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292 lines
10 KiB
292 lines
10 KiB
"""
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Check that the output from irrational functions is accurate for
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high-precision input, from 5 to 200 digits. The reference values were
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verified with Mathematica.
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"""
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import time
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from mpmath import *
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precs = [5, 15, 28, 35, 57, 80, 100, 150, 200]
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# sqrt(3) + pi/2
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a = \
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"3.302847134363773912758768033145623809041389953497933538543279275605"\
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"841220051904536395163599428307109666700184672047856353516867399774243594"\
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"67433521615861420725323528325327484262075464241255915238845599752675"
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# e + 1/euler**2
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b = \
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"5.719681166601007617111261398629939965860873957353320734275716220045750"\
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"31474116300529519620938123730851145473473708966080207482581266469342214"\
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"824842256999042984813905047895479210702109260221361437411947323431"
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# sqrt(a)
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sqrt_a = \
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"1.817373691447021556327498239690365674922395036495564333152483422755"\
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"144321726165582817927383239308173567921345318453306994746434073691275094"\
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"484777905906961689902608644112196725896908619756404253109722911487"
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# sqrt(a+b*i).real
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sqrt_abi_real = \
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"2.225720098415113027729407777066107959851146508557282707197601407276"\
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"89160998185797504198062911768240808839104987021515555650875977724230130"\
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"3584116233925658621288393930286871862273400475179312570274423840384"
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# sqrt(a+b*i).imag
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sqrt_abi_imag = \
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"1.2849057639084690902371581529110949983261182430040898147672052833653668"\
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"0629534491275114877090834296831373498336559849050755848611854282001250"\
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"1924311019152914021365263161630765255610885489295778894976075186"
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# log(a)
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log_a = \
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"1.194784864491089550288313512105715261520511949410072046160598707069"\
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"4336653155025770546309137440687056366757650909754708302115204338077595203"\
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"83005773986664564927027147084436553262269459110211221152925732612"
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# log(a+b*i).real
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log_abi_real = \
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"1.8877985921697018111624077550443297276844736840853590212962006811663"\
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"04949387789489704203167470111267581371396245317618589339274243008242708"\
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"014251531496104028712866224020066439049377679709216784954509456421"
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# log(a+b*i).imag
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log_abi_imag = \
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"1.0471204952840802663567714297078763189256357109769672185219334169734948"\
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"4265809854092437285294686651806426649541504240470168212723133326542181"\
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"8300136462287639956713914482701017346851009323172531601894918640"
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# exp(a)
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exp_a = \
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"27.18994224087168661137253262213293847994194869430518354305430976149"\
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"382792035050358791398632888885200049857986258414049540376323785711941636"\
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"100358982497583832083513086941635049329804685212200507288797531143"
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# exp(a+b*i).real
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exp_abi_real = \
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"22.98606617170543596386921087657586890620262522816912505151109385026"\
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"40160179326569526152851983847133513990281518417211964710397233157168852"\
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"4963130831190142571659948419307628119985383887599493378056639916701"
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# exp(a+b*i).imag
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exp_abi_imag = \
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"-14.523557450291489727214750571590272774669907424478129280902375851196283"\
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"3377162379031724734050088565710975758824441845278120105728824497308303"\
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"6065619788140201636218705414429933685889542661364184694108251449"
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# a**b
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pow_a_b = \
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"928.7025342285568142947391505837660251004990092821305668257284426997"\
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"361966028275685583421197860603126498884545336686124793155581311527995550"\
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"580229264427202446131740932666832138634013168125809402143796691154"
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# (a**(a+b*i)).real
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pow_a_abi_real = \
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"44.09156071394489511956058111704382592976814280267142206420038656267"\
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"67707916510652790502399193109819563864568986234654864462095231138500505"\
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"8197456514795059492120303477512711977915544927440682508821426093455"
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# (a**(a+b*i)).imag
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pow_a_abi_imag = \
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"27.069371511573224750478105146737852141664955461266218367212527612279886"\
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"9322304536553254659049205414427707675802193810711302947536332040474573"\
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"8166261217563960235014674118610092944307893857862518964990092301"
