/usr/share/gap/lib/integer.gi is in gap-libs 4r6p5-3.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
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1622 1623 1624 1625 1626 1627 1628 1629 1630 1631 1632 1633 1634 1635 1636 1637 1638 1639 1640 1641 1642 1643 1644 1645 1646 1647 1648 1649 1650 1651 1652 1653 1654 1655 1656 1657 1658 1659 1660 1661 1662 1663 1664 1665 1666 1667 1668 1669 1670 1671 1672 1673 1674 1675 1676 1677 1678 1679 1680 1681 1682 1683 1684 1685 1686 1687 1688 1689 1690 1691 1692 1693 1694 1695 1696 1697 1698 1699 1700 1701 1702 1703 1704 1705 1706 1707 1708 1709 1710 1711 1712 1713 1714 1715 1716 1717 1718 1719 1720 1721 1722 1723 1724 1725 1726 1727 1728 1729 1730 1731 1732 1733 1734 1735 1736 1737 1738 1739 1740 1741 1742 1743 1744 1745 1746 1747 1748 1749 1750 1751 1752 1753 1754 1755 1756 1757 1758 1759 1760 1761 1762 1763 1764 1765 1766 1767 1768 1769 1770 1771 1772 1773 1774 1775 1776 1777 1778 1779 1780 1781 1782 1783 1784 1785 1786 1787 1788 1789 1790 1791 1792 1793 1794 1795 1796 1797 1798 1799 1800 1801 1802 1803 1804 1805 1806 1807 1808 1809 1810 1811 1812 1813 1814 1815 1816 1817 1818 1819 1820 1821 1822 1823 1824 1825 1826 1827 1828 1829 1830 1831 1832 1833 1834 1835 1836 1837 1838 1839 1840 1841 1842 1843 1844 1845 1846 1847 1848 1849 1850 1851 1852 1853 1854 1855 1856 1857 1858 1859 1860 1861 1862 1863 1864 1865 1866 1867 1868 1869 1870 1871 1872 1873 1874 1875 1876 1877 1878 1879 1880 1881 1882 1883 1884 1885 1886 1887 1888 1889 1890 1891 1892 1893 1894 1895 1896 1897 1898 1899 1900 1901 1902 1903 1904 1905 1906 1907 1908 1909 1910 1911 1912 1913 1914 1915 1916 1917 1918 1919 1920 1921 1922 1923 1924 1925 1926 1927 1928 1929 1930 1931 1932 1933 1934 1935 1936 1937 1938 1939 1940 1941 1942 1943 1944 1945 1946 1947 1948 1949 1950 1951 1952 1953 1954 1955 1956 1957 1958 1959 1960 1961 1962 1963 1964 1965 1966 1967 1968 | #############################################################################
##
#W integer.gi GAP library Thomas Breuer
#W & Frank Celler
#W & Stefan Kohl
#W & Werner Nickel
#W & Alice Niemeyer
#W & Martin Schönert
#W & Alex Wegner
##
##
#Y Copyright (C) 1997, Lehrstuhl D für Mathematik, RWTH Aachen, Germany
#Y (C) 1998 School Math and Comp. Sci., University of St Andrews, Scotland
#Y Copyright (C) 2002 The GAP Group
##
#############################################################################
##
#V Integers . . . . . . . . . . . . . . . . . . . . . ring of the integers
##
InstallValue( Integers, Objectify( NewType(
CollectionsFamily( CyclotomicsFamily ),
IsIntegers and IsAttributeStoringRep ),
rec() ) );
SetName( Integers, "Integers" );
SetString( Integers, "Integers" );
SetIsLeftActedOnByDivisionRing( Integers, false );
SetSize( Integers, infinity );
SetLeftActingDomain( Integers, Integers );
SetGeneratorsOfRing( Integers, [ 1 ] );
SetGeneratorsOfLeftModule( Integers, [ 1 ] );
SetIsFiniteDimensional( Integers, true );
SetUnits( Integers, [ -1, 1 ] );
SetIsWholeFamily( Integers, false );
#############################################################################
##
#V NonnegativeIntegers . . . . . . . . . . semiring of nonnegative integers
##
InstallValue( NonnegativeIntegers, Objectify( NewType(
CollectionsFamily( CyclotomicsFamily ),
IsNonnegativeIntegers and IsAttributeStoringRep ),
rec() ) );
SetName( NonnegativeIntegers, "NonnegativeIntegers" );
SetString( NonnegativeIntegers, "NonnegativeIntegers" );
SetSize( NonnegativeIntegers, infinity );
SetGeneratorsOfSemiringWithZero( NonnegativeIntegers, [ 1 ] );
SetGeneratorsOfAdditiveMagmaWithZero( NonnegativeIntegers, [ 1 ] );
SetIsWholeFamily( NonnegativeIntegers, false );
#############################################################################
##
#V PositiveIntegers . . . . . . . . . . . . . semiring of positive integers
##
InstallValue( PositiveIntegers, Objectify( NewType(
CollectionsFamily( CyclotomicsFamily ),
IsPositiveIntegers and IsAttributeStoringRep ),
rec() ) );
SetName( PositiveIntegers, "PositiveIntegers" );
SetString( PositiveIntegers, "PositiveIntegers" );
SetSize( PositiveIntegers, infinity );
SetGeneratorsOfSemiring( PositiveIntegers, [ 1 ] );
SetGeneratorsOfAdditiveMagma( PositiveIntegers, [ 1 ] );
SetIsWholeFamily( PositiveIntegers, false );
#############################################################################
##
#V GaussianIntegers . . . . . . . . . . . . . . . ring of Gaussian integers
##
InstallValue( GaussianIntegers, Objectify( NewType(
CollectionsFamily(CyclotomicsFamily),
IsGaussianIntegers and IsAttributeStoringRep ),
rec() ) );
SetLeftActingDomain( GaussianIntegers, Integers );
SetName( GaussianIntegers, "GaussianIntegers" );
SetString( GaussianIntegers, "GaussianIntegers" );
SetIsLeftActedOnByDivisionRing( GaussianIntegers, false );
SetSize( GaussianIntegers, infinity );
SetGeneratorsOfRing( GaussianIntegers, [ E(4) ] );
SetGeneratorsOfLeftModule( GaussianIntegers, [ 1, E(4) ] );
SetUnits( GaussianIntegers, [ -1, 1, -E(4), E(4) ] );
SetIsWholeFamily( GaussianIntegers, false );
#############################################################################
##
#R IsCanonicalBasisIntegersRep
##
DeclareRepresentation(
"IsCanonicalBasisIntegersRep",
IsAttributeStoringRep,
[] );
#T is this needed at all?
#############################################################################
##
#M Basis( Integers )
##
InstallMethod( Basis,
"for integers (delegate to `CanonicalBasis')",
[ IsIntegers ], CANONICAL_BASIS_FLAGS,
CanonicalBasis );
#############################################################################
##
#M CanonicalBasis( Integers )
##
InstallMethod( CanonicalBasis,
"for Integers",
true,
[ IsIntegers ], 0,
function( Integers )
local B;
B:= Objectify( NewType( FamilyObj( Integers ),
IsFiniteBasisDefault
and IsCanonicalBasis
and IsCanonicalBasisIntegersRep ),
rec() );
SetUnderlyingLeftModule( B, Integers );
SetBasisVectors( B, [ 1 ] );
return B;
end );
InstallMethod( Coefficients,
"for the canonical basis of Integers",
IsCollsElms,
[ IsBasis and IsCanonicalBasis and IsCanonicalBasisIntegersRep,
IsCyc ], 0,
function( B, v )
if IsInt( v ) then
return [ v ];
else
return fail;
fi;
end );
#############################################################################
##
#V Primes . . . . . . . . . . . . . . . . . . . . . . list of small primes
##
InstallValue( Primes,
[ 2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61,
67, 71, 73, 79, 83, 89, 97,101,103,107,109,113,127,131,137,139,149,151,
157,163,167,173,179,181,191,193,197,199,211,223,227,229,233,239,241,251,
257,263,269,271,277,281,283,293,307,311,313,317,331,337,347,349,353,359,
367,373,379,383,389,397,401,409,419,421,431,433,439,443,449,457,461,463,
467,479,487,491,499,503,509,521,523,541,547,557,563,569,571,577,587,593,
599,601,607,613,617,619,631,641,643,647,653,659,661,673,677,683,691,701,
709,719,727,733,739,743,751,757,761,769,773,787,797,809,811,821,823,827,
829,839,853,857,859,863,877,881,883,887,907,911,919,929,937,941,947,953,
967,971,977,983,991,997 ] );
MakeImmutable( Primes );
