(* Title: HOL/HOLCF/Cfun.thy
Author: Franz Regensburger
Author: Brian Huffman
*)
header {* The type of continuous functions *}
theory Cfun
imports Cpodef Fun_Cpo Product_Cpo
begin
default_sort cpo
subsection {* Definition of continuous function type *}
cpodef ('a, 'b) cfun (infixr "->" 0) = "{f::'a => 'b. cont f}"
by (auto intro: cont_const adm_cont)
type_notation (xsymbols)
cfun ("(_ \<rightarrow>/ _)" [1, 0] 0)
notation
Rep_cfun ("(_$/_)" [999,1000] 999)
notation (xsymbols)
Rep_cfun ("(_\<cdot>/_)" [999,1000] 999)
notation (HTML output)
Rep_cfun ("(_\<cdot>/_)" [999,1000] 999)
subsection {* Syntax for continuous lambda abstraction *}
syntax "_cabs" :: "[logic, logic] \<Rightarrow> logic"
parse_translation {*
(* rewrite (_cabs x t) => (Abs_cfun (%x. t)) *)
[mk_binder_tr (@{syntax_const "_cabs"}, @{const_syntax Abs_cfun})];
*}
print_translation {*
[(@{const_syntax Abs_cfun}, fn [Abs abs] =>
let val (x, t) = atomic_abs_tr' abs
in Syntax.const @{syntax_const "_cabs"} $ x $ t end)]
*} -- {* To avoid eta-contraction of body *}
text {* Syntax for nested abstractions *}
syntax
"_Lambda" :: "[cargs, logic] \<Rightarrow> logic" ("(3LAM _./ _)" [1000, 10] 10)
syntax (xsymbols)
"_Lambda" :: "[cargs, logic] \<Rightarrow> logic" ("(3\<Lambda> _./ _)" [1000, 10] 10)
parse_ast_translation {*
(* rewrite (LAM x y z. t) => (_cabs x (_cabs y (_cabs z t))) *)
(* cf. Syntax.lambda_ast_tr from src/Pure/Syntax/syn_trans.ML *)
let
fun Lambda_ast_tr [pats, body] =
Ast.fold_ast_p @{syntax_const "_cabs"}
(Ast.unfold_ast @{syntax_const "_cargs"} (Ast.strip_positions pats), body)
| Lambda_ast_tr asts = raise Ast.AST ("Lambda_ast_tr", asts);
in [(@{syntax_const "_Lambda"}, Lambda_ast_tr)] end;
*}
print_ast_translation {*
(* rewrite (_cabs x (_cabs y (_cabs z t))) => (LAM x y z. t) *)
(* cf. Syntax.abs_ast_tr' from src/Pure/Syntax/syn_trans.ML *)
let
fun cabs_ast_tr' asts =
(case Ast.unfold_ast_p @{syntax_const "_cabs"}
(Ast.Appl (Ast.Constant @{syntax_const "_cabs"} :: asts)) of
([], _) => raise Ast.AST ("cabs_ast_tr'", asts)
| (xs, body) => Ast.Appl
[Ast.Constant @{syntax_const "_Lambda"},
Ast.fold_ast @{syntax_const "_cargs"} xs, body]);
in [(@{syntax_const "_cabs"}, cabs_ast_tr')] end
*}
text {* Dummy patterns for continuous abstraction *}
translations
"\<Lambda> _. t" => "CONST Abs_cfun (\<lambda> _. t)"
subsection {* Continuous function space is pointed *}
lemma bottom_cfun: "\<bottom> \<in> cfun"
by (simp add: cfun_def inst_fun_pcpo)
instance cfun :: (cpo, discrete_cpo) discrete_cpo
by intro_classes (simp add: below_cfun_def Rep_cfun_inject)
instance cfun :: (cpo, pcpo) pcpo
by (rule typedef_pcpo [OF type_definition_cfun below_cfun_def bottom_cfun])
lemmas Rep_cfun_strict =
typedef_Rep_strict [OF type_definition_cfun below_cfun_def bottom_cfun]
lemmas Abs_cfun_strict =
typedef_Abs_strict [OF type_definition_cfun below_cfun_def bottom_cfun]
text {* function application is strict in its first argument *}
lemma Rep_cfun_strict1 [simp]: "\<bottom>\<cdot>x = \<bottom>"
by (simp add: Rep_cfun_strict)
lemma LAM_strict [simp]: "(\<Lambda> x. \<bottom>) = \<bottom>"
by (simp add: inst_fun_pcpo [symmetric] Abs_cfun_strict)
text {* for compatibility with old HOLCF-Version *}
lemma inst_cfun_pcpo: "\<bottom> = (\<Lambda> x. \<bottom>)"
by simp
subsection {* Basic properties of continuous functions *}
text {* Beta-equality for continuous functions *}
lemma Abs_cfun_inverse2: "cont f \<Longrightarrow> Rep_cfun (Abs_cfun f) = f"
by (simp add: Abs_cfun_inverse cfun_def)
lemma beta_cfun: "cont f \<Longrightarrow> (\<Lambda> x. f x)\<cdot>u = f u"
by (simp add: Abs_cfun_inverse2)
text {* Beta-reduction simproc *}
text {*
Given the term @{term "(\<Lambda> x. f x)\<cdot>y"}, the procedure tries to
construct the theorem @{term "(\<Lambda> x. f x)\<cdot>y == f y"}. If this
theorem cannot be completely solved by the cont2cont rules, then
the procedure returns the ordinary conditional @{text beta_cfun}
rule.
