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mm0.mm1
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import "peano_hex.mm1";
-- The sort modifiers 'pure', 'strict', 'provable', 'free'
--| `sPure : SortData -> Bool`
@_ def sPure (n: nat): wff = $ true (pi11 n) $;
--| `sStrict : SortData -> Bool`
@_ def sStrict (n: nat): wff = $ true (pi12 n) $;
--| `sProvable : SortData -> Bool`
@_ def sProvable (n: nat): wff = $ true (pi21 n) $;
--| `sFree : SortData -> Bool`
@_ def sFree (n: nat): wff = $ true (pi22 n) $;
-- A binder is either a bound variable with sort s, or a regular variable
-- with sort s and dependencies vs.
--| `PBound : SortID -> Binder`
@_ def PBound (s: nat): nat = $ b0 s $;
--| `PReg : SortID -> set VarID -> Binder`
@_ def PReg (s vs: nat): nat = $ b1 (s <> vs) $;
--| Get the sort of a binder.
--|
--| `binderSort : Binder -> SortID`
@_ def binderSort (x: nat): nat =
$ case (\ n, n) (\ n, fst n) @ x $;
pub theorem binderSortBound (s: nat): $ binderSort (PBound s) = s $ =
(named '(eqtr casel @ applame id));
pub theorem binderSortReg (s vs: nat): $ binderSort (PReg s vs) = s $ =
(named '(eqtr caser @ applame @ syl6eq fstpr fsteq));
theorem binderSort_leid (s: nat): $ binderSort bi <= bi $ =
'(eori
(mpbiri b0leid (leeqd (syl6eq binderSortBound binderSorteq) id))
(mpbiri (leb1tr fstleid)
(leeqd (syl6eq binderSortReg @ binderSorteqd @ syl6eqr (b1eq fstsnd) id) id)) b0orb1);
-- An s-expression, representing the terms and formulas. It can be either a
-- variable (v is a VarID) or an application of the term with TermID `f`
-- to arguments `x` (a list of s-expressions).
--| `SVar : VarID -> SExpr`
@_ def SVar (v: nat): nat = $ b0 v $;
--| `SApp : TermID -> list SExpr -> SExpr`
@_ def SApp (f x: nat): nat = $ b1 (f <> x) $;
theorem SApp_ltid: $ e IN es -> e < SApp f es $ =
'(rsyl lmemlt @ mpi (ltb1tr leprid2) lttr);
@_ local def SExprRec (V F: set): set =
$ \ e, srec (\ ih, case V (\\ f, \ x, F @ (f <> x <> map ih x)) @ size (Dom ih)) e $;
theorem SExprRec_val: $ SExprRec V F @ e =
case V (\\ f, \ x, F @ (f <> x <> map (SExprRec V F |` upto e) x)) @ e $ =
(named '(eqtr (applame sreceq2) @
! eqtr _ $ _ @ (lower (SExprRec V F |` _)) $ _ srecval @
applame @ appeqd
(caseeq2d @ slameqd @ lameqd @ appeq2d @ preq2d @
preq2d @ mapeq1d @ bi2 @ eqlower2 @ finlam finns)
sreclem));
theorem SExprRec_Var: $ SExprRec V F @ (SVar v) = V @ v $ =
(named '(eqtr SExprRec_val casel));
theorem SExprRec_App:
$ SExprRec V F @ (SApp f es) = F @ (f <> es <> map (SExprRec V F) es) $ =
(named '(eqtr SExprRec_val @ eqtr caser @
appslame @ applamed @ appeq2d @ preqd anl @ preqd anr @ syl6eq
(mapeqg @ mpbir allal @ !! ax_gen e @ syl resapp @ sylibr elupto SApp_ltid)
(mapeq2d anr)));
theorem indd_aux (G p: wff x) (e: $ x = b -> (p <-> q) $)
(h: $ G /\ a = b -> q $): $ G /\ a = b -> [a / x] p $ =
'(mpbird (syl6bb (sbe e) @ anwr sbeq1) h);
theorem SExpr_indd {x f es} (n) (px: wff x) (pv: wff v) (pe: wff f es)
(hn: $ x = n -> (px <-> pn) $)
(hv: $ x = SVar v -> (px <-> pv) $)
(he: $ x = SApp f es -> (px <-> pe) $)
(h1: $ G -> pv $) (h2: $ G /\ all {x | px} es -> pe $): $ G -> pn $ =
(focus
'(sylib (sbe hn) @ !! indstr z w sbeq1 sbeq1 _)
(split-sop '{
($SVar v$ => (indd_aux hv @ anwll h1)) +
($SApp f es$ => (indd_aux he @ sylan h2 anll @
sylibr (alleq1 cbvabs) @ sylibr allal @ sylc _ anr anlr))
})
'(alimd @ imim1d @ syl5 SApp_ltid @ bi2d lteq2));
-- The environment is composed of declarations, which come in a few types:
--| A `sort` declaration has an associated `SortData` with the sort modifiers.
--| Sorts are indexed by SortID and picked out by `getSD`.
--|
--| `DSort : SortID -> SortData -> Decl`
@_ def DSort (id sd: nat): nat = $ b0 (b0 (b0 (id <> sd))) $;
--| A `term` declaration has a list of binders, and a target type (a DepType,
--| which is a `(SortID, set VarID)` pair).
--| Terms are indexed by TermID and picked out by `getTerm`.
--|
--| `DTerm : TermID -> Ctx -> DepType -> Decl`
@_ def DTerm (id args ret: nat): nat = $ b0 (b0 (b1 (id <> args <> ret))) $;
--| An `axiom` declaration has a list of binders, a list of hypotheses,
--| and a consequent.
--|
--| Axioms are not indexed, they are simply found by statement.
--|
--| `DAxiom : Ctx -> list SExpr -> SExpr -> Decl`
@_ def DAxiom (args hs ret: nat): nat = $ b0 (b1 (args <> hs <> ret)) $;
--| A `def` declaration is the same as a `term` except it also has an optional
--| definition component which lists the sorts of the dummy variables and the
--| definition's expression.
--|
--| Defs are indexed by TermID and picked out by `getTerm`.
--|
--| `DDef : TermID -> Ctx -> DepType -> option (list SortID, SExpr) -> Decl`
@_ def DDef (id args ret def: nat): nat =
$ b1 (b0 (id <> args <> ret <> def)) $;
--| A `theorem` declaration is exactly the same structure as an `axiom`, but
--| the interpretation is different - theorems require proofs, while axioms are
--| added in the spec.
--|
--| Theorems are not indexed, they are simply found by statement.
--|
--| `DThm : Ctx -> list SExpr -> SExpr -> Decl`
@_ def DThm (vs hs ret: nat): nat = $ b1 (b1 (vs <> hs <> ret)) $;
--| This function extracts the `SortData` for a sort given by `SortID`.
--|
--| `getSD : Env -> SortID -> SortData -> Bool`
@_ def getSD (env id sd: nat): wff = $ DSort id sd IN env $;
--| This function gets the term and definition data for a term.
--|
--| `getTerm : Env -> TermID -> Ctx -> DepType -> option (list SortID, SExpr) -> Bool`
@_ def getTerm (env id a r v: nat): wff =
$ v = 0 /\ DTerm id a r IN env \/ DDef id a r v IN env $;
theorem getTerm_ltid: $ getTerm env x a r v -> x < env /\ a < env /\ r < env /\ v < env $ =
(focus
'(eor _ _)
(focus
'(imp @ syl5 (rsyl lmemlt @ lelttr @ leb0tr @ leb0tr b1leid) @
mpbiri _ (imeq2d @ aneq2d lteq1))
'(iand (iand (iand _ _) _) (lelttr le01))
'(lelttr leprid1)
'(lelttr @ lepr2tr leprid1)
'(lelttr @ lepr2tr leprid2))
(focus
'(rsyl lmemlt @ rsyl (lelttr @ leb1tr b0leid) _)
'(iand (iand (iand _ _) _) _)
'(lelttr leprid1)
'(lelttr @ lepr2tr leprid1)
'(lelttr @ lepr2tr @ lepr2tr leprid1)
'(lelttr @ lepr2tr @ lepr2tr leprid2)));
theorem getTerm_retltid: $ getTerm env x a r v -> r < env $ = '(rsyl getTerm_ltid anlr);
--| This function gets the data for an axiom or theorem.
