theory Terms
imports "Nominal2_Atoms" "Nominal2_Eqvt" "Nominal2_Supp" "../QuotMain" "Abs"
begin

atom_decl name

text {* primrec seems to be genarally faster than fun *}

section {*** lets with binding patterns ***}

datatype rtrm1 =
  rVr1 "name"
| rAp1 "rtrm1" "rtrm1"
| rLm1 "name" "rtrm1"        --"name is bound in trm1"
| rLt1 "bp" "rtrm1" "rtrm1"   --"all variables in bp are bound in the 2nd trm1"
and bp =
  BUnit
| BVr "name"
| BPr "bp" "bp"

(* to be given by the user *)

primrec 
  bv1
where
  "bv1 (BUnit) = {}"
| "bv1 (BVr x) = {atom x}"
| "bv1 (BPr bp1 bp2) = (bv1 bp1) \<union> (bv1 bp1)"

(* needs to be calculated by the package *)
primrec 
  rfv_trm1 and rfv_bp
where
  "rfv_trm1 (rVr1 x) = {atom x}"
| "rfv_trm1 (rAp1 t1 t2) = (rfv_trm1 t1) \<union> (rfv_trm1 t2)"
| "rfv_trm1 (rLm1 x t) = (rfv_trm1 t) - {atom x}"
| "rfv_trm1 (rLt1 bp t1 t2) = (rfv_trm1 t1) \<union> (rfv_trm1 t2 - bv1 bp)"
| "rfv_bp (BUnit) = {}"
| "rfv_bp (BVr x) = {atom x}"
| "rfv_bp (BPr b1 b2) = (rfv_bp b1) \<union> (rfv_bp b2)"

(* needs to be stated by the package *)
instantiation 
  rtrm1 and bp :: pt
begin

primrec
  permute_rtrm1 and permute_bp
where
  "permute_rtrm1 pi (rVr1 a) = rVr1 (pi \<bullet> a)"
| "permute_rtrm1 pi (rAp1 t1 t2) = rAp1 (permute_rtrm1 pi t1) (permute_rtrm1 pi t2)"
| "permute_rtrm1 pi (rLm1 a t) = rLm1 (pi \<bullet> a) (permute_rtrm1 pi t)"
| "permute_rtrm1 pi (rLt1 bp t1 t2) = rLt1 (permute_bp pi bp) (permute_rtrm1 pi t1) (permute_rtrm1 pi t2)"
| "permute_bp pi (BUnit) = BUnit"
| "permute_bp pi (BVr a) = BVr (pi \<bullet> a)"
| "permute_bp pi (BPr bp1 bp2) = BPr (permute_bp pi bp1) (permute_bp pi bp2)"

lemma pt_rtrm1_bp_zero:
  fixes t::rtrm1
  and   b::bp
  shows "0 \<bullet> t = t"
  and   "0 \<bullet> b = b"
apply(induct t and b rule: rtrm1_bp.inducts)
apply(simp_all)
done

lemma pt_rtrm1_bp_plus:
  fixes t::rtrm1
  and   b::bp
  shows "((p + q) \<bullet> t) = p \<bullet> (q \<bullet> t)"
  and   "((p + q) \<bullet> b) = p \<bullet> (q \<bullet> b)"
apply(induct t and b rule: rtrm1_bp.inducts)
apply(simp_all)
done

instance
apply default
apply(simp_all add: pt_rtrm1_bp_zero pt_rtrm1_bp_plus)
done

end

inductive
  alpha1 :: "rtrm1 \<Rightarrow> rtrm1 \<Rightarrow> bool" ("_ \<approx>1 _" [100, 100] 100)
where
  a1: "a = b \<Longrightarrow> (rVr1 a) \<approx>1 (rVr1 b)"
| a2: "\<lbrakk>t1 \<approx>1 t2; s1 \<approx>1 s2\<rbrakk> \<Longrightarrow> rAp1 t1 s1 \<approx>1 rAp1 t2 s2"
| a3: "(\<exists>pi. (({atom aa}, t) \<approx>gen alpha1 rfv_trm1 pi ({atom ab}, s))) \<Longrightarrow> rLm1 aa t \<approx>1 rLm1 ab s"
| a4: "t1 \<approx>1 t2 \<Longrightarrow> (\<exists>pi. (((bv1 b1), s1) \<approx>gen alpha1 rfv_trm1 pi ((bv1 b2), s2))) \<Longrightarrow> rLt1 b1 t1 s1 \<approx>1 rLt1 b2 t2 s2"

lemma alpha1_inj:
"(rVr1 a \<approx>1 rVr1 b) = (a = b)"
"(rAp1 t1 s1 \<approx>1 rAp1 t2 s2) = (t1 \<approx>1 t2 \<and> s1 \<approx>1 s2)"
"(rLm1 aa t \<approx>1 rLm1 ab s) = (\<exists>pi. (({atom aa}, t) \<approx>gen alpha1 rfv_trm1 pi ({atom ab}, s)))"
"(rLt1 b1 t1 s1 \<approx>1 rLt1 b2 t2 s2) = (t1 \<approx>1 t2 \<and> (\<exists>pi. (((bv1 b1), s1) \<approx>gen alpha1 rfv_trm1 pi ((bv1 b2), s2))))"
apply -
apply rule apply (erule alpha1.cases) apply (simp_all add: alpha1.intros)
apply rule apply (erule alpha1.cases) apply (simp_all add: alpha1.intros)
apply rule apply (erule alpha1.cases) apply (simp_all add: alpha1.intros)
apply rule apply (erule alpha1.cases) apply (simp_all add: alpha1.intros)
done

