view src/elaborate.sml @ 135:b1cfe49ce692

Proper escaping of cdata
author Adam Chlipala <adamc@hcoop.net>
date Thu, 17 Jul 2008 13:33:56 -0400
parents e3041657d653
children adfa2c7a75da
line wrap: on
line source
(* Copyright (c) 2008, Adam Chlipala
 * All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions are met:
 *
 * - Redistributions of source code must retain the above copyright notice,
 *   this list of conditions and the following disclaimer.
 * - Redistributions in binary form must reproduce the above copyright notice,
 *   this list of conditions and the following disclaimer in the documentation
 *   and/or other materials provided with the distribution.
 * - The names of contributors may not be used to endorse or promote products
 *   derived from this software without specific prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
 * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
 * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 
 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 * POSSIBILITY OF SUCH DAMAGE.
 *)

structure Elaborate :> ELABORATE = struct

structure P = Prim
structure L = Source
structure L' = Elab
structure E = ElabEnv
structure U = ElabUtil
structure D = Disjoint

open Print
open ElabPrint

structure SS = BinarySetFn(struct
                           type ord_key = string
                           val compare = String.compare
                           end)

fun elabExplicitness e =
    case e of
        L.Explicit => L'.Explicit
      | L.Implicit => L'.Implicit

fun occursKind r =
    U.Kind.exists (fn L'.KUnif (_, _, r') => r = r'
                    | _ => false)

datatype kunify_error =
         KOccursCheckFailed of L'.kind * L'.kind
       | KIncompatible of L'.kind * L'.kind

exception KUnify' of kunify_error

fun kunifyError err =
    case err of
        KOccursCheckFailed (k1, k2) =>
        eprefaces "Kind occurs check failed"
        [("Kind 1", p_kind k1),
         ("Kind 2", p_kind k2)]
      | KIncompatible (k1, k2) =>
        eprefaces "Incompatible kinds"
        [("Kind 1", p_kind k1),
         ("Kind 2", p_kind k2)]

fun unifyKinds' (k1All as (k1, _)) (k2All as (k2, _)) =
    let
        fun err f = raise KUnify' (f (k1All, k2All))
    in
        case (k1, k2) of
            (L'.KType, L'.KType) => ()
          | (L'.KUnit, L'.KUnit) => ()

          | (L'.KArrow (d1, r1), L'.KArrow (d2, r2)) =>
            (unifyKinds' d1 d2;
             unifyKinds' r1 r2)
          | (L'.KName, L'.KName) => ()
          | (L'.KRecord k1, L'.KRecord k2) => unifyKinds' k1 k2

          | (L'.KError, _) => ()
          | (_, L'.KError) => ()

          | (L'.KUnif (_, _, ref (SOME k1All)), _) => unifyKinds' k1All k2All
          | (_, L'.KUnif (_, _, ref (SOME k2All))) => unifyKinds' k1All k2All

          | (L'.KUnif (_, _, r1), L'.KUnif (_, _, r2)) =>
            if r1 = r2 then
                ()
            else
                r1 := SOME k2All

          | (L'.KUnif (_, _, r), _) =>
            if occursKind r k2All then
                err KOccursCheckFailed
            else
                r := SOME k2All
          | (_, L'.KUnif (_, _, r)) =>
            if occursKind r k1All then
                err KOccursCheckFailed
            else
                r := SOME k1All

          | _ => err KIncompatible
    end

exception KUnify of L'.kind * L'.kind * kunify_error

fun unifyKinds k1 k2 =
    unifyKinds' k1 k2
    handle KUnify' err => raise KUnify (k1, k2, err)

datatype con_error =
         UnboundCon of ErrorMsg.span * string
       | UnboundStrInCon of ErrorMsg.span * string
       | WrongKind of L'.con * L'.kind * L'.kind * kunify_error
       | DuplicateField of ErrorMsg.span * string

fun conError env err =
    case err of
        UnboundCon (loc, s) =>
        ErrorMsg.errorAt loc ("Unbound constructor variable " ^ s)
      | UnboundStrInCon (loc, s) =>
        ErrorMsg.errorAt loc ("Unbound structure " ^ s)
      | WrongKind (c, k1, k2, kerr) =>
        (ErrorMsg.errorAt (#2 c) "Wrong kind";
         eprefaces' [("Constructor", p_con env c),
                     ("Have kind", p_kind k1),
                     ("Need kind", p_kind k2)];
         kunifyError kerr)
      | DuplicateField (loc, s) =>
        ErrorMsg.errorAt loc ("Duplicate record field " ^ s)

fun checkKind env c k1 k2 =
    unifyKinds k1 k2
    handle KUnify (k1, k2, err) =>
           conError env (WrongKind (c, k1, k2, err))

val dummy = ErrorMsg.dummySpan

val ktype = (L'.KType, dummy)
val kname = (L'.KName, dummy)
val ktype_record = (L'.KRecord ktype, dummy)

val cerror = (L'.CError, dummy)
val kerror = (L'.KError, dummy)
val eerror = (L'.EError, dummy)
val sgnerror = (L'.SgnError, dummy)
val strerror = (L'.StrError, dummy)

val int = ref cerror
val float = ref cerror
val string = ref cerror

local
    val count = ref 0
in

fun resetKunif () = count := 0

fun kunif loc =
    let
        val n = !count
        val s = if n <= 26 then
                    str (chr (ord #"A" + n))
                else
                    "U" ^ Int.toString (n - 26)
    in
        count := n + 1;
        (L'.KUnif (loc, s, ref NONE), dummy)
    end

end

local
    val count = ref 0
in

fun resetCunif () = count := 0

fun cunif (loc, k) =
    let
        val n = !count
        val s = if n <= 26 then
                    str (chr (ord #"A" + n))
                else
                    "U" ^ Int.toString (n - 26)
    in
        count := n + 1;
        (L'.CUnif (loc, k, s, ref NONE), dummy)
    end

end

fun elabKind (k, loc) =
    case k of
        L.KType => (L'.KType, loc)
      | L.KArrow (k1, k2) => (L'.KArrow (elabKind k1, elabKind k2), loc)
      | L.KName => (L'.KName, loc)
      | L.KRecord k => (L'.KRecord (elabKind k), loc)
      | L.KUnit => (L'.KUnit, loc)
      | L.KWild => kunif loc

fun foldKind (dom, ran, loc)=
    (L'.KArrow ((L'.KArrow ((L'.KName, loc),
                            (L'.KArrow (dom,
                                        (L'.KArrow (ran, ran), loc)), loc)), loc),
                (L'.KArrow (ran,
                            (L'.KArrow ((L'.KRecord dom, loc),
                                        ran), loc)), loc)), loc)

fun elabCon (env, denv) (c, loc) =
    case c of
        L.CAnnot (c, k) =>
        let
            val k' = elabKind k
            val (c', ck, gs) = elabCon (env, denv) c
        in
            checkKind env c' ck k';
            (c', k', gs)
        end

      | L.TFun (t1, t2) =>
        let
            val (t1', k1, gs1) = elabCon (env, denv) t1
            val (t2', k2, gs2) = elabCon (env, denv) t2
        in
            checkKind env t1' k1 ktype;
            checkKind env t2' k2 ktype;
            ((L'.TFun (t1', t2'), loc), ktype, gs1 @ gs2)
        end
      | L.TCFun (e, x, k, t) =>
        let
            val e' = elabExplicitness e
            val k' = elabKind k
            val env' = E.pushCRel env x k'
            val (t', tk, gs) = elabCon (env', D.enter denv) t
        in
            checkKind env t' tk ktype;
            ((L'.TCFun (e', x, k', t'), loc), ktype, gs)
        end
      | L.TDisjoint (c1, c2, c) =>
        let
            val (c1', k1, gs1) = elabCon (env, denv) c1
            val (c2', k2, gs2) = elabCon (env, denv) c2

            val ku1 = kunif loc
            val ku2 = kunif loc

            val (denv', gs3) = D.assert env denv (c1', c2')
            val (c', k, gs4) = elabCon (env, denv') c
        in
            checkKind env c1' k1 (L'.KRecord ku1, loc);
            checkKind env c2' k2 (L'.KRecord ku2, loc);

            ((L'.TDisjoint (c1', c2', c'), loc), k, gs1 @ gs2 @ gs3 @ gs4)
        end
      | L.TRecord c =>
        let
            val (c', ck, gs) = elabCon (env, denv) c
            val k = (L'.KRecord ktype, loc)
        in
            checkKind env c' ck k;
            ((L'.TRecord c', loc), ktype, gs)
        end

      | L.CVar ([], s) =>
        (case E.lookupC env s of
             E.NotBound =>
             (conError env (UnboundCon (loc, s));
              (cerror, kerror, []))
           | E.Rel (n, k) =>
             ((L'.CRel n, loc), k, [])
           | E.Named (n, k) =>
             ((L'.CNamed n, loc), k, []))
      | L.CVar (m1 :: ms, s) =>
        (case E.lookupStr env m1 of
             NONE => (conError env (UnboundStrInCon (loc, m1));
                      (cerror, kerror, []))
           | SOME (n, sgn) =>
             let
                 val (str, sgn) = foldl (fn (m, (str, sgn)) =>
                                     case E.projectStr env {sgn = sgn, str = str, field = m} of
                                         NONE => (conError env (UnboundStrInCon (loc, m));
                                                  (strerror, sgnerror))
                                       | SOME sgn => ((L'.StrProj (str, m), loc), sgn))
                                  ((L'.StrVar n, loc), sgn) ms

                 val k = case E.projectCon env {sgn = sgn, str = str, field = s} of
                             NONE => (conError env (UnboundCon (loc, s));
                                      kerror)
                           | SOME (k, _) => k
             in
                 ((L'.CModProj (n, ms, s), loc), k, [])
             end)
                                                                       
      | L.CApp (c1, c2) =>
        let
            val (c1', k1, gs1) = elabCon (env, denv) c1
            val (c2', k2, gs2) = elabCon (env, denv) c2
            val dom = kunif loc
            val ran = kunif loc
        in
            checkKind env c1' k1 (L'.KArrow (dom, ran), loc);
            checkKind env c2' k2 dom;
            ((L'.CApp (c1', c2'), loc), ran, gs1 @ gs2)
        end
      | L.CAbs (x, ko, t) =>
        let
            val k' = case ko of
                         NONE => kunif loc
                       | SOME k => elabKind k
            val env' = E.pushCRel env x k'
            val (t', tk, gs) = elabCon (env', D.enter denv) t
        in
            ((L'.CAbs (x, k', t'), loc),
             (L'.KArrow (k', tk), loc),
             gs)
        end

      | L.CDisjoint (c1, c2, c) =>
        let
            val (c1', k1, gs1) = elabCon (env, denv) c1
            val (c2', k2, gs2) = elabCon (env, denv) c2

            val ku1 = kunif loc
            val ku2 = kunif loc

            val (denv', gs3) = D.assert env denv (c1', c2')
            val (c', k, gs4) = elabCon (env, denv') c
        in
            checkKind env c1' k1 (L'.KRecord ku1, loc);
            checkKind env c2' k2 (L'.KRecord ku2, loc);

