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\documentclass{article}
\usepackage{open-axiom}
\begin{document}
\title{\$SPAD/src/algebra ffhom.spad}
\author{Johannes Grabmeier, Alfred Scheerhorn}
\maketitle
\begin{abstract}
\end{abstract}
\eject
\tableofcontents
\eject
\begin{verbatim}
-- 28.01.93: AS and JG: setting of init? flag in
-- functions initialize put at the
-- end to avoid errors with interruption.
-- 12.05.92 JG: long lines
-- 17.02.92 AS: convertWRTdifferentDefPol12 and convertWRTdifferentDefPol21
-- simplified.
-- 17.02.92 AS: initialize() modified set up of basis change
-- matrices between normal and polynomial rep.
-- New version uses reducedQPowers and is more efficient.
-- 24.07.92 JG: error messages improved
\end{verbatim}
\section{package FFHOM FiniteFieldHomomorphisms}
<<package FFHOM FiniteFieldHomomorphisms>>=
)abbrev package FFHOM FiniteFieldHomomorphisms
++ Authors: J.Grabmeier, A.Scheerhorn
++ Date Created: 26.03.1991
++ Date Last Updated:
++ Basic Operations:
++ Related Constructors: FiniteFieldCategory, FiniteAlgebraicExtensionField
++ Also See:
++ AMS Classifications:
++ Keywords: finite field, homomorphism, isomorphism
++ References:
++ R.Lidl, H.Niederreiter: Finite Field, Encycoldia of Mathematics and
++ Its Applications, Vol. 20, Cambridge Univ. Press, 1983, ISBN 0 521 30240 4
++ J. Grabmeier, A. Scheerhorn: Finite Fields in AXIOM.
++ AXIOM Technical Report Series, ATR/5 NP2522.
++ Description:
++ FiniteFieldHomomorphisms(F1,GF,F2) exports coercion functions of
++ elements between the fields {\em F1} and {\em F2}, which both must be
++ finite simple algebraic extensions of the finite ground field {\em GF}.
FiniteFieldHomomorphisms(F1,GF,F2): Exports == Implementation where
F1: FiniteAlgebraicExtensionField(GF)
GF: FiniteFieldCategory
F2: FiniteAlgebraicExtensionField(GF)
-- the homorphism can only convert elements w.r.t. the last extension .
-- Adding a function 'groundField()' which returns the groundfield of GF
-- as a variable of type FiniteFieldCategory in the new compiler, one
-- could build up 'convert' recursively to get an homomorphism w.r.t
-- the whole extension.
I ==> Integer
NNI ==> NonNegativeInteger
SI ==> SingleInteger
PI ==> PositiveInteger
SUP ==> SparseUnivariatePolynomial
M ==> Matrix GF
FFP ==> FiniteFieldExtensionByPolynomial
FFPOL2 ==> FiniteFieldPolynomialPackage2
FFPOLY ==> FiniteFieldPolynomialPackage
OUT ==> OutputForm
Exports ==> with
coerce: F1 -> F2
++ coerce(x) is the homomorphic image of x from
++ {\em F1} in {\em F2}. Thus {\em coerce} is a
++ field homomorphism between the fields extensions
++ {\em F1} and {\em F2} both over ground field {\em GF}
++ (the second argument to the package).
++ Error: if the extension degree of {\em F1} doesn't divide
++ the extension degree of {\em F2}.
++ Note that the other coercion function in the
++ \spadtype{FiniteFieldHomomorphisms} is a left inverse.
coerce: F2 -> F1
++ coerce(x) is the homomorphic image of x from
++ {\em F2} in {\em F1}, where {\em coerce} is a
++ field homomorphism between the fields extensions
++ {\em F2} and {\em F1} both over ground field {\em GF}
++ (the second argument to the package).
++ Error: if the extension degree of {\em F2} doesn't divide
++ the extension degree of {\em F1}.
++ Note that the other coercion function in the
++ \spadtype{FiniteFieldHomomorphisms} is a left inverse.
