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\documentclass{article}
\usepackage{open-axiom}
\begin{document}
\title{\$SPAD/src/algebra gaussian.spad}
\author{Barry Trager, James Davenport}
\maketitle
\begin{abstract}
\end{abstract}
\eject
\tableofcontents
\eject
\section{category COMPCAT ComplexCategory}
<<category COMPCAT ComplexCategory>>=
)abbrev category COMPCAT ComplexCategory
++ Author:
++ Date Created:
++ Date Last Updated: 18 March 1994
++ Basic Functions:
++ Related Constructors:
++ Also See:
++ AMS Classifications:
++ Keywords: complex, gaussian
++ References:
++ Description:
++ This category represents the extension of a ring by a square
++ root of -1.
ComplexCategory(R:CommutativeRing): Category ==
Join(MonogenicAlgebra(R, SparseUnivariatePolynomial R), FullyRetractableTo R,
DifferentialExtension R, FullyEvalableOver R, FullyPatternMatchable(R),
Patternable(R), FullyLinearlyExplicitRingOver R, CommutativeRing) with
complex ++ indicates that % has sqrt(-1)
imaginary: () -> % ++ imaginary() = sqrt(-1) = %i.
conjugate: % -> % ++ conjugate(x + %i y) returns x - %i y.
complex : (R, R) -> % ++ complex(x,y) constructs x + %i*y.
imag : % -> R ++ imag(x) returns imaginary part of x.
real : % -> R ++ real(x) returns real part of x.
norm : % -> R ++ norm(x) returns x * conjugate(x)
if R has IntegralDomain then
IntegralDomain
exquo : (%,R) -> Union(%,"failed")
++ exquo(x, r) returns the exact quotient of x by r, or
++ "failed" if r does not divide x exactly.
if R has EuclideanDomain then EuclideanDomain
if R has multiplicativeValuation then multiplicativeValuation
if R has additiveValuation then additiveValuation
if R has Field then -- this is a lie; we must know that
Field -- x**2+1 is irreducible in R
if R has ConvertibleTo InputForm then ConvertibleTo InputForm
if R has CharacteristicZero then CharacteristicZero
if R has CharacteristicNonZero then CharacteristicNonZero
if R has RealConstant then
ConvertibleTo Complex DoubleFloat
ConvertibleTo Complex Float
if R has RealNumberSystem then
abs: % -> %
++ abs(x) returns the absolute value of x = sqrt(norm(x)).
if R has TranscendentalFunctionCategory then
TranscendentalFunctionCategory
argument: % -> R ++ argument(x) returns the angle made by (0,1) and (0,x).
if R has RadicalCategory then RadicalCategory
if R has RealNumberSystem then
polarCoordinates: % -> Record(r:R, phi:R)
++ polarCoordinates(x) returns (r, phi) such that x = r * exp(%i * phi).
if R has IntegerNumberSystem then
rational? : % -> Boolean
++ rational?(x) tests if x is a rational number.
rational : % -> Fraction Integer
++ rational(x) returns x as a rational number.
++ Error: if x is not a rational number.
rationalIfCan: % -> Union(Fraction Integer, "failed")
++ rationalIfCan(x) returns x as a rational number, or
++ "failed" if x is not a rational number.