            ((L'.CDisjoint (c1', c2', c'), loc), k, gs1 @ gs2 @ gs3 @ gs4)
        end

      | L.CName s =>
        ((L'.CName s, loc), kname, [])

      | L.CRecord xcs =>
        let
            val k = kunif loc

            val (xcs', gs) = ListUtil.foldlMap (fn ((x, c), gs) =>
                                                   let
                                                       val (x', xk, gs1) = elabCon (env, denv) x
                                                       val (c', ck, gs2) = elabCon (env, denv) c
                                                   in
                                                       checkKind env x' xk kname;
                                                       checkKind env c' ck k;
                                                       ((x', c'), gs1 @ gs2 @ gs)
                                                   end) [] xcs

            val rc = (L'.CRecord (k, xcs'), loc)
            (* Add duplicate field checking later. *)

            fun prove (xcs, ds) =
                case xcs of
                    [] => ds
                  | xc :: rest =>
                    let
                        val r1 = (L'.CRecord (k, [xc]), loc)
                        val ds = foldl (fn (xc', ds) =>
                                           let
                                               val r2 = (L'.CRecord (k, [xc']), loc)
                                           in
                                               D.prove env denv (r1, r2, loc) @ ds
                                           end)
                                 ds rest
                    in
                        prove (rest, ds)
                    end
        in
            (rc, (L'.KRecord k, loc), prove (xcs', gs))
        end
      | L.CConcat (c1, c2) =>
        let
            val (c1', k1, gs1) = elabCon (env, denv) c1
            val (c2', k2, gs2) = elabCon (env, denv) c2
            val ku = kunif loc
            val k = (L'.KRecord ku, loc)
        in
            checkKind env c1' k1 k;
            checkKind env c2' k2 k;
            ((L'.CConcat (c1', c2'), loc), k,
             D.prove env denv (c1', c2', loc) @ gs1 @ gs2)
        end
      | L.CFold =>
        let
            val dom = kunif loc
            val ran = kunif loc
        in
            ((L'.CFold (dom, ran), loc),
             foldKind (dom, ran, loc),
             [])
        end

      | L.CUnit => ((L'.CUnit, loc), (L'.KUnit, loc), [])

      | L.CWild k =>
        let
            val k' = elabKind k
        in
            (cunif (loc, k'), k', [])
        end

fun kunifsRemain k =
    case k of
        L'.KUnif (_, _, ref NONE) => true
      | _ => false
fun cunifsRemain c =
    case c of
        L'.CUnif (loc, _, _, ref NONE) => SOME loc
      | _ => NONE

val kunifsInDecl = U.Decl.exists {kind = kunifsRemain,
                                  con = fn _ => false,
                                  exp = fn _ => false,
                                  sgn_item = fn _ => false,
                                  sgn = fn _ => false,
                                  str = fn _ => false,
                                  decl = fn _ => false}

val cunifsInDecl = U.Decl.search {kind = fn _ => NONE,
                                  con = cunifsRemain,
                                  exp = fn _ => NONE,
                                  sgn_item = fn _ => NONE,
                                  sgn = fn _ => NONE,
                                  str = fn _ => NONE,
                                  decl = fn _ => NONE}

fun occursCon r =
    U.Con.exists {kind = fn _ => false,
                  con = fn L'.CUnif (_, _, _, r') => r = r'
                         | _ => false}

datatype cunify_error =
         CKind of L'.kind * L'.kind * kunify_error
       | COccursCheckFailed of L'.con * L'.con
       | CIncompatible of L'.con * L'.con
       | CExplicitness of L'.con * L'.con
       | CKindof of L'.con
       | CRecordFailure

exception CUnify' of cunify_error

fun cunifyError env err =
    case err of
        CKind (k1, k2, kerr) =>
        (eprefaces "Kind unification failure"
                   [("Kind 1", p_kind k1),
                    ("Kind 2", p_kind k2)];
         kunifyError kerr)
      | COccursCheckFailed (c1, c2) =>
        eprefaces "Constructor occurs check failed"
                  [("Con 1", p_con env c1),
                   ("Con 2", p_con env c2)]
      | CIncompatible (c1, c2) =>
        eprefaces "Incompatible constructors"
                  [("Con 1", p_con env c1),
                   ("Con 2", p_con env c2)]
      | CExplicitness (c1, c2) =>
        eprefaces "Differing constructor function explicitness"
                  [("Con 1", p_con env c1),
                   ("Con 2", p_con env c2)]
      | CKindof c =>
        eprefaces "Kind unification variable blocks kindof calculation"
                  [("Con", p_con env c)]
      | CRecordFailure =>
        eprefaces "Can't unify record constructors" []

exception SynUnif = E.SynUnif

open ElabOps

type record_summary = {
     fields : (L'.con * L'.con) list,
     unifs : (L'.con * L'.con option ref) list,
     others : L'.con list
}

fun summaryToCon {fields, unifs, others} =
    let
        val c = (L'.CRecord (ktype, []), dummy)
        val c = List.foldr (fn (c', c) => (L'.CConcat (c', c), dummy)) c others
        val c = List.foldr (fn ((c', _), c) => (L'.CConcat (c', c), dummy)) c unifs
    in
        (L'.CConcat ((L'.CRecord (ktype, fields), dummy), c), dummy)
    end

fun p_summary env s = p_con env (summaryToCon s)

exception CUnify of L'.con * L'.con * cunify_error

fun hnormKind (kAll as (k, _)) =
    case k of
        L'.KUnif (_, _, ref (SOME k)) => hnormKind k
      | _ => kAll

fun kindof env (c, loc) =
    case c of
        L'.TFun _ => ktype
      | L'.TCFun _ => ktype
      | L'.TDisjoint _ => ktype
      | L'.TRecord _ => ktype

      | L'.CRel xn => #2 (E.lookupCRel env xn)
      | L'.CNamed xn => #2 (E.lookupCNamed env xn)
      | L'.CModProj (n, ms, x) =>
        let
            val (_, sgn) = E.lookupStrNamed env n
            val (str, sgn) = foldl (fn (m, (str, sgn)) =>
                                       case E.projectStr env {sgn = sgn, str = str, field = m} of
                                           NONE => raise Fail "kindof: Unknown substructure"
                                         | SOME sgn => ((L'.StrProj (str, m), loc), sgn))
                             ((L'.StrVar n, loc), sgn) ms
        in
            case E.projectCon env {sgn = sgn, str = str, field = x} of
                NONE => raise Fail "kindof: Unknown con in structure"
              | SOME (k, _) => k
        end

      | L'.CApp (c, _) =>
        (case #1 (hnormKind (kindof env c)) of
             L'.KArrow (_, k) => k
           | L'.KError => kerror
           | _ => raise CUnify' (CKindof c))
      | L'.CAbs (x, k, c) => (L'.KArrow (k, kindof (E.pushCRel env x k) c), loc)
      | L'.CDisjoint (_, _, c) => kindof env c

      | L'.CName _ => kname

      | L'.CRecord (k, _) => (L'.KRecord k, loc)
      | L'.CConcat (c, _) => kindof env c
      | L'.CFold (dom, ran) => foldKind (dom, ran, loc)

      | L'.CUnit => (L'.KUnit, loc)

      | L'.CError => kerror
      | L'.CUnif (_, k, _, _) => k

val hnormCon = D.hnormCon

fun unifyRecordCons (env, denv) (c1, c2) =
    let
        fun rkindof c =
            case kindof env c of
                (L'.KRecord k, _) => k
              | _ => raise CUnify' (CKindof c)

        val k1 = rkindof c1
        val k2 = rkindof c2

        val (r1, gs1) = recordSummary (env, denv) c1
        val (r2, gs2) = recordSummary (env, denv) c2
    in
        unifyKinds k1 k2;
        unifySummaries (env, denv) (k1, r1, r2);
        gs1 @ gs2
    end

and recordSummary (env, denv) c =
    let
        val (c, gs) = hnormCon (env, denv) c

        val (sum, gs') =
            case c of
                (L'.CRecord (_, xcs), _) => ({fields = xcs, unifs = [], others = []}, [])
              | (L'.CConcat (c1, c2), _) =>
                let
                    val (s1, gs1) = recordSummary (env, denv) c1
                    val (s2, gs2) = recordSummary (env, denv) c2
                in
                    ({fields = #fields s1 @ #fields s2,
                      unifs = #unifs s1 @ #unifs s2,
                      others = #others s1 @ #others s2},
                     gs1 @ gs2)
                end
              | (L'.CUnif (_, _, _, ref (SOME c)), _) => recordSummary (env, denv) c
              | c' as (L'.CUnif (_, _, _, r), _) => ({fields = [], unifs = [(c', r)], others = []}, [])
              | c' => ({fields = [], unifs = [], others = [c']}, [])
    in
        (sum, gs @ gs')
    end

and consEq (env, denv) (c1, c2) =
    (case unifyCons (env, denv) c1 c2 of
         [] => true
       | _ => false)
    handle CUnify _ => false

and consNeq env (c1, c2) =
    case (#1 (ElabOps.hnormCon env c1), #1 (ElabOps.hnormCon env c2)) of
        (L'.CName x1, L'.CName x2) => x1 <> x2
      | _ => false

and unifySummaries (env, denv) (k, s1 : record_summary, s2 : record_summary) =
    let
        (*val () = eprefaces "Summaries" [("#1", p_summary env s1),
                                          ("#2", p_summary env s2)]*)

