLE-ALIST 76462
; UNNORMALIZED-BODY 61718
; TYPE-PRESCRIPTIONS 56193
; LEMMAS 54533
; CONSTRAINEDP 52642
; SYMBOL-CLASS 43824
; CONGRUENCES 36786
; MACRO-BODY 30206
; STOBJS-OUT 27727
; THEOREM 15714
;
; ============================================================
;
; stats4 (rtl/rel5/support/drnd):
;
; COARSENINGS 20881212
; GLOBAL-VALUE 10230404
; RUNIC-MAPPING-PAIRS 7726914
; TYPE-PRESCRIPTIONS 4177523
; DEF-BODIES 2732746
; SYMBOL-CLASS 705776
; STOBJS-OUT 671763
; TABLE-ALIST 664941
; CONGRUENCES 497120
; LEMMAS 376371
; MACRO-BODY 294016
;
; ============================================================
;
; stats5 (rtl/rel2/support/cert.lsp):
;
; COARSENINGS 21792912
; GLOBAL-VALUE 15497700
; RUNIC-MAPPING-PAIRS 8088313
; TYPE-PRESCRIPTIONS 6554966
; DEF-BODIES 5365470
; TABLE-ALIST 2641304
; SYMBOL-CLASS 1873984
; CONGRUENCES 1562924
; LEMMAS 1220873
; STOBJS-OUT 420330
; MACRO-BODY 364583
; FORMALS 248019
; FORWARD-CHAINING-RULES 245442
;
; ============================================================
; End of Experimental Results.
; Below we list the most important property keys according to the results
; above. Keys are stored in alists in this order, i.e., keys occurring earlier
; in this list are stored earlier in the alists. When a key not occurring in
; this list is added to the alist it is as though it occurred at the very end
; of this list, i.e., it gets a low priority. Not all keys used by the current
; system are in this list (see below).
(defparameter *current-acl2-world-key-ordering*
'(COARSENINGS
GLOBAL-VALUE ; mostly looked up for RECOGNIZER-ALIST and UNTOUCHABLES,
; which do not have other properties
RUNIC-MAPPING-PAIRS
DEF-BODIES
TYPE-PRESCRIPTIONS
TABLE-ALIST
CONGRUENCES
SYMBOL-CLASS
LEMMAS
STOBJS-OUT
MACRO-BODY
FORMALS
FORWARD-CHAINING-RULES
; Note: As of this writing there are many properties not included above, all of
; which fall into the low priority category. We have omitted keys simply to
; keep the list shortened and thus to speed up the insertion program
; (merge-into-alist, on behalf of destructive-push-assoc) a little. This is an
; unanalyzed "optimization".
))
(defun-one-output key-lesseqp (key1 key2 ordering)
; We return t if key1 occurs weakly before key2 in the ordering.
(cond ((null ordering) t)
((eq key1 (car ordering)) t)
((eq key2 (car ordering)) nil)
(t (key-lesseqp key1 key2 (cdr ordering)))))
(defun-one-output merge-into-alist (key val alist)
; Alist is a symbol alist, key is a symbol that is not bound in alist. We wish
; to create the alist that is logically equivalent under assoc-eq to (cons
; (cons key val) alist) but we actually place the new pair in the proper place
; according to the *current-acl2-world-key-ordering*.
(cond ((null alist) (list (cons key val)))
((key-lesseqp key (caar alist) *current-acl2-world-key-ordering*)
(cons (cons key val) alist))
(t (cons (car alist) (merge-into-alist key val (cdr alist))))))
(defun-one-output destructive-push-assoc (key value alist world-key)
; We push value onto the stack associated with key in alist. If key has no
; value in alist, we pretend it has the empty stack. E.g., if alist is '((a .
; (1))) and we push 2 on 'a we get '((a . (2 1))) and if we then push 0 on 'b
; we get '((b . (0)) (a . (2 1))). This function is maximally destructive on
; the cons structure of alist and the stacks, but doesn't touch the cons
; structure of the values. We keep the alists in sorted order iff the
; world-key is our special one, *current-acl2-world-key*.
(let ((temp (assoc key alist :test #'eq)))
(cond (temp (setf (cdr temp) (cons value (cdr temp)))
alist)
((eq world-key *current-acl2-world-key*)
(merge-into-alist key (list value) alist))
(t (cons (cons key (list value)) alist)))))
(defun-one-output destructive-pop-assoc (key alist)
(let ((temp (assoc key alist :test #'eq)))
(cond (temp (setf (cdr temp) (cdr (cdr temp)))
alist)
(t alist))))
(defun-one-output remove-current-acl2-world-key (plist)
(cond ((null plist) plist)
((eq (car plist) *current-acl2-world-key*)
(cddr plist))
(t (cons (car plist)
(cons (cadr plist)
(remove-current-acl2-world-key (cddr plist)))))))
; We now develop support for early loading of compiled files, beginning with an
; essay that outlines that development.
; Essay on Hash Table Support for Compilation
; This essay has the following main parts:
; Part 0: High-level summary
; Part 1: A more detailed introduction
; Part 2: Including a certified book
; Part 3: Writing an expansion file for compilation
; Part 0: High-level summary
; We strive for efficiency of include-book. By doing all compilation at
; certify-book time rather than include-book time, we may greatly speed up
; definitional processing in lisps such as CCL and SBCL, which compile every
; definition on the fly. We were motivated by profiling results showing that
; such processing can take 45% of include-book time: a test case from Centaur
; using CCL was spending this proportion of time in the installation of a
; Common Lisp symbol-function for each defun event, in add-trip. The problem
; was that the CCL compiler is called every time a defun is evaluated, and
; although the CCL compiler is impressively fast, it's not instantaneous. Dave
; Greve has reported observing significant such slowdowns using CCL at Rockwell
; Collins.
; Happily, with this change we found the time cut roughly in half for two
; include-book tests from Centaur provided by Sol Swords. Other tests suggest
; no noticeable slowdown for certify-book or include-book for GCL or Allegro
; CL, which do not compile on the fly.
; Our approach is to avoid calling the compiler (by CCL or SBCL, at least)
; every time a definition is encountered by include-book, by instead using
; existing code previously compiled by certify-book, which is loaded before
; processing of events by include-book. Thus, the main efficiency gains from
; this change are expected to be for ACL2 built on CCL or SBCL, as these are
; the Lisps we know of (as of March 2010) that compile all definitions at
; submission time and therefore had been compiling on behalf of add-trip.
; However, this approach may also boost efficiency in some cases even for Lisps
; other than CCL and SBCL. For one thing, include-book will now install a
; compiled symbol-function for each defun, even for those other Lisps, which
; can speed up computations in ensuing defconst forms and defmacro forms of the
; book. Moreover, compiled code will be installed for defmacro and defconst
; forms, which can avoid the need for redoing macroexpansion of the bodies of
; such forms during add-trip.
; A simple-minded approach is to load the compiled file for a book *before*
; processing events in the book. The obvious problem is that ACL2 demands that
; a function not be pre-defined in raw Lisp when evaluating a defun event, and
; for good reason: we want to protect against accidental previous definition in
; raw Lisp. So instead, our solution is to arrange that loading compiled files
; does not actually install definitions, but rather, builds hash tables that
; associate symbols with their definitions. The file to be compiled thus has
; roughly the following structure; the prefix "hcomp" is intended to refer to
; "hash-table-supported compilation".
; (in-package "ACL2")
;;; Introduce some packages, without any imports:
; (maybe-introduce-empty-pkg "MY-PKG")
;;; Save some information about the fni:
; (setq *hcomp-fn-alist* '((fn1 ..) (fn2 ..) ..))
;;; Build a hash table associating each fni with its pre-existing
;;; symbol-function or special *unbound* mark:
; (hcomp-init)
;;; Generate declaim forms (depending on the Lisp):
; ...
;;; Portcullis commands and events from the book, with make-events expanded:
; ...
;;; *1* definitions to compile:
; ...
; The load of each book in raw Lisp (by function load-compiled-book) is
; followed by code that saves the symbol-function for each fni in a hash table,
; *hcomp-fn-ht* (function hcomp-transfer-to-hash-tables), which in turn is
; associated with the full-book-name in a global hash table, *hcomp-book-ht*.
; But first, the (hcomp-init) form arranges to save -- in a global hash table,
; *hcomp-fn-macro-restore-ht* -- an association of each fi with its existing
; symbol-function (or a "not bound" marker). After all such files are loaded
; in raw Lisp under the top-level included book (by a call of include-book-raw
; under include-book-fn), the relevant *hcomp-fn-ht* hash tables will have been
; populated and saved in the global hash table mentioned above,
; *hcomp-book-ht*, keyed on full-book-names. The top-level include-book will
; finish up after such files are loaded (for that book and subsidiary included
; books), using the global hash table *hcomp-fn-macro-restore-ht* to restore
; the symbol-function of fi (much more typically, to make the symbol-function
; of fi unbound) when the top-level load concludes.
; Above, we say "roughly" because there are numerous complications. For
; example, *1* functions can be defined twice (once for :program mode and once
; for :logic mode); there may be portcullis commands for subsidiary
; include-book events within the book; and the absence of a missing compiled
; file for a sub-book can cause an abort, so some of the above finishing up
; might need to be done in the cleanup form of an acl2-unwind-protect. In this
; Essay we outline our mechanism and explain how we deal with such
; complications.
; We are breaking from ACL2 versions up through 3.6.1, by insisting that the
; compiled file for a book is loaded "early" (if it is loaded at all), i.e.,
; before events are processed from that book. This approach not only can boost
; efficiency of include-book, but it also provides a solution to a soundness
; bug in the redundancy of :program mode definitions with preceding :logic mode
; definitions, present from Version_3.5 through Version_3.6.1. To illustrate
; this bug, consider the two books below, which have been certified in ACL2
; 3.6.1 built on GCL. The problem is that inclusion of bk1 inside bk2 smashes
; the symbol-function of *1*foo, because of loading of compiled file bk1.o.
; (The Allegro CL version merely breaks when attempting to prove BUG.)
; -------------------- bk1.lisp --------------------
; (in-package "ACL2")
; (defun foo (x)
; (declare (xargs :mode :program))
; (car x))
; -------------------- bk2.lisp --------------------
; (in-package "ACL2")
; (defun foo (x)
; (car x))
; (defun bar (x)
; (foo x))
; (defthm fact
; (null (bar 3))
; :rule-classes nil)
; (encapsulate
; ()
; (local (include-book "bk1"))
; (defthm bug
; (not (null (bar 3)))
; :rule-classes nil))
; (defthm contradiction
; nil
; :hints (("Goal" :use (fact bug)
; :in-theory (disable (bar) bar)))
; :rule-classes nil)
; ----------------------------------------
; The bug occurs because the local include-book of "bk1" loads bk1.o, which
; smashes the symbol-function of *1*foo to its :program mode version, which
; unlike the :logic mode version passes evaluation directly to raw Lisp,
; causing evaluation of (car 3). Of course we don't really need to solve this
; problem for CCL-based ACL2 images that do not load compiled files. But that
; seems ugly, as one could then certify a book with CCL that cannot be
; certified with another Lisp.
; Another, less serious problem is also solved by early loading of compiled
; files. Consider the following books.
;;; bar.lisp
; (in-package "ACL2")
; (defun foo (x)
; (declare (xargs :guard t))
; (cons x x))
;;; foo.lisp
; (in-package "ACL2")
; (defun foo (x)
; (cons x x))
;;; top.lisp
; (in-package "ACL2")
; (include-book "bar")
; (include-book "foo")
; The *1* function generated for foo in bar.lisp is considerably simpler than
; in the case of foo.lisp, because there need be no check that the symbol-class
; of foo is :common-lisp-compliant. When we include top in Version_3.6.1 or
; earlier, loading compiled files, the compiled file for foo overwrites the one
; for bar, leaving us with the more complicated *1* code. This is clear if one
; uses CLISP and evaluates (disassemble (*1*-symbol 'foo)) in raw Lisp: 13
; byte-code instructions if one includes foo or top, but only 3 byte-code
; instructions if one includes bar instead. With early loading of compiled
; files, evaluation of (include-book "top") will define this *1* function when
; including bar, but will not define it again when including foo.
; (The above example isn't convincing of much, really, since if we switch the
; order of the include-book forms in top.lisp then we will get the complicated
; *1* compiled definition of foo, because the definition from bar.lisp will be
; redundant. But it still seems preferable to avoid loading compiled files
; that overwrite definitions needlessly, for example to put less stress on the
; garbage collector.)
; Of course, these issues disappear if the compiled file is not loaded at all,
; and we support that too, using state global 'compiler-enabled.
; We conclude this Part with a few words about handling of the case that
; include-book argument :load-compiled-file has argument :comp. The basic idea
; is to wait until the book is included, and then check that either the
; compiled file or the expansion file exists and is not older than the
; certificate; and only then, if the expansion file exists but the compiled
; file does not, do we compile the expansion file and then load it in the
; ordinary way (without messing with hash tables, by leaving the relevant
; variables such as *hcomp-fn-ht* bound to nil). We considered more complex
; approaches but are quite happy with this simple solution, and we don't say
; anything further about the case of :load-compiled-file :comp in this Essay.
; Part 1: A more detailed introduction
; We now give a more detailed global view of our approach based on hash tables.
; Note that since compilation is inherently a raw-Lisp activity, we code
; shamelessly in raw Lisp when that is convenient.
; The idea is for include-book to load an existing compiled file before
; processing events from the book, even before its portcullis commands are
; processed. The compiled definitions are stored in hash tables for subsequent
; use by add-trip, then immediately undone so that existing definitions are
; restored (or, much more often, symbols are again unbound). We must however
; be careful to use these hash tables only when appropriate: in particular,
; verify-termination changes *1* definitions, so there can be two definitions
; generated for the same symbol -- and loading the compiled file provides the
; latter definition, which is inappropriate to use for the first defun but is
; appropriate for the defun generated by the verify-termination.
; (Aside: We might consider using the latter symbol-function for both the
; :program and :logic mode *1* functions. But it's easy to imagine that the
; :logic code asks about the symbol-class of the function symbol under the
; assumption that it's definitely not :program -- and that assumption would be
; violated if we installed that code when the :program mode version is
; introduced. Whether or not that problem actually exists, or at least is easy
; to fix, this example nevertheless illustrates that evaluation in ACL2 is
; complex and delicate. So we prefer to be conservative and not to install a
; :logic mode *1* function definition for a :program mode function.)
; The introduction of make-event in 2006 initiated the writing of what we call
; below an "expansion file", to be compiled instead of the source book,
; creating what we call below the "compiled file". This feature was further
; exploited by incorporating compiled *1* functions into the compiled file
; (Version_3.2.1). We take further advantage of these expansion files by
; putting forms into them to implement the plan outlined above. Note that we
; handle certain events that create 'cltl-command properties, as processed by
; add-trip: defun, defstobj, defabsstobj, defconst, and defmacro, but not
; memoize and unmemoize, even in the #+hons case. Extra forms near the top of
; the expansion file will be evaluated when loading the compiled file, to store
; values in hash tables for later use, when add-trip deals with 'cltl-command
; properties. Those extra forms are based on information deduced during the
; include-book phase of book certification, at which time Lisp global
; *inside-include-book-fn* has value 'hcomp-build. Later, during subsequent
; include-books, that information directs which definitions from the expansion
; file are to be stored in our hash tables. Additional forms are evaluated
; after completion of the load of the compiled file, to transfer the compiled
; definitions to hash tables and eventually to remove each definition installed
; by the expansion file (restoring any pre-existing definitions). This
; eventual removal occurs only after a load completes for the top-level
; compiled file of a book, and hence also for all books included therein.
; Portcullis commands and included sub-books present challenges. Consider for
; example a constant whose value is a symbol in a package defined in a
; sub-book's portcullis commands. If we load the compiled file for the book
; that defines that constant, but treat the include-book of the sub-book as a
; no-op (as was done through Version_3.6.1), then it doesn't seem clear that
; this constant's value would be interned in any package, since its package is
; defined in the portcullis commands of the not-yet-loaded sub-book. Indeed,
; we need to consider loading not only the sub-book but also its portcullis
; commands. At the very least, we want to avoid warnings that could occur when
; encountering a global or function call in the parent book (say, during macro
; expansion) when the definition of that global or function (by defconst or
; defun, respectively) comes from the unloaded sub-book. And certainly we do
; need a sub-book's portcullis commands when loading it, for example in case
; one of those commands defines a function that is used in a defconst form in
; the book.
; We thus write portcullis commands into the expansion file. But with some
; reflection one discovers that a book's initial in-package form itself could
; be problematic, since if the package in question is not the "ACL2" package
; then it needs to be defined in some book's portcullis commands! So we always
; start an expansion file with (in-package "ACL2"), and when we write the forms
; into the expansion file, we always do so relative to the ACL2 package.
; But our problems with packages don't end there! The setq forms defining
; *hcomp-fn-alist* and the like may involve symbols defined in packages
; introduced in the portcullis commands. (Why use setq instead of
; defparameter? Variables such as *hcomp-fn-alist* are already declared
; special using defvar in the ACL2 sources, so setq is certainly legal. We
; found a case with CCL in which the use of defparameter slowed down
; include-book by a factor of more than 100.) But we want to lay these down
; before a call of hcomp-init, which will consult *hcomp-fn-alist* and such
; when storing information to let us undo definitions installed by loading the
; compiled file. This call of hcomp-init, and its preceding definitions of
; *hcomp-fn-alist* and the like, must therefore be laid down before the very
; portcullis commands that may define packages of symbols used in these
; definitions. Our solution is to use defpackage to introduce packages before
; the symbols are read, and to make a note using special variable
; *defpkg-virgins* that such packages are legitimate targets for the defpkg
; forms to come.
; (Aside: Why does it work to start the expansion file with the introduction of
; an empty package, say "MY-PKG", and then lay down forms like the
; *hcomp-fn-alist* form, above, that may refer to symbols written out at the
; end of book certification? The only symbols where one might imagine this is
; an issue are ones that are printed differently when "MY-PKG" is fully defined
; (near the end of certification) than when it is introduced with no imports by
; an initial form that introduces the package as "empty" (no imports). The
; only such symbols are those written without a package prefix, hence included
; in the "ACL2" package, that are in the import list for "MY-PKG". But such
; symbols aren't a problem after all, because any reference to such a symbol in
; the "ACL2" package is really a reference to a symbol of that name in the
; "MY-PKG" package, once that package is "truly" introduced by defpkg. And
; until such a defpkg form is evaluated, ACL2 will not dabble in symbols in the
; "MY-PKG" package, other than to save them in *hcomp-fn-alist* and related
; lists near the top of the expansion file.)
; Note that in a break from ACL2 versions up through 3.6.1, where ACL2 could
; load compiled files for uncertified books, the write-date comparison of the
; compiled file (or expansion file) is against the certificate rather than the
; source .lisp file. (Well, that's not quite true: the comparison remains
; against the source book when include-book is executed in raw mode, since raw
; mode does not involve the certificate file.)
; We designate three "add-trip contexts", according to whether processing of a
; 'cltl-command property by add-trip is assigning a function, a global variable
; (e.g. for defconst), or a macro value. We refer to the symbol being assigned
; a value as an "add-trip symbol", and we call that value a "relevant value"
; (with respect to that context, which is often implicit) for that symbol.
; Whenever we refer to the add-trip symbols of a book, that reference includes
; add-trip symbols for the book's portcullis commands as well, but not add-trip
; symbols of subsidiary included books. Note by the way that a *1* function
; symbol can be an add-trip symbol. The final step after loading a top-level
; compiled file will be to undo the load's assignment of relevant values to
; add-trip symbols. This step will be done in the cleanup form of an
; unwind-protect, so as to clean up if an error or interrupt occurs during
; loading of the compiled file. (The clean-up won't be complete for functions
; defined in raw-mode, just as it hasn't been in earlier versions of ACL2 that
; did not load compiled files early. But raw-mode is ultimately the user's
; responsibility, and we expect problems from such aborts to be rare.)
; We next describe several variables and a constant, which we define before
; include-book-fn.
; Variables *hcomp-fn-ht*, *hcomp-const-ht*, and *hcomp-macro-ht* are
; intended to be let-bound to eq hash tables: one for ACL2 user functions and
; their *1* symbols, one for constants (as with defconst), and one for
; macros.
; Variables *hcomp-fn-alist*, *hcomp-const-alist*, and *hcomp-macro-alist*
; will be be let-bound to alists related to the above hash tables, in senses
; described below.
; The variable *hcomp-fake-value* is used as a "fake value", not in any
; package known in the ACL2 loop, for various purposes below.
; Variables *hcomp-fn-macro-restore-ht* and *hcomp-macro-restore-ht* are
; globally bound to hash tables that are populated as books are included,
; storing existing relevant values (or *hcomp-fake-value* when the relevant
; value is unbound) for add-trip symbols.
; A hash table variable, *hcomp-book-ht*, holds other hash tables, as
; follows.
; A key of *hcomp-book-ht* is a full-book-name. Values in this hash table are
; hcomp-book-ht-entry records, where each record has a status field that
; describes the attempt to load the book's compiled file, and also has optional
; fields corresponding to values of *hcomp-fn-ht*, *hcomp-const-ht*, and
; *hcomp-macro-ht*. When ACL2 encounters an include-book form during an early
; raw-Lisp load of an include-book whose full-book-name is not already a key of
; the world's 'include-book-alist or of *hcomp-book-ht*, then include-book
; loads that sub-book's compiled file, hence with new let-bindings of the
; *hcomp-xxx-alist* and *hcomp-xxx-ht* variables, along with unwind protection
; using the *hcomp-xxx-restore-ht* values that can restore relevant values
; after transferring them to those hash tables. Upon exiting include-book
; successfully, the *hcomp-xxx-ht* variables are associated with the
; full-book-name in *hcomp-book-ht*.
; (Note: One might think that the hash tables one gets by loading the compiled
; file could vary with context, which makes it unreasonable to compute them for
; a sub-book before processing events in the main book. But as long as the
; book and all books under it remain certified and unchanged, we expect that
; all relevant values depend essentially only on the closure under ancestors of
; the events in the sub-book.)
; We next consider the question of whether it really buys us anything to save
; compiled definitions for defconst and defmacro forms. The answer is (or can
; be) yes, because macros may have been expanded away. (See the discussion of
; "minimal compilation" in the Common Lisp Hyperspec: it is defined in
; http://www.lispworks.com/documentation/HyperSpec/Body/03_bbb.htm, and it is
; specified for file compilation in #6 of
; http://www.lispworks.com/documentation/HyperSpec/Body/03_bca.htm.) One
; experiment that drives this point home (we have tried GCL and CCL) is the
; following. Consider the following files, and see the comments in the
; commands below them.
; .................... tmp.lsp ....................
; (in-package "ACL2")
; (defun foo (n)
; (cond ((zp n) 1)
; (t (loop for i from 0 to (1- n)
; when (equal (foo i) 2)
; do (return i))
; 1)))
; (defmacro mac () (foo 27))
; .................... tmp2.lsp ...................
; (in-package "ACL2")
; (load "tmp") ; load compiled file
; (defmacro mac2 () (mac))
; .................... tmp3.lsp ...................
; (in-package "ACL2")
; (load "tmp") ; load compiled file
; (defconst *c* (mac))
; .................................................
; Now do the following (with both CCL-based and GCL-based ACL2 images):
; <Start ACL2>
; :q
; (compile-file "tmp.lsp") ; fast
; (quit)
; <Start ACL2>
; :q
; (load "tmp2.lsp") ; slow definition of mac2
; (compile-file "tmp2.lsp") ; slow
; (load "tmp2") ; fast definition of mac2 from compiled file
; (quit)
; <Start ACL2>
; :q
; (load "tmp2") ; fast definition of mac2 from compiled file
; (quit)
; <Start ACL2>
; :q
; (load "tmp3.lsp") ; slow definition of *c*
; (compile-file "tmp3.lsp") ; fast
; (load "tmp3") ; fast
; (quit)
; <Start ACL2>
; :q
; (load "tmp3") ; slow(GCL)/fast(CCL) def of *c* from compiled file
; (load "tmp3") ; faster (some kind of memoization?)
; (quit)
; We conclude this Part with a discussion of some tricky issues for the case
; that an expansion or compiled file is loaded by include-book, i.e., the case
; that a book is being included with a non-nil effective value of
; :load-compiled-file, where by "effective value" we mean the value after
; accounting for state global 'compiler-enabled.
; A stobj may be defined during evaluation of the raw Lisp definition of
; include-book. In that case, the-live-name for that stobj is an add-trip
; symbol, and hence its value is stored in *hcomp-const-ht*. However, the raw
; Lisp definition of defstobj or defabsstobj also assigns to
; *user-stobj-alist*, which we expect will associate the-live-name of a stobj
; with its Lisp relevant value. Now imagine subsequent processing of events by
; the same include-book. When defstobj or defabsstobj is encountered, add-trip
; obtains the value of the-live-name of that stobj from *hcomp-const-ht*, and
; uses that value to update *user-stobj-alist* just as it would if it were
; updating without benefit of *hcomp-const-ht*. The only tricky bit here is
; that we need to ensure that add-trip, along with undo-trip and flush-trip,
; are the only functions that update *user-stobj-alist*. Therefore, we bind
; *user-stobj-alist* to itself when doing an early load of the compiled file or
; expansion file; see include-book-raw.
; If the compiled file or certificate is missing, or else if the compiled file
; is older than the certificate, we may print a warning and go on, assigning
; 'incomplete status to that book in *hcomp-book-ht* -- but there are a couple
; of exceptions. If :load-compiled-file is t for the current book or any
; parent include-book in progress (as recorded by special variable
; *load-compiled-stack*), then we cause an error. If :load-compiled-file is
; not t, then we are content with loading the expansion file in place of the
; compiled file, provided the expansion file is not older than the certificate;
; see load-compiled-book. In that case we obtain interpreted code when
; add-trip reads a hash table for the value to use, for lisps that do not
; compile on-the-fly; but in that case we are really no worse off than if we
; were computing and evaluating the corresponding definition during event
; processing.