if R has PolynomialFactorizationExplicit and R has EuclideanDomain then
PolynomialFactorizationExplicit
add
import MatrixCategoryFunctions2(%, Vector %, Vector %, Matrix %,
R, Vector R, Vector R, Matrix R)
SUP ==> SparseUnivariatePolynomial
before?(x,y) ==
real x = real y => before?(imag x,imag y)
before?(real x,real y)
characteristicPolynomial x ==
v := monomial(1,1)$SUP(R)
v**2 - trace(x)*v**1 + norm(x)*v**0
if R has PolynomialFactorizationExplicit and R has EuclideanDomain then
SupR ==> SparseUnivariatePolynomial R
Sup ==> SparseUnivariatePolynomial %
import FactoredFunctionUtilities Sup
import UnivariatePolynomialCategoryFunctions2(R,SupR,%,Sup)
import UnivariatePolynomialCategoryFunctions2(%,Sup,R,SupR)
pp,qq:Sup
if R has IntegerNumberSystem then
myNextPrime: (%,NonNegativeInteger) -> %
myNextPrime(x,n ) == -- prime is actually in R, and = 3(mod 4)
xr:=real(x)-4::R
while not prime? xr repeat
xr:=xr-4::R
complex(xr,0)
--!TT:=InnerModularGcd(%,Sup,32719 :: %,myNextPrime)
--!gcdPolynomial(pp,qq) == modularGcd(pp,qq)$TT
solveLinearPolynomialEquation(lp:List Sup,p:Sup) ==
solveLinearPolynomialEquation(lp,p)$ComplexIntegerSolveLinearPolynomialEquation(R,%)
normPolynomial: Sup -> SupR
normPolynomial pp ==
map(retract(#1@%)::R,pp * map(conjugate,pp))
factorPolynomial pp ==
refine(squareFree pp,factorSquareFreePolynomial)
factorSquareFreePolynomial pp ==
pnorm:=normPolynomial pp
k:R:=0
while degree gcd(pnorm,differentiate pnorm)>0 repeat
k:=k+1
pnorm:=normPolynomial
elt(pp,monomial(1,1)-monomial(complex(0,k),0))
fR:=factorSquareFreePolynomial pnorm
numberOfFactors fR = 1 =>
makeFR(1,[["irred",pp,1]])
lF:List Record(flg:Union("nil", "sqfr", "irred", "prime"),
fctr:Sup, xpnt:Integer):=[]
for u in factorList fR repeat
p1:=map((#1@R)::%,u.fctr)
if not zero? k then
p1:=elt(p1,monomial(1,1)+monomial(complex(0,k),0))
p2:=gcd(p1,pp)
lF:=cons(["irred",p2,1],lF)
pp:=(pp exquo p2)::Sup
makeFR(pp,lF)
rank() == 2
discriminant() == -4 :: R
norm x == real(x)**2 + imag(x)**2
trace x == 2 * real x
imaginary() == complex(0, 1)
conjugate x == complex(real x, - imag x)
characteristic == characteristic$R
map(fn, x) == complex(fn real x, fn imag x)
x = y == real(x) = real(y) and imag(x) = imag(y)
x + y == complex(real x + real y, imag x + imag y)
- x == complex(- real x, - imag x)
r:R * x:% == complex(r * real x, r * imag x)
coordinates(x:%) == [real x, imag x]
n:Integer * x:% == complex(n * real x, n * imag x)
differentiate(x:%, d:R -> R) == complex(d real x, d imag x)
definingPolynomial() ==
monomial(1,2)$(SUP R) + monomial(1,0)$(SUP R)
reduce(pol:SUP R) ==
part:= (monicDivide(pol,definingPolynomial())).remainder
complex(coefficient(part,0),coefficient(part,1))
lift(x) == monomial(real x,0)$(SUP R)+monomial(imag x,1)$(SUP R)
minimalPolynomial x ==
zero? imag x =>
monomial(1, 1)$(SUP R) - monomial(real x, 0)$(SUP R)
monomial(1, 2)$(SUP R) - monomial(trace x, 1)$(SUP R)
+ monomial(norm x, 0)$(SUP R)
coordinates(x:%, v:Vector %):Vector(R) ==
ra := real(a := v(minIndex v))
rb := real(b := v(maxIndex v))
(#v ~= 2) or
((d := recip(ra * (ib := imag b) - (ia := imag a) * rb))
case "failed") =>error "coordinates: vector is not a basis"
rx := real x
ix := imag x
[d::R * (rx * ib - ix * rb), d::R * (ra * ix - ia * rx)]
coerce(x:%):OutputForm ==
re := (r := real x)::OutputForm
ie := (i := imag x)::OutputForm
zero? i => re
outi := '%i::OutputForm
ip :=
one? i => outi
one?(-i) => -outi
ie * outi
zero? r => ip
re + ip
retract(x:%):R ==
not zero?(imag x) =>
error "Imaginary part is nonzero. Cannot retract."