        fun eatMatching p (ls1, ls2) =
            let
                fun em (ls1, ls2, passed1) =
                    case ls1 of
                        [] => (rev passed1, ls2)
                      | h1 :: t1 =>
                        let
                            fun search (ls2', passed2) =
                                case ls2' of
                                    [] => em (t1, ls2, h1 :: passed1)
                                  | h2 :: t2 =>
                                    if p (h1, h2) then
                                        em (t1, List.revAppend (passed2, t2), passed1)
                                    else
                                        search (t2, h2 :: passed2)
                        in
                            search (ls2, [])
                        end
            in
                em (ls1, ls2, [])
            end

        val (fs1, fs2) = eatMatching (fn ((x1, c1), (x2, c2)) =>
                                         not (consNeq env (x1, x2))
                                         andalso consEq (env, denv) (c1, c2)
                                         andalso consEq (env, denv) (x1, x2))
                                     (#fields s1, #fields s2)
        (*val () = eprefaces "Summaries2" [("#1", p_summary env {fields = fs1, unifs = #unifs s1, others = #others s1}),
                                           ("#2", p_summary env {fields = fs2, unifs = #unifs s2, others = #others s2})]*)
        val (unifs1, unifs2) = eatMatching (fn ((_, r1), (_, r2)) => r1 = r2) (#unifs s1, #unifs s2)
        val (others1, others2) = eatMatching (consEq (env, denv)) (#others s1, #others s2)

        fun unifFields (fs, others, unifs) =
            case (fs, others, unifs) of
                ([], [], _) => ([], [], unifs)
              | (_, _, []) => (fs, others, [])
              | (_, _, (_, r) :: rest) =>
                let
                    val r' = ref NONE
                    val cr' = (L'.CUnif (dummy, k, "recd", r'), dummy)

                    val prefix = case (fs, others) of
                                     ([], other :: others) =>
                                     List.foldl (fn (other, c) =>
                                                    (L'.CConcat (c, other), dummy))
                                                other others
                                   | (fs, []) =>
                                     (L'.CRecord (k, fs), dummy)
                                   | (fs, others) =>
                                     List.foldl (fn (other, c) =>
                                                    (L'.CConcat (c, other), dummy))
                                                (L'.CRecord (k, fs), dummy) others
                in
                    r := SOME (L'.CConcat (prefix, cr'), dummy);
                    ([], [], (cr', r') :: rest)
                end

        val (fs1, others1, unifs2) = unifFields (fs1, others1, unifs2)
        val (fs2, others2, unifs1) = unifFields (fs2, others2, unifs1)

        val clear = case (fs1, others1, fs2, others2) of
                         ([], [], [], []) => true
                       | _ => false
        val empty = (L'.CRecord (k, []), dummy)
        fun pairOffUnifs (unifs1, unifs2) =
            case (unifs1, unifs2) of
                ([], _) =>
                if clear then
                    List.app (fn (_, r) => r := SOME empty) unifs2
                else
                    raise CUnify' CRecordFailure
              | (_, []) =>
                if clear then
                    List.app (fn (_, r) => r := SOME empty) unifs1
                else
                    raise CUnify' CRecordFailure
              | ((c1, _) :: rest1, (_, r2) :: rest2) =>
                (r2 := SOME c1;
                 pairOffUnifs (rest1, rest2))
    in
        pairOffUnifs (unifs1, unifs2)
    end

and unifyCons' (env, denv) c1 c2 =
    let
        val (c1, gs1) = hnormCon (env, denv) c1
        val (c2, gs2) = hnormCon (env, denv) c2
        val gs3 = unifyCons'' (env, denv) c1 c2
    in
        gs1 @ gs2 @ gs3
    end
    
and unifyCons'' (env, denv) (c1All as (c1, _)) (c2All as (c2, _)) =
    let
        fun err f = raise CUnify' (f (c1All, c2All))

        fun isRecord () = unifyRecordCons (env, denv) (c1All, c2All)
    in
        (*eprefaces "unifyCons''" [("c1All", p_con env c1All),
                                 ("c2All", p_con env c2All)];*)

        case (c1, c2) of
            (L'.CUnit, L'.CUnit) => []

          | (L'.TFun (d1, r1), L'.TFun (d2, r2)) =>
            unifyCons' (env, denv) d1 d2
            @ unifyCons' (env, denv) r1 r2
          | (L'.TCFun (expl1, x1, d1, r1), L'.TCFun (expl2, _, d2, r2)) =>
            if expl1 <> expl2 then
                err CExplicitness
            else
                (unifyKinds d1 d2;
                 unifyCons' (E.pushCRel env x1 d1, D.enter denv) r1 r2)
          | (L'.TRecord r1, L'.TRecord r2) => unifyCons' (env, denv) r1 r2

          | (L'.CRel n1, L'.CRel n2) =>
            if n1 = n2 then
                []
            else
                err CIncompatible
          | (L'.CNamed n1, L'.CNamed n2) =>
            if n1 = n2 then
                []
            else
                err CIncompatible

          | (L'.CApp (d1, r1), L'.CApp (d2, r2)) =>
            (unifyCons' (env, denv) d1 d2;
             unifyCons' (env, denv) r1 r2)
          | (L'.CAbs (x1, k1, c1), L'.CAbs (_, k2, c2)) =>
            (unifyKinds k1 k2;
             unifyCons' (E.pushCRel env x1 k1, D.enter denv) c1 c2)

          | (L'.CName n1, L'.CName n2) =>
            if n1 = n2 then
                []
            else
                err CIncompatible

          | (L'.CModProj (n1, ms1, x1), L'.CModProj (n2, ms2, x2)) =>
            if n1 = n2 andalso ms1 = ms2 andalso x1 = x2 then
                []
            else
                err CIncompatible

          | (L'.CError, _) => []
          | (_, L'.CError) => []

          | (L'.CRecord _, _) => isRecord ()
          | (_, L'.CRecord _) => isRecord ()
          | (L'.CConcat _, _) => isRecord ()
          | (_, L'.CConcat _) => isRecord ()
          (*| (L'.CUnif (_, (L'.KRecord _, _), _, _), _) => isRecord ()
          | (_, L'.CUnif (_, (L'.KRecord _, _), _, _)) => isRecord ()*)

          | (L'.CUnif (_, k1, _, r1), L'.CUnif (_, k2, _, r2)) =>
            if r1 = r2 then
                []
            else
                (unifyKinds k1 k2;
                 r1 := SOME c2All;
                 [])

          | (L'.CUnif (_, _, _, r), _) =>
            if occursCon r c2All then
                err COccursCheckFailed
            else
                (r := SOME c2All;
                 [])
          | (_, L'.CUnif (_, _, _, r)) =>
            if occursCon r c1All then
                err COccursCheckFailed
            else
                (r := SOME c1All;
                 [])


          | (L'.CFold (dom1, ran1), L'.CFold (dom2, ran2)) =>
            (unifyKinds dom1 dom2;
             unifyKinds ran1 ran2;
             [])

          | _ => err CIncompatible
    end

and unifyCons (env, denv) c1 c2 =
    unifyCons' (env, denv) c1 c2
    handle CUnify' err => raise CUnify (c1, c2, err)
         | KUnify args => raise CUnify (c1, c2, CKind args)

datatype exp_error =
       UnboundExp of ErrorMsg.span * string
     | UnboundStrInExp of ErrorMsg.span * string
     | Unify of L'.exp * L'.con * L'.con * cunify_error
     | Unif of string * L'.con
     | WrongForm of string * L'.exp * L'.con
     | IncompatibleCons of L'.con * L'.con

fun expError env err =
    case err of
        UnboundExp (loc, s) =>
        ErrorMsg.errorAt loc ("Unbound expression variable " ^ s)
      | UnboundStrInExp (loc, s) =>
        ErrorMsg.errorAt loc ("Unbound structure " ^ s)
      | Unify (e, c1, c2, uerr) =>
        (ErrorMsg.errorAt (#2 e) "Unification failure";
         eprefaces' [("Expression", p_exp env e),
                     ("Have con", p_con env c1),
                     ("Need con", p_con env c2)];
         cunifyError env uerr)
      | Unif (action, c) =>
        (ErrorMsg.errorAt (#2 c) ("Unification variable blocks " ^ action);
         eprefaces' [("Con", p_con env c)])
      | WrongForm (variety, e, t) =>
        (ErrorMsg.errorAt (#2 e) ("Expression is not a " ^ variety);
         eprefaces' [("Expression", p_exp env e),
                     ("Type", p_con env t)])
      | IncompatibleCons (c1, c2) =>
        (ErrorMsg.errorAt (#2 c1) "Incompatible constructors";
         eprefaces' [("Con 1", p_con env c1),
                     ("Con 2", p_con env c2)])

fun checkCon (env, denv) e c1 c2 =
    unifyCons (env, denv) c1 c2
    handle CUnify (c1, c2, err) =>
           (expError env (Unify (e, c1, c2, err));
            [])

fun primType env p =
    case p of
        P.Int _ => !int
      | P.Float _ => !float
      | P.String _ => !string

fun recCons (k, nm, v, rest, loc) =
    (L'.CConcat ((L'.CRecord (k, [(nm, v)]), loc),
                 rest), loc)

fun foldType (dom, loc) =
    (L'.TCFun (L'.Explicit, "ran", (L'.KArrow ((L'.KRecord dom, loc), (L'.KType, loc)), loc),
               (L'.TFun ((L'.TCFun (L'.Explicit, "nm", (L'.KName, loc),
                                    (L'.TCFun (L'.Explicit, "v", dom,
                                               (L'.TCFun (L'.Explicit, "rest", (L'.KRecord dom, loc),
                                                          (L'.TFun ((L'.CApp ((L'.CRel 3, loc), (L'.CRel 0, loc)), loc),
                                                                    (L'.CApp ((L'.CRel 3, loc),
                                                                              recCons (dom,
                                                                                       (L'.CRel 2, loc),
                                                                                       (L'.CRel 1, loc),
                                                                                       (L'.CRel 0, loc),
                                                                                       loc)), loc)), loc)),
                                                loc)), loc)), loc),
                         (L'.TFun ((L'.CApp ((L'.CRel 0, loc), (L'.CRecord (dom, []), loc)), loc),
                                   (L'.TCFun (L'.Explicit, "r", (L'.KRecord dom, loc),
                                              (L'.CApp ((L'.CRel 1, loc), (L'.CRel 0, loc)), loc)), loc)),
                          loc)), loc)), loc)