--|
--| `getThm : Env -> Ctx -> list SExpr -> SExpr -> Bool`
@_ def getThm (env a h r: nat): wff =
$ DAxiom a h r IN env \/ DThm a h r IN env $;
--| Is this ID a valid sort?
--|
--| `isSort : Env -> SortID -> Bool`
@_ def isSort (env s .sd: nat): wff = $ E. sd getSD env s sd $;
--| Looks this variable up in the context, and reports whether it represents a
--| bound variable.
--|
--| `isBound : Ctx -> VarID -> Bool`
@_ def isBound (ctx x .s: nat): wff = $ E. s nth x ctx = suc (PBound s) $;
--| Checks if this a well formed dependent type in the context. A DepType is a
--| pair (SortID, set VarID) giving the sort and the variable dependencies.
--|
--| `DepType : Env -> Ctx -> DepType -> Bool`
@_ def DepType (env ctx ty .x: nat): wff =
$ isSort env (fst ty) /\ A. x (x e. snd ty -> isBound ctx x) $;
@_ local def Ctx_aux (env ctx: nat): nat =
$ rlrec 1 (\\ ctx2, \\ bi, \ ih, ih * nat (bi e. Sum
{s | E. sd (getSD env s sd /\ ~ sStrict sd)}
{svs | DepType env ctx2 svs})) ctx $;
theorem Ctx_aux0 (env: nat): $ Ctx_aux env 0 = 1 $ = (named 'rlrec0);
theorem Ctx_auxS (env: nat): $ Ctx_aux env (ctx |> bi) = Ctx_aux env ctx *
nat (bi e. Sum
{s | E. sd (getSD env s sd /\ ~ sStrict sd)}
{svs | DepType env ctx svs}) $ =
(named '(! eqtr _ $ _ @ (_ <> _ <> Ctx_aux env ctx) $ _ rlrecS @
appslame @ appslamed @ applamed @ muleqd anr @
nateqd @ eleqd anlr @ Sumeq2d @ abeqd @ DepTypeeq2d anll));
--| Checks if this a well formed context. A context can be extended with a bound
--| variable binder if the sort of the binder is not `strict`.
--| Note `Ctx = list Binder`.
--|
--| `Ctx : Env -> Ctx -> Bool`
@_ def Ctx (env ctx: nat): wff = $ true (Ctx_aux env ctx) $;
pub theorem Ctx0 (env: nat): $ Ctx env 0 $ = '(mpbir (trueeq Ctx_aux0) true1);
pub theorem CtxBound (env ctx s: nat) {sd: nat}: $ Ctx env (ctx |> PBound s) <->
Ctx env ctx /\ E. sd (getSD env s sd /\ ~ sStrict sd) $ =
(named '(bitr (trueeq Ctx_auxS) @ bitr truemul @ aneq2i @
bitr truenat @ bitr Suml @ elabe @ exeqd @ aneq1d getSDeq2));
pub theorem CtxReg (env ctx s vs: nat): $ Ctx env (ctx |> PReg s vs) <->
Ctx env ctx /\ DepType env ctx (s <> vs) $ =
(named '(bitr (trueeq Ctx_auxS) @ bitr truemul @ aneq2i @
bitr truenat @ bitr Sumr @ elabe DepTypeeq3));
@_ local def ExprBi_aux (env ctx e ih: nat): set = $ Sum
{s | E. v (e = SVar v /\ nth v ctx = suc (PBound s))}
{svs | fst svs e. ih} $;
@_ local def Expr_aux (env ctx: nat): set =
$ SExprRec
(\ v, lower {s | E. bi (nth v ctx = suc bi /\ binderSort bi = s)})
(\\ f, \\ xs, \ ih, lower {s | E. args E. ret E. o
(getTerm env f args ret o /\
zip xs ih <> args e. all2 (S\ x, ExprBi_aux env ctx (fst x) (snd x)) /\
s = fst ret)}) $;
theorem Expr_aux_Var: $ Expr_aux env ctx @ SVar v =
lower {s | E. bi (nth v ctx = suc bi /\ binderSort bi = s)} $ =
(named '(eqtr SExprRec_Var @ applame @
lowereqd @ abeqd @ exeqd @ aneq1d @ eqeq1d @ ntheq1));
theorem Expr_aux_App: $ Expr_aux env ctx @ SApp f es =
lower {s | E. args E. ret E. o
(getTerm env f args ret o /\
zip es (map (Expr_aux env ctx) es) <> args e. all2 (S\ x, ExprBi_aux env ctx (fst x) (snd x)) /\
s = fst ret)} $ =
(named '(eqtr SExprRec_App @
! appslame _ $_ <> map (Expr_aux _ _) _$ _ _ _ @ appslamed @ applamed @
lowereqd @ abeqd @ exeqd @ exeqd @ exeqd @ aneq1d @ aneqd
(getTermeq2d anll)
(eleq1d @ preq1d @ zipeqd anlr anr)));
--| These mutually recursive functions check if an expression `e` is well-typed
--| with sort `s`, and that `e` is well-typed and valid for entry into a binder
--| `bi`. The main difference is that for an expression to be valid for a
--| BV binder, the expression must itself be a bound variable.
--|
--| `Expr : Env -> Ctx -> SExpr -> SortID -> Bool`
@_ def Expr (env ctx e s: nat): wff = $ s e. Expr_aux env ctx @ e $;
--| `ExprBi : Env -> Ctx -> SExpr -> Binder -> Bool`
@_ def ExprBi (env ctx e bi: nat): wff =
$ bi e. ExprBi_aux env ctx e (Expr_aux env ctx @ e) $;
theorem ExprBi_aux_map:
$ zip es (map (Expr_aux env ctx) es) <> args e. all2 (S\ p, ExprBi_aux env ctx (fst p) (snd p)) <->
es <> args e. all2 (S\ x, {a | ExprBi env ctx x a}) $ =
(named @ focus
(def h '(bieqd (eleq1d preq2) (eleq1d preq2)))
'(eale ,h ,(induct '(listind) 'es _ _))
'(ax_gen @ bitr (eleq1 @ preq1 zip01) @ bitr4 all201 all201)
'(sylbi (cbval ,h) @ iald @
bitr4g (bitr (eleq1 @ preq1 @ eqtr (zipeq2 mapS) zipS) all2S1) all2S1 @
exeqd @ syl exeq @ alimi @ syl aneq2a @ exp @ aneqd (a1i _) anl)
'(bitr4 (elsabe @ sylbir (eqeq1 fstsnd) @ sylbi prth ,eqtac) @
elsabe @ eleq2d @ syl5eqs abid2 ,eqtac));
pub theorem ExprVar (env ctx v s: nat) {bi: nat}: $ Expr env ctx (SVar v) s <->
E. bi (nth v ctx = suc bi /\ binderSort bi = s) $ =
(named @ focus
'(bitr (elneq2 Expr_aux_Var) @ bitr (ellower @ subsnfin @ subsnss _ subsnsn) @
elabe @ exeqd @ aneq2d eqeq2)
'(mpbi ssab1 @ ax_gen @ eex @ sylibr elsn @ eqtr2d _ anr)
'(binderSorteqd @ syl6eq sucsub1 @ subeq1d anl));
pub theorem ExprApp (env ctx f xs s: nat) {args ret o x a: nat}:
$ Expr env ctx (SApp f xs) s <-> E. args E. ret E. o
(getTerm env f args ret o /\
xs <> args e. all2 (S\ x, {a | ExprBi env ctx x a}) /\
s = fst ret) $ =
(named @ focus
'(bitr (elneq2 Expr_aux_App) @ bitr (ellower @ finss _ ltfin) @
elabe @ exeqd @ exeqd @ exeqd @ aneqd (a1i @ aneq2i ExprBi_aux_map) eqeq1)
'(mpbi ssab @ ax_gen @ eex @ eex @ eex @ mpbird (lteq1d anr) @ anwll @
syl (lelttr fstleid) getTerm_retltid));
pub theorem ExprBiBound (env ctx e s: nat) {v: nat}:
$ ExprBi env ctx e (PBound s) <->
E. v (e = SVar v /\ nth v ctx = suc (PBound s)) $ =
(named '(bitr Suml @ elabe @ exeqd @ aneq2d @ eqeq2d @ suceqd @ PBoundeq));
pub theorem ExprBiReg (env ctx e s vs: nat):
$ ExprBi env ctx e (PReg s vs) <-> Expr env ctx e s $ =
(named '(bitr Sumr @ elabe @ eleq1d @ syl6eq fstpr fsteq));
--| Is this a type correct expression of provable type? This is used to
--| typecheck expressions appearing in hypotheses and conclusions of
--| axiom/theorem.
