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\documentclass{article}
\usepackage{open-axiom}
\begin{document}
\title{\$SPAD/src/algebra galfact.spad}
\author{Frederic Lehobey}
\maketitle
\begin{abstract}
\end{abstract}
\eject
\tableofcontents
\eject
\section{package GALFACT GaloisGroupFactorizer}
<<package GALFACT GaloisGroupFactorizer>>=
)abbrev package GALFACT GaloisGroupFactorizer
++ Author: Frederic Lehobey
++ Date Created: 28 June 1994
++ Date Last Updated: 11 July 1997
++ Basic Operations: factor
++ Related Domains:
++ Also See:
++ AMS Classifications:
++ Keywords: factorization
++ Examples:
++ References:
++ [1] Bernard Beauzamy, Vilmar Trevisan and Paul S. Wang, Polynomial
++ Factorization: Sharp Bounds, Efficient Algorithms,
++ J. Symbolic Computation (1993) 15, 393-413
++ [2] John Brillhart, Note on Irreducibility Testing,
++ Mathematics of Computation, vol. 35, num. 35, Oct. 1980, 1379-1381
++ [3] David R. Musser, On the Efficiency of a Polynomial Irreducibility Test,
++ Journal of the ACM, Vol. 25, No. 2, April 1978, pp. 271-282
++ Description: \spadtype{GaloisGroupFactorizer} provides functions
++ to factor resolvents.
-- improvements to do :
-- + reformulate the lifting problem in completeFactor -- See [1] (hard)
-- + implement algorithm RC -- See [1] (easy)
-- + use Dedekind's criterion to prove sometimes irreducibility (easy)
-- or even to improve early detection of true factors (hard)
-- + replace Sets by Bits
GaloisGroupFactorizer(UP): Exports == Implementation where
Z ==> Integer
UP: UnivariatePolynomialCategory Z
N ==> NonNegativeInteger
P ==> PositiveInteger
CYC ==> CyclotomicPolynomialPackage()
SUPZ ==> SparseUnivariatePolynomial Z
ParFact ==> Record(irr: UP, pow: Z)
FinalFact ==> Record(contp: Z, factors: List ParFact)
DDRecord ==> Record(factor: UP, degree: Z) -- a Distinct-Degree factor
DDList ==> List DDRecord
MFact ==> Record(prime: Z,factors: List UP) -- Modular Factors
LR ==> Record(left: UP, right: UP) -- Functional decomposition
Exports ==> with
makeFR: FinalFact -> Factored UP
++ makeFR(flist) turns the final factorization of henselFact into a
++ \spadtype{Factored} object.
degreePartition: DDList -> Multiset N
++ degreePartition(ddfactorization) returns the degree partition of
++ the polynomial f modulo p where ddfactorization is the distinct
++ degree factorization of f computed by
++ \spadfunFrom{ddFact}{ModularDistinctDegreeFactorizer}
++ for some prime p.
musserTrials: () -> P
++ musserTrials() returns the number of primes that are tried in
++ \spadfun{modularFactor}.
musserTrials: P -> P
++ musserTrials(n) sets to n the number of primes to be tried in
++ \spadfun{modularFactor} and returns the previous value.
stopMusserTrials: () -> P
++ stopMusserTrials() returns the bound on the number of factors for
++ which \spadfun{modularFactor} stops to look for an other prime. You
++ will have to remember that the step of recombining the extraneous
++ factors may take up to \spad{2**stopMusserTrials()} trials.
stopMusserTrials: P -> P
++ stopMusserTrials(n) sets to n the bound on the number of factors for
++ which \spadfun{modularFactor} stops to look for an other prime. You
++ will have to remember that the step of recombining the extraneous
++ factors may take up to \spad{2**n} trials. Returns the previous
++ value.
numberOfFactors: DDList -> N
++ numberOfFactors(ddfactorization) returns the number of factors of
++ the polynomial f modulo p where ddfactorization is the distinct
++ degree factorization of f computed by
++ \spadfunFrom{ddFact}{ModularDistinctDegreeFactorizer}
++ for some prime p.
modularFactor: UP -> MFact
++ modularFactor(f) chooses a "good" prime and returns the factorization
++ of f modulo this prime in a form that may be used by
++ \spadfunFrom{completeHensel}{GeneralHenselPackage}. If prime is zero
++ it means that f has been proved to be irreducible over the integers
++ or that f is a unit (i.e. 1 or -1).
