(UNSET-WATERFALL-PARALLELISM)
(ASSIGN SCRIPT-MODE T)
 T
(SET-LD-PROMPT T STATE)
 T
ACL2 !>>(SET-INHIBITED-SUMMARY-TYPES '(TIME STEPS))
 (TIME STEPS)
ACL2 !>>(SET-INHIBIT-OUTPUT-LST '(PROOF-TREE))
 (PROOF-TREE)
ACL2 !>>(SET-GUARD-CHECKING NIL)

Masking guard violations but still checking guards except for self-
recursive calls.  To avoid guard checking entirely, :SET-GUARD-CHECKING
:NONE.  See :DOC set-guard-checking.

ACL2 >>(SET-GAG-MODE NIL)
<state>
ACL2 >>(INCLUDE-BOOK "m1")

Summary
Form:  ( INCLUDE-BOOK "m1" ...)
Rules: NIL
 (:SYSTEM . "demos/marktoberdorf-08/m1.lisp")
ACL2 >>(INCLUDE-BOOK "compile")

Summary
Form:  ( INCLUDE-BOOK "compile" ...)
Rules: NIL
 (:SYSTEM . "demos/marktoberdorf-08/compile.lisp")
ACL2 >>(IN-PACKAGE "M1")
 "M1"
M1 >>(DEFUN F (N)
       (IF (ZP N) 1 (* N (F (- N 1)))))

The admission of F is trivial, using the relation O< (which is known
to be well-founded on the domain recognized by O-P) and the measure
(ACL2-COUNT N).  We observe that the type of F is described by the
theorem (AND (INTEGERP (F N)) (< 0 (F N))).  We used the :compound-
recognizer rule ACL2::ZP-COMPOUND-RECOGNIZER and primitive type reasoning.

Summary
Form:  ( DEFUN F ...)
Rules: ((:COMPOUND-RECOGNIZER ACL2::ZP-COMPOUND-RECOGNIZER)
        (:FAKE-RUNE-FOR-TYPE-SET NIL))
 F
M1 >>(DEFUN G (N A)
       (IF (ZP N) A (G (- N 1) (* N A))))

The admission of G is trivial, using the relation O< (which is known
to be well-founded on the domain recognized by O-P) and the measure
(ACL2-COUNT N).  We observe that the type of G is described by the
theorem (OR (ACL2-NUMBERP (G N A)) (EQUAL (G N A) A)).  We used primitive
type reasoning.

Summary
Form:  ( DEFUN G ...)
Rules: ((:FAKE-RUNE-FOR-TYPE-SET NIL))
 G
M1 >>(DEFCONST *G*
       '((PUSH 1)
         (STORE 1)
         (LOAD 0)
         (IFLE 10)
         (LOAD 0)
         (LOAD 1)
         (MUL)
         (STORE 1)
         (LOAD 0)
         (PUSH 1)
         (SUB)
         (STORE 0)
         (GOTO -10)
         (LOAD 1)
         (RETURN)))

Summary
Form:  ( DEFCONST *G* ...)
Rules: NIL
 *G*
M1 >>(DEFUN G-SCHED-LOOP (N)
       (IF (ZP N)
           (REPEAT 0 4)
         (APPEND (REPEAT 0 11)
                 (G-SCHED-LOOP (- N 1)))))

The admission of G-SCHED-LOOP is trivial, using the relation O< (which
is known to be well-founded on the domain recognized by O-P) and the
measure (ACL2-COUNT N).  We observe that the type of G-SCHED-LOOP is
described by the theorem (TRUE-LISTP (G-SCHED-LOOP N)).  We used the
:type-prescription rules BINARY-APPEND, REPEAT and ACL2::TRUE-LISTP-APPEND.

Summary
Form:  ( DEFUN G-SCHED-LOOP ...)
Rules: ((:TYPE-PRESCRIPTION BINARY-APPEND)
        (:TYPE-PRESCRIPTION REPEAT)
        (:TYPE-PRESCRIPTION ACL2::TRUE-LISTP-APPEND))
 G-SCHED-LOOP
M1 >>(DEFUN G-SCHED (N)
       (APPEND (REPEAT 0 2) (G-SCHED-LOOP N)))

Since G-SCHED is non-recursive, its admission is trivial.  We observe
that the type of G-SCHED is described by the theorem 
(TRUE-LISTP (G-SCHED N)).  We used the :type-prescription rules G-SCHED-LOOP
and ACL2::TRUE-LISTP-APPEND.

Summary
Form:  ( DEFUN G-SCHED ...)
Rules: ((:TYPE-PRESCRIPTION G-SCHED-LOOP)
        (:TYPE-PRESCRIPTION ACL2::TRUE-LISTP-APPEND))
 G-SCHED
M1 >>'(END OF SETUP)
(END OF SETUP)
M1 >>(THM (EQUAL (RUN (REPEAT 0 9)
                      (MAKE-STATE 4 (LIST N A) STK *G*))
                 ???))

By the :executable-counterpart of REPEAT and the simple :rewrite rule
RUN-OPENER we reduce the conjecture to

Goal'
(EQUAL
 (STEP
  (STEP
   (STEP
        (STEP (STEP (STEP (STEP (STEP (STEP (MAKE-STATE 4 (LIST N A)
                                                        STK
                                                        '((PUSH 1)
                                                          (STORE 1)
                                                          (LOAD 0)
                                                          (IFLE 10)
                                                          (LOAD 0)
                                                          (LOAD 1)
                                                          (MUL)
                                                          (STORE 1)
                                                          (LOAD 0)
                                                          (PUSH 1)
                                                          (SUB)
                                                          (STORE 0)
                                                          (GOTO -10)
                                                          (LOAD 1)
                                                          (RETURN))))))))))))
 ???).