--|
--| `ExprProv : Env -> Ctx -> SExpr -> Bool`
@_ def ExprProv (env ctx e .s .sd: nat): wff =
$ E. s E. sd (Expr env ctx e s /\ getSD env s sd /\ sProvable sd) $;
--| A helper function to add dummy variables to the context.
--|
--| `appendDummies : Ctx -> list SortID -> Ctx`
@_ def appendDummies (ctx ds .d: nat): nat = $ ctx ++ map (\ d, PBound d) ds $;
@_ local def HasVar_aux (ctx: nat): set =
$ SExprRec
(\ u, lower {v | E. s nth u ctx = suc (PBound s) /\ u = v \/
E. s E. vs (nth u ctx = suc (PReg s vs) /\ v e. vs)})
(\\ f, \\ xs, \ ih, lower {v | E. s (s IN ih /\ v e. s)}) $;
--| Does this expression contain any occurrence of the variable `v`? This check
--| ignores bound variables, "metamath style". We use this stricter check for
--| verifying theorem applications.
--|
--| `HasVar : Ctx -> SExpr -> VarID -> Bool`
@_ def HasVar (ctx e v: nat): wff = $ v e. HasVar_aux ctx @ e $;
theorem HasVar_Var: $ HasVar ctx (SVar u) v <->
E. s nth u ctx = suc (PBound s) /\ u = v \/
E. s E. vs (nth u ctx = suc (PReg s vs) /\ v e. vs) $ =
(named @ focus
'(bitr (elneq2 @ eqtr SExprRec_Var @ applame @ lowereqd @ abeqd @
oreqd (aneqd (exeqd @ eqeq1d ntheq1) eqeq1) (exeqd @ exeqd @ aneq1d @ eqeq1d ntheq1)) @
bitr (ellower @ finss (mpbi ssab @ ax_gen _) ltfin) @
elabe @ oreqd (aneq2d eqeq2) (exeqd @ exeqd @ aneq2d eleq1))
'(eor
(mpbid (lteq1d anr) @ anwl @ eex @ syl (mpi lenleid ltletr) @
sylib nthne0 sucne0)
(eex @ eex @ lttrd (anwr ellt) @
anwl @ syl (lelttr @ leb1tr leprid2) @ syl lmemlt nthlmem)));
pub theorem HasVarBound (ctx u v s: nat):
$ nth u ctx = suc (PBound s) -> (HasVar ctx (SVar u) v <-> u = v) $ =
(named '(syl5bb HasVar_Var @ bitrd
(syl bior2 @ nexd @ nexd @ mpi b0neb1 @
con3d @ exp @ sylib peano2 @ eqtr3d anl anrl)
(syl bian1 @ iexe @ eqeq2d @ suceqd PBoundeq)));
pub theorem HasVarReg (ctx u v s vs: nat):
$ nth u ctx = suc (PReg s vs) -> (HasVar ctx (SVar u) v <-> v e. vs) $ =
(named '(syl5bb HasVar_Var @ bitrd
(syl bior1 @ syl (con3 anl) @ nexd @ mpi b0neb1 @ con3d @ exp @
sylib peano2 @ eqtr3d anr anl)
(syl6bb (exeqe biidd) @ exeqd @ syl6bb (exeqe @ aneq2d elneq2) @ exeqd @
syl6bb anlass @ syl6bb anass @ aneq1d @
syl6bb (bitr peano2 @ bitr b1can @ bitr eqcomb prth) eqeq1)));
pub theorem HasVarApp (ctx f es v: nat) {e: nat}:
$ HasVar ctx (SApp f es) v <-> E. e (e IN es /\ HasVar ctx e v) $ =
(named @ focus
'(bitr (elneq2 @ eqtr {SExprRec_App : $ _ = _ @ (_ <> _ <> map (HasVar_aux ctx) _) $} @
appslame @ appslamed @ applamed @ lowereqd @ abeqd @
exeqd @ aneq1d @ lmemeq2d anr) @
bitr (ellower @ finss (mpbi ssab @ ax_gen _) ltfin) @
bitr (elabe @ exeqd @ syl6bbr exan2 @ aneqd (a1i lmemmap) eleq1) @
bitr excomb @ exeqi @ bitr (exeqi @ bitr (aneq1i ancomb) anass) @
exeqe @ aneq2d elneq2)
'(eex @ lttrd (anwr ellt) (anwl lmemlt)));
--| A helper function for `Free`. This constructs the set `_V \ deps(a)` if `a`
--| is a regular argument and `(/)` if `a` is a bound argument.
--|
--| `MaybeFreeArgs : list SExpr -> Binder -> VarID -> Bool`
@_ def MaybeFreeArgs (es a v .s .vs .u: nat): wff =
$ E. s E. vs (a = PReg s vs /\ ~(E. u (u e. vs /\ nth u es = suc (SVar v)))) $;
@_ local def Free_aux (env ctx v: nat): set =
$ SExprRec
(\ u, nat (HasVar ctx (SVar u) v))
(\\ f, \\ es, \ ih, nat (E. args E. r E. rs E. o
(getTerm env f args (r <> rs) o /\
(ih <> args e. ex2 (S\ ih1, {a | true ih1 /\ MaybeFreeArgs es a v}) \/
E. u (u e. rs /\ nth u es = suc (SVar v)))))) $;
--| Does this expression contain any _free_ occurrence of the variable `v`?
--| This is the more complex binder-respecting check. Intuitively, if
--| `term foo {x y: set} (ph: set x): set y;`, then `foo` binds occurrences of
--| `x` in `ph`, and adds a dependency on `y` regardless. We might write this
--| as `FV(foo x y ph) = (FV(ph) \ {x}) u {y}`, but the definition below is
--| for arbitrary binding structures.
--|
--| `Free : Env -> Ctx -> SExpr -> VarID -> Bool`
@_ def Free (env ctx e v: nat): wff = $ true (Free_aux env ctx v @ e) $;
pub theorem FreeVar (env ctx u v: nat):
$ Free env ctx (SVar u) v <-> HasVar ctx (SVar u) v $ =
(named '(bitr
(trueeq @ eqtr SExprRec_Var @ applame @ nateqd @ HasVareq2d SVareq)
truenat));
pub theorem FreeApp (env ctx f es v: nat) {args r rs o n e a u: nat}:
$ Free env ctx (SApp f es) v <-> E. args E. r E. rs E. o
(getTerm env f args (r <> rs) o /\
(es <> args e. ex2 (S\ e, {a | Free env ctx e v /\ MaybeFreeArgs es a v}) \/
E. u (u e. rs /\ nth u es = suc (SVar v)))) $ =
(named @ focus
'(bitr (trueeq _) truenat)
'(eqtr {SExprRec_App : $ _ = _ @ (_ <> _ <> map (Free_aux env ctx v) _) $} _)
'(appslame @ appslamed @ applamed @
nateqd @ exeqd @ exeqd @ exeqd @ exeqd @ aneqd (getTermeq2d anll) @
oreqd _ @ exeqd @ aneq2d @ eqeq1d @ ntheq2d anlr)
'(syl6bb _ (eleqd (preq1d anr) (ex2eqd @ sabeqd @ abeqd @ aneq2d @ MaybeFreeArgseq1d anlr)))
'(bitr4 elex2 @ bitr4 elex2 @ aneq (eqeq1 maplen) @ exeqi @
bitr excomb @ bitr (exeqi _) excomb)
'(bitr (exeqi @ bitr4 (aneq1i @ bitr4 (aneq1i mapnthb) exan2) exan2) @
bitr excomb @ exeqi @
bitr (exeqi @ bitr (aneq1i @ bitr (aneq1i ancomb) anass) anass) @
exeqe @ aneq2d @ bitr4g _ _ @ aneq1d trueeq)
'(elsabe @ elabed ,eqtac) '(elsabe @ elabed ,eqtac));
--| Is this a valid term in the given environment? A term is valid if
--| the argument list is valid, the return type is valid, and the return sort
--| is not `pure` (because `pure` sorts are not allowed to have term
--| constructors).
