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\documentclass{article}
\usepackage{open-axiom}
\title{src/algebra boolean.spad}
\author{Stephen M. Watt, Michael Monagan, Gabriel Dos~Reis}
\begin{document}
\maketitle
\begin{abstract}
\end{abstract}
\tableofcontents
\eject
\section{Categories an domains for logic}
<<category BOOLE BooleanLogic>>=
)abbrev category BOOLE BooleanLogic
++ Author: Gabriel Dos Reis
++ Date Created: April 04, 2010
++ Date Last Modified: April 04, 2010
++ Description:
++ This is the category of Boolean logic structures.
BooleanLogic(): Category == Logic with
not: % -> %
++ \spad{not x} returns the complement or negation of \spad{x}.
and: (%,%) -> %
++ \spad{x and y} returns the conjunction of \spad{x} and \spad{y}.
or: (%,%) -> %
++ \spad{x or y} returns the disjunction of \spad{x} and \spad{y}.
add
not x == ~ x
x and y == x /\ y
x or y == x \/ y
@
<<category PROPLOG PropositionalLogic>>=
)abbrev category PROPLOG PropositionalLogic
++ Author: Gabriel Dos Reis
++ Date Created: Januray 14, 2008
++ Date Last Modified: May 27, 2009
++ Description: This category declares the connectives of
++ Propositional Logic.
PropositionalLogic(): Category == Join(BooleanLogic,SetCategory) with
true: %
++ true is a logical constant.
false: %
++ false is a logical constant.
implies: (%,%) -> %
++ implies(p,q) returns the logical implication of `q' by `p'.
equiv: (%,%) -> %
++ equiv(p,q) returns the logical equivalence of `p', `q'.
@
\section{domain PROPFRML PropositionalFormula}
<<domain PROPFRML PropositionalFormula>>=
)set mess autoload on
)abbrev domain PROPFRML PropositionalFormula
++ Author: Gabriel Dos Reis
++ Date Created: Januray 14, 2008
++ Date Last Modified: February, 2011
++ Description: This domain implements propositional formula build
++ over a term domain, that itself belongs to PropositionalLogic
PropositionalFormula(T: SetCategory): Public == Private where
Public == Join(PropositionalLogic, CoercibleFrom T) with
isAtom : % -> Maybe T
++ \spad{isAtom f} returns a value \spad{v} such that
++ \spad{v case T} holds if the formula \spad{f} is a term.
isNot : % -> Maybe %
++ \spad{isNot f} returns a value \spad{v} such that
++ \spad{v case %} holds if the formula \spad{f} is a negation.
isAnd : % -> Maybe Pair(%,%)
++ \spad{isAnd f} returns a value \spad{v} such that
++ \spad{v case Pair(%,%)} holds if the formula \spad{f}
++ is a conjunction formula.
isOr : % -> Maybe Pair(%,%)
++ \spad{isOr f} returns a value \spad{v} such that
++ \spad{v case Pair(%,%)} holds if the formula \spad{f}
++ is a disjunction formula.
isImplies : % -> Maybe Pair(%,%)
++ \spad{isImplies f} returns a value \spad{v} such that
++ \spad{v case Pair(%,%)} holds if the formula \spad{f}
++ is an implication formula.
isEquiv : % -> Maybe Pair(%,%)
++ \spad{isEquiv f} returns a value \spad{v} such that
++ \spad{v case Pair(%,%)} holds if the formula \spad{f}
++ is an equivalence formula.
conjunction: (%,%) -> %
++ \spad{conjunction(p,q)} returns a formula denoting the
++ conjunction of \spad{p} and \spad{q}.
disjunction: (%,%) -> %
++ \spad{disjunction(p,q)} returns a formula denoting the
++ disjunction of \spad{p} and \spad{q}.