fun typeof env (e, loc) =
    case e of
        L'.EPrim p => primType env p
      | L'.ERel n => #2 (E.lookupERel env n)
      | L'.ENamed n => #2 (E.lookupENamed env n)
      | L'.EModProj (n, ms, x) =>
        let
            val (_, sgn) = E.lookupStrNamed env n
            val (str, sgn) = foldl (fn (m, (str, sgn)) =>
                                       case E.projectStr env {sgn = sgn, str = str, field = m} of
                                           NONE => raise Fail "kindof: Unknown substructure"
                                         | SOME sgn => ((L'.StrProj (str, m), loc), sgn))
                             ((L'.StrVar n, loc), sgn) ms
        in
            case E.projectVal env {sgn = sgn, str = str, field = x} of
                NONE => raise Fail "typeof: Unknown val in structure"
              | SOME t => t
        end

      | L'.EApp (e1, _) =>
        (case #1 (typeof env e1) of
             L'.TFun (_, c) => c
           | _ => raise Fail "typeof: Bad EApp")
      | L'.EAbs (_, _, ran, _) => ran
      | L'.ECApp (e1, c) =>
        (case #1 (typeof env e1) of
             L'.TCFun (_, _, _, c1) => subConInCon (0, c) c1
           | _ => raise Fail "typeof: Bad ECApp")
      | L'.ECAbs (expl, x, k, e1) => (L'.TCFun (expl, x, k, typeof (E.pushCRel env x k) e1), loc)

      | L'.ERecord xes => (L'.TRecord (L'.CRecord (ktype, map (fn (x, _, t) => (x, t)) xes), loc), loc)
      | L'.EField (_, _, {field, ...}) => field
      | L'.EFold dom => foldType (dom, loc)

      | L'.EError => cerror

fun elabHead (env, denv) (e as (_, loc)) t =
    let
        fun unravel (t, e) =
            let
                val (t, gs) = hnormCon (env, denv) t
            in
                case t of
                    (L'.TCFun (L'.Implicit, x, k, t'), _) =>
                    let
                        val u = cunif (loc, k)

                        val (e, t, gs') = unravel (subConInCon (0, u) t',
                                                   (L'.ECApp (e, u), loc))
                    in
                        (e, t, gs @ gs')
                    end
                  | _ => (e, t, gs)
            end
    in
        unravel (t, e)
    end

fun elabExp (env, denv) (eAll as (e, loc)) =
    let
        
    in
        (*eprefaces "elabExp" [("eAll", SourcePrint.p_exp eAll)];*)

        case e of
            L.EAnnot (e, t) =>
            let
                val (e', et, gs1) = elabExp (env, denv) e
                val (t', _, gs2) = elabCon (env, denv) t
                val gs3 = checkCon (env, denv) e' et t'
            in
                (e', t', gs1 @ gs2 @ gs3)
            end

          | L.EPrim p => ((L'.EPrim p, loc), primType env p, [])
          | L.EVar ([], s) =>
            (case E.lookupE env s of
                 E.NotBound =>
                 (expError env (UnboundExp (loc, s));
                  (eerror, cerror, []))
               | E.Rel (n, t) => ((L'.ERel n, loc), t, [])
               | E.Named (n, t) => ((L'.ENamed n, loc), t, []))
          | L.EVar (m1 :: ms, s) =>
            (case E.lookupStr env m1 of
                 NONE => (expError env (UnboundStrInExp (loc, m1));
                          (eerror, cerror, []))
               | SOME (n, sgn) =>
                 let
                     val (str, sgn) = foldl (fn (m, (str, sgn)) =>
                                                case E.projectStr env {sgn = sgn, str = str, field = m} of
                                                    NONE => (conError env (UnboundStrInCon (loc, m));
                                                             (strerror, sgnerror))
                                                  | SOME sgn => ((L'.StrProj (str, m), loc), sgn))
                                            ((L'.StrVar n, loc), sgn) ms

                     val t = case E.projectVal env {sgn = sgn, str = str, field = s} of
                                 NONE => (expError env (UnboundExp (loc, s));
                                          cerror)
                               | SOME t => t
                 in
                     ((L'.EModProj (n, ms, s), loc), t, [])
                 end)

          | L.EApp (arg as ((L.EApp ((L.ECApp ((L.EVar (["Basis"], "join"), _), (L.CWild _, _)), _), xml1), _), xml2)) =>
            let
                val (xml1', t1, gs1) = elabExp (env, denv) xml1
                val (xml2', t2, gs2) = elabExp (env, denv) xml2

                val kunit = (L'.KUnit, loc)
                val k = (L'.KRecord kunit, loc)

                val basis =
                    case E.lookupStr env "Basis" of
                        NONE => raise Fail "elabExp: Unbound Basis"
                      | SOME (n, _) => n

                fun xml () =
                    let
                        val ns = cunif (loc, k)
                    in
                        (ns, (L'.CApp ((L'.CModProj (basis, [], "xml"), loc), ns), loc))
                    end

                val (ns1, c1) = xml ()
                val (ns2, c2) = xml ()

                val gs3 = checkCon (env, denv) xml1' t1 c1
                val gs4 = checkCon (env, denv) xml2' t2 c2

                val (ns1, gs5) = hnormCon (env, denv) ns1
                val (ns2, gs6) = hnormCon (env, denv) ns2

                val cemp = (L'.CRecord (kunit, []), loc)

                val (shared, ctx1, ctx2) =
                    case (#1 ns1, #1 ns2) of
                        (L'.CRecord (_, ns1), L'.CRecord (_, ns2)) =>
                        let
                            val ns = List.filter (fn ((nm, _), _) =>
                                                     case nm of
                                                         L'.CName s =>
                                                         List.exists (fn ((L'.CName s', _), _) => s' = s
                                                                       | _ => false) ns2
                                                       | _ => false) ns1
                        in
                            ((L'.CRecord (kunit, ns), loc), cunif (loc, k), cunif (loc, k))
                        end
                      | (_, L'.CRecord _) => (ns2, cemp, cemp)
                      | _ => (ns1, cemp, cemp)

                val ns1' = (L'.CConcat (shared, ctx1), loc)
                val ns2' = (L'.CConcat (shared, ctx2), loc)

                val e = (L'.EModProj (basis, [], "join"), loc)
                val e = (L'.ECApp (e, shared), loc)
                val e = (L'.ECApp (e, ctx1), loc)
                val e = (L'.ECApp (e, ctx2), loc)
                val e = (L'.EApp (e, xml1'), loc)
                val e = (L'.EApp (e, xml2'), loc)

                val t = (L'.CApp ((L'.CModProj (basis, [], "xml"), loc), shared), loc)

                fun doUnify (ns, ns') =
                    let
                        fun setEmpty c =
                            let
                                val ((c, _), gs) = hnormCon (env, denv) c
                            in
                                case c of
                                    L'.CUnif (_, _, _, r) =>
                                    (r := SOME cemp;
                                     gs)
                                  | L'.CConcat (_, c') => setEmpty c' @ gs
                                  | _ => gs
                            end

                        val gs1 = unifyCons (env, denv) ns ns'
                        val gs2 = setEmpty ns'
                        val gs3 = unifyCons (env, denv) ns ns'
                    in
                        gs1 @ gs2 @ gs3
                    end handle CUnify _ => (expError env (IncompatibleCons (ns, ns'));
                                            [])

                val gs7 = doUnify (ns1, ns1')
                val gs8 = doUnify (ns2, ns2')
            in
                (e, t, (loc, env, denv, shared, ctx1)
                       :: (loc, env, denv, shared, ctx2)
                       :: gs1 @ gs2 @ gs3 @ gs4 @ gs5 @ gs6 @ gs7 @ gs8)
            end

          | L.EApp (e1, e2) =>
            let
                val (e1', t1, gs1) = elabExp (env, denv) e1
                val (e1', t1, gs2) = elabHead (env, denv) e1' t1
                val (e2', t2, gs3) = elabExp (env, denv) e2

                val dom = cunif (loc, ktype)
                val ran = cunif (loc, ktype)
                val t = (L'.TFun (dom, ran), dummy)

                val gs4 = checkCon (env, denv) e1' t1 t
                val gs5 = checkCon (env, denv) e2' t2 dom
            in
                ((L'.EApp (e1', e2'), loc), ran, gs1 @ gs2 @ gs3 @ gs4 @ gs5)
            end
          | L.EAbs (x, to, e) =>
            let
                val (t', gs1) = case to of
                                    NONE => (cunif (loc, ktype), [])
                                  | SOME t =>
                                    let
                                        val (t', tk, gs) = elabCon (env, denv) t
                                    in
                                        checkKind env t' tk ktype;
                                        (t', gs)
                                    end
                val (e', et, gs2) = elabExp (E.pushERel env x t', denv) e
            in
                ((L'.EAbs (x, t', et, e'), loc),
                 (L'.TFun (t', et), loc),
                 gs1 @ gs2)
            end
          | L.ECApp (e, c) =>
            let
                val (e', et, gs1) = elabExp (env, denv) e
                val (e', et, gs2) = elabHead (env, denv) e' et
                val (c', ck, gs3) = elabCon (env, denv) c
                val ((et', _), gs4) = hnormCon (env, denv) et
            in
                case et' of
                    L'.CError => (eerror, cerror, [])
                  | L'.TCFun (_, _, k, eb) =>
                    let
                        val () = checkKind env c' ck k
                        val eb' = subConInCon (0, c') eb
                            handle SynUnif => (expError env (Unif ("substitution", eb));
                                               cerror)
                    in
                        ((L'.ECApp (e', c'), loc), eb', gs1 @ gs2 @ gs3 @ gs4)
                    end

                  | L'.CUnif _ =>
                    (expError env (Unif ("application", et));
                     (eerror, cerror, []))

                  | _ =>
                    (expError env (WrongForm ("constructor function", e', et));
                     (eerror, cerror, []))
            end
          | L.ECAbs (expl, x, k, e) =>
            let
                val expl' = elabExplicitness expl
                val k' = elabKind k
                val (e', et, gs) = elabExp (E.pushCRel env x k', D.enter denv) e
            in
                ((L'.ECAbs (expl', x, k', e'), loc),
                 (L'.TCFun (expl', x, k', et), loc),
                 gs)
            end

          | L.EDisjoint (c1, c2, e) =>
            let
                val (c1', k1, gs1) = elabCon (env, denv) c1
                val (c2', k2, gs2) = elabCon (env, denv) c2

                val ku1 = kunif loc
                val ku2 = kunif loc

                val (denv', gs3) = D.assert env denv (c1', c2')
                val (e', t, gs4) = elabExp (env, denv') e
            in
                checkKind env c1' k1 (L'.KRecord ku1, loc);
                checkKind env c2' k2 (L'.KRecord ku2, loc);

