Mercurial > urweb
view src/elaborate.sml @ 10:dde5c52e5e5e
Start of elaborating expressions
| author | Adam Chlipala <adamc@hcoop.net> |
|---|---|
| date | Fri, 28 Mar 2008 13:59:03 -0400 |
| parents | 14b533dbe6cc |
| children | e97c6d335869 |
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(* 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 L = Source structure L' = Elab structure E = ElabEnv structure U = ElabUtil open Print open ElabPrint 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) 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'.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 | WrongKind of L'.con * L'.kind * L'.kind * kunify_error fun conError env err = case err of UnboundCon (loc, s) => ErrorMsg.errorAt loc ("Unbound constructor variable " ^ 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) 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 cerror = (L'.CError, dummy) val kerror = (L'.KError, dummy) val eerror = (L'.EError, dummy) local val count = ref 0 in fun resetKunif () = count := 0 fun kunif () = 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 (s, ref NONE), dummy) end end local val count = ref 0 in fun resetCunif () = count := 0 fun cunif 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 (k, s, ref NONE), dummy) end end fun elabCon env (c, loc) = case c of L.CAnnot (c, k) => let val k' = elabKind k val (c', ck) = elabCon env c in checkKind env c' ck k'; (c', k') end | L.TFun (t1, t2) => let val (t1', k1) = elabCon env t1 val (t2', k2) = elabCon env t2 in checkKind env t1' k1 ktype; checkKind env t2' k2 ktype; ((L'.TFun (t1', t2'), loc), ktype) 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) = elabCon env' t in checkKind env t' tk ktype; ((L'.TCFun (e', x, k', t'), loc), ktype) end | L.TRecord c => let val (c', ck) = elabCon env c val k = (L'.KRecord ktype, loc) in checkKind env c' ck k; ((L'.TRecord c', loc), ktype) 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.CApp (c1, c2) => let val (c1', k1) = elabCon env c1 val (c2', k2) = elabCon env c2 val dom = kunif () val ran = kunif () in checkKind env c1' k1 (L'.KArrow (dom, ran), loc); checkKind env c2' k2 dom; ((L'.CApp (c1', c2'), loc), ran) end | L.CAbs (x, k, t) => let val k' = elabKind k val env' = E.pushCRel env x k' val (t', tk) = elabCon env' t in ((L'.CAbs (x, k', t'), loc), (L'.KArrow (k', tk), loc)) end | L.CName s => ((L'.CName s, loc), kname) | L.CRecord xcs => let val k = kunif () val xcs' = map (fn (x, c) => let val (x', xk) = elabCon env x val (c', ck) = elabCon env c in checkKind env x' xk kname; checkKind env c' ck k; (x', c') end) xcs in ((L'.CRecord (k, xcs'), loc), (L'.KRecord k, loc)) end | L.CConcat (c1, c2) => let val (c1', k1) = elabCon env c1 val (c2', k2) = elabCon env c2 val ku = kunif () val k = (L'.KRecord ku, loc) in checkKind env c1' k1 k; checkKind env c2' k2 k; ((L'.CConcat (c1', c2'), loc), k) end fun kunifsRemain k = case k of L'.KUnif (_, ref NONE) => true | _ => false fun cunifsRemain c = case c of L'.CUnif (_, _, ref NONE) => true | _ => false val kunifsInKind = U.Kind.exists kunifsRemain val kunifsInCon = U.Con.exists {kind = kunifsRemain, con = fn _ => false} val kunifsInExp = U.Exp.exists {kind = kunifsRemain, con = fn _ => false, exp = fn _ => false} val cunifsInCon = U.Con.exists {kind = fn _ => false, con = cunifsRemain} val cunifsInExp = U.Exp.exists {kind = fn _ => false, con = cunifsRemain, exp = fn _ => false} 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 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)] fun unifyCons' env (c1All as (c1, _)) (c2All as (c2, _)) = let fun err f = raise CUnify' (f (c1All, c2All)) in case (c1, c2) of (L'.TFun (d1, r1), L'.TFun (d2, r2)) => (unifyCons' env d1 d2; unifyCons' env 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) r1 r2) | (L'.TRecord r1, L'.TRecord r2) => unifyCons' env 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 d1 d2; unifyCons' env r1 r2) | (L'.CAbs (x1, k1, c1), L'.CAbs (_, k2, c2)) => (unifyKinds k1 k2; unifyCons' (E.pushCRel env x1 k1) c1 c2) | (L'.CName n1, L'.CName n2) => if