(* Shouyld we derive it? But bv is given by the user? *)
lemma bv1_eqvt[eqvt]:
  shows "(pi \<bullet> bv1 x) = bv1 (pi \<bullet> x)"
  apply (induct x)
apply (simp_all add: empty_eqvt insert_eqvt atom_eqvt)
done

lemma rfv_trm1_eqvt[eqvt]:
  shows "(pi\<bullet>rfv_trm1 t) = rfv_trm1 (pi\<bullet>t)"
  apply (induct t)
  apply (simp_all add: insert_eqvt atom_eqvt empty_eqvt union_eqvt Diff_eqvt bv1_eqvt)
  done


lemma alpha1_eqvt:
  shows "t \<approx>1 s \<Longrightarrow> (pi \<bullet> t) \<approx>1 (pi \<bullet> s)"
  apply (induct t s rule: alpha1.inducts)
  apply (simp_all add:eqvts alpha1_inj)
  apply (erule exE)
  apply (rule_tac x="pi \<bullet> pia" in exI)
  apply (simp add: alpha_gen)
  apply(erule conjE)+
  apply(rule conjI)
  apply(rule_tac ?p1="- pi" in permute_eq_iff[THEN iffD1])
  apply(simp add: atom_eqvt Diff_eqvt insert_eqvt empty_eqvt rfv_trm1_eqvt)
  apply(rule conjI)
  apply(rule_tac ?p1="- pi" in fresh_star_permute_iff[THEN iffD1])
  apply(simp add: atom_eqvt Diff_eqvt rfv_trm1_eqvt insert_eqvt empty_eqvt)
  apply(simp add: permute_eqvt[symmetric])
  apply (erule exE)
  apply (rule_tac x="pi \<bullet> pia" in exI)
  apply (simp add: alpha_gen)
  apply(erule conjE)+
  apply(rule conjI)
  apply(rule_tac ?p1="- pi" in permute_eq_iff[THEN iffD1])
  apply(simp add: rfv_trm1_eqvt Diff_eqvt bv1_eqvt)
  apply(rule conjI)
  apply(rule_tac ?p1="- pi" in fresh_star_permute_iff[THEN iffD1])
  apply(simp add: atom_eqvt rfv_trm1_eqvt Diff_eqvt bv1_eqvt)
  apply(simp add: permute_eqvt[symmetric])
  done

lemma alpha1_equivp: "equivp alpha1" 
  sorry

quotient_type trm1 = rtrm1 / alpha1
  by (rule alpha1_equivp)

quotient_definition
  "Vr1 :: name \<Rightarrow> trm1"
as
  "rVr1"

quotient_definition
  "Ap1 :: trm1 \<Rightarrow> trm1 \<Rightarrow> trm1"
as
  "rAp1"

quotient_definition
  "Lm1 :: name \<Rightarrow> trm1 \<Rightarrow> trm1"
as
  "rLm1"

quotient_definition
  "Lt1 :: bp \<Rightarrow> trm1 \<Rightarrow> trm1 \<Rightarrow> trm1"
as
  "rLt1"

quotient_definition
  "fv_trm1 :: trm1 \<Rightarrow> atom set"
as
  "rfv_trm1"

lemma alpha_rfv1:
  shows "t \<approx>1 s \<Longrightarrow> rfv_trm1 t = rfv_trm1 s"
  apply(induct rule: alpha1.induct)
  apply(simp_all add: alpha_gen.simps)
  done

lemma [quot_respect]:
 "(op = ===> alpha1) rVr1 rVr1"
 "(alpha1 ===> alpha1 ===> alpha1) rAp1 rAp1"
 "(op = ===> alpha1 ===> alpha1) rLm1 rLm1"
 "(op = ===> alpha1 ===> alpha1 ===> alpha1) rLt1 rLt1"
apply (auto intro: alpha1.intros)
apply(rule a3) apply (rule_tac x="0" in exI)
apply (simp add: fresh_star_def fresh_zero_perm alpha_rfv1 alpha_gen)
apply(rule a4) apply assumption apply (rule_tac x="0" in exI)
apply (simp add: fresh_star_def fresh_zero_perm alpha_rfv1 alpha_gen)
done

lemma [quot_respect]:
  "(op = ===> alpha1 ===> alpha1) permute permute"
apply auto
apply (rule alpha1_eqvt)
apply simp
done

lemma [quot_respect]:
  "(alpha1 ===> op =) rfv_trm1 rfv_trm1"
apply (simp add: alpha_rfv1)
done