#############################################################################
##
#V Primes2 . . . . . . . . . . . . . . . . . . . . . . additional prime list
#V ProbablePrimes2 . . . . . . . . . . . . . . . . . . additional prime list
##
## Some primes in `Primes2' are taken from the tables of Richard Brent,
## which are available at
## ftp://ftp.comlab.ox.ac.uk/pub/Documents/techpapers/Richard.Brent/factors/
##
## More factors of cyclotomic numbers are now available via the FactInt
## package. This should be cleaned up.
##
InstallFlushableValue( Primes2, [
10047871, 10567201, 10746341, 12112549, 12128131, 12207031, 12323587,
12553493, 12865927, 13097927, 13264529, 13473433, 13821503, 13960201,
14092193, 14597959, 15216601, 15790321, 16018507, 18837001, 20381027,
20394401, 20515111, 20515909, 21207101, 21523361, 22253377, 22366891,
22996651, 23850061, 25781083, 26295457, 28325071, 28878847, 29010221,
29247661, 29423041, 29866451, 32234893, 32508061, 36855109, 41540861,
42521761, 43249589, 44975113, 47392381, 47763361, 48544121, 48912491,
49105547, 49892851, 51457561, 55527473, 56409643, 56737873, 59302051,
59361349, 59583967, 60816001, 62020897, 63512437, 65628751, 69566521,
75068993, 76066181, 85280581, 93507247, 96656723, 97685839,
106431697, 107367629, 109688713, 110211473, 112901153, 119782433, 127540261,
134818753, 134927809, 136151713, 147300841, 155072369, 160465489, 164511353,
177237331, 183794551, 184481113, 190295821, 190771747, 193707721, 195019441,
202029703, 206244761, 212601841, 212885833, 228511817, 231769777, 234750601,
272010961, 280314943, 283763713, 297315901, 305175781, 308761441, 319020217,
359390389, 407865361, 420778751, 424256201, 432853009, 457315063, 466344409,
510810301, 515717329, 527093491, 529510939, 536903681, 540701761, 550413361,
603926681, 616318177, 632133361, 715827883, 724487149, 745988807, 763539787,
815702161, 834019001, 852133201, 857643277, 879399649, 909139159,
1001523179, 1036745531, 1065264019, 1106131489, 1169382127, 1390636259,
1503418321, 1527007411, 1636258751, 1644512641, 1743831169, 1824179209,
1824726041, 1826934301, 1866013003, 1990415149, 2127357527, 2127431041,
2147483647, 2238236249, 2316281689, 2413941289, 2481791513, 2550183799,
2576743207, 2664097031, 2767631689, 2903110321, 2931542417, 3021012311,
3158528101, 3173389601, 3357897971, 3652120847, 4011586307, 4058036683,
4278255361, 4375578271, 4562284561, 4649919401, 4698932281, 4795973261,
4885168129, 5960555749, 6622733113, 6630274723, 6809710909, 6860024417,
7068569257, 7151459701, 7484047069, 7685542369, 7830118297, 7866608083,
8209475377, 8831418697, 9598959833,
10879733611, 11368765063, 11898664849, 12447002677, 13455809771, 13564461457,
13841169553, 13971969971, 14425532687, 15085812853, 15768033143, 15888756269,
16055056483, 16148168401, 17056050293, 17154094481, 17189128703, 19707683773,
22434744889, 23140471537, 23535794707, 24127552321, 25194773531, 25480398173,
25829691707, 25994736109, 27669118297, 27989941729, 28086211607, 30327152671,
32952799801, 33057806959, 35532364099, 39940132241, 43872038849, 45076044553,
47072139617, 50150933101, 54410972897, 56625998353, 56770350869, 60726444167,
61070817601, 62983048367, 65247271367, 69238518539, 70845409351, 76831835389,
77158673929, 77192844961, 78009515593, 83960385389, 86950696619, 87423871753,
88959882481, 99810171997,
115868130379, 125096112091, 127522693159, 128011456717, 128653413121,
129924628343, 131105292137, 152587500001, 158822951431, 159248456569,
164504919713, 165768537521, 168749965921, 213657222007, 229890275929,
241931001601, 269089806001, 282429005041, 301077652751, 332207361361,
368592716837, 374857981681, 386478495679, 392038110671, 402011881627,
441019876741, 447600088289, 461587317509, 487824887233, 531968664833,
555915824341, 593554036769, 598761682261, 641625222857, 654652168021,
761838257287, 810221830361, 840139875599, 918585913061,
1030330938209, 1047623475541, 1113491139767, 1133836730401, 1273880539247,
1284297400723, 1408429185797, 1534179947851, 1628744948329, 1654058017289,
1759217765581, 1856458657451, 2098303812601, 2454335007529, 2481357870461,
2549755542947, 2663568851051, 2738039191709, 2879347902817, 2932031007403,
3138426605161, 3203431780337, 3421169496361, 3740221981231, 4363953127297,
4432676798593, 4446437759531, 4534166740403, 4981857697937, 5625767248687,
6090817323763, 6493405343627, 6713103182899, 6740339310641, 7432339208719,
8090594434231, 8157179360521, 8737481256739, 8868050880709, 9361973132609,
9468940004449, 9857737155463,
10052678938039, 10979607179423, 13952598148481, 15798461357509,
15919793462773, 17175865789597, 18158209813151, 22125996444329,
22542470482159, 22735632934561, 23161037562937, 23792163643711,
24517014940753, 24587411156281, 28059810762433, 29078814248401,
31280679788951, 31479823396757, 32688470798197, 33232924804801,
42272797713043, 44479210368001, 45920153384867, 49971617830801,
57583418699431, 62911130477521, 67280421310721, 70601370627701,
71316922984999, 83181652304609, 89620825374601, 94404837727799,
95052547721497,
110133112994711, 140737471578113, 145295143558111, 150224123975857,
160026187716961, 204064664440913, 205367807127911, 242099935645987,
270547105429567, 303567967057423, 332584516519201, 434502978835771,
475384700124973, 500805747488153, 520518327319589, 560088668384411,
608459012088799, 637265428480297, 643170158708221, 707179356161321,
866802946161469, 926510094425921, 990643452963163,
1034150930241911, 1066818132868207, 1120648576818041, 1357105535093947,
1416258521793067, 1587855697992791, 1611479891519807, 1628413557556843,
1900857799450121, 1958423494433591, 2134387368610417, 2646507710984041,
2649263870814793, 2752135920929651, 2864226125209369, 3208002856867129,
4557772677741827, 4889988840047743, 5420506947192709, 6957533874046531,
9460375336977361, 9472026608675509,
11264087821629961, 12557612956332313, 13722816749522711, 14436295738510501,
18584774046020617, 18624275418445601, 20986207825565581, 21180247636732981,
22666879066355177, 27145365052629449, 32233368385529653, 39392783590192547,
46329453543600481, 50544702849929377, 59509429687890001, 60081451169922001,
70084436712553223, 76394148218203559, 77001139434480073, 79787519018560501,
96076791871613611,
133088039373662309, 144542918285300809, 145171177264407947,
153560376376050799, 166003607842448777, 177722253954175633,
196915704073465747, 316825425410373433, 341117531003194129,
380808546861411923, 489769993189671059, 538953023961943033,
581283643249112959, 617886851384381281, 625552508473588471,
645654335737185721, 646675035253258729, 658812288653553079,
768614336404564651, 862970652262943171, 909456847814334401,
1100876018364883721, 1195857367853217109, 1245576402371959291,
1795918038741070627, 2192537062271178641, 2305843009213693951,
2312581841562813841, 2461243576713869557, 2615418118891695851,
2691614274040036601, 3011347479614249131, 3358335487319458201,
3421093417510114543, 3602372010909260861, 3747607031112307667,
3999088279399464409, 4710883168879506001, 5079304643216687969,
5559917315850179173, 5782172113400990737, 6106505825833677713,
6115909044841454629, 9213624084535989031, 9520972806333758431,
10527743181888260981, 14808607715315782481, 18446744069414584321,
26831423036065352611, 32032215596496435569, 34563155350221618511,
36230454570129675721, 58523123221688392679, 60912916512835721519,
82064241848634269407, 86656268566282183151, 87274497124602996457,
105668621839502584913, 157571957584602258799, 162715052426691233701,
172827552198815888791, 195489390796456327201, 240031591394168814433,
266834785363181152127, 344120456368919234899, 358475907408445923469,