n1 = n2 then () else err CIncompatible | (L'.CRecord (k1, rs1), L'.CRecord (k2, rs2)) => (unifyKinds k1 k2; ((ListPair.appEq (fn ((n1, v1), (n2, v2)) => (unifyCons' env n1 n2; unifyCons' env v1 v2)) (rs1, rs2)) handle ListPair.UnequalLengths => err CIncompatible)) | (L'.CConcat (d1, r1), L'.CConcat (d2, r2)) => (unifyCons' env d1 d2; unifyCons' env r1 r2) | (L'.CError, _) => () | (_, L'.CError) => () | (L'.CUnif (_, _, ref (SOME c1All)), _) => unifyCons' env c1All c2All | (_, L'.CUnif (_, _, ref (SOME c2All))) => unifyCons' env c1All c2All | (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 | _ => err CIncompatible end exception CUnify of L'.con * L'.con * cunify_error fun unifyCons env c1 c2 = unifyCons' env 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 | Unify of L'.exp * L'.con * L'.con * cunify_error fun expError env err = case err of UnboundExp (loc, s) => ErrorMsg.errorAt loc ("Unbound expression variable " ^ 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) fun checkCon env e c1 c2 = unifyCons env c1 c2 handle CUnify (c1, c2, err) => expError env (Unify (e, c1, c2, err)) fun elabExp env (e, loc) = case e of L.EAnnot (e, t) => let val (e', et) = elabExp env e val (t', _) = elabCon env t in checkCon env e' et t'; (e', t') end | 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.EApp (e1, e2) => let val (e1', t1) = elabExp env e1 val (e2', t2) = elabExp env e2 val dom = cunif ktype val ran = cunif ktype val t = (L'.TFun (dom, ran), dummy) in checkCon env e1' t1 t; checkCon env e2' t2 dom; ((L'.EApp (e1', e2'), loc), ran) end | L.EAbs (x, to, e) => let val t' = case to of NONE => cunif ktype | SOME t => let val (t', tk) = elabCon env t in checkKind env t' tk ktype; t' end val (e', et) = elabExp (E.pushERel env x t') e in ((L'.EAbs (x, t', e'), loc), (L'.TFun (t', et), loc)) end | L.ECApp (e, c) => let val (e', et) = elabExp env e val (c', ck) = elabCon env c in raise Fail "ECApp" end | L.ECAbs _ => raise Fail "ECAbs" datatype decl_error = KunifsRemainKind of ErrorMsg.span * L'.kind | KunifsRemainCon of ErrorMsg.span * L'.con | KunifsRemainExp of ErrorMsg.span * L'.exp | CunifsRemainCon of ErrorMsg.span * L'.con | CunifsRemainExp of ErrorMsg.span * L'.exp fun declError env err = case err of KunifsRemainKind (loc, k) => (ErrorMsg.errorAt loc "Some kind unification variables are undetermined in kind"; eprefaces' [("Kind", p_kind k)]) | KunifsRemainCon (loc, c) => (ErrorMsg.errorAt loc "Some kind unification variables are undetermined in constructor"; eprefaces' [("Constructor", p_con env c)]) | KunifsRemainExp (loc, e) => (ErrorMsg.errorAt loc "Some kind unification variables are undetermined in expression"; eprefaces' [("Expression", p_exp env e)]) | CunifsRemainCon (loc, c) => (ErrorMsg.errorAt loc "Some constructor unification variables are undetermined in constructor"; eprefaces' [("Constructor", p_con env c)]) | CunifsRemainExp (loc, e) => (ErrorMsg.errorAt loc "Some constructor unification variables are undetermined in expression"; eprefaces' [("Expression", p_exp env e)]) fun elabDecl env (d, loc) = (resetKunif (); case d of L.DCon (x, ko, c) => let val k' = case ko of NONE => kunif () | SOME k => elabKind k val (c', ck) = elabCon env c val (env', n) = E.pushCNamed env x k' in checkKind env c' ck k'; if kunifsInKind k' then declError env (KunifsRemainKind (loc, k')) else (); if kunifsInCon c' then declError env (KunifsRemainCon (loc, c')) else (); (env', (L'.DCon (x, n, k', c'), loc)) end | L.DVal (x, co, e) => let val (c', ck) = case co of NONE => (cunif ktype, ktype) | SOME c => elabCon env c val (e', et) = elabExp env e val (env', n) = E.pushENamed env x c' in checkCon env e' et c'; if kunifsInCon c' then declError env (KunifsRemainCon (loc, c')) else (); if cunifsInCon c' then declError env (CunifsRemainCon (loc, c')) else (); if kunifsInExp e' then declError env (KunifsRemainExp (loc, e')) else (); if cunifsInExp e' then declError env (CunifsRemainExp (loc, e')) else (); (env', (L'.DVal (x, n, c', e'), loc)) end) fun elabFile env ds = ListUtil.mapfoldl (fn (d, env) => elabDecl env d) env ds end