lemma trm1_bp_induct: "
\<lbrakk>\<And>name. P1 (Vr1 name);
 \<And>rtrm11 rtrm12. \<lbrakk>P1 rtrm11; P1 rtrm12\<rbrakk> \<Longrightarrow> P1 (Ap1 rtrm11 rtrm12);
 \<And>name rtrm1. P1 rtrm1 \<Longrightarrow> P1 (Lm1 name rtrm1);
 \<And>bp rtrm11 rtrm12.
    \<lbrakk>P2 bp; P1 rtrm11; P1 rtrm12\<rbrakk> \<Longrightarrow> P1 (Lt1 bp rtrm11 rtrm12);
 P2 BUnit; \<And>name. P2 (BVr name);
 \<And>bp1 bp2. \<lbrakk>P2 bp1; P2 bp2\<rbrakk> \<Longrightarrow> P2 (BPr bp1 bp2)\<rbrakk>
\<Longrightarrow> P1 rtrma \<and> P2 bpa"
apply (lifting rtrm1_bp.induct)
done

lemma trm1_bp_inducts: "
\<lbrakk>\<And>name. P1 (Vr1 name);
 \<And>rtrm11 rtrm12. \<lbrakk>P1 rtrm11; P1 rtrm12\<rbrakk> \<Longrightarrow> P1 (Ap1 rtrm11 rtrm12);
 \<And>name rtrm1. P1 rtrm1 \<Longrightarrow> P1 (Lm1 name rtrm1);
 \<And>bp rtrm11 rtrm12.
    \<lbrakk>P2 bp; P1 rtrm11; P1 rtrm12\<rbrakk> \<Longrightarrow> P1 (Lt1 bp rtrm11 rtrm12);
 P2 BUnit; \<And>name. P2 (BVr name);
 \<And>bp1 bp2. \<lbrakk>P2 bp1; P2 bp2\<rbrakk> \<Longrightarrow> P2 (BPr bp1 bp2)\<rbrakk>
\<Longrightarrow> P1 rtrma"
"\<lbrakk>\<And>name. P1 (Vr1 name);
 \<And>rtrm11 rtrm12. \<lbrakk>P1 rtrm11; P1 rtrm12\<rbrakk> \<Longrightarrow> P1 (Ap1 rtrm11 rtrm12);
 \<And>name rtrm1. P1 rtrm1 \<Longrightarrow> P1 (Lm1 name rtrm1);
 \<And>bp rtrm11 rtrm12.
    \<lbrakk>P2 bp; P1 rtrm11; P1 rtrm12\<rbrakk> \<Longrightarrow> P1 (Lt1 bp rtrm11 rtrm12);
 P2 BUnit; \<And>name. P2 (BVr name);
 \<And>bp1 bp2. \<lbrakk>P2 bp1; P2 bp2\<rbrakk> \<Longrightarrow> P2 (BPr bp1 bp2)\<rbrakk>
\<Longrightarrow> P2 bpa"
by (lifting rtrm1_bp.inducts)

instantiation trm1 and bp :: pt
begin

quotient_definition
  "permute_trm1 :: perm \<Rightarrow> trm1 \<Rightarrow> trm1"
as
  "permute :: perm \<Rightarrow> rtrm1 \<Rightarrow> rtrm1"

lemma permute_trm1 [simp]:
  shows "pi \<bullet> Vr1 a = Vr1 (pi \<bullet> a)"
  and   "pi \<bullet> Ap1 t1 t2 = Ap1 (pi \<bullet> t1) (pi \<bullet> t2)"
  and   "pi \<bullet> Lm1 a t = Lm1 (pi \<bullet> a) (pi \<bullet> t)"
  and   "pi \<bullet> Lt1 b t s = Lt1 (pi \<bullet> b) (pi \<bullet> t) (pi \<bullet> s)"
apply -
apply(lifting permute_rtrm1_permute_bp.simps(1))
apply(lifting permute_rtrm1_permute_bp.simps(2))
apply(lifting permute_rtrm1_permute_bp.simps(3))
apply(lifting permute_rtrm1_permute_bp.simps(4))
done
instance
apply default
apply(induct_tac [!] x rule: trm1_bp_inducts(1))
apply(simp_all)
done

end

lemma fv_trm1:
"fv_trm1 (Vr1 x) = {atom x}"
"fv_trm1 (Ap1 t1 t2) = fv_trm1 t1 \<union> fv_trm1 t2"
"fv_trm1 (Lm1 x t) = fv_trm1 t - {atom x}"
"fv_trm1 (Lt1 bp t1 t2) = fv_trm1 t1 \<union> (fv_trm1 t2 - bv1 bp)"
apply -
apply (lifting rfv_trm1_rfv_bp.simps(1))
apply (lifting rfv_trm1_rfv_bp.simps(2))
apply (lifting rfv_trm1_rfv_bp.simps(3))
apply (lifting rfv_trm1_rfv_bp.simps(4))
done

lemma fv_trm1_eqvt:
  shows "(p \<bullet> fv_trm1 t) = fv_trm1 (p \<bullet> t)"
apply(lifting rfv_trm1_eqvt)
done

lemma alpha1_INJ:
"(Vr1 a = Vr1 b) = (a = b)"
"(Ap1 t1 s1 = Ap1 t2 s2) = (t1 = t2 \<and> s1 = s2)"
"(Lm1 aa t = Lm1 ab s) = (\<exists>pi. (({atom aa}, t) \<approx>gen (op =) fv_trm1 pi ({atom ab}, s)))"
"(Lt1 b1 t1 s1 = Lt1 b2 t2 s2) = (t1 = t2 \<and> (\<exists>pi. (((bv1 b1), s1) \<approx>gen (op =) fv_trm1 pi ((bv1 b2), s2))))"
unfolding alpha_gen apply (lifting alpha1_inj[unfolded alpha_gen])
done