++ f shall be primitive (i.e. content(p)=1) and square free (i.e.
++ without repeated factors).
useSingleFactorBound?: () -> Boolean
++ useSingleFactorBound?() returns \spad{true} if algorithm with single
++ factor bound is used for factorization, \spad{false} for algorithm
++ with overall bound.
useSingleFactorBound: Boolean -> Boolean
++ useSingleFactorBound(b) chooses the algorithm to be used by the
++ factorizers: \spad{true} for algorithm with single
++ factor bound, \spad{false} for algorithm with overall bound.
++ Returns the previous value.
useEisensteinCriterion?: () -> Boolean
++ useEisensteinCriterion?() returns \spad{true} if factorizers
++ check Eisenstein's criterion before factoring.
useEisensteinCriterion: Boolean -> Boolean
++ useEisensteinCriterion(b) chooses whether factorizers check
++ Eisenstein's criterion before factoring: \spad{true} for
++ using it, \spad{false} else. Returns the previous value.
eisensteinIrreducible?: UP -> Boolean
++ eisensteinIrreducible?(p) returns \spad{true} if p can be
++ shown to be irreducible by Eisenstein's criterion,
++ \spad{false} is inconclusive.
tryFunctionalDecomposition?: () -> Boolean
++ tryFunctionalDecomposition?() returns \spad{true} if
++ factorizers try functional decomposition of polynomials before
++ factoring them.
tryFunctionalDecomposition: Boolean -> Boolean
++ tryFunctionalDecomposition(b) chooses whether factorizers have
++ to look for functional decomposition of polynomials
++ (\spad{true}) or not (\spad{false}). Returns the previous value.
factor: UP -> Factored UP
++ factor(p) returns the factorization of p over the integers.
factor: (UP,N) -> Factored UP
++ factor(p,r) factorizes the polynomial p using the single factor bound
++ algorithm and knowing that p has at least r factors.
factor: (UP,List N) -> Factored UP
++ factor(p,listOfDegrees) factorizes the polynomial p using the single
++ factor bound algorithm and knowing that p has for possible
++ splitting of its degree listOfDegrees.
factor: (UP,List N,N) -> Factored UP
++ factor(p,listOfDegrees,r) factorizes the polynomial p using the single
++ factor bound algorithm, knowing that p has for possible
++ splitting of its degree listOfDegrees and that p has at least r
++ factors.
factor: (UP,N,N) -> Factored UP
++ factor(p,d,r) factorizes the polynomial p using the single
++ factor bound algorithm, knowing that d divides the degree of all
++ factors of p and that p has at least r factors.
factorSquareFree: UP -> Factored UP
++ factorSquareFree(p) returns the factorization of p which is supposed
++ not having any repeated factor (this is not checked).
factorSquareFree: (UP,N) -> Factored UP
++ factorSquareFree(p,r) factorizes the polynomial p using the single
++ factor bound algorithm and knowing that p has at least r factors.
++ f is supposed not having any repeated factor (this is not checked).
factorSquareFree: (UP,List N) -> Factored UP
++ factorSquareFree(p,listOfDegrees) factorizes the polynomial p using
++ the single factor bound algorithm and knowing that p has for possible
++ splitting of its degree listOfDegrees.
++ f is supposed not having any repeated factor (this is not checked).
factorSquareFree: (UP,List N,N) -> Factored UP
++ factorSquareFree(p,listOfDegrees,r) factorizes the polynomial p using
++ the single factor bound algorithm, knowing that p has for possible
++ splitting of its degree listOfDegrees and that p has at least r
++ factors.
++ f is supposed not having any repeated factor (this is not checked).
factorSquareFree: (UP,N,N) -> Factored UP
++ factorSquareFree(p,d,r) factorizes the polynomial p using the single
++ factor bound algorithm, knowing that d divides the degree of all
++ factors of p and that p has at least r factors.