; If however the compiled file is up-to-date with respect to the certificate,
; then we may reasonably assume that the compiled file was valid at one time,
; even if the book is now uncertified. (We could gain some confidence that the
; book is certified by insisting that the certificate is not older than the
; book. But some ACL2 users like to update the comments in a book without
; invalidating the certificate.) We load the compiled file with a suitable
; unwind-protect, restoring relevant values after the load completes (whether
; aborted or not). If it turns out that the book is uncertified, say because
; its certificate is out-of-date or is for the wrong ACL2 version, we will
; simply avoid using the hash tables computed when loading its compiled file,
; since we don't trust the relevant values stored in those tables.
; What happens if a compiled file is missing for a sub-book (and, if
; :load-compiled-file is not t, the expansion file is also missing)? Because
; of the possibility of missing packages, at the least, we want to avoid forms
; from the parent book's compiled file (or expansion file -- whichever we are
; loading) that are below the include-book of that sub-book. So, we abort with
; a throw and a warning, associating the partially-constructed hash tables with
; the parent full-book-name in *hcomp-book-ht*, and leaving it to the cleanup
; form of the surrounding unwind-protect to restore symbol-functions in
; existence before the load of the parent book's compiled file. Of course, if
; the parent book is itself a sub-book of a book being included, then its
; parent's load is in turn similarly aborted, and so on up the chain. Note
; that loading the source file in raw Lisp is not an option in general, because
; all of the *hcomp-xxx-alist* setq forms and (hcomp-init) form, not to mention
; that make-event forms in source files are illegal (with the rare exception of
; a consp :check-expansion argument). Again, the expansion file is a good
; candidate for loading if the compiled file is missing, and this is done in
; order to avoid the aborts described above provided we are not under an
; include-book with :load-compiled-file = t.
; Given a top-level include-book event, it may be helpful to visualize all
; included books and sub-books by arranging them into a tree growing downward,
; with the top-level included book as the root at the top, its sub-books as its
; children from left to right in order of their include-book forms in the
; top-level book, and similarly for sub-books of those sub-books, and
; recursively on downward. ACL2 will include books with a depth-first
; left-to-right traversal of this tree. First suppose that the top-level
; include-book form's :load-compile-file argument has an effective value (i.e.,
; accounting for 'compiler-enabled and defaults) other than nil. At the first
; failure to load a compiled file (either because it is missing or it is out of
; date with respect to the .cert file), all parent books up the tree are
; considered to have incomplete loads of their compiled files. However, if
; none of these superior books has a :load-compile-file argument with effective
; value of t, then the partially-populated hash tables are considered
; sufficient and the process continues. To see how warnings and errors are
; handled, suppose we have: book1 includes book2 includes book3 includes book4;
; the compiled file for book4 is missing; and the effective value of
; :load-compile-file for all of these is non-nil. Then we will see a "Compiled
; file" warning unless either book4 or one of its ancestor books (book1, book2,
; book3) has a :load-compile-file argument of t, in which case an error will
; occur.
; We close this introduction with a partial disclaimer. The Common Lisp
; Hyperspec does not seem to specify fully which side effects may be caused by
; DEFUN. Thus, although our approach will install symbol-functions, there
; seems to be no guarantee that it will allow other side-effects caused by
; DEFUN. No such side-effect is critical for ACL2. Nevetheless, it is
; fortunate that some such side-effects may still be handled, as illustrated by
; the following experiment in CCL. First, load a compiled definition of
; function foo from a compiled file, save the symbol-function of foo in
; variable xxx, evaluate (fmakunbound 'foo), and then evaluate (setf
; (symbol-function 'foo) xxx). After all this: if the defun of foo has a Lisp
; documentation string, then (documentation 'foo 'function) will still return
; that string; and if moreover ccl::*save-source-locations* is t, then
; (disassemble 'foo) will give the same nice result both before the fmakunbound
; and after the setf.
; We turn next to describing how compiled (and expansion) files are used when
; including a certified book. We defer to Part 3 an explanation of how
; expansion files are created (and thus, how compiled files are created) during
; book certification.
; In this essay, while we occasionally mention the use of raw mode within a
; book, presumably within a progn! form in the presence of a trust tag, we do
; not consider explicitly the evaluation of include-book forms in raw Lisp.
; This case is simpler than evaluation of include-book forms in the ACL2 loop;
; for example, the value of *hcomp-book-ht* is irrelevant for include-book
; performed in raw mode.
; Part 2: Including a certified book
; Fix a book for the following discussion. An add-trip symbol is "qualified"
; if whenever add-trip is to assign a relevant value by including the book in a
; boot-strap world, that value is equal to relevant value of the symbol if
; instead the compiled file is loaded. An add-trip symbol is "semi-qualified"
; if instead add-trip assigns a relevant value exactly twice, where the second
; value equals the relevant value of the symbol at the time the compiled file
; has just been loaded. This can happen if, and we believe only if (unless
; trust tags or make-event with non-nil :check-expansion are involved), the
; symbol is a *1* function symbol that is defined first in :program mode and
; then in :logic mode, say with verify-termination. We call an add-trip symbol
; "unqualified" if it is neither qualified nor semi-qualified.
; Include-book processes the book's compiled file using the following sequence
; of steps. (See also the summary shortly below this description.)
; First, include-book loads the compiled file:
; (1) Each *hcomp-xxx-alist* is an alist assigned by a form (setq
; *hcomp-xxx-alist* (quote ...)) near the top of the expansion file, after
; the initial (in-package "ACL2") but before the portcullis commands. This
; alist associates values with (and only with) all add-trip symbols: t for
; qualified, 'semi for semi-qualified, and nil for unqualified. Note that
; the values of these setq forms are quoted (laid down during book
; certification); hence the values of these globals are independent of the
; environment in which the compiled file is loaded. We use setq rather
; than defparameter because we have seen defparameter result in a slowdown
; of two orders of magnitude in CCL in doing the early load of compiled
; files.
; (2) Function hcomp-init is called (at load time), to do two things. For one,
; it adds to the *hcomp-xxx-restore-ht* hash tables, so that for each
; add-trip symbol that is not already a key of the suitable such hash
; table, that symbol is associated with its relevant value, if it has one,
; and otherwise is associated with a special "unbound" value,
; *hcomp-fake-value*. Also, it populates each *hcomp-xxx-ht* by
; associating each qualified add-trip symbol with t and each semi-qualified
; add-trip symbol with 'semi. Note that while the set of add-trip symbols
; (as well as their status as qualified, semi-qualified, or unqualified) is
; determined when the compiled file is written, the determination of
; relevant values written to *hcomp-xxx-alist* is done at load time. Also
; note that the domain of each *hcomp-xxx-alist*, representing the set of
; add-trip symbols, is the same as in Step (1).
; (3) Relevant values are assigned by loading the remainder of the compiled
; file, which starts with the portcullis commands. These are wrapped in a
; progn to maximize sharing using #n# syntax.
; Note however that the load may abort with a throw as described earlier above
; (missing compiled file for a sub-book). We'll catch any such throw before
; proceeding with the next step.
; (4) Evaluation of the form (hcomp-transfer-to-hash-tables) updates the
; *hcomp-xxx-ht* hash tables for use by add-trip, as follows. Let sym be
; an add-trip symbol with relevant value val and "qualified" status as
; determined by *hcomp-xxx-alist*. If sym is qualified, then sym is
; associated in *hcomp-xxx-ht* with val. Otherwise, if sym is
; semi-qualified, then sym is associated with the so-called "reclassifying
; value" (*hcomp-fake-value* . val). Otherwise, sym is not a key of the
; hash table.
; After attempting to load all compiled (or expansion) files under a top-level
; such load, ACL2 executes the following step as it cleans up using
; unwind-protection; see include-book-raw-top.
; (5) Relevant values are restored (which could mean making some symbols have
; undefined relevant values) for all add-trip symbols, regardless of
; "qualified" status, to what they were before Step (3), using the
; *hcomp-xxx-restore-ht* alists from Step (2).
; In summary, our alist and hash table globals have values as follows during
; the process of including a certified book. (NOTE that they have different
; values during the process of book certification, as discussed in Part 3
; below.)
; *hcomp-xxx-alist*
; -- Before evaluating hcomp-init (near the top of the expansion file):
; Associates each add-trip symbol with t if qualified, 'semi if
; semi-qualified and otherwise nil
; *hcomp-xxx-ht*
; -- After evaluating hcomp-init (near the top of the expansion file):
; Assigns each qualified add-trip symbol to t and each semi-qualified
; add-trip symbol to 'semi (and these are the only keys)
; -- After loading compiled definitions, hcomp-transfer-to-hash-tables is
; called to populate *hcomp-xxx-ht* by associating a value with each
; qualified or semi-qualified add-trip symbol that has a relevant value,
; val (and only in those cases), as follows:
; + a qualified symbol is bound to val
; + a semi-qualified symbol is bound to the so-called "reclassifying
; value" (*hcomp-fake-value* . val), where val is a :logic mode *1*
; definition
; *hcomp-xxx-restore-ht*
; -- After completing a top-level load of a compiled (or expansion) file:
; Associates each add-trip symbol with its relevant value if any, else to
; *hcomp-fake-value*
; So, how is a relevant value assigned to an add-trip symbol when including a
; certified book? If the symbol is qualified, then its value is obtained from
; the relevant *hcomp-xxx-ht* hash table. Otherwise add-trip proceeds without
; the help of that hash table. However, if the symbol is assigned a
; reclassifying value (*hcomp-fake-value* . val) in the hash table, then even
; though add-trip does not use that value to assign a relevant value, the
; symbol is reassigned to val in the hash table; so if and when subsequently
; this *1* symbol is assigned a :logic-mode value by add-trip it will be val,
; i.e., the symbol will be treated as qualified. That is appropriate because
; if add-trip assigns a new value -- and assuming that redefinition is off,
; which it is unless there is a trust tag -- then the subsequent :logic mode
; definition will be ready for this saved value.
; If raw-mode is entered, then loading the compiled file can assign relevant
; values to symbols other than add-trip symbols. (By the way, we are not
; talking here about memoize and unmemoize, even when #+hons, because these are
; no-ops in raw Lisp.) Upon completion of the above sequence of five steps,
; new relevant values are only assigned for symbols that are not add-trip
; symbols, since as specified in Step (5) above, relevant values for add-trip
; symbols are restored from the *hcomp-xxx-restore-ht* variables after loading
; the compiled files. Users need to manage raw-mode carefully with respect to
; loading compiled files when including a book.
; If future enhancements are to allow add-trip to assign more than one relevant
; value for other than *1* symbols, we expect to be able to deal with such
; cases. If there can in fact be more than two such assignments for the same
; symbol, we can replace a reclassifying value (cons *hcomp-fake-value* val) by
; something like (list* *hcomp-fake-value* count val), where count is initially
; the number of expected re-assignments, it is decremented with each
; assignment, and only when it would be about to decrement to 0 would we
; actually use the hash table's value. Note that some of the initial
; assignments made during certify-book might not be made during include-book,
; because of redundancy, so the last value is the only one that can reliably be
; assigned (if the count ever gets down to 1).
; Part 3: Writing an expansion file for compilation
; We next consider the writing of the expansion file by certify-book. This
; process has three main steps. The first main step is storing relevant values
; in the *hcomp-xxx-ht* hash tables both based on the certification world and
; during the process-embedded-events call during the include-book pass of
; certify-book. The second main step then determines the value of each
; *hcomp-xxx-alist* for the setq forms to be written to the expansion file.
; The third main step actually writes forms to the expansion file. We now
; consider these in turn. Note that we do not access the *hcomp-xxx-alist*
; variables; their part in writing an expansion file is only to occur
; syntactically in the setq forms.
; The first main step populates each *hcomp-xxx-ht*. We begin by let-binding
; each *hcomp-xxx-ht* to its own eq hash table. Then we populate these hash
; tables -- first using the portcullis commands of the certification world,
; then during the process-embedded-events phase of include-book-fn -- updating
; the appropriate hash table for each symbol that is assigned a relevant value
; (because of a 'cltl-command property) by add-trip. (In the case of the
; portcullis commands, we do not actually run add-trip, but rather we mirror
; its necessary effects in function hcomp-build-from-portcullis.) When we
; encounter a symbol that is not already a key of that hash table, then we
; associate it with its relevant value. Otherwise, if the symbol is a *1*
; symbol that already has a value that is not a reclassifying value, and it is
; now being converted from :program to :logic mode, then the symbol is
; associated with the reclassifying value (*hcomp-fake-value* . val), where val
; is its current relevant value. Otherwise the symbol is other than a *1*
; symbol and already has a relevant value -- presumably something unusual has
; occurred by virtue of a trust tag -- and the symbol is associated with
; *hcomp-fake-value*. Note (in particular for the #+hons version) that memoize
; and unmemoize events do not have any effect on the populating of
; *hcomp-xxx-ht*.
; The second main step takes place after the return from
; process-embedded-events, and considers each symbol, sym, and associated value
; in the appropriate *hcomp-xxx-ht*. If the value is a reclassifying value
; (*hcomp-fake-value* . val) and val equals the current relevant value of sym,
; then sym is semi-qualified and is therefore to be associated with 'semi in
; *hcomp-xxx-alist*. For any other value, val, besides *hcomp-fake-value*,
; such that val equals the current relevant value of sym, then sym is qualified
; and is therefore to be associated with t in *hcomp-xxx-alist*. Otherwise VAL
; is unqualified and hence is to be associated with nil in *hcomp-xxx-alist*
; (see function hcomp-alists-from-hts for the check against the current
; relevant value). This last case is likely to be rather unusual, but can
; happen in the #+hons case if memoization occurs after a definition without
; being followed by unmemoization (more on this in the next paragraph). It can
; also happen if a function is redefined in raw-mode, though of course a trust
; tag is needed in that case; but we do not guarantee perfect handling of
; raw-mode, as there might be no raw-mode redefinition during the include-book
; phase of book certification and yet there might be raw-mode redefinition
; later during inclusion of the certified book -- anyhow, uses of raw-mode are
; the user's responsibility. If not for raw-mode, we might simply avoid any
; check and consider every add-trip symbol to be qualified or semi-qualified;
; memoization isn't a problem, since memoize is a no-op in raw Lisp and hash
; tables are populated during early include-books performed in raw Lisp.
; Note that we take a conservative approach, where memoization can make a
; symbol unqualfied. The consequence seems small, since as of this writing,
; memoization is only done in the #+hons version, which is only for ACL2 built
; on CCL, and CCL compiles on-the-fly; so the marking of an add-trip symbol as
; unqualified will not result in interpreted code. A future optimization might
; be to to avoid disqualification due to memoization in suitable cases, perhaps
; by tracking raw-mode or trust tags, or perhaps by somehow taking advantage of
; the 'old-fn field of the *memoize-info-ht* entry.
; It is instructive to consider the case that a :program mode definition is
; redundant with an earlier :logic mode definition made in the book (or its
; portcullis commands), either directly or by way of a redundant encapsulate,
; as per the following example from Jared Davis:
; (encapsulate () (defun f (x) (declare (xargs :mode :program)) x))
; (verify-termination f)
; (encapsulate () (defun f (x) (declare (xargs :mode :program)) x))
; Recall that the *1* functions written to the expansion file are based on the
; definitional event installed at the end of the include-book phase of
; certify-book. In this case, that will be the :logic mode definition; the
; redundant event is properly ignored.
; The third main step, writing forms to the expansion file, is rather
; straightforward based on the discussion above. We bind the current package
; to "ACL2", and then write a sequence of forms as follows.
; - (in-package "ACL2")
; - Forms that introduce packages that may be needed for reading symbols in the
; initial setq forms. These are introduced using maybe-introduce-empty-pkg-1
; and maybe-introduce-empty-pkg-2. The maybe-introduce-empty-pkg-1 forms
; introduce all the packages together, just under the initial in-package
; form, thus avoiding a warning from GCL that can occur unless all defpackage
; forms immediately follow the initial in-package form. The
; maybe-introduce-empty-pkg-2 forms use special variable *defpkg-virgins* to
; let ACL2 know to accept subsequent corressponding defpkg forms.
; - Setq forms for the *hcomp-xxx-alist* variables as described above
; (hcomp-init)
; - Declaim forms (if any)
; - The portcullis commands
; - Book contents, modified according to the expansion-alist in the certificate
; that comes from make-event
; - *1* function definitions from the book (including the portcullis)
; Note that some of these are wrapped together in a progn to maximize sharing
; using #n# syntax.
; End of Essay on Hash Table Support for Compilation
(defun hcomp-init ()
; For context, see the Essay on Hash Table Support for Compilation.
; This function is called during loading of a compiled or expansion file by
; include-book, immediately after assigning alists to the *hcomp-xxx-alist*
; globals. The keys of each alist are the add-trip symbols for its type,
; associating value t if qualified, 'semi if semi-qualified, else nil. This
; function does two things. First, for each of the three alists, it puts an
; entry into the corresponding *hcomp-xxx-alist* hash table, for each key bound
; to non-nil in the alist. Second, it updates *hcomp-fn-restore-ht* to support
; the eventual restoration of relevant values for add-trip symbols. For
; details, see the Essay on Hash Table Support for Compilation.
(when (or (raw-mode-p *the-live-state*)
(null *hcomp-fn-ht*))
; In raw mode, or when loading before compiling for include-book with
; :load-compiled-file :comp, we don't bother with hcomp hash tables and such.
; Rather, we expect that loading of compiled files has the effect one normally
; expects for raw Lisp.
(assert (and (null *hcomp-const-ht*)
(null *hcomp-macro-ht*)))
(return-from hcomp-init nil))
(dolist (pair *hcomp-fn-alist*)
(when (cdr pair)
(setf (gethash (car pair) *hcomp-fn-ht*)
(cdr pair))))
(dolist (pair *hcomp-const-alist*)
(when (cdr pair)
(setf (gethash (car pair) *hcomp-const-ht*)
(cdr pair)))
(when *hcomp-const-restore-ht*
(multiple-value-bind (old present-p)
(gethash (car pair) *hcomp-const-restore-ht*)
(declare (ignore old))
(when (not present-p)
(setf (gethash (car pair) *hcomp-const-restore-ht*)
(cond ((boundp (car pair))
(symbol-value (car pair)))
(t *hcomp-fake-value*)))))))
(dolist (pair *hcomp-macro-alist*)
(when (cdr pair)
(setf (gethash (car pair) *hcomp-macro-ht*)
(cdr pair))))
(when *hcomp-fn-macro-restore-ht*
(dolist (pair (append *hcomp-macro-alist* *hcomp-fn-alist*))
(multiple-value-bind (old present-p)
(gethash (car pair) *hcomp-fn-macro-restore-ht*)
(declare (ignore old))
(when (not present-p)
(setf (gethash (car pair) *hcomp-fn-macro-restore-ht*)
(let ((mac (macro-function (car pair))))
(cond (mac (cons 'macro mac))
((fboundp (car pair))
(cons 'function
(symbol-function (car pair))))
(t *hcomp-fake-value*)))))))))
(defabbrev reclassifying-value-p (x)
; See the Essay on Hash Table Support for Compilation.
(and (consp x)
(eq (car x) *hcomp-fake-value*)))
(defmacro make-reclassifying-value (x)
; See the Essay on Hash Table Support for Compilation.
`(cons *hcomp-fake-value* ,x))
(defmacro unmake-reclassifying-value (x)
; See the Essay on Hash Table Support for Compilation.
`(cdr ,x))
(defun hcomp-transfer-to-hash-tables ()
; See the Essay on Hash Table Support for Compilation.
; This function populates *hcomp-xxx-ht* hash tables with relevant values of
; qualified and semi-qualified add-trip symbols, after including a compiled or
; expansion file.
(dolist (pair *hcomp-fn-alist*)
(let ((qualified (gethash (car pair) *hcomp-fn-ht*)))
(cond ((and qualified
(fboundp (car pair)) ; likely only falsified here by raw mode
)
(setf (gethash (car pair) *hcomp-fn-ht*)
(cond
((eq qualified t)
(symbol-function (car pair)))
(t
(assert$
(eq qualified 'semi)
(make-reclassifying-value
(symbol-function (car pair))))))))
(t (remhash (car pair) *hcomp-fn-ht*)))))
(dolist (pair *hcomp-const-alist*)
(let ((qualified (gethash (car pair) *hcomp-const-ht*)))
(cond ((and qualified
(boundp (car pair)) ; likely only falsified here by raw mode
)
(setf (gethash (car pair) *hcomp-const-ht*)
(assert$
(eq qualified t)
(symbol-value (car pair)))))
(t (remhash (car pair) *hcomp-const-ht*)))))
(dolist (pair *hcomp-macro-alist*)
(let ((qualified (gethash (car pair) *hcomp-macro-ht*)))
(cond ((and qualified
(macro-function (car pair)) ; raw mode check, as above
)
(setf (gethash (car pair) *hcomp-macro-ht*)
(assert$
(eq qualified t)
(macro-function (car pair)))))
(t (remhash (car pair) *hcomp-macro-ht*))))))
(defvar *saved-hcomp-restore-hts* nil)
(defun hcomp-restore-defs ()
; See the Essay on Hash Table Support for Compilation.
; This function undoes the effect of loading compiled and expansion files, in
; the sense that it restores relevant values: every add-trip symbol is given
; the relevant value it had before loading these, if any, else is unbound.
; The variable *saved-hcomp-restore-hts* should have just been been assigned to
; the current value of (list* *hcomp-fn-macro-restore-ht*
; *hcomp-const-restore-ht*).
(when (null *saved-hcomp-restore-hts*)
(er hard 'hcomp-restore-defs
"Apparently an interrupt has occurred at exactly the right time to ~
thwart ACL2's attempt to clean up by removing certain definitions in ~
raw Lisp. You are strongly advised to restart ACL2. You could ~
instead try to continue, but you might well encounter errors ~
regarding having definitions in raw Common Lisp."))
(let ((fn-macro-restore-ht (car *saved-hcomp-restore-hts*))
(const-restore-ht (cdr *saved-hcomp-restore-hts*)))
(when fn-macro-restore-ht
(maphash (lambda (k val)
(cond ((eq val *hcomp-fake-value*)
; We use fmakunbound! instead of fmakunbound in case trust tags have allowed
; some raw Lisp code to overwrite a function definition with a macro
; definition.
(fmakunbound! k))
((eq (car val) 'macro)
(setf (macro-function k) (cdr val)))
(t ; (eq (car val) 'function)
(fmakunbound! k) ; remove potential macro-function
(setf (symbol-function k) (cdr val)))))
fn-macro-restore-ht))
(when const-restore-ht
(maphash (lambda (k val)
(cond ((eq val *hcomp-fake-value*)
(remprop k 'redundant-raw-lisp-discriminator)
(makunbound k))
(t
; The 'redundant-raw-lisp-discriminator property may be wrong here; but really,
; we don't expect this case to occur, since redefinition with defconst is not
; supported (unless perhaps extraordinary measures are taken using trust
; tags).
(setf (symbol-value k) val))))
const-restore-ht))
nil))
(defun missing-compiled-book (ctx file reason-msg load-compiled-file state)
; This function is called when a compiled file is missing from an attempt to
; include a book. It either causes an error (because of an include-book called
; with :load-compiled-file t) or returns INCOMPLETE, which may be convenient
; when this result is to be placed into the status field of an
; hcomp-book-ht-entry record or is to be the value returned by
; load-compiled-book or include-book-raw.
; For convenience, we also use this function to report failure to complete the
; load of a compiled file when such a failure has previously been reported, but
; no such report has yet been made involving the files above that missing
; compiled file. In this case we pass reason-msg = nil. However, we do not
; expect this case to arise; see the comment about "flaw in our thinking" in
; include-book-raw.
; Warning: Do not change the message printed in the case reason-msg = nil
; without reading the comment in *uninhibited-warning-summaries* about
; "Compiled file".
(let ((see-doc " See :DOC include-book."))
(cond ((null load-compiled-file)
(er hard ctx
"Implementation error: the LOAD-COMPILED-FILE argument is ~x0 ~
in call ~x1."
nil
`(missing-compiled-book ',ctx ',file ',reason-msg
',load-compiled-file state)))
((or (eq load-compiled-file t)
(rassoc-eq t *load-compiled-stack*))
(let ((stack-msg
(cond ((eq load-compiled-file t)
(tilde-@-book-stack-msg t *load-compiled-stack*))
(t
(tilde-@-book-stack-msg
(car (rassoc-eq t *load-compiled-stack*))
*load-compiled-stack*)))))
(cond (reason-msg
(er hard ctx
"Unable to load compiled file~| ~s0~|because ~@1.~@2~@3"
file reason-msg see-doc stack-msg))
(t
(er hard ctx
"Unable to complete load of compiled file for book~|~ ~ ~
~s0,~|as already noted by a warning.~@1~@2"
file see-doc stack-msg)))))
(reason-msg
(warning$ ctx "Compiled file"
"Unable to load compiled file for book~| ~s0~|because ~
~@1.~@2~@3"
file
reason-msg
see-doc
(tilde-@-book-stack-msg nil *load-compiled-stack*)))
(t
(warning$ ctx "Compiled file"
"Unable to complete load of compiled file for book~| ~
~s0,~|as already noted by a previous warning.~@1"
file
(tilde-@-book-stack-msg nil *load-compiled-stack*)))))
'incomplete)
(defun load-compiled-book (file directory-name load-compiled-file ctx state)
; We are processing include-book-raw underneath include-book-fn (hence
; presumably not in raw mode). File is an ACL2 full-book-name and
; load-compiled-file is non-nil. We attempt to load the corresponding compiled
; or perhaps expansion file if not out of date with respect to the book's
; certificate file. Normally, we return COMPLETE if such a suitable compiled
; file or expansion file exists and is loaded to completion, but if file is the
; book being processed by a surrounding include-book-fn and compilation is
; indicated because load-compiled-file is :comp and the expansion file is
; loaded (not the compiled file), then we return TO-BE-COMPILED in that case.
; Otherwise we return INCOMPLETE, that is, either no load is attempted for the
; compiled or expansion file (because they don't exist or are out of date), or
; else such a load but is aborted partway through, which can happen because of
; an incomplete load of a subsidiary include-book's compiled or expansion file.