This simplifies, using the :compound-recognizer rule 
ACL2::NATP-COMPOUND-RECOGNIZER, the :definitions DO-INST, EXECUTE-GOTO,
EXECUTE-LOAD, EXECUTE-MUL, EXECUTE-PUSH, EXECUTE-STORE, EXECUTE-SUB,
NEXT-INST and UPDATE-NTH, the :executable-counterparts of ARG1, BINARY-+,
CONSP, EQUAL, NTH, OPCODE, UNARY-- and ZP and the :rewrite rules CAR-CONS,
CDR-CONS, COMMUTATIVITY-OF-*, COMMUTATIVITY-OF-+, NTH-0-CONS, NTH-ADD1!,
STACKS, STATES, STEP-OPENER and UPDATE-NTH-ADD1!, to

Goal''
(EQUAL (MAKE-STATE 2 (LIST (+ -1 N) (* A N))
                   STK
                   '((PUSH 1)
                     (STORE 1)
                     (LOAD 0)
                     (IFLE 10)
                     (LOAD 0)
                     (LOAD 1)
                     (MUL)
                     (STORE 1)
                     (LOAD 0)
                     (PUSH 1)
                     (SUB)
                     (STORE 0)
                     (GOTO -10)
                     (LOAD 1)
                     (RETURN)))
       ???).

Name the formula above *1.

No induction schemes are suggested by *1.  Consequently, the proof
attempt has failed.

Summary
Form:  ( THM ...)
Rules: ((:COMPOUND-RECOGNIZER ACL2::NATP-COMPOUND-RECOGNIZER)
        (:DEFINITION DO-INST)
        (:DEFINITION EXECUTE-GOTO)
        (:DEFINITION EXECUTE-LOAD)
        (:DEFINITION EXECUTE-MUL)
        (:DEFINITION EXECUTE-PUSH)
        (:DEFINITION EXECUTE-STORE)
        (:DEFINITION EXECUTE-SUB)
        (:DEFINITION NEXT-INST)
        (:DEFINITION UPDATE-NTH)
        (:EXECUTABLE-COUNTERPART ARG1)
        (:EXECUTABLE-COUNTERPART BINARY-+)
        (:EXECUTABLE-COUNTERPART CONSP)
        (:EXECUTABLE-COUNTERPART EQUAL)
        (:EXECUTABLE-COUNTERPART NTH)
        (:EXECUTABLE-COUNTERPART OPCODE)
        (:EXECUTABLE-COUNTERPART REPEAT)
        (:EXECUTABLE-COUNTERPART UNARY--)
        (:EXECUTABLE-COUNTERPART ZP)
        (:REWRITE CAR-CONS)
        (:REWRITE CDR-CONS)
        (:REWRITE COMMUTATIVITY-OF-*)
        (:REWRITE COMMUTATIVITY-OF-+)
        (:REWRITE NTH-0-CONS)
        (:REWRITE NTH-ADD1!)
        (:REWRITE RUN-OPENER)
        (:REWRITE STACKS)
        (:REWRITE STATES)
        (:REWRITE STEP-OPENER)
        (:REWRITE UPDATE-NTH-ADD1!))

---
The key checkpoint goal, below, may help you to debug this failure.
See :DOC failure and see :DOC set-checkpoint-summary-limit.
---

*** Key checkpoint at the top level: ***

Goal''
(EQUAL (MAKE-STATE 2 (LIST (+ -1 N) (* A N))
                   STK
                   '((PUSH 1)
                     (STORE 1)
                     (LOAD 0)
                     (IFLE 10)
                     (LOAD 0)
                     (LOAD 1)
                     (MUL)
                     (STORE 1)
                     (LOAD 0)
                     (PUSH 1)
                     (SUB)
                     (STORE 0)
                     (GOTO -10)
                     (LOAD 1)
                     (RETURN)))
       ???)

ACL2 Error [Failure] in ( THM ...):  See :DOC failure.

******** FAILED ********
M1 >>'(END OF DEMO 1)
(END OF DEMO 1)
M1 >>(THM (EQUAL (RUN (APPEND A B) S)
                 (RUN B (RUN A S)))
          :HINTS (("Goal" :IN-THEORY (DISABLE RUN-APPEND))))

[Note:  A hint was supplied for the goal above.  Thanks!]

Name the formula above *1.

Perhaps we can prove *1 by induction.  Three induction schemes are
suggested by this conjecture.  These merge into two derived induction
schemes.  However, one of these is flawed and so we are left with one
viable candidate.  

We will induct according to a scheme suggested by (RUN A S), but modified
to accommodate (APPEND A B).

These suggestions were produced using the :induction rules BINARY-APPEND
and RUN.  If we let (:P A B S) denote *1 above then the induction scheme
we'll use is
(AND (IMPLIES (AND (NOT (ENDP A))
                   (:P (CDR A) B (STEP S)))
              (:P A B S))
     (IMPLIES (ENDP A) (:P A B S))).
This induction is justified by the same argument used to admit RUN.
Note, however, that the unmeasured variable S is being instantiated.
When applied to the goal at hand the above induction scheme produces
two nontautological subgoals.

Subgoal *1/2
(IMPLIES (AND (NOT (ENDP A))
              (EQUAL (RUN (APPEND (CDR A) B) (STEP S))
                     (RUN B (RUN (CDR A) (STEP S)))))
         (EQUAL (RUN (APPEND A B) S)
                (RUN B (RUN A S)))).

