Mercurial > urweb
changeset 1215:360f1ed0a969
Implemented proper congruence closure, to the point where tests/policy works
author | Adam Chlipala <adamc@hcoop.net> |
---|---|
date | Thu, 08 Apr 2010 12:46:21 -0400 |
parents | 648e6b087dfb |
children | 09caa8c780e5 |
files | src/iflow.sml |
diffstat | 1 files changed, 553 insertions(+), 320 deletions(-) [+] |
line wrap: on
line diff
--- a/src/iflow.sml Thu Apr 08 09:57:37 2010 -0400 +++ b/src/iflow.sml Thu Apr 08 12:46:21 2010 -0400 @@ -32,10 +32,13 @@ structure IS = IntBinarySet structure IM = IntBinaryMap -structure SS = BinarySetFn(struct - type ord_key = string - val compare = String.compare - end) +structure SK = struct +type ord_key = string +val compare = String.compare +end + +structure SS = BinarySetFn(SK) +structure SM = BinaryMapFn(SK) val writers = ["htmlifyInt_w", "htmlifyFloat_w", @@ -56,11 +59,17 @@ type lvar = int +datatype func = + DtCon0 of string + | DtCon1 of string + | UnCon of string + | Other of string + datatype exp = Const of Prim.t | Var of int | Lvar of lvar - | Func of string * exp list + | Func of func * exp list | Recd of (string * exp) list | Proj of exp * string | Finish @@ -68,7 +77,8 @@ datatype reln = Known | Sql of string - | DtCon of string + | PCon0 of string + | PCon1 of string | Eq | Ne | Lt @@ -85,17 +95,34 @@ | Reln of reln * exp list | Cond of exp * prop +val unif = ref (IM.empty : exp IM.map) + +fun reset () = unif := IM.empty +fun save () = !unif +fun restore x = unif := x + local open Print val string = PD.string in +fun p_func f = + string (case f of + DtCon0 s => s + | DtCon1 s => s + | UnCon s => "un" ^ s + | Other s => s) + fun p_exp e = case e of Const p => Prim.p_t p | Var n => string ("x" ^ Int.toString n) - | Lvar n => string ("X" ^ Int.toString n) - | Func (f, es) => box [string (f ^ "("), + | Lvar n => + (case IM.find (!unif, n) of + NONE => string ("X" ^ Int.toString n) + | SOME e => p_exp e) + | Func (f, es) => box [p_func f, + string "(", p_list p_exp es, string ")"] | Recd xes => box [string "{", @@ -129,7 +156,10 @@ | Sql s => box [string (s ^ "("), p_list p_exp es, string ")"] - | DtCon s => box [string (s ^ "("), + | PCon0 s => box [string (s ^ "("), + p_list p_exp es, + string ")"] + | PCon1 s => box [string (s ^ "("), p_list p_exp es, string ")"] | Eq => p_bop "=" es @@ -198,12 +228,6 @@ Finish => true | _ => false -val unif = ref (IM.empty : exp IM.map) - -fun reset () = unif := IM.empty -fun save () = !unif -fun restore x = unif := x - fun simplify e = case e of Const _ => e @@ -212,42 +236,9 @@ (case IM.find (!unif, n) of NONE => e | SOME e => simplify e) - | Func (f, es) => - let - val es = map simplify es - - fun default () = Func (f, es) - in - if List.exists isFinish es then - Finish - else if String.isPrefix "un" f then - case es of - [Func (f', [e])] => if f' = String.extract (f, 2, NONE) then - e - else - default () - | _ => default () - else - default () - end - | Recd xes => - let - val xes = map (fn (x, e) => (x, simplify e)) xes - in - if List.exists (isFinish o #2) xes then - Finish - else - Recd xes - end - | Proj (e, s) => - (case simplify e of - Recd xes => - getOpt (ListUtil.search (fn (x, e') => if x = s then SOME e' else NONE) xes, Recd