Quotient types;

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+++ b/src/HOL/Library/Quotient.thy	Wed Oct 18 23:29:13 2000 +0200
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+(*  Title:      HOL/Library/Quotient.thy
+    ID:         $Id$
+    Author:     Gertrud Bauer and Markus Wenzel, TU Muenchen
+*)
+
+header {*
+  \title{Quotients}
+  \author{Gertrud Bauer and Markus Wenzel}
+*}
+
+theory Quotient = Main:
+
+text {*
+ Higher-order quotients are defined over partial equivalence relations
+ (PERs) instead of total ones.  We provide axiomatic type classes
+ @{text "equiv < partial_equiv"} and a type constructor
+ @{text "'a quot"} with basic operations.  Note that conventional
+ quotient constructions emerge as a special case.  This development is
+ loosely based on \cite{Slotosch:1997}.
+*}
+
+
+subsection {* Equivalence relations *}
+
+subsubsection {* Partial equivalence *}
+
+text {*
+ Type class @{text partial_equiv} models partial equivalence relations
+ (PERs) using the polymorphic @{text "\<sim> :: 'a => 'a => bool"} relation,
+ which is required to be symmetric and transitive, but not necessarily
+ reflexive.
+*}
+
+consts
+  eqv :: "'a => 'a => bool"    (infixl "\<sim>" 50)
+
+axclass partial_equiv < "term"
+  eqv_sym [elim?]: "x \<sim> y ==> y \<sim> x"
+  eqv_trans [trans]: "x \<sim> y ==> y \<sim> z ==> x \<sim> z"
+
+text {*
+ \medskip The domain of a partial equivalence relation is the set of
+ reflexive elements.  Due to symmetry and transitivity this
+ characterizes exactly those elements that are connected with
+ \emph{any} other one.
+*}
+
+constdefs
+  domain :: "'a::partial_equiv set"
+  "domain == {x. x \<sim> x}"
+
+lemma domainI [intro]: "x \<sim> x ==> x \<in> domain"
+  by (unfold domain_def) blast
+
+lemma domainD [dest]: "x \<in> domain ==> x \<sim> x"
+  by (unfold domain_def) blast
+
+theorem domainI' [elim?]: "x \<sim> y ==> x \<in> domain"
+proof
+  assume xy: "x \<sim> y"
+  also from xy have "y \<sim> x" ..
+  finally show "x \<sim> x" .
+qed
+
+
+subsubsection {* Equivalence on function spaces *}
+
+text {*
+ The @{text \<sim>} relation is lifted to function spaces.  It is
+ important to note that this is \emph{not} the direct product, but a
+ structural one corresponding to the congruence property.
+*}
+
+defs (overloaded)
+  eqv_fun_def: "f \<sim> g == \<forall>x \<in> domain. \<forall>y \<in> domain. x \<sim> y --> f x \<sim> g y"
+
+lemma partial_equiv_funI [intro?]:
+    "(!!x y. x \<in> domain ==> y \<in> domain ==> x \<sim> y ==> f x \<sim> g y) ==> f \<sim> g"
+  by (unfold eqv_fun_def) blast
+
+lemma partial_equiv_funD [dest?]:
+    "f \<sim> g ==> x \<in> domain ==> y \<in> domain ==> x \<sim> y ==> f x \<sim> g y"
+  by (unfold eqv_fun_def) blast
+
+text {*
+ The class of partial equivalence relations is closed under function
+ spaces (in \emph{both} argument positions).
+*}
+
+instance fun :: (partial_equiv, partial_equiv) partial_equiv
+proof intro_classes
+  fix f g h :: "'a::partial_equiv => 'b::partial_equiv"
+  assume fg: "f \<sim> g"
+  show "g \<sim> f"
+  proof
+    fix x y :: 'a
+    assume x: "x \<in> domain" and y: "y \<in> domain"
+    assume "x \<sim> y" hence "y \<sim> x" ..
+    with fg y x have "f y \<sim> g x" ..
+    thus "g x \<sim> f y" ..
+  qed
+  assume gh: "g \<sim> h"
+  show "f \<sim> h"
+  proof
+    fix x y :: 'a
+    assume x: "x \<in> domain" and y: "y \<in> domain" and "x \<sim> y"
+    with fg have "f x \<sim> g y" ..
+    also from y have "y \<sim> y" ..
+    with gh y y have "g y \<sim> h y" ..
+    finally show "f x \<sim> h y" .
