Mercurial > urweb
view src/iflow.sml @ 1207:ae3036773768
Introduced the known() predicate
author | Adam Chlipala <adamc@hcoop.net> |
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date | Tue, 06 Apr 2010 09:51:36 -0400 |
parents | 772760df4c4c |
children | b5a4c5407ae0 |
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(* Copyright (c) 2010, 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 Iflow :> IFLOW = struct open Mono structure IS = IntBinarySet structure IM = IntBinaryMap structure SS = BinarySetFn(struct type ord_key = string val compare = String.compare end) val writers = ["htmlifyInt_w", "htmlifyFloat_w", "htmlifyString_w", "htmlifyBool_w", "htmlifyTime_w", "attrifyInt_w", "attrifyFloat_w", "attrifyString_w", "attrifyChar_w", "urlifyInt_w", "urlifyFloat_w", "urlifyString_w", "urlifyBool_w"] val writers = SS.addList (SS.empty, writers) type lvar = int datatype exp = Const of Prim.t | Var of int | Lvar of lvar | Func of string * exp list | Recd of (string * exp) list | Proj of exp * string | Finish datatype reln = Known | Sql of string | Eq datatype prop = True | False | Unknown | And of prop * prop | Or of prop * prop | Reln of reln * exp list | Select of int * lvar * lvar * prop * exp local open Print val string = PD.string in 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 ^ "("), p_list p_exp es, string ")"] | Recd xes => box [string "{", p_list (fn (x, e) => box [string "x", space, string "=", space, p_exp e]) xes, string "}"] | Proj (e, x) => box [p_exp e, string ("." ^ x)] | Finish => string "FINISH" fun p_reln r es = case r of Known => (case es of [e] => box [string "known(", p_exp e, string ")"] | _ => raise Fail "Iflow.p_reln: Known") | Sql s => box [string (s ^ "("), p_list p_exp es, string ")"] | Eq => (case es of [e1, e2] => box [p_exp e1, space, string "=", space, p_exp e2] | _ => raise Fail "Iflow.p_reln: Eq") fun p_prop p = case p of True => string "True" | False => string "False" | Unknown => string "??" | And (p1, p2) => box [string "(", p_prop p1, string ")", space, string "&&", space, string "(", p_prop p2, string ")"] | Or (p1, p2) => box [string "(", p_prop p1, string ")", space, string "||", space, string "(", p_prop p2, string ")"] | Reln (r, es) => p_reln r es | Select (n1, n2, n3, p, e) => box [string ("select(x" ^ Int.toString n1 ^ ",X" ^ Int.toString n2 ^ ",X" ^ Int.toString n3 ^ "){"), p_prop p, string "}{", p_exp e, string "}"] end local val count = ref 1 in fun newLvar () = let val n = !count in count := n + 1; n end end fun subExp (v, lv) = let fun sub e = case e of Const _ => e | Var v' => if v' = v then Lvar lv else e | Lvar _ => e | Func (f, es) => Func (f, map sub es) | Recd xes => Recd (map (fn (x, e) => (x, sub e)) xes) | Proj (e, s) => Proj (sub e, s) | Finish => Finish in sub end fun subProp (v, lv) = let fun sub p = case p of True => p | False => p | Unknown => p | And (p1, p2) => And (sub p1, sub p2) | Or (p1, p2) => Or (sub p1, sub p2) | Reln (r, es) => Reln (r, map (subExp (v, lv)) es) | Select (v1, lv1, lv2, p, e) => Select (v1, lv1, lv2, sub p, subExp (v, lv) e) in sub end fun isKnown e = case e of Const _ => true | Func (_, es) => List.all isKnown es | Recd xes => List.all (isKnown o #2) xes | Proj (e, _) => isKnown e | _ => false fun isFinish e = case e of