real x
retractIfCan(x:%):Union(R, "failed") ==
not zero?(imag x) => "failed"
real x
x:% * y:% ==
complex(real x * real y - imag x * imag y,
imag x * real y + imag y * real x)
reducedSystem(m:Matrix %):Matrix R ==
vertConcat(map(real, m), map(imag, m))
reducedSystem(m:Matrix %, v:Vector %):
Record(mat:Matrix R, vec:Vector R) ==
rh := reducedSystem(v::Matrix %)@Matrix(R)
[reducedSystem(m)@Matrix(R), column(rh, minColIndex rh)]
if R has RealNumberSystem then
abs(x:%):% == (sqrt norm x)::%
if R has RealConstant then
convert(x:%):Complex(DoubleFloat) ==
complex(convert(real x)@DoubleFloat,convert(imag x)@DoubleFloat)
convert(x:%):Complex(Float) ==
complex(convert(real x)@Float, convert(imag x)@Float)
if R has ConvertibleTo InputForm then
convert(x:%):InputForm ==
convert([convert('complex), convert real x,
convert imag x]$List(InputForm))@InputForm
if R has ConvertibleTo Pattern Integer then
convert(x:%):Pattern Integer ==
convert(x)$ComplexPattern(Integer, R, %)
if R has ConvertibleTo Pattern Float then
convert(x:%):Pattern Float ==
convert(x)$ComplexPattern(Float, R, %)
if R has PatternMatchable Integer then
patternMatch(x:%, p:Pattern Integer,
l:PatternMatchResult(Integer, %)) ==
patternMatch(x, p, l)$ComplexPatternMatch(Integer, R, %)
if R has PatternMatchable Float then
patternMatch(x:%, p:Pattern Float,
l:PatternMatchResult(Float, %)) ==
patternMatch(x, p, l)$ComplexPatternMatch(Float, R, %)
if R has IntegerNumberSystem then
rational? x == zero? imag x
rational x ==
zero? imag x => rational real x
error "Not a rational number"
rationalIfCan x ==
zero? imag x => rational real x
"failed"
if R has Field then
inv x ==
zero? imag x => (inv real x)::%
r := norm x
complex(real(x) / r, - imag(x) / r)
if R has IntegralDomain then
x:% exquo r:R ==
one? r => x
(r1 := real(x) exquo r) case "failed" => "failed"
(r2 := imag(x) exquo r) case "failed" => "failed"
complex(r1, r2)
x:% exquo y:% ==
zero? imag y => x exquo real y
x * conjugate(y) exquo norm(y)
recip(x:%) == 1 exquo x
if R has OrderedRing then
unitNormal x ==
zero? x => [1,x,1]
(u := recip x) case % => [x, 1, u]
zero? real x =>
c := unitNormal imag x
[complex(0, c.unit), (c.associate * imag x)::%,
complex(0, - c.associate)]
c := unitNormal real x
x := c.associate * x
imag x < 0 =>
x := complex(- imag x, real x)
[- c.unit * imaginary(), x, c.associate * imaginary()]
[c.unit ::%, x, c.associate ::%]
else
unitNormal x ==
zero? x => [1,x,1]
(u := recip x) case % => [x, 1, u]
zero? real x =>
c := unitNormal imag x
[complex(0, c.unit), (c.associate * imag x)::%,
complex(0, - c.associate)]
c := unitNormal real x
x := c.associate * x
[c.unit ::%, x, c.associate ::%]
if R has EuclideanDomain then
if R has additiveValuation then
euclideanSize x == max(euclideanSize real x,
euclideanSize imag x)
else
euclideanSize x == euclideanSize(real(x)**2 + imag(x)**2)$R
if R has IntegerNumberSystem then
x rem y ==
zero? imag y =>
yr:=real y