+  qed
+qed
+
+
+subsubsection {* Total equivalence *}
+
+text {*
+ The class of total equivalence relations on top of PERs.  It
+ coincides with the standard notion of equivalence, i.e.\
+ @{text "\<sim> :: 'a => 'a => bool"} is required to be reflexive, transitive
+ and symmetric.
+*}
+
+axclass equiv < partial_equiv
+  eqv_refl [intro]: "x \<sim> x"
+
+text {*
+ On total equivalences all elements are reflexive, and congruence
+ holds unconditionally.
+*}
+
+theorem equiv_domain [intro]: "(x::'a::equiv) \<in> domain"
+proof
+  show "x \<sim> x" ..
+qed
+
+theorem equiv_cong [dest?]: "f \<sim> g ==> x \<sim> y ==> f x \<sim> g (y::'a::equiv)"
+proof -
+  assume "f \<sim> g"
+  moreover have "x \<in> domain" ..
+  moreover have "y \<in> domain" ..
+  moreover assume "x \<sim> y"
+  ultimately show ?thesis ..
+qed
+
+
+subsection {* Quotient types *}
+
+subsubsection {* General quotients and equivalence classes *}
+
+text {*
+ The quotient type @{text "'a quot"} consists of all \emph{equivalence
+ classes} over elements of the base type @{typ 'a}.
+*}
+
+typedef 'a quot = "{{x. a \<sim> x}| a::'a. True}"
+  by blast
+
+lemma quotI [intro]: "{x. a \<sim> x} \<in> quot"
+  by (unfold quot_def) blast
+
+lemma quotE [elim]: "R \<in> quot ==> (!!a. R = {x. a \<sim> x} ==> C) ==> C"
+  by (unfold quot_def) blast
+
+
+text {*
+ \medskip Standard properties of type-definitions.\footnote{(FIXME)
+ Better incorporate these into the typedef package?}
+*}
+
+theorem Rep_quot_inject: "(Rep_quot x = Rep_quot y) = (x = y)"
+proof
+  assume "Rep_quot x = Rep_quot y"
+  hence "Abs_quot (Rep_quot x) = Abs_quot (Rep_quot y)" by (simp only:)
+  thus "x = y" by (simp only: Rep_quot_inverse)
+next
+  assume "x = y"
+  thus "Rep_quot x = Rep_quot y" by simp
+qed
+
+theorem Abs_quot_inject:
+  "x \<in> quot ==> y \<in> quot ==> (Abs_quot x = Abs_quot y) = (x = y)"
+proof
+  assume "Abs_quot x = Abs_quot y"
+  hence "Rep_quot (Abs_quot x) = Rep_quot (Abs_quot y)" by simp
+  also assume "x \<in> quot" hence "Rep_quot (Abs_quot x) = x" by (rule Abs_quot_inverse)
+  also assume "y \<in> quot" hence "Rep_quot (Abs_quot y) = y" by (rule Abs_quot_inverse)
+  finally show "x = y" .
+next
+  assume "x = y"
+  thus "Abs_quot x = Abs_quot y" by simp
+qed
+
+theorem Rep_quot_induct: "y \<in> quot ==> (!!x. P (Rep_quot x)) ==> P y"
+proof -
+  assume "!!x. P (Rep_quot x)" hence "P (Rep_quot (Abs_quot y))" .
+  also assume "y \<in> quot" hence "Rep_quot (Abs_quot y) = y" by (rule Abs_quot_inverse)
+  finally show "P y" .
+qed
+
+theorem Abs_quot_induct: "(!!y. y \<in> quot ==> P (Abs_quot y)) ==> P x"
+proof -
+  assume r: "!!y. y \<in> quot ==> P (Abs_quot y)"
+  have "Rep_quot x \<in> quot" by (rule Rep_quot)
+  hence "P (Abs_quot (Rep_quot x))" by (rule r)
+  also have "Abs_quot (Rep_quot x) = x" by (rule Rep_quot_inverse)
+  finally show "P x" .
+qed
+
+text {*
+ \medskip Abstracted equivalence classes are the canonical
+ representation of elements of a quotient type.
+*}
+
+constdefs
+  eqv_class :: "('a::partial_equiv) => 'a quot"    ("\<lfloor>_\<rfloor>")
+  "\<lfloor>a\<rfloor> == Abs_quot {x. a \<sim> x}"
+
+theorem quot_rep: "\<exists>a. A = \<lfloor>a\<rfloor>"
+proof (unfold eqv_class_def)
+  show "\<exists>a. A = Abs_quot {x. a \<sim> x}"
+  proof (induct A rule: Abs_quot_induct)
+    fix R assume "R \<in> quot"
+    hence "\<exists>a. R = {x. a \<sim> x}" by blast
+    thus "\<exists>a. Abs_quot R = Abs_quot {x. a \<sim> x}" by blast
+  qed
+qed
+
+lemma quot_cases [case_names rep, cases type: quot]:
+    "(!!a. A = \<lfloor>a\<rfloor> ==> C) ==> C"
+  by (insert quot_rep) blast
+
+
+subsubsection {* Equality on quotients *}
+
+text {*
+ Equality of canonical quotient elements corresponds to the original
+ relation as follows.