By the simple :definition ENDP we reduce the conjecture to

Subgoal *1/2'
(IMPLIES (AND (CONSP A)
              (EQUAL (RUN (APPEND (CDR A) B) (STEP S))
                     (RUN B (RUN (CDR A) (STEP S)))))
         (EQUAL (RUN (APPEND A B) S)
                (RUN B (RUN A S)))).

But simplification reduces this to T, using the :definitions BINARY-APPEND
and RUN, primitive type reasoning and the :rewrite rule RUN-OPENER.

Subgoal *1/1
(IMPLIES (ENDP A)
         (EQUAL (RUN (APPEND A B) S)
                (RUN B (RUN A S)))).

By the simple :definition ENDP we reduce the conjecture to

Subgoal *1/1'
(IMPLIES (NOT (CONSP A))
         (EQUAL (RUN (APPEND A B) S)
                (RUN B (RUN A S)))).

But simplification reduces this to T, using the :definitions BINARY-APPEND
and RUN and primitive type reasoning.

That completes the proof of *1.

Q.E.D.

Summary
Form:  ( THM ...)
Rules: ((:DEFINITION BINARY-APPEND)
        (:DEFINITION ENDP)
        (:DEFINITION NOT)
        (:DEFINITION RUN)
        (:FAKE-RUNE-FOR-TYPE-SET NIL)
        (:INDUCTION BINARY-APPEND)
        (:INDUCTION RUN)
        (:REWRITE RUN-OPENER))

Proof succeeded.
M1 >>'(END OF DEMO 2)
(END OF DEMO 2)
M1 >>(DEFTHM STEP-1-[LOOP]
       (IMPLIES (AND (NATP N) (NATP A))
                (EQUAL (RUN (G-SCHED-LOOP N)
                            (MAKE-STATE 2 (LIST N A) STK *G*))
                       (MAKE-STATE 14 (LIST 0 (G N A))
                                   (PUSH (G N A) STK)
                                   *G*))))

Name the formula above *1.

Perhaps we can prove *1 by induction.  Three induction schemes are
suggested by this conjecture.  Subsumption reduces that number to one.

We will induct according to a scheme suggested by (G N A).

This suggestion was produced using the :induction rules G and G-SCHED-LOOP.
If we let (:P A N STK) denote *1 above then the induction scheme we'll
use is
(AND (IMPLIES (AND (NOT (ZP N))
                   (:P (* N A) (+ -1 N) STK))
              (:P A N STK))
     (IMPLIES (ZP N) (:P A N STK))).
This induction is justified by the same argument used to admit G. 
Note, however, that the unmeasured variable A is being instantiated.
When applied to the goal at hand the above induction scheme produces
four nontautological subgoals.

Subgoal *1/4
(IMPLIES (AND (NOT (ZP N))
              (EQUAL (RUN (G-SCHED-LOOP (+ -1 N))
                          (MAKE-STATE 2 (LIST (+ -1 N) (* N A))
                                      STK
                                      '((PUSH 1)
                                        (STORE 1)
                                        (LOAD 0)
                                        (IFLE 10)
                                        (LOAD 0)
                                        (LOAD 1)
                                        (MUL)
                                        (STORE 1)
                                        (LOAD 0)
                                        (PUSH 1)
                                        (SUB)
                                        (STORE 0)
                                        (GOTO -10)
                                        (LOAD 1)
                                        (RETURN))))
                     (MAKE-STATE 14 (LIST 0 (G (+ -1 N) (* N A)))
                                 (PUSH (G (+ -1 N) (* N A)) STK)
                                 '((PUSH 1)
                                   (STORE 1)
                                   (LOAD 0)
                                   (IFLE 10)
                                   (LOAD 0)
                                   (LOAD 1)
                                   (MUL)
                                   (STORE 1)
                                   (LOAD 0)
                                   (PUSH 1)
                                   (SUB)
                                   (STORE 0)
                                   (GOTO -10)
                                   (LOAD 1)
                                   (RETURN))))
              (NATP N)
              (NATP A))
         (EQUAL (RUN (G-SCHED-LOOP N)
                     (MAKE-STATE 2 (LIST N A)
                                 STK
                                 '((PUSH 1)
                                   (STORE 1)
                                   (LOAD 0)
                                   (IFLE 10)
                                   (LOAD 0)
                                   (LOAD 1)
                                   (MUL)
                                   (STORE 1)
                                   (LOAD 0)
                                   (PUSH 1)
                                   (SUB)
                                   (STORE 0)
                                   (GOTO -10)
                                   (LOAD 1)
                                   (RETURN))))
                (MAKE-STATE 14 (LIST 0 (G N A))
                            (PUSH (G N A) STK)
                            '((PUSH 1)
                              (STORE 1)
                              (LOAD 0)
                              (IFLE 10)
                              (LOAD 0)
                              (LOAD 1)
                              (MUL)
                              (STORE 1)
                              (LOAD 0)
                              (PUSH 1)
                              (SUB)
                              (STORE 0)
                              (GOTO -10)
                              (LOAD 1)
                              (RETURN))))).