lemma lm1_supp_pre:
  shows "(supp (atom x, t)) supports (Lm1 x t) "
apply(simp add: supports_def)
apply(fold fresh_def)
apply(simp add: fresh_Pair swap_fresh_fresh)
apply(clarify)
apply(subst swap_at_base_simps(3))
apply(simp_all add: fresh_atom)
done

lemma lt1_supp_pre:
  shows "(supp (x, t, s)) supports (Lt1 t x s) "
apply(simp add: supports_def)
apply(fold fresh_def)
apply(simp add: fresh_Pair swap_fresh_fresh)
done

lemma bp_supp: "finite (supp (bp :: bp))"
  apply (induct bp)
  apply(simp_all add: supp_def)
  apply (fold supp_def)
  apply (simp add: supp_at_base)
  apply(simp add: Collect_imp_eq)
  apply(simp add: Collect_neg_eq[symmetric])
  apply (fold supp_def)
  apply (simp)
  done

instance trm1 :: fs
apply default
apply(induct_tac x rule: trm1_bp_inducts(1))
apply(simp_all)
apply(simp add: supp_def alpha1_INJ eqvts)
apply(simp add: supp_def[symmetric] supp_at_base)
apply(simp only: supp_def alpha1_INJ eqvts permute_trm1)
apply(simp add: Collect_imp_eq Collect_neg_eq)
apply(rule supports_finite)
apply(rule lm1_supp_pre)
apply(simp add: supp_Pair supp_atom)
apply(rule supports_finite)
apply(rule lt1_supp_pre)
apply(simp add: supp_Pair supp_atom bp_supp)
done

lemma supp_fv:
  shows "supp t = fv_trm1 t"
apply(induct t rule: trm1_bp_inducts(1))
apply(simp_all)
apply(simp add: supp_def permute_trm1 alpha1_INJ fv_trm1)
apply(simp only: supp_at_base[simplified supp_def])
apply(simp add: supp_def permute_trm1 alpha1_INJ fv_trm1)
apply(simp add: Collect_imp_eq Collect_neg_eq)
apply(subgoal_tac "supp (Lm1 name rtrm1) = supp (Abs {atom name} rtrm1)")
apply(simp add: supp_Abs fv_trm1)
apply(simp (no_asm) add: supp_def permute_set_eq atom_eqvt)
apply(simp add: alpha1_INJ)
apply(simp add: Abs_eq_iff)
apply(simp add: alpha_gen.simps)
apply(simp add: supp_eqvt[symmetric] fv_trm1_eqvt[symmetric])
apply(subgoal_tac "supp (Lt1 bp rtrm11 rtrm12) = supp(rtrm11) \<union> supp (Abs (bv1 bp) rtrm12)")
apply(simp add: supp_Abs fv_trm1)
apply(simp (no_asm) add: supp_def)
apply(simp add: alpha1_INJ)
apply(simp add: Abs_eq_iff)
apply(simp add: alpha_gen)
apply(simp add: supp_eqvt[symmetric] fv_trm1_eqvt[symmetric] bv1_eqvt)
apply(simp add: Collect_imp_eq Collect_neg_eq)
done

lemma trm1_supp:
  "supp (Vr1 x) = {atom x}"
  "supp (Ap1 t1 t2) = supp t1 \<union> supp t2"
  "supp (Lm1 x t) = (supp t) - {atom x}"
  "supp (Lt1 b t s) = supp t \<union> (supp s - bv1 b)"
  by (simp_all only: supp_fv fv_trm1)

lemma trm1_induct_strong:
  assumes "\<And>name b. P b (Vr1 name)"
  and     "\<And>rtrm11 rtrm12 b. \<lbrakk>\<And>c. P c rtrm11; \<And>c. P c rtrm12\<rbrakk> \<Longrightarrow> P b (Ap1 rtrm11 rtrm12)"
  and     "\<And>name rtrm1 b. \<lbrakk>\<And>c. P c rtrm1; (atom name) \<sharp> b\<rbrakk> \<Longrightarrow> P b (Lm1 name rtrm1)"
  and     "\<And>bp rtrm11 rtrm12 b. \<lbrakk>\<And>c. P c rtrm11; \<And>c. P c rtrm12; bp1 bp \<sharp>* b\<rbrakk> \<Longrightarrow> P b (Lt1 bp rtrm11 rtrm12)"
  shows   "P a rtrma"
sorry

section {*** lets with single assignments ***}

datatype trm2 =
  Vr2 "name"
| Ap2 "trm2" "trm2"
| Lm2 "name" "trm2"
| Lt2 "assign" "trm2"
and assign =
  As "name" "trm2"

(* to be given by the user *)
primrec 
  bv2
where
  "bv2 (As x t) = {atom x}"

(* needs to be calculated by the package *)
primrec
  fv_trm2 and fv_assign
where
  "fv_trm2 (Vr2 x) = {atom x}"
| "fv_trm2 (Ap2 t1 t2) = (fv_trm2 t1) \<union> (fv_trm2 t2)"
| "fv_trm2 (Lm2 x t) = (fv_trm2 t) - {atom x}"
| "fv_trm2 (Lt2 as t) = (fv_trm2 t - bv2 as) \<union> (fv_assign as)"
| "fv_assign (As x t) = (fv_trm2 t)"