complex(symmetricRemainder(real(x), yr),
symmetricRemainder(imag(x), yr))
divide(x, y).remainder
x quo y ==
zero? imag y =>
yr:= real y
xr:= real x
xi:= imag x
complex((xr-symmetricRemainder(xr,yr)) quo yr,
(xi-symmetricRemainder(xi,yr)) quo yr)
divide(x, y).quotient
else
x rem y ==
zero? imag y =>
yr:=real y
complex(real(x) rem yr,imag(x) rem yr)
divide(x, y).remainder
x quo y ==
zero? imag y => complex(real x quo real y,imag x quo real y)
divide(x, y).quotient
divide(x, y) ==
r := norm y
y1 := conjugate y
xx := x * y1
x1 := real(xx) rem r
a := x1
if x1~=0 and sizeLess?(r, 2 * x1) then
a := x1 - r
if sizeLess?(x1, a) then a := x1 + r
x2 := imag(xx) rem r
b := x2
if x2~=0 and sizeLess?(r, 2 * x2) then
b := x2 - r
if sizeLess?(x2, b) then b := x2 + r
y1 := (complex(a, b) exquo y1)::%
[((x - y1) exquo y)::%, y1]
if R has TranscendentalFunctionCategory then
half := recip(2::R)::R
if R has RealNumberSystem then
atan2loc(y: R, x: R): R ==
pi1 := pi()$R
pi2 := pi1 * half
x = 0 => if y >= 0 then pi2 else -pi2
-- Atan in (-pi/2,pi/2]
theta := atan(y * recip(x)::R)
while theta <= -pi2 repeat theta := theta + pi1
while theta > pi2 repeat theta := theta - pi1
x >= 0 => theta -- I or IV
if y >= 0 then
theta + pi1 -- II
else
theta - pi1 -- III
argument x == atan2loc(imag x, real x)
else
if R has RadicalCategory then
argument x ==
n1 := sqrt(norm(x))
x1 := real(x) + n1
(2::R)*atan(imag(x) * recip(x1)::R)
else
-- Emulate sqrt using exp and log
argument x ==
n1 := exp(half*log(norm(x)))
x1 := real(x) + n1
(2::R)*atan(imag(x) * recip(x1)::R)
pi() == pi()$R :: %
if R is DoubleFloat then
stoc ==> S_-TO_-C$Lisp
ctos ==> C_-TO_-S$Lisp
exp x == ctos EXP(stoc x)$Lisp
log x == ctos LOG(stoc x)$Lisp
sin x == ctos SIN(stoc x)$Lisp
cos x == ctos COS(stoc x)$Lisp
tan x == ctos TAN(stoc x)$Lisp
asin x == ctos ASIN(stoc x)$Lisp
acos x == ctos ACOS(stoc x)$Lisp
atan x == ctos ATAN(stoc x)$Lisp
sinh x == ctos SINH(stoc x)$Lisp
cosh x == ctos COSH(stoc x)$Lisp
tanh x == ctos TANH(stoc x)$Lisp
asinh x == ctos ASINH(stoc x)$Lisp
acosh x == ctos ACOSH(stoc x)$Lisp
atanh x == ctos ATANH(stoc x)$Lisp
else
atan x ==
ix := imaginary()*x
- imaginary() * half * (log(1 + ix) - log(1 - ix))
log x ==
complex(log(norm x) * half, argument x)
exp x ==
e := exp real x
complex(e * cos imag x, e * sin imag x)
cos x ==
e := exp(imaginary() * x)
half * (e + recip(e)::%)
sin x ==
e := exp(imaginary() * x)
- imaginary() * half * (e - recip(e)::%)
if R has RealNumberSystem then
polarCoordinates x ==
[sqrt norm x, (negative?(t := argument x) => t + 2 * pi(); t)]
x:% ** q:Fraction(Integer) ==
zero? q =>
zero? x => error "0 ** 0 is undefined"
1
zero? x => 0
rx := real x
zero? imag x and positive? rx => (rx ** q)::%
zero? imag x and denom q = 2 => complex(0, (-rx)**q)
ax := sqrt(norm x) ** q
tx := q::R * argument x
complex(ax * cos tx, ax * sin tx)
else if R has RadicalCategory then
x:% ** q:Fraction(Integer) ==
zero? q =>