--|
--| `TermOk : Env -> TermID -> Ctx -> DepType -> Bool`
@_ def TermOk (env id args ret .a .r .v .sd: nat): wff =
$ ~E. a E. r E. v getTerm env id a r v /\
Ctx env args /\ DepType env args ret /\
E. sd (getSD env (fst ret) sd /\ ~ sPure sd) $;
--| Is this a valid definition in the given environment? A definition is valid
--| if it is a valid term, and the definition typechecks, and all free variables
--| are declared in the return type. (Note in particular that dummies cannot
--| appear in the return type dependencies, so this ensures that all dummies are
--| bound by the definition.)
--|
--| `DefOk : Env -> TermID -> Ctx -> DepType -> Bool`
@_ def DefOk (env id args ret ds e .ctx .v .s .sd: nat): wff =
$ TermOk env id args ret /\ [ appendDummies args ds / ctx ]
(Ctx env ctx /\ Expr env ctx e (fst ret) /\
A. v (Free env ctx e v -> v e. snd ret \/
E. sd E. s (nth v ctx = suc (PBound s) /\
getSD env s sd /\ sFree sd))) $;
@_ local def DeclThm_aux (env: nat): set =
$ S\ args, S\ hs, {ret | Ctx env args /\ all {x | ExprProv env args x} (ret : hs)} $;
theorem DeclThm_aux_val (env args hs ret: nat) {x: nat}:
$ args <> hs <> ret e. DeclThm_aux env <->
Ctx env args /\ all {x | ExprProv env args x} (ret : hs) $ =
(named '(elsabe @ elsabed @ elabed @ aneqd (Ctxeq2d anll) @
alleqd (abeqd @ ExprProveq2d anll) (conseqd anr anlr)));
--| Is this a valid declaration in the environment?
--|
--| `Decl : Env -> Decl -> Bool`
@_ def Decl (env d: nat): wff =
$ d e. Sum
(Sum
(Sum
_V
(S\ id, S\ args, {ret | TermOk env id args ret}))
(DeclThm_aux env))
(Sum
(S\ id, S\ args, S\ ret, {o | TermOk env id args ret /\
A. ds A. e (o = suc (ds <> e) -> DefOk env id args ret ds e)})
(DeclThm_aux env)) $;
pub theorem DeclSort (env id sd: nat): $ Decl env (DSort id sd) $ =
(named '(mpbir Suml @ mpbir Suml @ mpbir Suml elv));
pub theorem DeclTerm (env id args ret: nat):
$ Decl env (DTerm id args ret) <-> TermOk env id args ret $ =
(named '(bitr Suml @ bitr Suml @ bitr Sumr @
elsabe @ elsabed @ elabed @ TermOkeqd eqidd anll anlr anr));
pub theorem DeclAxiom (env args hs ret: nat) {x: nat}:
$ Decl env (DAxiom args hs ret) <->
Ctx env args /\ all {x | ExprProv env args x} (ret : hs) $ =
(named '(bitr Suml @ bitr Sumr DeclThm_aux_val));
pub theorem DeclDef (env id args ret: nat) {ds e o v: nat}:
$ Decl env (DDef id args ret o) <-> TermOk env id args ret /\
A. ds A. e (o = suc (ds <> e) -> DefOk env id args ret ds e) $ =
(named '(bitr Sumr @ bitr Suml @ elsabe @ elsabed @ elsabed @ elabed @
aneqd (TermOkeqd eqidd an3l anllr anlr) @ aleqd @ aleqd @
imeqd (eqeq1d anr) @ DefOkeqd eqidd an3l anllr anlr eqidd eqidd));
pub theorem DeclThm (env args hs ret: nat) {x: nat}:
$ Decl env (DThm args hs ret) <->
Ctx env args /\ all {x | ExprProv env args x} (ret : hs) $ =
(named '(bitr Sumr @ bitr Sumr DeclThm_aux_val));
@_ local def Env_aux (e: nat): nat =
$ rlrec 1 (\\ e1, \\ s, \ ih, ih * nat (Decl e1 s)) e $;
--| This defines a valid mm0 specification. These are well formed ASTs for which
--| we can assign a provability predicate.
--|
--| `Env : Env -> Bool`
@_ def Env (e: nat): wff = $ true (Env_aux e) $;
pub theorem Env0: $ Env 0 $ = (named '(mpbir (trueeq rlrec0) true1));
pub theorem EnvS (e s: nat): $ Env (e |> s) <-> Env e /\ Decl e s $ =
(named '(bitr
(trueeq @ eqtr {rlrecS : $_ = _ @ (_ <> _ <> Env_aux _)$} @
appslame @ appslamed @ applamed @ muleqd anr @ nateqd @ Decleqd anll anlr)
(bitr truemul @ aneq2i truenat)));
@_ local def EnvExtend_aux (e2_: nat): nat =
$ rlrec (sn 0)
(\\ e2, \\ d, \ ih, case
(case
(case
(\\ id, \ sd, lower {e1 | E. e (e1 = e |> DSort id sd /\ e e. ih)})
(\\ id, \\ a, \ r, lower {e1 | E. e (e1 = e |> DTerm id a r /\ e e. ih)}))
(\\ a, \\ h, \ r, lower {e1 | E. e (e1 = e |> DAxiom a h r /\ e e. ih)}))
(case
(\\ id, \\ a, \\ r, \ o, lower {e1 |
E. e E. o2 ((o2 != 0 -> o2 = o) /\
e1 = e |> DDef id a r o2 /\ e e. ih) \/
e1 e. ih})
(\\ a, \\ h, \ r, lower {e1 |
E. e (e1 = e |> DThm a h r /\ e e. ih) \/
e1 e. ih}))
@ d)
e2_ $;
--| `EnvExtend e1 e2` means that environment `e2` is an extension of `e1`,
--| meaning that all sorts, terms, and axioms are preserved, but abstract defs
--| may be provided definitions, and new defs and theorems can be added.