                (e', (L'.TDisjoint (c1', c2', t), loc), gs1 @ gs2 @ gs3 @ gs4)
            end

          | L.ERecord xes =>
            let
                val (xes', gs) = ListUtil.foldlMap (fn ((x, e), gs) =>
                                                       let
                                                           val (x', xk, gs1) = elabCon (env, denv) x
                                                           val (e', et, gs2) = elabExp (env, denv) e
                                                       in
                                                           checkKind env x' xk kname;
                                                           ((x', e', et), gs1 @ gs2 @ gs)
                                                       end)
                                                   [] xes

                val k = (L'.KType, loc)

                fun prove (xets, gs) =
                    case xets of
                        [] => gs
                      | (x, _, t) :: rest =>
                        let
                            val xc = (x, t)
                            val r1 = (L'.CRecord (k, [xc]), loc)
                            val gs = foldl (fn ((x', _, t'), gs) =>
                                               let
                                                   val xc' = (x', t')
                                                   val r2 = (L'.CRecord (k, [xc']), loc)
                                               in
                                                   D.prove env denv (r1, r2, loc) @ gs
                                               end)
                                           gs rest
                        in
                            prove (rest, gs)
                        end
            in
                ((L'.ERecord xes', loc),
                 (L'.TRecord (L'.CRecord (ktype, map (fn (x', _, et) => (x', et)) xes'), loc), loc),
                 prove (xes', gs))
            end

          | L.EField (e, c) =>
            let
                val (e', et, gs1) = elabExp (env, denv) e
                val (c', ck, gs2) = elabCon (env, denv) c

                val ft = cunif (loc, ktype)
                val rest = cunif (loc, ktype_record)
                val first = (L'.CRecord (ktype, [(c', ft)]), loc)
                            
                val gs3 =
                    checkCon (env, denv) e' et
                             (L'.TRecord (L'.CConcat (first, rest), loc), loc)
                val gs4 = D.prove env denv (first, rest, loc)
            in
                ((L'.EField (e', c', {field = ft, rest = rest}), loc), ft, gs1 @ gs2 @ gs3 @ gs4)
            end

          | L.EFold =>
            let
                val dom = kunif loc
            in
                ((L'.EFold dom, loc), foldType (dom, loc), [])
            end
    end
            

datatype decl_error =
         KunifsRemain of L'.decl list
       | CunifsRemain of L'.decl list

fun lspan [] = ErrorMsg.dummySpan
  | lspan ((_, loc) :: _) = loc

fun declError env err =
    case err of
        KunifsRemain ds =>
        (ErrorMsg.errorAt (lspan ds) "Some kind unification variables are undetermined in declaration";
         eprefaces' [("Decl", p_list_sep PD.newline (p_decl env) ds)])
      | CunifsRemain ds =>
        (ErrorMsg.errorAt (lspan ds) "Some constructor unification variables are undetermined in declaration";
         eprefaces' [("Decl", p_list_sep PD.newline (p_decl env) ds)])

datatype sgn_error =
         UnboundSgn of ErrorMsg.span * string
       | UnmatchedSgi of L'.sgn_item
       | SgiWrongKind of L'.sgn_item * L'.kind * L'.sgn_item * L'.kind * kunify_error
       | SgiWrongCon of L'.sgn_item * L'.con * L'.sgn_item * L'.con * cunify_error
       | SgnWrongForm of L'.sgn * L'.sgn
       | UnWhereable of L'.sgn * string
       | WhereWrongKind of L'.kind * L'.kind * kunify_error
       | NotIncludable of L'.sgn
       | DuplicateCon of ErrorMsg.span * string
       | DuplicateVal of ErrorMsg.span * string
       | DuplicateSgn of ErrorMsg.span * string
       | DuplicateStr of ErrorMsg.span * string
       | NotConstraintsable of L'.sgn

fun sgnError env err =
    case err of
        UnboundSgn (loc, s) =>
        ErrorMsg.errorAt loc ("Unbound signature variable " ^ s)
      | UnmatchedSgi (sgi as (_, loc)) =>
        (ErrorMsg.errorAt loc "Unmatched signature item";
         eprefaces' [("Item", p_sgn_item env sgi)])
      | SgiWrongKind (sgi1, k1, sgi2, k2, kerr) =>
        (ErrorMsg.errorAt (#2 sgi1) "Kind unification failure in signature matching:";
         eprefaces' [("Have", p_sgn_item env sgi1),
                     ("Need", p_sgn_item env sgi2),
                     ("Kind 1", p_kind k1),
                     ("Kind 2", p_kind k2)];
         kunifyError kerr)
      | SgiWrongCon (sgi1, c1, sgi2, c2, cerr) =>
        (ErrorMsg.errorAt (#2 sgi1) "Constructor unification failure in signature matching:";
         eprefaces' [("Have", p_sgn_item env sgi1),
                     ("Need", p_sgn_item env sgi2),
                     ("Con 1", p_con env c1),
                     ("Con 2", p_con env c2)];
         cunifyError env cerr)
      | SgnWrongForm (sgn1, sgn2) =>
        (ErrorMsg.errorAt (#2 sgn1) "Incompatible signatures:";
         eprefaces' [("Sig 1", p_sgn env sgn1),
                     ("Sig 2", p_sgn env sgn2)])
      | UnWhereable (sgn, x) =>
        (ErrorMsg.errorAt (#2 sgn) "Unavailable field for 'where'";
         eprefaces' [("Signature", p_sgn env sgn),
                     ("Field", PD.string x)])
      | WhereWrongKind (k1, k2, kerr) =>
        (ErrorMsg.errorAt (#2 k1) "Wrong kind for 'where'";
         eprefaces' [("Have", p_kind k1),
                     ("Need", p_kind k2)];
         kunifyError kerr)
      | NotIncludable sgn =>
        (ErrorMsg.errorAt (#2 sgn) "Invalid signature to 'include'";
         eprefaces' [("Signature", p_sgn env sgn)])
      | DuplicateCon (loc, s) =>
        ErrorMsg.errorAt loc ("Duplicate constructor " ^ s ^ " in signature")
      | DuplicateVal (loc, s) =>
        ErrorMsg.errorAt loc ("Duplicate value " ^ s ^ " in signature")
      | DuplicateSgn (loc, s) =>
        ErrorMsg.errorAt loc ("Duplicate signature " ^ s ^ " in signature")
      | DuplicateStr (loc, s) =>
        ErrorMsg.errorAt loc ("Duplicate structure " ^ s ^ " in signature")
      | NotConstraintsable sgn =>
        (ErrorMsg.errorAt (#2 sgn) "Invalid signature for 'open constraints'";
         eprefaces' [("Signature", p_sgn env sgn)])

datatype str_error =
         UnboundStr of ErrorMsg.span * string
       | NotFunctor of L'.sgn
       | FunctorRebind of ErrorMsg.span
       | UnOpenable of L'.sgn
       | NotType of L'.kind * (L'.kind * L'.kind * kunify_error)

fun strError env err =
    case err of
        UnboundStr (loc, s) =>
        ErrorMsg.errorAt loc ("Unbound structure variable " ^ s)
      | NotFunctor sgn =>
        (ErrorMsg.errorAt (#2 sgn) "Application of non-functor";
         eprefaces' [("Signature", p_sgn env sgn)])
      | FunctorRebind loc =>
        ErrorMsg.errorAt loc "Attempt to rebind functor"
      | UnOpenable sgn =>
        (ErrorMsg.errorAt (#2 sgn) "Un-openable structure";
         eprefaces' [("Signature", p_sgn env sgn)])
      | NotType (k, (k1, k2, ue)) =>
        (ErrorMsg.errorAt (#2 k) "'val' type kind is not 'Type'";
         eprefaces' [("Kind", p_kind k),
                     ("Subkind 1", p_kind k1),
                     ("Subkind 2", p_kind k2)];
         kunifyError ue)

val hnormSgn = E.hnormSgn

fun elabSgn_item ((sgi, loc), (env, denv, gs)) =
    case sgi of
        L.SgiConAbs (x, k) =>
        let
            val k' = elabKind k

            val (env', n) = E.pushCNamed env x k' NONE
        in
            ([(L'.SgiConAbs (x, n, k'), loc)], (env', denv, gs))
        end

      | L.SgiCon (x, ko, c) =>
        let
            val k' = case ko of
                         NONE => kunif loc
                       | SOME k => elabKind k

            val (c', ck, gs') = elabCon (env, denv) c
            val (env', n) = E.pushCNamed env x k' (SOME c')
        in
            checkKind env c' ck k';

            ([(L'.SgiCon (x, n, k', c'), loc)], (env', denv, gs' @ gs))
        end

      | L.SgiVal (x, c) =>
        let
            val (c', ck, gs') = elabCon (env, denv) c

            val (env', n) = E.pushENamed env x c'
        in
            (unifyKinds ck ktype
             handle KUnify ue => strError env (NotType (ck, ue)));

            ([(L'.SgiVal (x, n, c'), loc)], (env', denv, gs' @ gs))
        end

      | L.SgiStr (x, sgn) =>
        let
            val (sgn', gs') = elabSgn (env, denv) sgn
            val (env', n) = E.pushStrNamed env x sgn'
        in
            ([(L'.SgiStr (x, n, sgn'), loc)], (env', denv, gs' @ gs))
        end

      | L.SgiSgn (x, sgn) =>
        let
            val (sgn', gs') = elabSgn (env, denv) sgn
            val (env', n) = E.pushSgnNamed env x sgn'
        in
            ([(L'.SgiSgn (x, n, sgn'), loc)], (env', denv, gs' @ gs))
        end

      | L.SgiInclude sgn =>
        let
            val (sgn', gs') = elabSgn (env, denv) sgn
        in
            case #1 (hnormSgn env sgn') of
                L'.SgnConst sgis =>
                (sgis, (foldl (fn (sgi, env) => E.sgiBinds env sgi) env sgis, denv, gs' @ gs))
              | _ => (sgnError env (NotIncludable sgn');
                      ([], (env, denv, [])))
        end

      | L.SgiConstraint (c1, c2) =>
        let
            val (c1', k1, gs1) = elabCon (env, denv) c1
            val (c2', k2, gs2) = elabCon (env, denv) c2

            val (denv, gs3) = D.assert env denv (c1', c2')
        in
            checkKind env c1' k1 (L'.KRecord (kunif loc), loc);
            checkKind env c2' k2 (L'.KRecord (kunif loc), loc);