zero? x => error "0 ** 0 is undefined"
1
r := real x
zero?(i := imag x) => (r ** q)::%
t := numer(q) * recip(denom(q)::R)::R * argument x
e:R :=
zero? r => i ** q
norm(x) ** (q / (2::Fraction(Integer)))
complex(e * cos t, e * sin t)
@
\section{package COMPLPAT ComplexPattern}
<<package COMPLPAT ComplexPattern>>=
)abbrev package COMPLPAT ComplexPattern
++ Author: Barry Trager
++ Date Created: 30 Nov 1995
++ Date Last Updated:
++ Basic Functions:
++ Related Constructors:
++ Also See:
++ AMS Classifications:
++ Keywords: complex, patterns
++ References:
++ Description:
++ This package supports converting complex expressions to patterns
ComplexPattern(R, S, CS) : C == T where
R: SetCategory
S: Join(ConvertibleTo Pattern R, CommutativeRing)
CS: ComplexCategory S
C == with
convert: CS -> Pattern R
++ convert(cs) converts the complex expression cs to a pattern
T == add
ipat : Pattern R := patternVariable('%i, true, false, false)
convert(cs) ==
zero? imag cs => convert real cs
convert real cs + ipat * convert imag cs
@
\section{package CPMATCH ComplexPatternMatch}
<<package CPMATCH ComplexPatternMatch>>=
)abbrev package CPMATCH ComplexPatternMatch
++ Author: Barry Trager
++ Date Created: 30 Nov 1995
++ Date Last Updated:
++ Basic Functions:
++ Related Constructors:
++ Also See:
++ AMS Classifications:
++ Keywords: complex, pattern matching
++ References:
++ Description:
++ This package supports matching patterns involving complex expressions
ComplexPatternMatch(R, S, CS) : C == T where
R: SetCategory
S: Join(PatternMatchable R, CommutativeRing)
CS: ComplexCategory S
PMRS ==> PatternMatchResult(R, CS)
PS ==> Polynomial S
C == with
if PS has PatternMatchable(R) then
patternMatch: (CS, Pattern R, PMRS) -> PMRS
++ patternMatch(cexpr, pat, res) matches the pattern pat to the
++ complex expression cexpr. res contains the variables of pat
++ which are already matched and their matches.
T == add
import PatternMatchPushDown(R, S, CS)
import PatternMatchResultFunctions2(R, PS, CS)
import PatternMatchResultFunctions2(R, CS, PS)
ivar : PS := '%i::PS
makeComplex(p:PS):CS ==
up := univariate p
degree up > 1 => error "not linear in %i"
icoef:=leadingCoefficient(up)
rcoef:=leadingCoefficient(reductum p)
complex(rcoef,icoef)
makePoly(cs:CS):PS == real(cs)*ivar + imag(cs)::PS
if PS has PatternMatchable(R) then
patternMatch(cs, pat, result) ==
zero? imag cs =>
patternMatch(real cs, pat, result)
map(makeComplex,
patternMatch(makePoly cs, pat, map(makePoly, result)))
@
\section{domain COMPLEX Complex}
<<domain COMPLEX Complex>>=
)abbrev domain COMPLEX Complex
++ Author:
++ Date Created:
++ Date Last Updated:
++ Basic Functions:
++ Related Constructors:
++ Also See:
++ AMS Classifications:
++ Keywords:
++ References:
++ Description:
++ \spadtype {Complex(R)} creates the domain of elements of the form
++ \spad{a + b * i} where \spad{a} and b come from the ring R,
++ and i is a new element such that \spad{i**2 = -1}.
