Added bitvector library (Word) to HOL/Library and a theory using it (Adder)
to HOL/ex.
(* Title: HOL/Tools/prop_logic.ML
ID: $Id$
Author: Tjark Weber
Copyright 2004
Formulas of propositional logic.
*)
signature PROP_LOGIC =
sig
datatype prop_formula =
True
| False
| BoolVar of int (* NOTE: only use indices >= 1 *)
| Not of prop_formula
| Or of prop_formula * prop_formula
| And of prop_formula * prop_formula
val SNot : prop_formula -> prop_formula
val SOr : prop_formula * prop_formula -> prop_formula
val SAnd : prop_formula * prop_formula -> prop_formula
val indices : prop_formula -> int list (* all variable indices *)
val maxidx : prop_formula -> int (* maximal variable index *)
val nnf : prop_formula -> prop_formula (* negation normal form *)
val cnf : prop_formula -> prop_formula (* clause normal form *)
val defcnf : prop_formula -> prop_formula (* definitional cnf *)
val exists : prop_formula list -> prop_formula (* finite disjunction *)
val all : prop_formula list -> prop_formula (* finite conjunction *)
val dot_product : prop_formula list * prop_formula list -> prop_formula
val eval : (int -> bool) -> prop_formula -> bool (* semantics *)
end;
structure PropLogic : PROP_LOGIC =
struct
(* ------------------------------------------------------------------------- *)
(* prop_formula: formulas of propositional logic, built from boolean *)
(* variables (referred to by index) and True/False using *)
(* not/or/and *)
(* ------------------------------------------------------------------------- *)
datatype prop_formula =
True
| False
| BoolVar of int (* NOTE: only use indices >= 1 *)
| Not of prop_formula
| Or of prop_formula * prop_formula
| And of prop_formula * prop_formula;
(* ------------------------------------------------------------------------- *)
(* The following constructor functions make sure that True and False do not *)
(* occur within any of the other connectives (i.e. Not, Or, And), and *)
(* perform double-negation elimination. *)
(* ------------------------------------------------------------------------- *)
(* prop_formula -> prop_formula *)
fun SNot True = False
| SNot False = True
| SNot (Not fm) = fm
| SNot fm = Not fm;
(* prop_formula * prop_formula -> prop_formula *)
fun SOr (True, _) = True
| SOr (_, True) = True
| SOr (False, fm) = fm
| SOr (fm, False) = fm
| SOr (fm1, fm2) = Or (fm1, fm2);
(* prop_formula * prop_formula -> prop_formula *)
fun SAnd (True, fm) = fm
| SAnd (fm, True) = fm
| SAnd (False, _) = False
| SAnd (_, False) = False
| SAnd (fm1, fm2) = And (fm1, fm2);
(* ------------------------------------------------------------------------- *)
(* indices: collects all indices of boolean variables that occur in a *)
(* propositional formula 'fm'; no duplicates *)
(* ------------------------------------------------------------------------- *)
(* prop_formula -> int list *)
fun indices True = []
| indices False = []
| indices (BoolVar i) = [i]
| indices (Not fm) = indices fm
| indices (Or (fm1,fm2)) = (indices fm1) union_int (indices fm2)
| indices (And (fm1,fm2)) = (indices fm1) union_int (indices fm2);
(* ------------------------------------------------------------------------- *)
(* maxidx: computes the maximal variable index occuring in a formula of *)
(* propositional logic 'fm'; 0 if 'fm' contains no variable *)
(* ------------------------------------------------------------------------- *)
(* prop_formula -> int *)
fun maxidx True = 0
| maxidx False = 0
| maxidx (BoolVar i) = i
| maxidx (Not fm) = maxidx fm
| maxidx (Or (fm1,fm2)) = Int.max (maxidx fm1, maxidx fm2)
| maxidx (And (fm1,fm2)) = Int.max (maxidx fm1, maxidx fm2);
(* ------------------------------------------------------------------------- *)
(* nnf: computes the negation normal form of a formula 'fm' of propositional *)
(* logic (i.e. only variables may be negated, but not subformulas) *)
(* ------------------------------------------------------------------------- *)
(* prop_formula -> prop_formula *)
fun
(* constants *)
nnf True = True
| nnf False = False
(* variables *)
| nnf (BoolVar i) = BoolVar i
(* 'or' and 'and' as outermost connectives are left untouched *)
| nnf (Or (fm1,fm2)) = SOr (nnf fm1, nnf fm2)
| nnf (And (fm1,fm2)) = SAnd (nnf fm1, nnf fm2)
(* 'not' + constant *)
| nnf (Not True) = False
| nnf (Not False) = True
(* 'not' + variable *)
| nnf (Not (BoolVar i)) = Not (BoolVar i)
(* pushing 'not' inside of 'or'/'and' using de Morgan's laws *)
| nnf (Not (Or (fm1,fm2))) = SAnd (nnf (SNot fm1), nnf (SNot fm2))
| nnf (Not (And (fm1,fm2))) = SOr (nnf (SNot fm1), nnf (SNot fm2))
(* double-negation elimination *)
| nnf (Not (Not fm)) = nnf fm;
(* ------------------------------------------------------------------------- *)
(* cnf: computes the clause normal form (i.e. a conjunction of disjunctions) *)