(* needs to be stated by the package *)
instantiation 
  trm2 and assign :: pt
begin

primrec
  permute_trm2 and permute_assign
where
  "permute_trm2 pi (Vr2 a) = Vr2 (pi \<bullet> a)"
| "permute_trm2 pi (Ap2 t1 t2) = Ap2 (permute_trm2 pi t1) (permute_trm2 pi t2)"
| "permute_trm2 pi (Lm2 a t) = Lm2 (pi \<bullet> a) (permute_trm2 pi t)"
| "permute_trm2 pi (Lt2 as t) = Lt2 (permute_assign pi as) (permute_trm2 pi t)"
| "permute_assign pi (As a t) = As (pi \<bullet> a) (permute_trm2 pi t)"

lemma pt_trm2_assign_zero:
  fixes t::trm2
  and   b::assign
  shows "0 \<bullet> t = t"
  and   "0 \<bullet> b = b"
apply(induct t and b rule: trm2_assign.inducts)
apply(simp_all)
done

lemma pt_trm2_assign_plus:
  fixes t::trm2
  and   b::assign
  shows "((p + q) \<bullet> t) = p \<bullet> (q \<bullet> t)"
  and   "((p + q) \<bullet> b) = p \<bullet> (q \<bullet> b)"
apply(induct t and b rule: trm2_assign.inducts)
apply(simp_all)
done

instance
apply default
apply(simp_all add: pt_trm2_assign_zero pt_trm2_assign_plus)
done


end

inductive
  alpha2 :: "trm2 \<Rightarrow> trm2 \<Rightarrow> bool" ("_ \<approx>2 _" [100, 100] 100)
where
  a1: "a = b \<Longrightarrow> (Vr2 a) \<approx>2 (Vr2 b)"
| a2: "\<lbrakk>t1 \<approx>2 t2; s1 \<approx>2 s2\<rbrakk> \<Longrightarrow> Ap2 t1 s1 \<approx>2 Ap2 t2 s2"
| a3: "\<exists>pi. (fv_trm2 t - {atom a} = fv_trm2 s - {atom b} \<and> 
            (fv_trm2 t - {atom a})\<sharp>* pi \<and> 
            (pi \<bullet> t) \<approx>2 s \<and> 
            (pi \<bullet> a) = b)
       \<Longrightarrow> Lm2 a t \<approx>2 Lm2 b s"
| a4: "\<exists>pi. (
         fv_trm2 t1 - fv_assign b1 = fv_trm2 t2 - fv_assign b2 \<and>
         (fv_trm2 t1 - fv_assign b1) \<sharp>* pi \<and>
         pi \<bullet> t1 = t2       (* \<and> (pi \<bullet> b1 = b2) *)
       ) \<Longrightarrow> Lt2 b1 t1 \<approx>2 Lt2 b2 t2"

lemma alpha2_equivp: "equivp alpha2" 
  sorry

quotient_type qtrm2 = trm2 / alpha2
  by (rule alpha2_equivp)

section {*** lets with many assignments ***}

datatype trm3 =
  Vr3 "name"
| Ap3 "trm3" "trm3"
| Lm3 "name" "trm3"
| Lt3 "assigns" "trm3"
and assigns =
  ANil
| ACons "name" "trm3" "assigns"

(* to be given by the user *)
primrec 
  bv3
where
  "bv3 ANil = {}"
| "bv3 (ACons x t as) = {atom x} \<union> (bv3 as)"

primrec
  fv_trm3 and fv_assigns
where
  "fv_trm3 (Vr3 x) = {atom x}"
| "fv_trm3 (Ap3 t1 t2) = (fv_trm3 t1) \<union> (fv_trm3 t2)"
| "fv_trm3 (Lm3 x t) = (fv_trm3 t) - {atom x}"
| "fv_trm3 (Lt3 as t) = (fv_trm3 t - bv3 as) \<union> (fv_assigns as)"
| "fv_assigns (ANil) = {}"
| "fv_assigns (ACons x t as) = (fv_trm3 t) \<union> (fv_assigns as)"

(* needs to be stated by the package *)
instantiation
 trm3 and assigns :: pt
begin

primrec
  permute_trm3 and permute_assigns
where
  "permute_trm3 pi (Vr3 a) = Vr3 (pi \<bullet> a)"
| "permute_trm3 pi (Ap3 t1 t2) = Ap3 (permute_trm3 pi t1) (permute_trm3 pi t2)"
| "permute_trm3 pi (Lm3 a t) = Lm3 (pi \<bullet> a) (permute_trm3 pi t)"
| "permute_trm3 pi (Lt3 as t) = Lt3 (permute_assigns pi as) (permute_trm3 pi t)"
| "permute_assigns pi (ANil) = ANil"
| "permute_assigns pi (ACons a t as) = ACons (pi \<bullet> a) (permute_trm3 pi t) (permute_assigns pi as)"

lemma pt_trm3_assigns_zero:
  fixes t::trm3
  and   b::assigns
  shows "0 \<bullet> t = t"
  and   "0 \<bullet> b = b"
apply(induct t and b rule: trm3_assigns.inducts)
apply(simp_all)
done