++ f is supposed not having any repeated factor (this is not checked).
factorOfDegree: (P,UP) -> Union(UP,"failed")
++ factorOfDegree(d,p) returns a factor of p of degree d.
factorOfDegree: (P,UP,N) -> Union(UP,"failed")
++ factorOfDegree(d,p,r) returns a factor of p of degree
++ d knowing that p has at least r factors.
factorOfDegree: (P,UP,List N) -> Union(UP,"failed")
++ factorOfDegree(d,p,listOfDegrees) returns a factor
++ of p of degree d knowing that p has for possible splitting of its
++ degree listOfDegrees.
factorOfDegree: (P,UP,List N,N) -> Union(UP,"failed")
++ factorOfDegree(d,p,listOfDegrees,r) returns a factor
++ of p of degree d knowing that p has for possible splitting of its
++ degree listOfDegrees, and that p has at least r factors.
factorOfDegree: (P,UP,List N,N,Boolean) -> Union(UP,"failed")
++ factorOfDegree(d,p,listOfDegrees,r,sqf) returns a
++ factor of p of degree d knowing that p has for possible splitting of
++ its degree listOfDegrees, and that p has at least r factors.
++ If \spad{sqf=true} the polynomial is assumed to be square free (i.e.
++ without repeated factors).
henselFact: (UP,Boolean) -> FinalFact
++ henselFact(p,sqf) returns the factorization of p, the result
++ is a Record such that \spad{contp=}content p,
++ \spad{factors=}List of irreducible factors of p with exponent.
++ If \spad{sqf=true} the polynomial is assumed to be square free (i.e.
++ without repeated factors).
btwFact: (UP,Boolean,Set N,N) -> FinalFact
++ btwFact(p,sqf,pd,r) returns the factorization of p, the result
++ is a Record such that \spad{contp=}content p,
++ \spad{factors=}List of irreducible factors of p with exponent.
++ If \spad{sqf=true} the polynomial is assumed to be square free (i.e.
++ without repeated factors).
++ pd is the \spadtype{Set} of possible degrees. r is a lower bound for
++ the number of factors of p. Please do not use this function in your
++ code because its design may change.
Implementation ==> add
fUnion ==> Union("nil", "sqfr", "irred", "prime")
FFE ==> Record(flg:fUnion, fctr:UP, xpnt:Z) -- Flag-Factor-Exponent
DDFact ==> Record(prime:Z, ddfactors:DDList) -- Distinct Degree Factors
HLR ==> Record(plist:List UP, modulo:Z) -- HenselLift Record
mussertrials: P := 5
stopmussertrials: P := 8
usesinglefactorbound: Boolean := true
tryfunctionaldecomposition: Boolean := true
useeisensteincriterion: Boolean := true
useEisensteinCriterion?():Boolean == useeisensteincriterion
useEisensteinCriterion(b:Boolean):Boolean ==
(useeisensteincriterion,b) := (b,useeisensteincriterion)
b
tryFunctionalDecomposition?():Boolean == tryfunctionaldecomposition
tryFunctionalDecomposition(b:Boolean):Boolean ==
(tryfunctionaldecomposition,b) := (b,tryfunctionaldecomposition)
b
useSingleFactorBound?():Boolean == usesinglefactorbound
useSingleFactorBound(b:Boolean):Boolean ==
(usesinglefactorbound,b) := (b,usesinglefactorbound)
b
stopMusserTrials():P == stopmussertrials
stopMusserTrials(n:P):P ==
(stopmussertrials,n) := (n,stopmussertrials)
n
musserTrials():P == mussertrials
musserTrials(n:P):P ==
(mussertrials,n) := (n,mussertrials)
n
import GaloisGroupFactorizationUtilities(Z,UP,Float)
import GaloisGroupPolynomialUtilities(Z,UP)
import IntegerPrimesPackage(Z)
import IntegerFactorizationPackage(Z)
import ModularDistinctDegreeFactorizer(UP)
eisensteinIrreducible?(f:UP):Boolean ==
rf := reductum f
c: Z := content rf
zero? c => false
unit? c => false