--|
--| `EnvExtend : Env -> Env -> Bool`
@_ def EnvExtend (e1 e2: nat): wff = $ e1 e. EnvExtend_aux e2 $;
pub theorem EnvExtend0 (e: nat): $ EnvExtend e 0 <-> e = 0 $ =
(named '(bitr (elneq2 rlrec0) elsn));
theorem EnvExtend_lem {ih} (p: wff e1 e o2) (q: wff e o2) (A: nat o2)
(h1: $ ih = EnvExtend_aux E2 -> case
(case
(case
(\\ id, \ sd, lower {e1 | E. e (e1 = e |> DSort id sd /\ e e. ih)})
(\\ id, \\ a, \ r, lower {e1 | E. e (e1 = e |> DTerm id a r /\ e e. ih)}))
(\\ a, \\ h, \ r, lower {e1 | E. e (e1 = e |> DAxiom a h r /\ e e. ih)}))
(case
(\\ id, \\ a, \\ r, \ o, lower {e1 |
E. e E. o2 ((o2 != 0 -> o2 = o) /\
e1 = e |> DDef id a r o2 /\ e e. ih) \/
e1 e. ih})
(\\ a, \\ h, \ r, lower {e1 |
E. e (e1 = e |> DThm a h r /\ e e. ih) \/
e1 e. ih}))
@ d
= lower {e1 | p} $)
(h2: $ e1 = E1 -> (p <-> q) $)
(h3: $ p -> E. e E. x (x e. A /\ e1 = e |> x /\ EnvExtend e E2) \/ EnvExtend e1 E2 $):
$ EnvExtend E1 (E2 |> d) <-> q $ =
(named @ focus
'(bitr (elneq2 @ eqtr {rlrecS : $_ = _ @ (_ <> _ <> EnvExtend_aux _)$} @
appslame @ appslamed @ applamed @ eqtrd (appeq2d anlr) (anwr h1)) @
bitr (ellower _) (elabe h2))
'(finss (mpbi ssab @ ax_gen _) @
! ltfin $ lower ((\ u, fst u |> snd u) |` Xp (EnvExtend_aux E2) A) + EnvExtend_aux E2 $)
'(rsyl h3 @ eor
(ltletrd (eex @ eex @ mpbird (lteq1d anlr) _) (a1i leaddid1))
(ltletrd ellt (a1i leaddid2)))
'(lelttrd (a1i leprid2) @ syl ellt @
sylibr (ellower @ finlam @ xpfin finns finns) @
sylibr prelres @ iand (a1i _) @ sylibr prelxp @ iand anr anll)
'(mpbir ellam @ iexe (eqeq2d @ preqd id _) eqid)
'(snoceqd (syl6eq fstpr fsteq) (syl6eq sndpr sndeq)));
theorem EnvExtend_lem2 (p: wff e x)
(h: $ p -> E. e (e1 = e |> A /\ EnvExtend e E2) \/ EnvExtend e1 E2 $):
$ p -> E. e E. x (x e. sn A /\ e1 = e |> x /\ EnvExtend e E2) \/ EnvExtend e1 E2 $ =
'(rsyl h @ orim1 @ eximi @ iexe @ aneq1d @
bitrd (aneqd (a1i elsn) @ eqeq2d snoceq2) bian1);
pub theorem EnvExtendSort (e1 e2 id sd: nat) {e: nat}:
$ EnvExtend e1 (e2 |> DSort id sd) <->
E. e (e1 = e |> DSort id sd /\ EnvExtend e e2) $ =
(named '(EnvExtend_lem
(syl5eq casel @ syl5eq casel @ syl5eq casel @ appslamed @ applamed @
lowereqd @ abeqd @ exeqd @
aneqd (eqeq2d @ snoceq2d @ DSorteqd anlr anr) (elneq2d anll))
(exeqd @ aneq1d eqeq1)
(EnvExtend_lem2 orl)));
pub theorem EnvExtendTerm (e1 e2 id a r: nat) {e: nat}:
$ EnvExtend e1 (e2 |> DTerm id a r) <->
E. e (e1 = e |> DTerm id a r /\ EnvExtend e e2) $ =
(named '(EnvExtend_lem
(syl5eq casel @ syl5eq casel @ syl5eq caser @ appslamed @ appslamed @ applamed @
lowereqd @ abeqd @ exeqd @
aneqd (eqeq2d @ snoceq2d @ DTermeqd anllr anlr anr) (elneq2d an3l))
(exeqd @ aneq1d eqeq1)
(EnvExtend_lem2 orl)));
pub theorem EnvExtendAxiom (e1 e2 a h r: nat) {e: nat}:
$ EnvExtend e1 (e2 |> DAxiom a h r) <->
E. e (e1 = e |> DAxiom a h r /\ EnvExtend e e2) $ =
(named '(EnvExtend_lem
(syl5eq casel @ syl5eq caser @ appslamed @ appslamed @ applamed @
lowereqd @ abeqd @ exeqd @
aneqd (eqeq2d @ snoceq2d @ DAxiomeqd anllr anlr anr) (elneq2d an3l))
(exeqd @ aneq1d eqeq1)
(EnvExtend_lem2 orl)));
pub theorem EnvExtendDef (e1 e2 id a r o: nat) {e o2: nat}:
$ EnvExtend e1 (e2 |> DDef id a r o) <->
E. e E. o2 ((o2 != 0 -> o2 = o) /\
e1 = e |> DDef id a r o2 /\ EnvExtend e e2) \/
EnvExtend e1 e2 $ =
(named @ focus
'(EnvExtend_lem
(syl5eq caser @ syl5eq casel @ appslamed @ appslamed @ appslamed @ applamed @
lowereqd @ abeqd @ oreqd
(exeqd @ exeqd @ aneqd
(aneqd (anwr @ imeq2d eqeq2) @
eqeq2d @ snoceq2d @ DDefeqd an3lr anllr anlr eqidd)
(elneq2d an4l))
(elneq2d an4l))
(oreqd (exeqd @ exeqd @ aneq1d @ aneq2d eqeq1) eleq1)
_)
'(orim1 @ eximi @ eex @ iexde @ imp @ com12 @ anim1d @
animd (syl5 _ (bi2d eleq1)) (bi2d @ eqeq2d snoceq2))
'(sylibr elupto @ sylib leltsuc _)
'(sylib b1le @ sylib b0le @ sylib lepr2 @ sylib lepr2 @ sylib lepr2 _)
'(eor (mpbiri le01 leeq1) eqle));
pub theorem EnvExtendThm (e1 e2 id a h r: nat) {e: nat}:
$ EnvExtend e1 (e2 |> DThm a h r) <->
E. e (e1 = e |> DThm a h r /\ EnvExtend e e2) \/
EnvExtend e1 e2 $ =
(named '(EnvExtend_lem
(syl5eq caser @ syl5eq caser @ appslamed @ appslamed @ applamed @
lowereqd @ abeqd @ oreqd
(exeqd @ aneqd (eqeq2d @ snoceq2d @ DThmeqd anllr anlr anr) (elneq2d an3l))
(elneq2d an3l))
(oreqd (exeqd @ aneq1d eqeq1) eleq1)
(EnvExtend_lem2 id)));
------------------
-- Verification --
------------------
@_ local def substExpr_aux (subst: nat): set =
$ SExprRec (\ v, nth v subst - 1) (\\ f, \\ xs, \ ih, SApp f ih) $;
--| This performs simultaneous substitution of the variables in `e` with the
--| expressions in `subst`.