The simproc does not solve any more goals that would be solved by
using @{text beta_cfun} as a simp rule. The advantage of the
simproc is that it can avoid deeply-nested calls to the simplifier
that would otherwise be caused by large continuity side conditions.
Update: The simproc now uses rule @{text Abs_cfun_inverse2} instead
of @{text beta_cfun}, to avoid problems with eta-contraction.
*}
simproc_setup beta_cfun_proc ("Rep_cfun (Abs_cfun f)") = {*
fn phi => fn ss => fn ct =>
let
val dest = Thm.dest_comb;
val f = (snd o dest o snd o dest) ct;
val [T, U] = Thm.dest_ctyp (ctyp_of_term f);
val tr = instantiate' [SOME T, SOME U] [SOME f]
(mk_meta_eq @{thm Abs_cfun_inverse2});
val rules = Cont2ContData.get (Simplifier.the_context ss);
val tac = SOLVED' (REPEAT_ALL_NEW (match_tac rules));
in SOME (perhaps (SINGLE (tac 1)) tr) end
*}
text {* Eta-equality for continuous functions *}
lemma eta_cfun: "(\<Lambda> x. f\<cdot>x) = f"
by (rule Rep_cfun_inverse)
text {* Extensionality for continuous functions *}
lemma cfun_eq_iff: "f = g \<longleftrightarrow> (\<forall>x. f\<cdot>x = g\<cdot>x)"
by (simp add: Rep_cfun_inject [symmetric] fun_eq_iff)
lemma cfun_eqI: "(\<And>x. f\<cdot>x = g\<cdot>x) \<Longrightarrow> f = g"
by (simp add: cfun_eq_iff)
text {* Extensionality wrt. ordering for continuous functions *}
lemma cfun_below_iff: "f \<sqsubseteq> g \<longleftrightarrow> (\<forall>x. f\<cdot>x \<sqsubseteq> g\<cdot>x)"
by (simp add: below_cfun_def fun_below_iff)
lemma cfun_belowI: "(\<And>x. f\<cdot>x \<sqsubseteq> g\<cdot>x) \<Longrightarrow> f \<sqsubseteq> g"
by (simp add: cfun_below_iff)
text {* Congruence for continuous function application *}
lemma cfun_cong: "\<lbrakk>f = g; x = y\<rbrakk> \<Longrightarrow> f\<cdot>x = g\<cdot>y"
by simp
lemma cfun_fun_cong: "f = g \<Longrightarrow> f\<cdot>x = g\<cdot>x"
by simp
lemma cfun_arg_cong: "x = y \<Longrightarrow> f\<cdot>x = f\<cdot>y"
by simp
subsection {* Continuity of application *}
lemma cont_Rep_cfun1: "cont (\<lambda>f. f\<cdot>x)"
by (rule cont_Rep_cfun [OF cont_id, THEN cont2cont_fun])
lemma cont_Rep_cfun2: "cont (\<lambda>x. f\<cdot>x)"
apply (cut_tac x=f in Rep_cfun)
apply (simp add: cfun_def)
done
lemmas monofun_Rep_cfun = cont_Rep_cfun [THEN cont2mono]
lemmas monofun_Rep_cfun1 = cont_Rep_cfun1 [THEN cont2mono, standard]
lemmas monofun_Rep_cfun2 = cont_Rep_cfun2 [THEN cont2mono, standard]
text {* contlub, cont properties of @{term Rep_cfun} in each argument *}
lemma contlub_cfun_arg: "chain Y \<Longrightarrow> f\<cdot>(\<Squnion>i. Y i) = (\<Squnion>i. f\<cdot>(Y i))"
by (rule cont_Rep_cfun2 [THEN cont2contlubE])
lemma contlub_cfun_fun: "chain F \<Longrightarrow> (\<Squnion>i. F i)\<cdot>x = (\<Squnion>i. F i\<cdot>x)"
by (rule cont_Rep_cfun1 [THEN cont2contlubE])
text {* monotonicity of application *}