lc := leadingCoefficient f
tc := lc
while not zero? rf repeat
tc := leadingCoefficient rf
rf := reductum rf
for p in factors(factor c)$Factored(Z) repeat
if (one? p.exponent) and (not zero? (lc rem p.factor)) and
(not zero? (tc rem ((p.factor)**2))) then return true
false
numberOfFactors(ddlist:DDList):N ==
n: N := 0
d: Z := 0
for dd in ddlist repeat
n := n +
zero? (d := degree(dd.factor)::Z) => 1
(d quo dd.degree)::N
n
-- local function, returns the a Set of shifted elements
shiftSet(s:Set N,shift:N):Set N == set [ e+shift for e in members s ]
-- local function, returns the "reductum" of an Integer (as chain of bits)
reductum(n:Z):Z == n-shift(1,length(n)-1)
-- local function, returns an integer with level lowest bits set to 1
seed(level:Z):Z == shift(1,level)-1
-- local function, returns the next number (as a chain of bit) for
-- factor reconciliation of a given level (which is the number of
-- extraneaous factors involved) or "End of level" if not any
nextRecNum(levels:N,level:Z,n:Z):Union("End of level",Z) ==
if (l := length n)<levels then return(n+shift(1,l-1))
(n=shift(seed(level),levels-level)) => "End of level"
b: Z := 1
lr : Z
while ((l-b) = (lr := length(n := reductum n)))@Boolean repeat b := b+1
reductum(n)+shift(seed(b+1),lr)
-- local function, return the set of N, 0..n
fullSet(n:N):Set N == set [ i for i in 0..n ]
modularFactor(p:UP):MFact ==
not one? abs(content(p)) =>
error "modularFactor: the polynomial is not primitive."
zero? (n := degree p) => [0,[p]]
-- declarations --
cprime: Z := 2
trials: List DDFact := empty()
d: Set N := fullSet(n)
dirred: Set N := set [0,n]
s: Set N := empty()
ddlist: DDList := empty()
degfact: N := 0
nf: N := stopmussertrials+1
-- Musser, see [3] --
diffp := differentiate p
for i: Z in 1..mussertrials | nf>stopmussertrials repeat
-- test 1: cprime divides leading coefficient
-- test 2: "bad" primes: (in future: use Dedekind's Criterion)
while (zero? ((leadingCoefficient p) rem cprime)) or
(not zero? degree gcd(p,diffp,cprime)) repeat
cprime := nextPrime(cprime)
ddlist := ddFact(p,cprime)
-- degree compatibility: See [3] --
s := set [0]
for f in ddlist repeat
degfact := f.degree::N
if not zero? degfact then
for j in 1..(degree(f.factor) quo degfact) repeat
s := union(s, shiftSet(s,degfact))
trials := cons([cprime,ddlist]$DDFact,trials)
d := intersect(d, s)
d = dirred => return [0,[p]] -- p is irreducible
cprime := nextPrime(cprime)
nf := numberOfFactors ddlist
-- choose the one with the smallest number of factors
choice := first trials
nfc := numberOfFactors(choice.ddfactors)
for t in rest trials repeat
nf := numberOfFactors(t.ddfactors)
if nf<nfc or ((nf=nfc) and (t.prime>choice.prime)) then
nfc := nf
choice := t
cprime := choice.prime
-- HenselLift$GHENSEL expects the degree 0 factor first
[cprime,separateFactors(choice.ddfactors,cprime)]
degreePartition(ddlist:DDList):Multiset N ==
dp: Multiset N := empty()
d: N := 0
dd: N := 0
for f in ddlist repeat
zero? (d := degree(f.factor)) => dp := insert!(0,dp)
dd := f.degree::N
dp := insert!(dd,dp,d quo dd)
dp
import GeneralHenselPackage(Z,UP)
import UnivariatePolynomialDecompositionPackage(Z,UP)
import BrillhartTests(UP) -- See [2]
-- local function, finds the factors of f primitive, square-free, with
-- positive leading coefficient and non zero trailing coefficient,
-- using the overall bound technique. If pdecomp is true then look
-- for a functional decomposition of f.