--|
--| `substExpr : list SExpr -> SExpr => SExpr`
@_ def substExpr (subst e: nat): nat = $ substExpr_aux subst @ e $;
theorem substExpr_aux_lam: $ substExpr_aux subst == \ e, substExpr subst e $ =
(named '(eqscom (lameqi applam)));
pub theorem substExprVar (subst v e: nat):
$ substExpr subst (SVar v) = nth v subst - 1 $ =
(named '(eqtr SExprRec_Var @ applame @ subeq1d ntheq1));
pub theorem substExprApp (subst f es: nat) {e: nat}:
$ substExpr subst (SApp f es) = SApp f (map (\ e, substExpr subst e) es) $ =
(named '(eqtr SExprRec_App @
! appslame _ $_ <> map (substExpr_aux _) _$ _ _ _ @ appslamed @ applamed @
SAppeqd anll @ syl6eq (mapeq1 substExpr_aux_lam) anr));
--| A CExpr is a convertibility proof:
--| `CRefl e : e = e`
--|
--| `CRefl : SExpr -> CExpr`
@_ def CRefl (e: nat): nat = $ b0 (b0 e) $;
--| If `p : e = e'`, then `CSymm p : e' = e`
--|
--| `CSymm : CExpr -> CExpr`
@_ def CSymm (p: nat): nat = $ b0 (b1 p) $;
--| If `{p : e = e'}` then `CCong f {p} : f {e} = f {e'}`
--| where the braces denote iteration
--|
--| `CCong : TermID -> list CExpr -> CExpr`
@_ def CCong (f cs: nat): nat = $ b1 (b0 (f <> cs)) $;
--| If `f {x} := {y}. e'`, then
--| `p : e'[{x}, {y} -> {e}, {z}] = e'' |- CCong f {z} p : f {e} = e''`
--|
--| `CUnfold : TermID -> list VarID -> CExpr -> CExpr`
@_ def CUnfold (f es zs c: nat): nat = $ b1 (b1 (f <> es <> zs <> c)) $;
theorem CSymm_ltid: $ c < CSymm c $ = '(ltb0tr b1ltid);
theorem CCong_ltid: $ c IN cs -> c < CCong f cs $ =
'(rsyl lmemlt @ mpi (ltb1tr @ leb0tr leprid2) lttr);
theorem CUnfold_ltid: $ c < CUnfold f es zs c $ =
'(ltb1tr @ leb1tr @ lepr2tr @ lepr2tr leprid2);
@_ local def CExprRec (R S C U: set): set =
$ \ e, srec (\ ih, case
(case R (\ c, S @ (c <> ih @ c)))
(case
(\\ f, \ cs, C @ (f <> cs <> map ih cs))
(\\ f, \\ es, \\ zs, \ c, U @ (f <> es <> zs <> c <> ih @ c))) @ size (Dom ih)) e $;
theorem CExprRec_val: $ CExprRec R S C U @ e = case
(case R (\ c, S @ (c <> (CExprRec R S C U |` upto e) @ c)))
(case
(\\ f, \ cs, C @ (f <> cs <> map (CExprRec R S C U |` upto e) cs))
(\\ f, \\ es, \\ zs, \ c, U @ (f <> es <> zs <> c <> (CExprRec R S C U |` upto e) @ c))) @ e $ =
(named '(eqtr (applame sreceq2) @
! eqtr _ $ _ @ (lower (CExprRec R S C U |` _)) $ _ srecval @
applame @ appeqd
(rsyl (bi2 @ eqlower2 @ finlam finns) @
caseeqd (caseeq2d @ lameqd @ appeq2d @ preq2d appeq1) @
caseeqd (slameqd @ lameqd @ appeq2d @ preq2d @ preq2d mapeq1) @
slameqd @ slameqd @ slameqd @ lameqd @ appeq2d @ preq2d @ preq2d @ preq2d @ preq2d appeq1)
sreclem));
theorem CExprRec_CRefl: $ CExprRec R S C U @ CRefl e = R @ e $ =
(named '(eqtr CExprRec_val @ eqtr casel casel));
theorem CExprRec_CSymm:
$ CExprRec R S C U @ CSymm c = S @ (c <> CExprRec R S C U @ c) $ =
(named '(eqtr CExprRec_val @ eqtr casel @ eqtr caser @
applame @ appeq2d @ preqd id @ syl6eq (resapp @ mpbir elupto CSymm_ltid) appeq2));
theorem CExprRec_CCong:
$ CExprRec R S C U @ CCong f cs = C @ (f <> cs <> map (CExprRec R S C U) cs) $ =
(named '(eqtr CExprRec_val @ eqtr caser @ eqtr casel @
appslame @ applamed @ appeq2d @ preqd anl @ preqd anr @ syl6eq
(mapeqg @ mpbir allal @ !! ax_gen e @ syl resapp @ sylibr elupto CCong_ltid)
(mapeq2d anr)));
theorem CExprRec_CUnfold:
$ CExprRec R S C U @ CUnfold f es zs c = U @ (f <> es <> zs <> c <> CExprRec R S C U @ c) $ =
(named '(eqtr CExprRec_val @ eqtr caser @ eqtr caser @
appslame @ appslamed @ appslamed @ applamed @ appeq2d @
preqd an3l @ preqd anllr @ preqd anlr @ preqd anr @ syl6eq
(resapp @ mpbir elupto CUnfold_ltid)
(appeq2d anr)));
theorem indd_aux2 (G p: wff x) (e: $ x = c -> (p <-> q) $)
(h: $ c < b $): $ G /\ A. z (z < a -> [z / x] p) /\ a = b -> q $ =
'(sylc (eale (imeqd lteq1 (syl6bb (sbe e) sbeq1))) anlr @ mpbiri h @ lteq2d anr);
theorem CExpr_indd {x f e c es zs cs} (n)
(px: wff x) (pi: wff c) (pr: wff e) (ps: wff c) (pc: wff f cs) (pu: wff f es zs c)
(hn: $ x = n -> (px <-> pn) $)
(hr: $ x = CRefl e -> (px <-> pr) $)
(hs: $ x = CSymm c -> (px <-> ps) $)
(hc: $ x = CCong f cs -> (px <-> pc) $)
(hu: $ x = CUnfold f es zs c -> (px <-> pu) $)
(hi: $ x = c -> (px <-> pi) $)
(h1: $ G -> pr $)
(h2: $ G /\ pi -> ps $)
(h3: $ G /\ all {x | px} cs -> pc $)
(h4: $ G /\ pi -> pu $): $ G -> pn $ =
'(sylib (sbe hn) @ !! indstr z w sbeq1 sbeq1 ,(split-sop '{
{($CRefl e$ => (indd_aux hr @ anwll h1)) +
($CSymm c$ => (indd_aux hs @ mpd (indd_aux2 hi CSymm_ltid) (anwll @ exp h2)))} +
{($CCong f cs$ => (indd_aux hc @ sylan h3 anll @
sylibr (alleq1 cbvabs) @ sylibr allal @
sylc (alimd @ imim1d @ syl5 CCong_ltid @ bi2d lteq2) anr anlr)) +
($CUnfold f es zs c$ => (indd_aux hu @ mpd (indd_aux2 hi CUnfold_ltid) (anwll @ exp h4)))}
}));
-- A `VExpr` is a proof term.
--| A `VHyp` is a hypothesis step - a term is asserted from the local context.
--| Indexing is relative to the list of hypotheses to the theorem.
--|
--| `VHyp : HypID -> VExpr`
@_ def VHyp (n: nat): nat = $ b0 (b0 n) $;
--| A `VThm` is a theorem application - a step follows from previous steps by
--| application of a theorem. The arguments give the theorem to apply, the list
--| of substitutions of expressions for the variables, and the list of subproofs
--| for the hypotheses to the theorem.