But simplification reduces this to T, using the :compound-recognizer
rules ACL2::NATP-COMPOUND-RECOGNIZER and ACL2::ZP-COMPOUND-RECOGNIZER,
the :definitions BINARY-APPEND, DO-INST, EXECUTE-GOTO, EXECUTE-IFLE,
EXECUTE-LOAD, EXECUTE-MUL, EXECUTE-PUSH, EXECUTE-STORE, EXECUTE-SUB,
G, G-SCHED-LOOP, NEXT-INST and UPDATE-NTH, the :executable-counterparts
of ARG1, BINARY-+, CAR, CDR, CONSP, EQUAL, NTH, OPCODE, REPEAT, UNARY--
and ZP, primitive type reasoning and the :rewrite rules CAR-CONS, CDR-CONS,
COMMUTATIVITY-OF-*, COMMUTATIVITY-OF-+, NTH-0-CONS, NTH-ADD1!, RUN-OPENER,
STACKS, STATES, STEP-OPENER and UPDATE-NTH-ADD1!.

Subgoal *1/3
(IMPLIES (AND (NOT (ZP N))
              (NOT (NATP (* N A)))
              (NATP N)
              (NATP A))
         (EQUAL (RUN (G-SCHED-LOOP N)
                     (MAKE-STATE 2 (LIST N A)
                                 STK
                                 '((PUSH 1)
                                   (STORE 1)
                                   (LOAD 0)
                                   (IFLE 10)
                                   (LOAD 0)
                                   (LOAD 1)
                                   (MUL)
                                   (STORE 1)
                                   (LOAD 0)
                                   (PUSH 1)
                                   (SUB)
                                   (STORE 0)
                                   (GOTO -10)
                                   (LOAD 1)
                                   (RETURN))))
                (MAKE-STATE 14 (LIST 0 (G N A))
                            (PUSH (G N A) STK)
                            '((PUSH 1)
                              (STORE 1)
                              (LOAD 0)
                              (IFLE 10)
                              (LOAD 0)
                              (LOAD 1)
                              (MUL)
                              (STORE 1)
                              (LOAD 0)
                              (PUSH 1)
                              (SUB)
                              (STORE 0)
                              (GOTO -10)
                              (LOAD 1)
                              (RETURN))))).

But we reduce the conjecture to T, by the :compound-recognizer rules
ACL2::NATP-COMPOUND-RECOGNIZER and ACL2::ZP-COMPOUND-RECOGNIZER and
primitive type reasoning.

Subgoal *1/2
(IMPLIES (AND (NOT (ZP N))
              (NOT (NATP (+ -1 N)))
              (NATP N)
              (NATP A))
         (EQUAL (RUN (G-SCHED-LOOP N)
                     (MAKE-STATE 2 (LIST N A)
                                 STK
                                 '((PUSH 1)
                                   (STORE 1)
                                   (LOAD 0)
                                   (IFLE 10)
                                   (LOAD 0)
                                   (LOAD 1)
                                   (MUL)
                                   (STORE 1)
                                   (LOAD 0)
                                   (PUSH 1)
                                   (SUB)
                                   (STORE 0)
                                   (GOTO -10)
                                   (LOAD 1)
                                   (RETURN))))
                (MAKE-STATE 14 (LIST 0 (G N A))
                            (PUSH (G N A) STK)
                            '((PUSH 1)
                              (STORE 1)
                              (LOAD 0)
                              (IFLE 10)
                              (LOAD 0)
                              (LOAD 1)
                              (MUL)
                              (STORE 1)
                              (LOAD 0)
                              (PUSH 1)
                              (SUB)
                              (STORE 0)
                              (GOTO -10)
                              (LOAD 1)
                              (RETURN))))).

But we reduce the conjecture to T, by the :compound-recognizer rules
ACL2::NATP-COMPOUND-RECOGNIZER and ACL2::ZP-COMPOUND-RECOGNIZER and
primitive type reasoning.

Subgoal *1/1
(IMPLIES (AND (ZP N) (NATP N) (NATP A))
         (EQUAL (RUN (G-SCHED-LOOP N)
                     (MAKE-STATE 2 (LIST N A)
                                 STK
                                 '((PUSH 1)
                                   (STORE 1)
                                   (LOAD 0)
                                   (IFLE 10)
                                   (LOAD 0)
                                   (LOAD 1)
                                   (MUL)
                                   (STORE 1)
                                   (LOAD 0)
                                   (PUSH 1)
                                   (SUB)
                                   (STORE 0)
                                   (GOTO -10)
                                   (LOAD 1)
                                   (RETURN))))
                (MAKE-STATE 14 (LIST 0 (G N A))
                            (PUSH (G N A) STK)
                            '((PUSH 1)
                              (STORE 1)
                              (LOAD 0)
                              (IFLE 10)
                              (LOAD 0)
                              (LOAD 1)
                              (MUL)
                              (STORE 1)
                              (LOAD 0)
                              (PUSH 1)
                              (SUB)
                              (STORE 0)
                              (GOTO -10)
                              (LOAD 1)
                              (RETURN))))).

This simplifies, using the :compound-recognizer rules 
ACL2::NATP-COMPOUND-RECOGNIZER and ACL2::ZP-COMPOUND-RECOGNIZER, the
:executable-counterparts of G-SCHED-LOOP, NATP, NOT and ZP, equality
generation from inequalities and the :forward-chaining rule ACL2::NATP-FC-1,
to

Subgoal *1/1'
(IMPLIES (NATP A)
         (EQUAL (RUN '(0 0 0 0)
                     (MAKE-STATE 2 (LIST 0 A)
                                 STK
                                 '((PUSH 1)
                                   (STORE 1)
                                   (LOAD 0)
                                   (IFLE 10)
                                   (LOAD 0)
                                   (LOAD 1)
                                   (MUL)
                                   (STORE 1)
                                   (LOAD 0)
                                   (PUSH 1)
                                   (SUB)
                                   (STORE 0)
                                   (GOTO -10)
                                   (LOAD 1)
                                   (RETURN))))
                (MAKE-STATE 14 (LIST 0 (G 0 A))
                            (PUSH (G 0 A) STK)
                            '((PUSH 1)
                              (STORE 1)
                              (LOAD 0)
                              (IFLE 10)
                              (LOAD 0)
                              (LOAD 1)
                              (MUL)
                              (STORE 1)
                              (LOAD 0)
                              (PUSH 1)
                              (SUB)
                              (STORE 0)
                              (GOTO -10)
                              (LOAD 1)
                              (RETURN))))).