+*}
+
+theorem eqv_class_eqI [intro]: "a \<sim> b ==> \<lfloor>a\<rfloor> = \<lfloor>b\<rfloor>"
+proof -
+  assume ab: "a \<sim> b"
+  have "{x. a \<sim> x} = {x. b \<sim> x}"
+  proof (rule Collect_cong)
+    fix x show "(a \<sim> x) = (b \<sim> x)"
+    proof
+      from ab have "b \<sim> a" ..
+      also assume "a \<sim> x"
+      finally show "b \<sim> x" .
+    next
+      note ab
+      also assume "b \<sim> x"
+      finally show "a \<sim> x" .
+    qed
+  qed
+  thus ?thesis by (simp only: eqv_class_def)
+qed
+
+theorem eqv_class_eqD' [dest?]: "\<lfloor>a\<rfloor> = \<lfloor>b\<rfloor> ==> a \<in> domain ==> a \<sim> b"  (* FIXME [dest] would cause trouble with blast due to overloading *)
+proof (unfold eqv_class_def)
+  assume "Abs_quot {x. a \<sim> x} = Abs_quot {x. b \<sim> x}"
+  hence "{x. a \<sim> x} = {x. b \<sim> x}" by (simp only: Abs_quot_inject quotI)
+  moreover assume "a \<in> domain" hence "a \<sim> a" ..
+  ultimately have "a \<in> {x. b \<sim> x}" by blast
+  hence "b \<sim> a" by blast
+  thus "a \<sim> b" ..
+qed
+
+theorem eqv_class_eqD [dest?]: "\<lfloor>a\<rfloor> = \<lfloor>b\<rfloor> ==> a \<sim> (b::'a::equiv)"  (* FIXME [dest] would cause trouble with blast due to overloading *)
+proof (rule eqv_class_eqD')
+  show "a \<in> domain" ..
+qed
+
+lemma eqv_class_eq' [simp]: "a \<in> domain ==> (\<lfloor>a\<rfloor> = \<lfloor>b\<rfloor>) = (a \<sim> b)"
+  by (insert eqv_class_eqI eqv_class_eqD') blast
+
+lemma eqv_class_eq [simp]: "(\<lfloor>a\<rfloor> = \<lfloor>b\<rfloor>) = (a \<sim> (b::'a::equiv))"
+  by (insert eqv_class_eqI eqv_class_eqD) blast
+
+
+subsubsection {* Picking representing elements *}
+
+constdefs
+  pick :: "'a::partial_equiv quot => 'a"
+  "pick A == SOME a. A = \<lfloor>a\<rfloor>"
+
+theorem pick_eqv' [intro?, simp]: "a \<in> domain ==> pick \<lfloor>a\<rfloor> \<sim> a" (* FIXME [intro] !? *)
+proof (unfold pick_def)
+  assume a: "a \<in> domain"
+  show "(SOME x. \<lfloor>a\<rfloor> = \<lfloor>x\<rfloor>) \<sim> a"
+  proof (rule someI2)
+    show "\<lfloor>a\<rfloor> = \<lfloor>a\<rfloor>" ..
+    fix x assume "\<lfloor>a\<rfloor> = \<lfloor>x\<rfloor>"
+    hence "a \<sim> x" ..
+    thus "x \<sim> a" ..
+  qed
+qed
+
+theorem pick_eqv [intro, simp]: "pick \<lfloor>a\<rfloor> \<sim> (a::'a::equiv)"
+proof (rule pick_eqv')
+  show "a \<in> domain" ..
+qed
+
+theorem pick_inverse: "\<lfloor>pick A\<rfloor> = (A::'a::equiv quot)"   (* FIXME tune proof *)
+proof (cases A)
+  fix a assume a: "A = \<lfloor>a\<rfloor>"
+  hence "pick A \<sim> a" by (simp only: pick_eqv)
+  hence "\<lfloor>pick A\<rfloor> = \<lfloor>a\<rfloor>" by simp
+  with a show ?thesis by simp
+qed
+
+end