lemma monofun_cfun_fun: "f \<sqsubseteq> g \<Longrightarrow> f\<cdot>x \<sqsubseteq> g\<cdot>x"
by (simp add: cfun_below_iff)
lemma monofun_cfun_arg: "x \<sqsubseteq> y \<Longrightarrow> f\<cdot>x \<sqsubseteq> f\<cdot>y"
by (rule monofun_Rep_cfun2 [THEN monofunE])
lemma monofun_cfun: "\<lbrakk>f \<sqsubseteq> g; x \<sqsubseteq> y\<rbrakk> \<Longrightarrow> f\<cdot>x \<sqsubseteq> g\<cdot>y"
by (rule below_trans [OF monofun_cfun_fun monofun_cfun_arg])
text {* ch2ch - rules for the type @{typ "'a -> 'b"} *}
lemma chain_monofun: "chain Y \<Longrightarrow> chain (\<lambda>i. f\<cdot>(Y i))"
by (erule monofun_Rep_cfun2 [THEN ch2ch_monofun])
lemma ch2ch_Rep_cfunR: "chain Y \<Longrightarrow> chain (\<lambda>i. f\<cdot>(Y i))"
by (rule monofun_Rep_cfun2 [THEN ch2ch_monofun])
lemma ch2ch_Rep_cfunL: "chain F \<Longrightarrow> chain (\<lambda>i. (F i)\<cdot>x)"
by (rule monofun_Rep_cfun1 [THEN ch2ch_monofun])
lemma ch2ch_Rep_cfun [simp]:
"\<lbrakk>chain F; chain Y\<rbrakk> \<Longrightarrow> chain (\<lambda>i. (F i)\<cdot>(Y i))"
by (simp add: chain_def monofun_cfun)
lemma ch2ch_LAM [simp]:
"\<lbrakk>\<And>x. chain (\<lambda>i. S i x); \<And>i. cont (\<lambda>x. S i x)\<rbrakk> \<Longrightarrow> chain (\<lambda>i. \<Lambda> x. S i x)"
by (simp add: chain_def cfun_below_iff)
text {* contlub, cont properties of @{term Rep_cfun} in both arguments *}
lemma lub_APP:
"\<lbrakk>chain F; chain Y\<rbrakk> \<Longrightarrow> (\<Squnion>i. F i\<cdot>(Y i)) = (\<Squnion>i. F i)\<cdot>(\<Squnion>i. Y i)"
by (simp add: contlub_cfun_fun contlub_cfun_arg diag_lub)
lemma lub_LAM:
"\<lbrakk>\<And>x. chain (\<lambda>i. F i x); \<And>i. cont (\<lambda>x. F i x)\<rbrakk>
\<Longrightarrow> (\<Squnion>i. \<Lambda> x. F i x) = (\<Lambda> x. \<Squnion>i. F i x)"
by (simp add: lub_cfun lub_fun ch2ch_lambda)
lemmas lub_distribs = lub_APP lub_LAM
text {* strictness *}
lemma strictI: "f\<cdot>x = \<bottom> \<Longrightarrow> f\<cdot>\<bottom> = \<bottom>"
apply (rule bottomI)
apply (erule subst)
apply (rule minimal [THEN monofun_cfun_arg])
done
text {* type @{typ "'a -> 'b"} is chain complete *}
lemma lub_cfun: "chain F \<Longrightarrow> (\<Squnion>i. F i) = (\<Lambda> x. \<Squnion>i. F i\<cdot>x)"
by (simp add: lub_cfun lub_fun ch2ch_lambda)
subsection {* Continuity simplification procedure *}
text {* cont2cont lemma for @{term Rep_cfun} *}
lemma cont2cont_APP [simp, cont2cont]:
assumes f: "cont (\<lambda>x. f x)"
assumes t: "cont (\<lambda>x. t x)"
shows "cont (\<lambda>x. (f x)\<cdot>(t x))"
proof -
have 1: "\<And>y. cont (\<lambda>x. (f x)\<cdot>y)"
using cont_Rep_cfun1 f by (rule cont_compose)
show "cont (\<lambda>x. (f x)\<cdot>(t x))"
using t cont_Rep_cfun2 1 by (rule cont_apply)
qed
text {*
Two specific lemmas for the combination of LCF and HOL terms.
