|
%%% ADT file generated from csequence
csequence_codt[T: TYPE]: THEORY
BEGIN
csequence: TYPE
empty?, nonempty?: [csequence -> boolean]
first: [(nonempty?) -> T]
rest: [(nonempty?) -> csequence]
empty_cseq: (empty?)
add: [[T, csequence] -> (nonempty?)]
csequence_ord: [csequence -> upto(1)]
csequence_ord_defaxiom: AXIOM
csequence_ord(empty_cseq) = 0 AND
(FORALL (first: T, rest: csequence):
csequence_ord(add(first, rest)) = 1);
ord(x: csequence): [csequence -> upto(1)] =
CASES x OF empty_cseq: 0, add(add1_var, add2_var): 1 ENDCASES
csequence_empty_cseq_extensionality: AXIOM
FORALL (empty?_var: (empty?), empty?_var2: (empty?)):
empty?_var = empty?_var2;
csequence_add_extensionality: AXIOM
FORALL (nonempty?_var: (nonempty?), nonempty?_var2: (nonempty?)):
first(nonempty?_var) = first(nonempty?_var2) AND
rest(nonempty?_var) = rest(nonempty?_var2)
IMPLIES nonempty?_var = nonempty?_var2;
csequence_add_eta: AXIOM
FORALL (nonempty?_var: (nonempty?)):
add(first(nonempty?_var), rest(nonempty?_var)) = nonempty?_var;
csequence_first_add: AXIOM
FORALL (add1_var: T, add2_var: csequence):
first(add(add1_var, add2_var)) = add1_var;
csequence_rest_add: AXIOM
FORALL (add1_var: T, add2_var: csequence):
rest(add(add1_var, add2_var)) = add2_var;
csequence_inclusive: AXIOM
FORALL (csequence_var: csequence):
empty?(csequence_var) OR nonempty?(csequence_var);
bisimulation?(R: PRED[[csequence, csequence]]): boolean =
FORALL (x: csequence, y: csequence):
R(x, y) IMPLIES
empty?(x) AND empty?(y) OR
nonempty?(x) AND
nonempty?(y) AND first(x) = first(y) AND R(rest(x), rest(y));
coinduction: AXIOM
FORALL (B: (bisimulation?), x: csequence, y: csequence):
B(x, y) => x = y;
every(p: PRED[T])(a: csequence): COINDUCTIVE boolean =
CASES a
OF empty_cseq: TRUE,
add(add1_var, add2_var): p(add1_var) AND every(p)(add2_var)
ENDCASES;
every_weak_coinduction: AXIOM
FORALL (p: PRED[T], P: [csequence -> boolean]):
(FORALL (a: csequence):
P(a) IMPLIES
CASES a
OF empty_cseq: TRUE,
add(add1_var, add2_var): p(add1_var) AND P(add2_var)
ENDCASES)
IMPLIES (FORALL (a: csequence): P(a) IMPLIES every(p)(a));
every_coinduction: AXIOM
FORALL (p: PRED[T], P: [csequence -> boolean]):
(FORALL (a: csequence):
P(a) IMPLIES
CASES a
OF empty_cseq: TRUE,
add(add1_var, add2_var):
p(add1_var) AND (every(p)(add2_var) OR P(add2_var))
ENDCASES)
IMPLIES (FORALL (a: csequence): P(a) IMPLIES every(p)(a));
some(p: PRED[T])(a: csequence): INDUCTIVE boolean =
CASES a
OF empty_cseq: FALSE,
add(add1_var, add2_var): p(add1_var) OR some(p)(add2_var)
ENDCASES;
some_weak_induction: AXIOM
FORALL (p: PRED[T], P: [csequence -> boolean]):
(FORALL (a: csequence):
CASES a
OF empty_cseq: FALSE,
add(add1_var, add2_var): p(add1_var) OR P(add2_var)
ENDCASES
IMPLIES P(a))
IMPLIES (FORALL (a: csequence): some(p)(a) IMPLIES P(a));
some_induction: AXIOM
FORALL (p: PRED[T], P: [csequence -> boolean]):
(FORALL (a: csequence):
CASES a