henselfact(f:UP,pdecomp:Boolean):List UP ==
if brillhartIrreducible? f or
(useeisensteincriterion => eisensteinIrreducible? f ; false)
then return [f]
cf: Union(LR,"failed")
if pdecomp and tryfunctionaldecomposition then
cf := monicDecomposeIfCan f
else
cf := "failed"
cf case "failed" =>
m := modularFactor f
zero? (cprime := m.prime) => m.factors
b: P := (2*leadingCoefficient(f)*beauzamyBound(f)) :: P
completeHensel(f,m.factors,cprime,b)
lrf := cf::LR
"append"/[ henselfact(g(lrf.right),false) for g in
henselfact(lrf.left,true) ]
-- local function, returns the complete factorization of its arguments,
-- using the single-factor bound technique
completeFactor(f:UP,lf:List UP,cprime:Z,pk:P,r:N,d:Set N):List UP ==
lc := leadingCoefficient f
f0 := coefficient(f,0)
ltrue: List UP := empty()
found? := true
degf: N := 0
degg: N := 0
g0: Z := 0
g: UP := 0
rg: N := 0
nb: Z := 0
lg: List UP := empty()
b: P := 1
dg: Set N := empty()
llg: HLR := [empty(),0]
levels: N := #lf
level: Z := 1
ic: Union(Z,"End of level") := 0
i: Z := 0
while level<levels repeat
-- try all possible factors with degree in d
ic := seed(level)
while ((not found?) and (ic case Z)) repeat
i := ic::Z
degg := 0
g0 := 1 -- LC algorithm
for j in 1..levels repeat
if bit?(i,j-1) then
degg := degg+degree lf.j
g0 := g0*coefficient(lf.j,0) -- LC algorithm
g0 := symmetricRemainder(lc*g0,pk) -- LC algorithm
if member?(degg,d) and (((lc*f0) exquo g0) case Z) then
-- LC algorithm
g := lc::UP -- build the possible factor -- LC algorithm
for j in 1..levels repeat if bit?(i,j-1) then g := g*lf.j
g := primitivePart reduction(g,pk)
f1 := f exquo g
if f1 case UP then -- g is a true factor
found? := true
-- remove the factors of g from lf
nb := 1
for j in 1..levels repeat
if bit?(i,j-1) then
swap!(lf,j,nb)
nb := nb+1
lg := lf
lf := rest(lf,level::N)
setrest!(rest(lg,(level-1)::N),empty()$List(UP))
f := f1::UP
lc := leadingCoefficient f
f0 := coefficient(f,0)
-- is g irreducible?
dg := select(#1<=degg,d)
if not(dg=set [0,degg]) then -- implies degg >= 2
rg := max(2,r+level-levels)::N
b := (2*leadingCoefficient(g)*singleFactorBound(g,rg)) :: P
if b>pk and (not brillhartIrreducible?(g)) and
(useeisensteincriterion => not eisensteinIrreducible?(g) ;
true)
then
-- g may be reducible
llg := HenselLift(g,lg,cprime,b)
gpk: P := (llg.modulo)::P
-- In case exact factorisation has been reached by
-- HenselLift before coefficient bound.
if gpk<b then
lg := llg.plist
else
lg := completeFactor(g,llg.plist,cprime,gpk,rg,dg)
else lg := [ g ] -- g irreducible
else lg := [ g ] -- g irreducible
ltrue := append(ltrue,lg)
r := max(2,(r-#lg))::N
degf := degree f
d := select(#1<=degf,d)
if degf<=1 then -- lf exhausted
if one? degf then
ltrue := cons(f,ltrue)
return ltrue -- 1st exit, all factors found
else -- can we go on with the same pk?
b := (2*lc*singleFactorBound(f,r)) :: P
if b>pk then -- unlucky: no we can't
llg := HenselLift(f,lf,cprime,b) -- I should reformulate
-- the lifting probleme, but hadn't time for that.
-- In any case, such case should be quite exceptional.
lf := llg.plist
pk := (llg.modulo)::P
-- In case exact factorisation has been reached by
-- HenselLift before coefficient bound.
if pk<b then return append(lf,ltrue) -- 2nd exit
level := 1
ic := nextRecNum(levels,level,i)
if found? then
levels := #lf
found? := false
if not (ic case Z) then level := level+1
cons(f,ltrue) -- 3rd exit, the last factor was irreducible but not "true"
-- local function, returns the set of elements "divided" by an integer
divideSet(s:Set N, n:N):Set N ==
l: List N := [ 0 ]
for e in members s repeat
if (ee := (e exquo n)$N) case N then l := cons(ee::N,l)
set(l)
-- Beauzamy-Trevisan-Wang FACTOR, see [1] with some refinements
-- and some differences. f is assumed to be primitive, square-free
-- and with positive leading coefficient. If pdecomp is true then
-- look for a functional decomposition of f.