Complex(R:CommutativeRing): ComplexCategory(R) with
if R has OpenMath then OpenMath
== add
Rep := Record(real:R, imag:R)
if R has OpenMath then
writeOMComplex(dev: OpenMathDevice, x: %): Void ==
OMputApp(dev)
OMputSymbol(dev, "complex1", "complex__cartesian")
OMwrite(dev, real x)
OMwrite(dev, imag x)
OMputEndApp(dev)
OMwrite(x: %): String ==
s: String := ""
sp := OM_-STRINGTOSTRINGPTR(s)$Lisp
dev: OpenMathDevice := OMopenString(sp pretend String, OMencodingXML)
OMputObject(dev)
writeOMComplex(dev, x)
OMputEndObject(dev)
OMclose(dev)
s := OM_-STRINGPTRTOSTRING(sp)$Lisp pretend String
s
OMwrite(x: %, wholeObj: Boolean): String ==
s: String := ""
sp := OM_-STRINGTOSTRINGPTR(s)$Lisp
dev: OpenMathDevice := OMopenString(sp pretend String, OMencodingXML)
if wholeObj then
OMputObject(dev)
writeOMComplex(dev, x)
if wholeObj then
OMputEndObject(dev)
OMclose(dev)
s := OM_-STRINGPTRTOSTRING(sp)$Lisp pretend String
s
OMwrite(dev: OpenMathDevice, x: %): Void ==
OMputObject(dev)
writeOMComplex(dev, x)
OMputEndObject(dev)
OMwrite(dev: OpenMathDevice, x: %, wholeObj: Boolean): Void ==
if wholeObj then
OMputObject(dev)
writeOMComplex(dev, x)
if wholeObj then
OMputEndObject(dev)
0 == [0, 0]
1 == [1, 0]
zero? x == zero?(x.real) and zero?(x.imag)
one? x == one?(x.real) and zero?(x.imag)
coerce(r:R):% == [r, 0]
complex(r, i) == [r, i]
real x == x.real
imag x == x.imag
x + y == [x.real + y.real, x.imag + y.imag]
-- by re-defining this here, we save 5 fn calls
x:% * y:% ==
[x.real * y.real - x.imag * y.imag,
x.imag * y.real + y.imag * x.real] -- here we save nine!
if R has IntegralDomain then
x:% exquo y:% == -- to correct bad defaulting problem
zero? y.imag => x exquo y.real
x * conjugate(y) exquo norm(y)
@
\section{package COMPLEX2 ComplexFunctions2}
<<package COMPLEX2 ComplexFunctions2>>=
)abbrev package COMPLEX2 ComplexFunctions2
++ Author:
++ Date Created:
++ Date Last Updated:
++ Basic Functions:
++ Related Constructors:
++ Also See:
++ AMS Classifications:
++ Keywords:
++ References:
++ Description:
++ This package extends maps from underlying rings to maps between
++ complex over those rings.
ComplexFunctions2(R:CommutativeRing, S:CommutativeRing): with
map: (R -> S, Complex R) -> Complex S
++ map(f,u) maps f onto real and imaginary parts of u.
== add
map(fn, gr) == complex(fn real gr, fn imag gr)
@
\section{package COMPFACT ComplexFactorization}
<<package COMPFACT ComplexFactorization>>=
)abbrev package COMPFACT ComplexFactorization
++ Author:
++ Date Created:
++ Date Last Updated:
++ Basic Functions:
++ Related Constructors: Complex, UnivariatePolynomial
++ Also See:
++ AMS Classifications:
++ Keywords: complex, polynomial factorization, factor
++ References:
ComplexFactorization(RR,PR) : C == T where
RR : EuclideanDomain -- R is Z or Q
PR : UnivariatePolynomialCategory Complex RR
R ==> Complex RR
I ==> Integer
RN ==> Fraction I
GI ==> Complex I
GRN ==> Complex RN
C == with
factor : PR -> Factored PR
++ factor(p) factorizes the polynomial p with complex coefficients.