; As suggested above, we may allow the corresponding expansion file to take the
; place of a missing or out-of-date compiled file. However, we do not allow
; this if load-compiled-file is t or a parent include-book has
; :load-compiled-file t.
(assert load-compiled-file)
(mv-let
(cfile state)
(certificate-file file state)
(let* ((os-file (pathname-unix-to-os file state))
(cfile-date (and cfile (file-write-date cfile)))
(ofile (convert-book-name-to-compiled-name os-file state))
(ofile-exists (probe-file ofile))
(ofile-date (and ofile-exists (file-write-date ofile)))
(ofile-p (and ofile-date cfile-date (>= ofile-date cfile-date)))
(efile (and (not (eq load-compiled-file t))
(expansion-filename file t state)))
(efile-exists (and efile (probe-file efile)))
(file-is-older-str
"the file-write-date of ~x0 is less than that of ~x1"))
(cond
((not cfile)
(missing-compiled-book ctx
file
"that book is not certified"
load-compiled-file
state))
((and (not ofile-exists)
(not efile-exists))
(missing-compiled-book ctx
file
"the compiled file does not exist"
load-compiled-file
state))
((not cfile-date)
(missing-compiled-book
ctx
file
(msg "~x0 is ~x1 (which is odd since file ~x2 exists)"
`(file-write-date ,cfile)
nil
cfile)
load-compiled-file
state))
((not (or ofile-p
(let ((efile-date (and efile-exists (file-write-date efile))))
(and efile-date (>= efile-date cfile-date)))))
(cond
(ofile-exists
(missing-compiled-book
ctx
file
(msg file-is-older-str ofile cfile)
load-compiled-file
state))
(t ; hence efile-exists
(missing-compiled-book
ctx
file
(msg "the compiled file does not exist and ~@0"
(msg file-is-older-str efile cfile))
load-compiled-file
state))))
((and (not ofile-p) ; hence efile is suitable to load, except:
(rassoc-eq t *load-compiled-stack*))
(missing-compiled-book
ctx
file
(if ofile-exists
"that compiled file does not exist"
"that compiled file is out-of-date")
load-compiled-file
state))
(t ; either ofile or efile is suitable for loading
(let ((to-be-compiled-p ; true at top level of include-book-fn with :comp
(and (not ofile-p)
(null *load-compiled-stack*)
(eq load-compiled-file :comp)))
(status 'incomplete))
(when (and (not ofile-p)
(not to-be-compiled-p))
; Hence efile is suitable and we are not in the special case of compiling it on
; behalf of include-book-fn. Note that for the case of compiling on behalf of
; include-book-fn, either that compilation will succeed or there will be an
; error -- either way, there is no need to warn here.
(warning$ ctx "Compiled file"
"Loading expansion file ~x0 in place of compiled file ~
~x1, because ~@2."
efile ofile
(cond (ofile-exists
(msg file-is-older-str ofile cfile))
(t
(msg "the compiled file is missing")))))
(catch 'missing-compiled-book
; bogus compiler warning in LispWorks 6.0.1, gone in LispWorks 6.1
(state-global-let*
((raw-include-book-dir-alist nil)
(connected-book-directory directory-name))
(let ((*load-compiled-stack* (acons file
load-compiled-file
*load-compiled-stack*)))
(cond (ofile-p (load-compiled ofile t))
(t (with-reckless-read (load efile))))
(value (setq status (if to-be-compiled-p
'to-be-compiled
'complete))))))
(hcomp-transfer-to-hash-tables)
(assert$ (member-eq status '(to-be-compiled complete incomplete))
status)))))))
(defun include-book-raw (book-name directory-name load-compiled-file dir ctx
state)
; This function is generally called on behalf of include-book-fn. No load
; takes place if load-compiled-file is effectively nil (either nil or else
; compiler-enabled is nil) unless we are in raw mode, in which case we attempt
; to load the source file, book-name. So suppose load-compiled-file is not
; nil. When the call is not under certify-book-fn, the effect is to populate
; *hcomp-book-ht* with *hcomp-xxx-ht* hash tables for the given book and
; (recursively) all its sub-books; see the Essay on Hash Table Support for
; Compilation. Otherwise its effect is as follows: load the compiled file if
; it exists and is up-to-date with respect to the certificate, else load the
; expansion file, else (but only in raw mode) load the source book. (The
; *hcomp-xxx* variables are irrelevant, by the way, if we are not calling
; add-trip or otherwise involving ACL2 event processing.)
; If directory-name is nil, then book-name is a user-book-name. Otherwise
; book-name is a full-book-name whose directory is directory-name.
; Load-compiled-file and dir are the arguments of these names from
; include-book.
; Now suppose that we are not in raw mode, i.e., we are evaluating this call
; underneath some call of include-book-fn. We return nil if no load is
; attempted, for example because load-compiled-file is effectively nil. If the
; compiled file or expansion file is loaded in its entirety, then we return
; 'complete. Otherwise we throw to the tag 'missing-compiled-book with the
; status 'incomplete.
(when (not (member-eq load-compiled-file *load-compiled-file-values*))
(er hard ctx
"The only legal values for the :LOAD-COMPILED-FILE keyword argument ~
of ~x0 are ~&1. The value ~x2 is thus illegal."
'include-book
*load-compiled-file-values*
load-compiled-file))
(when *compiling-certified-file*
; See the comment below related to *compiling-certified-file*.
(return-from include-book-raw nil))
(let* ((raw-mode-p (raw-mode-p state))
(load-compiled-file
(cond ((null (f-get-global 'compiler-enabled state))
nil)
((eq load-compiled-file :default)
:warn)
(t (or load-compiled-file
; If load-compiled-file is nil but we are in the process of loading the
; compiled file for a superior book, then there is an include-book for such a
; book, B, with a non-nil value of :load-compiled-file. Even if that value is
; :warn or :comp, hence not t, we still need to try to load a compiled file for
; the present book; of course, if a compiled file is missing for the present
; book or any sub-book, then whether that causes an error or only a warning
; depends on whether some such book B has :load-compiled-file t.
(and *load-compiled-stack*
:warn))))))
(when (and (not raw-mode-p)
(null load-compiled-file))
(return-from include-book-raw nil))
(mv-let
(full-book-name directory-name ignore-familiar-name)
(cond (directory-name (mv book-name directory-name nil))
(t (parse-book-name
(cond (dir (or (include-book-dir dir state)
(er hard ctx
"Unable to find the :dir argument to ~
include-book, ~x0, which should have been ~
defined by add-include-book-dir. Perhaps ~
the book ~x1 needs to be recertified."
dir
book-name)))
(t (f-get-global 'connected-book-directory state)))
book-name ".lisp" ctx state)))
(declare (ignore ignore-familiar-name))
(cond
((let ((true-full-book-name (our-truename full-book-name :safe)))
(and true-full-book-name
(assoc-equal true-full-book-name
(global-val 'include-book-alist (w state)))))
; In ACL2 Version_4.1 running on Allegro CL, we got an error when attempting to
; certify the following book.
; (in-package "ACL2")
; (include-book "coi/lists/memberp" :dir :system)
; The problem was that truename is (one might say) broken in Allegro CL.
; Fortunately, Allegro CL provides an alternative that seems to work --
; excl::pathname-resolve-symbolic-links -- and we now use that function (see
; our-truename). The problem goes away if that function is applied to
; full-book-name under the call of assoc-equal below. But the error occurred
; in the context of loading a file just compiled from a book, and in that
; context there is no reason to execute any raw-Lisp include-book. Thus, we
; short-circuit in that case -- see the use of *compiling-certified-file* above
; -- and now we never even get to the above assoc-equal test in that case.
; A final comment in the case that we really do get to this point:
; Since all relevant values have been defined, there is no need to transfer to
; hash tables (as per the Essay on Hash Table Support for Compilation). This
; is the case even if we loaded in raw-mode. It would be harmless enough to
; load in the raw-mode case, and could be desirable if values are
; context-dependent and it is expected that we re-load, but for now we avoid
; the inefficiency of repeated loads.
nil)
((or raw-mode-p
; If *hcomp-book-ht* is nil and we are not in raw mode, then we are under an
; include-book-fn being performed on behalf of certify-book. In that case we
; just do a load as we would in raw Lisp, without regard to the hash tables
; described in the Essay on Hash Table Support for Compilation.
(null *hcomp-book-ht*))
(state-free-global-let*
((connected-book-directory directory-name))
(let* ((os-file (pathname-unix-to-os full-book-name state))
(ofile (convert-book-name-to-compiled-name os-file state))
(os-file-exists (probe-file os-file))
(ofile-exists (probe-file ofile))
(book-date (and os-file-exists (file-write-date os-file)))
(ofile-date (and ofile-exists (file-write-date ofile))))
(cond ((not os-file-exists)
(er hard ctx
"File ~x0 does not exist."
os-file))
((null load-compiled-file)
(assert$ raw-mode-p ; otherwise we already returned above
; If make-event is used in the book, then the following load may cause an
; error. The user of raw mode who supplied a :load-compiled-file argument is
; responsible for the ensuing behavior.
(load os-file)))
((and book-date
ofile-date
(<= book-date ofile-date))
(load-compiled ofile t))
(t (let ((reason (cond (ofile-exists
"the compiled file is not at least as ~
recent as the book")
(t "the compiled file does not exist"))))
(cond ((eq load-compiled-file t)
(er hard ctx
"The compiled file for ~x0 was not loaded ~
because ~@1."
reason))
(t (let* ((efile (expansion-filename
full-book-name t state))
(efile-date (and (probe-file efile)
(file-write-date efile)))
(efile-p (and book-date
efile-date
(<= book-date efile-date)))
(lfile (cond (efile-p efile)
(raw-mode-p os-file)
(t
(er hard ctx
"Implementation error: ~
We seem to have ~
called ~
include-book-raw on ~
book ~x0 with non-nil ~
load-compiled-file ~
argument under the ~
include-book-fn call ~
in certify-book-fn."
book-name)))))
(warning$ ctx "Compiled file"
"Attempting to load ~@0 instead of ~
the corresponding compiled file, ~
because ~@1."
(msg (cond
(efile-p "expansion file ~x0")
(t "source file ~x0"))
lfile)
reason)
(cond (efile-p
(with-reckless-read (load efile)))
(raw-mode-p (load os-file))))))))))))
((let* ((entry (assert$ *hcomp-book-ht* ; not raw mode, e.g.
(gethash full-book-name *hcomp-book-ht*)))
(status (and entry
(access hcomp-book-ht-entry entry :status))))
; The status might be nil because of soft links, in analogy to the case for
; soft links described in a comment above. But as explained in that comment,
; this is harmless; it would simply cause us to fall through and deal with the
; book as though it's newly encountered.
; Below, when status is nil then it is because entry is nil, in which case it
; is correct to fall through to the next top-level COND branch. See (defrec
; hcomp-book-ht-entry ...) for a comment on the legal (hence non-nil) status
; values.
(cond (raw-mode-p
status) ; if nil then there is no entry, so fall through
((and
(eq status 'incomplete) ; so not from raw-mode include-book
*load-compiled-stack*)
; Can the status really be INCOMPLETE? At first glance it would seem this this
; is impossible. For, imagine that we are loading a book's compiled file (or
; expansion file) in raw Lisp prior to processing its events. At the first
; INCOMPLETE status, the tree of include-book forms rooted at that top
; include-book is no longer consulted -- no further loads occur anywhere to the
; right of the branch above the node on which the INCOMPLETE status is
; returned. Ah, but perhaps the topmost include-book has :load-compiled-file
; nil. The argument above shows that any book with existing INCOMPLETE status
; must have been processed by some earlier include-book having non-nil
; :load-compiled-file. But then the offending book has already been included,
; and hence no raw-Lisp load will take place, since the offending book is on the
; 'include-book-alist of the current world.
; But we keep this case, just in case we later find a flaw in our thinking!
; (If this comment is removed, consider the reference to "flaw in our thinking"
; in function missing-compiled-book.)
(error "Implementation error; see include-book-raw.")
; Code we keep in case our thinking above is flawed:
(throw 'missing-compiled-book
(missing-compiled-book ctx full-book-name nil
load-compiled-file state)))
(t status))))
(t ; not raw-mode, and load-compiled-file is non-nil
(with-hcomp-bindings
t
(let ((status
(let ((*user-stobj-alist*
; Our intention is that the call of load-compiled-book below has no effect on
; the state other than to define some packages and populate *hcomp-xxx-ht* hash
; tables. We therefore protect the one global managed by add-trip that is not
; managed by those hash tables: *user-stobj-alist*. See the Essay on Hash
; Table Support for Compilation.
*user-stobj-alist*))
(load-compiled-book full-book-name directory-name
load-compiled-file ctx state))))
(setf (gethash full-book-name *hcomp-book-ht*)
(make hcomp-book-ht-entry
:status status
:fn-ht *hcomp-fn-ht*
:const-ht *hcomp-const-ht*
:macro-ht *hcomp-macro-ht*))
(cond ((member-eq status '(to-be-compiled complete))
status)
(status
(assert$ (eq status 'incomplete)
(cond (*load-compiled-stack*
(throw 'missing-compiled-book 'incomplete))
(t 'incomplete))))))))))))
(defun include-book-raw-top (full-book-name directory-name load-compiled-file
dir ctx state)
(let ((*hcomp-fn-macro-restore-ht* (make-hash-table :test 'eq))
(*hcomp-const-restore-ht* (make-hash-table :test 'eq)))
; We need to be careful about handling interrupts. On the one hand, we want to
; take advantage of the "idempotency" provided by acl2-unwind-protect that is
; described in The Unwind-Protect Essay. On the other hand, cleanup forms of
; acl2-unwind-protect will be evaluated outside the scope of the bindings just
; above. Our solution is for an unwind-protect cleanup form to do nothing more
; than save the above three hash tables -- which we expect can complete without
; interruption, though we check for that in hcomp-restore-defs -- and then for
; acl2-unwind-protect to do the actual cleanup using those saved values.
(setq *saved-hcomp-restore-hts* nil)
(acl2-unwind-protect
"include-book-raw"
(unwind-protect
(progn (include-book-raw
full-book-name directory-name
load-compiled-file dir ctx state)
(value nil))
(setq *saved-hcomp-restore-hts*
(list* *hcomp-fn-macro-restore-ht*
*hcomp-const-restore-ht*)))
(progn (hcomp-restore-defs)
(setq *saved-hcomp-restore-hts* nil)
state)
(progn (hcomp-restore-defs)
(setq *saved-hcomp-restore-hts* nil)
state))))
(defmacro hcomp-ht-from-type (type ctx)
`(case ,type
(defun *hcomp-fn-ht*)
(defparameter *hcomp-const-ht*)
((defmacro defabbrev) *hcomp-macro-ht*)
(otherwise (er hard ,ctx
"Implementation error: Unknown case, ~x0."
,type))))
(defmacro hcomp-build-p ()
'(and (eq *inside-include-book-fn* 'hcomp-build) ; under certify-book-fn
*hcomp-fn-ht* ; compile-flg is true
))
(defun install-for-add-trip-hcomp-build (def reclassifyingp evalp)
; Def is a definition starting with defun, defconst, defmacro, or defabbrev.
(let* ((type (car def))
(name (cadr def))
(ht (hcomp-ht-from-type type 'install-for-add-trip-hcomp-build))
(oldp (and (eq type 'defparameter)
(boundp name))))
(when evalp
(eval def))
(assert ht)
(multiple-value-bind (old present-p)
(gethash name ht)
(cond ((eq old *hcomp-fake-value*)) ; then we keep the fake value
(present-p (cond ((and reclassifyingp
(not (reclassifying-value-p old)))
(assert$ (eq type 'defun)
; We expect a *1* function here. If that is not the case (for some odd reason
; we don't foresee), then we will be making a reclassifying value here that
; presumably won't get used.
(setf (gethash name ht)
(make-reclassifying-value
(symbol-function name)))))
(t
; This case is presumably impossible unless raw mode is used somehow to allow
; redefinition. But we are conservative here.
(setf (gethash name ht)
*hcomp-fake-value*))))
(oldp
; Name is already boundp, perhaps even by a defattach in the ACL2 source code.
; Handling of this case supports our fix for a bug described in note-4-2:
; "Fixed a bug in which the wrong attachment could be made...." We hit that
; bug when we tried to attach to acl2x-expansion-alist upon including the
; community book books/make-event/acl2x-help.lisp (see the defattach there for
; that function), causing certification to fail for
; books/make-event/acl2x-help.lisp. That certification failed because the
; attachment was getting its value from *hcomp-const-ht*, which had not seen
; that attachment because the load was aborted due to a missing compiled file
; for a book included under acl2x-help.lisp. Perhaps we should never put a
; defparameter for a defattach into *hcomp-const-ht*, but anyhow, the following
; setf handles the issue.
(setf (gethash name ht)
*hcomp-fake-value*))
(t
(setf (gethash name ht)
(case type
(defun (symbol-function name))
(defparameter (symbol-value name))
(otherwise (macro-function name)))))))))
(defun install-for-add-trip-include-book (type name def reclassifyingp)
; Def is nil if no evaluation of a definition is desired, in which case we
; return true when the definition exists in the appropriate hash table.
; Otherwise def is a definition starting with defun, defconst, defmacro, or
; defabbrev.
(let ((ht (hcomp-ht-from-type type 'install-for-add-trip-include-book)))
(when (null ht) ; e.g., including uncertified book
(return-from install-for-add-trip-include-book
(when def (eval def))))
(multiple-value-bind (val present-p)
(gethash name ht)
(cond
(present-p
(assert$
(not (eq val *hcomp-fake-value*))
(cond
((reclassifying-value-p val)
(assert$
(eq type 'defun) ; presumably a *1* symbol
(let ((fixed-val (unmake-reclassifying-value val)))
(setf (gethash name ht) fixed-val)
(cond (reclassifyingp
; We are converting the definition of some function, F, from :program mode to
; :logic mode. Since reclassifying-value-p holds of val, the book (including
; its portcullis commands) contains both a :program mode definition of F and a
; :logic mode definition of F, and so far we have processed neither while
; including this book. Since parameter reclassifyingp is true, we are now
; converting F from :program mode to :logic mode, which may seem surprising
; given that we have not processed the earlier :program mode definition in the
; book. The situation however is that now, we are including this book in a
; world where F was already defined in :program mode. Since we are now
; reclassifying to :logic mode, there is no need to go through the usual
; two-step process; rather, we can simply define the function now. We probably
; don't need to modify the hash table in this case (as we did above); but this
; case is probably unusual so the potential efficiency hit seems trivial, and
; it seems safest to go ahead and keep only the true value in the hash table
; henceforth.
(setf (symbol-function name) fixed-val)
t)
(t (when def (eval def)))))))
(t (case type
(defun
(setf (symbol-function name) val))
(defparameter
(setf (symbol-value name)
(cond ((and (consp (caddr def))
(eq (car (caddr def)) 'quote))
; Remark on Fast-alists.
; We get here from processing of an add-trip form by defconst, immediately
; after setting the 'redundant-raw-lisp-discriminator property for the symbol
; being defined. Now, the raw Lisp definition of defconst (which may be
; invoked during early load of compiled files later in the session) insists
; that the cddr above property agree with (be EQ to) the symbol's symbol-value.
; In the case of a quotep, these are both to be EQ to the cadr of that quotep,
; in support of the #+hons version of ACL2, as described below. So in this
; quotep case, we avoid the value stored in the hash table, i.e., the value
; produced by the compiler.
; To see why we want to avoid the value produced by the compiler in the #+hons
; case, consider the following event.
; (make-event
; `(defconst *foo* ',(make-fast-alist '((1 . 10) (2 . 20)))))
; The intention here is to store a fast-alist in *foo*, and the serialize
; reader supports this when reading from the expansion-alist in the book's
; certificate, where the above fast-alist will be stored. However, that
; fast-alist nature of this constant is lost when the alist comes from the
; book's compiled file.
; See also related comments in defconst-val, make-certificate-file1.
(cadr (caddr def)))
(t val))))
(otherwise
(assert$ (member-eq type '(defabbrev defmacro))
(setf (macro-function name) val))))
t))))
(t (when def (eval def)))))))
(defun install-for-add-trip (def reclassifyingp evalp)
; For background on how we use hash tables to support early loading of compiled
; files by include-book, see the Essay on Hash Table Support for Compilation.
; Evalp is only relevant when (hcomp-build), in which case it is passed to
; install-for-add-trip-hcomp-build.
(cond
((eq *inside-include-book-fn* t) ; in include-book-fn, not certify-book-fn
(install-for-add-trip-include-book (car def) (cadr def) def
reclassifyingp))
((hcomp-build-p)
(install-for-add-trip-hcomp-build def reclassifyingp evalp))
(t (eval def))))
(defun install-defs-for-add-trip (defs reclassifying-p wrld declaim-p evalp)
; Defs is a list of definitions, each of which is a call of defun, defabbrev,
; or defmacro, or else of the form (ONEIFY-CLTL-CODE defun-mode def
; stobj-name), where def is the cdr of a call of defun.
; This function, which may destructively modify defs, is responsible for
; declaiming and submitting every definition in defs, while avoiding such
; effort when a definition is already available from *hcomp-fn-ht*. Note that
; if its definition is available from that hash table, then it was already
; declaimed (if necessary) during the load of the expansion file (or the
; compiled version of it) that populated that hash table with its definition.
; The only time we retrieve an existing definition from *hcomp-fn-ht* is during
; include-book-fn but not during certify-book-fn, i.e., when
; *inside-include-book-fn* is t.
; Evalp is only relevant when (hcomp-build),in which case it is passed to
; install-for-add-trip-hcomp-build.
; We start with declaiming of inline and notinline.
(loop for tail on defs
do
(let* ((def (car tail))
(oneify-p (eq (car def) 'oneify-cltl-code))
(def0 (if oneify-p (caddr def) (cdr def)))
(name (symbol-name (car def0))))
(cond ((equal (caddr def0)
'(DECLARE (XARGS :NON-EXECUTABLE :PROGRAM)))
; We allow redefinition for a function introduced by :defproxy, regardless of
; the value of state global 'ld-redefinition-action. If the original
; definition were inlined, then this redefinition might be ignored, and it
; could reasonably be viewed as our fault, because we would not be able to say
; "all bets are off with the use of ld-redefinition-action".
; If we change or remove this proclaim form, then revisit the comment about
; inlining in redefinition-renewal-mode.
(let ((form (list 'notinline
(if oneify-p
(*1*-symbol (car def0))
(car def0)))))
(proclaim form)
(push (list 'declaim form) *declaim-list*)))
(oneify-p nil)
((terminal-substringp *inline-suffix*
name
*inline-suffix-len-minus-1*
(1- (length name)))
(let ((form (list 'inline (car def0))))
(proclaim form)
(push (list 'declaim form) *declaim-list*)))
((terminal-substringp *notinline-suffix*
name
*notinline-suffix-len-minus-1*
(1- (length name)))
(let ((form (list 'notinline (car def0))))
(proclaim form)
(push (list 'declaim form) *declaim-list*))))))
(loop for tail on defs
do
(let* ((def (car tail))
(oneify-p (eq (car def) 'oneify-cltl-code))
(def0 (if oneify-p (caddr def) (cdr def))))
(cond ((and (eq *inside-include-book-fn* t)
(if oneify-p
(install-for-add-trip-include-book
'defun
(*1*-symbol (car def0))
nil
reclassifying-p)
(install-for-add-trip-include-book
(car def)
(cadr def)
nil
reclassifying-p)))
(setf (car tail) nil))
(t (let (form)
(cond
(oneify-p
(let ((*1*-def (cons 'defun
(oneify-cltl-code (cadr def)
def0
(cdddr def)
wrld))))
(setf (car tail) *1*-def)
; While it is tempting to do a declaim for a *1* function,
; make-defun-declare-form isn't up to the task as of the development sources on
; 5/2/2013. Perhaps this would be easy to fix, but since we only declaim for
; GCL, and it is not an important goal to make *1* functions efficient, we skip
; this step.
; (when declaim-p
; (setq form
; (make-defun-declare-form (car def0)
; *1*-def)))
))
((and declaim-p
(not (member-eq (car def)
'(defmacro defabbrev))))
(setq form (make-defun-declare-form (cadr def) def))))
(when (and form (hcomp-build-p))
(push form *declaim-list*))
(when evalp
(eval form)))))))
(cond ((eq *inside-include-book-fn* t)
(loop for tail on defs
when (car tail)
do (eval (car tail))))
((hcomp-build-p)
(loop for def in defs
do
(install-for-add-trip-hcomp-build def reclassifying-p evalp)))
(t
(loop for def in defs
do (eval def)))))
(defun hcomp-build-from-portcullis-raw (cltl-cmds state)
; Warning: If you change this function, consider making corresponding changes
; to add-trip. We wrote the present function primarily by eliminating extra
; code from the definition of add-trip, to satisfy the following spec. We also
; eliminated comments; see add-trip for those.
; Cltl-cmds is a list of cltl-command values, each the cddr of some triple in
; the world. We are certifying a book, and we want to populate the
; *hcomp-xxx-ht* hash-tables much as we do when processing events in the book.
; We also start populating *declaim-list*.