xes) - | e' => - if isFinish e' then - Finish - else - Proj (e', s)) + | Func (f, es) => Func (f, map simplify es) + | Recd xes => Recd (map (fn (x, e) => (x, simplify e)) xes) + | Proj (e, s) => Proj (simplify e, s) | Finish => Finish datatype atom = @@ -259,25 +250,6 @@ AReln x => Reln x | ACond x => Cond x) -fun decomp fals or = - let - fun decomp p k = - case p of - True => k [] - | False => fals - | Unknown => k [] - | And (p1, p2) => - decomp p1 (fn ps1 => - decomp p2 (fn ps2 => - k (ps1 @ ps2))) - | Or (p1, p2) => - or (decomp p1 k, fn () => decomp p2 k) - | Reln x => k [AReln x] - | Cond x => k [ACond x] - in - decomp - end - fun lvarIn lv = let fun lvi e = @@ -407,259 +379,522 @@ (* Congruence closure *) structure Cc :> sig - type t - val empty : t - val assert : t * exp * exp -> t - val query : t * exp * exp -> bool - val allPeers : t * exp -> exp list - val p_t : t Print.printer + type database + type representative + + exception Contradiction + exception Undetermined + + val database : unit -> database + val representative : database * exp -> representative + + val assert : database * atom -> unit + val check : database * atom -> bool + + val p_database : database Print.printer end = struct -fun eq (e1, e2) = eeq (simplify e1, simplify e2) +exception Contradiction +exception Undetermined -type t = (exp * exp) list +structure CM = BinaryMapFn(struct + type ord_key = Prim.t + val compare = Prim.compare + end) -val empty = [] +datatype node = Node of {Rep : node ref option ref, + Cons : node ref SM.map ref, + Variety : variety, + Known : bool ref} -fun lookup (t, e) = - case List.find (fn (e', _) => eq (e', e)) t of - NONE => e - | SOME (_, e2) => lookup (t, e2) + and variety = + Dt0 of string + | Dt1 of string * node ref + | Prim of Prim.t + | Recrd of node ref SM.map ref + | VFinish + | Nothing -fun allPeers (t, e) = +type representative = node ref + +val finish = ref (Node {Rep = ref NONE, + Cons = ref SM.empty, + Variety = VFinish, + Known = ref false}) + +type database = {Vars : representative IM.map ref, + Consts : representative CM.map ref, + Con0s : representative SM.map ref, + Records : (representative SM.map * representative) list ref, + Funcs : ((string * representative list) * representative) list ref } + +fun database () = {Vars = ref IM.empty, + Consts = ref CM.empty, + Con0s = ref SM.empty, + Records = ref [], + Funcs = ref []} + +fun unNode n = + case !n of + Node r => r + +open Print +val string = PD.string +val newline = PD.newline + +fun p_rep n = + case !(#Rep (unNode n)) of + SOME n => p_rep n + | NONE => + case #Variety (unNode n) of + Nothing => string ("?" ^ Int.toString (Unsafe.cast n)) + | Dt0 s => string ("Dt0(" ^ s ^ ")") + | Dt1 (s, n) => box[string ("Dt1(" ^ s ^ ","), + space, + p_rep n, + string ")"] + | Prim p => Prim.p_t p + | Recrd (ref m) => box [string "{", + p_list (fn (x, n) => box [string x, + space, + string "=", + space, + p_rep n]) (SM.listItemsi m), + string "}"] + | VFinish => string "FINISH" + +fun p_database (db : database) = + box [string "Vars:", + newline, + p_list_sep newline (fn (i, n) => box [string ("x" ^ Int.toString i), + space, + string "=", + space, + p_rep n]) (IM.listItemsi (!