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view src/elab_env.sml @ 2307:6ae9a2784a45
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| author | Adam Chlipala <adam@chlipala.net> |
|---|---|
| date | Sun, 20 Dec 2015 14:39:50 -0500 |
| parents | 100352dbae36 |
| children |
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(* Copyright (c) 2008-2009, 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 ElabEnv :> ELAB_ENV = struct open Elab structure U = ElabUtil structure IM = IntBinaryMap structure SM = BinaryMapFn(struct type ord_key = string val compare = String.compare end) exception UnboundRel of int exception UnboundNamed of int (* AST utility functions *) val liftKindInKind = U.Kind.mapB {kind = fn bound => fn k => case k of KRel xn => if xn < bound then k else KRel (xn + 1) | _ => k, bind = fn (bound, _) => bound + 1} val liftKindInCon = U.Con.mapB {kind = fn bound => fn k => case k of KRel xn => if xn < bound then k else KRel (xn + 1) | _ => k, con = fn _ => fn c => c, bind = fn (bound, U.Con.RelK _) => bound + 1 | (bound, _) => bound} val liftConInCon = U.Con.mapB {kind = fn _ => fn k => k, con = fn bound => fn c => case c of CRel xn => if xn < bound then c else CRel (xn + 1) | CUnif (nl, loc, k, s, r) => CUnif (nl+1, loc, k, s, r) | _ => c, bind = fn (bound, U.Con.RelC _) => bound + 1 | (bound, _) => bound} val lift = liftConInCon 0 fun mliftConInCon by c = if by = 0 then c else U.Con.mapB {kind = fn _ => fn k => k, con = fn bound => fn c => case c of CRel xn => if xn < bound then c else CRel (xn + by) | CUnif (nl, loc, k, s, r) => CUnif (nl+by, loc, k, s, r) | _ => c, bind = fn (bound, U.Con.RelC _) => bound + 1 | (bound, _) => bound} 0 c val () = U.mliftConInCon := mliftConInCon val liftKindInExp = U.Exp.mapB {kind = fn bound => fn k => case k of KRel xn => if xn < bound then k else KRel (xn + 1) | _ => k, con = fn _ => fn c => c, exp = fn _ => fn e => e, bind = fn (bound, U.Exp.RelK _) => bound + 1 | (bound, _) => bound} val liftConInExp = U.Exp.mapB {kind = fn _ => fn k => k, con = fn bound => fn c => case c of CRel xn => if xn < bound then c else CRel (xn + 1) | CUnif (nl, loc, k, s, r) => CUnif (nl+1, loc, k, s, r) | _ => c, exp = fn _ => fn e => e, bind = fn (bound, U.Exp.RelC _) => bound + 1 | (bound, _) => bound} val liftExpInExp = U.Exp.mapB {kind = fn _ => fn k => k, con = fn _ => fn c => c, exp = fn bound => fn e => case e of ERel xn => if xn < bound then e else ERel (xn + 1) | _ => e, bind = fn (bound, U.Exp.RelE _) => bound + 1 | (bound, _) => bound} val liftExp = liftExpInExp 0 val subExpInExp = U.Exp.mapB {kind = fn _ => fn k => k, con = fn _ => fn c => c, exp = fn (xn, rep) => fn e => case e of ERel xn' => (case Int.compare (xn', xn) of EQUAL => #1 rep | GREATER=> ERel (xn' - 1) | LESS => e) | _ => e, bind = fn ((xn, rep), U.Exp.RelE _) => (xn+1, liftExpInExp 0 rep) | ((xn, rep), U.Exp.RelC _) => (xn, liftConInExp 0 rep) | (ctx, _) => ctx} (* Back to environments *) datatype 'a var' = Rel' of int * 'a | Named' of int * 'a datatype 'a var = NotBound | Rel of int * 'a | Named of int * 'a type datatyp = string list * (string * con option) IM.map datatype class_name = ClNamed of int | ClProj of int * string list * string fun class_name_out cn = case cn of ClNamed n => (CNamed n, ErrorMsg.dummySpan) | ClProj x => (CModProj x, ErrorMsg.dummySpan) fun cn2s cn = case cn of ClNamed n => "Named(" ^ Int.toString n ^ ")" | ClProj (m, ms, x) => "Proj(" ^ Int.toString m ^ "," ^ String.concatWith "," ms ^ "," ^ x ^ ")" structure CK = struct type ord_key = class_name open Order fun compare x = case x of (ClNamed n1, ClNamed n2) => Int.compare (n1, n2) | (ClNamed _, _) => LESS | (_, ClNamed _) => GREATER | (ClProj (m1, ms1, x1), ClProj (m2, ms2, x2)) => join (Int.compare (m1, m2), fn () => join (joinL String.compare (ms1, ms2), fn () => String.compare (x1, x2))) end structure CS = BinarySetFn(CK) structure CM = BinaryMapFn(CK) type rules = (int * con list * con * exp) list type class = {closedRules : rules, openRules : rules} val empty_class = {closedRules = [], openRules = []} type env = { renameK : int SM.map, relK : string list, renameC : kind var' SM.map, relC : (string * kind) list, namedC : (string * kind * con option) IM.map, datatypes : datatyp IM.map, constructors : (datatype_kind * int * string list * con option * int) SM.map, classes : class CM.map, renameE : con var' SM.map, relE : (string * con) list, namedE : (string * con) IM.map, renameSgn : (int * sgn) SM.map, sgn : (string * sgn) IM.map, renameStr : (int * sgn) SM.map, str : (string * sgn) IM.map } fun dump (env : env) = (print "NamedC:\n"; IM.appi (fn (n, (x, k, co)) => print (x ^ " [" ^ Int.toString n ^ "]\n")) (#namedC env)) val namedCounter = ref 0 fun newNamed () = let val r = !namedCounter in namedCounter := r + 1; r end val empty = { renameK = SM.empty, relK = [], renameC = SM.empty, relC = [], namedC = IM.empty, datatypes = IM.empty, constructors = SM.empty, classes = CM.empty, renameE = SM.empty, relE = [], namedE = IM.empty, renameSgn = SM.empty, sgn = IM.empty, renameStr = SM.empty, str = IM.empty } fun pushKRel (env : env) x = let val renameK = SM.map (fn n => n+1) (#renameK env) in {renameK = SM.insert (renameK, x, 0), relK = x :: #relK env, renameC = SM.map (fn Rel' (n, k) => Rel' (n, liftKindInKind 0 k) | x => x) (#renameC env), relC = map (fn (x, k) => (x, liftKindInKind 0 k)) (#relC env), namedC = #namedC env, datatypes = #datatypes env, constructors = #constructors env, classes = CM.map (fn cl => {closedRules = #closedRules cl, openRules = map (fn (nvs, cs, c, e) => (nvs, map (liftKindInCon 0) cs, liftKindInCon 0 c, liftKindInExp 0 e)) (#openRules cl)}) (#classes env), renameE = SM.map (fn Rel' (n, c) => Rel' (n, liftKindInCon 0 c) | Named' (n, c) => Named' (n, c)) (#renameE env), relE = map (fn (x, c) => (x, liftKindInCon 0 c)) (#relE env), namedE = #namedE env, renameSgn = #renameSgn env, sgn = #sgn env, renameStr = #renameStr env, str = #str env } end fun lookupKRel (env : env) n = (List.nth (#relK env, n)) handle Subscript => raise UnboundRel n fun lookupK (env : env) x = SM.find (#renameK env, x) fun pushCRel (env : env) x k = let val renameC = SM.map (fn Rel' (n, k) => Rel' (n+1, k) | x => x) (#renameC env) in {renameK = #renameK env, relK = #relK env, renameC = SM.insert (renameC, x, Rel' (0, k)), relC = (x, k) :: #relC env, namedC = #namedC env, datatypes = #datatypes env, constructors = #constructors env, classes = CM.map (fn class => {closedRules = #closedRules class, openRules = map (fn (nvs, cs, c, e) => (nvs, map (liftConInCon 0) cs, liftConInCon 0 c, liftConInExp 0 e)) (#openRules class)}) (#classes env), renameE = SM.map (fn Rel' (n, c) => Rel' (n, lift c) | Named' (n, c) => Named' (n, c)) (#renameE env), relE = map (fn (x, c) => (x, lift c)) (#relE env), namedE = #namedE env, renameSgn = #renameSgn env, sgn = #sgn env, renameStr = #renameStr env, str = #str env } end fun lookupCRel (env : env) n = (List.nth (#relC env, n)) handle Subscript => raise UnboundRel n fun pushCNamedAs (env : env) x n k co = {renameK = #renameK env, relK = #relK env, renameC = SM.insert (#renameC env, x, Named' (n, k)), relC = #relC env, namedC = IM.insert (#namedC env, n, (x, k, co)), datatypes = #datatypes env, constructors = #constructors env, classes = #classes env, renameE = #renameE env, relE = #relE env, namedE = #namedE env, renameSgn = #renameSgn env, sgn = #sgn env, renameStr = #renameStr env, str = #str env} fun pushCNamed env x k co = let val n = !namedCounter in namedCounter := n + 1; (pushCNamedAs env x n k co, n) end fun lookupCNamed (env : env) n = case IM.find (#namedC env, n) of NONE => raise UnboundNamed n | SOME x => x fun lookupC (env : env) x = case SM.find (#renameC env, x) of NONE => NotBound | SOME (Rel' x) => Rel x | SOME (Named' x) => Named x fun pushDatatype (env : env) n xs xncs = let val dk = U.classifyDatatype xncs in {renameK = #renameK env, relK = #relK env, renameC = #renameC env, relC = #relC env, namedC = #namedC env, datatypes = IM.insert (#datatypes env, n, (xs, foldl (fn ((x, n, to), cons) => IM.insert (cons, n, (x, to))) IM.empty xncs)), constructors = foldl (fn ((x, n', to), cmap) => SM.insert (cmap, x, (dk, n', xs, to, n))) (#constructors env) xncs, classes = #classes env, renameE = #renameE env, relE = #relE env, namedE = #namedE env, renameSgn = #renameSgn env, sgn = #sgn env, renameStr = #renameStr env, str = #str env} end fun lookupDatatype (env : env) n = case IM.find (#datatypes env, n) of NONE => raise UnboundNamed n | SOME x => x fun lookupDatatypeConstructor (_, dt) n = case IM.find (dt, n) of NONE => raise UnboundNamed n | SOME x => x fun lookupConstructor (env : env) s = SM.find (#constructors env, s) fun datatypeArgs (xs, _) = xs fun constructors (_, dt) = IM.foldri (fn (n, (x, to), ls) => (x, n, to) :: ls) [] dt fun listClasses (env : env) = map (fn (cn, {closedRules, openRules}) => (class_name_out cn, map (fn (nvs, cs, c, e) => let val loc = #2 c val c = foldr (fn (c', c) => (TFun (c', c), loc)) c cs val c = ListUtil.foldli (fn (n, (), c) => (TCFun (Explicit, "x" ^ Int.toString n, (KError, loc), c), loc)) c (List.tabulate (nvs, fn _ => ())) in (c, e) end) (closedRules @ openRules))) (CM.listItemsi (#classes env)) fun pushClass (env : env) n = {renameK = #renameK env, relK = #relK