846041103974872866961,
2519545342349331183143, 3658524738455131951223, 3793685967117002179453,
3976656429941438590393, 5439042183600204290159, 8198241112969626815581,
11600321878916922053491, 12812432238302009985937, 17551032119981679046729,
18489605314740987765913, 27665283091695977275201, 42437717969530394595211,
57912614113275649087721, 61654440233248340616559, 63681511996418550459487,
105293313660391861035901, 155285743288572277679887, 201487636602438195784363,
231669654363683130095909, 235169662395069356312233, 402488219476647465854701,
535347624791488552837151, 604088623657497125653141, 870035986098720987332873,
950996059627210897943351,
1412900479108654932024439, 1431185706701868962383741,
2047572230657338751575051, 2048568835297380486760231,
2741672362528725535068727, 3042645634792541312037847,
3745603812007166116831643, 4362139336229068656094783,
4805345109492315767981401, 5042939439565996049162197,
7289088383388253664437433, 8235109336690846723986161,
9680647790568589086355559, 9768997162071483134919121,
9842332430037465033595921,
11053036065049294753459639, 11735415506748076408140121,
13842607235828485645766393, 17499733663152976533452519,
26273701844015319144827917, 75582488424179347083438319,
88040095945103834627376781,
100641220283951395639601683, 140194179307171898833699259,
207617485544258392970753527, 291280009243618888211558641,
303309617049998388989376043, 354639323684545612988577649,
618970019642690137449562111, 913242407367610843676812931,
7222605228105536202757606969, 7248808599285760001152755641,
8170509011431363408568150369, 8206973609150536446402438593,
9080418348371887359375390001,
14732265321145317331353282383, 15403468930064931175264655869,
15572244900182528777225808449, 18806327041824690595747113889,
21283620033217629539178799361, 37201708625305146303973352041,
42534656091583268045915654719, 48845962828028421155731228333,
123876132205208335762278423601, 134304196845099262572814573351,
172974812463239310024750410929, 217648180992721729506406538251,
227376585863531112677002031251,
1786393878363164227858270210279, 2598696228942460402343442913969,
2643999917660728787808396988849, 3340762283952395329506327023033,
5465713352000770660547109750601,
28870194250662203210437116612769, 70722308812401674174993533367023,
78958087694609321439660131899631, 88262612316754526107621113329689,
162259276829213363391578010288127, 163537220852725398851434325720959,
177635683940025046467781066894531,
2679895157783862814690027494144991, 3754733257489862401973357979128773,
5283012903770196631383821046101707, 5457586804596062091175455674392801,
10052011757370829033540932021825161, 11419697846380955982026777206637491,
38904276017035188056372051839841219,
1914662449813727660680530326064591907, 7923871097285295625344647665764672671,
9519524151770349914726200576714027279,
10350794431055162386718619237468234569,
170141183460469231731687303715884105727,
1056836588644853738704557482552056406147,
6918082374901313855125397665325977135579,
235335702141939072378977155172505285655211,
360426336941693434048414944508078750920763,
1032670816743843860998850056278950666491537,
1461808298382111034194027645506019619578037,
79638304766856507377778616296087448490695649,
169002145064468556765676975247413756542145739,
8166146875847876762859119015147004762656450569,
18607929421228039083223253529869111644362732899,
33083146850190391025301565142735000331370209599,
138497973518827432485604572537024087153816681041,
673267426712748387612994804392183645147042355211,
1489459109360039866456940197095433721664951999121,
4884164093883941177660049098586324302977543600799,
466345922275629775763320748688970211803553256223529,
26828803997912886929710867041891989490486893845712448833,
153159805660301568024613754993807288151489686913246436306439,
1051153199500053598403188407217590190707671147285551702341089650185945215953
] );
IsSSortedList( Primes2 );
# for 41^41-1
ADD_SET(Primes2, 5926187589691497537793497756719);
# for 89^89-1
ADD_SET(Primes2, 4330075309599657322634371042967428373533799534566765522517);
# for 97^97-1
ADD_SET(Primes2, 549180361199324724418373466271912931710271534073773);
ADD_SET(Primes2, 85411410016592864938535742262164288660754818699519364051241927961077872028620787589587608357877);
InstallFlushableValue(ProbablePrimes2, []);
IsSSortedList( ProbablePrimes2 );
#############################################################################
##
#F BestQuoInt( <n>, <m> )
##
## `BestQuoInt' returns the best quotient <q> of the integers <n> and <m>.
## This is the quotient such that `<n>-<q>\*<m>' has minimal absolute value.
## If there are two quotients whose remainders have the same absolute value,
## then the quotient with the smaller absolute value is choosen.
##
InstallGlobalFunction(BestQuoInt,function ( n, m )
if 0 <= m and 0 <= n then
return QuoInt( n + QuoInt( m - 1, 2 ), m );
elif 0 <= m then
return QuoInt( n - QuoInt( m - 1, 2 ), m );
elif 0 <= n then
return QuoInt( n - QuoInt( m + 1, 2 ), m );
else
return QuoInt( n + QuoInt( m + 1, 2 ), m );
fi;
end);
#############################################################################
##
#F ChineseRem( <moduli>, <residues> ) . . . . . . . . . . chinese remainder
##
InstallGlobalFunction(ChineseRem,function ( moduli, residues )
local i, c, l, g;
# combine the residues modulo the moduli
i := 1;
c := residues[1];
l := moduli[1];
while i < Length(moduli) do
i := i + 1;
g := Gcdex( l, moduli[i] );
if g.gcd <> 1 and (residues[i]-c) mod g.gcd <> 0 then
Error("the residues must be equal modulo ",g.gcd);
fi;
c := l * (((residues[i]-c) / g.gcd * g.coeff1) mod moduli[i]) + c;
l := moduli[i] / g.gcd * l;
od;
# reduce c into the range [0..l-1]
c := c mod l;
return c;
end);
#############################################################################
##
#F CoefficientsQadic( <i>, <q> ) . . . . . . <q>-adic representation of <i>
##
InstallMethod( CoefficientsQadic, "for two integers",
true, [ IsInt, IsInt ], 0,
function( i, q )
local v;
if q <= 1 then
Error("2nd argument of CoefficientsQadic should be greater than 1\n");
fi;
if i < 0 then
# if FR package is loaded and supplies an implementation
# to return a periodic list for negative i
TryNextMethod();
fi;
# represent the integer <i> as <q>-adic number
v := [];
while i > 0 do
Add( v, RemInt( i, q ) );
i := QuoInt( i, q );
od;
return v;
end);
#############################################################################
##
#F CoefficientsMultiadic( ints, int )
##
InstallGlobalFunction(CoefficientsMultiadic, function( ints, int )
local vec, i;
vec := List( ints, x -> 0 );
for i in Reversed( [1..Length(ints)] ) do
vec[i] := RemInt( int, ints[i] );
int := QuoInt( int, ints[i] );
od;
return vec;
end);
#############################################################################
##
#F DivisorsInt( <n> ) . . . . . . . . . . . . . . . divisors of an integer
##
BindGlobal("DivisorsIntCache",
List([[1],[1,2],[1,3],[1,2,4],[1,5],[1,2,3,6],[1,7]], Immutable));
InstallGlobalFunction(DivisorsInt,function ( n )
local divisors, factors, divs;
# make <n> it nonnegative, handle trivial cases, and get prime factors
if n < 0 then n := -n; fi;
if n = 0 then Error("DivisorsInt: <n> must not be 0"); fi;
if n <= Length(DivisorsIntCache) then
return DivisorsIntCache[n];
fi;
factors := FactorsInt( n );
# recursive function to compute the divisors
divs := function ( i, m )
if Length(factors) < i then return [ m ];
elif m mod factors[i] = 0 then return divs(i+1,m*factors[i]);
else return Concatenation( divs(i+1,m), divs(i+1,m*factors[i]) );
fi;
end;
divisors := divs( 1, 1 );
Sort( divisors );
return Immutable(divisors);
end);