(#Vars db)))] + +fun repOf (n : representative) : representative = + case !(#Rep (unNode n)) of + NONE => n + | SOME r => + let + val r = repOf r + in + #Rep (unNode n) := SOME r; + r + end + +fun markKnown r = + (#Known (unNode r) := true; + case #Variety (unNode r) of + Dt1 (_, r) => markKnown r + | Recrd xes => SM.app markKnown (!xes) + | _ => ()) + +fun representative (db : database, e) = let - val r = lookup (t, e) + fun rep e = + case e of + Const p => (case CM.find (!(#Consts db), p) of + SOME r => repOf r + | NONE => + let + val r = ref (Node {Rep = ref NONE, + Cons = ref SM.empty, + Variety = Prim p, + Known = ref false}) + in + #Consts db := CM.insert (!(#Consts db), p, r); + r + end) + | Var n => (case IM.find (!(#Vars db), n) of + SOME r => repOf r + | NONE => + let + val r = ref (Node {Rep = ref NONE, + Cons = ref SM.empty, + Variety = Nothing, + Known = ref false}) + in + #Vars db := IM.insert (!(#Vars db), n, r); + r + end) + | Lvar n => + (case IM.find (!unif, n) of + NONE => raise Undetermined + | SOME e => rep e) + | Func (DtCon0 f, []) => (case SM.find (!(#Con0s db), f) of + SOME r => repOf r + | NONE => + let + val r = ref (Node {Rep = ref NONE, + Cons = ref SM.empty, + Variety = Dt0 f, + Known = ref false}) + in + #Con0s db := SM.insert (!(#Con0s db), f, r); + r + end) + | Func (DtCon0 _, _) => raise Fail "Iflow.rep: DtCon0" + | Func (DtCon1 f, [e]) => + let + val r = rep e + in + case SM.find (!(#Cons (unNode r)), f) of + SOME r => repOf r + | NONE => + let + val r' = ref (Node {Rep = ref NONE, + Cons = ref SM.empty, + Variety = Dt1 (f, r), + Known = ref false}) + in + #Cons (unNode r) := SM.insert (!(#Cons (unNode r)), f, r'); + r' + end + end + | Func (DtCon1 _, _) => raise Fail "Iflow.rep: DtCon1" + | Func (UnCon f, [e]) => + let + val r = rep e + in + case #Variety (unNode r) of + Dt1 (f', n) => if f' = f then + repOf n + else + raise Contradiction + | Nothing => + let + val cons = ref SM.empty + val r' = ref (Node {Rep = ref NONE, + Cons = cons, + Variety = Nothing, + Known = ref false}) + + val r'' = ref (Node {Rep = ref NONE, + Cons = #Cons (unNode r), + Variety = Dt1 (f, r'), + Known = #Known (unNode r)}) + in + cons := SM.insert (!cons, f, r''); + #Rep (unNode r) := SOME r''; + r' + end + | VFinish => r + | _ => raise Contradiction + end + | Func (UnCon _, _) => raise Fail "Iflow.rep: UnCon" + | Func (Other f, es) => + let + val rs = map rep es + in + case List.find (fn (x : string * representative list, _) => x = (f, rs)) (!(#Funcs db)) of + NONE => + let + val r = ref (Node {Rep = ref NONE, + Cons = ref SM.empty, + Variety = Nothing, + Known = ref false}) + in + #Funcs db := ((f, rs), r) :: (!(#Funcs db)); + r + end + | SOME (_, r) => repOf r + end + | Recd xes => + let + val xes = map (fn (x, e) => (x, rep e)) xes + val len = length xes + in + case List.find (fn (xes', _) => + SM.numItems xes' = len + andalso List.all (fn (x, n) => + case SM.find (xes', x) of + NONE => false + | SOME n' => n = repOf n') xes) + (!(#Records db)) of + SOME (_, r) => repOf r + | NONE => + let + val xes = foldl SM.insert' SM.empty xes + + val r' = ref (Node {Rep = ref NONE, + Cons = ref SM.empty, + Variety = Recrd (ref xes), + Known = ref false}) + in + #Records db := (xes, r') :: (!