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\documentclass{article}
\usepackage{axiom}
\begin{document}
\title{\$SPAD/src/algebra expexpan.spad}
\author{Clifton J. Williamson}
\maketitle
\begin{abstract}
\end{abstract}
\eject
\tableofcontents
\eject
\section{domain EXPUPXS ExponentialOfUnivariatePuiseuxSeries}
<<domain EXPUPXS ExponentialOfUnivariatePuiseuxSeries>>=
)abbrev domain EXPUPXS ExponentialOfUnivariatePuiseuxSeries
++ Author: Clifton J. Williamson
++ Date Created: 4 August 1992
++ Date Last Updated: 27 August 1992
++ Basic Operations:
++ Related Domains: UnivariatePuiseuxSeries(FE,var,cen)
++ Also See:
++ AMS Classifications:
++ Keywords: limit, functional expression, power series, essential singularity
++ Examples:
++ References:
++ Description:
++ ExponentialOfUnivariatePuiseuxSeries is a domain used to represent
++ essential singularities of functions. An object in this domain is a
++ function of the form \spad{exp(f(x))}, where \spad{f(x)} is a Puiseux
++ series with no terms of non-negative degree. Objects are ordered
++ according to order of singularity, with functions which tend more
++ rapidly to zero or infinity considered to be larger. Thus, if
++ \spad{order(f(x)) < order(g(x))}, i.e. the first non-zero term of
++ \spad{f(x)} has lower degree than the first non-zero term of \spad{g(x)},
++ then \spad{exp(f(x)) > exp(g(x))}. If \spad{order(f(x)) = order(g(x))},
++ then the ordering is essentially random. This domain is used
++ in computing limits involving functions with essential singularities.
ExponentialOfUnivariatePuiseuxSeries(FE,var,cen):_
Exports == Implementation where
FE : Field
var : Symbol
cen : FE
UPXS ==> UnivariatePuiseuxSeries(FE,var,cen)
Exports ==> Join(UnivariatePuiseuxSeriesCategory(FE),OrderedAbelianMonoid) _
with
exponential : UPXS -> %
++ exponential(f(x)) returns \spad{exp(f(x))}.
++ Note: the function does NOT check that \spad{f(x)} has no
++ non-negative terms.
exponent : % -> UPXS
++ exponent(exp(f(x))) returns \spad{f(x)}
exponentialOrder: % -> Fraction Integer
++ exponentialOrder(exp(c * x **(-n) + ...)) returns \spad{-n}.
++ exponentialOrder(0) returns \spad{0}.
Implementation ==> UPXS add
Rep := UPXS
exponential f == complete f
exponent f == f pretend UPXS
exponentialOrder f == order(exponent f,0)
zero? f == empty? entries complete terms f
f = g ==
-- we redefine equality because we know that we are dealing with
-- a FINITE series, so there is no danger in computing all terms
(entries complete terms f) = (entries complete terms g)
f < g ==
zero? f => not zero? g
zero? g => false
(ordf := exponentialOrder f) > (ordg := exponentialOrder g) => true
ordf < ordg => false
(fCoef := coefficient(f,ordf)) = (gCoef := coefficient(g,ordg)) =>
reductum(f) < reductum(g)
before?(fCoef,gCoef) -- this is "random" if FE is EXPR INT
coerce(f:%):OutputForm ==
("%e" :: OutputForm) ** ((coerce$Rep)(complete f)@OutputForm)
@
\section{domain UPXSSING UnivariatePuiseuxSeriesWithExponentialSingularity}
<<domain UPXSSING UnivariatePuiseuxSeriesWithExponentialSingularity>>=
)abbrev domain UPXSSING UnivariatePuiseuxSeriesWithExponentialSingularity
++ Author: Clifton J. Williamson
++ Date Created: 4 August 1992
++ Date Last Updated: 27 August 1992
++ Basic Operations:
++ Related Domains: UnivariatePuiseuxSeries(FE,var,cen),
++ ExponentialOfUnivariatePuiseuxSeries(FE,var,cen)
++ ExponentialExpansion(R,FE,var,cen)
++ Also See:
++ AMS Classifications:
++ Keywords: limit, functional expression, power series
++ Examples:
++ References:
++ Description:
++ UnivariatePuiseuxSeriesWithExponentialSingularity is a domain used to
++ represent functions with essential singularities. Objects in this
++ domain are sums, where each term in the sum is a univariate Puiseux
++ series times the exponential of a univariate Puiseux series. Thus,
++ the elements of this domain are sums of expressions of the form
++ \spad{g(x) * exp(f(x))}, where g(x) is a univariate Puiseux series
++ and f(x) is a univariate Puiseux series with no terms of non-negative
++ degree.