(let ((*inside-include-book-fn* 'hcomp-build))
(dolist (cltl-cmd cltl-cmds)
(let* ((wrld (w state)))
(case (car cltl-cmd)
(defuns
(let ((ignorep (caddr cltl-cmd))
(defun-mode (cadr cltl-cmd))
(new-defs nil)
(new-*1*-defs nil))
(dolist
(def (cdddr cltl-cmd))
(cond ((and (consp ignorep)
(eq (car ignorep) 'defstobj))
nil)
(t
(or ignorep
(setq new-defs (cons (cons 'defun def)
new-defs)))
(setq new-*1*-defs
(cons (list* 'oneify-cltl-code
defun-mode
def
(if (consp ignorep)
(cdr ignorep)
nil))
new-*1*-defs)))))
(install-defs-for-add-trip (nconc new-defs new-*1*-defs)
(eq ignorep 'reclassifying)
wrld t nil)))
((defstobj defabsstobj)
(let ((name (nth 1 cltl-cmd))
(the-live-name (nth 2 cltl-cmd))
(init (nth 3 cltl-cmd))
(raw-defs (nth 4 cltl-cmd))
(ax-defs (nth 6 cltl-cmd))
(new-defs nil))
(install-for-add-trip `(defparameter ,the-live-name ,init)
nil
nil)
(dolist
(def raw-defs)
(push (cond ((eq (car cltl-cmd) 'defabsstobj)
(cons 'defmacro def))
((member-equal *stobj-inline-declare* def)
(cons 'defabbrev
(remove-stobj-inline-declare def)))
(t (cons 'defun def)))
new-defs))
(dolist
(def ax-defs)
(push (list* 'oneify-cltl-code :logic def name)
new-defs))
(setq new-defs (nreverse new-defs))
(install-defs-for-add-trip new-defs nil wrld t nil)))
(defconst
(install-for-add-trip `(defparameter ,(cadr cltl-cmd)
',(cadddr cltl-cmd))
nil
nil))
(defmacro
(install-for-add-trip cltl-cmd nil nil))
(attachment ; (cddr trip) is produced by attachment-cltl-cmd
(dolist (x (cdr cltl-cmd))
(let ((name (if (symbolp x) x (car x))))
(install-for-add-trip
(cond ((symbolp x)
(set-attachment-symbol-form x nil))
(t (set-attachment-symbol-form name (cdr x))))
nil
nil))))
; There is nothing to do for memoize or unmemoize.
))))
(value nil))
(defun hcomp-alists-from-hts ()
(let ((fn-alist nil)
(const-alist nil)
(macro-alist nil))
(maphash (lambda (k val)
(push (cons k
(cond ((eq val *hcomp-fake-value*)
nil)
((not (fboundp k))
nil)
((reclassifying-value-p val)
(and (eq (unmake-reclassifying-value val)
(symbol-function k))
'semi))
((eq val (symbol-function k))
t)
(t nil)))
fn-alist))
*hcomp-fn-ht*)
(maphash (lambda (k val)
(push (cons k
(cond ((eq val *hcomp-fake-value*)
nil)
((not (boundp k))
nil)
((eq val (symbol-value k))
t)
(t nil)))
const-alist))
*hcomp-const-ht*)
(maphash (lambda (k val)
(push (cons k
(cond ((eq val *hcomp-fake-value*)
nil)
((and val
(eq val (macro-function k)))
t)
(t nil)))
macro-alist))
*hcomp-macro-ht*)
(mv fn-alist const-alist macro-alist)))
; This concludes development of code for early loading of compiled files
; (though other related such code may be found elsewhere).
(defun-one-output add-trip (world-name world-key trip)
; Warning: If you change this function, consider making corresponding changes
; to hcomp-build-from-portcullis-raw.
; Add-trip is the function that moves a triple, (symb key . val) from
; a property list world into the von Neumann space of Common Lisp.
; World-name is the name of the world being installed. World-key is
; the property being used to hold the installed properties of that
; world (i.e., the cdr of its 'acl2-world-pair).
; First we set the properties for the global-symbol and *1*-symbol, so that
; these will ultimately be behind the world-key property (as guaranteed at the
; end of the code for this function).
(global-symbol (car trip))
(*1*-symbol? (car trip)) ; e.g. hard-error for *1*-symbol with (table :a 3 4)
; Our next step is to push val onto the key stack in (get symb world-key).
(setf (get (car trip) world-key)
(destructive-push-assoc (cadr trip) (cddr trip)
(get (car trip) world-key)
world-key))
; Now, in the case that we are messing with 'current-acl2-world and
; symb is 'CLTL-COMMAND and key is 'GLOBAL-VALUE, we smash the
; symbol-function or symbol-value cell of the appropriate name, first
; saving the old value (form) on the undo-stack.
(cond
((and (eq world-name 'current-acl2-world)
(eq (car trip) 'cltl-command)
(eq (cadr trip) 'global-value)
(consp (cddr trip)))
(let* ((wrld (w *the-live-state*))
(boot-strap-flg (global-val 'boot-strap-flg wrld)))
(case (car (cddr trip))
(defuns
; (cddr trip) is of the form (defuns defun-mode ignorep def1 ... defn).
; Defun-mode non-nil is stored by DEFUNS and defun-mode nil by :non-executable
; DEFUNS and by ENCAPSULATE when it is defining the constrained fns.
; Oneify-cltl-code relies on the fact that functions with defun-mode nil do a
; THROW.
; Observe that we sometimes use oneify-cltl-code to modify the actual Common
; Lisp code. Why don't we modify the defi before storing the cltl-command
; tuple? Because we want to make it easy on ourselves to recover from the
; world the actual defi used to define :program mode functions. See
; verify-termination.
; Recall that ignorep is non-nil if we are to AVOID storing the
; symbol-functions for names. If ignorep is non-nil, then it is either
; reclassifying -- meaning we are reclassifying a symbol from :program
; to :logic mode. We don't want to overwrite its
; symbol-function since that might be ACL2 source code.
; We still write a *1* definition in this case.
; (defstobj . stobj)
; -- meaning the names being introduced are actually being
; defun'd under (defstobj stobj ...) or (defabsstobj stobj
; ...). We don't want to store the code generated by defun
; for these names because defstobj and defabsstobj will
; generate a CLTL-COMMAND containing the made-to-order raw
; defs. We also do not store the *1* definition in this
; case, because in CCL (at least) this would cause a problem
; since the *1* code calls the raw Lisp function, which has
; not yet been defined and in the :inline case is actually a
; macro. (See also the comment in defstobj-functionsp.)
; Why do we need the stobj name in the case of ignorep = '(defstobj . stobj)?
; The reason is that when we generate the *1* code for the function, fn, we
; must generate a throw to handle a guard violation and the argument to that
; throw is an object which includes, among other things, the stobjs-in of fn so
; we will know how to print them. You might think we would get the stobjs-in
; of fn from the world. But we can't because this defun is being done under,
; and as part of, a defstobj or defabsstobj event, and the event will later
; declare stobj to be a stobj name. So the stobjs-in of fn in the world right
; now is wrong. The stobjs-in we need is built into the object thrown and so
; won't be overwritten when the event gets around to declaring stobj a stobj.
; So oneify-cltl-code, called below, takes the stobj name as its input and
; computes the appropriate stobjs-in from the formals. This is a problem
; analogous to the one addressed by the super-defun-wart table.
(let ((ignorep (caddr (cddr trip)))
(defun-mode (cadr (cddr trip)))
(new-defs
; We avoid potential "undefined" warnings by holding off on compilation until
; all the functions have been defined. Moreover, in the case of CCL we
; need to hold off even on defining the functions. So we collect up the
; definitions that need to be made in Common Lisp, proclaiming as we go
; (although proclaiming may be a no-op in some Lisps), then make all the
; definitions, and finally do the compilation as appropriate.
nil)
(new-*1*-defs nil))
(dolist
(def (cdddr (cddr trip)))
(cond ((and boot-strap-flg
(not (global-val 'boot-strap-pass-2 wrld)))
; During the first pass of initialization, we insist that every function
; defined already be defined in raw lisp. During pass two we can't expect this
; because there may be LOCAL defuns that got skipped during compilation and the
; first pass.
(or (fboundp (car def))
; Note that names of macros are fboundp, so we can get away with symbols that
; are defined to be macros in raw Lisp but functions in the logic (e.g.,
; return-last).
(interface-er "~x0 is not fboundp!"
(car def)))
; But during the first pass of initialization, we do NOT assume that every (or
; any) function's corresponding *1* function has been defined. So we take care
; of that now.
(or (member-eq (car def)
; For explanation of the special handling of the first three of the following
; function symbols, see the comments in their defun-*1* forms. For
; *defun-overrides*, we have already taken responsibility for defining *1*
; functions that we don't want to override here.
`(mv-list return-last wormhole-eval
,@*defun-overrides*))
(setq new-*1*-defs
(cons (list* 'oneify-cltl-code
defun-mode
def
; The if below returns the stobj name being introduced, if any.
(if (consp ignorep)
(cdr ignorep)
nil))
new-*1*-defs))))
((and (not ignorep)
(equal *main-lisp-package-name*
(symbol-package-name (car def))))
(interface-er "It is illegal to redefine a function in ~
the main Lisp package, such as ~x0!"
(car def)))
((and (consp ignorep)
(eq (car ignorep) 'defstobj))
; We wait for the cltl-command from the defstobj or defabsstobj (which is laid
; down last by defstobj-fn or defabsstobj-fn, using install-event) before
; defining/compiling the *1* functions, in order to avoid potential "undefined"
; warnings and, more importantly, to avoid defining *1* functions in terms of
; undefined macros (for the :inline case of defstobj and for defabsstobj),
; which confuses CCL as described in a comment in defstobj-functionsp. We
; still save the existing values (if any) of the current def and the current
; *1* def; see the next comment about ignorep.
(maybe-push-undo-stack 'defun (car def) ignorep))
(t (maybe-push-undo-stack 'defun (car def) ignorep)
; Note: If ignorep is '(defstobj . stobj), we save both the current def and the
; current *1* def. If ignorep is 'reclassifying, we save only the *1* def.
; The former behavior means that in defstobj, when the defun runs for each
; name, we will save both symbol-function cells, even though we store into
; neither. The code for installing a defstobj CLTL-COMMAND doesn't bother to
; do undo-stack work, because it knows both cells were saved by the defun.
(or ignorep
(setq new-defs (cons (cons 'defun def) new-defs)))
(setq new-*1*-defs
(cons (list* 'oneify-cltl-code
defun-mode
def
; The if below returns the stobj name being introduced, if any.
(if (consp ignorep)
(cdr ignorep)
nil))
new-*1*-defs)))))
(dolist (def new-defs)
; Remove the documentation string potentially stored in raw Lisp, if a copy is
; already around in our documentation database, just to save space.
(when (and (eq (car def) 'defun)
(doc-stringp (documentation (cadr def) 'function)))
(setf (documentation (cadr def) 'function) nil)))
(setq new-defs (nconc new-defs new-*1*-defs))
(install-defs-for-add-trip new-defs
(eq ignorep 'reclassifying)
wrld
(not boot-strap-flg)
t)
(cond ((not (eq (f-get-global 'compiler-enabled *the-live-state*)
t))
; Then skip compilation.
)
((or
; It seems critical to compile as we go in CMUCL 18e during the boot-strap, in
; order to avoid stack overflows. This seems to cut about 20% off the
; regression time for Allegro builds, so we go ahead and do this in all Lisps.
; See also the long comment for the case (eq fns :some) in
; compile-uncompiled-*1*-defuns. It is tempting to avoid this on-the-fly
; compilation for GCL, where we have seen build time shrink from over 22 to
; under 7 minutes and have seen roughly a percent or slightly less degradation
; in regression time, probably because of the lack of compilation in that case
; of *1* functions for built-in :program mode functions. But we have decided,
; at least for now, to keep the code simple by doing the same thing for all
; lisps and be happy with even that small improvement in regression time for
; GCL. (Note that by using make with
; LISP='gcl -eval "(defparameter user::*fast-acl2-gcl-build* t)"'
; one can get a faster build, without this on-the-fly compilation, with very
; little performance penalty at runtime. Something like this could be done
; with any Common Lisp, but there is only a point in GCL; see above.)
(and #+gcl (not user::*fast-acl2-gcl-build*)
boot-strap-flg) ; delete for build speedup (see above)
(and
(not *inside-include-book-fn*)
(default-compile-fns wrld)))
(dolist (def new-defs)
(assert$
def
; Install-defs-for-add-trip can't make def nil, since either we are in the
; boot-strap or else the value of 'ld-skip-proofsp is not 'include-book.
(let ((name (cond ((eq (car def) 'defun)
(cadr def))
((eq (car def) 'oneify-cltl-code)
(car (caddr def)))
(t (error "Implementation error: ~
unexpected form in ~
add-trip, ~x0"
def)))))
(eval `(compile ',name)))))))))
((defstobj defabsstobj)
; (cddr trip) is of one of the forms
; (DEFSTOBJ name the-live-name init raw-defs template axiomatic-defs) or
; (DEFABSSTOBJ name the-live-name init raw-defs event axiomatic-defs).
; Init is a form to eval to obtain the initial setting for the live variable.
; Each def in raw-defs and in axiomatic-defs is of the form (name args dcl
; body), where dcl may be omitted. We make a function or macro definition for
; each raw-def, and we make a defun for the oneification of each axiomatic-def.
(let ((absp (eq (car (cddr trip)) 'defabsstobj))
(name (nth 1 (cddr trip)))
(the-live-name (nth 2 (cddr trip)))
(init (nth 3 (cddr trip)))
(raw-defs (nth 4 (cddr trip)))
(template-or-event (nth 5 (cddr trip)))
(ax-defs (nth 6 (cddr trip)))
(new-defs
; We avoid "undefined function" warnings by Allegro during compilation by
; defining all the functions first, and compiling them only after they have all
; been defined. But we go further; see the comment in the binding of new-defs
; in the previous case.
nil))
(maybe-push-undo-stack 'defconst the-live-name)
(maybe-push-undo-stack 'defconst '*user-stobj-alist*)
; See the comment below, just above where we formerly set the symbol-value of
; name. If we re-install that code, then the next line of code also needs to
; be re-installed.
; (maybe-push-undo-stack 'defconst name)
(install-for-add-trip `(defparameter ,the-live-name ,init) nil t)
; Memoize-flush expects the variable (st-lst name) to be bound. We take care
; of that directly here. We see no need to involve install-for-add-trip or the
; like.
#+hons (let ((var (st-lst name)))
(or (boundp var)
(eval `(defg ,var nil))))
; As with defconst we want to make it look like we eval'd this defstobj or
; defabsstobj in raw lisp, so we set up the redundancy stuff:
(setf (get the-live-name 'redundant-raw-lisp-discriminator)
(cond (absp template-or-event)
(t (list* 'defstobj
(car template-or-event)
(cadr template-or-event)
(caddr template-or-event)
(if (sixth template-or-event)
(congruent-stobj-rep-raw
(sixth template-or-event))
name)))))
; At one point we executed the following form. But now we see that this is not
; necessary, since trans-eval binds stobj names anyhow using *user-stobj-alist*
; and even acl2-raw-eval uses *user-stobj-alist* to bind stobj names. If the
; following code is re-installed (uncommented), then also re-install the code
; (maybe-push-undo-stack 'defconst name) above.
; (setf (symbol-value name) (symbol-value the-live-name))
; The following assignment to *user-stobj-alist* is structured to keep
; new ones at the front, so we can more often exploit the optimization
; in put-assoc-eq-alist.
(setq *user-stobj-alist*
(cond ((assoc-eq name *user-stobj-alist*)
; This is a redefinition! We'll just replace the old entry.
(put-assoc-eq name
(symbol-value the-live-name)
*user-stobj-alist*))
(t (cons (cons name (symbol-value the-live-name))
*user-stobj-alist*))))
; We eval and compile the raw lisp definitions first, some of which may be
; macros (because :inline t was supplied for defstobj, or because we are
; handling defabsstobj), before dealing with the *1* functions.
(dolist
(def raw-defs)
(cond ((and boot-strap-flg
(not (global-val 'boot-strap-pass-2 wrld)))
; During the first pass of initialization, we insist that every function
; defined already be defined in raw lisp. During pass two we can't expect this
; because there may be LOCAL defuns that got skipped during compilation and the
; first pass.
(or (fboundp (car def))
(interface-er "~x0 is not fboundp!"
(car def))))
((equal *main-lisp-package-name*
(symbol-package-name (car def)))
(interface-er
"It is illegal to redefine a function in the main Lisp ~
package, such as ~x0!"
(car def)))
; We don't do maybe-push-undo-stack for defuns (whether inlined or not) under
; the defstobj or defabsstobj CLTL-COMMAND, because we did it for their
; defuns.
(t
(let ((def (cond
(absp (cons 'defmacro def))
((member-equal *stobj-inline-declare* def)
; We now handle the case where we are going to inline the function calls by
; defining the function as a defabbrev. Note that this is allowed for
; access/update/array-length functions for stobjs, but only for these, where
; speed is often a requirement for efficiency.
(cons 'defabbrev
(remove-stobj-inline-declare def)))
(t (cons 'defun def)))))
(setq new-defs (cons def new-defs))))))
(dolist
(def ax-defs)
(setq new-defs (cons (list* 'oneify-cltl-code :logic def name)
new-defs)))
(setq new-defs
; We reverse new-defs because we want to be sure to define the *1*
; defs after the raw Lisp defs (which may be macros, because of :inline).
(nreverse new-defs))
(install-defs-for-add-trip new-defs nil wrld (not boot-strap-flg)
t)
(when (and (eq (f-get-global 'compiler-enabled *the-live-state*)
t)
(not *inside-include-book-fn*)
(default-compile-fns wrld))
(dolist (def new-defs)
(assert$
; Install-defs-for-add-trip can't make def nil, since the value of
; 'ld-skip-proofsp is not 'include-book.
def
(let ((name (cond ((or (eq (car def) 'defun)
(eq (car def) 'defabbrev)
(eq (car def) 'defmacro))
(cadr def))
((eq (car def) 'oneify-cltl-code)
(car (caddr def)))
(t (error "Implementation error: ~
unexpected form in add-trip, ~x0"
def)))))
; CMUCL versions 18e and 19e cannot seem to compile macros at the top level.
; Email from Raymond Toy on June 9, 2004 suggests that this appears to be a bug
; that exists in CMUCL 18e sources. We'll thus give special treatment to any
; version 18 or 19 of CMUCL, but we'll avod that for CMUCL version 20, since
; 20D at least can compile macros.
#+(and cmu (or cmu18 cmu19))
(cond ((and (not (eq (car def) 'defabbrev))
(not (eq (car def) 'defmacro)))
(eval `(compile ',name))))
#-(and cmu (or cmu18 cmu19))
(eval `(compile ',name))))))))
(defpkg
(maybe-push-undo-stack 'defpkg (cadr (cddr trip)))
(eval (cons 'defpkg (cdr (cddr trip)))))
(defconst
; Historical remark on defconstant.
; In the beginning we supported defconstant. We changed to
; defparameter and then changed to defconst. As things stand now,
; ACL2 supports defconst, which has the same effect at the raw lisp
; level (i.e., the cltl-command) as defparameter, and in addition
; causes proclaim-file to exectute an appropriate proclamation for the
; parameter, knowing as we do that it is really constant. Here are
; some historical remarks that explain why we have gone down this
; path.
; "Currently we turn defconstants into defparameters at the raw Lisp
; level (that is, the cltl-command for defconstant is a defparameter).
; However, we have begun to contemplate alternatives, as we now
; explain.
; We have run into the following problem with defconstant: the
; compiler won't let us compile certified books containing defconstant
; forms because it thinks that constants are special variables
; (because that is what the defparameter cltl-command does). What can
; we do about this problem? One idea was to temporarily redefine
; defconstant to be defparameter (during the compilation done by
; certify-book), but macrolet has only lexical scope, and anyhow Boyer
; says that it's illegal to redefine a Common Lisp function (as we did
; using setf, macro-function, and unwind-protect).
; Another possibilty is to change defconstant-fn so that it really
; does create defconstants. But the reason we use defparameter now is
; that when we undo we need to unbind (because we're always checking
; to see if something is already bound), and we can't unbind a
; constant.
; Why not just eliminate defconstant in favor of defparameter
; everywhere? This is very appealing, especially because defconstant
; is inherently not amenable to undoing. But, Boyer thinks that when
; you defconstant something to a value that is a fixnum, then the
; compiler knows it's a fixnum. This could be very important for
; speed in type-set reasoning. Without the consideration of
; arithmetic, Schelter thinks that we're only paying the price of two
; memory references for defparameter vs. one for defconstant; but a
; factor of 80 or so seems like too high a price to pay.
; So, how about allowing both defconstant and defparameter, but not
; allowing any undoing back past a defconstant? After all, we already
; have a notion of not undoing into the system initialization, so
; we're just talking about a very reasonable extension of that
; protocol. One problem with this approach is that certify-book
; currently does an include-book after a ubt, and this ubt would
; probably fail. But perhaps we can force this to work. The user
; could then develop his work using defparameter, but certify the
; final "toothbrush" book using defconstant. Perhaps defconst would
; be a convenient macro that could be redefined so as to be one or the
; other of defparameter or defconstant. With this approach it would
; probably be useful to require answering a query in order to execute
; a defconstant.
; Another option would be to have acl2::defconstant be distinct from
; lisp::defconstant, but as Boyer points out, this violates our desire
; to have such Lisp primitives available to the user that he can count
; on. Or, we could define a new package that's just like the acl2
; package but doesn't import defconstant. But note that
; (symbol-package 'defconstant) would create different answers in the
; ACL2 package than in this package -- ouch!"
; Note: (cddr trip) here is (defconst var form val).
(cond (boot-strap-flg
(or (boundp (cadr (cddr trip)))
(interface-er "~x0 is not boundp!"
(cadr (cddr trip)))))
((equal *main-lisp-package-name*
(symbol-package-name (cadr (cddr trip))))
(interface-er "It is illegal to redefine a defconst in ~
the main Lisp package, such as ~x0!"
(cadr (cddr trip))))
(t (maybe-push-undo-stack 'defconst (cadr (cddr trip)))
; We do not want to eval (defconst var form) here because that will recompute
; val. But we make raw Lisp look like it did that.
(setf (get (cadr (cddr trip))
'redundant-raw-lisp-discriminator)
(list* 'defconst
(caddr (cddr trip)) ; form
(cadddr (cddr trip)))) ; val
(install-for-add-trip `(defparameter ,(cadr (cddr trip))
',(cadddr (cddr trip)))
nil
t)))
(cond ((doc-stringp (and (cadr (cddr trip))
(documentation (cadr (cddr trip))
'variable)))
(setf (documentation (cadr (cddr trip)) 'variable)
nil))))
(defmacro
(cond (boot-strap-flg
(or (fboundp (cadr (cddr trip)))
(interface-er "~x0 is not fboundp!"
(cadr (cddr trip)))))
((equal *main-lisp-package-name*
(symbol-package-name (cadr (cddr trip))))
(interface-er "It is illegal to redefine a macro in the ~
main Lisp package, such as ~x0!"
(cadr (cddr trip))))
(t (maybe-push-undo-stack 'defmacro (cadr (cddr trip)))
(install-for-add-trip (cddr trip) nil t)))
(cond ((doc-stringp (documentation (cadr (cddr trip)) 'function))
(setf (documentation (cadr (cddr trip)) 'function)
nil))))
(attachment ; (cddr trip) is produced by attachment-cltl-cmd
(dolist (x (cdr (cddr trip)))
(let ((name (if (symbolp x) x (car x))))
#+hons (push name *defattach-fns*)
(maybe-push-undo-stack 'attachment name)
(install-for-add-trip
(cond ((symbolp x)
(set-attachment-symbol-form x nil))
(t (set-attachment-symbol-form name (cdr x))))
nil
t))))
#+hons
(memoize
(maybe-push-undo-stack 'memoize (cadr (cddr trip)))
(let* ((tuple (cddr trip))
(cl-defun (nth 5 tuple)))
(assert$
cl-defun
(memoize-fn (nth 1 tuple)
:condition (nth 2 tuple)
:inline (nth 3 tuple)
:trace (nth 4 tuple)
:cl-defun cl-defun
:formals (nth 6 tuple)
:stobjs-in (nth 7 tuple)
:stobjs-out (nth 8 tuple)
:commutative (nth 10 tuple)
:forget (nth 11 tuple)
:memo-table-init-size (nth 12 tuple)
:aokp (nth 13 tuple)))))
#+hons
(unmemoize
(maybe-push-undo-stack 'unmemoize (cadr (cddr trip)))
(unmemoize-fn (cadr (cddr trip))))))))
; Finally, we make sure always to leave the *current-acl2-world-key* as the
; first property on the symbol-plist of the symbol.
(let ((temp (get (car trip) *current-acl2-world-key*))
(plist (symbol-plist (car trip))))
(cond ((and temp (not (eq (car plist) *current-acl2-world-key*)))
(setf (symbol-plist (car trip))
(cons *current-acl2-world-key*
(cons temp
(remove-current-acl2-world-key
plist))))))))
(defun-one-output undo-trip (world-name world-key trip)
; Undo-trip is the function that removes from the ``real'' Common Lisp
; the things installed by add-trip. It works merely by popping the
; appropriate stacks.
(setf (get (car trip) world-key)
(destructive-pop-assoc (cadr trip) (get (car trip) world-key)))
(cond
((and (eq world-name 'current-acl2-world)
(eq (car trip) 'cltl-command)
(eq (cadr trip) 'global-value)
(consp (cddr trip)))
(case (car (cddr trip))
(defuns
; Note that :inlined defstobj functions as well as defabsstobj exported
; functions are processed by eval-event-lst as though they are ordinary defuns,
; even though they correspond to macros in raw Lisp (defined by defabbrev and
; defmacro, respectively). We are relying on the fact that
; maybe-push-undo-stack handled defun and defmacro the same, so that the form
; eveluated by maybe-pop-undo-stack will be appropriate even though the
; "function" is actually a macro.
(dolist (tuple (cdddr (cddr trip)))
(maybe-pop-undo-stack (car tuple))))
((defstobj defabsstobj)
(let ((name (nth 1 (cddr trip)))
(the-live-name (nth 2 (cddr trip))))
(maybe-pop-undo-stack name)
(maybe-pop-undo-stack '*user-stobj-alist*)
(maybe-pop-undo-stack the-live-name)))
(defpkg nil)
((defconst defmacro #+hons memoize #+hons unmemoize)
(maybe-pop-undo-stack (cadr (cddr trip))))
(attachment ; (cddr trip) is produced by attachment-cltl-cmd
(let ((lst (cdr (cddr trip))))
(dolist (x lst)
(let ((name (if (symbolp x) x (car x))))
(maybe-pop-undo-stack name)))))
(otherwise nil)))))
(defun-one-output flush-trip (name world-key trip)
(remprop (car trip) world-key)
(cond ((and (eq name 'current-acl2-world)
(eq (car trip) 'cltl-command)
(eq (cadr trip) 'global-value)
(consp (cddr trip)))
(case (car (cddr trip))
(defuns
; Note that :inlined stobj functions are handled properly here; see the
; corresponding comment in undo-trip.