btwFactor(f:UP,d:Set N,r:N,pdecomp:Boolean):List UP ==
df := degree f
not (max(d) = df) => error "btwFact: Bad arguments"
reverse?: Boolean := false
negativelc?: Boolean := false
(d = set [0,df]) => [ f ]
if abs(coefficient(f,0))<abs(leadingCoefficient(f)) then
f := reverse f
reverse? := true
brillhartIrreducible? f or
(useeisensteincriterion => eisensteinIrreducible?(f) ; false) =>
if reverse? then [ reverse f ] else [ f ]
if negative? leadingCoefficient(f) then
f := -f
negativelc? := true
cf: Union(LR,"failed")
if pdecomp and tryfunctionaldecomposition then
cf := monicDecomposeIfCan f
else
cf := "failed"
if cf case "failed" then
m := modularFactor f
zero? (cprime := m.prime) =>
if reverse? then
if negativelc? then return [ -reverse f ]
else return [ reverse f ]
else if negativelc? then return [ -f ]
else return [ f ]
if noLinearFactor? f then d := remove(1,d)
lc := leadingCoefficient f
f0 := coefficient(f,0)
b: P := (2*lc*singleFactorBound(f,r)) :: P -- LC algorithm
lm := HenselLift(f,m.factors,cprime,b)
lf := lm.plist
pk: P := (lm.modulo)::P
if ground? first lf then lf := rest lf
-- in case exact factorisation has been reached by HenselLift
-- before coefficient bound
if not pk < b then lf := completeFactor(f,lf,cprime,pk,r,d)
else
lrf := cf::LR
dh := degree lrf.right
lg := btwFactor(lrf.left,divideSet(d,dh),2,true)
lf: List UP := empty()
for i in 1..#lg repeat
g := lg.i
dgh := (degree g)*dh
df := subtractIfCan(df,dgh)::N
lfg := btwFactor(g(lrf.right),
select(#1<=dgh,d),max(2,r-df)::N,false)
lf := append(lf,lfg)
r := max(2,r-#lfg)::N
if reverse? then lf := [ reverse(fact) for fact in lf ]
for i in 1..#lf repeat
if negative? leadingCoefficient(lf.i) then lf.i := -lf.i
-- because we assume f with positive leading coefficient
lf
makeFR(flist:FinalFact):Factored UP ==
ctp := factor flist.contp
fflist: List FFE := empty()
for ff in flist.factors repeat
fflist := cons(["prime", ff.irr, ff.pow]$FFE, fflist)
for fc in factorList ctp repeat
fflist := cons([fc.flg, fc.fctr::UP, fc.xpnt]$FFE, fflist)
makeFR(unit(ctp)::UP, fflist)
import IntegerRoots(Z)
-- local function, factorizes a quadratic polynomial
quadratic(p:UP):List UP ==
a := leadingCoefficient p
b := coefficient(p,1)
d := b**2-4*a*coefficient(p,0)
r := perfectSqrt(d)
r case "failed" => [p]
b := b+(r::Z)
a := 2*a
d := gcd(a,b)
if not one? d then
a := a quo d
b := b quo d
f: UP := monomial(a,1)+monomial(b,0)
cons(f,[(p exquo f)::UP])
isPowerOf2(n:Z): Boolean ==
n = 1 => true
qr: Record(quotient: Z, remainder: Z) := divide(n,2)
qr.remainder = 1 => false
isPowerOf2 qr.quotient
subMinusX(supPol: SUPZ): UP ==
minusX: SUPZ := monomial(-1,1)$SUPZ
unmakeSUP(elt(supPol,minusX)$SUPZ)
henselFact(f:UP, sqf:Boolean):FinalFact ==
factorlist: List(ParFact) := empty()
-- make m primitive
c: Z := content f
f := (f exquo c)::UP
-- make the leading coefficient positive
if negative? leadingCoefficient f then
c := -c
f := -f
-- is x**d factor of f
if positive?(d := minimumDegree f) then
f := monicDivide(f,monomial(1,d)).quotient
factorlist := [[monomial(1,1),d]$ParFact]
d := degree f
-- is f constant?
zero? d => [c,factorlist]$FinalFact
-- is f linear?
one? d => [c,cons([f,1]$ParFact,factorlist)]$FinalFact
lcPol: UP := leadingCoefficient(f) :: UP
-- is f cyclotomic (x**n - 1)?