Private == add
Rep == Union(T, Kernel %)
import Kernel %
import BasicOperator
import KernelFunctions2(Identifier,%)
import List %
-- Local names for proposition logical operators
macro FALSE == '%false
macro TRUE == '%true
macro NOT == '%not
macro AND == '%and
macro OR == '%or
macro IMP == '%implies
macro EQV == '%equiv
-- Return the nesting level of a formula
level(f: %): NonNegativeInteger ==
f' := rep f
f' case T => 0
height f'
-- A term is a formula
coerce(t: T): % ==
per t
false == per constantKernel FALSE
true == per constantKernel TRUE
~ p ==
per kernel(operator(NOT, 1::Arity), [p], 1 + level p)
conjunction(p,q) ==
per kernel(operator(AND, 2), [p, q], 1 + max(level p, level q))
p /\ q == conjunction(p,q)
disjunction(p,q) ==
per kernel(operator(OR, 2), [p, q], 1 + max(level p, level q))
p \/ q == disjunction(p,q)
implies(p,q) ==
per kernel(operator(IMP, 2), [p, q], 1 + max(level p, level q))
equiv(p,q) ==
per kernel(operator(EQV, 2), [p, q], 1 + max(level p, level q))
isAtom f ==
f' := rep f
f' case T => just(f'@T)
nothing
isNot f ==
f' := rep f
f' case Kernel(%) and is?(f', NOT) => just(first argument f')
nothing
isBinaryOperator(f: Kernel %, op: Symbol): Maybe Pair(%, %) ==
not is?(f, op) => nothing
args := argument f
just pair(first args, second args)
isAnd f ==
f' := rep f
f' case Kernel % => isBinaryOperator(f', AND)
nothing
isOr f ==
f' := rep f
f' case Kernel % => isBinaryOperator(f', OR)
nothing
isImplies f ==
f' := rep f
f' case Kernel % => isBinaryOperator(f', IMP)
nothing
isEquiv f ==
f' := rep f
f' case Kernel % => isBinaryOperator(f', EQV)
nothing
-- Unparsing grammar.
--
-- Ideally, the following syntax would the external form
-- Formula:
-- EquivFormula
--
-- EquivFormula:
-- ImpliesFormula
-- ImpliesFormula <=> EquivFormula
--
-- ImpliesFormula:
-- OrFormula
-- OrFormula => ImpliesFormula
--
-- OrFormula:
-- AndFormula
-- AndFormula or OrFormula
--
-- AndFormula
-- NotFormula
-- NotFormula and AndFormula
--
-- NotFormula:
-- PrimaryFormula
-- not NotFormula
--
-- PrimaryFormula:
-- Term
-- ( Formula )
--
-- Note: Since the token '=>' already means a construct different
-- from what we would like to have as a notation for
-- propositional logic, we will output the formula `p => q'
-- as implies(p,q), which looks like a function call.
-- Similarly, we do not have the token `<=>' for logical
-- equivalence; so we unparser `p <=> q' as equiv(p,q).
--
-- So, we modify the nonterminal PrimaryFormula to read
-- PrimaryFormula:
-- Term
-- implies(Formula, Formula)
-- equiv(Formula, Formula)
formula: % -> OutputForm
coerce(p: %): OutputForm ==
formula p
primaryFormula(p: %): OutputForm ==
p' := rep p
p' case T => p'@T::OutputForm
case constantIfCan p' is
c@Identifier => c::OutputForm
otherwise =>
is?(p', IMP) or is?(p', EQV) =>
args := argument p'
elt(operator(p')::OutputForm,
[formula first args, formula second args])$OutputForm
paren(formula p)$OutputForm
notFormula(p: %): OutputForm ==
case isNot p is
f@% => elt(outputForm 'not, [notFormula f])$OutputForm
otherwise => primaryFormula p
andFormula(f: %): OutputForm ==
case isAnd f is
p@Pair(%,%) =>
-- ??? idealy, we should be using `and$OutputForm' but
-- ??? a bug in the compiler currently prevents that.