            ([(L'.SgiConstraint (c1', c2'), loc)], (env, denv, gs1 @ gs2 @ gs3))
        end

and elabSgn (env, denv) (sgn, loc) =
    case sgn of
        L.SgnConst sgis =>
        let
            val (sgis', (_, _, gs)) = ListUtil.foldlMapConcat elabSgn_item (env, denv, []) sgis

            val _ = foldl (fn ((sgi, loc), (cons, vals, sgns, strs)) =>
                              case sgi of
                                  L'.SgiConAbs (x, _, _) =>
                                  (if SS.member (cons, x) then
                                       sgnError env (DuplicateCon (loc, x))
                                   else
                                       ();
                                   (SS.add (cons, x), vals, sgns, strs))
                                | L'.SgiCon (x, _, _, _) =>
                                  (if SS.member (cons, x) then
                                       sgnError env (DuplicateCon (loc, x))
                                   else
                                       ();
                                   (SS.add (cons, x), vals, sgns, strs))
                                | L'.SgiVal (x, _, _) =>
                                  (if SS.member (vals, x) then
                                       sgnError env (DuplicateVal (loc, x))
                                   else
                                       ();
                                   (cons, SS.add (vals, x), sgns, strs))
                                | L'.SgiSgn (x, _, _) =>
                                  (if SS.member (sgns, x) then
                                       sgnError env (DuplicateSgn (loc, x))
                                   else
                                       ();
                                   (cons, vals, SS.add (sgns, x), strs))
                                | L'.SgiStr (x, _, _) =>
                                  (if SS.member (strs, x) then
                                       sgnError env (DuplicateStr (loc, x))
                                   else
                                       ();
                                   (cons, vals, sgns, SS.add (strs, x)))
                                | L'.SgiConstraint _ => (cons, vals, sgns, strs))
                    (SS.empty, SS.empty, SS.empty, SS.empty) sgis'
        in
            ((L'.SgnConst sgis', loc), gs)
        end
      | L.SgnVar x =>
        (case E.lookupSgn env x of
             NONE =>
             (sgnError env (UnboundSgn (loc, x));
              ((L'.SgnError, loc), []))
           | SOME (n, sgis) => ((L'.SgnVar n, loc), []))
      | L.SgnFun (m, dom, ran) =>
        let
            val (dom', gs1) = elabSgn (env, denv) dom
            val (env', n) = E.pushStrNamed env m dom'
            val (ran', gs2) = elabSgn (env', denv) ran
        in
            ((L'.SgnFun (m, n, dom', ran'), loc), gs1 @ gs2)
        end
      | L.SgnWhere (sgn, x, c) =>
        let
            val (sgn', ds1) = elabSgn (env, denv) sgn
            val (c', ck, ds2) = elabCon (env, denv) c
        in
            case #1 (hnormSgn env sgn') of
                L'.SgnError => (sgnerror, [])
              | L'.SgnConst sgis =>
                if List.exists (fn (L'.SgiConAbs (x', _, k), _) =>
                                   x' = x andalso
                                   (unifyKinds k ck
                                    handle KUnify x => sgnError env (WhereWrongKind x);
                                    true)
                                 | _ => false) sgis then
                    ((L'.SgnWhere (sgn', x, c'), loc), ds1 @ ds2)
                else
                    (sgnError env (UnWhereable (sgn', x));
                     (sgnerror, []))
              | _ => (sgnError env (UnWhereable (sgn', x));
                      (sgnerror, []))
        end
      | L.SgnProj (m, ms, x) =>
        (case E.lookupStr env m of
             NONE => (strError env (UnboundStr (loc, m));
                      (sgnerror, []))
           | SOME (n, sgn) =>
             let
                 val (str, sgn) = foldl (fn (m, (str, sgn)) =>
                                          case E.projectStr env {sgn = sgn, str = str, field = m} of
                                              NONE => (strError env (UnboundStr (loc, m));
                                                       (strerror, sgnerror))
                                            | SOME sgn => ((L'.StrProj (str, m), loc), sgn))
                                ((L'.StrVar n, loc), sgn) ms
             in
                 case E.projectSgn env {sgn = sgn, str = str, field = x} of
                     NONE => (sgnError env (UnboundSgn (loc, x));
                              (sgnerror, []))
                   | SOME _ => ((L'.SgnProj (n, ms, x), loc), [])
             end)
                                                              

fun selfify env {str, strs, sgn} =
    case #1 (hnormSgn env sgn) of
        L'.SgnError => sgn
      | L'.SgnVar _ => sgn

      | L'.SgnConst sgis =>
        (L'.SgnConst (map (fn (L'.SgiConAbs (x, n, k), loc) =>
                              (L'.SgiCon (x, n, k, (L'.CModProj (str, strs, x), loc)), loc)
                            | (L'.SgiStr (x, n, sgn), loc) =>
                              (L'.SgiStr (x, n, selfify env {str = str, strs = strs @ [x], sgn = sgn}), loc)
                            | x => x) sgis), #2 sgn)
      | L'.SgnFun _ => sgn
      | L'.SgnWhere _ => sgn
      | L'.SgnProj (m, ms, x) =>
        case E.projectSgn env {str = foldl (fn (m, str) => (L'.StrProj (str, m), #2 sgn))
                                           (L'.StrVar m, #2 sgn) ms,
                               sgn = #2 (E.lookupStrNamed env m),
                               field = x} of
            NONE => raise Fail "Elaborate.selfify: projectSgn returns NONE"
          | SOME sgn => selfify env {str = str, strs = strs, sgn = sgn}

fun selfifyAt env {str, sgn} =
    let
        fun self (str, _) =
            case str of
                L'.StrVar x => SOME (x, [])
              | L'.StrProj (str, x) =>
                (case self str of
                     NONE => NONE
                   | SOME (m, ms) => SOME (m, ms @ [x]))
              | _ => NONE
    in
        case self str of
            NONE => sgn
          | SOME (str, strs) => selfify env {sgn = sgn, str = str, strs = strs}
    end

fun dopen (env, denv) {str, strs, sgn} =
    let
        val m = foldl (fn (m, str) => (L'.StrProj (str, m), #2 sgn))
                (L'.StrVar str, #2 sgn) strs
    in
        case #1 (hnormSgn env sgn) of
            L'.SgnConst sgis =>
            ListUtil.foldlMap (fn ((sgi, loc), (env', denv')) =>
                                  case sgi of
                                      L'.SgiConAbs (x, n, k) =>
                                      let
                                          val c = (L'.CModProj (str, strs, x), loc)
                                      in
                                          ((L'.DCon (x, n, k, c), loc),
                                           (E.pushCNamedAs env' x n k (SOME c), denv'))
                                      end
                                    | L'.SgiCon (x, n, k, c) =>
                                      ((L'.DCon (x, n, k, (L'.CModProj (str, strs, x), loc)), loc),
                                       (E.pushCNamedAs env' x n k (SOME c), denv'))
                                    | L'.SgiVal (x, n, t) =>
                                      ((L'.DVal (x, n, t, (L'.EModProj (str, strs, x), loc)), loc),
                                       (E.pushENamedAs env' x n t, denv'))
                                    | L'.SgiStr (x, n, sgn) =>
                                      ((L'.DStr (x, n, sgn, (L'.StrProj (m, x), loc)), loc),
                                       (E.pushStrNamedAs env' x n sgn, denv'))
                                    | L'.SgiSgn (x, n, sgn) =>
                                      ((L'.DSgn (x, n, (L'.SgnProj (str, strs, x), loc)), loc),
                                       (E.pushSgnNamedAs env' x n sgn, denv'))
                                    | L'.SgiConstraint (c1, c2) =>
                                      ((L'.DConstraint (c1, c2), loc),
                                       (env', denv (* D.assert env denv (c1, c2) *) )))
                              (env, denv) sgis
          | _ => (strError env (UnOpenable sgn);
                  ([], (env, denv)))
    end

fun dopenConstraints (loc, env, denv) {str, strs} =
    case E.lookupStr env str of
        NONE => (strError env (UnboundStr (loc, str));
                 denv)
      | SOME (n, sgn) =>
        let
            val (st, sgn) = foldl (fn (m, (str, sgn)) =>
                                      case E.projectStr env {str = str, sgn = sgn, field = m} of
                                          NONE => (strError env (UnboundStr (loc, m));
                                                   (strerror, sgnerror))
                                        | SOME sgn => ((L'.StrProj (str, m), loc), sgn))
                                  ((L'.StrVar n, loc), sgn) strs
                            
            val cso = E.projectConstraints env {sgn = sgn, str = st}

            val denv = case cso of
                           NONE => (strError env (UnboundStr (loc, str));
                                    denv)
                         | SOME cs => foldl (fn ((c1, c2), denv) =>
                                                let
                                                    val (denv, gs) = D.assert env denv (c1, c2)
                                                in
                                                    case gs of
                                                        [] => ()
                                                      | _ => raise Fail "dopenConstraints: Sub-constraints remain";