(#Records db)); + r' + end + end + | Proj (e, f) => + let + val r = rep e + in + case #Variety (unNode r) of + Recrd xes => + (case SM.find (!xes, f) of + SOME r => repOf r + | NONE =>let + val r = ref (Node {Rep = ref NONE, + Cons = ref SM.empty, + Variety = Nothing, + Known = ref false}) + in + xes := SM.insert (!xes, f, r); + r + end) + | Nothing => + let + val r' = ref (Node {Rep = ref NONE, + Cons = ref SM.empty, + Variety = Nothing, + Known = ref false}) + + val r'' = ref (Node {Rep = ref NONE, + Cons = #Cons (unNode r), + Variety = Recrd (ref (SM.insert (SM.empty, f, r'))), + Known = #Known (unNode r)}) + in + #Rep (unNode r) := SOME r''; + r' + end + | VFinish => r + | _ => raise Contradiction + end + | Finish => finish in - r :: List.mapPartial (fn (e1, e2) => - let - val r' = lookup (t, e2) - in - if eq (r, r') then - SOME e1 - else - NONE - end) t + rep e end -open Print +fun assert (db, a) = + case a of + ACond _ => () + | AReln x => + case x of + (Known, [e]) => markKnown (representative (db, e)) + | (PCon0 f, [e]) => + let + val r = representative (db, e) + in + case #Variety (unNode r) of + Dt0 f' => if f = f' then + () + else + raise Contradiction + | Nothing => + let + val r' = ref (Node {Rep = ref NONE, + Cons = ref SM.empty, + Variety = Dt0 f, + Known = ref false}) + in + #Rep (unNode r) := SOME r' + end + | _ => raise Contradiction + end + | (PCon1 f, [e]) => + let + val r = representative (db, e) + in + case #Variety (unNode r) of + Dt1 (f', e') => if f = f' then + () + else + raise Contradiction + | Nothing => + let + val r'' = ref (Node {Rep = ref NONE, + Cons = ref SM.empty, + Variety = Nothing, + Known = ref false}) -val p_t = p_list (fn (e1, e2) => box [p_exp (simplify e1), - space, - PD.string "->", - space, - p_exp (simplify e2)]) + val r' = ref (Node {Rep = ref NONE, + Cons = ref SM.empty, + Variety = Dt1 (f, r''), + Known = ref false}) + in + #Rep (unNode r) := SOME r' + end + | _ => raise Contradiction + end + | (Eq, [e1, e2]) => + let + fun markEq (r1, r2) = + if r1 = r2 then + () + else case (#Variety (unNode r1), #Variety (unNode r2)) of + (Prim p1, Prim p2) => if Prim.equal (p1, p2) then + () + else + raise Contradiction + | (Dt0 f1, Dt0 f2) => if f1 = f2 then + () + else + raise Contradiction + | (Dt1 (f1, r1), Dt1 (f2, r2)) => if f1 = f2 then + markEq (r1, r2) + else + raise Contradiction + | (Recrd xes1, Recrd xes2) => + let + fun unif (xes1, xes2) = + SM.appi (fn (x, r1) => + case SM.find (xes2, x) of + NONE => () + | SOME r2 => markEq (r1, r2)) xes1 + in + unif (!xes1, !xes2); + unif (!xes2, !xes1) + end + | (VFinish, VFinish) => () + | (Nothing, _) => + (#Rep (unNode r1) := SOME r2; + if !(#Known (unNode r1)) andalso not (!(#Known (unNode r2))) then + markKnown r2 + else + (); + #Cons (unNode r2) := SM.unionWith #1 (!(#Cons (unNode r2)), !(#Cons (unNode r1))); + compactFuncs ()) + | (_, Nothing) => + (#Rep (unNode r2) := SOME r1; + if !(#Known (unNode r2)) andalso not (!(#Known (unNode r1))) then + markKnown r1 + else + (); + #Cons (unNode r1) := SM.unionWith #1 (!(#Cons (unNode r1)), !