infix(outputForm 'and, notFormula first p,
andFormula second p)$OutputForm
otherwise => notFormula f
orFormula(f: %): OutputForm ==
case isOr f is
p@Pair(%,%) =>
-- ??? idealy, we should be using `or$OutputForm' but
-- ??? a bug in the compiler currently prevents that.
infix(outputForm 'or, andFormula first p,
orFormula second p)$OutputForm
otherwise => andFormula f
formula f ==
-- Note: this should be equivFormula, but see the explanation above.
orFormula f
@
<<package PROPFUN1 PropositionalFormulaFunctions1>>=
)abbrev package PROPFUN1 PropositionalFormulaFunctions1
++ Author: Gabriel Dos Reis
++ Date Created: April 03, 2010
++ Date Last Modified: April 03, 2010
++ Description:
++ This package collects unary functions operating on propositional
++ formulae.
PropositionalFormulaFunctions1(T): Public == Private where
T: SetCategory
Public == Type with
dual: PropositionalFormula T -> PropositionalFormula T
++ \spad{dual f} returns the dual of the proposition \spad{f}.
atoms: PropositionalFormula T -> Set T
++ \spad{atoms f} ++ returns the set of atoms appearing in
++ the formula \spad{f}.
simplify: PropositionalFormula T -> PropositionalFormula T
++ \spad{simplify f} returns a formula logically equivalent
++ to \spad{f} where obvious tautologies have been removed.
Private == add
macro F == PropositionalFormula T
inline Pair(F,F)
dual f ==
f = true$F => false$F
f = false$F => true$F
isAtom f case T => f
(f1 := isNot f) case F => not dual f1
(f2 := isAnd f) case Pair(F,F) =>
disjunction(dual first f2, dual second f2)
(f2 := isOr f) case Pair(F,F) =>
conjunction(dual first f2, dual second f2)
error "formula contains `equiv' or `implies'"
atoms f ==
(t := isAtom f) case T => { t }
(f1 := isNot f) case F => atoms f1
(f2 := isAnd f) case Pair(F,F) =>
union(atoms first f2, atoms second f2)
(f2 := isOr f) case Pair(F,F) =>
union(atoms first f2, atoms second f2)
empty()$Set(T)
-- one-step simplification helper function
simplifyOneStep(f: F): F ==
(f1 := isNot f) case F =>
f1 = true$F => false$F
f1 = false$F => true$F
(f1' := isNot f1) case F => f1' -- assume classical logic
f
(f2 := isAnd f) case Pair(F,F) =>
first f2 = false$F or second f2 = false$F => false$F
first f2 = true$F => second f2
second f2 = true$F => first f2
f
(f2 := isOr f) case Pair(F,F) =>
first f2 = false$F => second f2
second f2 = false$F => first f2
first f2 = true$F or second f2 = true$F => true$F
f
(f2 := isImplies f) case Pair(F,F) =>
first f2 = false$F or second f2 = true$F => true$F
first f2 = true$F => second f2
second f2 = false$F => not first f2
f
(f2 := isEquiv f) case Pair(F,F) =>
first f2 = true$F => second f2
second f2 = true$F => first f2
first f2 = false$F => not second f2
second f2 = false$F => not first f2
f
f
simplify f ==
(f1 := isNot f) case F => simplifyOneStep(not simplify f1)
(f2 := isAnd f) case Pair(F,F) =>
simplifyOneStep(conjunction(simplify first f2, simplify second f2))
(f2 := isOr f) case Pair(F,F) =>
simplifyOneStep(disjunction(simplify first f2, simplify second f2))
(f2 := isImplies f) case Pair(F,F) =>
simplifyOneStep(implies(simplify first f2, simplify second f2))
(f2 := isEquiv f) case Pair(F,F) =>
simplifyOneStep(equiv(simplify first f2, simplify second f2))
f
@
<<package PROPFUN2 PropositionalFormulaFunctions2>>=
)abbrev package PROPFUN2 PropositionalFormulaFunctions2
++ Author: Gabriel Dos Reis
++ Date Created: April 03, 2010
++ Date Last Modified: April 03, 2010
++ Description:
++ This package collects binary functions operating on propositional
++ formulae.
