(* ========================================================================= *)
(* FIRST ORDER LOGIC LITERALS *)
(* Copyright (c) 2001-2006 Joe Hurd, distributed under the BSD License *)
(* ========================================================================= *)
structure Literal :> Literal =
struct
open Useful;
(* ------------------------------------------------------------------------- *)
(* A type for storing first order logic literals. *)
(* ------------------------------------------------------------------------- *)
type polarity = bool;
type literal = polarity * Atom.atom;
(* ------------------------------------------------------------------------- *)
(* Constructors and destructors. *)
(* ------------------------------------------------------------------------- *)
fun polarity ((pol,_) : literal) = pol;
fun atom ((_,atm) : literal) = atm;
fun name lit = Atom.name (atom lit);
fun arguments lit = Atom.arguments (atom lit);
fun arity lit = Atom.arity (atom lit);
fun positive lit = polarity lit;
fun negative lit = not (polarity lit);
fun negate (pol,atm) : literal = (not pol, atm)
fun relation lit = Atom.relation (atom lit);
fun functions lit = Atom.functions (atom lit);
fun functionNames lit = Atom.functionNames (atom lit);
(* Binary relations *)
fun mkBinop rel (pol,a,b) : literal = (pol, Atom.mkBinop rel (a,b));
fun destBinop rel ((pol,atm) : literal) =
case Atom.destBinop rel atm of (a,b) => (pol,a,b);
fun isBinop rel = can (destBinop rel);
(* Formulas *)
fun toFormula (true,atm) = Formula.Atom atm
| toFormula (false,atm) = Formula.Not (Formula.Atom atm);
fun fromFormula (Formula.Atom atm) = (true,atm)
| fromFormula (Formula.Not (Formula.Atom atm)) = (false,atm)
| fromFormula _ = raise Error "Literal.fromFormula";
(* ------------------------------------------------------------------------- *)
(* The size of a literal in symbols. *)
(* ------------------------------------------------------------------------- *)
fun symbols ((_,atm) : literal) = Atom.symbols atm;
(* ------------------------------------------------------------------------- *)
(* A total comparison function for literals. *)
(* ------------------------------------------------------------------------- *)
val compare = prodCompare boolCompare Atom.compare;
fun equal (p1,atm1) (p2,atm2) = p1 = p2 andalso Atom.equal atm1 atm2;
(* ------------------------------------------------------------------------- *)
(* Subterms. *)
(* ------------------------------------------------------------------------- *)
fun subterm lit path = Atom.subterm (atom lit) path;
fun subterms lit = Atom.subterms (atom lit);
fun replace (lit as (pol,atm)) path_tm =
let
val atm' = Atom.replace atm path_tm
in
if Portable.pointerEqual (atm,atm') then lit else (pol,atm')
end;
(* ------------------------------------------------------------------------- *)
(* Free variables. *)
(* ------------------------------------------------------------------------- *)
fun freeIn v lit = Atom.freeIn v (atom lit);
fun freeVars lit = Atom.freeVars (atom lit);
(* ------------------------------------------------------------------------- *)
(* Substitutions. *)
(* ------------------------------------------------------------------------- *)
fun subst sub (lit as (pol,atm)) : literal =
let
val atm' = Atom.subst sub atm
in
if Portable.pointerEqual (atm',atm) then lit else (pol,atm')
end;
(* ------------------------------------------------------------------------- *)
(* Matching. *)
(* ------------------------------------------------------------------------- *)
fun match sub ((pol1,atm1) : literal) (pol2,atm2) =
let
val _ = pol1 = pol2 orelse raise Error "Literal.match"
in
Atom.match sub atm1 atm2
end;
(* ------------------------------------------------------------------------- *)