OF empty_cseq: FALSE,
add(add1_var, add2_var):
p(add1_var) OR some(p)(add2_var) AND P(add2_var)
ENDCASES
IMPLIES P(a))
IMPLIES (FORALL (a: csequence): some(p)(a) IMPLIES P(a));
END csequence_codt
csequence_codt_map[T: TYPE, T1: TYPE]: THEORY
BEGIN
IMPORTING csequence_codt
map(f: [T -> T1])(a: csequence[T]): csequence[T1] =
CASES a
OF empty_cseq: empty_cseq,
add(add1_var, add2_var): add(f(add1_var), map(f)(add2_var))
ENDCASES;
map(f: [T -> T1], a: csequence[T]): csequence[T1] =
CASES a
OF empty_cseq: empty_cseq,
add(add1_var, add2_var): add(f(add1_var), map(f, add2_var))
ENDCASES;
every(R: [[T, T1] -> boolean])(x: csequence[T], y: csequence[T1]):
boolean =
empty?(x) AND empty?(y) OR
nonempty?(x) AND
nonempty?(y) AND
R(first(x), first(y)) AND every(R)(rest(x), rest(y));
END csequence_codt_map
csequence_codt_coreduce[T: TYPE, domain: TYPE]: THEORY
BEGIN
IMPORTING csequence_codt[T]
csequence_struct: DATATYPE
BEGIN
inj_empty_cseq: inj_empty?
inj_add(inj_first: T, inj_rest: domain): inj_nonempty?
END csequence_struct
csequence_struct: TYPE
inj_empty?, inj_nonempty?: [csequence_struct -> boolean]
inj_first: [(inj_nonempty?) -> T]
inj_rest: [(inj_nonempty?) -> domain]
inj_empty_cseq: (inj_empty?)
inj_add: [[T, domain] -> (inj_nonempty?)]
csequence_struct_ord: [csequence_struct -> upto(1)]
csequence_struct_ord_defaxiom: AXIOM
csequence_struct_ord(inj_empty_cseq) = 0 AND
(FORALL (inj_first: T, inj_rest: domain):
csequence_struct_ord(inj_add(inj_first, inj_rest)) = 1);
ord(x: csequence_struct): [csequence_struct -> upto(1)] =
CASES x OF inj_empty_cseq: 0, inj_add(inj_add1_var, inj_add2_var): 1
ENDCASES
csequence_struct_inj_empty_cseq_extensionality: AXIOM
FORALL (inj_empty?_var: (inj_empty?), inj_empty?_var2: (inj_empty?)):
inj_empty?_var = inj_empty?_var2;
csequence_struct_inj_add_extensionality: AXIOM
FORALL (inj_nonempty?_var: (inj_nonempty?),
inj_nonempty?_var2: (inj_nonempty?)):
inj_first(inj_nonempty?_var) = inj_first(inj_nonempty?_var2) AND
inj_rest(inj_nonempty?_var) = inj_rest(inj_nonempty?_var2)
IMPLIES inj_nonempty?_var = inj_nonempty?_var2;
csequence_struct_inj_add_eta: AXIOM
FORALL (inj_nonempty?_var: (inj_nonempty?)):
inj_add(inj_first(inj_nonempty?_var), inj_rest(inj_nonempty?_var)) =
inj_nonempty?_var;
csequence_struct_inj_first_inj_add: AXIOM
FORALL (inj_add1_var: T, inj_add2_var: domain):
inj_first(inj_add(inj_add1_var, inj_add2_var)) = inj_add1_var;
csequence_struct_inj_rest_inj_add: AXIOM
FORALL (inj_add1_var: T, inj_add2_var: domain):
inj_rest(inj_add(inj_add1_var, inj_add2_var)) = inj_add2_var;
csequence_struct_inclusive: AXIOM
FORALL (csequence_struct_var: csequence_struct):
inj_empty?(csequence_struct_var) OR
inj_nonempty?(csequence_struct_var);
csequence_struct_induction: AXIOM
FORALL (p: [csequence_struct -> boolean]):
(p(inj_empty_cseq) AND
(FORALL (inj_add1_var: T, inj_add2_var: domain):
p(inj_add(inj_add1_var, inj_add2_var))))
IMPLIES