PropositionalFormulaFunctions2(S,T): Public == Private where
S: SetCategory
T: SetCategory
Public == Type with
map: (S -> T, PropositionalFormula S) -> PropositionalFormula T
++ \spad{map(f,x)} returns a propositional formula where
++ all atoms in \spad{x} have been replaced by the result
++ of applying the function \spad{f} to them.
Private == add
macro FS == PropositionalFormula S
macro FT == PropositionalFormula T
map(f,x) ==
x = true$FS => true$FT
x = false$FS => false$FT
(t := isAtom x) case S => f(t)::FT
(f1 := isNot x) case FS => not map(f,f1)
(f2 := isAnd x) case Pair(FS,FS) =>
conjunction(map(f,first f2), map(f,second f2))
(f2 := isOr x) case Pair(FS,FS) =>
disjunction(map(f,first f2), map(f,second f2))
(f2 := isImplies x) case Pair(FS,FS) =>
implies(map(f,first f2), map(f,second f2))
(f2 := isEquiv x) case Pair(FS,FS) =>
equiv(map(f,first f2), map(f,second f2))
error "invalid propositional formula"
@
\section{domain REF Reference}
<<domain REF Reference>>=
)abbrev domain REF Reference
++ Author: Stephen M. Watt
++ Date Created:
++ Date Last Changed: October 11, 2011
++ Basic Operations: deref, ref, setref, =
++ Related Constructors:
++ Keywords: reference
++ Description: \spadtype{Reference} is for making a changeable instance
++ of something.
Reference(S:Type): SetCategory with
ref : S -> %
++ \spad{ref(s)} creates a reference to the object \spad{s}.
deref : % -> S
++ \spad{deref(r)} returns the object referenced by \spad{r}
setref: (%, S) -> S
++ setref(r,s) reset the reference \spad{r} to refer to \spad{s}
= : (%, %) -> Boolean
++ \spad{a=b} tests if \spad{a} and \spad{b} are equal.
== add
Rep == Record(value: S)
import %peq: (%,%) -> Boolean from Foreign Builtin
p = q == %peq(p,q)
ref v == per [v]
deref p == rep(p).value
setref(p, v) == rep(p).value := v
coerce p ==
obj :=
S has CoercibleTo OutputForm => rep(p).value::OutputForm
'?::OutputForm
prefix('ref::OutputForm, [obj])
@
\section{category LOGIC Logic}
<<category LOGIC Logic>>=
)abbrev category LOGIC Logic
++ Author:
++ Date Created:
++ Date Last Changed: May 27, 2009
++ Basic Operations: ~, /\, \/
++ Related Constructors:
++ Keywords: boolean
++ Description:
++ `Logic' provides the basic operations for lattices,
++ e.g., boolean algebra.
Logic: Category == Type with
~: % -> %
++ ~(x) returns the logical complement of x.
/\: (%, %) -> %
++ \spadignore { /\ }returns the logical `meet', e.g. `and'.
\/: (%, %) -> %
++ \spadignore{ \/ } returns the logical `join', e.g. `or'.
add
x \/ y == ~(~x /\ ~y)
@
\section{domain BOOLEAN Boolean}
<<domain BOOLEAN Boolean>>=
)abbrev domain BOOLEAN Boolean
++ Author: Stephen M. Watt
++ Date Created:
++ Date Last Changed: May 27, 2009
++ Basic Operations: true, false, not, and, or, xor, nand, nor, implies
++ Related Constructors:
++ Keywords: boolean
++ Description: \spadtype{Boolean} is the elementary logic with 2 values:
++ true and false
Boolean(): Join(OrderedFinite, PropositionalLogic, ConvertibleTo InputForm) with
xor : (%, %) -> %
++ xor(a,b) returns the logical exclusive {\em or}
++ of Boolean \spad{a} and b.
nand : (%, %) -> %
++ nand(a,b) returns the logical negation of \spad{a} and b.
nor : (%, %) -> %
++ nor(a,b) returns the logical negation of \spad{a} or b.
