1Math::NumSeq::RepdigitRUasdeirx(C3o)ntributed Perl DocumMeanttha:t:iNounmSeq::RepdigitRadix(3)
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6 Math::NumSeq::RepdigitRadix -- radix in which i is a repdigit
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9 use Math::NumSeq::RepdigitRadix;
10 my $seq = Math::NumSeq::RepdigitRadix->new;
11 my ($i, $value) = $seq->next;
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14 The radix in which i is a repdigit,
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16 2, 0, 0, 2, 3, 4, 5, 2, 3, 8, 4, 10, etc
17 starting i=0
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19 i=0 is taken to be a repdigit "00" in base 2. i=1 and i=2 are not
20 repdigits in any radix. Then i=3 is repdigit "11" in base 2. Any i>=3
21 is at worst a repdigit "11" in base i-1, but may be a repdigit in a
22 smaller base. For example i=8 is "22" in base 3.
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24 Is this behaviour for i=0,1,2 any good? Perhaps it will change.
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27 See "FUNCTIONS" in Math::NumSeq for behaviour common to all sequence
28 classes.
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30 "$seq = Math::NumSeq::RepdigitRadix->new ()"
31 Create and return a new sequence object.
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33 Random Access
34 "$value = $seq->ith($i)"
35 Return the radix in which $i is a repdigit.
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37 The current code relies on factorizing $i and a hard limit of 2**32
38 is placed on $i in the interests of not going into a near-infinite
39 loop.
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42 ith() Value
43 "ith()" looks for the smallest radix r for which there's a digit d and
44 length len satisfying
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46 i = d * repunit(len)
47 i = d * (r^(len-1) + r^(len-2) + ... + r^2 + r + 1)
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49 The current approach is to consider repdigit lengths successively from
50 log2(i) downwards and candidate digits d from among the divisors of i.
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52 for len=log2(i) down to 2
53 for d each divisor of i, descending
54 r = nthroot(i/d, len-1)
55 if r >= r_found then next len
56 if r <= d then next divisor
57 if (r^len-1)/(r-1) == i/d then r_found=r, next len
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59 if no r_found then r_found = i-1
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61 For a given d the radix r to give i would be
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63 i/d = r^(len-1) + ... + r + 1
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65 but it's enough to calculate
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67 i/d = r^(len-1)
68 r = floor nthroot(i/d, len-1)
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70 and then power up to see if it gives the desired i/d.
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72 repunit(len) = r^(len-1) + ... + r + 1
73 = (r^len - 1) / (r-1)
74 check if equals i/d
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76 floor(nthroot()) is never too small, since an r+1 from it would give
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78 (r+1)^(len-1) = r^(len-1) + binomial*r^(len-2) + ... + 1
79 > r^(len-1) + r^(len-2) + ... + 1
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81 Divisors are taken in descending order so the radices r are in
82 increasing order. So if a repdigit is found in a given len then it's
83 the smallest of that length and can go on to other lengths.
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85 The lengths can be considered in any order but the current code goes
86 from high to low since a bigger length means a smaller maximum radix
87 within that length (occurring when d=1, ie. a repunit), so it might
88 establish a smaller "r_found" and a smaller r_found limits the number
89 of divisors to be tried in subsequent lengths. But does that actually
90 happen often enough to make any difference?
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92 ith() Other Possibilities
93 When len is even the repunit part r^(len-1)+...+1 is a multiple of r+1.
94 Can that cut the search? For a given divisor the r is found easily
95 enough by nthroot, but maybe i with only two prime factors can never be
96 an even length>=4 repdigit, or something like that.
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99 Math::NumSeq, Math::NumSeq::RepdigitAny
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102 <http://user42.tuxfamily.org/math-numseq/index.html>
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105 Copyright 2010, 2011, 2012, 2013, 2014, 2016, 2019 Kevin Ryde
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107 Math-NumSeq is free software; you can redistribute it and/or modify it
108 under the terms of the GNU General Public License as published by the
109 Free Software Foundation; either version 3, or (at your option) any
110 later version.
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112 Math-NumSeq is distributed in the hope that it will be useful, but
113 WITHOUT ANY WARRANTY; without even the implied warranty of
114 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
115 General Public License for more details.
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117 You should have received a copy of the GNU General Public License along
118 with Math-NumSeq. If not, see <http://www.gnu.org/licenses/>.
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122perl v5.32.1 2021-01-27 Math::NumSeq::RepdigitRadix(3)