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\documentclass{article}
\usepackage{axiom}
\begin{document}
\title{\$SPAD/src/algebra modring.spad}
\author{Patrizia Gianni, Barry Trager}
\maketitle
\begin{abstract}
\end{abstract}
\eject
\tableofcontents
\eject
\section{domain MODRING ModularRing}
<<domain MODRING ModularRing>>=
)abbrev domain MODRING ModularRing
++ Author: P.Gianni, B.Trager
++ Date Created:
++ Date Last Updated:
++ Basic Functions:
++ Related Constructors:
++ Also See:
++ AMS Classifications:
++ Keywords:
++ References:
++ Description:
++ These domains are used for the factorization and gcds
++ of univariate polynomials over the integers in order to work modulo
++ different primes.
++ See \spadtype{EuclideanModularRing} ,\spadtype{ModularField}
ModularRing(R,Mod,reduction:(R,Mod) -> R,
merge:(Mod,Mod) -> Union(Mod,"failed"),
exactQuo : (R,R,Mod) -> Union(R,"failed")) : C == T
where
R : CommutativeRing
Mod : AbelianMonoid
C == Ring with
modulus : % -> Mod
++ modulus(x) \undocumented
coerce : % -> R
++ coerce(x) \undocumented
reduce : (R,Mod) -> %
++ reduce(r,m) \undocumented
exQuo : (%,%) -> Union(%,"failed")
++ exQuo(x,y) \undocumented
recip : % -> Union(%,"failed")
++ recip(x) \undocumented
inv : % -> %
++ inv(x) \undocumented
T == add
--representation
Rep:= Record(val:R,modulo:Mod)
--declarations
x,y: %
--define
modulus(x) == x.modulo
coerce(x: %): R == x.val
coerce(i:Integer):% == [i::R,0]$Rep
i:Integer * x:% == (i::%)*x
coerce(x):OutputForm == (x.val)::OutputForm
reduce (a:R,m:Mod) == [reduction(a,m),m]$Rep
characteristic():NonNegativeInteger == characteristic()$R
0 == [0$R,0$Mod]$Rep
1 == [1$R,0$Mod]$Rep
zero? x == zero? x.val
one? x == one? x.val
newmodulo(m1:Mod,m2:Mod) : Mod ==
r:=merge(m1,m2)
r case "failed" => error "incompatible moduli"
r::Mod
x=y ==
x.val = y.val => true
x.modulo = y.modulo => false
(x-y).val = 0
x+y == reduce((x.val +$R y.val),newmodulo(x.modulo,y.modulo))
x-y == reduce((x.val -$R y.val),newmodulo(x.modulo,y.modulo))
-x == reduce ((-$R x.val),x.modulo)
x*y == reduce((x.val *$R y.val),newmodulo(x.modulo,y.modulo))
exQuo(x,y) ==
xm:=x.modulo
if xm ~=$Mod y.modulo then xm:=newmodulo(xm,y.modulo)
r:=exactQuo(x.val,y.val,xm)
r case "failed"=> "failed"
[r::R,xm]$Rep
--if R has EuclideanDomain then
recip x ==
r:=exactQuo(1$R,x.val,x.modulo)
r case "failed" => "failed"
[r,x.modulo]$Rep
inv x ==
if (u:=recip x) case "failed" then error("not invertible")
else u::%
@
\section{domain EMR EuclideanModularRing}
<<domain EMR EuclideanModularRing>>=
)abbrev domain EMR EuclideanModularRing
++ Description:
++ These domains are used for the factorization and gcds
++ of univariate polynomials over the integers in order to work modulo
++ different primes.