-lcPol = reductum(f) => -- if true, both will = 1
for fac in map(unmakeSUP(#1)$UP,
cyclotomicDecomposition(d)$CYC)$ListFunctions2(SUPZ,UP) repeat
factorlist := cons([fac,1]$ParFact,factorlist)
[c,factorlist]$FinalFact
-- is f odd cyclotomic (x**(2*n+1) + 1)?
odd?(d) and (lcPol = reductum(f)) =>
for sfac in cyclotomicDecomposition(d)$CYC repeat
fac := subMinusX sfac
if negative? leadingCoefficient fac then fac := -fac
factorlist := cons([fac,1]$ParFact,factorlist)
[c,factorlist]$FinalFact
-- is the poly of the form x**n + 1 with n a power of 2?
-- if so, then irreducible
isPowerOf2(d) and (lcPol = reductum(f)) =>
factorlist := cons([f,1]$ParFact,factorlist)
[c,factorlist]$FinalFact
-- other special cases to implement...
-- f is square-free :
sqf => [c, append([[pf,1]$ParFact for pf in henselfact(f,true)],
factorlist)]$FinalFact
-- f is not square-free :
sqfflist := factors squareFree f
for sqfr in sqfflist repeat
mult := sqfr.exponent
sqff := sqfr.factor
d := degree sqff
one? d => factorlist := cons([sqff,mult]$ParFact,factorlist)
d=2 =>
factorlist := append([[pf,mult]$ParFact for pf in quadratic(sqff)],
factorlist)
factorlist := append([[pf,mult]$ParFact for pf in
henselfact(sqff,true)],factorlist)
[c,factorlist]$FinalFact
btwFact(f:UP, sqf:Boolean, fd:Set N, r:N):FinalFact ==
d := degree f
not(max(fd)=d) => error "btwFact: Bad arguments"
factorlist: List(ParFact) := empty()
-- make m primitive
c: Z := content f
f := (f exquo c)::UP
-- make the leading coefficient positive
if negative? leadingCoefficient f then
c := -c
f := -f
-- is x**d factor of f
if positive?(maxd := minimumDegree f) then
f := monicDivide(f,monomial(1,maxd)).quotient
factorlist := [[monomial(1,1),maxd]$ParFact]
r := max(2,r-maxd)::N
d := subtractIfCan(d,maxd)::N
fd := select(#1<=d,fd)
-- is f constant?
zero? d => [c,factorlist]$FinalFact
-- is f linear?
one? d => [c,cons([f,1]$ParFact,factorlist)]$FinalFact
lcPol: UP := leadingCoefficient(f) :: UP
-- is f cyclotomic (x**n - 1)?
-lcPol = reductum(f) => -- if true, both will = 1
for fac in map(unmakeSUP(#1)$UP,
cyclotomicDecomposition(d)$CYC)$ListFunctions2(SUPZ,UP) repeat
factorlist := cons([fac,1]$ParFact,factorlist)
[c,factorlist]$FinalFact
-- is f odd cyclotomic (x**(2*n+1) + 1)?
odd?(d) and (lcPol = reductum(f)) =>
for sfac in cyclotomicDecomposition(d)$CYC repeat
fac := subMinusX sfac
if negative? leadingCoefficient fac then fac := -fac
factorlist := cons([fac,1]$ParFact,factorlist)
[c,factorlist]$FinalFact
-- is the poly of the form x**n + 1 with n a power of 2?
-- if so, then irreducible
isPowerOf2(d) and (lcPol = reductum(f)) =>
factorlist := cons([f,1]$ParFact,factorlist)
[c,factorlist]$FinalFact
-- other special cases to implement...