(#Cons (unNode r2))); + compactFuncs ()) + | _ => raise Contradiction -fun query (t, e1, e2) = - let - fun doUn e = - case e of - Func (f, [e1]) => - if String.isPrefix "un" f then + and compactFuncs () = let - val s = String.extract (f, 2, NONE) + fun loop funcs = + case funcs of + [] => [] + | (fr as ((f, rs), r)) :: rest => + let + val rest = List.filter (fn ((f' : string, rs'), r') => + if f' = f + andalso ListPair.allEq (fn (r1, r2) => + repOf r1 = repOf r2) + (rs, rs') then + (markEq (r, r'); + false) + else + true) rest + in + fr :: loop rest + end in - case ListUtil.search (fn e => - case e of - Func (f', [e']) => - if f' = s then - SOME e' - else - NONE - | _ => NONE) (allPeers (t, e1)) of - NONE => e - | SOME e => doUn e + #Funcs db := loop (!(#Funcs db)) end - else - e - | _ => e + in + markEq (representative (db, e1), representative (db, e2)) + end + | _ => () - val e1' = doUn (lookup (t, doUn (simplify e1))) - val e2' = doUn (lookup (t, doUn (simplify e2))) - in - (*prefaces "CC query" [("e1", p_exp (simplify e1)), - ("e2", p_exp (simplify e2)), - ("e1'", p_exp (simplify e1')), - ("e2'", p_exp (simplify e2')), - ("t", p_t t)];*) - eq (e1', e2') - end - -fun assert (t, e1, e2) = - let - val r1 = lookup (t, e1) - val r2 = lookup (t, e2) - in - if eq (r1, r2) then - t - else +fun check (db, a) = + case a of + ACond _ => false + | AReln x => + case x of + (Known, [e]) => !(#Known (unNode (representative (db, e)))) + | (PCon0 f, [e]) => + (case #Variety (unNode (representative (db, e))) of + Dt0 f' => f' = f + | _ => false) + | (PCon1 f, [e]) => + (case #Variety (unNode (representative (db, e))) of + Dt1 (f', _) => f' = f + | _ => false) + | (Eq, [e1, e2]) => let - fun doUn (t, e1, e2) = - case e1 of - Func (f, [e]) => if String.isPrefix "un" f then - let - val s = String.extract (f, 2, NONE) - in - foldl (fn (e', t) => - case e' of - Func (f', [e']) => - if f' = s then - assert (assert (t, e', e1), e', e2) - else - t - | _ => t) t (allPeers (t, e)) - end - else - t - | _ => t - - fun doProj (t, e1, e2) = - foldl (fn ((e1', e2'), t) => - let - fun doOne (e, t) = - case e of - Proj (e', f) => - if query (t, e1, e') then - assert (t, e, Proj (e2, f)) - else - t - | _ => t - in - doOne (e1', doOne (e2', t)) - end) t t - - val t = (r1, r2) :: t - val t = doUn (t, r1, r2) - val t = doUn (t, r2, r1) - val t = doProj (t, r1, r2) - val t = doProj (t, r2, r1) + val r1 = representative (db, e1) + val r2 = representative (db, e2) in - t + repOf r1 = repOf r2 end - end + | _ => false end -fun rimp cc ((r1, es1), (r2, es2)) = - case (r1, r2) of - (Sql r1', Sql r2') => - r1' = r2' andalso - (case (es1, es2) of - ([e1], [e2]) => eq (e1, e2) - | _ => false) - | (Eq, Eq) => - (case (es1, es2) of - ([x1, y1], [x2, y2]) => - let - val saved = save () - in - if eq (x1, x2) andalso eq (y1, y2) then - true - else - (restore saved; - if eq (x1, y2) andalso eq (y1, x2) then - true - else - (restore saved; - false)) - end - | _ => false) - | (Known, Known) => - (case (es1, es2) of - ([Var v], [e2]) => - let - fun matches e = - case e of - Var v' => v' = v - | Proj (e, _) => matches e - | Func (f, [e]) => String.isPrefix "un" f andalso matches e - | _ => false - in - (*Print.prefaces "Checking peers" [("e2", p_exp e2), - ("peers", Print.p_list p_exp (Cc.allPeers (cc, e2))), - ("db", Cc.p_t cc)];*) - List.exists