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# ((a+b*i)**(a+b*i)).real
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pow_abi_abi_real = \
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"-0.15171310677859590091001057734676423076527145052787388589334350524"\
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"8084195882019497779202452975350579073716811284169068082670778986235179"\
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"0813026562962084477640470612184016755250592698408112493759742219150452"\
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# ((a+b*i)**(a+b*i)).imag
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pow_abi_abi_imag = \
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"1.2697592504953448936553147870155987153192995316950583150964099070426"\
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"4736837932577176947632535475040521749162383347758827307504526525647759"\
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"97547638617201824468382194146854367480471892602963428122896045019902"
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# sin(a)
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sin_a = \
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"-0.16055653857469062740274792907968048154164433772938156243509084009"\
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"38437090841460493108570147191289893388608611542655654723437248152535114"\
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"528368009465836614227575701220612124204622383149391870684288862269631"
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# sin(1000*a)
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sin_1000a = \
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"-0.85897040577443833776358106803777589664322997794126153477060795801"\
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"09151695416961724733492511852267067419573754315098042850381158563024337"\
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"216458577140500488715469780315833217177634490142748614625281171216863"
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# sin(a+b*i)
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sin_abi_real = \
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"-24.4696999681556977743346798696005278716053366404081910969773939630"\
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"7149215135459794473448465734589287491880563183624997435193637389884206"\
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"02151395451271809790360963144464736839412254746645151672423256977064"
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sin_abi_imag = \
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"-150.42505378241784671801405965872972765595073690984080160750785565810981"\
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"8314482499135443827055399655645954830931316357243750839088113122816583"\
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"7169201254329464271121058839499197583056427233866320456505060735"
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# cos
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cos_a = \
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"-0.98702664499035378399332439243967038895709261414476495730788864004"\
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"05406821549361039745258003422386169330787395654908532996287293003581554"\
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"257037193284199198069707141161341820684198547572456183525659969145501"
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cos_1000a = \
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"-0.51202523570982001856195696460663971099692261342827540426136215533"\
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"52686662667660613179619804463250686852463876088694806607652218586060613"\
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"951310588158830695735537073667299449753951774916401887657320950496820"
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# tan
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tan_a = \
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"0.162666873675188117341401059858835168007137819495998960250142156848"\
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"639654718809412181543343168174807985559916643549174530459883826451064966"\
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"7996119428949951351938178809444268785629011625179962457123195557310"
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tan_abi_real = \
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"6.822696615947538488826586186310162599974827139564433912601918442911"\
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"1026830824380070400102213741875804368044342309515353631134074491271890"\
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"467615882710035471686578162073677173148647065131872116479947620E-6"
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tan_abi_imag = \
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"0.9999795833048243692245661011298447587046967777739649018690797625964167"\
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"1446419978852235960862841608081413169601038230073129482874832053357571"\
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"62702259309150715669026865777947502665936317953101462202542168429"
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def test_hp():
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for dps in precs:
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mp.dps = dps + 8
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aa = mpf(a)
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bb = mpf(b)
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a1000 = 1000*mpf(a)
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abi = mpc(aa, bb)
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mp.dps = dps
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assert (sqrt(3) + pi/2).ae(aa)
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assert (e + 1/euler**2).ae(bb)
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assert sqrt(aa).ae(mpf(sqrt_a))
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assert sqrt(abi).ae(mpc(sqrt_abi_real, sqrt_abi_imag))
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assert log(aa).ae(mpf(log_a))
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assert log(abi).ae(mpc(log_abi_real, log_abi_imag))
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assert exp(aa).ae(mpf(exp_a))
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assert exp(abi).ae(mpc(exp_abi_real, exp_abi_imag))
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assert (aa**bb).ae(mpf(pow_a_b))
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assert (aa**abi).ae(mpc(pow_a_abi_real, pow_a_abi_imag))
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assert (abi**abi).ae(mpc(pow_abi_abi_real, pow_abi_abi_imag))
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assert sin(a).ae(mpf(sin_a))
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assert sin(a1000).ae(mpf(sin_1000a))
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assert sin(abi).ae(mpc(sin_abi_real, sin_abi_imag))
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assert cos(a).ae(mpf(cos_a))
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assert cos(a1000).ae(mpf(cos_1000a))
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assert tan(a).ae(mpf(tan_a))
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assert tan(abi).ae(mpc(tan_abi_real, tan_abi_imag))
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# check that complex cancellation is avoided so that both
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# real and imaginary parts have high relative accuracy.