#############################################################################
##
#F FactorsRho( <n>, <inc>, <cluster>, <limit> ) Pollards rho factorization
##
## `FactorsInt' does trial divisions by the primes less than 1000 to detect
## all composites with a factor less than 1000 and primes less than 1000000.
## After that it calls `FactorsRho(<n>,1,16,8192)' to do the hard work.
##
## `FactorsRho' will return a list of factors and a list of composite
## number. Usually `FactorsInt' factors integers with prime factors
## $\<1000$ faster. However for integers with no factor $\<1000$
## `FactorsRho' will be faster.
##
## `FactorsRho' uses Pollards $\rho$ method to factor the integer $n = p q$.
## For a small simple example lets assume we want to factor $667 = 23 * 29$.
## `FactorsRho' first calls `IsPrimeInt' to avoid trying to factor a prime.
##
## Then it uses the sequence defined by $x_0=1, x_{i+1}=(x_i^2+1)$ mod $n$.
## In our example this is $1, 2, 5, 26, 10, 101, 197, 124, 36, 630, .. $.
##
## Modulo $p$ it takes on at most $p-1$ different values, thus it eventually
## becomes recurrent, usually this happens after roughly $2 \sqrt{p}$ steps.
## In our example modulo 23 we get $1, 2, 5, 3, 10, 9, 13, 9, 13, 9, .. $.
##
## Thus there exist pairs $i, j$ such that $x_i = x_j$ mod $p$, i.e., such
## that $p$ divides $Gcd( n, x_j-x_i )$. With a bit of luck no other factor
## of $n$ divides $x_j - x_i$ so we find $p$ if we know such a pair. In our
## example $5, 7$ is the first pair, $x_7-x_5=23$, and $Gcd(667,23) = 23$.
##
## Now it is too expensive to check all pairs, but there also must be pairs
## of the form $2^i-1, j$ with $3*2^{i-1} <= j < 4*2^{i-1}$. In our example
## $7, 13$ is the first such pair, $x_13-x_7=506$, and $Gcd(667,506) = 23$.
##
## Thus by taking the gcds of $n$ and $x_j-x_i$ for such pairs, we will find
## the factor $p$ after approximately $2 \sqrt{p} \<= 2 \sqrt^4{n}$ steps.
##
## If $Gcd( n, x_j - x_i )$ is not a prime `FactorsRho' will call itself
## recursivly with a different value for <inc>, i.e., it will try to factor
## the gcd using a different sequence $x_{i+1} = (x_i^2 + inc)$ mod $n$.
##
## Since the gcd computations are by far the most time consuming part of the
## algorithm one can save time by clustering differences and computing the
## gcd only every <cluster> iteration. This slightly increases the chance
## that a gcd is composite, but reduces the runtime by a large amount.
##
## Finally `FactorsRho' accepts an argument <limit> which is the number of
## iterations performed by `FactorsRho' before giving up. The default value
## is 8192 which corresponds to a few minutes while guaranteing that all
## prime factors less than $10^6$ and most less than $10^9$ are found.
##
## Better descriptions of the algorithm and related topics can be found in:
## J. Pollard, A Monte Carlo Method for Factorization, BIT 15, 1975, 331-334
## R. Brent, An Improved Monte Carlo Method for Fact., BIT 20, 1980, 176-184
## D. Knuth, Seminumerical Algorithms (TACP II), AddiWesl, 1973, 369-371
##
FactorsRho := function ( n, inc, cluster, limit )
local i, sign, factors, composite, x, y, k, z, g, tmp,
IsPrimeOrProbablyPrimeInt;
# make $n$ positive and handle trivial cases
sign := 1;
if n < 0 then sign := -sign; n := -n; fi;
if n < 4 then return [ [ sign * n ], [] ]; fi;
factors := [];
composite := [];
while n mod 2 = 0 do Add( factors, 2 ); n := n / 2; od;
while n mod 3 = 0 do Add( factors, 3 ); n := n / 3; od;
if ValueOption("UseProbabilisticPrimalityTest") = true
then IsPrimeOrProbablyPrimeInt := IsProbablyPrimeInt;
else IsPrimeOrProbablyPrimeInt := IsPrimeInt; fi;
if IsPrimeOrProbablyPrimeInt(n) then Add( factors, n ); n := 1; fi;
# initialize $x_0$
x := 1; z := 1; i := 0;
# loop until we have factored $n$ completely or run out of patience
while 1 < n and 2^i <= limit do
# $y = x_{2^i-1}$
y := x; i := i + 1;
# $x_{2^i}, .., x_{3*2^{i-1}-1}$ need not be compared to $x_{2^i-1}$
for k in [1..2^(i-1)] do
x := (x^2 + inc) mod n;
od;
# compare $x_{3*2^{i-1}}, .., x_{4*2^{i-1}-1}$ with $x_{2^i-1}$
for k in [1..2^(i-1)] do
x := (x^2 + inc) mod n;
z := z * (x - y) mod n;
# from time to time compute the gcd
if k mod cluster = 0 then
g := GcdInt( n, z );
# if it is > 1 we have found a factor which need not be prime
if g > 1 then
tmp := FactorsRho(g,inc+1,QuoInt(cluster+1,2),limit);
factors := Concatenation( factors, tmp[1] );
composite := Concatenation( composite, tmp[2] );
n := n / g;
if IsPrimeOrProbablyPrimeInt(n) then
Add( factors, n ); n := 1;
fi;
fi;
fi;
od;
od;
# add <n> to the list of composite numbers
if 1 < n then
Add( composite, n );
fi;
# sort the list of factors and composite numbers and return it
Sort(factors);
Sort(composite);
if 0 < Length(factors) then
factors[1] := sign * factors[1];
else
composite[1] := sign * composite[1];
fi;
return [ factors, composite ];
end;
MakeReadOnlyGlobal( "FactorsRho" );
#############################################################################
##
#F FactorsInt( <n> ) . . . . . . . . . . . . . . prime factors of an integer
#F FactorsInt( <n> : RhoTrials := <trials>)
#F FactorsInt( <n> : quiet)
##
## In the second form, FactorsRho is called with a limit of <trials>
## on the number of trials is performs. The default is 8192.
##
## The option `quiet' makes the function return even if the `rho'
## factorization failed and return the factorization found so far.
##
InstallGlobalFunction(FactorsInt,function ( n )
local sign, factors, p, tmp, n_orig, len, rt, tmp2;
n_orig := n;
# make $n$ positive and handle trivial cases
sign := 1;
if n < 0 then sign := -sign; n := -n; fi;
if n < 4 then return [ sign * n ]; fi;
factors := [];
# do trial divisions by the primes less than 1000
# faster than anything fancier because $n$ mod <small int> is very fast
for p in Primes do
while n mod p = 0 do Add( factors, p ); n := n / p; od;
if n < (p+1)^2 and 1 < n then Add(factors,n); n := 1; fi;
if n = 1 then factors[1] := sign*factors[1]; return factors; fi;
od;
# do trial divisions by known primes
for p in Primes2 do
while n mod p = 0 do Add( factors, p ); n := n / p; od;
if p^2 > n then break; fi;
if n = 1 then factors[1] := sign*factors[1]; return factors; fi;
od;
# do trial divisions by known probable primes (and issue warning, if found)
tmp := [];
for p in ProbablePrimes2 do
while n mod p = 0 do
AddSet(tmp, p);
Add( factors, p );
n := n / p;
od;
if n = 1 then break; fi;
od;
if Length(tmp) > 0 then
Info(InfoPrimeInt, 1 ,
"FactorsInt: used the following factor(s) which are probably primes:");
for p in tmp do
Info(InfoPrimeInt, 1, " ", p);
od;
fi;
if n = 1 then factors[1] := sign*factors[1]; return factors; fi;
# handle perfect powers
p := SmallestRootInt( n );
if p < n then
while 1 < n do
Append( factors, FactorsInt(p) );
n := n / p;
od;
Sort( factors );
factors[1] := sign * factors[1];
return factors;
fi;
# let `FactorsRho' do the work
if ValueOption("RhoTrials") <> fail then
tmp := FactorsRho( n, 1, 16, ValueOption("RhoTrials") );
else
tmp := FactorsRho( n, 1, 16, 8192 );
fi;
if 0 < Length(tmp[2]) then
if ValueOption("quiet")<>true then
len := Length(tmp[2]);
if LoadPackage("FactInt") = true then
## # in general cases we should proceed with the found factors:
## while len > 0 do
## Append(tmp[1], Factors(tmp[2][len]));
## Unbind(tmp[2][len]);
## len := len-1;
## od;
# but this way we miss that FactInt can detect certain numbers of
# special shape for which it uses lookup tables, therefore for the
# moment:
return Factors(n_orig);
else
Error( "sorry, cannot factor ", tmp[2],
"\ntype 'return;' to try again with a larger number of trials in\n",
"FactorsRho (or use option 'RhoTrials')\n");
if ValueOption("RhoTrials") <> fail then
rt := 5 * ValueOption("RhoTrials");