== add
import %false: % from Foreign Builtin
import %true: % from Foreign Builtin
import %peq: (%,%) -> Boolean from Foreign Builtin
import %and: (%,%) -> % from Foreign Builtin
import %or: (%,%) -> % from Foreign Builtin
import %not: % -> % from Foreign Builtin
true == %true
false == %false
not b == %not b
~b == %not b
a and b == %and(a,b)
a /\ b == %and(a,b)
a or b == %or(a,b)
a \/ b == %or(a,b)
xor(a, b) == (a => %not b; b)
nor(a, b) == (a => %false; %not b)
nand(a, b) == (a => %not b; %true)
a = b == %peq(a,b)
implies(a, b) == (a => b; %true)
equiv(a,b) == %peq(a, b)
a < b == (b => %not a; %false)
size() == 2
index i ==
even?(i::Integer) => %false
%true
lookup a ==
a => 1
2
random() ==
even?(random()$Integer) => %false
%true
convert(x:%):InputForm ==
x => 'true
'false
coerce(x:%):OutputForm ==
x => 'true
'false
@
\section{domain IBITS IndexedBits}
<<domain IBITS IndexedBits>>=
)abbrev domain IBITS IndexedBits
++ Author: Stephen Watt and Michael Monagan
++ Date Created:
++ July 86
++ Change History:
++ Oct 87
++ Basic Operations: range
++ Related Constructors:
++ Keywords: indexed bits
++ Description: \spadtype{IndexedBits} is a domain to compactly represent
++ large quantities of Boolean data.
IndexedBits(mn:Integer): BitAggregate() with
-- temporaries until parser gets better
Not: % -> %
++ Not(n) returns the bit-by-bit logical {\em Not} of n.
Or : (%, %) -> %
++ Or(n,m) returns the bit-by-bit logical {\em Or} of
++ n and m.
And: (%, %) -> %
++ And(n,m) returns the bit-by-bit logical {\em And} of
++ n and m.
== add
import %2bool: NonNegativeInteger -> Boolean from Foreign Builtin
import %2bit: Boolean -> NonNegativeInteger from Foreign Builtin
import %bitveccopy: % -> % from Foreign Builtin
import %bitveclength: % -> NonNegativeInteger from Foreign Builtin
import %bitvecref: (%,Integer) -> NonNegativeInteger
from Foreign Builtin
import %bitveceq: (%,%) -> Boolean from Foreign Builtin
import %bitveclt: (%,%) -> Boolean from Foreign Builtin
import %bitvecnot: % -> % from Foreign Builtin
import %bitvecand: (%,%) -> % from Foreign Builtin
import %bitvecor: (%,%) -> % from Foreign Builtin
import %bitvecxor: (%,%) -> % from Foreign Builtin
import %bitvector: (NonNegativeInteger,NonNegativeInteger) -> %
from Foreign Builtin
minIndex u == mn
-- range check index of `i' into `v'.