By the simple :rewrite rule RUN-OPENER we reduce the conjecture to

Subgoal *1/1''
(IMPLIES (NATP A)
         (EQUAL (STEP (STEP (STEP (STEP (MAKE-STATE 2 (LIST 0 A)
                                                    STK
                                                    '((PUSH 1)
                                                      (STORE 1)
                                                      (LOAD 0)
                                                      (IFLE 10)
                                                      (LOAD 0)
                                                      (LOAD 1)
                                                      (MUL)
                                                      (STORE 1)
                                                      (LOAD 0)
                                                      (PUSH 1)
                                                      (SUB)
                                                      (STORE 0)
                                                      (GOTO -10)
                                                      (LOAD 1)
                                                      (RETURN)))))))
                (MAKE-STATE 14 (LIST 0 (G 0 A))
                            (PUSH (G 0 A) STK)
                            '((PUSH 1)
                              (STORE 1)
                              (LOAD 0)
                              (IFLE 10)
                              (LOAD 0)
                              (LOAD 1)
                              (MUL)
                              (STORE 1)
                              (LOAD 0)
                              (PUSH 1)
                              (SUB)
                              (STORE 0)
                              (GOTO -10)
                              (LOAD 1)
                              (RETURN))))).

But simplification reduces this to T, using the :compound-recognizer
rule ACL2::NATP-COMPOUND-RECOGNIZER, the :definitions DO-INST, EXECUTE-IFLE,
EXECUTE-LOAD, G and NEXT-INST, the :executable-counterparts of <, ARG1,
BINARY-+, CONSP, EQUAL, NTH, OPCODE and ZP, primitive type reasoning
and the :rewrite rules CDR-CONS, NTH-0-CONS, NTH-ADD1!, STACKS, STATES
and STEP-OPENER.

That completes the proof of *1.

Q.E.D.

Summary
Form:  ( DEFTHM STEP-1-[LOOP] ...)
Rules: ((:COMPOUND-RECOGNIZER ACL2::NATP-COMPOUND-RECOGNIZER)
        (:COMPOUND-RECOGNIZER ACL2::ZP-COMPOUND-RECOGNIZER)
        (:DEFINITION BINARY-APPEND)
        (:DEFINITION DO-INST)
        (:DEFINITION EXECUTE-GOTO)
        (:DEFINITION EXECUTE-IFLE)
        (:DEFINITION EXECUTE-LOAD)
        (:DEFINITION EXECUTE-MUL)
        (:DEFINITION EXECUTE-PUSH)
        (:DEFINITION EXECUTE-STORE)
        (:DEFINITION EXECUTE-SUB)
        (:DEFINITION G)
        (:DEFINITION G-SCHED-LOOP)
        (:DEFINITION NEXT-INST)
        (:DEFINITION NOT)
        (:DEFINITION UPDATE-NTH)
        (:EXECUTABLE-COUNTERPART <)
        (:EXECUTABLE-COUNTERPART ARG1)
        (:EXECUTABLE-COUNTERPART BINARY-+)
        (:EXECUTABLE-COUNTERPART CAR)
        (:EXECUTABLE-COUNTERPART CDR)
        (:EXECUTABLE-COUNTERPART CONSP)
        (:EXECUTABLE-COUNTERPART EQUAL)
        (:EXECUTABLE-COUNTERPART G-SCHED-LOOP)
        (:EXECUTABLE-COUNTERPART NATP)
        (:EXECUTABLE-COUNTERPART NOT)
        (:EXECUTABLE-COUNTERPART NTH)
        (:EXECUTABLE-COUNTERPART OPCODE)
        (:EXECUTABLE-COUNTERPART REPEAT)
        (:EXECUTABLE-COUNTERPART UNARY--)
        (:EXECUTABLE-COUNTERPART ZP)
        (:FAKE-RUNE-FOR-LINEAR-EQUALITIES NIL)
        (:FAKE-RUNE-FOR-TYPE-SET NIL)
        (:FORWARD-CHAINING ACL2::NATP-FC-1)
        (:INDUCTION G)
        (:INDUCTION G-SCHED-LOOP)
        (:REWRITE CAR-CONS)
        (:REWRITE CDR-CONS)
        (:REWRITE COMMUTATIVITY-OF-*)
        (:REWRITE COMMUTATIVITY-OF-+)
        (:REWRITE NTH-0-CONS)
        (:REWRITE NTH-ADD1!)
        (:REWRITE RUN-OPENER)
        (:REWRITE STACKS)
        (:REWRITE STATES)
        (:REWRITE STEP-OPENER)
        (:REWRITE UPDATE-NTH-ADD1!))
 STEP-1-[LOOP]
M1 >>'(END OF DEMO 3)
(END OF DEMO 3)
M1 >>(DEFTHM STEP-1
       (IMPLIES (NATP N)
                (EQUAL (RUN (G-SCHED N)
                            (MAKE-STATE 0 (LIST N A) STK *G*))
                       (MAKE-STATE 14 (LIST 0 (G N 1))
                                   (PUSH (G N 1) STK)
                                   *G*))))

ACL2 Warning [Non-rec] in ( DEFTHM STEP-1 ...):  A :REWRITE rule generated
from STEP-1 will be triggered only by terms containing the function
symbol G-SCHED, which has a non-recursive definition.  Unless this
definition is disabled, this rule is unlikely ever to be used.