-- coerce(coerce(x:F1)@F2)@F1 = x and coerce(coerce(y:F2)@F1)@F2 = y
Implementation ==> add
-- global variables ===================================================
degree1:NNI:= extensionDegree()$F1
degree2:NNI:= extensionDegree()$F2
-- the degrees of the last extension
-- a necessary condition for the one field being an subfield of
-- the other one is, that the respective extension degrees are
-- multiples
if max(degree1,degree2) rem min(degree1,degree2) ~= 0 then
error "FFHOM: one extension degree must divide the other one"
conMat1to2:M:= zero(degree2,degree1)$M
-- conversion Matix for the conversion direction F1 -> F2
conMat2to1:M:= zero(degree1,degree2)$M
-- conversion Matix for the conversion direction F2 -> F1
repType1:=representationType()$F1
repType2:=representationType()$F2
-- the representation types of the fields
init?:Boolean:=true
-- gets false after initialization
defPol1:=definingPolynomial()$F1
defPol2:=definingPolynomial()$F2
-- the defining polynomials of the fields
-- functions ==========================================================
compare: (SUP GF,SUP GF) -> Boolean
-- compares two polynomials
convertWRTsameDefPol12: F1 -> F2
convertWRTsameDefPol21: F2 -> F1
-- homomorphism if the last extension of F1 and F2 was build up
-- using the same defining polynomials
convertWRTdifferentDefPol12: F1 -> F2
convertWRTdifferentDefPol21: F2 -> F1
-- homomorphism if the last extension of F1 and F2 was build up
-- with different defining polynomials
initialize: () -> Void
-- computes the conversion matrices
compare(g:(SUP GF),f:(SUP GF)) ==
degree(f)$(SUP GF) >$NNI degree(g)$(SUP GF) => true
degree(f)$(SUP GF) <$NNI degree(g)$(SUP GF) => false
equal:Integer:=0
for i in degree(f)$(SUP GF)..0 by -1 while equal=0 repeat
not zero?(coefficient(f,i)$(SUP GF))$GF and _
zero?(coefficient(g,i)$(SUP GF))$GF => equal:=1
not zero?(coefficient(g,i)$(SUP GF))$GF and _
zero?(coefficient(f,i)$(SUP GF))$GF => equal:=(-1)
(f1:=lookup(coefficient(f,i)$(SUP GF))$GF) >$PositiveInteger _
(g1:=lookup(coefficient(g,i)$(SUP GF))$GF) => equal:=1
f1 <$PositiveInteger g1 => equal:=(-1)
equal=1 => true
false
initialize() ==
-- 1) in the case of equal def. polynomials initialize is called only
-- if one of the rep. types is "normal" and the other one is "polynomial"
-- we have to compute the basis change matrix 'mat', which i-th
-- column are the coordinates of a**(q**i), the i-th component of
-- the normal basis ('a' the root of the def. polynomial and q the
-- size of the groundfield)
defPol1 =$(SUP GF) defPol2 =>
-- new code using reducedQPowers
mat:=zero(degree1,degree1)$M
arr:=reducedQPowers(defPol1)$FFPOLY(GF)
for i in 1..degree1 repeat
setColumn!(mat,i,vectorise(arr.(i-1),degree1)$SUP(GF))$M
-- old code
-- here one of the representation types must be "normal"
--a:=basis()$FFP(GF,defPol1).2 -- the root of the def. polynomial
--setColumn!(mat,1,coordinates(a)$FFP(GF,defPol1))$M
--for i in 2..degree1 repeat
-- a:= a **$FFP(GF,defPol1) size()$GF
-- setColumn!(mat,i,coordinates(a)$FFP(GF,defPol1))$M
--for the direction "normal" -> "polynomial" we have to multiply the
-- coordinate vector of an element of the normal basis field with
-- the matrix 'mat'. In this case 'mat' is the correct conversion
-- matrix for the conversion of F1 to F2, its inverse the correct
-- inversion matrix for the conversion of F2 to F1
repType1 = "normal" => -- repType2 = "polynomial"
conMat1to2:=copy(mat)
conMat2to1:=copy(inverse(mat)$M :: M)
--we finish the function for one case, hence reset initialization flag
init? := false
-- print("'normal' <=> 'polynomial' matrices initialized"::OUT)
-- in the other case we have to change the matrices
-- repType2 = "normal" and repType1 = "polynomial"
conMat2to1:=copy(mat)
conMat1to2:=copy(inverse(mat)$M :: M)
-- print("'normal' <=> 'polynomial' matrices initialized"::OUT)
--we finish the function for one case, hence reset initialization flag
init? := false
-- 2) in the case of different def. polynomials we have to order the
-- fields to get the same isomorphism, if the package is called with
-- the fields F1 and F2 swapped.
dPbig:= defPol2
rTbig:= repType2
dPsmall:= defPol1
rTsmall:= repType1
degbig:=degree2
degsmall:=degree1
if compare(defPol2,defPol1) then
degsmall:=degree2
degbig:=degree1
dPbig:= defPol1
rTbig:= repType1
dPsmall:= defPol2
rTsmall:= repType2
-- 3) in every case we need a conversion between the polynomial
-- represented fields. Therefore we compute 'root' as a root of the
-- 'smaller' def. polynomial in the 'bigger' field.