(dolist (tuple (cdddr (cddr trip)))
(flush-undo-stack (car tuple))))
((defstobj defabsstobj)
(let ((name (nth 1 (cddr trip)))
(the-live-name (nth 2 (cddr trip))))
(flush-undo-stack name)
(flush-undo-stack '*user-stobj-alist*)
(flush-undo-stack the-live-name)))
(defpkg nil)
((defconst defmacro #+hons memoize #+hons unmemoize)
(flush-undo-stack (cadr (cddr trip))))
(attachment ; (cddr trip) is produced by attachment-cltl-cmd
(let ((lst (cdr (cddr trip))))
(dolist (x lst)
(let ((name (if (symbolp x) x (car x))))
(flush-undo-stack name)))))
(otherwise nil)))))
(defvar *bad-wrld*)
(defun check-acl2-world-invariant (wrld old-wrld)
; Old-wrld is the world currently installed under 'current-acl2-world.
; Wrld is a world we are trying to install there. We check that
; old-world is in fact the current global value of 'current-acl2-
; world. We have gotten out of sync on this once or twice. It is
; cheap to check and pernicious to track down.
(cond ((not (eq old-wrld
(w *the-live-state*)))
(setq *bad-wrld* wrld)
(interface-er
"Extend-world1 or rollback-world1 has been asked to install ~
a world at a moment when the current global value of ~
'current-acl2-world was not the installed world! The ~
world we were asked to install may be found in the variable ~
*bad-wrld*."))))
(defparameter *known-worlds* nil)
(defun update-wrld-structures (wrld state)
(install-global-enabled-structure wrld state)
(recompress-global-enabled-structure
'global-arithmetic-enabled-structure
wrld)
(recompress-stobj-accessor-arrays
(strip-cars *user-stobj-alist*)
wrld)
#+hons
(update-memo-entries-for-attachments *defattach-fns* wrld state))
(defun-one-output extend-world1 (name wrld)
; Wrld must be a world that is an extension of the world currently
; installed under name.
; Warning: Even though this program does not take state as an
; argument, it has the effect of smashing the value of the live state
; global 'current-acl2-world if name is 'current-acl2-world. In
; particular, we maintain the invariant that the live global value of
; 'current-acl2-world is always the world installed under that name.
; If you don't want these changes to occur to your state, don't call
; this program!
(let ((pair (get name 'acl2-world-pair)) old-wrld world-key new-trips)
(cond
((null pair)
(setq pair (cons nil (if (eq name 'current-acl2-world)
*current-acl2-world-key*
(gensym))))
(pushnew name *known-worlds*)
(cond ((eq name 'current-acl2-world)
(f-put-global 'current-acl2-world nil *the-live-state*)))
(setf (get name 'acl2-world-pair) pair)))
(setq old-wrld (car pair))
(setq world-key (cdr pair))
; Pair is of the form (old-wrld . world-key) and means that the world
; currently installed under name is old-wrld and its properties are
; stored at world-key.
(cond ((eq name 'current-acl2-world)
(check-acl2-world-invariant wrld old-wrld)))
; We now scan down the about-to-be-installed world and push onto the
; temporary new-trips the triples that constitute the extension. If
; we fail to find the old world, we will cause a hard error. It may look
; like we are doing this scan to guarantee that wrld is an extension.
; Were that the reason, we would do this as we installed the properties.
; No, the real reason we do this scan is so that we can collect, in reverse
; order, the triples we must install. The order in which we push the
; values into the property lists is important!
(do ((tl wrld (cdr tl)))
((equal tl old-wrld)) ; best to avoid eq; see comment in retract-world1
(cond
((null tl)
(setq *bad-wrld* wrld)
(er hard 'extend-world1
"Extend-world1 was called upon to ``extend'' ~x0. But ~
the world supplied to extend-world1, which is now the ~
value of the Lisp global *bad-wrld*, is not an ~
extension of the current ~x0. The alist corresponding ~
to the current ~x0 may be obtained via ~x1. No ~
properties were modified -- that is, the symbol-plists ~
still reflect the pre-extend-world1 ~x0."
name
`(car (get ',name 'acl2-world-pair))))
(t (push (car tl) new-trips))))
(let ((state *the-live-state*))
; We bind state only so our use of acl2-unwind-protect below isn't so odd
; looking. Logically the body never signals an error, but if an abort
; occurs, we will do recover-world for cleanup.
(acl2-unwind-protect
"extend-world1"
(value
; It is a bit unfortunate to use with-more-warnings-suppressed below, since we
; have such a call in LP. However, this is how we see a way to suppress
; complaints about undefined functions during the build, without suppressing
; compiler warnings entirely during the build. Note that with-compilation-unit
; does not always defer warnings for calls of the compiler in general -- at
; least, we have seen this with CCL and Allegro CL -- but only for calls of
; compile-file.
(with-more-warnings-suppressed
; Observe that wrld has recover-world properties (a) and (b). (a) at
; the time of any abort during this critical section, every symbol
; that may have a world-key property is in wrld (because the only
; symbols with a world-key property initially are those in old-wrld,
; wrld is an extension of old-wrld, and during the critical section we
; add world-key properties just to symbols in wrld); and (b): every
; symbol in old-wrld is a symbol in wrld (because wrld is an extension
; of old-wrld). (Of course, by "symbol in" here we mean "symbol
; occuring as the car of an element".)
(dolist (trip new-trips)
(add-trip name world-key trip))
(setf (car pair) wrld)
(cond ((eq name 'current-acl2-world)
(f-put-global 'current-acl2-world wrld *the-live-state*)
(update-wrld-structures wrld state)))))
(recover-world 'extension name old-wrld wrld nil)
; Observe that wrld has recover-world properties (a) and (b). (a) at
; the time of any abort during this critical section, every symbol
; that may have a world-key property is in wrld (because the only
; symbols with a world-key property initially are those in old-wrld,
; wrld is an extension of old-wrld, and during the critical section we
; add world-key properties just to symbols in wrld); and (b): every
; symbol in old-wrld is a symbol in wrld (because wrld is an extension
; of old-wrld). (Of course, by "symbol in" here we mean "symbol
; occuring as the car of an element".)
state)
; The acl2-unwind-protect returns (mv nil x *the-live-state*), for some x.
; All three values are ignored.
wrld)))
(defun-one-output retract-world1 (name wrld)
; Wrld must be a world that is a retraction of the world currently installed
; under name.
; Warning: Even though this program does not take state as an argument, it has
; the effect of smashing the value of the live state global 'current-acl2-world
; if name is 'current-acl2-world. In particular, we maintain the invariant
; that the live global value of 'current-acl2-world is always the world
; installed under that name. We also maintain the invariant that the binding
; of 'current-package is a known package, by setting 'current-package to "ACL2"
; if we have to. If you don't want these changes to occur to your state, don't
; call this program!
(let ((pair (get name 'acl2-world-pair)) old-wrld world-key)
(cond
((null pair)
(setq pair (cons nil (if (eq name 'current-acl2-world)
*current-acl2-world-key*
(gensym))))
(pushnew name *known-worlds*)
(cond ((eq name 'current-acl2-world)
(f-put-global 'current-acl2-world nil *the-live-state*)))
(setf (get name 'acl2-world-pair) pair)))
(setq old-wrld (car pair))
(setq world-key (cdr pair))
; Pair is of the form (old-wrld . world-key) and means that the world currently
; installed under name is old-wrld and its properties are stored at world-key.
(cond ((eq name 'current-acl2-world)
(check-acl2-world-invariant wrld old-wrld)))
(let ((state *the-live-state*)
(pkg (current-package *the-live-state*)))
(acl2-unwind-protect
"retract-world1"
(value
(progn
; We now scan down old-wrld until we get to wrld, doing a pop for each triple
; in the initial segment of old-wrld. Note that we do not do the pops in the
; reverse order (as we did the pushes). It doesn't matter. All that matters
; is that we one pop for each push that was done.
(do ((tl old-wrld (cdr tl)))
((equal tl
; At one time we used eq here. But old-wrld and wrld are equal, but not eq,
; when retract-world1 is called in the following example.
; (defun f1 (x) x)
; (defun f2 (x) x)
; :ubt! f1
; (defun f1 (x) x)
; :oops
wrld))
(cond
((null tl)
(setq *bad-wrld* wrld)
(er hard 'retract-world1
"Retract-world1 was called upon to ``retract'' ~
~x0. But the world supplied to retract-world1, ~
which is now the value of the Lisp global ~
variable *bad-wrld*, is not a retraction of the ~
currently installed ~x0. The alist corresponding ~
to the current ~x0 may be obtained via ~x1. ~
Unfortunately, this problem was not discovered ~
until all of the properties in ~x0 were removed. ~
Those properties can be restored via ~
(recover-world)."
name
`(car (get ',name 'acl2-world-pair))))
(t (undo-trip name world-key (car tl)))))
(setf (car pair) wrld)
(cond ((eq name 'current-acl2-world)
(f-put-global 'current-acl2-world wrld *the-live-state*)
(cond ((not (find-non-hidden-package-entry
(current-package *the-live-state*)
(known-package-alist *the-live-state*)))
; Note: Known-package-alist returns the new known packages because of the setf
; above!
(f-put-global 'current-package "ACL2" *the-live-state*)))
(update-wrld-structures wrld state)))))
(recover-world 'retraction name old-wrld old-wrld pkg)
; Note that old-wrld has recover-world properties (a) and (b). (a) At the time
; of any abort during this critical section, every symbol that may possibly
; have the world-key property occurs as a car of some element of old-wrld (at
; the beginning of this operation the only symbols with the world-key property
; are in old-wrld and during the critical section we may only remove the
; property). (b) Every symbol in old-wrld is in old-wrld. Note that it is not
; important whether wrld is actually a retraction, because we are just removing
; world-key properties.
state)
wrld)))
(defun-one-output recover-world1 (wrld saved-wrld ans)
; This is like (revappend wrld ans) except that we cons successive tails of
; wrld onto ans instead of successive elements until wrld is either saved-wrld
; or nil. Thus, assuming saved-wrld is nil, if you start with wrld = '(trip3
; trip2 trip1) you end up with ans = '((trip1) (trip2 trip1) (trip3 trip2
; trip1)). By scanning ans you will see the successive cdrs of world, starting
; with the shortest.
(cond ((eq wrld saved-wrld)
ans)
((null wrld)
(error "Implementation error in recover-world1"))
(t (recover-world1 (cdr wrld) saved-wrld (cons wrld ans)))))
(defun-one-output recover-world (op name old-wrld universe pkg)
; If this function is called then an extension or retraction operation (op) was
; aborted. The arguments tell us how to restore the world to the configuration
; it had when the aborted operation was initiated. Toward that end, the two
; operations execute this form on the cleanup1 side of acl2-unwind-protects,
; after saving in locals the name and world before they start making changes to
; the symbol- plists. Our recovery mechanism has two steps. First, we throw
; away all properties stored under the name in question. Second, we extend
; that empty world to the saved one. The extension part is easy.
; But how do we "throw away all properties" stored under a given name? One way
; is to get the world key, world-key, associated with the name, and then visit
; each CLTL symbol, sym, and do (remprop sym world-key). But sweeping through
; all symbols seems to be slow. So instead we enforce the discipline of having
; a "universal list" of all the symbols which might, remotely, have the
; world-key property. This list is actually a list of triples (it is, in fact,
; always one of the two worlds involved in the aborted operation) and we visit
; the symbol in each car of each triple.
; So much for spoon-fed background information. Name is the name of the world
; whose installation was aborted. We know that the cdr of the 'acl2-world-pair
; property of name is some uninterned symbol, world-key, at which all the
; properties for this world are stored. Old-wrld is the alist of triples that
; was actually installed at the time the aborted operation was initiated -- and
; is thus the world we are going to re-install. And universe is a list of
; pairs (triples actually) with the following two properties:
; (a) at the time of any abort during the critical section, each symbol having
; the world-key property occurs as the car of some pair in universe, and (b)
; each symbol occuring as the car of some pair in old-wrld occurs as the car of
; a pair in universe.
; The latter property is necessary to ensure that we can recover from an
; aborted attempt to recover.
; In addition, if operation is 'retraction, then pkg is the current- package at
; the inception of the operation. If operation is not 'retraction, pkg is
; irrelevant.
(let* ((pair (get name 'acl2-world-pair))
(world-key (cdr pair))
#+hons *defattach-fns* ; needs to be bound, but not truly used
(*in-recover-world-flg* t))
; The *in-recover-world-flg* is used by the raw lisp implementation of defpkg.
; How is defpkg called from within this function? Add-trip, above, is the
; program used to add the triples in old-wrld to the raw property lists. It
; notes CLTL-COMMAND triples and executes the appropriate Common Lisp to cause
; the raw defuns, defmacros, constants, and packages to come into existence.
; So we execute defpkg when we store a CLTL-COMMAND property with val (DEFPKG
; ...). Normally, defpkg unbinds all the symbols in the dual package (where
; state globals are actually stored). But we can't afford to do that if we
; are recovering the world (because state globals are unaffected by world
; operations).
(when (null pair)
(er hard 'recover-world
"There is no acl2-world-pair stored on ~x0, which is the name of ~
the world we are supposed to recover."
name))
(fmt1 "Flushing current installed world.~%"
nil 0 (standard-co *the-live-state*) *the-live-state*
nil)
(dolist (trip universe) (flush-trip name world-key trip))
(let* ((checkpoint-world-len-and-alist (checkpoint-world-len-and-alist))
(chkpt-alist (cddr checkpoint-world-len-and-alist))
(start-wrld
(and (eq name 'current-acl2-world)
*checkpoint-world-len-and-alist-stack*
(let ((chkpt-wrld (car checkpoint-world-len-and-alist))
(chkpt-len (cadr checkpoint-world-len-and-alist))
(old-wrld-len (length old-wrld)))
(and (<= chkpt-len old-wrld-len)
(eq (nthcdr (- old-wrld-len chkpt-len) old-wrld)
chkpt-wrld)
(let ((universe-len (length universe)))
(and (<= chkpt-len universe-len)
(eq (nthcdr (- universe-len chkpt-len) universe)
chkpt-wrld)
chkpt-wrld)))))))
(dolist (x chkpt-alist)
(setf (get (car x) world-key)
(copy-alist (cdr x))))
(cond ((eq name 'current-acl2-world)
(f-put-global 'current-acl2-world start-wrld
*the-live-state*)))
(setf (car pair) start-wrld)
(fmt1 "Reversing the new world.~%" nil 0
(standard-co *the-live-state*) *the-live-state* nil)
(let ((rwtls (recover-world1 old-wrld start-wrld nil))
(*inside-include-book-fn*
; We defeat the special hash table processing done by the install-for-add-trip*
; functions. (This binding might not be necessary, but it seems safe.)
nil))
(fmt1 "Installing the new world.~%" nil 0
(standard-co *the-live-state*) *the-live-state* nil)
; It is a bit unfortunate to use with-more-warnings-suppressed below, since we
; have such a call in LP. However, this is how we see a way to suppress
; complaints about undefined functions during the build, without suppressing
; compiler warnings entirely during the build. Note that with-compilation-unit
; does not always defer warnings for calls of the compiler in general -- at
; least, we have seen this with CCL and Allegro CL -- but only for calls of
; compile-file.
(with-more-warnings-suppressed
(do ((tl rwtls (cdr tl)))
((null tl))
(add-trip name world-key (caar tl))
(cond ((eq name 'current-acl2-world)
(f-put-global 'current-acl2-world (car tl)
*the-live-state*)))
(setf (car pair) (car tl)))))
(cond ((eq name 'current-acl2-world)
(cond ((eq op 'retraction)
(f-put-global 'current-package pkg
*the-live-state*)))
#+hons (setq *defattach-fns* :clear)
(update-wrld-structures old-wrld *the-live-state*))))))
; VIRGINITY
; We do not want the ACL2 user to define any symbol that already has
; any sort of definition.
(defun-one-output virginp (name new-type)
(and (symbolp name)
(if (member-eq new-type '(function macro constrained-function t))
(not (or (fboundp name)
(macro-function name)
(special-form-or-op-p name)))
t)
(if (member-eq new-type '(const stobj stobj-live-var t))
(not (boundp name))
t)))
(defun-one-output chk-virgin2 (name new-type wrld)
(cond ((virginp name new-type) nil)
((global-val 'boot-strap-flg wrld)
(setf (get name '*predefined*) t))
; A name regains its true virginity the moment we decide to give it a
; 'redefined property, which only happens just after the user has said that
; it's OK to redefine it.
((getprop name 'redefined nil 'current-acl2-world wrld)
nil)
(t
(let ((reason
(cond ((not (symbolp name)) "it is not a symbol")
((member-eq new-type
'(function macro constrained-function t))
(cond
((special-form-or-op-p name) "it is a special form")
((macro-function name) "it has a macro definition")
((fboundp name) "it has a function definition")
(t "there is an inconsistency in the definition of ~
virginp and chk-virgin2")))
((member-eq new-type '(const stobj stobj-live-var t))
(cond
((boundp name) "it has a top level binding")
(t "there is an inconsistency in the definition of ~
virginp and chk-virgin2")))
(t "there is an inconsistency in the definition of ~
virginp and chk-virgin2")))
(suggestion
(let ((str " If earlier you accidentally made this ~
definition or assignment outside the ACL2 ~
loop, then you might consider exiting the ~
ACL2 loop and executing appropriate ~
Common Lisp to erase those mistakes. ~
This is a potentially perilous act unless ~
you are sure these names were introduced ~
by you and are not involved in any ~
logical code. ~#3~[~/To erase a function ~
or macro definition use (fmakunbound! ~
'~x0). ~]~#4~[~/To erase a variable ~
setting use (makunbound '~x0). ~]"))
(cond ((not (symbolp name)) "")
((member-eq new-type
'(function macro constrained-function t))
(cond
((special-form-or-op-p name) "")
(t str)))
(t ; (member-eq new-type '(const stobj
; stobj-live-var t))
str)))))
(interface-er
"It is illegal to define ~x0 because ~@1 in raw Common Lisp.~@2"
name
reason
suggestion
(if (member-eq new-type
'(function macro constrained-function t))
1
0)
(if (member-eq new-type '(const stobj stobj-live-var t))
1
0))))))
; PACKAGE VIRGINITY
(defun-one-output chk-package-reincarnation-import-restrictions2
(name proposed-imports)
; This routine returns nil or causes a hard error. It is used in the
; implementation of the logical function chk-package-reincarnation-import-
; restrictions, which axiomatically always returns t but may cause this hard
; error (which can be thought of as a resource error).
; Note: The "2" in the name stems from chk-virgin2, which plays a similar role
; in chk-virgin. Chk-virgin1 has been lost in the mist of time, but
; chk-package-reincarnation-import-restrictions1 has never existed!
(let ((pkg (find-package name))
(temp (find-package-entry name *ever-known-package-alist*)))
(cond
(pkg
(cond
(temp
(check-proposed-imports name temp proposed-imports)
nil)
((member-equal name *defpkg-virgins*)
nil)
(t
; The package has been built in this Common Lisp but not by defpkg.
(interface-er
"It is illegal to defpkg ~x0 because a package of that name already ~
exists in this lisp."
name))))
(t
; The package has never been built in this Common Lisp.
nil))))
; ACL2 INITIALIZATION ROUTINES
#+gcl
(defvar user::*acl2-keep-tmp-files* nil)
(defun-one-output enter-boot-strap-mode (system-books-dir operating-system)
; If we interrupted an earlier initialization, the following form will undo it.
; This will set the *acl2-unwind-protect-stack* to nil because *ld-level* is
; 0 at the top.
(acl2-unwind *ld-level* nil)
; Now provide a frame into which the set-w can push its acl2-unwind-protect
; forms. An abort of the set-w will leave the forms in the frame so that the
; above acl2-unwind will undo them upon the next initialization attempt. But
; if the set-w is successful, it will leave the then empty frame on the stack.
(push nil *acl2-unwind-protect-stack*)
(set-w 'retraction nil *the-live-state*)
(do-symbols (sym (find-package "ACL2_GLOBAL_ACL2"))
(makunbound sym))
(do-symbols (sym (find-package
(concatenate 'string
*global-package-prefix*
*main-lisp-package-name*)))
(makunbound sym))
(do-symbols (sym (find-package "ACL2_GLOBAL_KEYWORD"))
(makunbound sym))
(initialize-state-globals)
; The following patch for save-gprof.lsp may be more heavy-handed than
; necessary, because maybe we don't need to keep all TMP* files. See also
; "Note: temporary files" in save-gprof.lsp.
; If we want to let the user set other variables, we could replace
; user::*acl2-keep-tmp-files* with a variable whose value associates state
; global symbol names with initial values. But then we will need to check that
; none is untouchable, and we will need to make a corresponding change in
; save-gprof.lsp.
#+gcl
(f-put-global 'keep-tmp-files user::*acl2-keep-tmp-files* *the-live-state*)
(f-put-global 'global-enabled-structure
(initial-global-enabled-structure "ENABLED-ARRAY-")
*the-live-state*)
(f-put-ld-specials *initial-ld-special-bindings* *the-live-state*)
; The next set-w will avail itself of the empty frame left above.
(set-w 'extension
(primordial-world operating-system)
*the-live-state*)
; Set the system books directory now that the operating-system has been defined
; (needed by pathname-os-to-unix).
(cond (system-books-dir
(let ((dir (unix-full-pathname
(cond
((symbolp system-books-dir)
(symbol-name system-books-dir))
((stringp system-books-dir)
system-books-dir)
(t (er hard 'initialize-acl2
"Unable to complete initialization, because the ~
supplied system books directory, ~x0, is not a ~
string."
system-books-dir))))))
(f-put-global 'system-books-dir
(canonical-dirname! (maybe-add-separator dir)
'enter-boot-strap-mode
*the-live-state*)
*the-live-state*)))
(t (f-put-global 'system-books-dir
(concatenate
'string
(canonical-dirname! (our-pwd)
'enter-boot-strap-mode
*the-live-state*)
#-:non-standard-analysis
"books/"
#+:non-standard-analysis
"books/nonstd/")
*the-live-state*)))
; Inhibit proof-tree output during the build, including pass-2 if present.
(f-put-global 'inhibit-output-lst '(proof-tree) *the-live-state*)
; We now pop the empty frame. There is no way this acl2-unwind will do any
; real work because only an abort would leave stuff in the frame and an abort
; would prevent us from getting here. Note that in the scheme of things,
; namely within the control structure of initialize-acl2, it is strictly
; unnecessary for us to pop this empty frame: each LD called by initialize-acl2
; will unwind the stack back to nil. But I do it here out of politeness: the
; stack started empty and ends that way.
(acl2-unwind *ld-level* nil))
(defun-one-output move-current-acl2-world-key-to-front (wrld)
; This program sweeps the world and makes sure that the current acl2 world key
; is the first property on every property list upon which it is found. We try
; to maintain that invariant in set-w where we always move the property up when
; we mess with a symbol's plist. Of course, one must then wonder why this
; program is ever useful. The reason is that in some lisps, e.g., AKCL, when
; you ask for the symbol-name of a symbol it has the side-effect of storing the
; string on the plist for future use. Thus, for example, during booting of
; ACL2 we keep the world key at the front but then when we print the name of
; the event we accidentally cover the world key up with a SYSTEM:PNAME
; property. This doesn't happen for every name. Apparently for most we access
; the symbol-name during the processing and cause the property to come into
; existence and then store our world key in front of it. But for some names we
; don't, apparently, ever access the symbol-name during processing and then our
; world key is covered up the first time the name is printed by ACL2. Among
; the names so covered up by system properties are the names such as |Make
; RECOGNIZER-TUPLE record| INCLUDE-BOOK-ALIST, CERTIFICATION-TUPLE,
; TYPE-SET-INVERTER-RULES, PROVED-FUNCTIONAL-INSTANCES-ALIST, GENERALIZE-RULES,
; WELL-FOUNDED-RELATION-ALIST, WORLD-GLOBALS, and CHK-NEW-NAME-LST. It is my
; theory that these names are simply never set a second time in booting and
; their initial setting is made before they are first printed.
; In any case, the following sweep takes only a second or two at the end of a
; boot and will make our world key the first property. We hope to keep it that
; way in add-trip, but we cannot guarantee it, since the Lisp system might
; legally at anytime cover it up with some system property.
(cond ((null wrld) nil)
((eq (car (symbol-plist (caar wrld))) *current-acl2-world-key*)
(move-current-acl2-world-key-to-front (cdr wrld)))
(t (let ((temp (get (caar wrld) *current-acl2-world-key*)))
(cond (temp
(setf (symbol-plist (caar wrld))
(cons *current-acl2-world-key*
(cons temp
(remove-current-acl2-world-key
(symbol-plist (caar wrld)))))))))
(move-current-acl2-world-key-to-front (cdr wrld)))))
(progn
; Warning: These definitions will replace both the raw Lisp and *1* definitions
; of the first argument of each defun-overrides call. We must ensure that these
; definitions can't be evaluated when proving theorems unless each has
; unknown-constraints and never returns two values for the same input (which is
; automatically taken care of by passing in live states with unknown oracles).