By the simple :definition G-SCHED, the :executable-counterpart of REPEAT
and the simple :rewrite rules RUN-APPEND and RUN-OPENER we reduce the
conjecture to

Goal'
(IMPLIES (NATP N)
         (EQUAL (RUN (G-SCHED-LOOP N)
                     (STEP (STEP (MAKE-STATE 0 (LIST N A)
                                             STK
                                             '((PUSH 1)
                                               (STORE 1)
                                               (LOAD 0)
                                               (IFLE 10)
                                               (LOAD 0)
                                               (LOAD 1)
                                               (MUL)
                                               (STORE 1)
                                               (LOAD 0)
                                               (PUSH 1)
                                               (SUB)
                                               (STORE 0)
                                               (GOTO -10)
                                               (LOAD 1)
                                               (RETURN))))))
                (MAKE-STATE 14 (LIST 0 (G N 1))
                            (PUSH (G N 1) STK)
                            '((PUSH 1)
                              (STORE 1)
                              (LOAD 0)
                              (IFLE 10)
                              (LOAD 0)
                              (LOAD 1)
                              (MUL)
                              (STORE 1)
                              (LOAD 0)
                              (PUSH 1)
                              (SUB)
                              (STORE 0)
                              (GOTO -10)
                              (LOAD 1)
                              (RETURN))))).

But simplification reduces this to T, using the :compound-recognizer
rule ACL2::NATP-COMPOUND-RECOGNIZER, the :definitions DO-INST, EXECUTE-PUSH,
EXECUTE-STORE, NEXT-INST and UPDATE-NTH, the :executable-counterparts
of ARG1, BINARY-+, CONS, CONSP, EQUAL, NTH, OPCODE and ZP, primitive
type reasoning and the :rewrite rules CAR-CONS, CDR-CONS, STACKS, STATES,
STEP-1-[LOOP], STEP-OPENER and UPDATE-NTH-ADD1!.

Q.E.D.

Summary
Form:  ( DEFTHM STEP-1 ...)
Rules: ((:COMPOUND-RECOGNIZER ACL2::NATP-COMPOUND-RECOGNIZER)
        (:DEFINITION DO-INST)
        (:DEFINITION EXECUTE-PUSH)
        (:DEFINITION EXECUTE-STORE)
        (:DEFINITION G-SCHED)
        (:DEFINITION NEXT-INST)
        (:DEFINITION UPDATE-NTH)
        (:EXECUTABLE-COUNTERPART ARG1)
        (:EXECUTABLE-COUNTERPART BINARY-+)
        (:EXECUTABLE-COUNTERPART CONS)
        (:EXECUTABLE-COUNTERPART CONSP)
        (:EXECUTABLE-COUNTERPART EQUAL)
        (:EXECUTABLE-COUNTERPART NTH)
        (:EXECUTABLE-COUNTERPART OPCODE)
        (:EXECUTABLE-COUNTERPART REPEAT)
        (:EXECUTABLE-COUNTERPART ZP)
        (:FAKE-RUNE-FOR-TYPE-SET NIL)
        (:REWRITE CAR-CONS)
        (:REWRITE CDR-CONS)
        (:REWRITE RUN-APPEND)
        (:REWRITE RUN-OPENER)
        (:REWRITE STACKS)
        (:REWRITE STATES)
        (:REWRITE STEP-1-[LOOP])
        (:REWRITE STEP-OPENER)
        (:REWRITE UPDATE-NTH-ADD1!))
Warnings:  Non-rec
 STEP-1
M1 >>(IN-THEORY (DISABLE G-SCHED))

Summary
Form:  ( IN-THEORY (DISABLE ...))
Rules: NIL
 :CURRENT-THEORY-UPDATED
M1 >>'(END OF DEMO 4)
(END OF DEMO 4)
M1 >>(DEFTHM STEP-2
       (IMPLIES (NATP A)
                (EQUAL (G N A) (* A (F N)))))

Name the formula above *1.

Perhaps we can prove *1 by induction.  Two induction schemes are suggested
by this conjecture.  Subsumption reduces that number to one.  

We will induct according to a scheme suggested by (G N A).

This suggestion was produced using the :induction rules F and G.  If
we let (:P A N) denote *1 above then the induction scheme we'll use
is
(AND (IMPLIES (AND (NOT (ZP N)) (:P (* N A) (+ -1 N)))
              (:P A N))
     (IMPLIES (ZP N) (:P A N))).
This induction is justified by the same argument used to admit G. 
Note, however, that the unmeasured variable A is being instantiated.
When applied to the goal at hand the above induction scheme produces
three nontautological subgoals.

Subgoal *1/3
(IMPLIES (AND (NOT (ZP N))
              (EQUAL (G (+ -1 N) (* N A))
                     (* (* N A) (F (+ -1 N))))
              (NATP A))
         (EQUAL (G N A) (* A (F N)))).

By the simple :rewrite rule ASSOCIATIVITY-OF-* we reduce the conjecture
to

Subgoal *1/3'
(IMPLIES (AND (NOT (ZP N))
              (EQUAL (G (+ -1 N) (* N A))
                     (* N A (F (+ -1 N))))
              (NATP A))
         (EQUAL (G N A) (* A (F N)))).