env, renameC = #renameC env, relC = #relC env, namedC = #namedC env, datatypes = #datatypes env, constructors = #constructors env, classes = CM.insert (#classes env, ClNamed n, empty_class), renameE = #renameE env, relE = #relE env, namedE = #namedE env, renameSgn = #renameSgn env, sgn = #sgn env, renameStr = #renameStr env, str = #str env} fun class_name_in (c, _) = case c of CNamed n => SOME (ClNamed n) | CModProj x => SOME (ClProj x) | CUnif (_, _, _, _, ref (Known c)) => class_name_in c | _ => NONE fun isClass (env : env) c = let fun find NONE = false | find (SOME c) = Option.isSome (CM.find (#classes env, c)) in find (class_name_in c) end fun class_head_in c = case #1 c of CApp (f, _) => class_head_in f | CUnif (_, _, _, _, ref (Known c)) => class_head_in c | _ => class_name_in c exception Unify fun unifyKinds (k1, k2) = case (#1 k1, #1 k2) of (KType, KType) => () | (KArrow (d1, r1), KArrow (d2, r2)) => (unifyKinds (d1, d2); unifyKinds (r1, r2)) | (KName, KName) => () | (KRecord k1, KRecord k2) => unifyKinds (k1, k2) | (KUnit, KUnit) => () | (KTuple ks1, KTuple ks2) => (ListPair.appEq unifyKinds (ks1, ks2) handle ListPair.UnequalLengths => raise Unify) | (KUnif (_, _, ref (KKnown k1)), _) => unifyKinds (k1, k2) | (_, KUnif (_, _, ref (KKnown k2))) => unifyKinds (k1, k2) | (KRel n1, KRel n2) => if n1 = n2 then () else raise Unify | (KFun (_, k1), KFun (_, k2)) => unifyKinds (k1, k2) | _ => raise Unify fun eqCons (c1, c2) = case (#1 c1, #1 c2) of (CUnif (nl, _, _, _, ref (Known c1)), _) => eqCons (mliftConInCon nl c1, c2) | (_, CUnif (nl, _, _, _, ref (Known c2))) => eqCons (c1, mliftConInCon nl c2) | (CRel n1, CRel n2) => if n1 = n2 then () else raise Unify | (TFun (d1, r1), TFun (d2, r2)) => (eqCons (d1, d2); eqCons (r1, r2)) | (TCFun (_, _, k1, r1), TCFun (_, _, k2, r2)) => (unifyKinds (k1, k2); eqCons (r1, r2)) | (TRecord c1, TRecord c2) => eqCons (c1, c2) | (TDisjoint (a1, b1, c1), TDisjoint (a2, b2, c2)) => (eqCons (a1, a2); eqCons (b1, b2); eqCons (c1, c2)) | (CNamed n1, CNamed n2) => if n1 = n2 then () else raise Unify | (CModProj (n1, ms1, x1), CModProj (n2, ms2, x2)) => if n1 = n2 andalso ms1 = ms2 andalso x1 = x2 then () else raise Unify | (CApp (f1, x1), CApp (f2, x2)) => (eqCons (f1, f2); eqCons (x1, x2)) | (CAbs (_, k1, b1), CAbs (_, k2, b2)) => (unifyKinds (k1, k2); eqCons (b1, b2)) | (CKAbs (_, b1), CKAbs (_, b2)) => eqCons (b1, b2) | (CKApp (c1, k1), CKApp (c2, k2)) => (eqCons (c1, c2); unifyKinds (k1, k2)) | (TKFun (_, c1), TKFun (_, c2)) => eqCons (c1, c2) | (CName s1, CName s2) => if s1 = s2 then () else raise Unify | (CRecord (k1, xcs1), CRecord (k2, xcs2)) => (unifyKinds (k1, k2); if length xcs1 <> length xcs2 then raise Unify else List.app (fn (x1, c1) => if List.exists (fn (x2, c2) => (eqCons (x1, x2); eqCons (c1, c2); true) handle Unify => false) xcs2 then () else raise Unify) xcs1) | (CConcat (f1, x1), CConcat (f2, x2)) => (eqCons (f1, f2); eqCons (x1, x2)) | (CMap (d1, r1), CMap (d2, r2)) => (unifyKinds (d1, d2); unifyKinds (r1, r2)) | (CUnit, CUnit) => () | (CTuple cs1, CTuple cs2) => (ListPair.appEq (eqCons) (cs1, cs2) handle ListPair.UnequalLengths => raise Unify) | (CProj (c1, n1), CProj (c2, n2)) => (eqCons (c1, c2); if n1 = n2 then () else raise Unify) | _ => raise Unify fun unifyCons (hnorm : con -> con) rs = let fun unify d (c1, c2) = case (#1 (hnorm c1), #1 (hnorm c2)) of (CUnif (nl, _, _, _, ref (Known c1)), _) => unify d (mliftConInCon nl c1, c2) | (_, CUnif (nl, _, _, _, ref (Known c2))) => unify d (c1, mliftConInCon nl c2) | (CUnif _, _) => () | (c1', CRel n2) => if n2 < d then case c1' of CRel n1 => if n1 = n2 then () else raise Unify | _ => raise Unify else if n2 - d >= length rs then case c1' of CRel n1 => if n1 = n2 - length rs then () else raise Unify | _ => raise Unify else let val r = List.nth (rs, n2 - d) in case !r of NONE => r := SOME c1 | SOME c2 => eqCons (c1, c2) end | (TFun (d1, r1), TFun (d2, r2)) => (unify d (d1, d2); unify d (r1, r2)) | (TCFun (_, _, k1, r1), TCFun (_, _, k2, r2)) => (unifyKinds (k1, k2); unify (d + 1) (r1, r2)) | (TRecord c1, TRecord c2) => unify d (c1, c2) | (TDisjoint (a1, b1, c1), TDisjoint (a2, b2, c2)) => (unify d (a1, a2); unify d (b1, b2); unify d (c1, c2)) | (CNamed n1, CNamed n2) => if n1 = n2 then () else raise Unify | (CModProj (n1, ms1, x1), CModProj (n2, ms2, x2)) => if n1 = n2 andalso ms1 = ms2 andalso x1 = x2 then () else raise Unify | (CApp (f1, x1), CApp (f2, x2)) => (unify d (f1, f2); unify d (x1, x2)) | (CAbs (_, k1, b1), CAbs (_, k2, b2)) => (unifyKinds (k1, k2); unify (d + 1) (b1, b2)) | (CKAbs (_, b1), CKAbs (_, b2)) => unify d (b1, b2) | (CKApp (c1, k1), CKApp (c2, k2)) => (unify d (c1, c2); unifyKinds (k1, k2)) | (TKFun (_, c1), TKFun (_, c2)) => unify d (c1, c2) | (CName s1, CName s2) => if s1 = s2 then () else raise Unify | (CRecord (k1, xcs1), CRecord (k2, xcs2)) => (unifyKinds (k1, k2); if length xcs1 <> length xcs2 then raise Unify else app (fn (x1, c1) => if List.exists (fn (x2, c2) => (unify d (x1, x2); unify d (c1, c2); true) handle Unify => false) xcs2 then () else raise Unify) xcs1) | (CConcat (f1, x1), CConcat (f2, x2)) => (unify d (f1, f2); unify d (x1, x2)) | (CMap (d1, r1), CMap (d2, r2)) => (unifyKinds (d1, d2); unifyKinds (r1, r2)) | (CUnit, CUnit) => () | (CTuple cs1, CTuple cs2) => (ListPair.appEq (unify d) (cs1, cs2) handle ListPair.UnequalLengths => raise Unify) | (CProj (c1, n1), CProj (c2, n2)) => (unify d (c1, c2); if n1 = n2 then () else raise Unify) | _ => raise Unify in unify end fun tryUnify hnorm nRs (c1, c2) = let val rs = List.tabulate (nRs, fn _ => ref NONE) in (unifyCons hnorm rs 0 (c1, c2); SOME (map (fn r => case !r of NONE => raise Unify | SOME c => c) rs)) handle Unify => NONE end fun unifySubst (rs : con list) = U.Con.mapB {kind = fn _ => fn k => k, con = fn d => fn c => case c of CRel n => if n < d then c else if n - d >= length rs then CRel (n - d) else #1 (List.nth (rs, n - d)) | _ => c, bind = fn (d, U.Con.RelC _) => d + 1 | (d, _) => d} 0 exception Bad of con * con val hasUnif = U.Con.exists {kind = fn _ => false, con = fn CUnif (_, _, _, _, ref (Unknown _)) => true | _ => false} fun startsWithUnif c = let fun firstArg (c, acc) = case #1 c of CApp (f, x) => firstArg (f, SOME x) | _ => acc in case firstArg (c, NONE) of NONE => false | SOME x => hasUnif x end val cause = ref (NONE : con option) fun resolveFailureCause () = !cause fun resolveClass (hnorm : con -> con) (consEq : con * con -> bool) (env : env) = let fun resolve firstLevel c = let fun notFound () = (if firstLevel then () else cause := SOME c; NONE) fun doHead f = case CM.find (#classes env, f) of NONE => notFound () | SOME class => let val loc = #2 c fun generalize (c as (_, loc)) = case #1 c of CApp (f, x) => let val (f, equate) = generalize f fun isRecord () = let val rk = ref (KUnknown (fn _ => true)) val k = (KUnif (loc, "k", rk), loc) val r = ref (Unknown (fn _ => true)) val rc = (CUnif (0, loc, k, "x", r), loc) in ((CApp (f, rc), loc), fn () => (if consEq (rc, x) then true else (raise Bad (rc, x); false)) andalso equate ()) end in case #1 x of CConcat _ => isRecord () | CRecord _ => isRecord () | _ => ((CApp (f, x), loc), equate) end | _ => (c, fn () => true) val (c, equate) = generalize c fun tryRules rules = case rules of [] => notFound () | (nRs, cs, c', e) :: rules' => case tryUnify hnorm nRs (c, c') of NONE => tryRules rules' | SOME rs => let val eos = map (resolve false o unifySubst rs) cs in if List.exists (not o Option.isSome) eos orelse not (equate ()) orelse not (consEq (c, unifySubst rs c')) then tryRules rules' else let val es = List.mapPartial (fn x => x) eos val e = foldr (fn (c, e) => (ECApp (e, c), loc)) e rs val e = foldl (fn (e', e) => (EApp (e, e'), loc)) e es in SOME e end end in tryRules (#openRules class @ #closedRules class) end in if startsWithUnif c then notFound () else case #1 c of TRecord c => (case #1 (hnorm c) of CRecord (_, xts) => let fun resolver (xts, acc) = case xts of [] => SOME (ERecord acc, #2 c) | (x, t) :: xts => let val t = hnorm t val t = case t of (CApp (f, x), loc) => (CApp (hnorm f, hnorm x), loc) | _ => t in case resolve false t of NONE => notFound () | SOME e => resolver (xts, (x, e, t) :: acc) end in resolver (xts, []) end | _ => notFound ()) | _ => case class_head_in c of SOME f => doHead f | _ => notFound () end in cause := NONE; resolve true end fun rule_in c = let fun quantifiers (c, nvars) = case #1 c of CUnif (_, _, _, _, ref (Known c)) => quantifiers (c, nvars) | TCFun (_, _, _, c) => quantifiers (c, nvars + 1) | _ => let fun clauses (c, hyps) = case #1 c of TFun (hyp, c) => (case class_head_in hyp of SOME _ => clauses (c, hyp :: hyps) | NONE => NONE) | _ => case class_head_in c of NONE => NONE | SOME f => SOME (f, nvars, rev hyps, c) in clauses (c, []) end in quantifiers (c, 0) end fun pushERel (env : env) x t = let val renameE = SM.map (fn Rel' (n, t) => Rel' (n+1, t) | x => x) (#renameE env) val classes = CM.map (fn class => {openRules = map (fn (nvs, cs, c, e) => (nvs, cs, c, liftExp e)) (#openRules class), closedRules = #closedRules class}) (#classes env) val classes = case rule_in t of NONE => classes | SOME (f, nvs, cs, c) => case CM.find (classes, f) of NONE => classes | SOME class => let val rule = (nvs, cs, c, (ERel 0, #2 t)) val class = {openRules = rule :: #openRules class, closedRules = #closedRules class} in CM.insert (classes, f, class) end in {renameK = #renameK env, relK = #relK env, renameC = #renameC env, relC = #relC env, namedC = #namedC env, datatypes = #datatypes env, constructors = #constructors env, classes = classes, renameE = SM.insert (renameE, x, Rel' (0, t)), relE = (x, t) :: #relE env, namedE = #namedE env, renameSgn = #renameSgn env, sgn = #sgn env, renameStr = #renameStr env, str = #str env} end fun lookupERel (env : env) n = (List.nth (#relE env, n)) handle Subscript => raise UnboundRel n fun pushENamedAs (env : env) x n t = let val classes = #classes env val classes = case rule_in t of NONE => classes | SOME (f, nvs, cs, c) => case CM.find (classes, f) of NONE => classes | SOME class => let val e = (ENamed n, #2 t) val class = {openRules = #openRules class, closedRules = (nvs, cs, c, e) :: #closedRules class} in CM.insert (classes, f, class) end in {renameK = #renameK env, relK = #relK env, renameC = #renameC env, relC = #relC env, namedC = #namedC env, datatypes = #datatypes env, constructors = #constructors env, classes = classes, renameE = SM.insert (#renameE env, x, Named' (n, t)), relE = #relE env, namedE = IM.insert (#namedE env, n, (x, t)), renameSgn = #renameSgn env, sgn = #sgn env, renameStr = #renameStr env, str = #str env} end fun pushENamed env x t = let val n = !namedCounter in namedCounter := n + 1; (pushENamedAs env x n t, n) end fun lookupENamed (env : env) n = case IM.find (#namedE env, n) of NONE => raise UnboundNamed n | SOME x => x fun checkENamed (env : env) n = Option.isSome (IM.find (#namedE env, n)) fun lookupE (env : env) x = case SM.find (#renameE env, x) of NONE => NotBound | SOME (Rel' x) => Rel x | SOME (Named' x) => Named x fun pushSgnNamedAs (env : env) x n sgis = {renameK = #renameK env, relK = #relK env, renameC = #renameC env, relC = #relC env, namedC = #namedC env, datatypes = #datatypes env, constructors = #constructors env, classes = #classes env, renameE = #renameE env, relE = #relE env, namedE = #namedE env, renameSgn = SM.insert (#renameSgn env, x, (n, sgis)), sgn = IM.insert (#sgn env, n, (x, sgis)), renameStr = #renameStr env, str = #str env} fun pushSgnNamed env x sgis = let val n = !namedCounter in namedCounter := n + 1; (pushSgnNamedAs env x n sgis, n) end fun lookupSgnNamed (env : env) n = case IM.find (#sgn env, n) of NONE => raise UnboundNamed n | SOME x => x fun lookupSgn (env : env) x = SM.find (#renameSgn env, x) fun lookupStrNamed (env : env) n = case IM.find (#str env, n) of NONE => raise UnboundNamed n | SOME x => x fun lookupStr (env : env) x = SM.find (#renameStr env, x) fun sgiSeek (sgi, (sgns, strs, cons)) = case sgi of SgiConAbs (x, n, _) => (sgns, strs, IM.insert (cons, n, x)) | SgiCon (x, n, _, _) => (sgns, strs, IM.insert (cons, n, x)) | SgiDatatype dts => (sgns, strs, foldl (fn ((x, n, _, _), cons) => IM.insert (cons, n, x)) cons dts) | SgiDatatypeImp (x, n, _, _, _, _, _) => (sgns, strs, IM.insert (cons, n, x)) | SgiVal _ => (sgns, strs, cons) | SgiSgn (x, n, _) => (IM.insert (sgns, n, x), strs, cons) | SgiStr (_, x, n, _) => (sgns, IM.insert (strs, n, x), cons) | SgiConstraint _ => (sgns, strs, cons) | SgiClassAbs (x, n, _) => (sgns, strs, IM.insert (cons, n, x)) | SgiClass (x, n, _, _) => (sgns, strs, IM.insert (cons, n, x)) fun sgnSeek f sgis = let fun seek (sgis, sgns, strs, cons) = case sgis of [] => NONE | (sgi, _) :: sgis => case f sgi of SOME v => let val cons = case sgi of SgiDatatype dts => foldl (fn ((x, n, _, _), cons) => IM.insert (cons, n, x)) cons dts | SgiDatatypeImp (x, n, _, _, _, _, _) => IM.insert (cons, n, x) | _ => cons in SOME (v, (sgns, strs, cons)) end | NONE => let val (sgns, strs, cons) = sgiSeek (sgi, (sgns, strs, cons)) in seek (sgis, sgns, strs, cons) end in seek (sgis, IM.empty, IM.empty, IM.empty) end fun id x = x fun unravelStr (str, _) = case str of StrVar x => (x, []) | StrProj (str, m) => let val (x, ms) = unravelStr str in (x, ms @ [m]) end | _ => raise Fail "unravelStr" fun sgnS_con (str, (sgns, strs, cons)) c = case c of CModProj (m1, ms, x) => (case IM.find (strs, m1) of NONE => c | SOME m1x => let val (m1, ms') = unravelStr str in CModProj (m1, ms' @ m1x :: ms, x) end) | CNamed n => (case IM.find (cons, n) of NONE => c | SOME nx => let val (m1, ms) = unravelStr str in CModProj (m1, ms, nx) end) | _ => c fun sgnS_con' (m1, ms', (sgns, strs, cons)) = U.Con.map {kind = fn x => x, con = fn c => case c of CModProj (m1', ms, x) => (case IM.find (strs, m1') of NONE => c | SOME m1x => CModProj (m1, ms' @ m1x :: ms, x)) | CNamed n => (case IM.find (cons, n) of NONE => c | SOME nx => CModProj (m1, ms', nx)) | _ => c} fun sgnS_sgn (str, (sgns, strs, cons)) sgn = case sgn of SgnProj (m1, ms, x) => (case IM.find (strs, m1) of NONE => sgn | SOME m1x => let val (m1, ms') = unravelStr str in SgnProj (m1, ms' @ m1x :: ms, x) end) | SgnVar n => (case IM.find (sgns, n) of NONE => sgn | SOME nx => let val (m1, ms) = unravelStr str in SgnProj (m1, ms, nx) end) | _ => sgn fun sgnSubSgn x = ElabUtil.Sgn.map {kind = id, con = sgnS_con x, sgn_item = id, sgn = sgnS_sgn x} and projectSgn env {sgn, str, field} = case #1 (hnormSgn env sgn) of SgnConst sgis => (case sgnSeek (fn SgiSgn (x, _, sgn) => if x = field then SOME sgn else NONE | _ => NONE) sgis of NONE => NONE | SOME (sgn, subs) => SOME (sgnSubSgn (str, subs) sgn)) | SgnError => SOME (SgnError, ErrorMsg.dummySpan) | _ => NONE and hnormSgn env (all as (sgn, loc)) = case sgn of SgnError => all | SgnVar n => hnormSgn env (#2 (lookupSgnNamed env n)) | SgnConst _ => all | SgnFun _ => all | SgnProj (m, ms, x) => let val (_, sgn) = lookupStrNamed env m in case projectSgn env {str = foldl (fn (m, str) => (StrProj (str, m), loc)) (StrVar m, loc) ms, sgn = sgn, field = x} of NONE => raise Fail "ElabEnv.hnormSgn: projectSgn failed" | SOME sgn => hnormSgn env sgn end | SgnWhere (sgn, ms, x, c) => let fun rewrite (sgn, ms) = case #1 (hnormSgn env sgn) of SgnError => (SgnError, loc) | SgnConst sgis => let fun traverse (ms, pre, post) = case post of [] => raise Fail "ElabEnv.hnormSgn: Can't reduce 'where' [1]" | (sgi as (SgiConAbs (x', n, k), loc)) :: rest => if List.null ms andalso x = x' then List.revAppend (pre, (SgiCon (x', n, k, c), loc) :: rest) else traverse (ms, sgi :: pre, rest) | (sgi as (SgiStr (im, x', n, sgn'), loc)) :: rest => (case ms of [] => traverse (ms, sgi :: pre, rest) | x :: ms' => if x = x' then List.revAppend (pre, (SgiStr (im, x', n, rewrite (sgn', ms')), loc) :: rest) else traverse (ms, sgi :: pre, rest)) | sgi :: rest => traverse (ms, sgi :: pre, rest) val sgis = traverse (ms, [], sgis) in (SgnConst sgis, loc) end | _ => raise Fail "ElabEnv.hnormSgn: Can't reduce 'where' [2]" in rewrite (sgn, ms) end fun manifest (m, ms, loc) = foldl (fn (m, str) => (StrProj (str, m), loc)) (StrVar m, loc) ms fun enrichClasses env classes (m1, ms) sgn = case #1 (hnormSgn env sgn) of SgnConst sgis => let val (classes, _, _, _) = foldl (fn (sgi, (classes, newClasses, fmap, env)) => let fun found (x, n) = (CM.insert (classes, ClProj (m1, ms, x), empty_class), IM.insert (newClasses, n, x), sgiSeek (#1 sgi, fmap), env) fun default () = (classes, newClasses, sgiSeek (#1 sgi, fmap), env) in case #1 sgi of SgiStr (Import, x, _, sgn) => let val str = manifest (m1, ms, #2 sgi) val sgn' = sgnSubSgn (str, fmap) sgn in (enrichClasses env classes (m1, ms @ [x]) sgn', newClasses, sgiSeek (#1 sgi, fmap), env) end | SgiSgn (x, n, sgn) => (classes, newClasses, fmap, pushSgnNamedAs env x n sgn) | SgiClassAbs (x, n, _) => found (x, n) | SgiClass (x, n, _, _) => found (x, n) | SgiVal (x, n, c) => (case rule_in c of NONE => default () | SOME (cn, nvs, cs, c) => let val loc = #2 c val globalize = sgnS_con' (m1, ms, fmap) val nc = case cn of ClNamed f => IM.find (newClasses, f) | _ => NONE in case nc of NONE => let val classes = case CM.find (classes, cn) of NONE => classes | SOME class => let val e = (EModProj (m1, ms, x), #2 sgn) val class = {openRules = #openRules class, closedRules = (nvs, map globalize cs, globalize c, e) :: #closedRules class} in CM.insert (classes, cn, class) end in (classes, newClasses, fmap, env) end | SOME fx => let val cn = ClProj (m1, ms, fx) val classes = case CM.find (classes, cn) of NONE => classes | SOME class => let val e = (EModProj (m1, ms, x), #2 sgn) val class = {openRules = #openRules class, closedRules = (nvs, map globalize cs, globalize c, e) :: #closedRules class} in CM.insert (classes, cn, class) end in (classes, newClasses, fmap, env) end end) | _ => default () end) (classes, IM.empty, (IM.empty, IM.empty, IM.empty), env) sgis in classes end | _ => classes fun pushStrNamedAs (env : env) x n sgn = {renameK = #renameK env, relK = #relK env, renameC = #renameC env, relC = #relC env, namedC = #namedC env, datatypes = #datatypes env, constructors = #constructors env, classes = enrichClasses env (#classes env) (n, []) sgn, renameE = #renameE env, relE = #relE env, namedE = #namedE env, renameSgn = #renameSgn env, sgn = #sgn env, renameStr = SM.insert (#renameStr env, x, (n, sgn)), str = IM.insert (#str env, n, (x, sgn))} fun pushStrNamed env x sgn = let val n = !namedCounter in namedCounter := n + 1; (pushStrNamedAs env x n sgn, n) end fun sgiBinds env (sgi, loc) = case sgi of SgiConAbs (x, n, k) => pushCNamedAs env x n k NONE | SgiCon (x, n, k, c) => pushCNamedAs env x n k (SOME c) | SgiDatatype dts => let fun doOne ((x, n, xs, xncs), env) = let val k = (KType, loc) val k' = foldr (fn (_, k') => (KArrow (k, k'), loc)) k xs val env = pushCNamedAs env x n k' NONE in foldl (fn ((x', n', to), env) => let val t = case to of NONE => (CNamed n, loc) | SOME t => (TFun (t, (CNamed n, loc)), loc) val k = (KType, loc) val t = foldr (fn (x, t) => (TCFun (Explicit, x, k, t), loc)) t xs in pushENamedAs env x' n' t end) env xncs end in foldl doOne env dts end | SgiDatatypeImp (x, n, m1, ms, x', xs, xncs) => let val k = (KType, loc) val k' = foldr (fn (_, k') => (KArrow (k, k'), loc)) k xs val env = pushCNamedAs env x n k' (SOME (CModProj (m1, ms, x'), loc)) in foldl (fn ((x', n', to), env) => let val t = case to of NONE => (CNamed n, loc) | SOME t => (TFun (t, (CNamed n, loc)), loc) val k = (KType, loc) val t = foldr (fn (x, t) => (TCFun (Explicit, x, k, t), loc)) t xs in pushENamedAs env x' n' t end) env xncs end | SgiVal (x, n, t) => pushENamedAs env x n t | SgiStr (_, x, n, sgn) => pushStrNamedAs env x n sgn | SgiSgn (x, n, sgn) => pushSgnNamedAs env x n sgn | SgiConstraint _ => env | SgiClassAbs (x, n, k) => pushCNamedAs env x n k NONE | SgiClass (x, n, k, c) => pushCNamedAs env x n k (SOME c) fun sgnSubCon x = ElabUtil.Con.map {kind = id, con = sgnS_con x} fun projectStr env {sgn, str, field} = case #1 (hnormSgn env sgn) of SgnConst sgis => (case sgnSeek (fn SgiStr (_, x, _, sgn) => if x = field then SOME sgn else NONE | _ => NONE) sgis of NONE => NONE | SOME (sgn, subs) => SOME (sgnSubSgn (str, subs) sgn)) | SgnError => SOME (SgnError, ErrorMsg.dummySpan) | _ => NONE fun chaseMpath env (n, ms) = let val (_, sgn) = lookupStrNamed env n in foldl (fn (m, (str, sgn)) => case projectStr env {sgn = sgn, str = str, field = m} of NONE => raise Fail "kindof: Unknown substructure" | SOME sgn => ((StrProj (str, m), #2 sgn), sgn)) ((StrVar n, #2 sgn), sgn) ms end fun projectCon env {sgn, str, field} = case #1 (hnormSgn env sgn) of SgnConst sgis => (case sgnSeek (fn SgiConAbs (x, _, k) => if x = field then SOME (k, NONE) else NONE | SgiCon (x, _, k, c) => if x = field then SOME (k, SOME c) else NONE | SgiDatatype dts => (case List.find (fn (x, _, xs, _) => x = field) dts of SOME (_, _, xs, _) => let val k = (KType, #2 sgn) val k' = foldl (fn (_, k') => (KArrow (k, k'), #2 sgn)) k xs in SOME (k', NONE) end | NONE => NONE) | SgiDatatypeImp (x, _, m1, ms, x', xs, _) => if x = field then let val k = (KType, #2 sgn) val k' = foldl (fn (_, k') => (KArrow (k, k'), #2 sgn)) k xs in SOME (k', SOME (CModProj (m1, ms, x'), #2 sgn)) end else NONE | SgiClassAbs (x, _, k) => if x = field then SOME (k, NONE) else NONE | SgiClass (x, _, k, c) => if x = field then SOME (k, SOME c) else NONE | _ => NONE) sgis of NONE => NONE | SOME ((k, co), subs) => SOME (k, Option.map (sgnSubCon (str, subs)) co)) | SgnError => SOME ((KError, ErrorMsg.dummySpan), SOME (CError, ErrorMsg.dummySpan)) | _ => NONE fun projectDatatype env {sgn, str, field} = case #1 (hnormSgn env sgn) of SgnConst sgis => (case sgnSeek (fn SgiDatatype dts => (case List.find (fn (x, _, _, _) => x = field) dts of SOME (_, _, xs, xncs) => SOME (xs, xncs) | NONE => NONE) | SgiDatatypeImp (x, _, _, _, _, xs, xncs) => if x = field then SOME (xs, xncs) else NONE | _ => NONE) sgis of NONE => NONE | SOME ((xs, xncs), subs) => SOME (xs, map (fn (x, n, to) => (x, n, Option.map (sgnSubCon (str, subs)) to)) xncs)) | _ => NONE fun projectConstructor env {sgn, str, field} = case #1 (hnormSgn env sgn) of SgnConst sgis => let fun consider (n, xs, xncs) = ListUtil.search (fn (x, n', to) => if x <> field then NONE else SOME (U.classifyDatatype xncs, n', xs, to, (CNamed n, #2 str))) xncs in case sgnSeek (fn SgiDatatype dts => let fun search dts = case dts of [] => NONE | (_, n, xs, xncs) :: dts => case consider (n, xs, xncs) of NONE => search dts | v => v in search dts end | SgiDatatypeImp (_, n, _, _, _, xs, xncs) => consider (n, xs, xncs) | _ => NONE) sgis of NONE => NONE | SOME ((dk, n, xs, to, t), subs) => SOME (dk, n, xs, Option.map (sgnSubCon (str, subs)) to, sgnSubCon (str, subs) t) end | _ => NONE fun projectVal env {sgn, str, field} = case #1 (hnormSgn env sgn) of SgnConst sgis => let fun seek (n, xs, xncs) = ListUtil.search (fn (x, _, to) => if x = field then SOME (let val base = (CNamed n, #2 sgn) val nxs = length xs val base = ListUtil.foldli (fn (i, _, base) => (CApp (base, (CRel (nxs - i - 1), #2 sgn)), #2 sgn)) base xs val t = case to of NONE => base | SOME t => (TFun (t, base), #2 sgn) val k = (KType, #2 sgn) in foldr (fn (x, t) => (TCFun (Implicit, x, k, t), #2 sgn)) t xs