-- We compute the matrix 'matsb', which i-th column are the coordinates
-- of the (i-1)-th power of root, i=1..degsmall. Multiplying a
-- coordinate vector of an element of the 'smaller' field by this
-- matrix, we got the coordinates of the corresponding element in the
-- 'bigger' field.
-- compute the root of dPsmall in the 'big' field
root:=rootOfIrreduciblePoly(dPsmall)$FFPOL2(FFP(GF,dPbig),GF)
-- set up matrix for polynomial conversion
matsb:=zero(degbig,degsmall)$M
qsetelt!(matsb,1,1,1$GF)$M
a:=root
for i in 2..degsmall repeat
setColumn!(matsb,i,coordinates(a)$FFP(GF,dPbig))$M
a := a *$FFP(GF,dPbig) root
-- the conversion from 'big' to 'small': we can't invert matsb
-- directly, because it has degbig rows and degsmall columns and
-- may be no square matrix. Therfore we construct a square matrix
-- mat from degsmall linear independent rows of matsb and invert it.
-- Now we get the conversion matrix 'matbs' for the conversion from
-- 'big' to 'small' by putting the columns of mat at the indices
-- of the linear independent rows of matsb to columns of matbs.
ra:I:=1 -- the rank
mat:M:=transpose(row(matsb,1))$M -- has already rank 1
rowind:I:=2
iVec:Vector I:=new(degsmall,1$I)$(Vector I)
while ra < degsmall repeat
if rank(vertConcat(mat,transpose(row(matsb,rowind))$M)$M)$M > ra then
mat:=vertConcat(mat,transpose(row(matsb,rowind))$M)$M
ra:=ra+1
iVec.ra := rowind
rowind:=rowind + 1
mat:=inverse(mat)$M :: M
matbs:=zero(degsmall,degbig)$M
for i in 1..degsmall repeat
setColumn!(matbs,iVec.i,column(mat,i)$M)$M
-- print(matsb::OUT)
-- print(matbs::OUT)
-- 4) if the 'bigger' field is "normal" we have to compose the
-- polynomial conversion with a conversion from polynomial to normal
-- between the FFP(GF,dPbig) and FFNBP(GF,dPbig) the 'bigger'
-- field. Therefore we compute a conversion matrix 'mat' as in 1)
-- Multiplying with the inverse of 'mat' yields the desired
-- conversion from polynomial to normal. Multiplying this matrix by
-- the above computed 'matsb' we got the matrix for converting form
-- 'small polynomial' to 'big normal'.
-- set up matrix 'mat' for polynomial to normal
if rTbig = "normal" then
arr:=reducedQPowers(dPbig)$FFPOLY(GF)
mat:=zero(degbig,degbig)$M
for i in 1..degbig repeat
setColumn!(mat,i,vectorise(arr.(i-1),degbig)$SUP(GF))$M
-- old code
--a:=basis()$FFP(GF,dPbig).2 -- the root of the def.Polynomial
--setColumn!(mat,1,coordinates(a)$FFP(GF,dPbig))$M
--for i in 2..degbig repeat
-- a:= a **$FFP(GF,dPbig) size()$GF
-- setColumn!(mat,i,coordinates(a)$FFP(GF,dPbig))$M
-- print(inverse(mat)$M::OUT)
matsb:= (inverse(mat)$M :: M) * matsb
-- print("inv *.."::OUT)
matbs:=matbs * mat
-- 5) if the 'smaller' field is "normal" we have first to convert
-- from 'small normal' to 'small polynomial', that is from
-- FFNBP(GF,dPsmall) to FFP(GF,dPsmall). Therefore we compute a
-- conversion matrix 'mat' as in 1). Multiplying with 'mat'
-- yields the desired conversion from normal to polynomial.
-- Multiplying the above computed 'matsb' with 'mat' we got the
-- matrix for converting form 'small normal' to 'big normal'.