But simplification reduces this to T, using the :compound-recognizer
rule ACL2::ZP-COMPOUND-RECOGNIZER, the :definitions F and G, primitive
type reasoning and the :rewrite rule ACL2::COMMUTATIVITY-2-OF-*.

Subgoal *1/2
(IMPLIES (AND (NOT (ZP N))
              (NOT (NATP (* N A)))
              (NATP A))
         (EQUAL (G N A) (* A (F N)))).

But we reduce the conjecture to T, by the :compound-recognizer rules
ACL2::NATP-COMPOUND-RECOGNIZER and ACL2::ZP-COMPOUND-RECOGNIZER and
primitive type reasoning.

Subgoal *1/1
(IMPLIES (AND (ZP N) (NATP A))
         (EQUAL (G N A) (* A (F N)))).

But simplification reduces this to T, using the :compound-recognizer
rules ACL2::NATP-COMPOUND-RECOGNIZER and ACL2::ZP-COMPOUND-RECOGNIZER,
the :definitions F, FIX and G, primitive type reasoning and the :rewrite
rules COMMUTATIVITY-OF-* and UNICITY-OF-1.

That completes the proof of *1.

Q.E.D.

Summary
Form:  ( DEFTHM STEP-2 ...)
Rules: ((:COMPOUND-RECOGNIZER ACL2::NATP-COMPOUND-RECOGNIZER)
        (:COMPOUND-RECOGNIZER ACL2::ZP-COMPOUND-RECOGNIZER)
        (:DEFINITION F)
        (:DEFINITION FIX)
        (:DEFINITION G)
        (:DEFINITION NOT)
        (:FAKE-RUNE-FOR-TYPE-SET NIL)
        (:INDUCTION F)
        (:INDUCTION G)
        (:REWRITE ASSOCIATIVITY-OF-*)
        (:REWRITE ACL2::COMMUTATIVITY-2-OF-*)
        (:REWRITE COMMUTATIVITY-OF-*)
        (:REWRITE UNICITY-OF-1))
 STEP-2
M1 >>(DEFTHM MAIN
       (IMPLIES (NATP N)
                (EQUAL (RUN (G-SCHED N)
                            (MAKE-STATE 0 (LIST N A) STK *G*))
                       (MAKE-STATE 14 (LIST 0 (F N))
                                   (PUSH (F N) STK)
                                   *G*))))

ACL2 Warning [Subsume] in ( DEFTHM MAIN ...):  A newly proposed :REWRITE
rule generated from MAIN probably subsumes the previously added :REWRITE
rule STEP-1, in the sense that the new rule will now probably be applied
whenever the old rule would have been.


ACL2 Warning [Subsume] in ( DEFTHM MAIN ...):  The previously added
rule STEP-1 subsumes a newly proposed :REWRITE rule generated from
MAIN, in the sense that the old rule rewrites a more general target.
Because the new rule will be tried first, it may nonetheless find application.


But simplification reduces this to T, using the :compound-recognizer
rule ACL2::NATP-COMPOUND-RECOGNIZER, the :definition FIX, primitive
type reasoning, the :rewrite rules STEP-1, STEP-2 and UNICITY-OF-1
and the :type-prescription rule F.

Q.E.D.

Summary
Form:  ( DEFTHM MAIN ...)
Rules: ((:COMPOUND-RECOGNIZER ACL2::NATP-COMPOUND-RECOGNIZER)
        (:DEFINITION FIX)
        (:FAKE-RUNE-FOR-TYPE-SET NIL)
        (:REWRITE STEP-1)
        (:REWRITE STEP-2)
        (:REWRITE UNICITY-OF-1)
        (:TYPE-PRESCRIPTION F))
Warnings:  Subsume
 MAIN
M1 >>(DEFTHM COROLLARY1
       (LET ((S_FIN (RUN (G-SCHED N)
                         (MAKE-STATE 0 (LIST N A) STK *G*))))
         (IMPLIES (NATP N)
                  (AND (EQUAL (TOP (STACK S_FIN)) (F N))
                       (HALTEDP S_FIN)))))

ACL2 Warning [Non-rec] in ( DEFTHM COROLLARY1 ...):  A :REWRITE rule
generated from COROLLARY1 will be triggered only by terms containing
the function symbol HALTEDP, which has a non-recursive definition.
Unless this definition is disabled, this rule is unlikely ever to be
used.


By case analysis we reduce the conjecture to

Goal'
(IMPLIES (NATP N)
         (AND (EQUAL (TOP (STACK (RUN (G-SCHED N)
                                      (MAKE-STATE 0 (LIST N A)
                                                  STK
                                                  '((PUSH 1)
                                                    (STORE 1)
                                                    (LOAD 0)
                                                    (IFLE 10)
                                                    (LOAD 0)
                                                    (LOAD 1)
                                                    (MUL)
                                                    (STORE 1)
                                                    (LOAD 0)
                                                    (PUSH 1)
                                                    (SUB)
                                                    (STORE 0)
                                                    (GOTO -10)
                                                    (LOAD 1)
                                                    (RETURN))))))
                     (F N))
              (HALTEDP (RUN (G-SCHED N)
                            (MAKE-STATE 0 (LIST N A)
                                        STK
                                        '((PUSH 1)
                                          (STORE 1)
                                          (LOAD 0)
                                          (IFLE 10)
                                          (LOAD 0)
                                          (LOAD 1)
                                          (MUL)
                                          (STORE 1)
                                          (LOAD 0)
                                          (PUSH 1)
                                          (SUB)
                                          (STORE 0)
                                          (GOTO -10)
                                          (LOAD 1)
                                          (RETURN))))))).