(defun-overrides mfc-ts-fn (term mfc state forcep)
(mv-let (ans ttree)
(mfc-ts-raw term mfc state forcep)
(declare (ignore ttree))
ans))
(defun-overrides mfc-ts-ttree (term mfc state forcep)
(mfc-ts-raw term mfc state forcep))
(defun-overrides mfc-rw-fn (term obj equiv-info mfc state forcep)
(mv-let (ans ttree)
(mfc-rw-raw term nil obj equiv-info mfc 'mfc-rw state
forcep)
(declare (ignore ttree))
ans))
(defun-overrides mfc-rw-ttree (term obj equiv-info mfc state forcep)
(mfc-rw-raw term nil obj equiv-info mfc 'mfc-rw state forcep))
(defun-overrides mfc-rw+-fn (term alist obj equiv-info mfc state forcep)
(mfc-rw-raw term alist obj equiv-info mfc 'mfc-rw+ state forcep))
(defun-overrides mfc-rw+-ttree (term alist obj equiv-info mfc state forcep)
(mv-let (ans ttree)
(mfc-rw-raw term alist obj equiv-info mfc 'mfc-rw+ state
forcep)
(declare (ignore ttree))
ans))
(defun-overrides mfc-relieve-hyp-fn (hyp alist rune target bkptr mfc state
forcep)
(mfc-relieve-hyp-raw hyp alist rune target bkptr mfc state
forcep))
(defun-overrides mfc-relieve-hyp-ttree (hyp alist rune target bkptr mfc
state forcep)
(mv-let (ans ttree)
(mfc-relieve-hyp-raw hyp alist rune target bkptr mfc state
forcep)
(declare (ignore ttree))
ans))
(defun-overrides mfc-ap-fn (term mfc state forcep)
(mfc-ap-raw term mfc state forcep)))
(defun-one-output exit-boot-strap-mode ()
; We need not unwind the *acl2-unwind-protect-stack* because it must be nil for
; us to have gotten here; had an abort occurred, leaving some frames on the
; stack, we would not get here. The frame we push below is used by the set-w
; and then popped unless an abort occurs.
(push nil *acl2-unwind-protect-stack*)
(set-w 'extension
(end-prehistoric-world (w *the-live-state*))
*the-live-state*)
(acl2-unwind *ld-level* nil)
(f-put-global 'inhibit-output-lst nil *the-live-state*)
(f-put-global 'slow-array-action :warning *the-live-state*)
; This is where to start up proof trees if we ever decide that this should be
; the default. But probably we don't want to do it in MCL.
(stop-proof-tree-fn *the-live-state*)
(f-put-global 'ld-skip-proofsp nil *the-live-state*)
(move-current-acl2-world-key-to-front (w *the-live-state*))
(checkpoint-world1 t (w *the-live-state*) *the-live-state*))
(defun-one-output ld-alist-raw (standard-oi ld-skip-proofsp ld-error-action)
`((standard-oi . ,standard-oi)
(standard-co . ,*standard-co*)
(proofs-co . ,*standard-co*)
(current-package . "ACL2")
(ld-skip-proofsp . ,ld-skip-proofsp)
(ld-redefinition-action . nil)
(ld-prompt . ,(if ld-skip-proofsp nil t))
(ld-missing-input-ok . nil)
(ld-pre-eval-filter . :all)
(ld-pre-eval-print . ,(if ld-skip-proofsp nil t))
(ld-post-eval-print . :command-conventions)
(ld-evisc-tuple .
; In order to avoid printing huge forms during initialization when ld-ing files
; that are among the pass two files:
,(abbrev-evisc-tuple *the-live-state*))
(ld-error-triples . t)
(ld-error-action . ,ld-error-action)
(ld-query-control-alist . t)
(ld-verbose . t)))
(defun enter-boot-strap-pass-2 ()
; We must provide set-w a frame on which to push its undo forms.
(push nil *acl2-unwind-protect-stack*)
(set-w 'extension
(global-set 'boot-strap-pass-2 t (w *the-live-state*))
*the-live-state*)
(acl2-unwind *ld-level* nil)
; We use an explicit call of LD-fn to change the defun-mode to :logic just to
; lay down an event in the pre-history, in case we someday want to poke around
; at the boundary.
(ld-fn (ld-alist-raw '((logic))
t
:error)
*the-live-state* nil))
; The following constant should be changed when we add to the collection of
; files to be processed in :logic default-defun-mode.
(defconst *acl2-pass-2-files*
; Note that some books depend on "memoize", "hons", and "serialize", even in
; #-hons. For example, community book books/misc/hons-help.lisp uses hons
; primitives.
'("axioms"
"memoize"
"hons"
"serialize"
"boot-strap-pass-2"
))
; Next we define fns-different-wrt-acl2-loop-only, used below in
; check-built-in-constants. We base our code loosely on
; functions-defined-in-file in hons-raw.lisp.
(defun our-update-ht (key val ht)
(let ((old (gethash key ht)))
(setf (gethash key ht)
(cond ((and (consp old)
(eq (car old) :multiple))
(list* (car old) val (cdr old)))
(old (list :multiple val))
(t val)))))
(defun note-fns-in-form (form ht)
; For every macro and every function defined by form, associate its definition
; with its name in the given hash table, ht. See note-fns-in-files.
(and (consp form)
(case (car form)
((defun defund defn defproxy defun-nx defun-one-output defstub
defmacro defabbrev defun@par defmacro-last defun-overrides)
(our-update-ht (cadr form) form ht))
(save-def
(note-fns-in-form (cadr form) ht))
(defun-for-state
(our-update-ht (defun-for-state-name (cadr form)) form ht))
(define-global
(our-update-ht (define-global-name (cadr form)) form ht)
(our-update-ht (cadr form) form ht))
((define-pc-atomic-macro define-pc-bind define-pc-help define-pc-macro
define-pc-meta define-pc-primitive)
(let ((name (make-official-pc-command
(if (eq (car form) 'define-pc-meta-or-macro-fn)
(nth 2 form)
(nth 1 form)))))
(our-update-ht name form ht)))
((mutual-recursion mutual-recursion@par progn)
(loop for x in (cdr form)
do (note-fns-in-form x ht)))
((encapsulate when)
(loop for x in (cddr form)
do (note-fns-in-form x ht)))
((skip-proofs local)
(note-fns-in-form (cadr form) ht))
(defrec ; pick just one function introduced
(our-update-ht (record-changer-function-name (cadr form)) form ht))
((add-custom-keyword-hint
add-macro-alias
add-macro-fn
#+ccl ccl:defstatic
declaim
def-basic-type-sets
defattach
defaxiom
defconst
defconstant
defdoc
defg
define-@par-macros
define-atomically-modifiable-counter
define-trusted-clause-processor ; should handle :partial-theory
deflabel
deflock
defparameter
defpkg
defstruct
deftheory
defthm
defthmd
deftype
defun-*1*
defv
defvar
eval ; presumably no ACL2 fn or macro underneath
eval-when ; presumably no ACL2 fn or macro underneath
f-put-global ; in axioms.lisp, before def. of set-ld-skip-proofsp
in-package
in-theory
initialize-state-globals
let ; could be arbitrarily complex, but we can only do so much!
link-doc-to
link-doc-to-keyword
logic
make-waterfall-parallelism-constants
make-waterfall-printing-constants
push
reset-future-parallelism-variables
set-invisible-fns-table
set-tau-auto-mode
set-waterfall-parallelism
setq
system-verify-guards
table
value
verify-guards
verify-termination-boot-strap)
nil)
(t
(error "Unexpected type of form, ~s. See note-fns-in-form."
(car form))))))
(defun note-fns-in-file (filename ht)
; For every macro and every function defined in the indicated file, associate
; its definition with its name in the given hash table, ht. See
; note-fns-in-files.
(with-open-file
(str filename :direction :input)
(let ((avrc (cons nil nil))
x)
(loop while (not (eq (setq x (read str nil avrc))
avrc))
do
(note-fns-in-form x ht)))))
(defun note-fns-in-files (filenames ht loop-only-p)
; For every macro and every function defined in filenames, associate its
; definition with its name in the given hash table, ht. We read each file in
; filenames either with or without feature :acl2-loop-only, according to
; whether loop-only-p is true or false, respectively.
(let ((*features* (if loop-only-p
(push :acl2-loop-only *features*)
(remove :acl2-loop-only *features*))))
(loop for filename in filenames
do (note-fns-in-file filename ht))))
(defun raw-source-name-p (filename-without-extension)
(let ((len (length filename-without-extension)))
(and (<= 4 len)
(equal (subseq filename-without-extension (- len 4) len)
"-raw"))))
; Set the following to t for a more informative error report.
(defvar *check-built-in-constants-debug* nil)
(defun fns-different-wrt-acl2-loop-only (acl2-files)
; For each file in acl2-files we collect up all definitions of functions and
; macros, reading each file both with and without feature :acl2-loop-only. We
; return (mv macro-result program-mode-result logic-mode-result), where each of
; macro-result, program-mode-result, and logic-mode-result is a list of
; symbols. Each symbol is the name of a macro, program-mode function, or
; logic-mode function (respectively) defined with feature :acl2-loop-only,
; which has a different (or absent) definition without feature :acl2-loop-only.
; This function is typically called with acl2-files equal to *acl2-files*, in
; the build directory. See the comment about redundant definitions in
; chk-acceptable-defuns-redundancy for a pertinent explanation.
(let ((logic-filenames (loop for x in acl2-files
when (not (raw-source-name-p x))
collect (concatenate 'string x ".lisp")))
(raw-filenames (loop for x in acl2-files
collect (concatenate 'string x ".lisp")))
(ht-raw (make-hash-table :test 'eq))
(ht-logic (make-hash-table :test 'eq))
(macro-result nil)
(program-mode-result nil)
(logic-mode-result nil)
(wrld (w *the-live-state*)))
(note-fns-in-files raw-filenames ht-raw nil)
(note-fns-in-files logic-filenames ht-logic t)
(maphash (lambda (key logic-val)
(progn
(assert (symbolp key))
(let ((raw-val (gethash key ht-raw)))
(or (equal logic-val raw-val)
(let ((x
(if *check-built-in-constants-debug*
(list key :logic logic-val :raw raw-val)
key)))
(cond ((getprop key 'macro-body nil
'current-acl2-world wrld)
(push x macro-result))
((eq (symbol-class key wrld)
:program)
(push x program-mode-result))
(t
(push x logic-mode-result))))))))
ht-logic)
(maphash (lambda (key raw-val)
(progn
(assert (symbolp key))
(when (not (or (gethash key ht-logic)
(assoc key *primitive-formals-and-guards* :test
'eq)))
(cond ((getprop key 'macro-body nil
'current-acl2-world wrld)
(push key macro-result))
(t (let ((c ; avoid symbol-class (defaults to :program)
(getprop key 'symbol-class nil
'current-acl2-world wrld)))
(when c
(let ((x
(if *check-built-in-constants-debug*
(list key :raw raw-val)
key)))
(if (eq c :program)
(push x program-mode-result)
(push x logic-mode-result))))))))))
ht-raw)
(mv macro-result program-mode-result logic-mode-result)))
(defun collect-monadic-booleans (fns ens wrld)
(cond ((endp fns) nil)
((and (equal (arity (car fns) wrld) 1)
(ts= (mv-let (ts ttree)
(type-set (fcons-term* (car fns) '(V)) nil nil nil
ens wrld
nil nil nil)
(declare (ignore ttree))
ts)
*ts-boolean*))
(cons (car fns)
(collect-monadic-booleans (cdr fns) ens wrld)))
(t (collect-monadic-booleans (cdr fns) ens wrld))))
(defun check-built-in-constants ()
; Certain defconsts are problematic because they build in values that one
; cannot know until the system is built! Getting their values right requires
; some thought or experiment and even then subsequent changes to the system can
; render the values incorrect. To guard against incorrect (obsolete) values
; for these contants, this function causes an error if doesn't like what it
; sees. We document only one such constant, *force-xnume*, which more or less
; describes the situation suffered by all of them.
; Our Code requires that *force-xnume* be the nume of (:EXECUTABLE-COUNTERPART
; FORCE). It would be nice to be able to write: (defconst *force-xnume*
; (fn-rune-nume 'force t t (w state))). But that suffers TWO problems. The
; first is that defconst disallows the use of any variable in the initial value
; form. Thus, state is illegal above. We tried fixing that, in a hypocritical
; way, by allowing it to ourselves in boot-strap even though we denied it to
; the user. But even that doesn't work because of the second problem: The
; first time the defconst is processed, no numes are being allocated because
; everything is done in the :program defun-mode. You might think, therefore,
; we ought to delay the execution of this defconst until after we've done the
; second pass and created the rune in question. But we cannot do that because
; we use *force-xnume* in our code (namely, in ok-to-force) and that function
; can't be defined until *force-xnume* is defined. Thus, this seemingly
; hackish way of doing it, where we actually specify ahead of time which nume
; will be assigned, is not as outlandish as it might at first seem. We check
; that the actual assignment is correct (using this function) after booting.
(let ((str "The defconst of ~x0 is ~x1 but should be ~x2. To fix ~
the error, change the offending defconst to the value ~
indicated and rebuild the system. To understand why the code ~
is written this way, see the comment in ~
check-built-in-constants."))
(cond
((not (equal *force-xnume* (fn-rune-nume 'force t t (w *the-live-state*))))
(interface-er str
'*force-xnume*
*force-xnume*
(fn-rune-nume 'force t t (w *the-live-state*)))))
(cond
((not
(equal *immediate-force-modep-xnume*
(fn-rune-nume 'immediate-force-modep t t (w *the-live-state*))))
(interface-er str
'*immediate-force-modep-xnume*
*immediate-force-modep-xnume*
(fn-rune-nume 'immediate-force-modep t t (w *the-live-state*)))))
(cond
((not
(equal *tau-system-xnume*
(fn-rune-nume 'tau-system t t (w *the-live-state*))))
(interface-er str
'*tau-system-xnume*
*tau-system-xnume*
(fn-rune-nume 'tau-system t t (w *the-live-state*)))))
(cond
((not
(equal *tau-acl2-numberp-pair*
(getprop 'acl2-numberp 'tau-pair nil
'current-acl2-world (w *the-live-state*))))
(interface-er str
'*tau-acl2-numberp-pair*
*tau-acl2-numberp-pair*
(getprop 'acl2-numberp 'tau-pair nil
'current-acl2-world (w *the-live-state*)))))
(cond
((not
(equal *tau-integerp-pair*
(getprop 'integerp 'tau-pair nil
'current-acl2-world (w *the-live-state*))))
(interface-er str
'*tau-integerp-pair*
*tau-integerp-pair*
(getprop 'integerp 'tau-pair nil
'current-acl2-world (w *the-live-state*)))))
(cond
((not
(equal *tau-rationalp-pair*
(getprop 'rationalp 'tau-pair nil
'current-acl2-world (w *the-live-state*))))
(interface-er str
'*tau-rationalp-pair*
*tau-rationalp-pair*
(getprop 'rationalp 'tau-pair nil
'current-acl2-world (w *the-live-state*)))))
(cond
((not
(equal *tau-natp-pair*
(getprop 'natp 'tau-pair nil
'current-acl2-world (w *the-live-state*))))
(interface-er str
'*tau-natp-pair*
*tau-natp-pair*
(getprop 'natp 'tau-pair nil
'current-acl2-world (w *the-live-state*)))))
(cond
((not
(equal *tau-posp-pair*
(getprop 'posp 'tau-pair nil
'current-acl2-world (w *the-live-state*))))
(interface-er str
'*tau-posp-pair*
*tau-posp-pair*
(getprop 'posp 'tau-pair nil
'current-acl2-world (w *the-live-state*)))))
(cond
((not
(equal *tau-minusp-pair*
(getprop 'minusp 'tau-pair nil
'current-acl2-world (w *the-live-state*))))
(interface-er str
'*tau-minusp-pair*
*tau-minusp-pair*
(getprop 'minusp 'tau-pair nil
'current-acl2-world (w *the-live-state*)))))
(cond
((not
(equal *tau-booleanp-pair*
(getprop 'booleanp 'tau-pair nil
'current-acl2-world (w *the-live-state*))))
(interface-er str
'*tau-booleanp-pair*
*tau-booleanp-pair*
(getprop 'booleanp 'tau-pair nil
'current-acl2-world (w *the-live-state*)))))
(cond
((not
(and (equal
*min-type-set*
#-:non-standard-analysis -8192 #+:non-standard-analysis -65536)
(equal
*max-type-set*
#-:non-standard-analysis 8191 #+:non-standard-analysis 65535)))
(interface-er
"The minimal and maximal type-sets are incorrectly built into the ~
definition of type-alist-entryp. These type-sets get generated by ~
the call of def-basic-type-sets in type-set-a.lisp are must be ~
mentioned, as above, in axioms.lisp. Evidently, a new type-set bit ~
was added. Update type-alist-entryp.")))
(cond
((not
(equal *primitive-monadic-booleans*
(collect-monadic-booleans
(strip-cars *primitive-formals-and-guards*)
(ens *the-live-state*)
(w *the-live-state*))))
(interface-er str
'*primitive-monadic-booleans*
*primitive-monadic-booleans*
(collect-monadic-booleans
(strip-cars *primitive-formals-and-guards*)
(ens *the-live-state*)
(w *the-live-state*)))))
(cond
((not (getprop 'booleanp 'tau-pair nil 'current-acl2-world (w *the-live-state*)))
(interface-er
"Our code for tau-term assumes that BOOLEANP is a tau predicate. But ~
it has no tau-pair property!")))
(let ((good-lst (chk-initial-built-in-clauses *initial-built-in-clauses*
(w *the-live-state*) nil nil)))
(cond
(good-lst
(interface-er
"The defconst of *initial-built-in-clauses* is bad because at least ~
one of the records supplies an :all-fnnames that is different from ~
that computed by all-fnnames-subsumer. The correct setting is ~
shown below. To preserve the comments in the source file it might ~
be best to compare -- with EQUAL -- the elements below with the ~
corresponding elements in the current source file and just replace ~
the ones that have changed. Here is a correct setting in 1:1 ~
correspondence with the current setting: ~X01."
`(defconst *initial-built-in-clauses*
(list ,@good-lst))
nil))))
(mv-let
(macros-found program-found logic-found)
(fns-different-wrt-acl2-loop-only *acl2-files*)
(flet ((my-diff (x y)
(if *check-built-in-constants-debug*
(loop for tuple in x
when (not (member (car tuple) y :test 'eq))
collect tuple)
(set-difference-eq x y))))
(let ((bad-macros (my-diff macros-found
*primitive-macros-with-raw-code*))
(bad-program (my-diff program-found
*primitive-program-fns-with-raw-code*))
(bad-logic (my-diff logic-found
*primitive-logic-fns-with-raw-code*)))
(when (or bad-macros bad-program bad-logic)
(format t "Failed check for coverage of functions with acl2-loop-only code
differences! Please send this error message to the ACL2 implementors.
Missing functions (use *check-built-in-constants-debug* = t for verbose report):
~s
~s;
~a
~s:
~a"
; We need to update *primitive-macros-with-raw-code*,
; *primitive-program-fns-with-raw-code*, or
; *primitive-logic-fns-with-raw-code*, respectively according to the non-nil
; fields in the error message.
(list (list '*primitive-macros-with-raw-code*
bad-macros)
(list '*primitive-program-fns-with-raw-code*
bad-program)
(list '*primitive-logic-fns-with-raw-code*
bad-logic))
'(lisp-implementation-type)
(lisp-implementation-type)
'(lisp-implementation-version)
(lisp-implementation-version))
(error "Check failed!")))))
; The following is a start on checking that we don't have superfluous symbols
; in the list values of certain constants. But in fact there can be such
; symbols: we want the value for each constant must be independent of
; features :hons or :acl2-par, yet some macros and functions are only defined
; when such features are present. We may think more about this later.
; (let ((undefined-macros
; (loop for x in *primitive-macros-with-raw-code*
; when (not (or (macro-function x) (symbol-function x)))
; collect x))
; (undefined-program-fns
; (loop for x in *primitive-program-fns-with-raw-code*
; when (not (fboundp x))
; collect x))
; (undefined-logic-fns
; (loop for x in *primitive-logic-fns-with-raw-code*
; when (not (fboundp x))
; collect x)))
; (when undefined-macros
; (format
; t
; "Undefined macros in *primitive-macros-with-raw-code*:~%~s~%"
; undefined-macros))
; (when undefined-program-fns
; (format
; t
; "Undefined macros in *primitive-program-fns-with-raw-code*:~%~s~%"
; undefined-program-fns))
; (when undefined-logic-fns
; (format
; t
; "Undefined macros in *primitive-logic-fns-with-raw-code*:~%~s~%"
; undefined-logic-fns))
; (when (or undefined-macros undefined-program-fns undefined-logic-fns)
; (error "Check failed!")))
))
(defun-one-output check-none-ideal (trips acc)
(cond
((null trips)
(cond ((null acc) nil)
(t (er hard 'check-none-ideal
"The following are :ideal mode functions that are not ~
non-executable. We rely in oneify-cltl-code on the absence ~
of such functions in the boot-strap world (see the comment ~
on check-none-ideal there). These functions should have ~
their guards verified: ~&0."
acc))))
(t
(let* ((trip (car trips))
(fn
; We need to rule out triples such as the following (but for :ideal mode)
; (EVENT-LANDMARK GLOBAL-VALUE 5054
; (DEFUN EVENS . :COMMON-LISP-COMPLIANT)
; DEFUN EVENS (L)
; (DECLARE (XARGS :GUARD (TRUE-LISTP L)))
; (COND ((ENDP L) NIL)
; (T (CONS (CAR L) (EVENS (CDDR L))))))
(and (eq (car trip) 'event-landmark)
(true-listp trip)
(eq (cadr trip) 'global-value)
(eq (nth 4 trip) 'defun)
(nth 5 trip))))
(cond ((and fn
(symbolp fn)
(eq (symbol-class fn
(w *the-live-state*))
:ideal)
(not (eq (getprop fn 'non-executablep nil
'current-acl2-world (w *the-live-state*))
t)))
(check-none-ideal (cdr trips) (cons fn acc)))
(t (check-none-ideal (cdr trips) acc)))))))
(defun check-state-globals-initialized ()
(let (bad)
(do-symbols
(sym (find-package "ACL2_GLOBAL_ACL2"))
(when (boundp sym)
(let ((acl2-sym (intern (symbol-name sym) "ACL2")))
(when (not
(or (assoc acl2-sym *initial-global-table* :test 'eq)
(assoc acl2-sym *initial-ld-special-bindings* :test 'eq)))
(push (cons acl2-sym (symbol-value sym))
bad)))))
(when bad
(error
"The following symbols, perhaps with the values shown, need to~%~
be added to *initial-global-table*:~%~s~%"
bad))))
(defun-one-output check-acl2-initialization ()
(check-built-in-constants)
(check-out-instantiablep (w *the-live-state*))
(check-none-ideal (w *the-live-state*) nil)
(check-state-globals-initialized))
(defun set-initial-cbd ()
(let ((state *the-live-state*))
(setq *initial-cbd* (our-pwd))
; In CCL, it seems that *initial-cbd* as computed above could give a string
; not ending in "/". We fix that here.
(cond ((and (stringp *initial-cbd*)
(not (equal *initial-cbd* ""))
(not (eql (char *initial-cbd*
(1- (length *initial-cbd*)))
#\/)))
(setq *initial-cbd*
(concatenate 'string *initial-cbd* "/"))))
(cond ((not (absolute-pathname-string-p
*initial-cbd*
t
(get-os)))
(error
"Our guess for the initial setting of cbd, ~x0, which was ~%~
generated by (our-pwd), is not a legal directory! Before ~%~
entering ACL2, please setq *initial-cbd* to a nonempty ~%~
string that represents an absolute ACL2 (i.e., Unix-style) ~%~
pathname. Sorry for the inconvenience."
*initial-cbd*)))
(f-put-global 'connected-book-directory *initial-cbd*
state)))
(defun initialize-acl2 (&optional (pass-2-ld-skip-proofsp 'include-book)
(acl2-pass-2-files *acl2-pass-2-files*)
system-books-dir
skip-comp-exec)
; Note: if system-books-dir is supplied, it should be a Unix-style
; pathname (either absolute or not [doesn't matter which]).
; This function first lds all of the *acl2-files* except boot-strap-pass-2.lisp
; and *-raw.lisp in default-defun-mode :program (which is the default
; default-defun-mode). It then loads the files in acl2-pass-2-files in :logic
; mode.
; During the first pass, ld-skip-proofsp is 'initialize-acl2, which is like the
; setting t (doing syntactic checks but skipping proofs and LOCALs) but omits a
; few of the checks so the bootstrapping can be done. During the second pass,
; ld-skip-proofsp is as specified by the &optional parameter above. It
; defaults to 'include-book, which means we skip LOCALs, all syntactic checks,
; and proofs. By calling this function with pass-2-ld-skip-proofsp nil you can
; arrange for it to try to prove its way through the second pass. However, see
; below.
; Why Two Passes? By doing things in two passes we make it possible to use all
; system functions in hints and other proof commands. In the one-pass
; initialization we used to use, it was impossible to use theory expressions in
; the defthms in axioms.lisp because the necessary theory functions were not
; yet defined and so trans-eval balked on them.
(when (null system-books-dir)
(let ((dir (getenv$-raw "ACL2_SYSTEM_BOOKS")))
(when (and dir (not (equal dir "")))
(setq system-books-dir dir))))
(with-warnings-suppressed
; Interactive Proofs: Many times, (initialize-acl2 nil) -- which causes the
; system to prove the admissibility of everything done in the second pass --
; will fail because insufficient lemmas are available to handle new functions
; added since the last such proof. But it will leave you in a state so that
; you can continue to develop proofs. In particular, if you have changed some
; of the proved code, e.g., axioms.lisp, and you wish to re-verify it, you can
; proceed as follows. First, fire up akcl. Then do (acl2::load-acl2).
; Finally do (initialize-acl2 nil) and wait for the first proof to fail. When
; it fails you will be returned to lisp. There, in raw lisp, you should
; execute
; (let ((state *the-live-state*))
; (reset-ld-specials t)
; ; (set-ld-redefinition-action '(:doit! . :overwrite) state) ;see below
; )
; This will set the ld-specials to their conventional post-boot-strap setting,
; except (possibly) for ld-redefinition-action which will allow redefinition.
; (We discuss this more below.) Then enter the loop with (LP!), which will set
; *features* to include :acl2-loop-only in case read conditionals are present
; in the sources you wish to develop. Once in the loop, you should be able to
; continue as normal with proof development.