--|
--| `VThm : ThmID -> list SExpr -> list VExpr -> VExpr`
@_ def VThm (a h r es ps: nat): nat = $ b0 (b1 (a <> h <> r <> es <> ps)) $;
--| `c : A = B, p : A |- VConv c p : B`
--|
--| `VConv : CExpr -> VExpr -> VExpr`
@_ def VConv (c p: nat): nat = $ b1 (c <> p) $;
theorem VThm_ltid: $ p IN ps -> p < VThm a h r es ps $ =
'(rsyl lmemlt @ mpi (ltb0tr @ ltb1tr @ lepr2tr @ lepr2tr @ lepr2tr leprid2) lttr);
theorem VConv_ltid: $ p < VConv c p $ =
'(ltb1tr leprid2);
@_ local def VExprRec (H T C: set): set =
$ \ e, srec (\ ih, case
(case H
(\\ a, \\ h, \\ r, \\ es, \ ps, T @ (a <> h <> r <> es <> ps <> map ih ps)))
(\\ c, \ p, C @ (c <> p <> ih @ p)) @ size (Dom ih)) e $;
theorem VExprRec_val: $ VExprRec H T C @ e = case
(case H
(\\ a, \\ h, \\ r, \\ es, \ ps, T @ (a <> h <> r <> es <> ps <> map (VExprRec H T C |` upto e) ps)))
(\\ c, \ p, C @ (c <> p <> (VExprRec H T C |` upto e) @ p)) @ e $ =
(named '(eqtr (applame sreceq2) @
! eqtr _ $ _ @ (lower (VExprRec H T C |` _)) $ _ srecval @
applame @ appeqd
(rsyl (bi2 @ eqlower2 @ finlam finns) @
caseeqd (caseeq2d @ slameqd @ slameqd @ slameqd @ slameqd @ lameqd @
appeq2d @ preq2d @ preq2d @ preq2d @ preq2d @ preq2d mapeq1) @
slameqd @ lameqd @ appeq2d @ preq2d @ preq2d appeq1)
sreclem));
theorem VExprRec_VHyp: $ VExprRec H T C @ VHyp n = H @ n $ =
(named '(eqtr VExprRec_val @ eqtr casel casel));
theorem VExprRec_VThm:
$ VExprRec H T C @ VThm a h r es ps = T @ (a <> h <> r <> es <> ps <> map (VExprRec H T C) ps) $ =
(named '(eqtr VExprRec_val @ eqtr casel @ eqtr caser @
appslame @ appslamed @ appslamed @ appslamed @ applamed @
appeq2d @ preqd an4l @ preqd an3lr @ preqd anllr @ preqd anlr @ preqd anr @ syl6eq
(mapeqg @ mpbir allal @ !! ax_gen p @ syl resapp @ sylibr elupto VThm_ltid)
(mapeq2d anr)));
theorem VExprRec_VConv:
$ VExprRec H T C @ VConv c p = C @ (c <> p <> VExprRec H T C @ p) $ =
(named '(eqtr VExprRec_val @ eqtr caser @
appslame @ applamed @ appeq2d @
preqd anl @ preqd anr @ syl6eq
(resapp @ mpbir elupto VConv_ltid)
(appeq2d anr)));
theorem VExpr_indd {x n a h r es ps c p} (q)
(px: wff x) (pi: wff p) (ph: wff n) (pt: wff a h r es ps) (pc: wff c p)
(hn: $ x = q -> (px <-> pq) $)
(hr: $ x = VHyp n -> (px <-> ph) $)
(hs: $ x = VThm a h r es ps -> (px <-> pt) $)
(hc: $ x = VConv c p -> (px <-> pc) $)
(hi: $ x = p -> (px <-> pi) $)
(h1: $ G -> ph $)
(h2: $ G /\ all {x | px} ps -> pt $)
(h3: $ G /\ pi -> pc $): $ G -> pq $ =
'(sylib (sbe hn) @ !! indstr z w sbeq1 sbeq1 ,(split-sop '{
{($VHyp n$ => (indd_aux hr @ anwll h1)) +
($VThm a h r es ps$ => (indd_aux hs @ sylan h2 anll @
sylibr (alleq1 cbvabs) @ sylibr allal @
sylc (alimd @ imim1d @ syl5 VThm_ltid @ bi2d lteq2) anr anlr))} +
($VConv c p$ => (indd_aux hc @ mpd (indd_aux2 hi VConv_ltid) (anwll @ exp h3)))}));
@_ local def VerifyConv_aux (env ctx: nat): set =
$ CExprRec
(\ e, lower (S\ e1, S\ e2, {s | Expr env ctx e s /\ e = e1 /\ e = e2}))
(\\ c, \ ih, lower (S\ e1, S\ e2, {s | e2 <> e1 <> s e. ih}))
(\\ f, \\ cs, \ ih, lower (S\ e1, S\ e2, {s |
E. args E. ret E. o E. es1 E. es2 (
e1 = SApp f es1 /\ e2 = SApp f es2 /\
getTerm env f args ret o /\ (
E. n (len cs = n /\ len es1 = n /\ len es2 = n /\ len args = n /\
A. i A. c A. e1 A. e2 A. bi (nth i ih = suc c ->
nth i es1 = suc e1 -> nth i es2 = suc e2 -> nth i args = suc bi ->
ExprBi env ctx e1 bi /\ ExprBi env ctx e2 bi /\
e1 <> e2 <> binderSort bi e. c))) /\
s = fst ret)}))
(\\ f, \\ es, \\ zs, \\ c, \ ih, lower (S\ e1, S\ e2, {s |
E. args E. ret E. ys E. val (
getTerm env f args ret (suc (ys <> val)) /\
e1 = SApp f es /\ s = fst ret /\
es <> args e. all2 (S\ e, {a | ExprBi env ctx e a}) /\
ys <> zs e. all2 (S\ y, {z | nth z ctx = suc (PBound y) /\
A. e (e IN es -> ~HasVar ctx e z)}) /\
substExpr (es ++ map (\ i, SVar i) zs) val <> e2 <> s e. ih)})) $;
--| Checking a conversion proof `c : (e1 : s) = (e2 : s)`.
--| `VerifyConv : Env -> Ctx -> CExpr -> SExpr -> SExpr -> SortID -> Bool`
@_ abstract def VerifyConv (env ctx c e1 e2 s: nat): wff =
$ e1 <> e2 <> s e. VerifyConv_aux env ctx @ c $;
--| `VerifyConvs : Env -> Ctx -> list CExpr -> list SExpr ->
--| list SExpr -> list Binder -> Bool`
@_ def VerifyConvs (env ctx cs es1 es2 bis .n .i .c .e1 .e2 .bi: nat): wff =
$ E. n (len cs = n /\ len es1 = n /\ len es2 = n /\ len bis = n /\
A. i A. c A. e1 A. e2 A. bi (nth i cs = suc c ->
nth i es1 = suc e1 -> nth i es2 = suc e2 -> nth i bis = suc bi ->
ExprBi env ctx e1 bi /\ ExprBi env ctx e2 bi /\
VerifyConv env ctx c e1 e2 (binderSort bi))) $;
theorem VerifyConvs_fin: $ E. n A. es1 A. es2 A. bis
(VerifyConvs env ctx cs es1 es2 bis -> es1 < n /\ es2 < n) $ =
(focus
(have 'h1
$ len cs = m /\ len es1 = m /\ len es2 = m /\ len bis = m -> i < m ->
E. c nth i cs = suc c /\ E. e1 nth i es1 = suc e1 /\
E. e2 nth i es2 = suc e2 /\ E. bi nth i bis = suc bi $
(def h '(syl6ib (bitr3 nthne0 exsuc) (com12 @ bi2d lteq2)))
'(com12 @ animd (animd (animd ,h ,h) ,h) ,h))
'(! iexe _ $ lower (Array (upto (map (VerifyConv_aux env ctx) cs)) (len cs)) $ _ _
(aleqd @ aleqd @ aleqd @ imeq2d @ aneqd lteq2 lteq2) @
ax_gen @ ax_gen @ ax_gen @ eex @ iand _ _)
(def (lem hlen hlen2 hpr f) @ focus
'(syl ellt @ sylibr (ellower @ Arrayfin finns) @
sylibr elArray @ iand _ @ eqtr4d ,hlen an4l)
'(sylibr elList @ sylibr allnth @ imp @ alimd @
syl6ib (bitr3 alim1 @ aleqi @ bitr3 impexp @ imeq1i @ bian1a @ sylib nthne0 sucne0) @
com23 @ syl6 _ @ mpbird (imeq1d @ lteq2d ,hlen2) h1)
'(com12 @ impd @ impd @ impd @ sylibr eexb @ alimi @
sylbi (bitr (!! aleqi e1 @ bitr (!! aleqi e2 alim1) alim1) alim1) @
a2i @ syl5bi (aleqi @ bitr (aleqi alim1) @ bitr alim1 @ imeq2i @ aleqi alim1) _)