else
rt := 5 * 8192;
fi;
while len > 0 do
tmp2 := FactorsInt(tmp[2][len]: RhoTrials := rt);
Append(tmp[1], tmp2);
Unbind(tmp[2][len]);
len := len-1;
od;
fi;
else
factors := Concatenation( factors, tmp[2] );
fi;
fi;
factors := Concatenation( factors, tmp[1] );
Sort( factors );
factors[1] := sign * factors[1];
return factors;
end);
#############################################################################
##
#F PrimeDivisors( <n> ) . . . . . . . . . . . . . . list of prime divisors
##
## delegating to FactorsInt
##
InstallMethod( PrimeDivisors, "for integer", [ IsInt ], function(n)
if n = 0 then
Error("PrimeDivisors: 0 has an infinite number of prime divisors.");
return;
fi;
if n < 0 then
n := -n;
fi;
if n = 1 then
return [];
fi;
return Set(FactorsInt(n));
end);
#############################################################################
##
#M PartialFactorization( <n>, <effort> ) . . . . . . . . . . generic method
##
InstallMethod( PartialFactorization,
"generic method", true, [ IsInt, IsInt ], 0,
function ( n, effort )
local N, sign, factors, p, k, root, rootfactors, rhotrials,
tmp, CheckAndSortFactors;
CheckAndSortFactors := function ( )
factors := SortedList(factors);
factors[1] := sign*factors[1];
if Product(factors) <> N
then Error("PartialFactorization: Internal error, wrong result!"); fi;
end;
N := n;
if effort < 0 then effort := 5; fi;
# make $n$ positive and handle trivial cases
sign := 1;
if n < 0 then sign := -sign; n := -n; fi;
if n < 4 then return [ sign * n ]; fi;
factors := [];
# least effort: do trial divisions by the primes less than 100
if effort = 0 then
for p in Primes{[1..25]} do
while n mod p = 0 do Add( factors, p ); n := n / p; od;
if n < (p+1)^2 and 1 < n then Add(factors,n); n := 1; fi;
if n = 1 then CheckAndSortFactors(); return factors; fi;
od;
Add(factors,n); CheckAndSortFactors(); return factors;
fi;
# do trial divisions by the primes less than 1000
# faster than anything fancier because $n$ mod <small int> is very fast
for p in Primes do
while n mod p = 0 do Add( factors, p ); n := n / p; od;
if n < (p+1)^2 and 1 < n then Add(factors,n); n := 1; fi;
if n = 1 then CheckAndSortFactors(); return factors; fi;
od;
if effort <= 1 then
Add(factors,n); CheckAndSortFactors();
return factors;
fi;
# do trial divisions by known primes
for p in Primes2 do
while n mod p = 0 do Add( factors, p ); n := n / p; od;
if n = 1 then CheckAndSortFactors(); return factors; fi;
od;
# do trial divisions by known probable primes
tmp := [];
for p in ProbablePrimes2 do
while n mod p = 0 do
AddSet(tmp, p);
Add( factors, p );
n := n / p;
od;
if n = 1 then break; fi;
od;
if n = 1 then CheckAndSortFactors(); return factors; fi;
# handle perfect powers
root := SmallestRootInt( n );
if root < n then
rootfactors := PartialFactorization(root,effort);
k := LogInt(n,root);
rootfactors := Concatenation(List([1..k],i->rootfactors));
factors := SortedList(Concatenation(factors,rootfactors));
CheckAndSortFactors();
return factors;
fi;
if effort = 2 or IsProbablyPrimeInt(n) then
Add(factors,n); CheckAndSortFactors(); return factors;
fi;
# if effort >= 3, use `FactorsRho'
if ValueOption("RhoTrials") <> fail then
tmp := FactorsRho(n,1,16,ValueOption("RhoTrials"):
UseProbabilisticPrimalityTest);
else
if effort = 3 then rhotrials := 256;
elif effort = 4 then rhotrials := 2048;
elif effort >= 5 then rhotrials := 8192; fi;
tmp := FactorsRho(n,1,16,rhotrials:UseProbabilisticPrimalityTest);
fi;
factors := SortedList(Concatenation(factors,tmp[1],tmp[2]));
CheckAndSortFactors();
return factors;
end );
#############################################################################
##
#M PartialFactorization( <n> ) . . . . . partial factorization of an integer
##
InstallOtherMethod( PartialFactorization,
"for integers", true, [ IsInt ], 0,
n -> PartialFactorization(n,5) );
#############################################################################
##
#F Gcdex( <m>, <n> ) . . . . . . . . . . greatest common divisor of integers
##
InstallGlobalFunction(Gcdex,function ( m, n )
local f, g, h, fm, gm, hm, q;
if 0 <= m then f:=m; fm:=1; else f:=-m; fm:=-1; fi;
if 0 <= n then g:=n; gm:=0; else g:=-n; gm:=0; fi;
while g <> 0 do
q := QuoInt( f, g );
h := g; hm := gm;
g := f - q * g; gm := fm - q * gm;
f := h; fm := hm;
od;
if n = 0 then
return rec( gcd := f, coeff1 := fm, coeff2 := 0,
coeff3 := gm, coeff4 := 1 );
else
return rec( gcd := f, coeff1 := fm, coeff2 := (f - fm * m) / n,
coeff3 := gm, coeff4 := (0 - gm * m) / n );
fi;
end);
#############################################################################
##
#F IsEvenInt( <n> ) . . . . . . . . . . . . . . . . . . test if <n> is even
##
InstallGlobalFunction( IsEvenInt, n -> n mod 2 = 0 );
#############################################################################
##
#F IsOddInt( <n> ) . . . . . . . . . . . . . . . . . . . test if <n> is odd
##
InstallGlobalFunction( IsOddInt, n -> n mod 2 = 1 );
#############################################################################
##
#F IsPrimeInt( <n> ) . . . . . . . . . . . . . . . . . . . test for a prime
##
## `IsPrimeInt' does trial divisions by the primes less than 1000 to detect
## composites with a factor less than 1000 and primes less than 1000000.
##
## `IsPrimeInt' then checks that $n$ is a strong pseudoprime to the base 2.
## This uses Fermats theorem which says $2^{n-1}=1$ mod $n$ for a prime $n$.
## If $2^{n-1}\<>1$ mod $n$, $n$ is composite, `IsPrimeInt' returns `false'.
## There are composite numbers for which $2^{n-1}=1$, but they are seldom.
##
## Then `IsPrimeInt' checks that $n$ is a Lucas pseudoprime for $p$, choosen
## so that the discriminant $d=p^2/4-1$ is an quadratic nonresidue mod $n$.
## I.e., `IsPrimeInt' takes the root $a = p/2+\sqrt{d}$ of $x^2 - px + 1$ in
## the ring $Z_n[\sqrt{d}] and computes the traces of $a^n$ and $a^{n+1}$.
## If $n$ is a prime, this ring is the field of order $n^2$ and raising to
## the $n$th power is conjugation, so $trace(a^n)=p$ and $trace(a^{n+1})=2$.
## However, these identities hold only for extremly few composite numbers.
##
## Note that this test for $trace(a^n) = p$ and $trace(a^{n+1}) = 2$ is
## usually formulated using the Lucas sequences $U_k = (a^k-b^k)/(a-b)$ and
## $V_k = (a^k+b^k)=trace(a^k)$, where one tests $U_{n+1} = 0, V_{n+1} = 2$.
## However, the trace test is equivalent and requires fewer multiplications.
## Thanks to Daniel R. Grayson (dan@symcom.math.uiuc.edu) for telling me.
##
## `IsPrimeInt' can be shown to return the correct answer for $n < 10^{13}$,
## by testing against R.G.E. Pinch's list of all pseudoprimes to base 2 less
## than $10^{13}$ ('ftp://dpmms.cam.ac.uk/pub/rgep/PSP/psp13.gz').
##
## Better descriptions of the algorithm and related topics can be found in:
## G. Miller, cf. Algorithms and Complexity ed. Traub, AcademPr, 1976, 35-36
## C. Pomerance et.al., Pseudoprimes to 25*10^9, MathComp 35 1980, 1003-1026
## D. Knuth, Seminumerical Algorithms (TACP II), AddiWesl, 1973, 378-380
## G. Gonnet, Heuristic Primality Testing, Maple Newsletter 4, 1989, 36-38
## R. Baillie, S. Wagstaff, Lucas Pseudoprimes, MathComp 35 1980, 1391-1417
## R. Pinch, Some Primality Testing Algorithms, Notic. AMS 9 1993, 1203-1210
##
# a non-recursive version, nowadays the algorithm can be applied to
# numbers with many thousand digits
InstallGlobalFunction(TraceModQF, function ( p, k, n )
local kb, trc, i;
kb := [];
while k <> 1 do
if k mod 2 = 0 then
k := k/2;
Add(kb, 0);
else
k := (k+1)/2;
Add(kb, 1);
fi;
od;
trc := [p, 2];
i := Length(kb);
while i >= 1 do
if kb[i] = 0 then
trc := [ (trc[1]^2 - 2) mod n, (trc[1]*trc[2] - p) mod n ];
else
trc := [ (trc[1]*trc[2] - p) mod n, (trc[2]^2 - 2) mod n ];
fi;
i := i-1;
od;
return trc;
end);