lemma pt_trm3_assigns_plus:
  fixes t::trm3
  and   b::assigns
  shows "((p + q) \<bullet> t) = p \<bullet> (q \<bullet> t)"
  and   "((p + q) \<bullet> b) = p \<bullet> (q \<bullet> b)"
apply(induct t and b rule: trm3_assigns.inducts)
apply(simp_all)
done

instance
apply default
apply(simp_all add: pt_trm3_assigns_zero pt_trm3_assigns_plus)
done


end

inductive
  alpha3 :: "trm3 \<Rightarrow> trm3 \<Rightarrow> bool" ("_ \<approx>3 _" [100, 100] 100)
where
  a1: "a = b \<Longrightarrow> (Vr3 a) \<approx>3 (Vr3 b)"
| a2: "\<lbrakk>t1 \<approx>3 t2; s1 \<approx>3 s2\<rbrakk> \<Longrightarrow> Ap3 t1 s1 \<approx>3 Ap3 t2 s2"
| a3: "\<exists>pi. (fv_trm3 t - {atom a} = fv_trm3 s - {atom b} \<and> 
             (fv_trm3 t - {atom a})\<sharp>* pi \<and> 
             (pi \<bullet> t) \<approx>3 s \<and> 
             (pi \<bullet> a) = b)
       \<Longrightarrow> Lm3 a t \<approx>3 Lm3 b s"
| a4: "\<exists>pi. (
         fv_trm3 t1 - fv_assigns b1 = fv_trm3 t2 - fv_assigns b2 \<and>
         (fv_trm3 t1 - fv_assigns b1) \<sharp>* pi \<and>
         pi \<bullet> t1 = t2      (* \<and> (pi \<bullet> b1 = b2)  *)
       ) \<Longrightarrow> Lt3 b1 t1 \<approx>3 Lt3 b2 t2"

lemma alpha3_equivp: "equivp alpha3" 
  sorry

quotient_type qtrm3 = trm3 / alpha3
  by (rule alpha3_equivp)


section {*** lam with indirect list recursion ***}

datatype trm4 =
  Vr4 "name"
| Ap4 "trm4" "trm4 list"
| Lm4 "name" "trm4"

thm trm4.recs

primrec
  fv_trm4 and fv_trm4_list
where
  "fv_trm4 (Vr4 x) = {atom x}"
| "fv_trm4 (Ap4 t ts) = (fv_trm4 t) \<union> (fv_trm4_list ts)"
| "fv_trm4 (Lm4 x t) = (fv_trm4 t) - {atom x}"
| "fv_trm4_list ([]) = {}"
| "fv_trm4_list (t#ts) = (fv_trm4 t) \<union> (fv_trm4_list ts)"


(* needs to be stated by the package *)
(* there cannot be a clause for lists, as *) 
(* permuteutations are  already defined in Nominal (also functions, options, and so on) *)
instantiation
  trm4 :: pt
begin

(* does not work yet *)
primrec
  permute_trm4  and permute_trm4_list
where
  "permute_trm4 pi (Vr4 a) = Vr4 (pi \<bullet> a)"
| "permute_trm4 pi (Ap4 t ts) = Ap4 (permute_trm4 pi t) (permute_trm4_list pi ts)"
| "permute_trm4 pi (Lm4 a t) = Lm4 (pi \<bullet> a) (permute_trm4 pi t)"
| "permute_trm4_list pi ([]) = []"
| "permute_trm4_list pi (t#ts) = (permute_trm4 pi t) # (permute_trm4_list pi ts)"

lemma pt_trm4_list_zero:
  fixes t::trm4
  and   ts::"trm4 list"
  shows "0 \<bullet> t = t"
  and   "permute_trm4_list 0 ts = ts"
apply(induct t and ts rule: trm4.inducts)
apply(simp_all)
done

lemma pt_trm4_list_plus:
  fixes t::trm4
  and   ts::"trm4 list"
  shows "((p + q) \<bullet> t) = p \<bullet> (q \<bullet> t)"
  and   "(permute_trm4_list (p + q) ts) = permute_trm4_list p (permute_trm4_list q ts)"
apply(induct t and ts rule: trm4.inducts)
apply(simp_all)
done


instance
apply(default)
apply(simp_all add: pt_trm4_list_zero pt_trm4_list_plus)
done

end

(* "repairing" of the permute function *)
lemma repaired:
  fixes ts::"trm4 list"
  shows "permute_trm4_list p ts = p \<bullet> ts"
  apply(induct ts)
  apply(simp_all)
  done

thm permute_trm4_permute_trm4_list.simps
thm permute_trm4_permute_trm4_list.simps[simplified repaired]

