Mercurial > urweb
view src/elab_util.sml @ 203:dd82457fda82
Parsing and elaborating 'table'
author | Adam Chlipala <adamc@hcoop.net> |
---|---|
date | Thu, 14 Aug 2008 13:20:29 -0400 |
parents | ab86aa858e6c |
children | cb8f69556975 |
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 ElabUtil :> ELAB_UTIL = struct open Elab fun classifyDatatype xncs = case xncs of [(_, _, NONE), (_, _, SOME _)] => Option | [(_, _, SOME _), (_, _, NONE)] => Option | _ => if List.all (fn (_, _, NONE) => true | _ => false) xncs then Enum else Default structure S = Search structure Kind = struct fun mapfold f = let fun mfk k acc = S.bindP (mfk' k acc, f) and mfk' (kAll as (k, loc)) = case k of KType => S.return2 kAll | KArrow (k1, k2) => S.bind2 (mfk k1, fn k1' => S.map2 (mfk k2, fn k2' => (KArrow (k1', k2'), loc))) | KName => S.return2 kAll | KRecord k => S.map2 (mfk k, fn k' => (KRecord k', loc)) | KUnit => S.return2 kAll | KError => S.return2 kAll | KUnif (_, _, ref (SOME k)) => mfk' k | KUnif _ => S.return2 kAll in mfk end fun exists f k = case mapfold (fn k => fn () => if f k then S.Return () else S.Continue (k, ())) k () of S.Return _ => true | S.Continue _ => false end structure Con = struct datatype binder = Rel of string * Elab.kind | Named of string * Elab.kind fun mapfoldB {kind = fk, con = fc, bind} = let val mfk = Kind.mapfold fk fun mfc ctx c acc = S.bindP (mfc' ctx c acc, fc ctx) and mfc' ctx (cAll as (c, loc)) = case c of TFun (c1, c2) => S.bind2 (mfc ctx c1, fn c1' => S.map2 (mfc ctx c2, fn c2' => (TFun (c1', c2'), loc))) | TCFun (e, x, k, c) => S.bind2 (mfk k, fn k' => S.map2 (mfc (bind (ctx, Rel (x, k))) c, fn c' => (TCFun (e, x, k', c'), loc))) | TDisjoint (c1, c2, c3) => S.bind2 (mfc ctx c1, fn c1' => S.bind2 (mfc ctx c2, fn c2' => S.map2 (mfc ctx c3, fn c3' => (TDisjoint (c1', c2', c3'), loc)))) | TRecord c => S.map2 (mfc ctx c, fn c' => (TRecord c', loc)) | CRel _ => S.return2 cAll | CNamed _ => S.return2 cAll | CModProj _ => S.return2 cAll | CApp (c1, c2) => S.bind2 (mfc ctx c1, fn c1' => S.map2 (mfc ctx c2, fn c2' => (CApp (c1', c2'), loc))) | CAbs (x, k, c) => S.bind2 (mfk k, fn k' => S.map2 (mfc (bind (ctx, Rel (x, k))) c, fn c' => (CAbs (x, k', c'), loc))) | CDisjoint (c1, c2, c3) => S.bind2 (mfc ctx c1, fn c1' => S.bind2 (mfc ctx c2, fn c2' => S.map2 (mfc ctx c3, fn c3' => (CDisjoint (c1', c2', c3'), loc)))) | CName _ => S.return2 cAll | CRecord (k, xcs) => S.bind2 (mfk k, fn k' => S.map2 (ListUtil.mapfold (fn (x, c) => S.bind2 (mfc ctx x, fn x' => S.map2 (mfc ctx c, fn c' => (x', c')))) xcs, fn xcs' => (CRecord (k', xcs'), loc))) | CConcat (c1, c2) => S.bind2 (mfc ctx c1, fn c1' => S.map2 (mfc ctx c2, fn c2' => (CConcat (c1', c2'), loc))) | CFold (k1, k2) => S.bind2 (mfk k1, fn k1' => S.map2 (mfk k2, fn k2' => (CFold (k1', k2'), loc))) | CUnit => S.return2 cAll | CError => S.return2 cAll | CUnif (_, _, _, ref (SOME c)) => mfc' ctx c | CUnif _ => S.return2 cAll in mfc end fun mapfold {kind = fk, con = fc} = mapfoldB {kind = fk, con = fn () => fc, bind = fn ((), _) => ()} () fun