-- f is square-free :
sqf => [c, append([[pf,1]$ParFact for pf in btwFactor(f,fd,r,true)],
factorlist)]$FinalFact
-- f is not square-free :
sqfflist := factors squareFree(f)
if one?(#(sqfflist)) then -- indeed f was a power of a square-free
r := max(r quo ((first sqfflist).exponent),2)::N
else
r := 2
for sqfr in sqfflist repeat
mult := sqfr.exponent
sqff := sqfr.factor
d := degree sqff
one? d =>
factorlist := cons([sqff,mult]$ParFact,factorlist)
maxd := (max(fd)-mult)::N
fd := select(#1<=maxd,fd)
d=2 =>
factorlist := append([[pf,mult]$ParFact for pf in quadratic(sqff)],
factorlist)
maxd := (max(fd)-2*mult)::N
fd := select(#1<=maxd,fd)
factorlist := append([[pf,mult]$ParFact for pf in
btwFactor(sqff,select(#1<=d,fd),r,true)],factorlist)
maxd := (max(fd)-d*mult)::N
fd := select(#1<=maxd,fd)
[c,factorlist]$FinalFact
factor(f:UP):Factored UP ==
makeFR
usesinglefactorbound => btwFact(f,false,fullSet(degree f),2)
henselFact(f,false)
-- local function, returns true if the sum of the elements of the list
-- is not the degree.
errorsum?(d:N,ld:List N):Boolean == not (d = +/ld)
-- local function, turns list of degrees into a Set
makeSet(ld:List N):Set N ==
s := set [0]
for d in ld repeat s := union(s,shiftSet(s,d))
s
factor(f:UP,ld:List N,r:N):Factored UP ==
errorsum?(degree f,ld) => error "factor: Bad arguments"
makeFR btwFact(f,false,makeSet(ld),r)
factor(f:UP,r:N):Factored UP == makeFR btwFact(f,false,fullSet(degree f),r)
factor(f:UP,ld:List N):Factored UP == factor(f,ld,2)
factor(f:UP,d:N,r:N):Factored UP ==
n := (degree f) exquo d
n case "failed" => error "factor: Bad arguments"
factor(f,new(n::N,d)$List(N),r)
factorSquareFree(f:UP):Factored UP ==
makeFR
usesinglefactorbound => btwFact(f,true,fullSet(degree f),2)
henselFact(f,true)
factorSquareFree(f:UP,ld:List(N),r:N):Factored UP ==
errorsum?(degree f,ld) => error "factorSquareFree: Bad arguments"
makeFR btwFact(f,true,makeSet(ld),r)
factorSquareFree(f:UP,r:N):Factored UP ==
makeFR btwFact(f,true,fullSet(degree f),r)
factorSquareFree(f:UP,ld:List N):Factored UP == factorSquareFree(f,ld,2)
factorSquareFree(f:UP,d:N,r:N):Factored UP ==
n := (degree f) exquo d
n case "failed" => error "factorSquareFree: Bad arguments"
factorSquareFree(f,new(n::N,d)$List(N),r)
factorOfDegree(d:P,p:UP,ld:List N,r:N,sqf:Boolean):Union(UP,"failed") ==
dp := degree p
errorsum?(dp,ld) => error "factorOfDegree: Bad arguments"
(one? (d::N)) and noLinearFactor?(p) => "failed"
lf := btwFact(p,sqf,makeSet(ld),r).factors
for f in lf repeat
degree(f.irr)=d => return f.irr
"failed"
factorOfDegree(d:P,p:UP,ld:List N,r:N):Union(UP,"failed") ==
factorOfDegree(d,p,ld,r,false)
factorOfDegree(d:P,p:UP,r:N):Union(UP,"failed") ==
factorOfDegree(d,p,new(degree p,1)$List(N),r,false)
factorOfDegree(d:P,p:UP,ld:List N):Union(UP,"failed") ==
factorOfDegree(d,p,ld,2,false)
factorOfDegree(d:P,p:UP):Union(UP,"failed") ==
factorOfDegree(d,p,new(degree p,1)$List(N),2,false)
@
\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 GALFACT GaloisGroupFactorizer>>
@
\eject
\begin{thebibliography}{99}
\bibitem{1} nothing
\end{thebibliography}
\end{document}
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