inductive
    alpha4 :: "trm4 \<Rightarrow> trm4 \<Rightarrow> bool" ("_ \<approx>4 _" [100, 100] 100)
and alpha4list :: "trm4 list \<Rightarrow> trm4 list \<Rightarrow> bool" ("_ \<approx>4list _" [100, 100] 100) 
where
  a1: "a = b \<Longrightarrow> (Vr4 a) \<approx>4 (Vr4 b)"
| a2: "\<lbrakk>t1 \<approx>4 t2; s1 \<approx>4list s2\<rbrakk> \<Longrightarrow> Ap4 t1 s1 \<approx>4 Ap4 t2 s2"
| a4: "\<exists>pi. (fv_trm4 t - {atom a} = fv_trm4 s - {atom b} \<and> 
            (fv_trm4 t - {atom a})\<sharp>* pi \<and> 
            (pi \<bullet> t) \<approx>4 s \<and> 
            (pi \<bullet> a) = b)
       \<Longrightarrow> Lm4 a t \<approx>4 Lm4 b s"
| a5: "[] \<approx>4list []"
| a6: "\<lbrakk>t \<approx>4 s; ts \<approx>4list ss\<rbrakk> \<Longrightarrow> (t#ts) \<approx>4list (s#ss)"

lemma alpha4_equivp: "equivp alpha4" sorry
lemma alpha4list_equivp: "equivp alpha4list" sorry

quotient_type 
  qtrm4 = trm4 / alpha4 and
  qtrm4list = "trm4 list" / alpha4list
  by (simp_all add: alpha4_equivp alpha4list_equivp)


datatype rtrm5 =
  rVr5 "name"
| rAp5 "rtrm5" "rtrm5"
| rLt5 "rlts" "rtrm5"
and rlts =
  rLnil
| rLcons "name" "rtrm5" "rlts"

primrec
  bv5
where
  "bv5 rLnil = {}"
| "bv5 (rLcons n t ltl) = {atom n} \<union> (bv5 ltl)"

primrec
  rfv_trm5 and rfv_lts
where
  "rfv_trm5 (rVr5 n) = {atom n}"
| "rfv_trm5 (rAp5 t s) = (rfv_trm5 t) \<union> (rfv_trm5 s)"
| "rfv_trm5 (rLt5 lts t) = (rfv_trm5 t - bv5 lts) \<union> (rfv_lts lts - bv5 lts)"
| "rfv_lts (rLnil) = {}"
| "rfv_lts (rLcons n t ltl) = (rfv_trm5 t) \<union> (rfv_lts ltl)"

instantiation
  rtrm5 and rlts :: pt
begin

primrec
  permute_rtrm5 and permute_rlts
where
  "permute_rtrm5 pi (rVr5 a) = rVr5 (pi \<bullet> a)"
| "permute_rtrm5 pi (rAp5 t1 t2) = rAp5 (permute_rtrm5 pi t1) (permute_rtrm5 pi t2)"
| "permute_rtrm5 pi (rLt5 as t) = rLt5 (permute_rlts pi as) (permute_rtrm5 pi t)"
| "permute_rlts pi (rLnil) = rLnil"
| "permute_rlts pi (rLcons n t ls) = rLcons (pi \<bullet> n) (permute_rtrm5 pi t) (permute_rlts pi ls)"

lemma pt_rtrm5_zero:
  fixes t::rtrm5
  and   l::rlts
  shows "0 \<bullet> t = t"
  and   "0 \<bullet> l = l"
apply(induct t and l rule: rtrm5_rlts.inducts)
apply(simp_all)
done

lemma pt_rtrm5_plus:
  fixes t::rtrm5
  and   l::rlts
  shows "((p + q) \<bullet> t) = p \<bullet> (q \<bullet> t)"
  and   "((p + q) \<bullet> l) = p \<bullet> (q \<bullet> l)"
apply(induct t and l rule: rtrm5_rlts.inducts)
apply(simp_all)
done

instance
apply default
apply(simp_all add: pt_rtrm5_zero pt_rtrm5_plus)
done

end

inductive
  alpha5 :: "rtrm5 \<Rightarrow> rtrm5 \<Rightarrow> bool" ("_ \<approx>5 _" [100, 100] 100)
and
  alphalts :: "rlts \<Rightarrow> rlts \<Rightarrow> bool" ("_ \<approx>l _" [100, 100] 100)
where
  a1: "a = b \<Longrightarrow> (rVr5 a) \<approx>5 (rVr5 b)"
| a2: "\<lbrakk>t1 \<approx>5 t2; s1 \<approx>5 s2\<rbrakk> \<Longrightarrow> rAp5 t1 s1 \<approx>5 rAp5 t2 s2"
| a3: "\<exists>pi. ((bv5 l1, t1) \<approx>gen alpha5 rfv_trm5 pi (bv5 l2, t2) \<and>
             (bv5 l1, l1) \<approx>gen alphalts rfv_lts pi (bv5 l2, l2) \<and>
              (pi \<bullet> (bv5 l1) = bv5 l2))
        \<Longrightarrow> rLt5 l1 t1 \<approx>5 rLt5 l2 t2"
| a4: "rLnil \<approx>l rLnil"
| a5: "ls1 \<approx>l ls2 \<Longrightarrow> t1 \<approx>5 t2 \<Longrightarrow> n1 = n2 \<Longrightarrow> rLcons n1 t1 ls1 \<approx>l rLcons n2 t2 ls2"