(FORALL (csequence_struct_var: csequence_struct):
p(csequence_struct_var));
subterm(x: csequence_struct, y: csequence_struct): boolean = x = y;
<<: (strict_well_founded?[csequence_struct]) =
LAMBDA (x, y: csequence_struct): FALSE;
csequence_struct_well_founded: AXIOM
strict_well_founded?[csequence_struct](<<);
reduce_nat(inj_empty?_fun: nat,
inj_nonempty?_fun: [[T, domain] -> nat]):
[csequence_struct -> nat] =
LAMBDA (csequence_struct_adtvar: csequence_struct):
LET red: [csequence_struct -> nat] =
reduce_nat(inj_empty?_fun, inj_nonempty?_fun)
IN
CASES csequence_struct_adtvar
OF inj_empty_cseq: inj_empty?_fun,
inj_add(inj_add1_var, inj_add2_var):
inj_nonempty?_fun(inj_add1_var, inj_add2_var)
ENDCASES;
REDUCE_nat(inj_empty?_fun: [csequence_struct -> nat],
inj_nonempty?_fun: [[T, domain, csequence_struct] -> nat]):
[csequence_struct -> nat] =
LAMBDA (csequence_struct_adtvar: csequence_struct):
LET red: [csequence_struct -> nat] =
REDUCE_nat(inj_empty?_fun, inj_nonempty?_fun)
IN
CASES csequence_struct_adtvar
OF inj_empty_cseq: inj_empty?_fun(csequence_struct_adtvar),
inj_add(inj_add1_var, inj_add2_var):
inj_nonempty?_fun(inj_add1_var, inj_add2_var,
csequence_struct_adtvar)
ENDCASES;
reduce_ordinal(inj_empty?_fun: ordinal,
inj_nonempty?_fun: [[T, domain] -> ordinal]):
[csequence_struct -> ordinal] =
LAMBDA (csequence_struct_adtvar: csequence_struct):
LET red: [csequence_struct -> ordinal] =
reduce_ordinal(inj_empty?_fun, inj_nonempty?_fun)
IN
CASES csequence_struct_adtvar
OF inj_empty_cseq: inj_empty?_fun,
inj_add(inj_add1_var, inj_add2_var):
inj_nonempty?_fun(inj_add1_var, inj_add2_var)
ENDCASES;
REDUCE_ordinal(inj_empty?_fun: [csequence_struct -> ordinal],
inj_nonempty?_fun:
[[T, domain, csequence_struct] -> ordinal]):
[csequence_struct -> ordinal] =
LAMBDA (csequence_struct_adtvar: csequence_struct):
LET red: [csequence_struct -> ordinal] =
REDUCE_ordinal(inj_empty?_fun, inj_nonempty?_fun)
IN
CASES csequence_struct_adtvar
OF inj_empty_cseq: inj_empty?_fun(csequence_struct_adtvar),
inj_add(inj_add1_var, inj_add2_var):
inj_nonempty?_fun(inj_add1_var, inj_add2_var,
csequence_struct_adtvar)
ENDCASES;
coreduce(op: [domain -> csequence_struct])(x: domain):
{c: csequence[T] |
inj_empty?(op(x)) AND empty?(c) OR
inj_nonempty?(op(x)) AND nonempty?(c)} =
CASES op(x)
OF inj_empty_cseq: empty_cseq,
inj_add(inj_add1_var, inj_add2_var):
add(inj_add1_var, coreduce(op)(inj_add2_var))
ENDCASES;
END csequence_codt_coreduce
¤ Diese beiden folgenden Angebotsgruppen bietet das Unternehmen0.25Angebot
Wie Sie bei der Firma Beratungs- und Dienstleistungen beauftragen können
¤
|
Haftungshinweis
Die Informationen auf dieser Webseite wurden
nach bestem Wissen sorgfältig zusammengestellt. Es wird jedoch weder Vollständigkeit, noch Richtigkeit,
noch Qualität der bereit gestellten Informationen zugesichert.
Bemerkung:
Die farbliche Syntaxdarstellung ist noch experimentell.
|