UnivariatePuiseuxSeriesWithExponentialSingularity(R,FE,var,cen):_
Exports == Implementation where
R : Join(RetractableTo Integer,_
LinearlyExplicitRingOver Integer,GcdDomain)
FE : Join(AlgebraicallyClosedField,TranscendentalFunctionCategory,_
FunctionSpace R)
var : Symbol
cen : FE
B ==> Boolean
I ==> Integer
L ==> List
RN ==> Fraction Integer
UPXS ==> UnivariatePuiseuxSeries(FE,var,cen)
EXPUPXS ==> ExponentialOfUnivariatePuiseuxSeries(FE,var,cen)
OFE ==> OrderedCompletion FE
Result ==> Union(OFE,"failed")
PxRec ==> Record(k: Fraction Integer,c:FE)
Term ==> Record(%coef:UPXS,%expon:EXPUPXS,%expTerms:List PxRec)
-- the %expTerms field is used to record the list of the terms (a 'term'
-- records an exponent and a coefficient) in the exponent %expon
TypedTerm ==> Record(%term:Term,%type:String)
-- a term together with a String which tells whether it has an infinite,
-- zero, or unknown limit as var -> cen+
TRec ==> Record(%zeroTerms: List Term,_
%infiniteTerms: List Term,_
%failedTerms: List Term,_
%puiseuxSeries: UPXS)
SIGNEF ==> ElementaryFunctionSign(R,FE)
Exports ==> Join(FiniteAbelianMonoidRing(UPXS,EXPUPXS),IntegralDomain) with
limitPlus : % -> Union(OFE,"failed")
++ limitPlus(f(var)) returns \spad{limit(var -> cen+,f(var))}.
dominantTerm : % -> Union(TypedTerm,"failed")
++ dominantTerm(f(var)) returns the term that dominates the limiting
++ behavior of \spad{f(var)} as \spad{var -> cen+} together with a
++ \spadtype{String} which briefly describes that behavior. The
++ value of the \spadtype{String} will be \spad{"zero"} (resp.
++ \spad{"infinity"}) if the term tends to zero (resp. infinity)
++ exponentially and will \spad{"series"} if the term is a
++ Puiseux series.
Implementation ==> PolynomialRing(UPXS,EXPUPXS) add
makeTerm : (UPXS,EXPUPXS) -> Term
coeff : Term -> UPXS
exponent : Term -> EXPUPXS
exponentTerms : Term -> List PxRec
setExponentTerms_! : (Term,List PxRec) -> List PxRec
computeExponentTerms_! : Term -> List PxRec
terms : % -> List Term
sortAndDiscardTerms: List Term -> TRec
termsWithExtremeLeadingCoef : (L Term,RN,I) -> Union(L Term,"failed")
filterByOrder: (L Term,(RN,RN) -> B) -> Record(%list:L Term,%order:RN)
dominantTermOnList : (L Term,RN,I) -> Union(Term,"failed")
iDominantTerm : L Term -> Union(Record(%term:Term,%type:String),"failed")
retractIfCan(f: %): Union(UPXS,"failed") ==
(numberOfMonomials f = 1) and (zero? degree f) => leadingCoefficient f
"failed"
recip f ==
numberOfMonomials f = 1 =>
monomial(inv leadingCoefficient f,- degree f)
"failed"
makeTerm(coef,expon) == [coef,expon,empty()]
coeff term == term.%coef
exponent term == term.%expon
exponentTerms term == term.%expTerms
setExponentTerms_!(term,list) == term.%expTerms := list
computeExponentTerms_! term ==
setExponentTerms_!(term,entries complete terms exponent term)
terms f ==
-- terms with a higher order singularity will appear closer to the
-- beginning of the list because of the ordering in EXPPUPXS;
-- no "expnonent terms" are computed by this function
zero? f => empty()
concat(makeTerm(leadingCoefficient f,degree f),terms reductum f)
sortAndDiscardTerms termList ==
-- 'termList' is the list of terms of some function f(var), ordered
-- so that terms with a higher order singularity occur at the
-- beginning of the list.