print_theorems

lemma alpha5_inj:
  "((rVr5 a) \<approx>5 (rVr5 b)) = (a = b)"
  "(rAp5 t1 s1 \<approx>5 rAp5 t2 s2) = (t1 \<approx>5 t2 \<and> s1 \<approx>5 s2)"
  "(rLt5 l1 t1 \<approx>5 rLt5 l2 t2) = (\<exists>pi. ((bv5 l1, t1) \<approx>gen alpha5 rfv_trm5 pi (bv5 l2, t2) \<and>
         (bv5 l1, l1) \<approx>gen alphalts rfv_lts pi (bv5 l2, l2) \<and>
         (pi \<bullet> (bv5 l1) = bv5 l2)))"
  "rLnil \<approx>l rLnil"
  "(rLcons n1 t1 ls1 \<approx>l rLcons n2 t2 ls2) = (ls1 \<approx>l ls2 \<and> t1 \<approx>5 t2 \<and> n1 = n2)"
apply -
apply (simp_all add: alpha5_alphalts.intros)
apply rule
apply (erule alpha5.cases)
apply (simp_all add: alpha5_alphalts.intros)
apply rule
apply (erule alpha5.cases)
apply (simp_all add: alpha5_alphalts.intros)
apply rule
apply (erule alpha5.cases)
apply (simp_all add: alpha5_alphalts.intros)
apply rule
apply (erule alphalts.cases)
apply (simp_all add: alpha5_alphalts.intros)
done

lemma alpha5_equivps:
  shows "equivp alpha5"
  and   "equivp alphalts"
sorry

quotient_type
  trm5 = rtrm5 / alpha5
and
  lts = rlts / alphalts
  by (auto intro: alpha5_equivps)

text {* type schemes *} 
datatype ty = 
  Var "name" 
| Fun "ty" "ty"

instantiation
  ty :: pt
begin

primrec
  permute_ty 
where
  "permute_ty pi (Var a) = Var (pi \<bullet> a)"
| "permute_ty pi (Fun T1 T2) = Fun (permute_ty pi T1) (permute_ty pi T2)"

lemma pt_ty_zero:
  fixes T::ty
  shows "0 \<bullet> T = T"
apply(induct T rule: ty.inducts)
apply(simp_all)
done

lemma pt_ty_plus:
  fixes T::ty
  shows "((p + q) \<bullet> T) = p \<bullet> (q \<bullet> T)"
apply(induct T rule: ty.inducts)
apply(simp_all)
done

instance
apply default
apply(simp_all add: pt_ty_zero pt_ty_plus)
done

end

datatype tyS = 
  All "name set" "ty" 

instantiation
  tyS :: pt
begin

primrec
  permute_tyS 
where
  "permute_tyS pi (All xs T) = All (pi \<bullet> xs) (pi \<bullet> T)"

lemma pt_tyS_zero:
  fixes T::tyS
  shows "0 \<bullet> T = T"
apply(induct T rule: tyS.inducts)
apply(simp_all)
done

lemma pt_tyS_plus:
  fixes T::tyS
  shows "((p + q) \<bullet> T) = p \<bullet> (q \<bullet> T)"
apply(induct T rule: tyS.inducts)
apply(simp_all)
done

instance
apply default
apply(simp_all add: pt_tyS_zero pt_tyS_plus)
done

end


abbreviation
  "atoms xs \<equiv> {atom x| x. x \<in> xs}"

primrec
  rfv_ty
where
  "rfv_ty (Var n) = {atom n}"
| "rfv_ty (Fun T1 T2) = (rfv_ty T1) \<union> (rfv_ty T2)"

primrec
  rfv_tyS
where 
  "rfv_tyS (All xs T) = (rfv_ty T - atoms xs)"

inductive
  alpha_tyS :: "tyS \<Rightarrow> tyS \<Rightarrow> bool" ("_ \<approx>tyS _" [100, 100] 100)
where
  a1: "\<exists>pi. ((atoms xs1, T1) \<approx>gen (op =) rfv_ty pi (atoms xs2, T2)) 
        \<Longrightarrow> All xs1 T1 \<approx>tyS All xs2 T2"

lemma
  shows "All {a, b} (Fun (Var a) (Var b)) \<approx>tyS All {b, a} (Fun (Var a) (Var b))"
  apply(rule a1)
  apply(simp add: alpha_gen)
  apply(rule_tac x="0::perm" in exI)
  apply(simp add: fresh_star_def)
  done

lemma
  shows "All {a, b} (Fun (Var a) (Var b)) \<approx>tyS All {a, b} (Fun (Var b) (Var a))"
  apply(rule a1)
  apply(simp add: alpha_gen)
  apply(rule_tac x="(atom a \<rightleftharpoons> atom b)" in exI)
  apply(simp add: fresh_star_def)
  done

lemma
  shows "All {a, b, c} (Fun (Var a) (Var b)) \<approx>tyS All {a, b} (Fun (Var a) (Var b))"
  apply(rule a1)
  apply(simp add: alpha_gen)
  apply(rule_tac x="0::perm" in exI)
  apply(simp add: fresh_star_def)
  done

lemma
  assumes a: "a \<noteq> b"
  shows "\<not>(All {a, b} (Fun (Var a) (Var b)) \<approx>tyS All {c} (Fun (Var c) (Var c)))"
  using a
  apply(clarify)
  apply(erule alpha_tyS.cases)
  apply(simp add: alpha_gen)
  apply(erule conjE)+
  apply(erule exE)
  apply(erule conjE)+
  apply(clarify)
  apply(simp)
  apply(simp add: fresh_star_def)
  apply(auto)
  done
  

end