(f '(alimd @ imim2d @ imp @ com23 @ syl6ibr eexb @ alimd @ imim2d @
exp @ sylibr elupto @ syl (lelttr ,hpr) @
lttrd (syl ellt anrr) @
syl lmemlt @ syl lmemmapi @ anwl nthlmem)))
(lem 'an3lr 'anllr 'leprid1 (fn (x)
'(syl6 ax_1 @ com23 @ exp @ com23 @ exp @ alimd @ imim2d @
anrasss @ imp @ com23 @ syl6ibr eexb ,x)))
(lem 'anllr 'anlr '(lepr2tr leprid1) (fn (x)
'(syl6ibr eexb @ alimd @ imim2d @ syl6 ax_1 @ com23 @ exp ,x))));
theorem VerifyConv_aux_Refl:
$ VerifyConv_aux env ctx @ CRefl e = lower (S\ e1, S\ e2, {s |
Expr env ctx e s /\ e = e1 /\ e = e2}) $ =
(named '(eqtr CExprRec_CRefl @ applame @ lowereqd @ sabeqd @ sabeqd @ abeqd @
aneqd (aneqd Expreq3 eqeq1) eqeq1));
pub theorem VerifyConvRefl (env ctx e e1 e2 s: nat):
$ VerifyConv env ctx (CRefl e) e1 e2 s <->
Expr env ctx e s /\ e = e1 /\ e = e2 $ =
(named @ focus
'(bitr (elneq2 VerifyConv_aux_Refl) @ bitr (ellower @ trud _) @
elsabe @ elsabed @ elabed @
aneqd (aneqd (Expreq4d anr) (eqeq2d anll)) (eqeq2d anlr))
'(sabfin (eexsabd @ eelabd @ a1i @ sylibr elsn @ eqcomd anlr) (a1i finns) @
sabfin (eelabd @ a1i @ sylibr elsn @ eqcomd anr) (a1i finns) @
a1i @ finss (mpbi ssab1 @ ax_gen anll) finns));
theorem VerifyConv_aux_Symm:
$ VerifyConv_aux env ctx @ CSymm c = lower (S\ e1, S\ e2, {s |
VerifyConv env ctx c e2 e1 s}) $ =
(named '(eqtr {CExprRec_CSymm : $_ = _ @ (_ <> VerifyConv_aux _ _ @ c)$} @
appslame @ applamed @ lowereqd @ sabeqd @ sabeqd @ abeqd @
elneq2d anr));
pub theorem VerifyConvSymm (env ctx c e1 e2 s: nat):
$ VerifyConv env ctx (CSymm c) e1 e2 s <-> VerifyConv env ctx c e2 e1 s $ =
(named @ focus
'(bitr (elneq2 VerifyConv_aux_Symm) @ bitr (ellower @ trud _) @
elsabe @ elsabed @ elabed @ VerifyConveqd eqidd eqidd eqidd anlr anll anr)
'(sabfin (eexsabd @ eelabd @ a1i @ syl preldm prelrn) (a1i @ dmfin @ rnfin finns) @
sabfin (eelabd @ a1i preldm) (a1i @ dmfin finns) @
a1i @ finss (mpbi ssab1 @ ax_gen @ syl prelrn prelrn) (rnfin @ rnfin finns)));
theorem VerifyConv_aux_Cong:
$ VerifyConv_aux env ctx @ CCong f cs = lower (S\ e1, S\ e2, {s |
E. args E. ret E. o E. es1 E. es2 (
e1 = SApp f es1 /\ e2 = SApp f es2 /\
getTerm env f args ret o /\
VerifyConvs env ctx cs es1 es2 args /\
s = fst ret)}) $ =
(named @ focus
'(eqtr {CExprRec_CCong : $_ = _ @ (_ <> _ <> map (VerifyConv_aux _ _) _)$} @
appslame @ appslamed @ applamed @ lowereqd @ sabeqd @ sabeqd @ abeqd @
exeqd @ exeqd @ exeqd @ exeqd @ exeqd @ aneq1d @
aneqd (aneqd
(aneqd (eqeq2d @ SAppeq1d anll) (eqeq2d @ SAppeq1d anll))
(getTermeq2d anll)) _)
'(exeqd @ aneqd (aneq1d @ aneq1d @ aneq1d @ eqeq1d @ leneqd anlr) @
!! aleqd n @
bitr4g alcomb alcomb @ !! aleqd e1 @
bitr4g alcomb alcomb @ !! aleqd e2 @
bitr4g alcomb alcomb @ !! aleqd bi @
syl6bb _ @ aleqd @ imeq1d @ eqeq1d @ ntheq2d anr)
'(bitr (aleqi @ bitr (imeq1i @ mapnthb) eexb) @
bitr alcomb @ aleqi @
bitr (!! aleqi _ @ bitr (imeq1i ancomb) impexp) @ aleqe @
imeq2d @ imeq2d @ imeq2d @ imeq2d @ aneq2d elneq2));
pub theorem VerifyConvCong (env ctx f cs e1 e2 s: nat) {args ret o es1 es2: nat}:
$ VerifyConv env ctx (CCong f cs) e1 e2 s <->
E. args E. ret E. o E. es1 E. es2 (
e1 = SApp f es1 /\ e2 = SApp f es2 /\
getTerm env f args ret o /\
VerifyConvs env ctx cs es1 es2 args /\
s = fst ret) $ =
(named @ focus
'(bitr (elneq2 VerifyConv_aux_Cong) @ bitr (ellower _) @
elsabe @ elsabed @ elabed @ exeqd @ exeqd @ exeqd @ exeqd @ exeqd @
aneqd (aneq1d @ aneq1d @ aneqd (eqeq1d anll) (eqeq1d anlr)) (eqeq1d anr))
(suffices 'h $ _ -> _ -> e1_ < SApp env n /\ e2_ < SApp env n /\ s_ < env $ '_)
(focus
'(ax_mp (eex _) VerifyConvs_fin)
'(sabfin (eexsabd @ eelabd @ syl6ibr elupto @ syl6 anll h) (a1i finns) @ anwl @
sabfin (eelabd @ syl6ibr elupto @ syl6 anlr h) (a1i finns) @ anwl @
syl (mpi ltfin finss) @ ssabd @ syl6 anr h))
'(eexd @ eexd @ eexd @ sylibr eexb @ alimi @ sylibr eexb @ alimi @
sylbir eexb @ com12 @ syld (rsyl anlr @ com12 @ imim1i @ iexe VerifyConvseq6) @
syld _ (bi2d @ aneqd (aneqd (lteq1d an4l) (lteq1d an3lr)) (lteq1d anr)))
'(rsyl anllr @ rsyl getTerm_ltid @ exp @ iand (iand _ _) _)
(focus '(sylib b1lt @ lttrd (sylib ltpr1 an4l) (sylib ltpr2 anrl)))
(focus '(sylib b1lt @ lttrd (sylib ltpr1 an4l) (sylib ltpr2 anrr)))
(focus '(syl (lelttr fstleid) anllr)));
theorem VerifyConv_aux_Unfold:
$ VerifyConv_aux env ctx @ CUnfold f es zs c = lower (S\ e1, S\ e2, {s |
E. args E. ret E. ys E. val (
getTerm env f args ret (suc (ys <> val)) /\
e1 = SApp f es /\ s = fst ret /\
es <> args e. all2 (S\ e, {a | ExprBi env ctx e a}) /\
ys <> zs e. all2 (S\ y, {z | nth z ctx = suc (PBound y) /\
A. e (e IN es -> ~HasVar ctx e z)}) /\
VerifyConv env ctx c (substExpr (es ++ map (\ i, SVar i) zs) val) e2 s)}) $ =
(named '(eqtr {CExprRec_CUnfold : $_ = _ @ (_ <> _ <> _ <> _ <> VerifyConv_aux _ _ @ c)$} @
appslame @ appslamed @ appslamed @ appslamed @ applamed @ lowereqd @ sabeqd @ sabeqd @ abeqd @
exeqd @ exeqd @ exeqd @ exeqd @ aneqd
(aneqd (aneqd (aneq1d @ aneqd (getTermeq2d an4l) (eqeq2d @ SAppeqd an4l an3lr))
(eleq1d @ preq1d an3lr))
(eleqd (preq2d anllr) (all2eqd @ sabeqd @ abeqd @ aneq2d @ aleqd @ imeq1d @ lmemeq2d an3lr)))
(elneqd (preq1d @ substExpreq1d @ appendeqd an3lr @ mapeq2d anllr) anr)));
pub theorem VerifyConvUnfold (env ctx f zs c e1 e2 s: nat)
{args ret ys val es a y z e i: nat}:
$ VerifyConv env ctx (CUnfold f es zs c) e1 e2 s <->
E. args E. ret E. ys E. val (
getTerm env f args ret (suc (ys <> val)) /\
e1 = SApp f es /\ s = fst ret /\
es <> args e. all2 (S\ e, {a | ExprBi env ctx e a}) /\
ys <> zs e. all2 (S\ y, {z | nth z ctx = suc (PBound y) /\
A. e (e IN es -> ~HasVar ctx e z)}) /\
VerifyConv env ctx c (substExpr (es ++ map (\ i, SVar i) zs) val) e2 s) $ =
(named @ focus