## returns `false' for proven composite, `true' for proven prime and
## `fail' for probable prime.
BindGlobal( "IsProbablyPrimeIntWithFail", function( n )
local p, e, o, x, i;
# make $n$ positive and handle trivial cases
if n < 0 then n := -n; fi;
if n in Primes then return true; fi;
if n in Primes2 then return true; fi;
if n in ProbablePrimes2 then return fail; fi;
if n <= 1000 then return false; fi;
# do trial divisions by the primes less than 1000
# faster than anything fancier because $n$ mod <small int> is very fast
for p in Primes do
if n mod p = 0 then return false; fi;
if n < (p+1)^2 then AddSet( Primes2, n ); return true; fi;
od;
# do trial division by the other known primes
for p in Primes2 do
if n mod p = 0 then return false; fi;
od;
# do trial division by the other known probable primes
for p in ProbablePrimes2 do
if n mod p = 0 then return false; fi;
od;
# find $e$ and $o$ odd such that $n-1 = 2^e * o$
e := 0; o := n-1; while o mod 2 = 0 do e := e+1; o := o/2; od;
# look at the seq $2^o, 2^{2 o}, 2^{4 o}, .., 2^{2^e o}=2^{n-1}$
x := PowerModInt( 2, o, n );
i := 0;
while i < e and x <> 1 and x <> n-1 do
x := x * x mod n;
i := i + 1;
od;
# if it is not of the form $.., -1, 1, 1, ..$ then $n$ is composite
if not (x = n-1 or (i = 0 and x = 1)) then
return false;
fi;
## # there are no strong pseudo-primes to base 2 smaller than 2047
## FL: never used
## if n < 2047 then
## AddSet( Primes2, n );
## return true;
## fi;
# make sure that $n$ is not a perfect power (especially not a square)
if SmallestRootInt(n) < n then
return false;
fi;
# find a quadratic nonresidue $d = p^2/4-1$ mod $n$
p := 2; while Jacobi( p^2-4, n ) <> -1 do p := p+1; od;
# for a prime $n$ the trace of $(p/2+\sqrt{d})^n$ must be $p$
# and the trace of $(p/2+\sqrt{d})^{n+1}$ must be 2
if TraceModQF( p, n+1, n ) = [ 2, p ] then
# n < 10^13 fulfilling the tests so far are prime
if n < 10^13 then
return true;
else
return fail;
fi;
fi;
# $n$ is not a prime
return false;
end);
InstallGlobalFunction(IsPrimeIntOld,function ( n )
local res;
res := IsProbablyPrimeIntWithFail(n);
if res = false then
return false;
else
if res = fail then
Info(InfoPrimeInt, 1,
"IsPrimeInt: probably prime, but not proven: ", n);
AddSet( ProbablePrimes2, n );
else
AddSet( Primes2, n );
fi;
return true;
fi;
end);
#############################################################################
##
#F IsPrimePowerInt( <n> ) . . . . . . . . . . . test for a power of a prime
##
InstallGlobalFunction( IsPrimePowerInt,
n -> IsPrimeInt( SmallestRootInt( n ) ) );
#############################################################################
##
#F LcmInt( <m>, <n> ) . . . . . . . . . . least common multiple of integers
##
InstallGlobalFunction(LcmInt,function ( n, m )
if m = 0 and n = 0 then
return 0;
else
return AbsInt( m / GcdInt( m, n ) * n );
fi;
end);
#############################################################################
##
#F LogInt( <n>, <base> ) . . . . . . . . . . . . . . logarithm of an integer
##
InstallGlobalFunction(LogInt,function ( n, base )
local log, p;
# check arguments
if not IsInt(n) or n <= 0 then
Error("<n> must be a positive integer");
fi;
if not IsInt(base) or base <= 1 then
Error("<base> must be an integer greater than 1");
fi;
# `log(b)' returns $log_b(n)$ and divides `n' by `b^log(b)'
## log := function ( b )
## local i;
## if b > n then return 0; fi;
## i := log( b^2 );
## if b > n then return 2 * i;
## else n := QuoInt( n, b ); return 2 * i + 1; fi;
## end;
##
## return log( base );
if n < base then
return 0;
elif base = 2 then
return Log2Int(n);
elif base = 8 then
return QuoInt(Log2Int(n), 3);
elif base = 16 then
return QuoInt(Log2Int(n), 4);
elif IsSmallIntRep(n) then
log := 1;
p := base * base;
while p <= n do
log := log + 1;
p := p * base;
od;
return log;
elif base = 10 then
log := QuoInt(Log2Int(n) * 10^6 , 3321929);
return log + LogInt(QuoInt(n, 10^log), 10);
else
log := QuoInt(Log2Int(n), Log2Int(base)+1);
if log = 0 then
log := 1;
fi;
return log + LogInt(QuoInt(n, base^log), base);
fi;
end);
#############################################################################
##
#F NextPrimeInt( <n> ) . . . . . . . . . . . . . . . . . . next larger prime
##
InstallGlobalFunction(NextPrimeInt,function ( n )
if -3 = n then n := -2;
elif -3 < n and n < 2 then n := 2;
elif n mod 2 = 0 then n := n+1;
else n := n+2;
fi;
while not IsPrimeInt(n) do
if n mod 6 = 1 then n := n+4;
else n := n+2;
fi;
od;
return n;
end);
#############################################################################
##
#F PowerModInt(<r>,<e>,<m>) . . . . . . power of one integer modulo another
##
InstallGlobalFunction(PowerModInt,function ( r, e, m )
local pow, f;
# handle special cases
if m = 1 then
return 0;
elif e = 0 then
return 1;
fi;
# reduce `r' initially
r := r mod m;
# if `e' is negative then invert `r' modulo `m' with Euclids algorithm
if e < 0 then
r := 1/r mod m;
e := -e;
fi;
# now use the repeated squaring method (right-to-left)
pow := 1;
f := 2 ^ (LogInt( e, 2 ) + 1);
while 1 < f do
pow := (pow * pow) mod m;
f := QuoInt( f, 2 );
if f <= e then
pow := (pow * r) mod m;
e := e - f;
fi;
od;
# return the power
return pow;
end);