These lemmas are needed in theories that use types like @{typ "'a \<rightarrow> 'b \<Rightarrow> 'c"}.
*}
lemma cont_APP_app [simp]: "\<lbrakk>cont f; cont g\<rbrakk> \<Longrightarrow> cont (\<lambda>x. ((f x)\<cdot>(g x)) s)"
by (rule cont2cont_APP [THEN cont2cont_fun])
lemma cont_APP_app_app [simp]: "\<lbrakk>cont f; cont g\<rbrakk> \<Longrightarrow> cont (\<lambda>x. ((f x)\<cdot>(g x)) s t)"
by (rule cont_APP_app [THEN cont2cont_fun])
text {* cont2mono Lemma for @{term "%x. LAM y. c1(x)(y)"} *}
lemma cont2mono_LAM:
"\<lbrakk>\<And>x. cont (\<lambda>y. f x y); \<And>y. monofun (\<lambda>x. f x y)\<rbrakk>
\<Longrightarrow> monofun (\<lambda>x. \<Lambda> y. f x y)"
unfolding monofun_def cfun_below_iff by simp
text {* cont2cont Lemma for @{term "%x. LAM y. f x y"} *}
text {*
Not suitable as a cont2cont rule, because on nested lambdas
it causes exponential blow-up in the number of subgoals.
*}
lemma cont2cont_LAM:
assumes f1: "\<And>x. cont (\<lambda>y. f x y)"
assumes f2: "\<And>y. cont (\<lambda>x. f x y)"
shows "cont (\<lambda>x. \<Lambda> y. f x y)"
proof (rule cont_Abs_cfun)
fix x
from f1 show "f x \<in> cfun" by (simp add: cfun_def)
from f2 show "cont f" by (rule cont2cont_lambda)
qed
text {*
This version does work as a cont2cont rule, since it
has only a single subgoal.
*}
lemma cont2cont_LAM' [simp, cont2cont]:
fixes f :: "'a::cpo \<Rightarrow> 'b::cpo \<Rightarrow> 'c::cpo"
assumes f: "cont (\<lambda>p. f (fst p) (snd p))"
shows "cont (\<lambda>x. \<Lambda> y. f x y)"
using assms by (simp add: cont2cont_LAM prod_cont_iff)
lemma cont2cont_LAM_discrete [simp, cont2cont]:
"(\<And>y::'a::discrete_cpo. cont (\<lambda>x. f x y)) \<Longrightarrow> cont (\<lambda>x. \<Lambda> y. f x y)"
by (simp add: cont2cont_LAM)
subsection {* Miscellaneous *}
text {* Monotonicity of @{term Abs_cfun} *}
lemma monofun_LAM:
"\<lbrakk>cont f; cont g; \<And>x. f x \<sqsubseteq> g x\<rbrakk> \<Longrightarrow> (\<Lambda> x. f x) \<sqsubseteq> (\<Lambda> x. g x)"
by (simp add: cfun_below_iff)
text {* some lemmata for functions with flat/chfin domain/range types *}
lemma chfin_Rep_cfunR: "chain (Y::nat => 'a::cpo->'b::chfin)
==> !s. ? n. (LUB i. Y i)$s = Y n$s"
apply (rule allI)
apply (subst contlub_cfun_fun)
apply assumption
apply (fast intro!: lub_eqI chfin lub_finch2 chfin2finch ch2ch_Rep_cfunL)
done
lemma adm_chfindom: "adm (\<lambda>(u::'a::cpo \<rightarrow> 'b::chfin). P(u\<cdot>s))"
by (rule adm_subst, simp, rule adm_chfin)
subsection {* Continuous injection-retraction pairs *}
text {* Continuous retractions are strict. *}
lemma retraction_strict:
"\<forall>x. f\<cdot>(g\<cdot>x) = x \<Longrightarrow> f\<cdot>\<bottom> = \<bottom>"