(* Unification. *)
(* ------------------------------------------------------------------------- *)
fun unify sub ((pol1,atm1) : literal) (pol2,atm2) =
let
val _ = pol1 = pol2 orelse raise Error "Literal.unify"
in
Atom.unify sub atm1 atm2
end;
(* ------------------------------------------------------------------------- *)
(* The equality relation. *)
(* ------------------------------------------------------------------------- *)
fun mkEq l_r : literal = (true, Atom.mkEq l_r);
fun destEq ((true,atm) : literal) = Atom.destEq atm
| destEq (false,_) = raise Error "Literal.destEq";
val isEq = can destEq;
fun mkNeq l_r : literal = (false, Atom.mkEq l_r);
fun destNeq ((false,atm) : literal) = Atom.destEq atm
| destNeq (true,_) = raise Error "Literal.destNeq";
val isNeq = can destNeq;
fun mkRefl tm = (true, Atom.mkRefl tm);
fun destRefl (true,atm) = Atom.destRefl atm
| destRefl (false,_) = raise Error "Literal.destRefl";
val isRefl = can destRefl;
fun mkIrrefl tm = (false, Atom.mkRefl tm);
fun destIrrefl (true,_) = raise Error "Literal.destIrrefl"
| destIrrefl (false,atm) = Atom.destRefl atm;
val isIrrefl = can destIrrefl;
fun sym (pol,atm) : literal = (pol, Atom.sym atm);
fun lhs ((_,atm) : literal) = Atom.lhs atm;
fun rhs ((_,atm) : literal) = Atom.rhs atm;
(* ------------------------------------------------------------------------- *)
(* Special support for terms with type annotations. *)
(* ------------------------------------------------------------------------- *)
fun typedSymbols ((_,atm) : literal) = Atom.typedSymbols atm;
fun nonVarTypedSubterms ((_,atm) : literal) = Atom.nonVarTypedSubterms atm;
(* ------------------------------------------------------------------------- *)
(* Parsing and pretty-printing. *)
(* ------------------------------------------------------------------------- *)
val pp = Print.ppMap toFormula Formula.pp;
val toString = Print.toString pp;
fun fromString s = fromFormula (Formula.fromString s);
val parse = Parse.parseQuotation Term.toString fromString;
end
structure LiteralOrdered =
struct type t = Literal.literal val compare = Literal.compare end
structure LiteralMap = KeyMap (LiteralOrdered);
structure LiteralSet =
struct
local
structure S = ElementSet (LiteralMap);
in
open S;
end;
fun negateMember lit set = member (Literal.negate lit) set;
val negate =
let
fun f (lit,set) = add set (Literal.negate lit)
in
foldl f empty
end;
val relations =
let
fun f (lit,set) = NameAritySet.add set (Literal.relation lit)
in
foldl f NameAritySet.empty
end;
val functions =
let
fun f (lit,set) = NameAritySet.union set (Literal.functions lit)
in
foldl f NameAritySet.empty
end;
fun freeIn v = exists (Literal.freeIn v);
val freeVars =
let
fun f (lit,set) = NameSet.union set (Literal.freeVars lit)
in
foldl f NameSet.empty
end;
val freeVarsList =
let
fun f (lits,set) = NameSet.union set (freeVars lits)
in
List.foldl f NameSet.empty
end;
val symbols =
let
fun f (lit,z) = Literal.symbols lit + z
in
foldl f 0
end;
val typedSymbols =
let
fun f (lit,z) = Literal.typedSymbols lit + z
in
foldl f 0
end;
fun subst sub lits =
let
fun substLit (lit,(eq,lits')) =
let
val lit' = Literal.subst sub lit
val eq = eq andalso Portable.pointerEqual (lit,lit')
in
(eq, add lits' lit')
end
val (eq,lits') = foldl substLit (true,empty) lits
in
if eq then lits else lits'
end;
fun conjoin set =
Formula.listMkConj (List.map Literal.toFormula (toList set));
fun disjoin set =
Formula.listMkDisj (List.map Literal.toFormula (toList set));
val pp =
Print.ppMap
toList
(Print.ppBracket "{" "}" (Print.ppOpList "," Literal.pp));
end
structure LiteralSetOrdered =
struct type t = LiteralSet.set val compare = LiteralSet.compare end
structure LiteralSetMap = KeyMap (LiteralSetOrdered);
structure LiteralSetSet = ElementSet (LiteralSetMap);