range(v: %, i: Integer): Integer ==
i >= 0 and i < #v => i
error "Index out of range"
coerce(v):OutputForm ==
t:Character := char "1"
f:Character := char "0"
s := new(#v, space()$Character)$String
for i in minIndex(s)..maxIndex(s) for j in mn.. repeat
s.i := if v.j then t else f
s::OutputForm
new(n, b) == %bitvector(n, %2bit(b)$Foreign(Builtin))
empty() == %bitvector(0,0)
copy v == %bitveccopy v
#v == %bitveclength v
v = u == %bitveceq(v,u)
v < u == %bitveclt(v,u)
u and v == (#v=#u => %bitvecand(v,u); map("and",v,u))
u or v == (#v=#u => %bitvecor(v,u); map("or", v,u))
xor(v,u) == (#v=#u => %bitvecxor(v,u); map("xor",v,u))
setelt(v:%, i:Integer, f:Boolean) ==
%2bool %store(%bitvecref(v,range(v,i-mn)),%2bit f)$Foreign(Builtin)
elt(v:%, i:Integer) ==
%2bool %bitvecref(v,range(v,i-mn))
Not v == %bitvecnot v
And(u, v) == (#v=#u => %bitvecand(v,u); map("and",v,u))
Or(u, v) == (#v=#u => %bitvecor(v,u); map("or", v,u))
@
\section{domain BITS Bits}
<<domain BITS Bits>>=
)abbrev domain BITS Bits
++ Author: Stephen M. Watt
++ Date Created:
++ Change History:
++ Basic Operations: And, Not, Or
++ Related Constructors:
++ Keywords: bits
++ Description: \spadtype{Bits} provides logical functions for Indexed Bits.
Bits(): Exports == Implementation where
Exports == BitAggregate() with
bits: (NonNegativeInteger, Boolean) -> %
++ bits(n,b) creates bits with n values of b
Implementation == IndexedBits(1) add
bits(n,b) == new(n,b)
@
\section{Kleene's Three-Valued Logic}
<<domain KTVLOGIC KleeneTrivalentLogic>>=
)abbrev domain KTVLOGIC KleeneTrivalentLogic
++ Author: Gabriel Dos Reis
++ Date Created: September 20, 2008
++ Date Last Modified: May 27, 2009
++ Description:
++ This domain implements Kleene's 3-valued propositional logic.
KleeneTrivalentLogic(): Public == Private where
Public == PropositionalLogic with
unknown: % ++ the indefinite `unknown'
case: (%,[| false |]) -> Boolean
++ x case false holds if the value of `x' is `false'
case: (%,[| unknown |]) -> Boolean
++ x case unknown holds if the value of `x' is `unknown'
case: (%,[| true |]) -> Boolean
++ s case true holds if the value of `x' is `true'.
Private == add
Rep == Byte -- We need only 3 bits, in fact.
false == per(0::Byte)
unknown == per(1::Byte)
true == per(2::Byte)
x = y == rep x = rep y
x case true == x = true
x case false == x = false
x case unknown == x = unknown
not x ==
x case false => true
x case unknown => unknown
false
x and y ==
x case false => false
x case unknown =>
y case false => false
unknown
y
x or y ==
x case false => y
x case true => x
y case true => y
unknown
implies(x,y) ==
x case false => true
x case true => y
y case true => true
unknown
equiv(x,y) ==
x case unknown => x
x case true => y
not y
coerce(x: %): OutputForm ==
x case true => outputForm 'true
x case false => outputForm 'false
outputForm 'unknown
@
\section{License}
<<license>>=
--Copyright (c) 1991-2002, The Numerical Algorithms Group Ltd.
--All rights reserved.
--Copyright (C) 2007-2010, Gabriel Dos Reis.
--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.
--
-- - Neither the name of The Numerical Algorithms Group Ltd. nor the
-- names of its contributors may 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.
@
<<*>>=
<<license>>
<<category BOOLE BooleanLogic>>
<<category LOGIC Logic>>
<<domain BOOLEAN Boolean>>
<<category PROPLOG PropositionalLogic>>
<<domain PROPFRML PropositionalFormula>>
<<package PROPFUN1 PropositionalFormulaFunctions1>>
<<package PROPFUN2 PropositionalFormulaFunctions2>>
<<domain KTVLOGIC KleeneTrivalentLogic>>
<<domain IBITS IndexedBits>>
<<domain BITS Bits>>
<<domain REF Reference>>
@
\eject
\begin{thebibliography}{99}
\bibitem{1} nothing
\end{thebibliography}
\end{document}
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