apply (rule bottomI)
apply (drule_tac x="\<bottom>" in spec)
apply (erule subst)
apply (rule monofun_cfun_arg)
apply (rule minimal)
done
lemma injection_eq:
"\<forall>x. f\<cdot>(g\<cdot>x) = x \<Longrightarrow> (g\<cdot>x = g\<cdot>y) = (x = y)"
apply (rule iffI)
apply (drule_tac f=f in cfun_arg_cong)
apply simp
apply simp
done
lemma injection_below:
"\<forall>x. f\<cdot>(g\<cdot>x) = x \<Longrightarrow> (g\<cdot>x \<sqsubseteq> g\<cdot>y) = (x \<sqsubseteq> y)"
apply (rule iffI)
apply (drule_tac f=f in monofun_cfun_arg)
apply simp
apply (erule monofun_cfun_arg)
done
lemma injection_defined_rev:
"\<lbrakk>\<forall>x. f\<cdot>(g\<cdot>x) = x; g\<cdot>z = \<bottom>\<rbrakk> \<Longrightarrow> z = \<bottom>"
apply (drule_tac f=f in cfun_arg_cong)
apply (simp add: retraction_strict)
done
lemma injection_defined:
"\<lbrakk>\<forall>x. f\<cdot>(g\<cdot>x) = x; z \<noteq> \<bottom>\<rbrakk> \<Longrightarrow> g\<cdot>z \<noteq> \<bottom>"
by (erule contrapos_nn, rule injection_defined_rev)
text {* a result about functions with flat codomain *}
lemma flat_eqI: "\<lbrakk>(x::'a::flat) \<sqsubseteq> y; x \<noteq> \<bottom>\<rbrakk> \<Longrightarrow> x = y"
by (drule ax_flat, simp)
lemma flat_codom:
"f\<cdot>x = (c::'b::flat) \<Longrightarrow> f\<cdot>\<bottom> = \<bottom> \<or> (\<forall>z. f\<cdot>z = c)"
apply (case_tac "f\<cdot>x = \<bottom>")
apply (rule disjI1)
apply (rule bottomI)
apply (erule_tac t="\<bottom>" in subst)
apply (rule minimal [THEN monofun_cfun_arg])
apply clarify
apply (rule_tac a = "f\<cdot>\<bottom>" in refl [THEN box_equals])
apply (erule minimal [THEN monofun_cfun_arg, THEN flat_eqI])
apply (erule minimal [THEN monofun_cfun_arg, THEN flat_eqI])
done
subsection {* Identity and composition *}
definition
ID :: "'a \<rightarrow> 'a" where
"ID = (\<Lambda> x. x)"
definition
cfcomp :: "('b \<rightarrow> 'c) \<rightarrow> ('a \<rightarrow> 'b) \<rightarrow> 'a \<rightarrow> 'c" where
oo_def: "cfcomp = (\<Lambda> f g x. f\<cdot>(g\<cdot>x))"
abbreviation
cfcomp_syn :: "['b \<rightarrow> 'c, 'a \<rightarrow> 'b] \<Rightarrow> 'a \<rightarrow> 'c" (infixr "oo" 100) where
"f oo g == cfcomp\<cdot>f\<cdot>g"
lemma ID1 [simp]: "ID\<cdot>x = x"
by (simp add: ID_def)
lemma cfcomp1: "(f oo g) = (\<Lambda> x. f\<cdot>(g\<cdot>x))"
by (simp add: oo_def)
lemma cfcomp2 [simp]: "(f oo g)\<cdot>x = f\<cdot>(g\<cdot>x)"
by (simp add: cfcomp1)
lemma cfcomp_LAM: "cont g \<Longrightarrow> f oo (\<Lambda> x. g x) = (\<Lambda> x. f\<cdot>(g x))"
by (simp add: cfcomp1)
lemma cfcomp_strict [simp]: "\<bottom> oo f = \<bottom>"
by (simp add: cfun_eq_iff)
text {*
Show that interpretation of (pcpo,@{text "_->_"}) is a category.