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# abs_eps should be 0, but has to be set to 1e-205 to pass the
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# 200-digit case, probably due to slight inaccuracy in the
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# precomputed input
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assert (tan(abi).real).ae(mpf(tan_abi_real), abs_eps=1e-205)
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assert (tan(abi).imag).ae(mpf(tan_abi_imag), abs_eps=1e-205)
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mp.dps = 460
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assert str(log(3))[-20:] == '02166121184001409826'
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mp.dps = 15
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# Since str(a) can differ in the last digit from rounded a, and I want
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# to compare the last digits of big numbers with the results in Mathematica,
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# I made this hack to get the last 20 digits of rounded a
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def last_digits(a):
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r = repr(a)
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s = str(a)
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#dps = mp.dps
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#mp.dps += 3
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m = 10
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r = r.replace(s[:-m],'')
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r = r.replace("mpf('",'').replace("')",'')
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num0 = 0
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for c in r:
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if c == '0':
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num0 += 1
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else:
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break
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b = float(int(r))/10**(len(r) - m)
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if b >= 10**m - 0.5: # pragma: no cover
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raise NotImplementedError
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n = int(round(b))
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sn = str(n)
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s = s[:-m] + '0'*num0 + sn
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return s[-20:]
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# values checked with Mathematica
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def test_log_hp():
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mp.dps = 2000
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a = mpf(10)**15000/3
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r = log(a)
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res = last_digits(r)
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# Mathematica N[Log[10^15000/3], 2000]
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# ...7443804441768333470331
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assert res == '43804441768333470331'
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# see issue 145
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r = log(mpf(3)/2)
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# Mathematica N[Log[3/2], 2000]
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# ...69653749808140753263288
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res = last_digits(r)
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assert res == '53749808140753263288'
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mp.dps = 10000
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r = log(2)
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res = last_digits(r)
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# Mathematica N[Log[2], 10000]
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# ...695615913401856601359655561
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assert res == '13401856601359655561'
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r = log(mpf(10)**10/3)
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res = last_digits(r)
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# Mathematica N[Log[10^10/3], 10000]
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# ...587087654020631943060007154
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assert res == '54020631943060007154', res
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r = log(mpf(10)**100/3)
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res = last_digits(r)
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# Mathematica N[Log[10^100/3], 10000]
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# ,,,59246336539088351652334666
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assert res == '36539088351652334666', res
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mp.dps += 10
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a = 1 - mpf(1)/10**10
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mp.dps -= 10
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r = log(a)
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res = last_digits(r)
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# ...3310334360482956137216724048322957404
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# 372167240483229574038733026370
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# Mathematica N[Log[1 - 10^-10]*10^10, 10000]
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# ...60482956137216724048322957404
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assert res == '37216724048322957404', res
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mp.dps = 10000
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mp.dps += 100
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a = 1 + mpf(1)/10**100
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mp.dps -= 100
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r = log(a)
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res = last_digits(+r)
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# Mathematica N[Log[1 + 10^-100]*10^10, 10030]
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# ...3994733877377412241546890854692521568292338268273 10^-91
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assert res == '39947338773774122415', res
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mp.dps = 15
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def test_exp_hp():
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mp.dps = 4000
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r = exp(mpf(1)/10)
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# IntegerPart[N[Exp[1/10] * 10^4000, 4000]]
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# ...92167105162069688129
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assert int(r * 10**mp.dps) % 10**20 == 92167105162069688129
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