matches (Cc.allPeers (cc, e2)) - end - | _ => false) - | _ => false +fun decomp fals or = + let + fun decomp p k = + case p of + True => k [] + | False => fals + | Unknown => k [] + | And (p1, p2) => + decomp p1 (fn ps1 => + decomp p2 (fn ps2 => + k (ps1 @ ps2))) + | Or (p1, p2) => + or (decomp p1 k, fn () => decomp p2 k) + | Reln x => k [AReln x] + | Cond x => k [ACond x] + in + decomp + end fun imply (p1, p2) = - let - fun doOne doKnown = - decomp true (fn (e1, e2) => e1 andalso e2 ()) p1 - (fn hyps => - decomp false (fn (e1, e2) => e1 orelse e2 ()) p2 - (fn goals => - let - val cc = foldl (fn (p, cc) => - case p of - AReln (Eq, [e1, e2]) => Cc.assert (cc, e1, e2) - | _ => cc) Cc.empty hyps - - fun gls goals onFail = - case goals of - [] => true - | ACond _ :: _ => false - | AReln g :: goals => - case (doKnown, g) of - (false, (Known, _)) => gls goals onFail - | _ => - let - fun hps hyps = - case hyps of - [] => ((*Print.prefaces "Fail" [("g", p_prop (Reln g)), - ("db", Cc.p_t cc)];*) - onFail ()) - | ACond _ :: hyps => hps hyps - | AReln h :: hyps => - let - val saved = save () - in - if rimp cc (h, g) then - let - val changed = IM.numItems (!unif) - <> IM.numItems saved - in - gls goals (fn () => (restore saved; - changed (*andalso - (Print.preface ("Retry", - p_prop - (Reln g) - ); true)*) - andalso hps hyps)) - end - else - hps hyps - end - in - (case g of - (Eq, [e1, e2]) => Cc.query (cc, e1, e2) - | _ => false) - orelse hps hyps - end - in - if List.exists (fn AReln (DtCon c1, [e]) => - List.exists (fn AReln (DtCon c2, [e']) => - c1 <> c2 andalso - Cc.query (cc, e, e') - | _ => false) hyps - orelse List.exists (fn Func (c2, []) => c1 <> c2 - | Finish => true - | _ => false) - (Cc.allPeers (cc, e)) - | _ => false) hyps - orelse gls goals (fn () => false) then - true - else - ((*Print.prefaces "Can't prove" - [("hyps", Print.p_list p_atom hyps), - ("goals", Print.p_list p_atom goals)];*) - false) - end)) - in - reset (); - doOne false; - doOne true - end + (reset (); + decomp true (fn (e1, e2) => e1 andalso e2 ()) p1 + (fn hyps => + decomp false (fn (e1, e2) => e1 orelse e2 ()) p2 + (fn goals => + let + fun gls goals onFail acc = + case goals of + [] => + (let + val cc = Cc.database () + val () = app (fn a => Cc.assert (cc, a)) hyps + in + (List.all (fn a => + if Cc.check (cc, a) then + true + else + ((*Print.prefaces "Can't prove" + [("a", p_atom a), + ("hyps", Print.p_list p_atom hyps), + ("db", Cc.p_database cc)];*) + false)) acc + orelse onFail ()) + handle Cc.Contradiction => onFail () + end handle Cc.Undetermined => onFail ()) + | AReln (Sql gf, [ge]) :: goals => + let + fun hps hyps = + case hyps of + [] => onFail () + | AReln (Sql hf, [he]) :: hyps => + if gf = hf then + let + val saved = save () + in + if eq (ge, he) then + let + val changed = IM.numItems (!unif) + <> IM.numItems saved + in + gls goals (fn () => (restore saved; + changed + andalso hps hyps)) + acc + end + else + hps hyps + end + else + hps hyps + | _ :: hyps => hps hyps + in + hps hyps + end + | g :: goals => gls goals onFail (g :: acc) + in + gls goals (fn () => false) [] + end handle Cc.Contradiction => true))) fun patCon pc = case pc of @@ -953,7 +1188,7 @@ (wrap (follow (follow select