Finish => true | _ => false fun simplify e = case e of Const _ => e | Var _ => e | Lvar _ => e | Func (f, es) => let val es = map simplify es in if List.exists isFinish es then Finish else Func (f, es) 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)) | Finish => Finish 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 [x] | Select _ => k [] in decomp end val unif = ref (IM.empty : exp IM.map) fun reset () = unif := IM.empty fun save () = !unif fun restore x = unif := x fun lvarIn lv = let fun lvi e = case e of Const _ => false | Var _ => false | Lvar lv' => lv' = lv | Func (_, es) => List.exists lvi es | Recd xes => List.exists (lvi o #2) xes | Proj (e, _) => lvi e | Finish => false in lvi end fun eq' (e1, e2) = case (e1, e2) of (Const p1, Const p2) => Prim.equal (p1, p2) | (Var n1, Var n2) => n1 = n2 | (Lvar n1, _) => (case IM.find (!unif, n1) of SOME e1 => eq' (e1, e2) | NONE => case e2 of Lvar n2 => (case IM.find (!unif, n2) of SOME e2 => eq' (e1, e2) | NONE => n1 = n2 orelse (unif := IM.insert (!unif, n1, e2); true)) | _ => if lvarIn n1 e2 then false else (unif := IM.insert (!unif, n1, e2); true)) | (_, Lvar n2) => (case IM.find (!unif, n2) of SOME e2 => eq' (e1, e2) | NONE => if lvarIn n2 e1 then false else (unif := IM.insert (!unif, n2, e1); true)) | (Func (f1, es1), Func (f2, es2)) => f1 = f2 andalso ListPair.allEq eq' (es1, es2) | (Recd xes1, Recd xes2) => ListPair.allEq (fn ((x1, e1), (x2, e2)) => x1 = x2 andalso eq' (e1, e2)) (xes1, xes2) | (Proj (e1, s1), Proj (e2, s2)) => eq' (e1, e2) andalso s1 = s2 | (Finish, Finish) => true | _ => false fun eq (e1, e2) = let val saved = save () in if eq' (simplify e1, simplify e2) then true else (restore saved; false) end exception Imply of prop * prop fun rimp ((r1, es1), (r2, es2)) = case (r1, r2) of (Sql r1', Sql r2') => r1' = r2' andalso (case (es1, es2) of ([Recd xes1], [Recd xes2]) => let val saved = save () in if List.all (fn (f, e2) => case ListUtil.search (fn (f', e1) => if f' = f then SOME e1 else NONE) xes1 of NONE => true | SOME e1 => eq (e1, e2)) xes2 then true else (restore saved; false) end | _ => 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; (*raise Imply (Reln (Eq, es1), Reln (Eq, es2));*) eq (x1, y2) andalso eq (y1, x2)) end | _ => false) | (Known, Known) => (case (es1, es2) of ([e1], [e2]) => let fun walk e2 = eq (e1, e2) orelse case e2 of Proj (e2, _) => walk e2 | _ => false in walk e2 end | _ => false) | _ => false fun imply (p1, p2) = (reset (); (*raise (Imply (p1, p2));*) 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 = case goals of [] => true | g :: goals => let fun hps hyps = case hyps of [] => onFail () | h :: hyps => let val saved = save () in if rimp (h, g) then let val changed = IM.numItems (!unif) <> IM.numItems saved in gls goals (fn () => (restore saved; changed andalso hps hyps)) end else hps hyps end in hps hyps end in gls goals (fn () => false) end))) fun patCon pc = case pc of PConVar n => "C" ^ Int.toString n | PConFfi {mod = m, datatyp = d, con = c, ...