; If the initialization did not get beyond pass one, :q is undefined and the
; only way to exit is to do (mv nil :q state). You will also note that other
; keyword commands, e.g., :pc, are unavailable. You can always execute the
; appropriate form in raw lisp, e.g.,
; (let ((state *the-live-state*)) (pc 'fn))
; If you did get beyond pass one, things will be pretty normal looking except
; that inspection will show that both (global-val 'boot-strap-flg (w state))
; and (global-val 'boot-strap-pass-2 (w state)) are t. This will manifest
; itself in some perhaps surprising ways during interactive proofs, e.g.,
; redundant deflabels are admitted during the second pass.
; Is Redefinition Permission Necessary? Not always. If you are re-verifying
; the sources the chances are you've changed something. Suppose some event is
; no longer admissible. If you have to change a function definition to admit
; it, i.e., one of your new events is incorrectly written, then redefinition
; permission is necessary because what you are trying to do is NOT just a
; simple reclassifying (you're changing the definition). If on the other hand
; you are not changing definitions but adding them, you need not perform the
; set-ld-redefinition-action shown above. A conservative thing to do is to
; leave the redefinition action nil and not set it until necessary.
; How do I Add a New Function Definition? If you try to add to the sources a
; new function definition while in pass one of the initialization it will fail
; because we insist that all functions defined logically already have raw lisp
; definitions. You should define the function first in raw lisp (by exiting
; the LP!) and then in the loop. If you discovered this problem by provoking
; the hard error: ACL2 Error in ACL2-INTERFACE: fn is not fboundp! then you
; must first exit the lisp break with :q. This will revert the world and throw
; you out of the LP!. The world is as it was before the offensive definition,
; so you should define the function in raw lisp, reenter LP! and proceed as
; intended.
; The Special State Discussion: We bind state to *the-live-state* below because
; the macro expansion of ld introduces the variable state. Once upon a time we
; declared state special with (defparameter state *the-live-state*) in this
; file. But that had the effect of preventing tail-recursion removal in
; situations like (pprogn (princ$ ...) (recursive-call ...)) because pprogn
; macro expands to a binding of state and you can't jump out of a binding of a
; special in tail recursion (it is only allowed if it is lexical). Thus, we
; got the curious and frustrating problem that if we recompiled system
; functions (like print-doc-string-part1) then they would no longer have tail
; recursions removed, even though the recursion would be so removed when we
; made the system from scratch. (Reiterating the reason: between the two
; compilations of the function, state became special. Had we declared state
; special in axioms.lisp instead of here in interface-raw.lisp, none of
; tail-recursion removal on state changing functions would have been done!) We
; no longer make state special and hence must bind it to *the-live-state*
; lexically when its use is unavoidable. In point of fact we now evaluate
; (setq state *the-live-state*) in (load-acl2), without making state special,
; and hence state may be used in raw Lisp after the system is loaded as long as
; the form using state is not compiled.
; Finally: another way to prove your way through axioms.lisp is to invoke
; (acl2::load-acl2) and (initialize-acl2), then save the system (e.g., in akcl
; execute (si::save-system "my-saved_acl2")), and now each time you invoke that
; saved image first execute
; (defconst *acl2-pass-2-files* '())
; in raw Lisp (or, execute this before saving the image), and then after
; executing (LP!) submit the form
; (set-w 'extension (global-set 'boot-strap-pass-2 t (w state)) state)
; to ACL2 in order to allow system DEFLABELs to be considered redundant.
; Save perhaps 12K in image.
(set-initial-cbd)
(makunbound '*copy-of-common-lisp-symbols-from-main-lisp-package*)
(let* ((*features* (cons :acl2-loop-only *features*))
#+akcl
; AKCL compiler note stuff. We have so many tail recursive functions
; that the notes about tail recursion optimization are just too much
; to take.
(compiler:*suppress-compiler-notes* t)
(state *the-live-state*)
pass-2-alist)
(enter-boot-strap-mode system-books-dir (get-os))
; Rockwell Addition: Here we initialize the nu-rewriter memo cache.
(initialize-nu-memos 65534)
(setq pass-2-alist
(let ((ans nil))
(dolist
(fl acl2-pass-2-files)
(mv-let (erp val state)
; Warning. Because of the read-file here, we have to be careful not to define
; any packages in the pass-2 files that contain symbols mentioned in those
; files. The read-file will break in any such case; the DEFPKG in such a file
; must be processed first.
(read-file (coerce
(append (coerce fl 'list)
(cons #\. (coerce *lisp-extension*
'list)))
'string)
*the-live-state*)
(declare (ignore state))
(cond (erp (interface-er "Unable to read file ~x0!"
fl))
(t (push (cons fl val) ans)))))
ans))
(dolist
(fl *acl2-files*)
(when (not (or (equal fl "boot-strap-pass-2")
(raw-source-name-p fl)))
(mv-let (er val st)
(ld-fn
(ld-alist-raw (or (cdr (assoc fl pass-2-alist :test #'equal))
(coerce
(append (coerce fl 'list)
(cons #\. (coerce *lisp-extension*
'list)))
'string))
'initialize-acl2
:error)
*the-live-state*
nil)
(declare (ignore val st))
(cond (er
; The load caused an error. We abort quietly without doing anything
; else so we are in the same state.
(return-from initialize-acl2 nil))))))
(enter-boot-strap-pass-2)
(dolist
(fl acl2-pass-2-files)
(mv-let (er val st)
(ld-fn
(ld-alist-raw (or (cdr (assoc fl pass-2-alist :test #'equal))
(interface-er "Did not find ~x0 in pass-2-alist."
fl))
pass-2-ld-skip-proofsp
:error)
state
nil)
(declare (ignore val st))
(cond (er
; The load caused an error. We abort quietly without doing anything
; else so we are in the same state.
(return-from initialize-acl2 nil)))))
; It is important not to wait to write out TMP1.lisp until after we leave the
; boot-strap. By doing so before that time, we ensure that the guard-check
; under safe mode is made for primitives (see oneify-cltl-code), and that
; compile-uncompiled-*1*-defuns will not encounter 'exit-boot-strap-mode and
; thus stop finding functions to compile. We use a call of ld here to make
; possible the subsidiary uses of state-global-let* on behalf of macroexpand1
; (see the comment in comp-fn for more information).
(if (not skip-comp-exec)
; Optimization: Skip this compile for generate-acl2-proclaims.
(ld '((comp-fn :exec nil "1" state))))
(exit-boot-strap-mode)
(initialize-pc-acl2 *the-live-state*)
; We now set up the ld specials as we wish them for the user's first
; invocation of LP. The ld specials were previously initialized (in
; enter-boot-strap-mode) to the same values used below (because the
; LDs above make reference to some of them so they must be bound).
; But the LD above changes them so we now initialize them again.
(f-put-ld-specials *initial-ld-special-bindings* *the-live-state*)
; We now check certain invariants, for example, that we have defined certain
; built-in constants correctly.
(or (not acl2-pass-2-files)
; The check for check-built-in-constants in check-acl2-initialization, for one,
; will fail if we do not make a second pass through axioms.lisp. That is
; because all (or at least most) of the 'level-no properties are still 0 before
; then, so chk-initial-built-in-clauses (called in check-built-in-constants)
; will fail, because its subroutine all-fnnames-subsumer does not behave
; properly until the 'level-no properties are set.
(check-acl2-initialization))
(cond
((or (not (probe-file *acl2-status-file*))
(delete-file *acl2-status-file*))
(with-open-file (str *acl2-status-file*
:direction :output)
(format str
"~s"
; The next token, :INITIALIZED, is used in GNUmakefile; keep in sync.
:INITIALIZED))))
; If you want the final image to have infixp = t, then put the following
; form here:
; (f-put-global 'infixp t *the-live-state*)
t)))
; LP
; Lp is the function that an ACL2 user invokes to get into the ACL2
; read-eval-print loop.
; Essay on Pathnames
; We use Unix-style pathnames everywhere in ACL2 except when interfacing with
; the operating system. Functions defined in this file, interface-raw.lisp,
; generally use real pathname strings for the host operating system.
; (Exceptions are clearly labeled, including compile-uncompiled-defuns and
; compile-uncompiled-*1*-defuns.) Functions defined outside this file
; (interface-raw.lisp) pass around ACL2 (Unix-style) pathname strings. Here
; are some functions that take pathnames whose form is based on (os (w state))
; rather than on Unix.
; acl2-compile-file [but see comment there]
; compile-file
; convert-book-name-to-compiled-name [Unix pathname is OK too]
; delete-file
; delete-compiled-file
; load
; probe-file
; proclaim-file
; Before defining lp, we provide support for inhibiting breaks.
#-(and gcl (not cltl2))
(defun our-abort (condition y
&aux
(state *the-live-state*)
(btp (member-eq
(f-get-global 'debugger-enable *the-live-state*)
'(:bt :break-bt :bt-break))))
; Keep this in sync with :doc set-debugger-enable.
(declare (ignore y))
#+acl2-par (setq *reset-parallelism-variables* t)
(print-proof-tree-finish state)
(when btp (print-call-history))
(cond ((or (debugger-enabledp state)
(eql *ld-level* 0)
; (global-val 'boot-strap-flg (w state)) ; avoid the potential error
(getprop 'boot-strap-flg 'global-value nil 'current-acl2-world
(w state)))
nil)
(t
(let ((*debugger-hook* nil) ; extra care to avoid possible loop
#+ccl ; as above, for CCL revision 12090 and beyond
(ccl::*break-hook* nil)
(*package* (find-package (current-package state)))
(continue-p (and (find-restart 'continue)
*acl2-time-limit-boundp*
(not (eql *acl2-time-limit* 0)))))
#+ccl ; for CCL revisions before 12090
(declare (ignorable ccl::*break-hook*))
(terpri t)
(format t
"***********************************************")
(cond
(continue-p
(format t
"~&Note: ~A~
~& Will attempt to exit the proof in progress;~
~& otherwise, the next interrupt will abort the proof."
condition))
(t
(format t
"~&************ ABORTING from raw Lisp ***********")
(format t
"~&Error: ~A"
condition)))
(when btp (format t "~%NOTE: See above for backtrace.~%"))
(format t
"~&***********************************************~&")
(unless *acl2-error-p*
(format
t
"~%The message above might explain the error. If not, and~%~
if you didn't cause an explicit interrupt (Control-C),~%~
then the root cause may be call of a :program mode~%~
function that has the wrong guard specified, or even no~%~
guard specified (i.e., an implicit guard of t).~%~
See :DOC guards.~&"))
(when (not (member-eq 'set-debugger-enable-fn
; (global-val 'untouchable-fns (w state))
(getprop 'untouchable-fns 'global-value nil
'current-acl2-world (w state))))
(format t
"~%To enable breaks into the debugger (also see :DOC ~
acl2-customization):~&~s~&"
'(set-debugger-enable t)))
(force-output t)
(cond (continue-p
(setq *acl2-time-limit* 0)
(invoke-restart 'continue))
(t
; Parallelism blemish: as of May 16, 2011, we also reset all parallelism
; variables in Rager's modified version of the source code. However, that
; strikes Rager as strange, since we went through so much trouble to find out
; where we should reset parallelism variables. So, it is now commented out,
; today, May 16, 2011, and we will wait to see what happens.
; #+acl2-par
; (reset-all-parallelism-variables)
; Parallelism blemish: after a single proof runs for awhile, at least with
; waterfall parallelism enabled, it can take two interrupts before the abort
; occurs. It would be nice if the proof could abort after the first interrupt,
; since when two interrupts are required, the summary does not print the
; ACL2(p) checkpoints.
(our-ignore-errors ; might not be in scope of catch
(throw 'local-top-level :our-abort))))))))
; We formerly set *debugger-hook* here, but now we set it in lp; see the
; comment there.
#+ccl ; for CCL revisions starting with 12090
(when (boundp 'ccl::*break-hook*)
(setq ccl::*break-hook* 'our-abort))
(defun initial-customization-filename ()
(let* ((cfb00 (getenv$-raw "ACL2_CUSTOMIZATION"))
(cfb0 (if (equal cfb00 "NONE")
:none
(and cfb00
(not (equal cfb00 ""))
(extend-pathname (f-get-global 'connected-book-directory
*the-live-state*)
cfb00
*the-live-state*)))))
(cond
((eq cfb0 :none)
:none)
((and cfb0 (probe-file cfb0))
cfb0)
(cfb0 ; but (not (probe-file cfb0))
(let ((*print-circle* nil))
(format t
"~%ERROR: Environment variable ACL2_CUSTOMIZATION has value~%~
~3T~a~%but file~%~3T~a~%does not appear to exist.~%~
Now quitting ACL2. To fix this problem, you may wish~%~
to fix the value of that environment variable by setting it~%~
to a valid file name, by unsetting it, or by setting it to~%~
the empty string.~%~%"
cfb00
cfb0))
(exit-lisp 1))
(t
(let* ((cb1 (our-merge-pathnames
(f-get-global 'connected-book-directory *the-live-state*)
"acl2-customization"))
(cfb1 (string-append cb1 ".lsp"))
(cfb1a (string-append cb1 ".lisp")))
(cond
((probe-file (pathname-unix-to-os cfb1 *the-live-state*))
cfb1)
((probe-file (pathname-unix-to-os cfb1a *the-live-state*))
cfb1a)
(t
(let* ((home (our-user-homedir-pathname))
(cb2 (and home
(our-merge-pathnames
; The call of pathname-os-to-unix below may seem awkward, since later we apply
; pathname-unix-to-os before calling probe-file. However, our-merge-pathnames
; requires Unix-style pathname arguments, and we prefer not to write an
; analogous function that takes pathnames for the host operating system.
(pathname-os-to-unix
; MCL does not seem to handle calls of truename correctly on logical pathnames.
; We should think some more about this, but for now, let's solve this problem
; by brute force.
#+(and mcl (not ccl))
(our-truename
(common-lisp::translate-logical-pathname
home)
t)
#-(and mcl (not ccl))
(our-truename home
"Note: Calling OUR-TRUENAME from ~
INITIAL-CUSTOMIZATION-FILENAME")
(os (w *the-live-state*))
*the-live-state*)
"acl2-customization")))
(cfb2 (and cb2 (string-append cb2 ".lsp")))
(cfb2a (and cb2 (string-append cb2 ".lisp"))))
(cond (cb2 (cond ((probe-file (pathname-unix-to-os
cfb2 *the-live-state*))
cfb2)
((probe-file (pathname-unix-to-os
cfb2a *the-live-state*))
cfb2a)
(t nil))))))))))))
#+(and acl2-par lispworks)
(setq system:*sg-default-size*
; Keep the below number in sync with the call to hcl:extend-current-stack in
; lp.
80000)
#+(and acl2-par lispworks)
(defun spawn-extra-lispworks-listener ()
; In Lispworks, we spawn a thread for the listener before we exit lp for the
; first time, so that when we exit lp, multiprocessing does not stop. This
; strategy is derived from the following quote, from Martin Simmons, of
; Lispworks.
;
; "If you want it to run a normal REPL, then you could call
; lw:start-tty-listener when acl2::lp returns. That will make a new thread
; running the REPL, which will prevent multiprocessing from stopping."
;
; Another strategy, which was never released, involved following the
; multiprocessing example in section 15.13 of the Lispworks 6.0 manual. To
; quickly outline that strategy, we (1) renamed "lp" to "lp1", (2) defined "lp"
; to spawn a thread that called "lp1", (3) saved the Lispworks image with the
; ":multiprocessing t" flag, and (4) ensured that the Lispworks image's restart
; function was acl2-default-restart-function, which called "lp".
;
; We feel that Martin's suggested implementation is simpler, and so we
; use that.
;
; We rely on the following property of lw:start-tty-listener: if the tty
; listener is already running, calling lw:start-tty-listener does nothing.
(lw:start-tty-listener))
(defun lp (&rest args)
; This function can only be called from within raw lisp, because no ACL2
; function mentions it. Thus, we assume we are in raw lisp. This is the
; top-level entry to ACL2. Note that truename can cause an error in some
; Common Lisps when the given file or directory does not exist, in which case
; our-truename will generally return nil. Hence, we sometimes call
; our-truename on "" rather than on a file name.
(when args
(error "LP takes no arguments."))
(with-more-warnings-suppressed
; Parallelism wart: we currently reset the parallelism variables twice on
; startup. Removing the below call to reset-all-parallelism-variables should
; be the correct way to remove this double-reset, because we more thoroughly
; determine where to reset parallelism variables elsewhere in the code.
#+acl2-par
(reset-all-parallelism-variables)
; Remark for #+acl2-par. Here we set the gc-threshold to a high number. If
; the Lisps support it, this threshold could be based off the actual memory in
; the system. We peform this setting of the threshold in lp, because Lispworks
; doesn't save the GC configuration as part of the Lisp image.
; Parallelism no-fix: the threshold below may cause problems for machines with
; less than that amount of free RAM. At a first glance, this shouldn't
; realistically be a problem. However, a user might actually encounter this
; problem when running several memory-intensive ACL2(p) sessions in parallel
; via make -j.
#+acl2-par
(when (not *lp-ever-entered-p*) (set-gc-threshold$ (expt 2 30) nil))
#+(and acl2-par lispworks)
(when (not *lp-ever-entered-p*)
(sys:set-default-segment-size 0 :cons 250)
(sys:set-default-segment-size 1 :cons 250)
(sys:set-default-segment-size 2 :cons 250)
(sys:set-default-segment-size 0 :other 250)
(sys:set-default-segment-size 1 :other 250)
(sys:set-default-segment-size 2 :other 250))
#+acl2-par
(f-put-global 'parallel-execution-enabled t *the-live-state*)
(let ((state *the-live-state*)
#+(and gcl (not cltl2))
(lisp::*break-enable* (debugger-enabledp *the-live-state*)))
(cond
((> *ld-level* 0)
(when (raw-mode-p *the-live-state*)
(fms "You have attempted to enter the ACL2 read-eval-print loop from ~
within raw mode. However, you appear already to be in that ~
loop. If your intention is to leave raw mode, then execute: ~
:set-raw-mode nil.~|"
nil (standard-co *the-live-state*) *the-live-state* nil))
(return-from lp nil))
((not *lp-ever-entered-p*)
(set-initial-cbd)
(eval `(in-package ,*startup-package-name*)) ;only changes raw Lisp pkg
; We formerly set *debugger-hook* at the top level using setq, just below the
; definition of our-abort. But that didn't work in Lispworks, where that value
; persisted right up to the saving of an image yet *debugger-hook* was nil
; after starting up that image. Apparently Lispworks 6.0 sets *debugger-hook*
; globally to nil when input comes from a file, which is how ACL2 is built,
; rather than standard-input,
#-(and gcl (not cltl2))
(setq *debugger-hook* 'our-abort)
; Even with the setting of *stack-overflow-behaviour* to nil or :warn in
; acl2-init.lisp, we cannot eliminate the following form for LispWorks. (We
; tried with LispWorks 6.0 and Lispworks 6.0.1 with *stack-overflow-behaviour*
; = nil and without the following form, but we got segmentation faults when
; certifying community books books/concurrent-programs/bakery/stutter2 and
; books/unicode/read-utf8.lisp.)
#+lispworks (hcl:extend-current-stack 400)
#+(and lispworks acl2-par)
(when (< (hcl:current-stack-length)
; Keep the below number (currently 80000) in sync with the value given to
; *sg-default-size* (set elsewhere in our code).
80000)
(hcl:extend-current-stack
; this calculation sets the current stack length to be within 1% of 80000
(- (round (* 100 (/ (hcl:current-stack-length) 80000))) 100)))
; Acl2-default-restart isn't enough in Allegro, at least, to get the new prompt
; when we start up:
(let* ((system-dir (let ((str (getenv$-raw "ACL2_SYSTEM_BOOKS")))
(and str
(maybe-add-separator str))))
(save-expansion (let ((s (getenv$-raw "ACL2_SAVE_EXPANSION")))
(and s
(not (equal s ""))
(not (equal (string-upcase s)
"NIL")))))
(user-home-dir-path (our-user-homedir-pathname))
(user-home-dir0 (and user-home-dir-path
(our-truename user-home-dir-path
"Note: Calling ~
OUR-TRUENAME from LP.")))
(user-home-dir (and user-home-dir0
(if (eql (char user-home-dir0
(1- (length user-home-dir0)))
*directory-separator*)
(subseq user-home-dir0
0
(1- (length user-home-dir0)))
user-home-dir0))))
(when system-dir
(f-put-global 'system-books-dir
(canonical-dirname!
(unix-full-pathname system-dir)
'lp
*the-live-state*)
*the-live-state*))
(when (and save-expansion
(not (equal (string-upcase save-expansion)
"NIL")))
(f-put-global 'save-expansion-file t *the-live-state*))
(when user-home-dir
(f-put-global 'user-home-dir user-home-dir *the-live-state*)))
(set-gag-mode-fn :goals *the-live-state*)
#-hons
; Hons users are presumably advanced enough to tolerate the lack of a
; "[RAW LISP]" prompt.
(install-new-raw-prompt)
#+hons (f-put-global 'serialize-character-system #\Z state)
#+(and (not acl2-loop-only) acl2-rewrite-meter)
(setq *rewrite-depth-alist* nil)
; Without the following call, it was impossible to read and write with ACL2 I/O
; functions to *standard-co* in CLISP 2.30. Apparently the appropriate Lisp
; streams at the time of the build were closed when the ACL2 image was brought
; up. So we "refresh" the appropriate property lists with the current such
; Lisp streams.
(setup-standard-io)
; The following applies to CLISP 2.30, where charset:iso-8859-1 is defined, not to
; CLISP 2.27, where charset:utf-8 is not defined. It apparently has to be
; executed in the current Lisp session. We tried executing the following form
; before saving an image, but the value of custom:*default-file-encoding* at
; startup was #<ENCODING CHARSET:ASCII :UNIX>.
#+(and clisp unicode)
(setq custom:*default-file-encoding* charset:iso-8859-1)
#+gcl
; In GCL, at least through Version 2.6.7, there are only 1024 indices n
; available for the #n= reader macro. That is such a small number that for
; GCL, we turn off the use of this reader macro when printing out files such as
; .cert files.
(f-put-global 'print-circle-files nil state)
(let ((customization-full-file-name
(initial-customization-filename)))
(cond
((or (eq customization-full-file-name :none)
(global-val 'boot-strap-flg (w state)))
nil)
(customization-full-file-name
; If the ACL2 customization file exists (and we are not booting) then it hasn't
; been included yet, and we include it now.
(fms "Customizing with ~x0.~%"
(list (cons #\0 customization-full-file-name))
*standard-co*
state
nil)
(let ((old-infixp (f-get-global 'infixp *the-live-state*)))
(f-put-global 'infixp nil *the-live-state*)
(with-suppression ; package locks, not just warnings, for read
(state-free-global-let*
((connected-book-directory
(f-get-global 'connected-book-directory state)))
(ld-fn (put-assoc-eq
'standard-oi
customization-full-file-name
(put-assoc-eq
'ld-error-action :return
(f-get-ld-specials *the-live-state*)))
*the-live-state*
nil)))
(f-put-global 'infixp old-infixp *the-live-state*)))))
(f-put-global 'ld-error-action :continue *the-live-state*)))
(with-suppression ; package locks, not just warnings; to read 'cl::foo
(cond ((and *return-from-lp*
(not *lp-ever-entered-p*))
(f-put-global 'standard-oi
`(,*return-from-lp* (value :q))
*the-live-state*)
(setq *return-from-lp* nil)
(setq *lp-ever-entered-p* t)
(state-free-global-let*
((ld-verbose nil)
(ld-prompt nil)
(ld-post-eval-print nil))
(ld-fn (f-get-ld-specials *the-live-state*)
*the-live-state*
nil)))
(t (setq *lp-ever-entered-p* t)
(f-put-global 'standard-oi *standard-oi* *the-live-state*)
(ld-fn (f-get-ld-specials *the-live-state*)
*the-live-state*
nil)
(fms "Exiting the ACL2 read-eval-print loop. To re-enter, ~
execute (LP)."
nil *standard-co* *the-live-state* nil))))
#+(and acl2-par lispworks)
(spawn-extra-lispworks-listener)
(values))))
(defmacro lp! (&rest args)
`(let ((*features* (add-to-set-eq :acl2-loop-only *features*)))
(lp ,@args)))
; COMPILING, SAVING, AND RESTORING
(defun acl2-compile-file (full-book-name os-expansion-filename)
; Full-book-name is a Unix-style pathname. Os-expansion-filename is a pathname
; for the current operating system of the file we want to compile. We compile
; os-expansion-filename but into the compiled filename corresponding to
; full-book-name.
; To compile os-expansion-filename, we need to make sure that uses in the file
; of backquote and comma conform in meaning to those that were in effect during
; certification.
; We assume that this function is called only after forms in the given
; full-book-name have already been evaluated and (if appropriate) proclaimed,
; hence in particular so that macros have been defined.
(progn
(chk-book-name full-book-name full-book-name 'acl2-compile-file
*the-live-state*)
(let ((*readtable* *acl2-readtable*)
(ofile (convert-book-name-to-compiled-name
(pathname-unix-to-os full-book-name *the-live-state*)
*the-live-state*))
(stream (get (proofs-co *the-live-state*)
*open-output-channel-key*)))
; It is tempting to evaluate (proclaim-file os-expansion-filename). However,
; all functions in full-book-name were presumably already proclaimed, as
; appropriate, during add-trip.
(let ((*readtable* *reckless-acl2-readtable*)
; We reduce the compiled file size produced by CCL, even in the #+hons case
; where we may have set ccl::*save-source-locations* to t. We have seen an
; example where this binding reduced the .dx64fsl size from 13696271 to 24493.
#+ccl (ccl::*save-source-locations* nil))
(compile-file os-expansion-filename :output-file ofile))
; Warning: Keep the following "compile on the fly" readtime conditional in sync
; with the one in initialize-state-globals. Here, we avoid loading the
; compiled file when compiling a certified book, because all functions are
; already compiled. Thus, the code dealing with hons-enabledp below is
; irrelevant as long as under-the-hood hons/memoize code is only used in CCL
; (or SBCL) builds.