from) (opt wher)) (fn ((fs, ts), wher) => {Select = fs, From = ts, Where = wher})) -fun removeDups ls = +fun removeDups (ls : (string * string) list) = case ls of [] => [] | x :: ls => @@ -1029,7 +1264,7 @@ end | SqFunc (f, e) => inl (case expIn e of - inl e => Func (f, [e]) + inl e => Func (Other f, [e]) | _ => raise Fail ("Iflow: non-expresion passed to function " ^ f)) | Count => inl count @@ -1081,12 +1316,12 @@ PWild => (env, True) | PVar _ => (e :: env, True) | PPrim _ => (env, True) - | PCon (_, pc, NONE) => (env, Reln (DtCon (patCon pc), [e])) + | PCon (_, pc, NONE) => (env, Reln (PCon0 (patCon pc), [e])) | PCon (_, pc, SOME pt) => let - val (env, p) = evalPat env (Func ("un" ^ patCon pc, [e])) pt + val (env, p) = evalPat env (Func (UnCon (patCon pc), [e])) pt in - (env, And (p, Reln (DtCon (patCon pc), [e]))) + (env, And (p, Reln (PCon1 (patCon pc), [e]))) end | PRecord xpts => foldl (fn ((x, pt, _), (env, p)) => @@ -1095,12 +1330,12 @@ in (env, And (p', p)) end) (env, True) xpts - | PNone _ => (env, Reln (DtCon "None", [e])) + | PNone _ => (env, Reln (PCon0 "None", [e])) | PSome (_, pt) => let - val (env, p) = evalPat env (Func ("unSome", [e])) pt + val (env, p) = evalPat env (Func (UnCon "Some", [e])) pt in - (env, And (p, Reln (DtCon "Some", [e]))) + (env, And (p, Reln (PCon1 "Some", [e]))) end fun peq (p1, p2) = @@ -1145,19 +1380,19 @@ EPrim p => (Const p, st) | ERel n => (List.nth (env, n), st) | ENamed _ => default () - | ECon (_, pc, NONE) => (Func (patCon pc, []), st) + | ECon (_, pc, NONE) => (Func (DtCon0 (patCon pc), []), st) | ECon (_, pc, SOME e) => let val (e, st) = evalExp env (e, st) in - (Func (patCon pc, [e]), st) + (Func (DtCon1 (patCon pc), [e]), st) end - | ENone _ => (Func ("None", []), st) + | ENone _ => (Func (DtCon0 "None", []), st) | ESome (_, e) => let val (e, st) = evalExp env (e, st) in - (Func ("Some", [e]), st) + (Func (DtCon1 "Some", [e]), st) end | EFfi _ => default () @@ -1174,7 +1409,7 @@ let val (es, st) = ListUtil.foldlMap (evalExp env) st es in - (Func (m ^ "." ^ s, es), st) + (Func (Other (m ^ "." ^ s), es), st) end | EApp (e1, e2) => @@ -1191,14 +1426,14 @@ let val (e1, st) = evalExp env (e1, st) in - (Func (s, [e1]), st) + (Func (Other s, [e1]), st) end | EBinop (s, e1, e2) => let val (e1, st) = evalExp env (e1, st) val (e2, st) = evalExp env (e2, st) in - (Func (s, [e1, e2]), st) + (Func (Other s, [e1, e2]), st) end | ERecord xets => let @@ -1241,7 +1476,7 @@ val (e1, st) = evalExp env (e1, st) val (e2, st) = evalExp env (e2, st) in - (Func ("cat", [e1, e2]), st) + (Func (Other "cat", [e1, e2]), st) end | EError _ => (Finish, st) | EReturnBlob {blob = b, mimeType = m, ...} => @@ -1279,7 +1514,7 @@ let val (es, st) = ListUtil.foldlMap (evalExp env) st es in - (Func ("Cl" ^ Int.toString n, es), st) + (Func (Other ("Cl" ^ Int.toString n), es), st) end | EQuery {query = q, body = b, initial = i, ...} => @@ -1409,10 +1644,8 @@ Const _ => () | Var _ => doOne e | Lvar _ => raise Fail "Iflow.doAll: Lvar" - | Func (f, es) => if String.isPrefix "un" f then - doOne e - else - app doAll es + | Func (UnCon _, [e]) => doOne e + | Func (_, es) => app doAll es | Recd xes => app (doAll o #2) xes | Proj _ => doOne e | Finish => ()