#############################################################################
##
#F PrevPrimeInt( <n> ) . . . . . . . . . . . . . . . previous smaller prime
##
## `PrevPrimeInt' returns the largest prime which is strictly smaller than
## the integer <n>.
##
InstallGlobalFunction(PrevPrimeInt,function ( n )
if 3 = n then n := 2;
elif -2 < n and n < 3 then n := -2;
elif n mod 2 = 0 then n := n-1;
else n := n-2;
fi;
while not IsPrimeInt(n) do
if n mod 6 = 5 then n := n-4;
else n := n-2;
fi;
od;
return n;
end);
#############################################################################
##
#F PrimePowerInt( <n> ) . . . . . . . . . . . . . . . . prime powers of <n>
##
InstallGlobalFunction(PrimePowersInt,function( n )
local p, pows, lst;
if n = 1 then
return [];
elif n = 0 then
Error( "<n> must be non zero" );
elif n < 0 then
n := -1 * n;
fi;
lst := Factors( Integers, n );
pows := [];
for p in Set( lst ) do
Add( pows, p );
Add( pows, Number( lst, x -> x = p ) );
od;
return pows;
end);
#############################################################################
##
#F RootInt( <n> ) . . . . . . . . . . . . . . . . . . . root of an integer
#F RootInt( <n>, <k> )
##
InstallGlobalFunction(RootInt,function ( arg )
local n, k, r, s, t;
# get the arguments
if Length(arg) = 1 then n := arg[1]; k := 2;
elif Length(arg) = 2 then n := arg[1]; k := arg[2];
else Error("usage: `Root( <n> )' or `Root( <n>, <k> )'");
fi;
# check the arguments and handle trivial cases
if k <= 0 then Error("<k> must be positive");
elif k = 1 then return n;
elif n < 0 and k mod 2 = 0 then Error("<n> must be positive");
elif n < 0 and k mod 2 = 1 then return -RootInt( -n, k );
elif n = 0 then return 0;
elif n <= k then return 1;
fi;
# r is the first approximation, s the second, we need: root <= s < r
r := n; s := 2^( QuoInt( LogInt(n,2), k ) + 1 ) - 1;
# do Newton iterations until the approximations stop decreasing
while s < r do
r := s; t := r^(k-1); s := QuoInt( n + (k-1)*r*t, k*t );
od;
# and thats the integer part of the root
return r;
end);
#############################################################################
##
#F AbsInt( <n> ) . . . . . . . . . . . . . . . absolute value of an integer
##
InstallGlobalFunction( AbsInt, function( n )
if 0 <= n then return n;
else return -n;
fi;
end );
#############################################################################
##
#F AbsoluteValue( <n> )
##
# uses the particular form of AbsInt
InstallMethod(AbsoluteValue,"rationals",true,[IsRat],0,AbsInt);
#############################################################################
##
#F SignInt( <n> ) . . . . . . . . . . . . . . . . . . . sign of an integer
##
InstallGlobalFunction( SignInt, function( n )
if 0 = n then
return 0;
elif 0 <= n then
return 1;
else
return -1;
fi;
end );
#############################################################################
##
#F SmallestRootInt( <n> ) . . . . . . . . . . . smallest root of an integer
##
InstallGlobalFunction(SmallestRootInt,function ( n )
local k, r, s, p, l, q;
# check the argument
if n > 0 then k := 2; s := 1;
elif n < 0 then k := 3; s := -1; n := -n;
else return 0;
fi;
# exclude small divisors, and thereby large exponents
if n mod 2 = 0 then
p := 2;
else
p := 3; while p < 100 and n mod p <> 0 do p := p+2; od;
fi;
l := LogInt( n, p );
# loop over the possible prime divisors of exponents
# use Euler's criterion to cast out impossible ones
while k <= l do
q := 2*k+1; while not IsPrimeInt(q) do q := q+2*k; od;
if PowerModInt( n, (q-1)/k, q ) <= 1 then
r := RootInt( n, k );
if r ^ k = n then
n := r;
l := QuoInt( l, k );
else
k := NextPrimeInt( k );
fi;
else
k := NextPrimeInt( k );
fi;
od;
return s * n;
end);
#############################################################################
##
#M RingByGenerators( <elms> ) . . . . . . . ring generated by some integers
##
InstallMethod( RingByGenerators,
"method that catches the cases of `Integers' and subrings of `Integers'",
[ IsCyclotomicCollection ],
SUM_FLAGS, # test this before doing anything else
function( elms )
if ForAll( elms, IsInt ) then
# check that the number of generators is bigger than one
# to avoid infinite recursion
if Length( elms ) > 1 then
return RingByGenerators( [ Gcd(elms) ] );
elif elms[1] = 1 then
return Integers;
else
TryNextMethod();
fi;
else
TryNextMethod();
fi;
end );
#############################################################################
##
#M RingWithOneByGenerators( <elms> ) . . . . ring generated by some integers
##
InstallMethod( RingWithOneByGenerators,
"method that catches the cases of `Integers'",
[ IsCyclotomicCollection ],
SUM_FLAGS, # test this before doing anything else
function( elms )
if ForAll( elms, IsInt ) then
return Integers;
else
TryNextMethod();
fi;
end );
#############################################################################
##
#M DefaultRingByGenerators( <elms> ) default ring generated by some integers
##
InstallMethod( DefaultRingByGenerators,
"method that catches the cases of `(Gaussian)Integers' and cycl. fields",
[ IsCyclotomicCollection ],
SUM_FLAGS, # test this before doing anything else
function( elms )
if ForAll( elms, IsInt ) then
return Integers;
elif ForAll( elms, IsGaussInt ) then
return GaussianIntegers;
else
return DefaultField( elms );
fi;
end );
#############################################################################
##
#M DefaultRingByGenerators( <mats> ) . for a list of n x n integer matrices
##
InstallMethod( DefaultRingByGenerators,
"for lists of n x n integer matrices", true,
[ IsCyclotomicCollCollColl and IsFinite ],
function ( mats )
local d;
if IsEmpty(mats) or not ForAll(mats,IsRectangularTable and IsMatrix) then
TryNextMethod();
fi;
d := Length( mats[1] );
if d=0 then
TryNextMethod();
fi;
if not ForAll( mats, m -> Length(m)=d and Length(m[1])=d ) then
TryNextMethod();
fi;
if not ForAll( mats, m -> ForAll( m, r -> ForAll(r,IsInt))) then
TryNextMethod();
fi;
return FullMatrixAlgebra(Integers,d);
end );
#############################################################################
##
#M Enumerator( Integers )
##
## $a_n = \frac{n}{2}$ if $n$ is even, and
## $a_n = \frac{1-n}{2}$ otherwise.
##
InstallMethod( Enumerator,
"for integers",
[ IsIntegers ],
Integers -> EnumeratorByFunctions( Integers,
rec( ElementNumber := function( e, n )
if n mod 2 = 0 then
return n / 2;
else
return ( 1 - n ) / 2;
fi;
end,
NumberElement := function( e, x )
local pos;
if not IsInt( x ) then
return fail;
elif 0 < x then
pos:= 2 * x;
else
pos:= -2 * x + 1;
fi;
return pos;
end ) ) );
#############################################################################
##
#M EuclideanDegree( Integers, <n> ) . . . . . . . . . . . . . absolut value
##
InstallMethod( EuclideanDegree,
"for integers",
true,
[ IsIntegers, IsInt ], 0,
function ( Integers, n )
if n < 0 then
return -n;
else
return n;
fi;
end );
#############################################################################
##
#M EuclideanQuotient( Integers, <n>, <m> ) . . . . . . Euclidean quotient
##
InstallMethod( EuclideanQuotient,
"for integers",
true,
[ IsIntegers, IsInt, IsInt ], 0,
function ( Integers, n, m )
return QuoInt( n, m );
end );
#############################################################################
##
#M EuclideanRemainder( Integers, <n>, <m> ) . . . . . . Euclidean remainder
##
InstallMethod( EuclideanRemainder,
"for integers",
true,
[ IsIntegers, IsInt, IsInt ], 0,
function ( Integers, n, m )
return RemInt( n, m );
end );
#############################################################################
##
#M Factors( Integers, <n> ) . . . . . . . . . . factorization of an integer
##
InstallMethod( Factors,
"for integers",
true,
[ IsIntegers, IsInt ], 0,
function ( Integers, n )
return FactorsInt( n );
end );
#############################################################################
##
#M GcdOp( Integers, <n>, <m> ) . . . . . . . . . . . . . gcd of two integers
##
InstallMethod( GcdOp,
"for integers",
true,
[ IsIntegers, IsInt, IsInt ], 0,
function ( Integers, n, m )
return GcdInt( n, m );
end );
#############################################################################
##
#M IsIrreducibleRingElement( Integers, <n> )
##
InstallMethod( IsIrreducibleRingElement,
"for integers",
true,
[ IsIntegers, IsInt ], 0,
function ( Integers, n )
return IsPrimeInt( n );
end );
#############################################################################
##
#M IsPrime( Integers, <n> ) . . . . . . test whether an integer is a prime
##
InstallMethod( IsPrime,
"for integers",
true,
[ IsIntegers, IsInt ], 0,
function ( Integers, n )
return IsPrimeInt( n );
end );
#############################################################################
##
#M Iterator( Integers )