                                                    denv
                                                end) denv cs
        in
            denv
        end

fun sgiOfDecl (d, loc) =
    case d of
        L'.DCon (x, n, k, c) => [(L'.SgiCon (x, n, k, c), loc)]
      | L'.DVal (x, n, t, _) => [(L'.SgiVal (x, n, t), loc)]
      | L'.DValRec vis => map (fn (x, n, t, _) => (L'.SgiVal (x, n, t), loc)) vis
      | L'.DSgn (x, n, sgn) => [(L'.SgiSgn (x, n, sgn), loc)]
      | L'.DStr (x, n, sgn, _) => [(L'.SgiStr (x, n, sgn), loc)]
      | L'.DFfiStr (x, n, sgn) => [(L'.SgiStr (x, n, sgn), loc)]
      | L'.DConstraint cs => [(L'.SgiConstraint cs, loc)]
      | L'.DExport _ => []

fun sgiBindsD (env, denv) (sgi, _) =
    case sgi of
        L'.SgiConstraint (c1, c2) =>
        (case D.assert env denv (c1, c2) of
             (denv, []) => denv
           | _ => raise Fail "sgiBindsD: Sub-constraints remain")
      | _ => denv

fun subSgn (env, denv) sgn1 (sgn2 as (_, loc2)) =
    case (#1 (hnormSgn env sgn1), #1 (hnormSgn env sgn2)) of
        (L'.SgnError, _) => ()
      | (_, L'.SgnError) => ()

      | (L'.SgnConst sgis1, L'.SgnConst sgis2) =>
        let
            fun folder (sgi2All as (sgi, _), (env, denv)) =
                let
                    fun seek p =
                        let
                            fun seek (env, denv) ls =
                                case ls of
                                    [] => (sgnError env (UnmatchedSgi sgi2All);
                                           (env, denv))
                                  | h :: t =>
                                    case p h of
                                        NONE => seek (E.sgiBinds env h, sgiBindsD (env, denv) h) t
                                      | SOME envs => envs
                        in
                            seek (env, denv) sgis1
                        end
                in
                    case sgi of
                        L'.SgiConAbs (x, n2, k2) =>
                        seek (fn sgi1All as (sgi1, _) =>
                                 let
                                     fun found (x', n1, k1, co1) =
                                         if x = x' then
                                             let
                                                 val () = unifyKinds k1 k2
                                                     handle KUnify (k1, k2, err) =>
                                                            sgnError env (SgiWrongKind (sgi1All, k1, sgi2All, k2, err))
                                                 val env = E.pushCNamedAs env x n1 k1 co1
                                             in
                                                 SOME (if n1 = n2 then
                                                           env
                                                       else
                                                           E.pushCNamedAs env x n2 k2 (SOME (L'.CNamed n1, loc2)),
                                                       denv)
                                             end
                                         else
                                             NONE
                                 in
                                     case sgi1 of
                                         L'.SgiConAbs (x', n1, k1) => found (x', n1, k1, NONE)
                                       | L'.SgiCon (x', n1, k1, c1) => found (x', n1, k1, SOME c1)
                                       | _ => NONE
                                 end)

                      | L'.SgiCon (x, n2, k2, c2) =>
                        seek (fn sgi1All as (sgi1, _) =>
                                 case sgi1 of
                                     L'.SgiCon (x', n1, k1, c1) =>
                                     if x = x' then
                                         let
                                             fun good () = SOME (E.pushCNamedAs env x n2 k2 (SOME c2), denv)
                                         in
                                             (case unifyCons (env, denv) c1 c2 of
                                                  [] => good ()
                                                | _ => NONE)
                                             handle CUnify (c1, c2, err) =>
                                                    (sgnError env (SgiWrongCon (sgi1All, c1, sgi2All, c2, err));
                                                     good ())
                                         end
                                     else
                                         NONE
                                   | _ => NONE)

                      | L'.SgiVal (x, n2, c2) =>
                        seek (fn sgi1All as (sgi1, _) =>
                                 case sgi1 of
                                     L'.SgiVal (x', n1, c1) =>
                                     if x = x' then
                                         (case unifyCons (env, denv) c1 c2 of
                                              [] => SOME (env, denv)
                                            | _ => NONE)
                                         handle CUnify (c1, c2, err) =>
                                                (sgnError env (SgiWrongCon (sgi1All, c1, sgi2All, c2, err));
                                                 SOME (env, denv))
                                     else
                                         NONE
                                   | _ => NONE)

                      | L'.SgiStr (x, n2, sgn2) =>
                        seek (fn sgi1All as (sgi1, _) =>
                                 case sgi1 of
                                     L'.SgiStr (x', n1, sgn1) =>
                                     if x = x' then
                                         let
                                             val () = subSgn (env, denv) sgn1 sgn2
                                             val env = E.pushStrNamedAs env x n1 sgn1
                                             val env = if n1 = n2 then
                                                           env
                                                       else
                                                           E.pushStrNamedAs env x n2
                                                                            (selfifyAt env {str = (L'.StrVar n1, #2 sgn2),
                                                                                            sgn = sgn2})
                                         in
                                             SOME (env, denv)
                                         end
                                     else
                                         NONE
                                   | _ => NONE)

                      | L'.SgiSgn (x, n2, sgn2) =>
                        seek (fn sgi1All as (sgi1, _) =>
                                 case sgi1 of
                                     L'.SgiSgn (x', n1, sgn1) =>
                                     if x = x' then
                                         let
                                             val () = subSgn (env, denv) sgn1 sgn2
                                             val () = subSgn (env, denv) sgn2 sgn1

                                             val env = E.pushSgnNamedAs env x n2 sgn2
                                             val env = if n1 = n2 then
                                                           env
                                                       else
                                                           E.pushSgnNamedAs env x n1 sgn2
                                         in
                                             SOME (env, denv)
                                         end
                                     else
                                         NONE
                                   | _ => NONE)

                      | L'.SgiConstraint (c2, d2) =>
                        seek (fn sgi1All as (sgi1, _) =>
                                 case sgi1 of
                                     L'.SgiConstraint (c1, d1) =>
                                     if consEq (env, denv) (c1, c2) andalso consEq (env, denv) (d1, d2) then
                                         let
                                             val (denv, gs) = D.assert env denv (c2, d2)
                                         in
                                             case gs of
                                                 [] => ()
                                               | _ => raise Fail "subSgn: Sub-constraints remain";

                                             SOME (env, denv)
                                         end
                                     else
                                         NONE
                                   | _ => NONE)
                end
        in
            ignore (foldl folder (env, denv) sgis2)
        end

      | (L'.SgnFun (m1, n1, dom1, ran1), L'.SgnFun (m2, n2, dom2, ran2)) =>
        let
            val ran1 =
                if n1 = n2 then
                    ran1
                else
                    subStrInSgn (n1, n2) ran1
        in
            subSgn (env, denv) dom2 dom1;
            subSgn (E.pushStrNamedAs env m2 n2 dom2, denv) ran1 ran2
        end

      | _ => sgnError env (SgnWrongForm (sgn1, sgn2))


fun elabDecl ((d, loc), (env, denv, gs)) =
    case d of
        L.DCon (x, ko, c) =>
        let
            val k' = case ko of
                         NONE => kunif loc
                       | SOME k => elabKind k

            val (c', ck, gs') = elabCon (env, denv) c
            val (env', n) = E.pushCNamed env x k' (SOME c')
        in
            checkKind env c' ck k';

            ([(L'.DCon (x, n, k', c'), loc)], (env', denv, gs' @ gs))
        end
      | L.DVal (x, co, e) =>
        let
            val (c', _, gs1) = case co of
                                    NONE => (cunif (loc, ktype), ktype, [])
                                  | SOME c => elabCon (env, denv) c

            val (e', et, gs2) = elabExp (env, denv) e
            val (env', n) = E.pushENamed env x c'

            val gs3 = checkCon (env, denv) e' et c'
        in
            ([(L'.DVal (x, n, c', e'), loc)], (env', denv, gs1 @ gs2 @ gs3 @ gs))
        end
      | L.DValRec vis =>
        let
            val (vis, gs) = ListUtil.foldlMap
                                (fn ((x, co, e), gs) =>
                                    let
                                        val (c', _, gs1) = case co of
                                                               NONE => (cunif (loc, ktype), ktype, [])
                                                             | SOME c => elabCon (env, denv) c
                                    in
                                        ((x, c', e), gs1 @ gs)
                                    end) [] vis

            val (vis, env) = ListUtil.foldlMap (fn ((x, c', e), env) =>
                                                   let
                                                       val (env, n) = E.pushENamed env x c'
                                                   in
                                                       ((x, n, c', e), env)
                                                   end) env vis

            val (vis, gs) = ListUtil.foldlMap (fn ((x, n, c', e), gs) =>
                                                  let
                                                      val (e', et, gs1) = elabExp (env, denv) e
                                                                          
                                                      val gs2 = checkCon (env, denv) e' et c'
                                                  in
                                                      ((x, n, c', e'), gs1 @ gs2 @ gs)
                                                  end) gs vis
        in
            ([(L'.DValRec vis, loc)], (env, denv, gs))
        end

      | L.DSgn (x, sgn) =>
        let
            val (sgn', gs') = elabSgn (env, denv) sgn
            val (env', n) = E.pushSgnNamed env x sgn'
        in
            ([(L'.DSgn (x, n, sgn'), loc)], (env', denv, gs' @ gs))
        end

      | L.DStr (x, sgno, str) =>
        let
            val () = if x = "Basis" then
                         raise Fail "Not allowed to redefine structure 'Basis'"
                     else
                         ()

            val formal = Option.map (elabSgn (env, denv)) sgno

            val (str', sgn', gs') =
                case formal of
                    NONE =>
                    let
                        val (str', actual, ds) = elabStr (env, denv) str
                    in
                        (str', selfifyAt env {str = str', sgn = actual}, ds)
                    end
                  | SOME (formal, gs1) =>
                    let
                        val str =
                            case #1 (hnormSgn env formal) of
                                L'.SgnConst sgis =>
                                (case #1 str of
                                     L.StrConst ds =>
                                     let
                                         val needed = foldl (fn ((sgi, _), needed) =>
                                                                case sgi of
                                                                    L'.SgiConAbs (x, _, _) => SS.add (needed, x)
                                                                  | _ => needed)
                                                            SS.empty sgis
                                                      
                                         val needed = foldl (fn ((d, _), needed) =>
                                                                case d of
                                                                    L.DCon (x, _, _) => (SS.delete (needed, x)
                                                                                         handle NotFound => needed)
                                                                  | L.DOpen _ => SS.empty
                                                                  | _ => needed)
                                                            needed ds
                                     in
                                         case SS.listItems needed of
                                             [] => str
                                           | xs =>
                                             let
                                                 val kwild = (L.KWild, #2 str)
                                                 val cwild = (L.CWild kwild, #2 str)
                                                 val ds' = map (fn x => (L.DCon (x, NONE, cwild), #2 str)) xs
                                             in
                                                 (L.StrConst (ds @ ds'), #2 str)
                                             end
                                     end
                                   | _ => str)
                              | _ => str

                        val (str', actual, gs2) = elabStr (env, denv) str
                    in
                        subSgn (env, denv) actual formal;
                        (str', formal, gs1 @ gs2)
                    end

            val (env', n) = E.pushStrNamed env x sgn'
        in
            case #1 (hnormSgn env sgn') of
                L'.SgnFun _ =>
                (case #1 str' of
                     L'.StrFun _ => ()
                   | _ => strError env (FunctorRebind loc))
              | _ => ();