-- This function returns lists of candidates for the "dominant
-- term" in 'termList', i.e. the term which describes the
-- asymptotic behavior of f(var) as var -> cen+.
-- 'zeroTerms' will contain terms which tend to zero exponentially
-- and contains only those terms with the lowest order singularity.
-- 'zeroTerms' will be non-empty only when there are no terms of
-- infinite or series type.
-- 'infiniteTerms' will contain terms which tend to infinity
-- exponentially and contains only those terms with the highest
-- order singularity.
-- 'failedTerms' will contain terms which have an exponential
-- singularity, where we cannot say whether the limiting value
-- is zero or infinity. Only terms with a higher order sigularity
-- than the terms on 'infiniteList' are included.
-- 'pSeries' will be a Puiseux series representing a term without an
-- exponential singularity. 'pSeries' will be non-zero only when no
-- other terms are known to tend to infinity exponentially
zeroTerms : List Term := empty()
infiniteTerms : List Term := empty()
failedTerms : List Term := empty()
-- we keep track of whether or not we've found an infinite term
-- if so, 'infTermOrd' will be set to a negative value
infTermOrd : RN := 0
-- we keep track of whether or not we've found a zero term
-- if so, 'zeroTermOrd' will be set to a negative value
zeroTermOrd : RN := 0
ord : RN := 0; pSeries : UPXS := 0 -- dummy values
while not empty? termList repeat
-- 'expon' is a Puiseux series
expon := exponent(term := first termList)
-- quit if there is an infinite term with a higher order singularity
(ord := order(expon,0)) > infTermOrd => leave "infinite term dominates"
-- if ord = 0, we've hit the end of the list
(ord = 0) =>
-- since we have a series term, don't bother with zero terms
leave(pSeries := coeff(term); zeroTerms := empty())
coef := coefficient(expon,ord)
-- if we can't tell if the lowest order coefficient is positive or
-- negative, we have a "failed term"
(signum := sign(coef)$SIGNEF) case "failed" =>
failedTerms := concat(term,failedTerms)
termList := rest termList
-- if the lowest order coefficient is positive, we have an
-- "infinite term"
(sig := signum :: Integer) = 1 =>
infTermOrd := ord
infiniteTerms := concat(term,infiniteTerms)
-- since we have an infinite term, don't bother with zero terms
zeroTerms := empty()
termList := rest termList
-- if the lowest order coefficient is negative, we have a
-- "zero term" if there are no infinite terms and no failed
-- terms, add the term to 'zeroTerms'
if empty? infiniteTerms then
zeroTerms :=
ord = zeroTermOrd => concat(term,zeroTerms)
zeroTermOrd := ord
list term
termList := rest termList
-- reverse "failed terms" so that higher order singularities
-- appear at the beginning of the list
[zeroTerms,infiniteTerms,reverse_! failedTerms,pSeries]
termsWithExtremeLeadingCoef(termList,ord,signum) ==
-- 'termList' consists of terms of the form [g(x),exp(f(x)),...];
-- when 'signum' is +1 (resp. -1), this function filters 'termList'
-- leaving only those terms such that coefficient(f(x),ord) is
-- maximal (resp. minimal)
while (coefficient(exponent first termList,ord) = 0) repeat
termList := rest termList
empty? termList => error "UPXSSING: can't happen"
coefExtreme := coefficient(exponent first termList,ord)
outList := list first termList; termList := rest termList
for term in termList repeat
(coefDiff := coefficient(exponent term,ord) - coefExtreme) = 0 =>
outList := concat(term,outList)
(sig := sign(coefDiff)$SIGNEF) case "failed" => return "failed"
(sig :: Integer) = signum => outList := list term
outList
filterByOrder(termList,predicate) ==
-- 'termList' consists of terms of the form [g(x),exp(f(x)),expTerms],
-- where 'expTerms' is a list containing some of the terms in the
-- series f(x).