++ See \spadtype{ModularRing}, \spadtype{ModularField}
EuclideanModularRing(S,R,Mod,reduction:(R,Mod) -> R,
merge:(Mod,Mod) -> Union(Mod,"failed"),
exactQuo : (R,R,Mod) -> Union(R,"failed")) : C == T
where
S : CommutativeRing
R : UnivariatePolynomialCategory S
Mod : AbelianMonoid
C == EuclideanDomain with
modulus : % -> Mod
++ modulus(x) \undocumented
coerce : % -> R
++ coerce(x) \undocumented
reduce : (R,Mod) -> %
++ reduce(r,m) \undocumented
exQuo : (%,%) -> Union(%,"failed")
++ exQuo(x,y) \undocumented
recip : % -> Union(%,"failed")
++ recip(x) \undocumented
inv : % -> %
++ inv(x) \undocumented
elt : (%, R) -> R
++ elt(x,r) or x.r \undocumented
T == ModularRing(R,Mod,reduction,merge,exactQuo) add
--representation
Rep:= Record(val:R,modulo:Mod)
--declarations
x,y,z: %
divide(x,y) ==
t:=merge(x.modulo,y.modulo)
t case "failed" => error "incompatible moduli"
xm:=t::Mod
yv:=y.val
invlcy:R
if one? leadingCoefficient yv then invlcy:=1
else
invlcy:=(inv reduce((leadingCoefficient yv)::R,xm)).val
yv:=reduction(invlcy*yv,xm)
r:=monicDivide(x.val,yv)
[reduce(invlcy*r.quotient,xm),reduce(r.remainder,xm)]
if R has fmecg:(R,NonNegativeInteger,S,R)->R
then x rem y ==
t:=merge(x.modulo,y.modulo)
t case "failed" => error "incompatible moduli"
xm:=t::Mod
yv:=y.val
invlcy:R
if not one? leadingCoefficient yv then
invlcy:=(inv reduce((leadingCoefficient yv)::R,xm)).val
yv:=reduction(invlcy*yv,xm)
dy:=degree yv
xv:=x.val
while (d:=degree xv - dy)>=0 repeat
xv:=reduction(fmecg(xv,d::NonNegativeInteger,
leadingCoefficient xv,yv),xm)
xv = 0 => return [xv,xm]$Rep
[xv,xm]$Rep
else x rem y ==
t:=merge(x.modulo,y.modulo)
t case "failed" => error "incompatible moduli"
xm:=t::Mod
yv:=y.val
invlcy:R
if not one? leadingCoefficient yv then
invlcy:=(inv reduce((leadingCoefficient yv)::R,xm)).val
yv:=reduction(invlcy*yv,xm)
r:=monicDivide(x.val,yv)
reduce(r.remainder,xm)
euclideanSize x == degree x.val
unitCanonical x ==
zero? x => x
degree(x.val) = 0 => 1
one? leadingCoefficient(x.val) => x
invlcx:%:=inv reduce((leadingCoefficient(x.val))::R,x.modulo)
invlcx * x
unitNormal x ==
zero?(x) or one?(leadingCoefficient(x.val)) => [1, x, 1]
lcx := reduce((leadingCoefficient(x.val))::R,x.modulo)
invlcx:=inv lcx
degree(x.val) = 0 => [lcx, 1, invlcx]
[lcx, invlcx * x, invlcx]
elt(x : %,s : R) : R == reduction(elt(x.val,s),x.modulo)
@
\section{domain MODFIELD ModularField}
<<domain MODFIELD ModularField>>=
)abbrev domain MODFIELD ModularField
++ These domains are used for the factorization and gcds
++ of univariate polynomials over the integers in order to work modulo
++ different primes.
++ See \spadtype{ModularRing}, \spadtype{EuclideanModularRing}
ModularField(R,Mod,reduction:(R,Mod) -> R,
merge:(Mod,Mod) -> Union(Mod,"failed"),
exactQuo : (R,R,Mod) -> Union(R,"failed")) : C == T
where
R : CommutativeRing
Mod : AbelianMonoid
C == Field with
modulus : % -> Mod
++ modulus(x) \undocumented
coerce : % -> R
++ coerce(x) \undocumented
reduce : (R,Mod) -> %
++ reduce(r,m) \undocumented
exQuo : (%,%) -> Union(%,"failed")
++ exQuo(x,y) \undocumented
T == ModularRing(R,Mod,reduction,merge,exactQuo)
@
\section{License}
<<license>>=
--Copyright (c) 1991-2002, The Numerical ALgorithms Group Ltd.
--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>>
<<domain MODRING ModularRing>>
<<domain EMR EuclideanModularRing>>
<<domain MODFIELD ModularField>>
@
\eject
\begin{thebibliography}{99}
\bibitem{1} nothing
\end{thebibliography}
\end{document}
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