} => m ^ "." ^ d ^ "." ^ c datatype chunk = String of string | Exp of Mono.exp fun chunkify e = case #1 e of EPrim (Prim.String s) => [String s] | EStrcat (e1, e2) => let val chs1 = chunkify e1 val chs2 = chunkify e2 in case chs2 of String s2 :: chs2' => (case List.last chs1 of String s1 => List.take (chs1, length chs1 - 1) @ String (s1 ^ s2) :: chs2' | _ => chs1 @ chs2) | _ => chs1 @ chs2 end | _ => [Exp e] type 'a parser = chunk list -> ('a * chunk list) option fun always v chs = SOME (v, chs) fun parse p s = case p (chunkify s) of SOME (v, []) => SOME v | _ => NONE fun const s chs = case chs of String s' :: chs => if String.isPrefix s s' then SOME ((), if size s = size s' then chs else String (String.extract (s', size s, NONE)) :: chs) else NONE | _ => NONE fun follow p1 p2 chs = case p1 chs of NONE => NONE | SOME (v1, chs) => case p2 chs of NONE => NONE | SOME (v2, chs) => SOME ((v1, v2), chs) fun wrap p f chs = case p chs of NONE => NONE | SOME (v, chs) => SOME (f v, chs) fun alt p1 p2 chs = case p1 chs of NONE => p2 chs | v => v fun altL ps = case rev ps of [] => (fn _ => NONE) | p :: ps => foldl (fn (p1, p2) => alt p1 p2) p ps fun opt p chs = case p chs of NONE => SOME (NONE, chs) | SOME (v, chs) => SOME (SOME v, chs) fun skip cp chs = case chs of String "" :: chs => skip cp chs | String s :: chs' => if cp (String.sub (s, 0)) then skip cp (String (String.extract (s, 1, NONE)) :: chs') else SOME ((), chs) | _ => SOME ((), chs) fun keep cp chs = case chs of String "" :: chs => keep cp chs | String s :: chs' => let val (befor, after) = Substring.splitl cp (Substring.full s) in if Substring.isEmpty befor then NONE else SOME (Substring.string befor, if Substring.isEmpty after then chs' else String (Substring.string after) :: chs') end | _ => NONE fun ws p = wrap (follow (skip (fn ch => ch = #" ")) (follow p (skip (fn ch => ch = #" ")))) (#1 o #2) val debug = ref false fun log name p chs = (if !debug then case chs of String s :: _ => print (name ^ ": " ^ s ^ "\n") | _ => print (name ^ ": blocked!\n") else (); p chs) fun list p chs = altL [wrap (follow p (follow (ws (const ",")) (list p))) (fn (v, ((), ls)) => v :: ls), wrap (ws p) (fn v => [v]), always []] chs val ident = keep (fn ch => Char.isAlphaNum ch orelse ch = #"_") val t_ident = wrap ident (fn s => if String.isPrefix "T_" s then String.extract (s, 2, NONE) else raise Fail "Iflow: Bad table variable") val uw_ident = wrap ident (fn s => if String.isPrefix "uw_" s then String.extract (s, 3, NONE) else raise Fail "Iflow: Bad uw_* variable") val sitem = wrap (follow t_ident (follow (const ".") uw_ident)) (fn (t, ((), f)) => (t, f)) datatype Rel = Exps of exp * exp -> prop | Props of prop * prop -> prop datatype sqexp = SqConst of Prim.t | Field of string * string | Binop of Rel * sqexp * sqexp | SqKnown of sqexp | Inj of Mono.exp val sqbrel = altL [wrap (const "=") (fn () => Exps (fn (e1, e2) => Reln (Eq, [e1, e2]))), wrap (const "AND") (fn () => Props And), wrap (const "OR") (fn () => Props Or)] datatype ('a, 'b) sum = inl of 'a | inr of 'b fun int chs = case chs of String s :: chs' => let val (befor, after) = Substring.splitl Char.isDigit (Substring.full s) in if Substring.isEmpty befor then NONE else case Int64.fromString (Substring.string befor) of NONE => NONE | SOME n => SOME (n, if Substring.isEmpty after then chs' else String (Substring.string after) :: chs') end | _ => NONE val prim = wrap (follow (wrap int Prim.Int) (opt (const "::int8"))) #1 fun known' chs = case chs of Exp (EFfi ("Basis", "sql_known"), _) :: chs => SOME ((), chs) | _ => NONE