            ([(L'.DStr (x, n, sgn', str'), loc)], (env', denv, gs' @ gs))
        end

      | L.DFfiStr (x, sgn) =>
        let
            val (sgn', gs') = elabSgn (env, denv) sgn

            val (env', n) = E.pushStrNamed env x sgn'
        in
            ([(L'.DFfiStr (x, n, sgn'), loc)], (env', denv, gs' @ gs))
        end

      | L.DOpen (m, ms) =>
        (case E.lookupStr env m of
             NONE => (strError env (UnboundStr (loc, m));
                      ([], (env, denv, [])))
           | SOME (n, sgn) =>
             let
                 val (_, sgn) = foldl (fn (m, (str, sgn)) =>
                                          case E.projectStr env {str = str, sgn = sgn, field = m} of
                                              NONE => (strError env (UnboundStr (loc, m));
                                                       (strerror, sgnerror))
                                            | SOME sgn => ((L'.StrProj (str, m), loc), sgn))
                                      ((L'.StrVar n, loc), sgn) ms

                 val (ds, (env', denv')) = dopen (env, denv) {str = n, strs = ms, sgn = sgn}
                 val denv' = dopenConstraints (loc, env', denv') {str = m, strs = ms}
             in
                 (ds, (env', denv', []))
             end)

      | L.DConstraint (c1, c2) =>
        let
            val (c1', k1, gs1) = elabCon (env, denv) c1
            val (c2', k2, gs2) = elabCon (env, denv) c2
            val gs3 = D.prove env denv (c1', c2', loc)

            val (denv', gs4) = D.assert env denv (c1', c2')
        in
            checkKind env c1' k1 (L'.KRecord (kunif loc), loc);
            checkKind env c2' k2 (L'.KRecord (kunif loc), loc);

            ([(L'.DConstraint (c1', c2'), loc)], (env, denv', gs1 @ gs2 @ gs3 @ gs4))
        end

      | L.DOpenConstraints (m, ms) =>
        let
            val denv = dopenConstraints (loc, env, denv) {str = m, strs = ms}
        in
            ([], (env, denv, []))
        end

      | L.DExport str =>
        let
            val (str', sgn, gs) = elabStr (env, denv) str

            val sgn =
                case #1 (hnormSgn env sgn) of
                    L'.SgnConst sgis =>
                    let
                        fun doOne (all as (sgi, _)) =
                            case sgi of
                                L'.SgiVal (x, n, t) =>
                                (case hnormCon (env, denv) t of
                                     ((L'.TFun (dom, ran), _), []) =>
                                     (case (hnormCon (env, denv) dom, hnormCon (env, denv) ran) of
                                          (((L'.TRecord domR, _), []),
                                           ((L'.CApp (tf, ranR), _), [])) =>
                                          (case (hnormCon (env, denv) tf, hnormCon (env, denv) ranR) of
                                               ((tf, []), (ranR, [])) =>
                                               (case (hnormCon (env, denv) domR, hnormCon (env, denv) ranR) of
                                                    ((domR, []), (ranR, [])) =>
                                                    (L'.SgiVal (x, n, (L'.TFun ((L'.TRecord domR, loc),
                                                                                (L'.CApp (tf, ranR), loc)),
                                                                       loc)), loc)
                                                  | _ => all)
                                             | _ => all)
                                        | _ => all)
                                   | _ => all)
                              | _ => all
                    in
                        (L'.SgnConst (map doOne sgis), loc)
                    end
                  | _ => sgn
        in
            ([(L'.DExport (E.newNamed (), sgn, str'), loc)], (env, denv, gs))
        end

and elabStr (env, denv) (str, loc) =
    case str of
        L.StrConst ds =>
        let
            val (ds', (_, _, gs)) = ListUtil.foldlMapConcat elabDecl (env, denv, []) ds
            val sgis = ListUtil.mapConcat sgiOfDecl ds'

            val (sgis, _, _, _, _) =
                foldr (fn ((sgi, loc), (sgis, cons, vals, sgns, strs)) =>
                          case sgi of
                              L'.SgiConAbs (x, n, k) =>
                              let
                                  val (cons, x) =
                                      if SS.member (cons, x) then
                                          (cons, "?" ^ x)
                                      else
                                          (SS.add (cons, x), x)
                              in
                                  ((L'.SgiConAbs (x, n, k), loc) :: sgis, cons, vals, sgns, strs)
                              end
                            | L'.SgiCon (x, n, k, c) =>
                              let
                                  val (cons, x) =
                                      if SS.member (cons, x) then
                                          (cons, "?" ^ x)
                                      else
                                          (SS.add (cons, x), x)
                              in
                                  ((L'.SgiCon (x, n, k, c), loc) :: sgis, cons, vals, sgns, strs)
                              end
                            | L'.SgiVal (x, n, c) =>
                              let
                                  val (vals, x) =
                                      if SS.member (vals, x) then
                                          (vals, "?" ^ x)
                                      else
                                          (SS.add (vals, x), x)
                              in
                                  ((L'.SgiVal (x, n, c), loc) :: sgis, cons, vals, sgns, strs)
                              end
                            | L'.SgiSgn (x, n, sgn) =>
                              let
                                  val (sgns, x) =
                                      if SS.member (sgns, x) then
                                          (sgns, "?" ^ x)
                                      else
                                          (SS.add (sgns, x), x)
                              in
                                  ((L'.SgiSgn (x, n, sgn), loc) :: sgis, cons, vals, sgns, strs)
                              end
 
                            | L'.SgiStr (x, n, sgn) =>
                              let
                                  val (strs, x) =
                                      if SS.member (strs, x) then
                                          (strs, "?" ^ x)
                                      else
                                          (SS.add (strs, x), x)
                              in
                                  ((L'.SgiStr (x, n, sgn), loc) :: sgis, cons, vals, sgns, strs)
                              end
                            | L'.SgiConstraint _ => ((sgi, loc) :: sgis, cons, vals, sgns, strs))

                ([], SS.empty, SS.empty, SS.empty, SS.empty) sgis
        in
            ((L'.StrConst ds', loc), (L'.SgnConst sgis, loc), gs)
        end
      | L.StrVar x =>
        (case E.lookupStr env x of
             NONE =>
             (strError env (UnboundStr (loc, x));
              (strerror, sgnerror, []))
           | SOME (n, sgn) => ((L'.StrVar n, loc), sgn, []))
      | L.StrProj (str, x) =>
        let
            val (str', sgn, gs) = elabStr (env, denv) str
        in
            case E.projectStr env {str = str', sgn = sgn, field = x} of
                NONE => (strError env (UnboundStr (loc, x));
                         (strerror, sgnerror, []))
              | SOME sgn => ((L'.StrProj (str', x), loc), sgn, gs)
        end
      | L.StrFun (m, dom, ranO, str) =>
        let
            val (dom', gs1) = elabSgn (env, denv) dom
            val (env', n) = E.pushStrNamed env m dom'
            val (str', actual, gs2) = elabStr (env', denv) str

            val (formal, gs3) =
                case ranO of
                    NONE => (actual, [])
                  | SOME ran =>
                    let
                        val (ran', gs) = elabSgn (env', denv) ran
                    in
                        subSgn (env', denv) actual ran';
                        (ran', gs)
                    end
        in
            ((L'.StrFun (m, n, dom', formal, str'), loc),
             (L'.SgnFun (m, n, dom', formal), loc),
             gs1 @ gs2 @ gs3)
        end
      | L.StrApp (str1, str2) =>
        let
            val (str1', sgn1, gs1) = elabStr (env, denv) str1
            val (str2', sgn2, gs2) = elabStr (env, denv) str2
        in
            case #1 (hnormSgn env sgn1) of
                L'.SgnError => (strerror, sgnerror, [])
              | L'.SgnFun (m, n, dom, ran) =>
                (subSgn (env, denv) sgn2 dom;
                 case #1 (hnormSgn env ran) of
                     L'.SgnError => (strerror, sgnerror, [])
                   | L'.SgnConst sgis =>
                     ((L'.StrApp (str1', str2'), loc),
                      (L'.SgnConst ((L'.SgiStr (m, n, selfifyAt env {str = str2', sgn = sgn2}), loc) :: sgis), loc),
                      gs1 @ gs2)
                   | _ => raise Fail "Unable to hnormSgn in functor application")
              | _ => (strError env (NotFunctor sgn1);
                      (strerror, sgnerror, []))
        end

fun elabFile basis env file =
    let
        val (sgn, gs) = elabSgn (env, D.empty) (L.SgnConst basis, ErrorMsg.dummySpan)
        val () = case gs of
                     [] => ()
                   | _ => raise Fail "Unresolved disjointness constraints in Basis"

        val (env', basis_n) = E.pushStrNamed env "Basis" sgn

        val (ds, (env', _)) = dopen (env', D.empty) {str = basis_n, strs = [], sgn = sgn}

        fun discoverC r x =
            case E.lookupC env' x of
                E.NotBound => raise Fail ("Constructor " ^ x ^ " unbound in Basis")
              | E.Rel _ => raise Fail ("Constructor " ^ x ^ " bound relatively in Basis")
              | E.Named (n, (_, loc)) => r := (L'.CNamed n, loc)

        val () = discoverC int "int"
        val () = discoverC float "float"
        val () = discoverC string "string"

        fun elabDecl' (d, (env, gs)) =
            let
                val () = resetKunif ()
                val () = resetCunif ()
                val (ds, (env, _, gs)) = elabDecl (d, (env, D.empty, gs))
            in
                if ErrorMsg.anyErrors () then
                    ()
                else (
                    if List.exists kunifsInDecl ds then
                        declError env (KunifsRemain ds)
                    else
                        ();
                    
                    case ListUtil.search cunifsInDecl ds of
                        NONE => ()
                      | SOME loc =>
                        declError env (CunifsRemain ds)
                    );

                (ds, (env, gs))
            end

        val (file, (_, gs)) = ListUtil.foldlMapConcat elabDecl' (env', []) file
    in
        if ErrorMsg.anyErrors () then
            ()
        else
            app (fn (loc, env, denv, c1, c2) =>
                    case D.prove env denv (c1, c2, loc) of
                        [] => ()
                      | _ =>
                        (ErrorMsg.errorAt loc "Couldn't prove field name disjointness";
                         eprefaces' [("Con 1", p_con env c1),
                                     ("Con 2", p_con env c2),
                                     ("Hnormed 1", p_con env (ElabOps.hnormCon env c1)),
                                     ("Hnormed 2", p_con env (ElabOps.hnormCon env c2))])) gs;

        (L'.DFfiStr ("Basis", basis_n, sgn), ErrorMsg.dummySpan) :: ds @ file
    end

end