But simplification reduces this to T, using the :compound-recognizer
rule ACL2::NATP-COMPOUND-RECOGNIZER, the :definitions DO-INST, HALTEDP
and NEXT-INST, the :executable-counterparts of CONSP, EQUAL, NTH and
OPCODE, primitive type reasoning and the :rewrite rules MAIN, STACKS,
STATES and STEP-OPENER.

Q.E.D.

The storage of COROLLARY1 depends upon the :type-prescription rule
HALTEDP.

Summary
Form:  ( DEFTHM COROLLARY1 ...)
Rules: ((:COMPOUND-RECOGNIZER ACL2::NATP-COMPOUND-RECOGNIZER)
        (:DEFINITION DO-INST)
        (:DEFINITION HALTEDP)
        (:DEFINITION NEXT-INST)
        (:EXECUTABLE-COUNTERPART CONSP)
        (:EXECUTABLE-COUNTERPART EQUAL)
        (:EXECUTABLE-COUNTERPART NTH)
        (:EXECUTABLE-COUNTERPART OPCODE)
        (:FAKE-RUNE-FOR-TYPE-SET NIL)
        (:REWRITE MAIN)
        (:REWRITE STACKS)
        (:REWRITE STATES)
        (:REWRITE STEP-OPENER)
        (:TYPE-PRESCRIPTION HALTEDP))
Warnings:  Non-rec
 COROLLARY1
M1 >>(DEFTHM COROLLARY2
       (LET ((S_FIN (RUN (G-SCHED N)
                         (MAKE-STATE 0 (LIST N A)
                                     STK
                                     (COMPILE '(N)
                                              '((A = 1)
                                                (WHILE (N > 0)
                                                       (A = (N * A))
                                                       (N = (N - 1)))
                                                (RETURN A)))))))
         (IMPLIES (NATP N)
                  (AND (EQUAL (TOP (STACK S_FIN)) (F N))
                       (HALTEDP S_FIN)))))

ACL2 Warning [Non-rec] in ( DEFTHM COROLLARY2 ...):  A :REWRITE rule
generated from COROLLARY2 will be triggered only by terms containing
the function symbol COMPILE, which has a non-recursive definition.
Unless this definition is disabled, this rule is unlikely ever to be
used.


ACL2 Warning [Non-rec] in ( DEFTHM COROLLARY2 ...):  A :REWRITE rule
generated from COROLLARY2 will be triggered only by terms containing
the function symbols HALTEDP and COMPILE, which have non-recursive
definitions.  Unless these definitions are disabled, this rule is unlikely
ever to be used.


By the :executable-counterpart of COMPILE we reduce the conjecture
to

Goal'
(IMPLIES (NATP N)
         (AND (EQUAL (TOP (STACK (RUN (G-SCHED N)
                                      (MAKE-STATE 0 (LIST N A)
                                                  STK
                                                  '((PUSH 1)
                                                    (STORE 1)
                                                    (LOAD 0)
                                                    (IFLE 10)
                                                    (LOAD 0)
                                                    (LOAD 1)
                                                    (MUL)
                                                    (STORE 1)
                                                    (LOAD 0)
                                                    (PUSH 1)
                                                    (SUB)
                                                    (STORE 0)
                                                    (GOTO -10)
                                                    (LOAD 1)
                                                    (RETURN))))))
                     (F N))
              (HALTEDP (RUN (G-SCHED N)
                            (MAKE-STATE 0 (LIST N A)
                                        STK
                                        '((PUSH 1)
                                          (STORE 1)
                                          (LOAD 0)
                                          (IFLE 10)
                                          (LOAD 0)
                                          (LOAD 1)
                                          (MUL)
                                          (STORE 1)
                                          (LOAD 0)
                                          (PUSH 1)
                                          (SUB)
                                          (STORE 0)
                                          (GOTO -10)
                                          (LOAD 1)
                                          (RETURN))))))).

But simplification reduces this to T, using the :compound-recognizer
rule ACL2::NATP-COMPOUND-RECOGNIZER, the :definitions DO-INST, HALTEDP
and NEXT-INST, the :executable-counterparts of CONSP, EQUAL, NTH and
OPCODE, primitive type reasoning and the :rewrite rules MAIN, STACKS,
STATES and STEP-OPENER.

Q.E.D.

The storage of COROLLARY2 depends upon the :type-prescription rule
HALTEDP.

Summary
Form:  ( DEFTHM COROLLARY2 ...)
Rules: ((:COMPOUND-RECOGNIZER ACL2::NATP-COMPOUND-RECOGNIZER)
        (:DEFINITION DO-INST)
        (:DEFINITION HALTEDP)
        (:DEFINITION NEXT-INST)
        (:EXECUTABLE-COUNTERPART COMPILE)
        (:EXECUTABLE-COUNTERPART CONSP)
        (:EXECUTABLE-COUNTERPART EQUAL)
        (:EXECUTABLE-COUNTERPART NTH)
        (:EXECUTABLE-COUNTERPART OPCODE)
        (:FAKE-RUNE-FOR-TYPE-SET NIL)
        (:REWRITE MAIN)
        (:REWRITE STACKS)
        (:REWRITE STATES)
        (:REWRITE STEP-OPENER)
        (:TYPE-PRESCRIPTION HALTEDP))
Warnings:  Non-rec
 COROLLARY2
M1 >>'(END OF DEMO 5)
(END OF DEMO 5)
M1 >>'(THE END)
(THE END)
M1 >>Bye.