The class of objects is interpretation of syntactical class pcpo.
The class of arrows between objects @{typ 'a} and @{typ 'b} is interpret. of @{typ "'a -> 'b"}.
The identity arrow is interpretation of @{term ID}.
The composition of f and g is interpretation of @{text "oo"}.
*}
lemma ID2 [simp]: "f oo ID = f"
by (rule cfun_eqI, simp)
lemma ID3 [simp]: "ID oo f = f"
by (rule cfun_eqI, simp)
lemma assoc_oo: "f oo (g oo h) = (f oo g) oo h"
by (rule cfun_eqI, simp)
subsection {* Strictified functions *}
default_sort pcpo
definition
seq :: "'a \<rightarrow> 'b \<rightarrow> 'b" where
"seq = (\<Lambda> x. if x = \<bottom> then \<bottom> else ID)"
lemma cont2cont_if_bottom [cont2cont, simp]:
assumes f: "cont (\<lambda>x. f x)" and g: "cont (\<lambda>x. g x)"
shows "cont (\<lambda>x. if f x = \<bottom> then \<bottom> else g x)"
proof (rule cont_apply [OF f])
show "\<And>x. cont (\<lambda>y. if y = \<bottom> then \<bottom> else g x)"
unfolding cont_def is_lub_def is_ub_def ball_simps
by (simp add: lub_eq_bottom_iff)
show "\<And>y. cont (\<lambda>x. if y = \<bottom> then \<bottom> else g x)"
by (simp add: g)
qed
lemma seq_conv_if: "seq\<cdot>x = (if x = \<bottom> then \<bottom> else ID)"
unfolding seq_def by simp
lemma seq_simps [simp]:
"seq\<cdot>\<bottom> = \<bottom>"
"seq\<cdot>x\<cdot>\<bottom> = \<bottom>"
"x \<noteq> \<bottom> \<Longrightarrow> seq\<cdot>x = ID"
by (simp_all add: seq_conv_if)
definition
strictify :: "('a \<rightarrow> 'b) \<rightarrow> 'a \<rightarrow> 'b" where
"strictify = (\<Lambda> f x. seq\<cdot>x\<cdot>(f\<cdot>x))"
lemma strictify_conv_if: "strictify\<cdot>f\<cdot>x = (if x = \<bottom> then \<bottom> else f\<cdot>x)"
unfolding strictify_def by simp
lemma strictify1 [simp]: "strictify\<cdot>f\<cdot>\<bottom> = \<bottom>"
by (simp add: strictify_conv_if)
lemma strictify2 [simp]: "x \<noteq> \<bottom> \<Longrightarrow> strictify\<cdot>f\<cdot>x = f\<cdot>x"
by (simp add: strictify_conv_if)
subsection {* Continuity of let-bindings *}
lemma cont2cont_Let:
assumes f: "cont (\<lambda>x. f x)"
assumes g1: "\<And>y. cont (\<lambda>x. g x y)"
assumes g2: "\<And>x. cont (\<lambda>y. g x y)"
shows "cont (\<lambda>x. let y = f x in g x y)"
unfolding Let_def using f g2 g1 by (rule cont_apply)
lemma cont2cont_Let' [simp, cont2cont]:
assumes f: "cont (\<lambda>x. f x)"
assumes g: "cont (\<lambda>p. g (fst p) (snd p))"
shows "cont (\<lambda>x. let y = f x in g x y)"
using f
proof (rule cont2cont_Let)
fix x show "cont (\<lambda>y. g x y)"
using g by (simp add: prod_cont_iff)
next
fix y show "cont (\<lambda>x. g x y)"
using g by (simp add: prod_cont_iff)
qed
text {* The simple version (suggested by Joachim Breitner) is needed if
the type of the defined term is not a cpo. *}
lemma cont2cont_Let_simple [simp, cont2cont]:
assumes "\<And>y. cont (\<lambda>x. g x y)"
shows "cont (\<lambda>x. let y = t in g x y)"
unfolding Let_def using assms .
end