-- set up matrix 'mat' for normal to polynomial
if rTsmall = "normal" then
arr:=reducedQPowers(dPsmall)$FFPOLY(GF)
mat:=zero(degsmall,degsmall)$M
for i in 1..degsmall repeat
setColumn!(mat,i,vectorise(arr.(i-1),degsmall)$SUP(GF))$M
-- old code
--b:FFP(GF,dPsmall):=basis()$FFP(GF,dPsmall).2
--setColumn!(mat,1,coordinates(b)$FFP(GF,dPsmall))$M
--for i in 2..degsmall repeat
-- b:= b **$FFP(GF,dPsmall) size()$GF
-- setColumn!(mat,i,coordinates(b)$FFP(GF,dPsmall))$M
-- print(mat::OUT)
matsb:= matsb * mat
matbs:= (inverse(mat) :: M) * matbs
-- now 'matsb' is the corret conversion matrix for 'small' to 'big'
-- and 'matbs' the corret one for 'big' to 'small'.
-- depending on the above ordering the conversion matrices are
-- initialized
dPbig =$(SUP GF) defPol2 =>
conMat1to2 :=matsb
conMat2to1 :=matbs
-- print(conMat1to2::OUT)
-- print(conMat2to1::OUT)
-- print("conversion matrices initialized"::OUT)
--we finish the function for one case, hence reset initialization flag
init? := false
conMat1to2 :=matbs
conMat2to1 :=matsb
-- print(conMat1to2::OUT)
-- print(conMat2to1::OUT)
-- print("conversion matrices initialized"::OUT)
--we finish the function for one case, hence reset initialization flag
init? := false
coerce(x:F1) ==
inGroundField?(x)$F1 => retract(x)$F1 :: F2
-- if x is already in GF then we can use a simple coercion
defPol1 =$(SUP GF) defPol2 => convertWRTsameDefPol12(x)
convertWRTdifferentDefPol12(x)
convertWRTsameDefPol12(x:F1) ==
repType1 = repType2 => x pretend F2
-- same groundfields, same defining polynomials, same
-- representation types --> F1 = F2, x is already in F2
repType1 = "cyclic" =>
x = 0$F1 => 0$F2
-- the SI corresponding to the cyclic representation is the exponent of
-- the primitiveElement, therefore we exponentiate the primitiveElement
-- of F2 by it.
primitiveElement()$F2 **$F2 (x pretend SI)
repType2 = "cyclic" =>
x = 0$F1 => 0$F2
-- to get the exponent, we have to take the discrete logarithm of the
-- element in the given field.
(discreteLog(x)$F1 pretend SI) pretend F2
-- here one of the representation types is "normal"
if init? then initialize()
-- here a conversion matrix is necessary, (see initialize())
represents(conMat1to2 *$(Matrix GF) coordinates(x)$F1)$F2
convertWRTdifferentDefPol12(x:F1) ==
if init? then initialize()
-- if we want to convert into a 'smaller' field, we have to test,
-- whether the element is in the subfield of the 'bigger' field, which
-- corresponds to the 'smaller' field
if degree1 > degree2 then
if positiveRemainder(degree2,degree(x)$F1)~= 0 then
error "coerce: element doesn't belong to smaller field"
represents(conMat1to2 *$(Matrix GF) coordinates(x)$F1)$F2
-- the three functions below equal the three functions above up to
-- '1' exchanged by '2' in all domain and variable names
coerce(x:F2) ==
inGroundField?(x)$F2 => retract(x)$F2 :: F1
-- if x is already in GF then we can use a simple coercion
defPol1 =$(SUP GF) defPol2 => convertWRTsameDefPol21(x)
convertWRTdifferentDefPol21(x)
convertWRTsameDefPol21(x:F2) ==
repType1 = repType2 => x pretend F1
-- same groundfields, same defining polynomials,
-- same representation types --> F1 = F2, that is:
-- x is already in F1
repType2 = "cyclic" =>
x = 0$F2 => 0$F1
primitiveElement()$F1 **$F1 (x pretend SI)
repType1 = "cyclic" =>
x = 0$F2 => 0$F1
(discreteLog(x)$F2 pretend SI) pretend F1
-- here one of the representation types is "normal"
if init? then initialize()
represents(conMat2to1 *$(Matrix GF) coordinates(x)$F2)$F1
convertWRTdifferentDefPol21(x:F2) ==
if init? then initialize()
if degree2 > degree1 then
if positiveRemainder(degree1,degree(x)$F2)~= 0 then
error "coerce: element doesn't belong to smaller field"
represents(conMat2to1 *$(Matrix GF) coordinates(x)$F2)$F1
@
\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>>
<<package FFHOM FiniteFieldHomomorphisms>>
@
\eject
\begin{thebibliography}{99}
\bibitem{1} nothing
\end{thebibliography}
\end{document}
|