mapB {kind, con, bind} ctx c = case mapfoldB {kind = fn k => fn () => S.Continue (kind k, ()), con = fn ctx => fn c => fn () => S.Continue (con ctx c, ()), bind = bind} ctx c () of S.Continue (c, ()) => c | S.Return _ => raise Fail "ElabUtil.Con.mapB: Impossible" fun map {kind, con} s = case mapfold {kind = fn k => fn () => S.Continue (kind k, ()), con = fn c => fn () => S.Continue (con c, ())} s () of S.Return () => raise Fail "ElabUtil.Con.map: Impossible" | S.Continue (s, ()) => s fun exists {kind, con} k = case mapfold {kind = fn k => fn () => if kind k then S.Return () else S.Continue (k, ()), con = fn c => fn () => if con c then S.Return () else S.Continue (c, ())} k () of S.Return _ => true | S.Continue _ => false end structure Exp = struct datatype binder = RelC of string * Elab.kind | NamedC of string * Elab.kind | RelE of string * Elab.con | NamedE of string * Elab.con fun mapfoldB {kind = fk, con = fc, exp = fe, bind} = let val mfk = Kind.mapfold fk fun bind' (ctx, b) = let val b' = case b of Con.Rel x => RelC x | Con.Named x => NamedC x in bind (ctx, b') end val mfc = Con.mapfoldB {kind = fk, con = fc, bind = bind'} fun mfe ctx e acc = S.bindP (mfe' ctx e acc, fe ctx) and mfe' ctx (eAll as (e, loc)) = case e of EPrim _ => S.return2 eAll | ERel _ => S.return2 eAll | ENamed _ => S.return2 eAll | EModProj _ => S.return2 eAll | EApp (e1, e2) => S.bind2 (mfe ctx e1, fn e1' => S.map2 (mfe ctx e2, fn e2' => (EApp (e1', e2'), loc))) | EAbs (x, dom, ran, e) => S.bind2 (mfc ctx dom, fn dom' => S.bind2 (mfc ctx ran, fn ran' => S.map2 (mfe (bind (ctx, RelE (x, dom'))) e, fn e' => (EAbs (x, dom', ran', e'), loc)))) | ECApp (e, c) => S.bind2 (mfe ctx e, fn e' => S.map2 (mfc ctx c, fn c' => (ECApp (e', c'), loc))) | ECAbs (expl, x, k, e) => S.bind2 (mfk k, fn k' => S.map2 (mfe (bind (ctx, RelC (x, k))) e, fn e' => (ECAbs (expl, x, k', e'), loc))) | ERecord xes => S.map2 (ListUtil.mapfold (fn (x, e, t) => S.bind2 (mfc ctx x, fn x' => S.bind2 (mfe ctx e, fn e' => S.map2 (mfc ctx t, fn t' => (x', e', t'))))) xes, fn xes' => (ERecord xes', loc)) | EField (e, c, {field, rest}) => S.bind2 (mfe ctx e, fn e' => S.bind2 (mfc ctx c, fn c' => S.bind2 (mfc ctx field, fn field' => S.map2 (mfc ctx rest, fn rest' => (EField (e', c', {field = field', rest = rest'}), loc))))) | ECut (e, c, {field, rest}) => S.bind2 (mfe ctx e, fn e' => S.bind2 (mfc ctx c, fn c' => S.bind2 (mfc ctx field, fn field' => S.map2 (mfc ctx rest, fn rest' => (ECut (e', c', {field = field', rest = rest'}), loc))))) | EFold k => S.map2 (mfk k, fn k' => (EFold k', loc)) | ECase (e, pes, {disc, result}) => S.bind2 (mfe ctx e, fn e' => S.bind2 (ListUtil.mapfold (fn (p, e) => S.map2 (mfe ctx e, fn e' => (p, e'))) pes, fn pes' => S.bind2 (mfc ctx disc, fn disc' => S.map2 (mfc ctx result, fn result' => (ECase (e', pes', {disc = disc', result = result'}), loc))))) | EError => S.return2 eAll in mfe end fun mapfold {kind = fk, con = fc, exp = fe} = mapfoldB {kind = fk, con = fn () => fc, exp = fn () => fe, bind = fn ((), _) => ()} () fun exists {kind, con, exp} k = case mapfold {kind = fn k => fn () => if kind k then S.Return () else S.Continue (k, ()), con = fn c => fn () => if con c then S.Return () else S.Continue (c, ()), exp = fn e => fn () => if exp e then S.Return () else S.Continue (e, ())} k () of S.Return _ => true | S.Continue _ => false end structure Sgn = struct datatype binder = RelC of string * Elab.kind | NamedC of string * Elab.kind | Str of string * Elab.sgn | Sgn of string * Elab.sgn fun mapfoldB {kind, con, sgn_item, sgn, bind} = let fun bind' (ctx, b) = let val b' = case b of Con.Rel x => RelC x | Con.Named x => NamedC x in bind (ctx, b') end val con = Con.mapfoldB {kind = kind, con = con, bind = bind'} val kind = Kind.mapfold kind fun sgi ctx si acc = S.bindP (sgi' ctx si acc, sgn_item ctx) and sgi' ctx (siAll as (si, loc)) = case si of SgiConAbs (x, n, k) => S.map2 (kind k, fn k' => (SgiConAbs (x, n, k'), loc)) | SgiCon (x, n, k, c) => S.bind2 (kind k, fn k' => S.map2 (con ctx c, fn c' => (SgiCon (x, n, k', c'), loc))) | SgiDatatype (x, n, xs, xncs) => S.map2 (ListUtil.mapfold (fn (x, n, c) => case c of NONE => S.return2 (x, n, c) | SOME c => S.map2 (con ctx c, fn c' => (x, n, SOME c'))) xncs, fn xncs' => (SgiDatatype (x, n, xs, xncs'), loc)) | SgiDatatypeImp (x, n, m1, ms, s, xs, xncs) => S.map2 (ListUtil.mapfold (fn (x, n, c) => case c of NONE => S.return2 (x, n, c) | SOME c => S.map2 (con ctx c, fn c' => (x, n, SOME c'))) xncs, fn xncs' => (SgiDatatypeImp (x, n, m1, ms, s, xs, xncs'), loc)) | SgiVal (x, n, c) => S.map2 (con ctx c, fn c' => (SgiVal (x, n, c'), loc)) | SgiStr (x, n, s) => S.map2 (sg ctx s, fn s' => (SgiStr (x, n, s'), loc)) | SgiSgn (x, n, s) => S.map2 (sg ctx s, fn s' => (SgiSgn (x, n, s'), loc)) | SgiConstraint (c1, c2) => S.bind2 (con ctx c1, fn c1' => S.map2 (con ctx c2, fn c2' => (SgiConstraint (c1', c2'), loc))) | SgiTable (x, n, c) => S.map2 (con ctx c, fn c' => (SgiTable (x, n, c'), loc)) and sg ctx s acc = S.bindP (sg' ctx s acc, sgn ctx) and sg' ctx (sAll as (s, loc)) = case s of SgnConst sgis => S.map2 (ListUtil.mapfoldB (fn (ctx, si) => (case #1 si of SgiConAbs (x, _, k) => bind (ctx, NamedC (x, k)) | SgiCon (x, _, k, _) => bind (ctx, NamedC (x, k)) | SgiDatatype (x, n, _, xncs) => bind (ctx, NamedC (x, (KType, loc))) | SgiDatatypeImp (x, _, _, _, _, _, _) => bind (ctx, NamedC (x, (KType, loc))) | SgiVal _ => ctx | SgiStr (x, _, sgn) => bind (ctx, Str (x, sgn)) | SgiSgn (x, _, sgn) => bind (ctx, Sgn (x, sgn)) | SgiConstraint _ => ctx | SgiTable _ => ctx, sgi ctx si)) ctx sgis, fn sgis' => (SgnConst sgis', loc)) | SgnVar _ => S.return2 sAll | SgnFun (m, n, s1, s2) => S.bind2 (sg ctx s1, fn s1' => S.map2 (sg (bind (ctx, Str (m, s1'))) s2, fn s2' => (SgnFun (m, n, s1', s2'), loc))) | SgnProj _ => S.return2 sAll | SgnWhere (sgn, x, c) => S.bind2 (sg ctx sgn, fn sgn' => S.map2 (con ctx c, fn c' => (SgnWhere (sgn', x, c'), loc))) | SgnError => S.return2 sAll in sg end fun mapfold {kind, con, sgn_item, sgn} = mapfoldB {kind = kind, con = fn () => con, sgn_item = fn () => sgn_item, sgn = fn () => sgn, bind = fn ((), _) => ()} () fun map {kind, con, sgn_item, sgn} s = case mapfold {kind = fn k => fn () => S.Continue (kind k, ()), con = fn c => fn () => S.Continue (con c, ()), sgn_item = fn si => fn () => S.Continue (sgn_item si, ()), sgn = fn s => fn () => S.Continue (sgn s, ())} s () of S.Return () => raise Fail "Elab_util.Sgn.map" | S.Continue (s, ()) => s end structure Decl = struct datatype binder = RelC of string * Elab.kind | NamedC of string * Elab.kind | RelE of string * Elab.con | NamedE of string * Elab.con | Str of string * Elab.sgn | Sgn of string * Elab.sgn fun mapfoldB {kind = fk, con = fc, exp = fe, sgn_item = fsgi, sgn = fsg, str = fst, decl = fd, bind} = let val mfk = Kind.mapfold fk fun bind' (ctx, b) = let val b' = case b of Con.Rel x => RelC x | Con.Named x => NamedC x in bind (ctx, b') end val mfc = Con.mapfoldB {kind = fk, con = fc, bind = bind'} fun bind' (ctx, b) = let val b' = case b of Exp.RelC x => RelC x | Exp.NamedC x => NamedC x | Exp.RelE x => RelE x | Exp.NamedE x => NamedE x in bind (ctx, b') end val mfe = Exp.mapfoldB {kind = fk, con = fc, exp = fe, bind = bind'} fun bind' (ctx, b) = let val b' = case b of Sgn.RelC x => RelC x | Sgn.NamedC x => NamedC x | Sgn.Sgn x => Sgn x | Sgn.Str x => Str x in bind (ctx, b') end val mfsg = Sgn.mapfoldB {kind = fk, con = fc, sgn_item = fsgi, sgn = fsg, bind = bind'} fun mfst ctx str acc = S.bindP (mfst' ctx str acc, fst ctx) and mfst' ctx (strAll as (str, loc)) = case str of StrConst ds => S.map2 (ListUtil.mapfoldB (fn (ctx, d) => (case #1 d of DCon (x, _, k, _) => bind (ctx, NamedC (x, k)) | DDatatype (x, n, xs, xncs) => let val ctx = bind (ctx, NamedC (x, (KType, loc))) in foldl (fn ((x, _, co), ctx) => let val t = case co of NONE => CNamed n | SOME t => TFun (t, (CNamed n, loc)) val k = (KType, loc) val t = (t, loc) val t = foldr (fn (x, t) => (TCFun (Explicit, x, k, t), loc)) t xs in bind (ctx, NamedE (x, t)) end) ctx xncs end | DDatatypeImp (x, n, m, ms, x', _, _) => bind (ctx, NamedC (x, (KType, loc))) | DVal (x, _, c, _) => bind (ctx, NamedE (x, c)) | DValRec vis => foldl (fn ((x, _, c, _), ctx) => bind (ctx, NamedE (x, c))) ctx vis | DSgn (x, _, sgn) => bind (ctx, Sgn (x, sgn)) | DStr (x, _, sgn, _) => bind (ctx, Str (x, sgn)) | DFfiStr (x, _, sgn) => bind (ctx, Str (x, sgn)) | DConstraint _ => ctx | DExport _ => ctx | DTable _ => ctx, mfd ctx d)) ctx ds, fn ds' => (StrConst ds', loc)) | StrVar _ => S.return2 strAll | StrProj (str, x) => S.map2 (mfst ctx str, fn str' => (StrProj (str', x), loc)) | StrFun (x, n, sgn1, sgn2, str) => S.bind2 (mfsg ctx sgn1, fn sgn1' => S.bind2 (mfsg ctx sgn2, fn sgn2' => S.map2 (mfst ctx str, fn str' => (StrFun (x, n, sgn1', sgn2', str'), loc)))) | StrApp (str1, str2) => S.bind2 (mfst ctx str1, fn str1' => S.map2 (mfst ctx str2, fn str2' => (StrApp (str1', str2'), loc))) | StrError => S.return2 strAll and mfd ctx d acc = S.bindP (mfd' ctx d acc, fd ctx) and mfd' ctx (dAll as (d, loc)) = case d of DCon (x, n, k, c) => S.bind2 (mfk k, fn k' => S.map2 (mfc ctx c, fn c' => (DCon (x, n, k', c'), loc))) | DDatatype (x, n, xs, xncs) => S.map2 (ListUtil.mapfold (fn (x, n, c) => case c of NONE => S.return2 (x, n, c) | SOME c => S.map2 (mfc ctx c, fn c' => (x, n, SOME c'))) xncs, fn xncs' => (DDatatype (x, n, xs, xncs'), loc)) | DDatatypeImp (x, n, m1, ms, s, xs, xncs) => S.map2 (ListUtil.mapfold (fn (x, n, c) => case c of NONE => S.return2 (x, n, c) | SOME c => S.map2 (mfc ctx c, fn c' => (x, n, SOME c'))) xncs, fn xncs' => (DDatatypeImp (x, n, m1, ms, s, xs, xncs'), loc)) | DVal vi => S.map2 (mfvi ctx vi, fn vi' => (DVal vi', loc)) | DValRec vis => S.map2 (ListUtil.mapfold (mfvi ctx) vis, fn vis' => (DValRec vis', loc)) | DSgn (x, n, sgn) => S.map2 (mfsg ctx sgn, fn sgn' => (DSgn (x, n, sgn'), loc)) | DStr (x, n, sgn, str) => S.bind2 (mfsg ctx sgn, fn sgn' => S.map2 (mfst ctx str, fn str' => (DStr (x, n, sgn', str'), loc))) | DFfiStr (x, n, sgn) => S.map2 (mfsg ctx sgn, fn sgn' => (DFfiStr (x, n, sgn'), loc)) | DConstraint (c1, c2) => S.bind2 (mfc ctx c1, fn c1' => S.map2 (mfc ctx c2, fn c2' => (DConstraint (c1', c2'), loc))) | DExport (en, sgn, str) => S.bind2 (mfsg ctx sgn, fn sgn' => S.map2 (mfst ctx str, fn str' => (DExport (en, sgn', str'), loc))) | DTable (x, n, c) => S.map2 (mfc ctx c, fn c' => (DTable (x, n, c'), loc)) and mfvi ctx (x, n, c, e) = S.bind2 (mfc ctx c, fn c' => S.map2 (mfe ctx e, fn e' => (x, n, c', e'))) in mfd end fun mapfold {kind, con, exp, sgn_item, sgn, str, decl} = mapfoldB {kind = kind, con = fn () => con, exp = fn () => exp, sgn_item = fn () => sgn_item, sgn = fn () => sgn, str = fn () => str, decl = fn () => decl, bind = fn ((), _) => ()} () fun exists {kind, con, exp, sgn_item, sgn, str, decl} k = case mapfold {kind = fn k => fn () => if kind k then S.Return () else S.Continue (k, ()), con = fn c => fn () => if con c then S.Return () else S.Continue (c, ()), exp = fn e => fn () => if exp e then S.Return () else S.Continue (e, ()), sgn_item = fn sgi => fn () => if sgn_item sgi then S.Return () else S.Continue (sgi, ()), sgn = fn x => fn () => if sgn x then S.Return () else S.Continue (x, ()), str = fn x => fn () => if str x then S.Return () else S.Continue (x, ()), decl = fn x => fn () => if decl x then S.Return () else S.Continue (x, ())} k () of S.Return _ => true | S.Continue _ => false fun search {kind, con, exp, sgn_item, sgn, str, decl} k = case mapfold {kind = fn x => fn () => case kind x of NONE => S.Continue (x, ()) | SOME v => S.Return v, con = fn x => fn () => case con x of NONE => S.Continue (x, ()) | SOME v => S.Return v, exp = fn x => fn () => case exp x of NONE => S.Continue (x, ()) | SOME v => S.Return v, sgn_item = fn x => fn () => case sgn_item x of NONE => S.Continue (x, ()) | SOME v => S.Return v, sgn = fn x => fn () => case sgn x of NONE => S.Continue (x, ()) | SOME v => S.Return v, str = fn x => fn () => case str x of NONE => S.Continue (x, ()) | SOME v => S.Return v, decl = fn x => fn () => case decl x of NONE => S.Continue (x, ()) | SOME v => S.Return v } k () of S.Return x => SOME x | S.Continue _ => NONE end end