T == add
SUP ==> SparseUnivariatePolynomial
fUnion ==> Union("nil", "sqfr", "irred", "prime")
FF ==> Record(flg:fUnion, fctr:PR, xpnt:Integer)
SAEF := SimpleAlgebraicExtensionAlgFactor(SUP RN,GRN,SUP GRN)
UPCF2 := UnivariatePolynomialCategoryFunctions2(R,PR,GRN,SUP GRN)
UPCFB := UnivariatePolynomialCategoryFunctions2(GRN,SUP GRN,R,PR)
myMap(r:R) : GRN ==
R is GI =>
cr :GI := r pretend GI
complex((real cr)::RN,(imag cr)::RN)
R is GRN => r pretend GRN
compND(cc:GRN):Record(cnum:GI,cden:Integer) ==
ccr:=real cc
cci:=imag cc
dccr:=denom ccr
dcci:=denom cci
ccd:=lcm(dccr,dcci)
[complex(((ccd exquo dccr)::Integer)*numer ccr,
((ccd exquo dcci)::Integer)*numer cci),ccd]
conv(f:SUP GRN) :Record(convP:SUP GI, convD:RN) ==
pris:SUP GI :=0
dris:Integer:=1
dris1:Integer:=1
pdris:Integer:=1
for i in 0..(degree f) repeat
(cf:= coefficient(f,i)) = 0 => "next i"
cdf:=compND cf
dris:=lcm(cdf.cden,dris1)
pris:=((dris exquo dris1)::Integer)*pris +
((dris exquo cdf.cden)::Integer)*
monomial(cdf.cnum,i)$(SUP GI)
dris1:=dris
[pris,dris::RN]
backConv(ffr:Factored SUP GRN) : Factored PR ==
R is GRN =>
makeFR((unit ffr) pretend PR,[[f.flg,(f.fctr) pretend PR,f.xpnt]
for f in factorList ffr])
R is GI =>
const:=unit ffr
ris: List FF :=[]
for ff in factorList ffr repeat
fact:=primitivePart(conv(ff.fctr).convP)
expf:=ff.xpnt
ris:=cons([ff.flg,fact pretend PR,expf],ris)
lc:GRN := myMap leadingCoefficient(fact pretend PR)
const:= const*(leadingCoefficient(ff.fctr)/lc)**expf
uconst:GI:= compND(coefficient(const,0)).cnum
makeFR((uconst pretend R)::PR,ris)
factor(pol : PR) : Factored PR ==
ratPol:SUP GRN := 0
ratPol:=map(myMap,pol)$UPCF2
ffr:=factor ratPol
backConv ffr
@
\section{package CINTSLPE ComplexIntegerSolveLinearPolynomialEquation}
<<package CINTSLPE ComplexIntegerSolveLinearPolynomialEquation>>=
)abbrev package CINTSLPE ComplexIntegerSolveLinearPolynomialEquation
++ Author: James Davenport
++ Date Created: 1990
++ Date Last Updated:
++ Basic Functions:
++ Related Constructors:
++ Also See:
++ AMS Classifications:
++ Keywords:
++ References:
++ Description:
++ This package provides the generalized euclidean algorithm which is
++ needed as the basic step for factoring polynomials.
ComplexIntegerSolveLinearPolynomialEquation(R,CR): C == T
where
CP ==> SparseUnivariatePolynomial CR
R:IntegerNumberSystem
CR:ComplexCategory(R)
C == with
solveLinearPolynomialEquation: (List CP,CP) -> Union(List CP,"failed")
++ solveLinearPolynomialEquation([f1, ..., fn], g)
++ where (fi relatively prime to each other)
++ returns a list of ai such that
++ g = sum ai prod fj (j \= i) or
++ equivalently g/prod fj = sum (ai/fi)
++ or returns "failed" if no such list exists
T == add
oldlp:List CP := []
slpePrime:R:=(2::R)
oldtable:Vector List CP := empty()
solveLinearPolynomialEquation(lp,p) ==
if (oldlp ~= lp) then
-- we have to generate a new table
deg:= +/[degree u for u in lp]
ans:Union(Vector List CP,"failed"):="failed"
slpePrime:=67108859::R -- 2**26 -5 : a prime
-- a good test case for this package is
-- (good question?)
while (ans case "failed") repeat
ans:=tablePow(deg,complex(slpePrime,0),lp)$GenExEuclid(CR,CP)
if (ans case "failed") then
slpePrime:= slpePrime-4::R
while not prime?(slpePrime)$IntegerPrimesPackage(R) repeat
slpePrime:= slpePrime-4::R
oldtable:=(ans:: Vector List CP)
answer:=solveid(p,complex(slpePrime,0),oldtable)
answer
@
\section{License}
<<license>>=
--Copyright (c) 1991-2002, The Numerical ALgorithms Group Ltd.
--All rights reserved.
--Copyright (C) 2007-2009, 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 COMPCAT ComplexCategory>>
<<package COMPLPAT ComplexPattern>>
<<package CPMATCH ComplexPatternMatch>>
<<domain COMPLEX Complex>>
<<package COMPLEX2 ComplexFunctions2>>
<<package COMPFACT ComplexFactorization>>
<<package CINTSLPE ComplexIntegerSolveLinearPolynomialEquation>>
@
\eject
\begin{thebibliography}{99}
\bibitem{1} nothing
\end{thebibliography}
\end{document}
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