-- The function filters 'termList' and, when 'predicate' is < (resp. >),
-- leaves only those terms with the lowest (resp. highest) order term
-- in 'expTerms'
while empty? exponentTerms first termList repeat
termList := rest termList
empty? termList => error "UPXSING: can't happen"
ordExtreme := (first exponentTerms first termList).k
outList := list first termList
for term in rest termList repeat
not empty? exponentTerms term =>
(ord := (first exponentTerms term).k) = ordExtreme =>
outList := concat(term,outList)
predicate(ord,ordExtreme) =>
ordExtreme := ord
outList := list term
-- advance pointers on "exponent terms" on terms on 'outList'
for term in outList repeat
setExponentTerms_!(term,rest exponentTerms term)
[outList,ordExtreme]
dominantTermOnList(termList,ord0,signum) ==
-- finds dominant term on 'termList'
-- it is known that "exponent terms" of order < 'ord0' are
-- the same for all terms on 'termList'
newList := termsWithExtremeLeadingCoef(termList,ord0,signum)
newList case "failed" => "failed"
termList := newList :: List Term
empty? rest termList => first termList
filtered :=
signum = 1 => filterByOrder(termList,#1 < #2)
filterByOrder(termList,#1 > #2)
termList := filtered.%list
empty? rest termList => first termList
dominantTermOnList(termList,filtered.%order,signum)
iDominantTerm termList ==
termRecord := sortAndDiscardTerms termList
zeroTerms := termRecord.%zeroTerms
infiniteTerms := termRecord.%infiniteTerms
failedTerms := termRecord.%failedTerms
pSeries := termRecord.%puiseuxSeries
-- in future versions, we will deal with "failed terms"
-- at present, if any occur, we cannot determine the limit
not empty? failedTerms => "failed"
not zero? pSeries => [makeTerm(pSeries,0),"series"]
not empty? infiniteTerms =>
empty? rest infiniteTerms => [first infiniteTerms,"infinity"]
for term in infiniteTerms repeat computeExponentTerms_! term
ord0 := order exponent first infiniteTerms
(dTerm := dominantTermOnList(infiniteTerms,ord0,1)) case "failed" =>
return "failed"
[dTerm :: Term,"infinity"]
empty? rest zeroTerms => [first zeroTerms,"zero"]
for term in zeroTerms repeat computeExponentTerms_! term
ord0 := order exponent first zeroTerms
(dTerm := dominantTermOnList(zeroTerms,ord0,-1)) case "failed" =>
return "failed"
[dTerm :: Term,"zero"]
dominantTerm f == iDominantTerm terms f
limitPlus f ==
-- list the terms occurring in 'f'; if there are none, then f = 0
empty?(termList := terms f) => 0
-- compute dominant term
(tInfo := iDominantTerm termList) case "failed" => "failed"
termInfo := tInfo :: Record(%term:Term,%type:String)
domTerm := termInfo.%term
(type := termInfo.%type) = "series" =>
-- find limit of series term
(ord := order(pSeries := coeff domTerm,1)) > 0 => 0
coef := coefficient(pSeries,ord)