#-(or ccl sbcl)
(let ((*compiling-certified-file*
; See the comment about an optimization using *compiling-certified-file* in the
; raw Lisp definition of acl2::defconst.
t)
(alist (and (hons-enabledp *the-live-state*)
(loop for pair in
(table-alist 'memoize-table (w *the-live-state*))
when (fboundp (car pair)) ; always true?
collect (cons (car pair)
(symbol-function (car pair)))))))
(load-compiled ofile t)
(loop for pair in alist ; nil if not hons-enabledp
when (not (eq (symbol-function (car pair))
(cdr pair)))
do (setf (symbol-function (car pair))
(cdr pair)))
(terpri stream)
(prin1 ofile stream))
(terpri stream)
(terpri stream))))
(defun-one-output delete-auxiliary-book-files (full-book-name)
(let* ((file (pathname-unix-to-os full-book-name *the-live-state*))
(ofile (convert-book-name-to-compiled-name file *the-live-state*))
(efile (expansion-filename file nil *the-live-state*))
(err-string "A file created for book ~x0, namely ~x1, exists and ~
cannot be deleted with Common Lisp's delete-file. We ~
do not know for sure whether this file was produced by ~
ACL2 and we do not even know that it corresponds to the ~
book ~x0. If ~x1 exists at the time of an ~
(include-book ~x0), it might be erroneously loaded, ~
possibly causing inconsistency."))
(when (probe-file ofile)
(cond ((delete-file ofile) nil)
(t (er hard 'delete-auxiliary-book-files
err-string
full-book-name ofile))))
#+clisp
(let* ((len (length file))
(lib-file (assert$ (equal (subseq file (- len 5) len) ".lisp")
(concatenate 'string
(subseq file 0 (- len 5))
".lib"))))
(when (probe-file lib-file)
(cond ((delete-file lib-file) nil)
(t (er hard 'delete-auxiliary-book-files
err-string
full-book-name lib-file)))))
(when (probe-file efile)
(cond ((delete-file efile) nil)
(t (er hard 'delete-auxiliary-book-files
err-string
full-book-name efile))))))
(defun delete-expansion-file (expansion-filename state)
(delete-file expansion-filename)
(io? event nil state
(expansion-filename)
(fms "Note: Deleting book expansion file,~%~s0.~|"
(list (cons #\0 expansion-filename))
(proofs-co state) state nil)))
(defun compile-uncompiled-defuns (file &optional (fns :some) gcl-flg
&aux (state *the-live-state*))
; File should be given in Unix-style syntax. Hence for example, "TMP" is
; relative to the current directory, even though on a Macintosh this might
; appear to be an absolute pathname for a file.
; Compile-uncompiled-defuns compiles the non-built-in defuns that are not
; currently compiled if FNS is :some. Otherwise, FNS should be a list of
; functions to compile.
(when (and (not (symbol-listp fns))
(not (eq fns :some)))
(er hard 'compile-uncompiled-defuns
"The argument to compile-uncompiled-defuns must be either a true list ~
of symbols or the keyword :some. The argument ~x0 is thus illegal."
fns))
(cond
((null fns)
(warning$ 'compile-uncompiled-defuns nil
"No functions to compile.")
(return-from compile-uncompiled-defuns file)))
(let ((os-file (pathname-unix-to-os file state)))
(state-global-let*
((print-circle (f-get-global 'print-circle-files state))
(serialize-character (f-get-global 'serialize-character-system state)))
(with-print-controls
:defaults
((*print-circle* (f-get-global 'print-circle state)))
(let ((seen (make-hash-table :test 'eq))
(fns (cond ((eq fns :uncompiled)
:some)
((eq fns t)
:all)
(t fns)))
(fn-file (format nil "~a.lisp" file)))
; (Warning: Do not delete the following comment without considering the pointer
; to it in compile-uncompiled-*1*-defuns.)
; The following use of with-output-object-channel-sharing causes #n= sharing
; notation to be used when printing each defun. The number of such indices (n)
; starts fresh with each definition. This should be OK since each defun will
; presumably be read separately -- quoting the CL HyperSpec, Section "2.4.8.15
; Sharpsign Equal-Sign": ... The scope of the label is the expression being
; read by the outermost call to read; within this expression, the same label
; may not appear twice.
(with-output-object-channel-sharing
chan fn-file
(let ((str0 (get-output-stream-from-channel chan)))
(format str0
"; This file is automatically generated, to be ~
compiled.~%; Feel free to delete it after compilation.~%")
; We print (in-package "...") but we do it this way to guarantee that the
; symbol 'in-package is printed correctly.
(print-object$ (list 'in-package (current-package state))
chan state)
(dolist (trip (w state))
(cond ((and (eq fns :some)
(eq (car trip) 'command-landmark)
(eq (cadr trip) 'global-value)
(equal (access-command-tuple-form (cddr trip))
'(exit-boot-strap-mode)))
(return))
((and (eq (car trip) 'cltl-command)
(eq (cadr trip) 'global-value)
(consp (cddr trip))
(eq (caddr trip) 'defuns)
; The next test asks whether the ignorep field of the defuns tuple is
; '(defstobj . stobj). If it is, this triple didn't actually make
; those definitions.
(not (and (consp (caddr (cddr trip)))
(eq (car (caddr (cddr trip))) 'defstobj))))
(dolist (x (cdddr (cddr trip)))
(cond ((and (not (gethash (car x) seen))
(or (eq fns :some)
(member-eq (car x) fns)))
(setf (gethash (car x) seen) t)
(when (not (compiled-function-p! (car x)))
(cond ((or (member-eq
(car x)
(f-get-global
'program-fns-with-raw-code
state))
(member-eq
(car x)
(f-get-global
'logic-fns-with-raw-code
state)))
(format t
"; (ACL2 Note) Attempting ~
separate compilation due to ~
raw code: ~s~&"
; We ignore errors (if possible), since for example, we have seen LispWorks
; complain when (car x) names a function that is a lexical closure.
(car x))
(our-ignore-errors (compile (car x))))
(t (print-object$ (cons 'defun x)
chan state))))))))
((and (eq (car trip) 'cltl-command)
(eq (cadr trip) 'global-value)
(consp (cddr trip))
(eq (caddr trip) 'defstobj))
(dolist (x (car (cddddr (cddr trip))))
; (cddr trip) is of the form
; (DEFSTOBJ name the-live-name init raw-defs template)
; and x here is one of the raw-defs. Note that since raw Lisp definitions for
; defabsstobj are defmacros, we do not deal with defabsstobj, just as we skip
; the defstobj case when defabbrev is used for raw Lisp definitions, as
; determined by (member-equal *stobj-inline-declare* x) as shown below.
(cond
((and (not (gethash (car x) seen))
(not (member-equal *stobj-inline-declare* x))
(or (eq fns :some)
(member-eq (car x) fns)))
(setf (gethash (car x) seen) t)
(when (not (compiled-function-p! (car x)))
(print-object$ (cons 'defun x)
chan state))))))
((eq (cadr trip) 'redefined)
; This case avoids redefining a macro back to an overritten function in the
; following example provided by Eric Smith.
; (defun foo (x) x)
; :redef!
; (defmacro foo (x) x)
; :comp t
(setf (gethash (car trip) seen) t))))
(newline chan state)
(close-output-channel chan state)))
(when (not (eq fns :some))
(let (missing)
(dolist (fn fns)
(when (not (gethash fn seen))
(push fn missing)))
(when missing
(format t
"~%Warning: The following functions have not been ~
compiled.~% ~s~%Perhaps you have not defined them ~
inside the ACL2 command loop.~%"
missing))))
(cond
(gcl-flg
#+gcl
(compile-file
(our-truename (pathname-unix-to-os fn-file state)
"Note: Calling OUR-TRUENAME from ~
COMPILE-UNCOMPILED-DEFUNS (under gcl-flg and #+gcl).")
:c-file t :h-file t)
#-gcl
(er hard 'compile-uncompiled-defuns
"The gcl-flg argument to compile-uncompiled-defuns is only ~
legal when running under GCL."))
(t
(let ((lisp-file
(our-truename (pathname-unix-to-os fn-file state)
"Note: Calling OUR-TRUENAME from ~
COMPILE-UNCOMPILED-DEFUNS.")))
(compile-file lisp-file)
(when (not (keep-tmp-files state))
(delete-file lisp-file)
#+clisp
(delete-file (concatenate 'string os-file ".lib"))))))
(load-compiled os-file t)
(if (not (keep-tmp-files state))
(delete-file (concatenate 'string os-file "."
*compiled-file-extension*))))
(value nil)))
os-file))
(defun compile-uncompiled-*1*-defuns (file &optional (fns :some) gcl-flg chan0
&aux
(state *the-live-state*)
(wrld (w *the-live-state*)))
; This is similar to compile-uncompiled-defuns, but for *1* functions.
; However, an optional chan0 may be supplied; if non-nil, then it is an open
; output channel of type :object, which is closed by this function.
; File should be given in Unix-style syntax. Hence for example, "TMP" is
; relative to the current directory, even though on a Macintosh this might
; appear to be an absolute pathname for a file.
; If chan0 is not nil, then unlike compile-uncompiled-defuns, we write out all
; relevant *1* function definitions, even those that are currently compiled.
(when (and (not (symbol-listp fns))
(not (eq fns :some)))
(er hard 'compile-uncompiled-*1*-defuns
"The argument to compile-uncompiled-*1*-defuns must be either a true ~
list of symbols or the keyword :some. The argument ~x0 is thus ~
illegal."
fns))
(cond
((and (null fns) (null chan0))
(warning$ 'compile-uncompiled-defuns nil
"No functions to compile.")
(return-from compile-uncompiled-*1*-defuns file)))
(let ((os-file (pathname-unix-to-os file state)))
(state-global-let*
((print-circle (f-get-global 'print-circle-files state))
(serialize-character (f-get-global 'serialize-character-system state)))
(with-print-controls
:defaults
((*print-circle* (f-get-global 'print-circle state)))
(let ((seen (let ((tbl (make-hash-table :test 'eq)))
(when (not (eq fns :some))
(dolist (fn fns)
(setf (gethash fn tbl) :init)))
tbl))
(fns (cond ((eq fns :uncompiled)
:some)
((eq fns t)
:all)
(t fns)))
(fn-file (format nil "~a.lisp" file))
(not-boot-strap-p (null (global-val 'boot-strap-flg wrld))))
; See the comment just above the call of with-output-object-channel-sharing in
; compile-uncompiled-defuns.
(with-output-object-channel-sharing
chan fn-file
(cond
((null chan)
(return-from compile-uncompiled-*1*-defuns
(er hard 'compile-uncompiled-*1*-defuns
"Unable to open file ~x0 for object output."
fn-file)))
(t
(let ((defs nil) ; only used in the case chan0 is not nil
(str0 (get-output-stream-from-channel chan)))
(cond ((null chan0) ; new output file
(format str0
"; This file is automatically generated, to be ~
compiled.~%; Feel free to delete it after ~
compilation.~%")
; We print (in-package "...") but we do it this way to guarantee that the
; symbol 'in-package is printed correctly.
(print-object$ (list 'in-package
(current-package state))
chan state))
(t state))
(dolist (trip wrld)
(cond ((and (eq fns :some)
(eq (car trip) 'command-landmark)
(eq (cadr trip) 'global-value)
(equal (access-command-tuple-form (cddr trip))
'(exit-boot-strap-mode)))
; If we are compiling while building the system, then we will never see
; 'exit-boot-strap-mode, which allows us to explore the entire world. But when
; a user executes (comp t), thus calling this function with argument fns equal
; to :some, the exploration should only consider user-defined events.
(return))
((and (eq (car trip) 'cltl-command)
(eq (cadr trip) 'global-value)
(consp (cddr trip))
(eq (caddr trip) 'defuns))
(dolist
(x (cdddr (cddr trip)))
(when (not (member-eq
(car x)
`(mv-list return-last wormhole-eval
,@*defun-overrides*)))
(let ((*1*fn (*1*-symbol (car x))))
(cond
((and (fboundp *1*fn)
(cond
((eq fns :some)
(and (not (gethash (car x) seen))
; We have seen during development of v2-9 that in Allegro CL, when compiling
; *1* functions on the fly during boot-strap (because of code in add-trip), the
; image size increases from 29.3M to 36.9M if we instead use the following
; code, which avoids writing *1* definitions to TMP1.lisp for compiled :logic
; mode functions at the end of the boot-strap.
; (and (not (compiled-function-p! *1*fn))
; (or not-boot-strap-p
; (not (eq (cadr (cddr trip))
; :program))))
; That is, when we wrote out a TMP1.lisp for all :logic mode functions at the
; end of initialization and compiled it, we saved 7.6M. This result remains a
; mystery, but we prefer the smaller image so we keep the code below. The
; resulting increase in wall-clock build time was only about 3 seconds. See
; also the corresponding comment mentioning compile-uncompiled-*1*-defuns in
; add-trip.
(if not-boot-strap-p
(not (compiled-function-p!
*1*fn))
; We have noticed about a corresponding 0.6% to 1.2% slowdown in the regression
; suite when we avoid compiling :program mode *1* functions for GCL during the
; build and also at the end, when TMP1.lisp is written, as discussed in the
; comment above "boot-strap-flg ; delete for build speed-up (see above)" in
; add-trip. With that mod, we have tried the following additional mod so that
; for GCL we still compile built-in :program mode *1* functions after all, by
; writing out a huge TMP1.lisp file (8.3 MB instead 0.4 MB).
; #+gcl t #-gcl
; But this made things worse. Here are examples for v2-9-1 (on the way to
; v2-9-2):
;
; During the build, compile :program mode functions on the fly (as usual):
; 9763.160u 146.760s 2:51:33.10 96.2% 0+0k 0+0io 13673004pf+0w
;
; During the build, do not compile :program mode functions at all:
; 9827.570u 149.730s 2:52:29.27 96.4% 0+0k 0+0io 14549410pf+0w
;
; During the build, do not compile :program mode functions until the end
; (creating very large TMP1.lisp file):
; 9893.870u 150.240s 2:54:22.62 95.9% 0+0k 0+0io 14528555pf+0w
;
; Moroever, the saved_acl2.gcl file went from 43 MB, for the first two, to 104
; MB for the last. So let's not write :program mode *1* functions to
; TMP1.lisp. See the long comment about *fast-acl2-gcl-build* in add-trip.
(not (eq (cadr (cddr trip))
:program)))
(setf (gethash (car x) seen) t)))
((eq (gethash (car x) seen) :init)
(setf (gethash (car x) seen) t)
(or chan0
(not (compiled-function-p!
*1*fn))))))
(let ((*1*def
(cons 'defun
(oneify-cltl-code
(cadr (cddr trip)) ; defun-mode
x
(getprop (car x)
'stobj-function
nil
'current-acl2-world
wrld)
wrld))))
(cond (chan0 (push *1*def defs))
(t (print-object$ *1*def chan
state))))))))))
((eq (cadr trip) 'redefined)
; This case avoids a hard error message when encountering a macro redefined
; from an earlier defun, in the following example provided by Eric Smith.
; (defun foo (x) x)
; :redef!
; (defmacro foo (x) x)
; :comp t
(setf (gethash (car trip) seen) t))))
(when chan0
; Print all the defs in a single progn, for maximum structure sharing via #n=
; and #n#.
(print-object$ (cons 'progn (nreverse defs)) chan state))
(newline chan state)
(cond (chan0 (return-from compile-uncompiled-*1*-defuns os-file))
(t (close-output-channel chan state))))))
chan0)
(when (not (eq fns :some))
(let (missing)
(dolist (fn fns)
(when (not (eq (gethash fn seen) t))
(push fn missing)))
(when missing
(format t
"~%Warning: The following executable-counterpart ~
functions have not been compiled.~% ~s~%Perhaps you ~
have not defined them inside the ACL2 command loop.~%"
missing))))
(cond
(gcl-flg
#+gcl
(compile-file
(our-truename (pathname-unix-to-os fn-file state)
"Note: Calling OUR-TRUENAME from ~
COMPILE-UNCOMPILED-*1*-DEFUNS (under gcl-flg and ~
#+gcl).")
:c-file t :h-file t)
#-gcl
(er hard 'compile-uncompiled-defuns
"The gcl-flg argument to compile-uncompiled-*1*-defuns is only ~
legal when running under GCL."))
(t
(let ((lisp-file
(our-truename (pathname-unix-to-os fn-file state)
"Note: Calling OUR-TRUENAME from ~
COMPILE-UNCOMPILED-*1*-DEFUNS.")))
(compile-file lisp-file)
(when (not (keep-tmp-files state))
(delete-file lisp-file)
#+clisp
(delete-file (concatenate 'string os-file ".lib"))))))
(load-compiled os-file t)
(if (not (keep-tmp-files state))
(delete-file (concatenate 'string os-file "."
*compiled-file-extension*)))
(value nil))))
os-file))
(defun compile-certified-file (expansion-filename full-book-name state)
; Warning: File full-book-name should already have been included in order that
; macros have been defined. But more than that, expansion-filename must
; already have been written.
(let* ((os-full-book-name (pathname-unix-to-os full-book-name state))
(os-full-book-name-compiled
(convert-book-name-to-compiled-name os-full-book-name state)))
(when (probe-file os-full-book-name-compiled)
(delete-file os-full-book-name-compiled))
(acl2-compile-file full-book-name expansion-filename)
state))
(defun compile-for-include-book (full-book-name certified-p ctx state)
(cond
((not certified-p)
; We warn rather than cause an error, since if one is including an uncertified
; book then one is presumably willing to live with the result. It could be
; annoying if an include-book :load-compiled-file :comp occurs inside another
; book, since one might not want to edit the parent book.
(pprogn (warning$ ctx "Compiled file"
"An include-book form for book ~x0 has specified option ~
:load-compiled-file :comp. But this book is ~
uncertified, so compilation is being skipped."
full-book-name)
(value nil)))
(t
(let* ((efile (expansion-filename full-book-name t state))
(entry (and *hcomp-book-ht*
(gethash full-book-name *hcomp-book-ht*)))
(status (and entry
(access hcomp-book-ht-entry entry :status))))
(cond ((eq status 'complete)
(value nil))
(t
(mv-let
(cfile state)
(certificate-file full-book-name state)
(let* ((cfile (and cfile (pathname-unix-to-os cfile state)))
(cfile-write-date (and cfile
(file-write-date cfile)))
(efile-write-date (and (probe-file efile)
(file-write-date efile)))
(reason (cond ((not (probe-file cfile))
"the certificate file does not exist")
((not (probe-file efile))
"the expansion file does not exist")
((not (eq status 'to-be-compiled))
"the expansion file or compiled file ~
appears not to have been loaded to ~
completion")
((and cfile-write-date
efile-write-date
(<= cfile-write-date efile-write-date))
nil)
(t
"the write-date of the expansion file is ~
not greater than the write date of the ~
certificate file"))))
(cond (reason (er soft ctx
"An include-book event with option ~
:load-compiled-file :comp has failed for ~
book~|~s0,~|because ~@1. See :DOC ~
include-book and see :DOC ~
book-compiled-file."
full-book-name reason))
(t
(observation ctx
"Compiling file ~x0, as specified by ~
include-book option :load-compiled-file ~
:comp."
full-book-name)
(acl2-compile-file full-book-name efile)
(value nil)))))))))))
; MISCELLANEOUS
(defun-one-output enabled-structurep (x)
; This function is basically a hack. We return t if x is probably an
; enable-structure. This is just part of the test of recognizing
; something we don't want to print out when tracing. See below.
; Without something like this, it is just too uncomfortable to trace
; many ACL2 functions because too much output is printed since
; enabled-structures typically take hundreds of lines to print.
; WARNING: Keep this in sync with enabled-structure.
(case-match x
(((index-of-last-enabling . theory-array)
(array-name . array-length)
array-name-root . array-name-suffix)
(and (integerp index-of-last-enabling)
(symbolp array-name)
(array1p array-name theory-array)
(integerp array-length)
(character-listp array-name-root)
(integerp array-name-suffix)))
(& nil)))
(defun-one-output rcnstp (x)
; This is another function in the spirit of enabled-structurep, above.
; WARNING: Keep this in sync with rewrite-constant.
(case-match x
(((current-enabled-structure)
(& & . &)
(& . &)
(& . &)
.
&)
(enabled-structurep current-enabled-structure))
(& nil)))
(defvar *trace-alist*
(list (cons 'state '|*the-live-state*|)))
(defun-one-output assoc-eq-trace-alist (val alist)
(cond
((endp alist) nil)
((and (boundp (caar alist))
(eq val (symbol-value (caar alist))))
(car alist))
(t (assoc-eq-trace-alist val (cdr alist)))))
(defun-one-output print-list-without-stobj-arrays (lst)
(loop for x in lst
collect
(or (and (arrayp x)
(stobj-print-symbol x *user-stobj-alist*))
x)))
(defun-one-output stobj-print-symbol (x user-stobj-alist-tail)
; Finds the (first) name of a pair (name . val) in user-stobj-alist-tail such
; that x is the symbol-value of that name's live var, and returns the symbol to
; print when encountering x during tracing.
(and user-stobj-alist-tail
(let ((pair (car user-stobj-alist-tail)))
(if (eq x (symbol-value (the-live-var (car pair))))
(let ((name (stobj-print-name (car pair))))
(intern-in-package-of-symbol
(cond ((eq x (cdr pair)) name)
(t (concatenate 'string name
"{instance}")))
(car pair)))
(stobj-print-symbol x (cdr user-stobj-alist-tail))))))
(defun-one-output trace-hide-world-and-state (l)
; This function intuitively belongs over in init.lisp but it is here so
; that it will get compiled so we won't get stack overflow when
; tracing large objects. It is used to replace certain offensive
; objects by less offensive ones before trace prints the args and
; results of traced functions. It may not work well with local stobjs.
; In some functions, notably trace-fix-exit-raw and trace-fix-exit for GCL, we
; assume that trace-hide-world-and-state and its subroutines do not call mv.
; If that changes then we should use protect-mv there as we do in some other
; places.
(let* ((stobj-pair (rassoc l *user-stobj-alist*))
(l (cond
(stobj-pair
(intern-in-package-of-symbol
(stobj-print-name (car stobj-pair))
(car stobj-pair)))
(t ; consider local stobjs
(or (and (arrayp l)
(stobj-print-symbol l *user-stobj-alist*))
l))))
(pair (assoc-eq-trace-alist l *trace-alist*)))
(cond (pair (cdr pair))
((atom l) l)
((eq l (w *the-live-state*))
'|current-acl2-world|)
((rcnstp l) '|some-rcnst|)
((enabled-structurep l) '|some-enabled-structure|)
((and (consp l)
(or (eq (car l) 'event-index)
(eq (car l) 'command-index))
(consp (cdr l))
(eq (car (cdr l)) 'global-value))
(list* (car l) 'global-value '|some-index|))
; I have been known to put this in here
; ((and (consp l)
; (consp (car l))
; (symbolp (car (car l)))
; (consp (cdr (car l)))
; (eq (car (cdr (car l))) 'global-value))
; '|some-other-world-perhaps|)
(t (cons (trace-hide-world-and-state (car l))
(trace-hide-world-and-state (cdr l)))))))
; The following would create warnings in MCL 4.2, presumably because this file
; is compiled in that Lisp; so we avoid it for MCL. It was originally in
; acl2-init.lisp, but cmulisp warned that *open-output-channel-key*,
; print-idate, and idate were undefined.
#-(and mcl (not ccl))
(defun-one-output saved-build-date-string ()
(with-output-to-string
(str)
(setf (get 'tmp-channel *open-output-channel-key*)
str)
(print-idate (idate)
'tmp-channel
*the-live-state*)
(remprop 'tmp-channel *open-output-channel-key*)
str))
(defun-one-output get-stobjs-out-for-declare-form (fn)
; Warning: Keep this in sync with stobjs-out.
; This function is used in acl2-fns.lisp.
; Here we essentially open-code stobjs-out, except that we allow for the
; possibility that fn is defined in raw Lisp.
(cond ((eq fn 'cons)
; We call this function on cons so often we optimize it.
'(nil))
((member-eq fn '(if return-last))
(interface-er "Implementation error in ~
get-stobjs-out-for-declare-form: Attempted to find ~
stobjs-out for ~x0."
fn))
(t (let ((w (w *the-live-state*)))
(or (getprop fn 'stobjs-out nil 'current-acl2-world w)
(and (getprop fn 'symbol-class nil 'current-acl2-world w)
'(nil)))))))
; The definition of fix-trace and its subfunction fix-trace-untrace can go
; anywhere, but since they are raw Lisp, we will put them in this file.
(defun fix-trace-untrace (new-trace-specs old-trace-specs)
; Collect functions traced in new-trace-specs that are not traced in
; old-trace-specs.
(cond ((endp new-trace-specs) nil)
((assoc-eq (caar new-trace-specs) old-trace-specs)
(fix-trace-untrace (cdr new-trace-specs) old-trace-specs))
(t
(cons (caar new-trace-specs)
(fix-trace-untrace (cdr new-trace-specs) old-trace-specs)))))
(defun fix-trace (old-trace-specs)
(let* ((new-trace-specs (f-get-global 'trace-specs *the-live-state*))
(to-untrace (fix-trace-untrace new-trace-specs old-trace-specs))
(to-retrace (set-difference-equal old-trace-specs new-trace-specs)))
(when to-untrace
(eval `(untrace$ ,@to-untrace)))
(when to-retrace
(eval `(trace$ ,@to-retrace)))))
; We define acl2-books-revision here rather than in acl2-init.lisp, so that
; f-get-global is already defined.
(defun acl2-books-revision ()
; We define acl2-books-revision here in interface-raw.lisp rather than in
; acl2-init.lisp, so that f-get-global is already defined.
(multiple-value-bind
(exit-code line)
(system-call+
(concatenate
'string
(f-get-global 'acl2-sources-dir *the-live-state*)
"bin/svn-info-books")
(list (f-get-global 'system-books-dir *the-live-state*)))
(cond ((or (not (eql exit-code 0))
(equal line ""))
"????")
(t (svn-revision-from-line line)))))
|