##
## uses the succession $0, 1, -1, 2, -2, 3, -3, \ldots$, that is,
## $a_n = \frac{n}{2}$ if $n$ is even, and $a_n = \frac{1-n}{2}$
## otherwise.
##
InstallMethod( Iterator,
"for `Integers'",
[ IsIntegers ],
Integers -> IteratorByFunctions( rec(
NextIterator := function( iter )
iter!.counter:= iter!.counter + 1;
if iter!.counter mod 2 = 0 then
return iter!.counter / 2;
else
return ( 1 - iter!.counter ) / 2;
fi;
end,
IsDoneIterator := ReturnFalse,
ShallowCopy := iter -> rec( counter:= iter!.counter ),
counter := 0 ) ) );
#############################################################################
##
#M Iterator( PositiveIntegers )
##
InstallMethod( Iterator,
"for `PositiveIntegers'",
[ IsPositiveIntegers ],
IsPositiveIntegers -> IteratorByFunctions( rec(
NextIterator := function( iter )
iter!.counter:= iter!.counter + 1;
return iter!.counter;
end,
IsDoneIterator := ReturnFalse,
ShallowCopy := iter -> rec( counter:= iter!.counter ),
counter := 0 ) ) ); # 0, since we first increment then return
#############################################################################
##
#M LcmOp( Integers, <n>, <m> ) . . . . . . least common multiple of integers
##
InstallMethod( LcmOp,
"for integers",
true,
[ IsIntegers, IsInt, IsInt ], 0,
function ( Integers, n, m )
return LcmInt( n, m );
end );
#############################################################################
##
#M Log( <n>, <base> )
##
InstallMethod( Log,
"for two integers",
true,
[ IsInt, IsInt ], 0,
LogInt );
#############################################################################
##
#M PowerMod( Integers, <r>, <e>, <m> ) . . . power of an integer mod another
##
InstallMethod( PowerMod,
"for integers",
true,
[ IsIntegers, IsInt, IsInt, IsInt ], 0,
function ( Integers, r, e, m )
return PowerModInt( r, e, m );
end );
#############################################################################
##
#M Quotient( <Integers>, <n>, <m> ) . . . . . . . quotient of two integers
##
InstallMethod( Quotient,
"for integers",
true,
[ IsIntegers, IsInt, IsInt ], 0,
function ( Integers, n, m )
local q;
q := QuoInt( n, m );
if n <> q * m then
q := fail;
fi;
return q;
end );
#############################################################################
##
#M QuotientMod( Integers , <r>, <s>, <m> ) . . . . . . . quotient modulo <m>
##
InstallMethod( QuotientMod,
"for integers",
true,
[ IsIntegers, IsInt, IsInt, IsInt ], 0,
function ( Integers, r, s, m )
if s>m then s:=s mod m;fi;
if m = 1 then
return 0;
elif r mod GcdInt( s, m ) = 0 then
return r/s mod m;
else
return fail;
fi;
end );
#############################################################################
##
#M QuotientRemainder( Integers, <n>, <m> ) . . . . . . . . . . . quo and rem
##
InstallMethod( QuotientRemainder,
"for integers",
true,
[ IsIntegers, IsInt, IsInt ], 0,
function ( Integers, n, m )
local q;
q := QuoInt(n,m);
#T kernel function should compute remainder at same time
return [ q, n - q * m ];
end );
#############################################################################
##
#M Random( Integers ) . . . . . . . . . . . . . . . . . . . random integer
##
## returns pseudo random integers between $-10$ and $10$
## distributed according to a binomial distribution.
##
## \begintt
## gap> Random( Integers );
## 1
## gap> Random( Integers );
## -4
## \endtt
##
## To generate uniformly distributed integers from a range, use the
## construct `Random( [ <low> .. <high> ] )'.
##
NrBitsInt := function ( n )
local nr, nr64;
nr64:=[0,1,1,2,1,2,2,3,1,2,2,3,2,3,3,4,1,2,2,3,2,3,3,4,2,3,3,4,3,4,4,5,
1,2,2,3,2,3,3,4,2,3,3,4,3,4,4,5,2,3,3,4,3,4,4,5,3,4,4,5,4,5,5,6];
nr := 0;
while 0 < n do
nr := nr + nr64[ n mod 64 + 1 ];
n := QuoInt( n, 64 );
od;
return nr;
end;
InstallMethod( Random,
"for `Integers'",
true,
[ IsIntegers ], 0,
function( Integers )
return NrBitsInt( Random( [0..2^20-1] ) ) - 10;
end );
#############################################################################
##
#M Root( <n>, <k> )
##
InstallMethod( Root,
"for two integers",
true,
[ IsInt, IsInt ], 0,
RootInt );
#############################################################################
##
#M RoundCyc( <cyc> ) . . . . . . . . . . cyclotomic integer near to <cyc>
##
InstallMethod( RoundCyc, "Integer", true, [ IsInt ], 0, x->x );
#############################################################################
##
#M RoundCycDown( <cyc> ) . . . . . . . . . . cyclotomic integer near to <cyc>
##
InstallMethod( RoundCycDown, "Integer", true, [ IsInt ], 0, x->x );
#############################################################################
##
#M StandardAssociate( Integers, <n> ) . . . . . . . . . . . absolute value
##
InstallMethod( StandardAssociate,
"for integers",
true,
[ IsIntegers, IsInt ], 0,
function ( Integers, n )
if n < 0 then
return -n;
else
return n;
fi;
end );
#############################################################################
##
#M StandardAssociateUnit( Integers, <n> )
##
InstallMethod( StandardAssociateUnit,
"for integers",
true,
[ IsIntegers, IsInt ], 0,
function ( Integers, n )
if n < 0 then
return -1;
else
return 1;
fi;
end );
#############################################################################
##
#M Valuation( <n>, <m> )
##
InstallOtherMethod( Valuation,
"for two integers",
IsIdenticalObj,
[ IsInt,
IsInt ],
0,
function( n, m )
local val;
if n = 0 then
val := infinity;
else
val := 0;
while n mod m = 0 do
val := val + 1;
n := n / m;
od;
fi;
return val;
end );
#############################################################################
##
#M \in( <n>, <Integers> ) . . . . . . . . . . membership test for integers
##
InstallMethod( \in,
"for integers",
IsElmsColls,
[ IsCyclotomic, IsIntegers ], 0,
function( n, Integers )
return IsInt( n );
end );
#############################################################################
##
#M \in( <n>, <PositiveIntegers> )
##
InstallMethod( \in,
"for positive integers",
IsElmsColls,
[ IsCyclotomic, IsPositiveIntegers ], 0,
function( n, PositiveIntegers )
return IsPosInt( n );
end );
#############################################################################
##
#M \in( <n>, <NonnegativeIntegers> )
##
InstallMethod( \in,
"for nonnegative integers",
IsElmsColls,
[ IsCyclotomic, IsNonnegativeIntegers ], 0,
function( n, NonnegativeIntegers )
return IsPosInt( n ) or IsZeroCyc( n );
end );
#############################################################################
##
#F PrintFactorsInt( <n> ) . . . . . . . . print factorization of an integer
##
InstallGlobalFunction(PrintFactorsInt,function ( n )
local decomp, i;
if -4 < n and n < 4 then
Print( n );
else
decomp := Collected( Factors( AbsInt( n ) ) );
if n > 0 then
Print( decomp[1][1] );
else
Print( -decomp[1][1] );
fi;
if decomp[1][2] > 1 then
Print( "^", decomp[1][2] );
fi;
for i in [ 2 .. Length( decomp ) ] do
Print( "*", decomp[i][1] );
if decomp[i][2] > 1 then
Print( "^", decomp[i][2] );
fi;
od;
fi;
end);
#############################################################################
##
#M Iterator( <posint> ) . . . . . . . . . . . . .give more informative error
##
## This method is mainly there to trap the "natural" error
## for i in 3 do ... od;
##
InstallOtherMethod(Iterator, "more helpful error for integers", true,
[IsPosInt], 0,
function(n)
Error("You cannot loop over the integer ",n,
" did you mean the range [1..",n,"]");
end);
InstallGlobalFunction(PowerDecompositions,function(n)
local d,i,r;
i:=2;
d:=[];
repeat
r:=RootInt(n,i);
if n=r^i then
Add(d,[r,i]);
fi;
i:=i+1;
until r<2;
return d;
end);
## The behaviour of View(String) for large integers can be configured via a
## user preference.
DeclareUserPreference( rec(
name:= "MaxBitsIntView",
description:= [
"Maximal bit length of integers to 'view' unabbreviated. \
Default is about 30 lines of a 80 character wide terminal. \
Set this to '0' to avoid abbreviated ints."
],
default:= 8000,
check:= val -> IsInt( val ) and 0 <= val,
) );
## give only a short info if |n| is larger than 2^GAPInfo.MaxBitsIntView
InstallMethod(ViewString, "for integer", [IsInt], function(n)
local mb, l, start, trail;
mb := UserPreference("MaxBitsIntView");
if not IsSmallIntRep(n) and mb <> fail and
mb > 64 and Log2Int(n) > mb then
if n < 0 then
l := LogInt(-n, 10);
trail := String(-n mod 1000);
else
l := LogInt(n, 10);
trail := String(n mod 1000);
fi;
start := String(QuoInt(n, 10^(l-2)));
while Length(trail) < 3 do
trail := Concatenation("0", trail);
od;
return Concatenation("<integer ",start,"...",trail," (",
String(l+1)," digits)>");
else
return String(n);
fi;
end);
#############################################################################
##
#E
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