end) else NONE) xncs in case sgnSeek (fn SgiVal (x, _, c) => if x = field then SOME c else NONE | SgiDatatype dts => let fun search dts = case dts of [] => NONE | (_, n, xs, xncs) :: dts => case seek (n, xs, xncs) of NONE => search dts | v => v in search dts end | SgiDatatypeImp (_, n, _, _, _, xs, xncs) => seek (n, xs, xncs) | _ => NONE) sgis of NONE => NONE | SOME (c, subs) => SOME (sgnSubCon (str, subs) c) end | SgnError => SOME (CError, ErrorMsg.dummySpan) | _ => NONE fun sgnSeekConstraints (str, sgis) = let fun seek (sgis, sgns, strs, cons, acc) = case sgis of [] => acc | (sgi, _) :: sgis => case sgi of SgiConstraint (c1, c2) => let val sub = sgnSubCon (str, (sgns, strs, cons)) in seek (sgis, sgns, strs, cons, (sub c1, sub c2) :: acc) end | SgiConAbs (x, n, _) => seek (sgis, sgns, strs, IM.insert (cons, n, x), acc) | SgiCon (x, n, _, _) => seek (sgis, sgns, strs, IM.insert (cons, n, x), acc) | SgiDatatype dts => seek (sgis, sgns, strs, foldl (fn ((x, n, _, _), cons) => IM.insert (cons, n, x)) cons dts, acc) | SgiDatatypeImp (x, n, _, _, _, _, _) => seek (sgis, sgns, strs, IM.insert (cons, n, x), acc) | SgiVal _ => seek (sgis, sgns, strs, cons, acc) | SgiSgn (x, n, _) => seek (sgis, IM.insert (sgns, n, x), strs, cons, acc) | SgiStr (_, x, n, _) => seek (sgis, sgns, IM.insert (strs, n, x), cons, acc) | SgiClassAbs (x, n, _) => seek (sgis, sgns, strs, IM.insert (cons, n, x), acc) | SgiClass (x, n, _, _) => seek (sgis, sgns, strs, IM.insert (cons, n, x), acc) in seek (sgis, IM.empty, IM.empty, IM.empty, []) end fun projectConstraints env {sgn, str} = case #1 (hnormSgn env sgn) of SgnConst sgis => SOME (sgnSeekConstraints (str, sgis)) | SgnError => SOME [] | _ => NONE fun patBinds env (p, loc) = case p of PWild => env | PVar (x, t) => pushERel env x t | PPrim _ => env | PCon (_, _, _, NONE) => env | PCon (_, _, _, SOME p) => patBinds env p | PRecord xps => foldl (fn ((_, p, _), env) => patBinds env p) env xps fun patBindsN (p, _) = case p of PWild => 0 | PVar _ => 1 | PPrim _ => 0 | PCon (_, _, _, NONE) => 0 | PCon (_, _, _, SOME p) => patBindsN p | PRecord xps => foldl (fn ((_, p, _), n) => patBindsN p + n) 0 xps fun edeclBinds env (d, loc) = case d of EDVal (p, _, _) => patBinds env p | EDValRec vis => foldl (fn ((x, t, _), env) => pushERel env x t) env vis fun declBinds env (d, loc) = case d of DCon (x, n, k, c) => pushCNamedAs env x n k (SOME c) | DDatatype dts => let fun doOne ((x, n, xs, xncs), env) = let val k = (KType, loc) val nxs = length xs val (tb, kb) = ListUtil.foldli (fn (i, x', (tb, kb)) => ((CApp (tb, (CRel (nxs - i - 1), loc)), loc), (KArrow (k, kb), loc))) ((CNamed n, loc), k) xs val env = pushCNamedAs env x n kb NONE val env = pushDatatype env n xs xncs in foldl (fn ((x', n', to), env) => let val t = case to of NONE => tb | SOME t => (TFun (t, tb), loc) val t = foldr (fn (x, t) => (TCFun (Implicit, x, k, t), loc)) t xs in pushENamedAs env x' n' t end) env xncs end in foldl doOne env dts end | DDatatypeImp (x, n, m, ms, x', xs, xncs) => let val t = (CModProj (m, ms, x'), loc) val k = (KType, loc) val nxs = length xs val (tb, kb) = ListUtil.foldli (fn (i, x', (tb, kb)) => ((CApp (tb, (CRel (nxs - i - 1), loc)), loc), (KArrow (k, kb), loc))) ((CNamed n, loc), k) xs val env = pushCNamedAs env x n kb (SOME t) val env = pushDatatype env n xs xncs in foldl (fn ((x', n', to), env) => let val t = case to of NONE => tb | SOME t => (TFun (t, tb), loc) val t = foldr (fn (x, t) => (TCFun (Implicit, x, k, t), loc)) t xs in pushENamedAs env x' n' t end) env xncs end | DVal (x, n, t, _) => pushENamedAs env x n t | DValRec vis => foldl (fn ((x, n, t, _), env) => pushENamedAs env x n t) env vis | DSgn (x, n, sgn) => pushSgnNamedAs env x n sgn | DStr (x, n, sgn, _) => pushStrNamedAs env x n sgn | DFfiStr (x, n, sgn) => pushStrNamedAs env x n sgn | DConstraint _ => env | DExport _ => env | DTable (tn, x, n, c, _, pc, _, cc) => let val ct = (CModProj (tn, [], "sql_table"), loc) val ct = (CApp (ct, c), loc) val ct = (CApp (ct, (CConcat (pc, cc), loc)), loc) in pushENamedAs env x n ct end | DSequence (tn, x, n) => let val t = (CModProj (tn, [], "sql_sequence"), loc) in pushENamedAs env x n t end | DView (tn, x, n, _, c) => let val ct = (CModProj (tn, [], "sql_view"), loc) val ct = (CApp (ct, c), loc) in pushENamedAs env x n ct end | DDatabase _ => env | DCookie (tn, x, n, c) => let val t = (CApp ((CModProj (tn, [], "cookie"), loc), c), loc) in pushENamedAs env x n t end | DStyle (tn, x, n) => let val t = (CModProj (tn, [], "css_class"), loc) in pushENamedAs env x n t end | DTask _ => env | DPolicy _ => env | DOnError _ => env | DFfi (x, n, _, t) => pushENamedAs env x n t end