(* of a formula 'fm' of propositional logic. The result formula may be *)
(* exponentially longer than 'fm'. *)
(* ------------------------------------------------------------------------- *)
(* prop_formula -> prop_formula *)
fun cnf fm =
let
fun
(* constants *)
cnf_from_nnf True = True
| cnf_from_nnf False = False
(* literals *)
| cnf_from_nnf (BoolVar i) = BoolVar i
| cnf_from_nnf (Not (BoolVar i)) = Not (BoolVar i)
(* pushing 'or' inside of 'and' using distributive laws *)
| cnf_from_nnf (Or (fm1,fm2)) =
let
val fm1' = cnf_from_nnf fm1
val fm2' = cnf_from_nnf fm2
in
case fm1' of
And (fm11,fm12) => cnf_from_nnf (SAnd (SOr(fm11,fm2'),SOr(fm12,fm2')))
| _ =>
(case fm2' of
And (fm21,fm22) => cnf_from_nnf (SAnd (SOr(fm1',fm21),SOr(fm1',fm22)))
(* neither subformula contains 'and' *)
| _ => Or (fm1,fm2))
end
(* 'and' as outermost connective is left untouched *)
| cnf_from_nnf (And (fm1,fm2)) = SAnd (cnf_from_nnf fm1, cnf_from_nnf fm2)
(* 'not' + something other than a variable: formula is not in negation normal form *)
| cnf_from_nnf _ = raise ERROR
in
(cnf_from_nnf o nnf) fm
end;
(* ------------------------------------------------------------------------- *)
(* defcnf: computes the definitional clause normal form of a formula 'fm' of *)
(* propositional logic, introducing auxiliary variables if necessary to *)
(* avoid an exponential blowup of the formula. The result formula is *)
(* satisfiable if and only if 'fm' is satisfiable. *)
(* ------------------------------------------------------------------------- *)
(* prop_formula -> prop_formula *)
fun defcnf fm =
let
(* prop_formula * int -> prop_formula * int *)
(* 'new' specifies the next index that is available to introduce an auxiliary variable *)
fun
(* constants *)
defcnf_from_nnf (True,new) = (True, new)
| defcnf_from_nnf (False,new) = (False, new)
(* literals *)
| defcnf_from_nnf (BoolVar i,new) = (BoolVar i, new)
| defcnf_from_nnf (Not (BoolVar i),new) = (Not (BoolVar i), new)
(* pushing 'or' inside of 'and' using distributive laws *)
| defcnf_from_nnf (Or (fm1,fm2),new) =
let
val (fm1',new') = defcnf_from_nnf (fm1, new)
val (fm2',new'') = defcnf_from_nnf (fm2, new')
in
case fm1' of
And (fm11,fm12) =>
let
val aux = BoolVar new''
in
(* '(fm11 AND fm12) OR fm2' is SAT-equivalent to '(fm11 OR aux) AND (fm12 OR aux) AND (fm2 OR NOT aux)' *)
defcnf_from_nnf (SAnd (SAnd (SOr (fm11,aux), SOr (fm12,aux)), SOr(fm2', Not aux)), new''+1)
end
| _ =>
(case fm2' of
And (fm21,fm22) =>
let
val aux = BoolVar new''
in
(* 'fm1 OR (fm21 AND fm22)' is SAT-equivalent to '(fm1 OR NOT aux) AND (fm21 OR aux) AND (fm22 OR NOT aux)' *)
defcnf_from_nnf (SAnd (SOr (fm1', Not aux), SAnd (SOr (fm21,aux), SOr (fm22,aux))), new''+1)
end
(* neither subformula contains 'and' *)
| _ => (Or (fm1,fm2),new))
end
(* 'and' as outermost connective is left untouched *)
| defcnf_from_nnf (And (fm1,fm2),new) =
let
val (fm1',new') = defcnf_from_nnf (fm1, new)
val (fm2',new'') = defcnf_from_nnf (fm2, new')
in
(SAnd (fm1', fm2'), new'')
end
(* 'not' + something other than a variable: formula is not in negation normal form *)
| defcnf_from_nnf (_,_) = raise ERROR
in
(fst o defcnf_from_nnf) (nnf fm, (maxidx fm)+1)
end;
(* ------------------------------------------------------------------------- *)
(* exists: computes the disjunction over a list 'xs' of propositional *)
(* formulas *)
(* ------------------------------------------------------------------------- *)
(* prop_formula list -> prop_formula *)
fun exists xs = foldl SOr (False, xs);
(* ------------------------------------------------------------------------- *)
(* all: computes the conjunction over a list 'xs' of propositional formulas *)
(* ------------------------------------------------------------------------- *)
(* prop_formula list -> prop_formula *)
fun all xs = foldl SAnd (True, xs);
(* ------------------------------------------------------------------------- *)
(* dot_product: ([x1,...,xn], [y1,...,yn]) -> x1*y1+...+xn*yn *)
(* ------------------------------------------------------------------------- *)
(* prop_formula list * prop_formula list -> prop_formula *)
fun dot_product (xs,ys) = exists (map SAnd (xs~~ys));
(* ------------------------------------------------------------------------- *)
(* eval: given an assignment 'a' of boolean values to variable indices, the *)
(* truth value of a propositional formula 'fm' is computed *)
(* ------------------------------------------------------------------------- *)
(* (int -> bool) -> prop_formula -> bool *)
fun eval a True = true
| eval a False = false
| eval a (BoolVar i) = (a i)
| eval a (Not fm) = not (eval a fm)
| eval a (Or (fm1,fm2)) = (eval a fm1) orelse (eval a fm2)
| eval a (And (fm1,fm2)) = (eval a fm1) andalso (eval a fm2);
end;