fun sqlify chs = case chs of Exp (EFfiApp ("Basis", f, [e]), _) :: chs => if String.isPrefix "sqlify" f then SOME (e, chs) else NONE | _ => NONE fun sqexp chs = log "sqexp" (altL [wrap prim SqConst, wrap sitem Field, wrap known SqKnown, wrap sqlify Inj, wrap (follow (ws (const "(")) (follow (wrap (follow sqexp (alt (wrap (follow (ws sqbrel) (ws sqexp)) inl) (always (inr ())))) (fn (e1, sm) => case sm of inl (bo, e2) => Binop (bo, e1, e2) | inr () => e1)) (const ")"))) (fn ((), (e, ())) => e)]) chs and known chs = wrap (follow known' (follow (const "(") (follow sqexp (const ")")))) (fn ((), ((), (e, ()))) => e) chs val select = log "select" (wrap (follow (const "SELECT ") (list sitem)) (fn ((), ls) => ls)) val fitem = wrap (follow uw_ident (follow (const " AS ") t_ident)) (fn (t, ((), f)) => (t, f)) val from = log "from" (wrap (follow (const "FROM ") (list fitem)) (fn ((), ls) => ls)) val wher = wrap (follow (ws (const "WHERE ")) sqexp) (fn ((), ls) => ls) val query = log "query" (wrap (follow (follow select from) (opt wher)) (fn ((fs, ts), wher) => {Select = fs, From = ts, Where = wher})) fun queryProp env rv oe e = case parse query e of NONE => (print ("Warning: Information flow checker can't parse SQL query at " ^ ErrorMsg.spanToString (#2 e) ^ "\n"); Unknown) | SOME r => let val p = foldl (fn ((t, v), p) => And (p, Reln (Sql t, [Recd (foldl (fn ((v', f), fs) => if v' = v then (f, Proj (Proj (Lvar rv, v), f)) :: fs else fs) [] (#Select r))]))) True (#From r) fun expIn e = case e of SqConst p => inl (Const p) | Field (v, f) => inl (Proj (Proj (Lvar rv, v), f)) | Binop (bo, e1, e2) => inr (case (bo, expIn e1, expIn e2) of (Exps f, inl e1, inl e2) => f (e1, e2) | (Props f, inr p1, inr p2) => f (p1, p2) | _ => Unknown) | SqKnown e => inr (case expIn e of inl e => Reln (Known, [e]) | _ => Unknown) | Inj e => let fun deinj (e, _) = case e of ERel n => List.nth (env, n) | EField (e, f) => Proj (deinj e, f) | _ => raise Fail "Iflow: non-variable injected into query" in inl (deinj e) end val p = case #Where r of NONE => p | SOME e => case expIn e of inr p' => And (p, p') | _ => p in case oe of NONE => p | SOME oe => And (p, foldl (fn ((v, f), p) => Or (p, Reln (Eq, [oe, Proj (Proj (Lvar rv, v), f)]))) False (#Select r)) end fun evalExp env (e as (_, loc), st as (nv, p, sent)) = let fun default () = (Var nv, (nv+1, p, sent)) fun addSent (p, e, sent) = if isKnown e then sent else (loc, e, p) :: sent in case #1 e of EPrim p => (Const p, st) | ERel n => (List.nth (env, n), st) | ENamed _ => default () | ECon (_, pc, NONE) => (Func (patCon pc, []), st) | ECon (_, pc, SOME e) => let val (e, st) = evalExp env (e, st) in (Func (patCon pc, [e]), st) end | ENone _ => (Func ("None", []), st) | ESome (_, e) => let val (e, st) = evalExp env (e, st) in (Func ("Some", [e]), st) end | EFfi _ => default () | EFfiApp (m, s, es) => if m = "Basis" andalso SS.member (writers, s) then let val (es, st) = ListUtil.foldlMap (evalExp env) st es in (Func ("unit", []), (#1 st, p, foldl (fn (e, sent) => addSent (#2 st, e, sent)) sent es)) end else if Settings.isEffectful (m, s) andalso not (Settings.isBenignEffectful (m, s)) then default () else let val (es, st) = ListUtil.foldlMap (evalExp env) st es in (Func (m ^ "." ^ s, es), st) end | EApp _ => default () | EAbs _ => default () | EUnop (s, e1) => let val (e1, st) = evalExp env (e1, st) in (Func (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) end | ERecord xets => let val (xes, st) = ListUtil.foldlMap (fn ((x, e, _), st) => let val (e, st) = evalExp env (e, st) in ((x, e), st) end) st xets in (Recd xes, st) end | EField (e, s) => let val (e, st) = evalExp env (e, st) in (Proj (e, s), st) end | ECase _ => default () | EStrcat (e1, e2) => let val (e1, st) = evalExp env (e1, st) val (e2, st) = evalExp env (e2, st) in (Func ("cat", [e1, e2]), st) end | EError _ => (Finish, st) | EReturnBlob {blob = b, mimeType = m, ...} => let val (b, st) = evalExp env (b, st) val (m, st) = evalExp env (m, st) in (Finish, (#1 st, p, addSent (#2 st, b, addSent (#2 st, m, sent)))) end | ERedirect (e, _) => let val (e, st) = evalExp env (e, st) in (Finish, (#1 st, p, addSent (#2 st, e, sent))) end | EWrite e => let val (e, st) = evalExp env (e, st) in (Func ("unit", []), (#1 st, p, addSent (#2 st, e, sent))) end | ESeq (e1, e2) => let val (_, st) = evalExp env (e1, st) in evalExp env (e2, st) end | ELet (_, _, e1, e2) => let val (e1, st) = evalExp env (e1, st) in evalExp (e1 :: env) (e2, st) end | EClosure (n, es) => let val (es, st) = ListUtil.foldlMap (evalExp env) st es in (Func ("Cl" ^ Int.toString n, es), st) end | EQuery {query = q, body = b, initial = i, ...} => let val (_, st) = evalExp env (q, st) val (i, st) = evalExp env (i, st) val r = #1 st val acc = #1 st + 1 val st' = (#1 st + 2, #2 st, #3 st) val (b, st') = evalExp (Var acc :: Var r :: env) (b, st') val r' = newLvar () val acc' = newLvar () val qp = queryProp env r' NONE q val doSubExp = subExp (r, r') o subExp (acc, acc') val doSubProp = subProp (r, r') o subProp (acc, acc') val p = doSubProp (#2 st') val p = And (p, qp) val p = Select (r, r', acc', p, doSubExp b) in (Var r, (#1 st + 1, And (#2 st, p), map (fn (loc, e, p) => (loc, doSubExp e, And (qp, doSubProp p))) (#3 st'))) end | EDml _ => default () | ENextval _ => default () | ESetval _ => default () | EUnurlify _ => default () | EJavaScript _ => default () | ESignalReturn _ => default () | ESignalBind _ => default () | ESignalSource _ => default () | EServerCall _ => default () | ERecv _ => default () | ESleep _ => default () | ESpawn _ => default () end fun check file = let val exptd = foldl (fn ((d, _), exptd) => case d of DExport (_, _, n, _, _, _) => IS.add (exptd, n) | _ => exptd) IS.empty file fun decl ((d, _), (vals, pols)) = case d of DVal (_, n, _, e, _) => let val isExptd = IS.member (exptd, n) fun deAbs (e, env, nv, p) = case #1 e of EAbs (_, _, _, e) => deAbs (e, Var nv :: env, nv + 1, if isExptd then And (p, Reln (Known, [Var nv])) else p) | _ => (e, env, nv, p) val (e, env, nv, p) = deAbs (e, [], 1, True) val (e, (_, p, sent)) = evalExp env (e, (nv, p, [])) in (sent @ vals, pols) end | DPolicy (PolQuery e) => (vals, queryProp [] 0 (SOME (Var 0)) e :: pols) | _ => (vals, pols) val () = reset () val (vals, pols) = foldl decl ([], []) file in app (fn (loc, e, p) => let val p = And (p, Reln (Eq, [Var 0, e])) in if List.exists (fn pol => imply (p, pol)) pols then () else (ErrorMsg.errorAt loc "The information flow policy may be violated here."; Print.preface ("The state satisifes this predicate:", p_prop p)) end) vals end end