member?(var,variables coef) => "failed"
ord = 0 => coef :: OFE
-- in the case of an infinite limit, we need to know the sign
-- of the first non-zero coefficient
(signum := sign(coef)$SIGNEF) case "failed" => "failed"
(signum :: Integer) = 1 => plusInfinity()
minusInfinity()
type = "zero" => 0
-- examine lowest order coefficient in series part of 'domTerm'
ord := order(pSeries := coeff domTerm)
coef := coefficient(pSeries,ord)
member?(var,variables coef) => "failed"
(signum := sign(coef)$SIGNEF) case "failed" => "failed"
(signum :: Integer) = 1 => plusInfinity()
minusInfinity()
@
\section{domain EXPEXPAN ExponentialExpansion}
<<domain EXPEXPAN ExponentialExpansion>>=
)abbrev domain EXPEXPAN ExponentialExpansion
++ Author: Clifton J. Williamson
++ Date Created: 13 August 1992
++ Date Last Updated: 27 August 1992
++ Basic Operations:
++ Related Domains: UnivariatePuiseuxSeries(FE,var,cen),
++ ExponentialOfUnivariatePuiseuxSeries(FE,var,cen)
++ Also See:
++ AMS Classifications:
++ Keywords: limit, functional expression, power series
++ Examples:
++ References:
++ Description:
++ UnivariatePuiseuxSeriesWithExponentialSingularity is a domain used to
++ represent essential singularities of functions. Objects in this domain
++ are quotients of sums, where each term in the sum is a univariate Puiseux
++ series times the exponential of a univariate Puiseux series.
ExponentialExpansion(R,FE,var,cen): Exports == Implementation where
R : Join(RetractableTo Integer,_
LinearlyExplicitRingOver Integer,GcdDomain)
FE : Join(AlgebraicallyClosedField,TranscendentalFunctionCategory,_
FunctionSpace R)
var : Symbol
cen : FE
RN ==> Fraction Integer
UPXS ==> UnivariatePuiseuxSeries(FE,var,cen)
EXPUPXS ==> ExponentialOfUnivariatePuiseuxSeries(FE,var,cen)
UPXSSING ==> UnivariatePuiseuxSeriesWithExponentialSingularity(R,FE,var,cen)
OFE ==> OrderedCompletion FE
Result ==> Union(OFE,"failed")
PxRec ==> Record(k: Fraction Integer,c:FE)
Term ==> Record(%coef:UPXS,%expon:EXPUPXS,%expTerms:List PxRec)
TypedTerm ==> Record(%term:Term,%type:String)
SIGNEF ==> ElementaryFunctionSign(R,FE)
Exports ==> Join(QuotientFieldCategory UPXSSING,RetractableTo UPXS) with
limitPlus : % -> Union(OFE,"failed")
++ limitPlus(f(var)) returns \spad{limit(var -> a+,f(var))}.
coerce: UPXS -> %
++ coerce(f) converts a \spadtype{UnivariatePuiseuxSeries} to
++ an \spadtype{ExponentialExpansion}.
Implementation ==> Fraction(UPXSSING) add
coeff : Term -> UPXS
exponent : Term -> EXPUPXS
upxssingIfCan : % -> Union(UPXSSING,"failed")
seriesQuotientLimit: (UPXS,UPXS) -> Union(OFE,"failed")
seriesQuotientInfinity: (UPXS,UPXS) -> Union(OFE,"failed")
Rep := Fraction UPXSSING
ZEROCOUNT : RN := 1000/1
coeff term == term.%coef
exponent term == term.%expon
--!! why is this necessary?
--!! code can run forever in retractIfCan if original assignment
--!! for 'ff' is used
upxssingIfCan f ==
one? denom f => numer f
"failed"
retractIfCan(f:%):Union(UPXS,"failed") ==
--ff := (retractIfCan$Rep)(f)@Union(UPXSSING,"failed")
--ff case "failed" => "failed"
(ff := upxssingIfCan f) case "failed" => "failed"
(fff := retractIfCan(ff::UPXSSING)@Union(UPXS,"failed")) case "failed" =>
"failed"
fff :: UPXS
f:UPXSSING / g:UPXSSING ==
(rec := recip g) case "failed" => f /$Rep g
f * (rec :: UPXSSING) :: %
f:% / g:% ==
(rec := recip numer g) case "failed" => f /$Rep g
(rec :: UPXSSING) * (denom g) * f
coerce(f:UPXS) == f :: UPXSSING :: %
seriesQuotientLimit(num,den) ==
-- limit of the quotient of two series
series := num / den
(ord := order(series,1)) > 0 => 0
coef := coefficient(series,ord)
member?(var,variables coef) => "failed"
ord = 0 => coef :: OFE
(sig := sign(coef)$SIGNEF) case "failed" => return "failed"
(sig :: Integer) = 1 => plusInfinity()
minusInfinity()
seriesQuotientInfinity(num,den) ==
-- infinite limit: plus or minus?
-- look at leading coefficients of series to tell
(numOrd := order(num,ZEROCOUNT)) = ZEROCOUNT => "failed"
(denOrd := order(den,ZEROCOUNT)) = ZEROCOUNT => "failed"
cc := coefficient(num,numOrd)/coefficient(den,denOrd)
member?(var,variables cc) => "failed"
(sig := sign(cc)$SIGNEF) case "failed" => return "failed"
(sig :: Integer) = 1 => plusInfinity()
minusInfinity()
limitPlus f ==
zero? f => 0
(den := denom f) = 1 => limitPlus numer f
(numerTerm := dominantTerm(num := numer f)) case "failed" => "failed"
numType := (numTerm := numerTerm :: TypedTerm).%type
(denomTerm := dominantTerm den) case "failed" => "failed"
denType := (denTerm := denomTerm :: TypedTerm).%type
numExpon := exponent numTerm.%term; denExpon := exponent denTerm.%term
numCoef := coeff numTerm.%term; denCoef := coeff denTerm.%term
-- numerator tends to zero exponentially
(numType = "zero") =>
-- denominator tends to zero exponentially
(denType = "zero") =>
(exponDiff := numExpon - denExpon) = 0 =>
seriesQuotientLimit(numCoef,denCoef)
expCoef := coefficient(exponDiff,order exponDiff)
(sig := sign(expCoef)$SIGNEF) case "failed" => return "failed"
(sig :: Integer) = -1 => 0
seriesQuotientInfinity(numCoef,denCoef)
0 -- otherwise limit is zero
-- numerator is a Puiseux series
(numType = "series") =>
-- denominator tends to zero exponentially
(denType = "zero") =>
seriesQuotientInfinity(numCoef,denCoef)
-- denominator is a series
(denType = "series") => seriesQuotientLimit(numCoef,denCoef)
0
-- remaining case: numerator tends to infinity exponentially
-- denominator tends to infinity exponentially
(denType = "infinity") =>
(exponDiff := numExpon - denExpon) = 0 =>
seriesQuotientLimit(numCoef,denCoef)
expCoef := coefficient(exponDiff,order exponDiff)
(sig := sign(expCoef)$SIGNEF) case "failed" => return "failed"
(sig :: Integer) = -1 => 0
seriesQuotientInfinity(numCoef,denCoef)
-- denominator tends to zero exponentially or is a series
seriesQuotientInfinity(numCoef,denCoef)
@
\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 EXPUPXS ExponentialOfUnivariatePuiseuxSeries>>
<<domain UPXSSING UnivariatePuiseuxSeriesWithExponentialSingularity>>
<<domain EXPEXPAN ExponentialExpansion>>
@
\eject
\begin{thebibliography}{99}
\bibitem{1} nothing
\end{thebibliography}
\end{document}
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