/usr/share/perl5/Math/PlanePath/ZOrderCurve.pm is in libmath-planepath-perl 117-1.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
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# This file is part of Math-PlanePath.
#
# Math-PlanePath is free software; you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by the
# Free Software Foundation; either version 3, or (at your option) any later
# version.
#
# Math-PlanePath is distributed in the hope that it will be useful, but
# WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
# or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
# for more details.
#
# You should have received a copy of the GNU General Public License along
# with Math-PlanePath. If not, see <http://www.gnu.org/licenses/>.
# math-image --path=ZOrderCurve,radix=3 --all --output=numbers
# math-image --path=ZOrderCurve --values=Fibbinary --text
#
# increment N+1 changes low 1111 to 10000
# X bits change 011 to 000, no carry, decreasing by number of low 1s
# Y bits change 011 to 100, plain +1
#
# cf A105186 replace odd position ternary digits with 0
#
package Math::PlanePath::ZOrderCurve;
use 5.004;
use strict;
use List::Util 'max';
use vars '$VERSION', '@ISA';
$VERSION = 117;
use Math::PlanePath;
@ISA = ('Math::PlanePath');
use Math::PlanePath::Base::Generic
'is_infinite',
'round_nearest';
use Math::PlanePath::Base::Digits
'parameter_info_array',
'digit_split_lowtohigh',
'digit_join_lowtohigh';
*_divrem_mutate = \&Math::PlanePath::_divrem_mutate;
# uncomment this to run the ### lines
#use Smart::Comments;
use constant n_start => 0;
use constant class_x_negative => 0;
use constant class_y_negative => 0;
*xy_is_visited = \&Math::PlanePath::Base::Generic::xy_is_visited_quad1;
use constant dx_maximum => 1;
use constant dy_maximum => 1;
use constant absdx_minimum => 1; # X coord always changes
use constant dsumxy_maximum => 1; # forward straight only
sub dir_maximum_dxdy {
my ($self) = @_;
return (1, 1 - $self->{'radix'}); # SE diagonal
}
#------------------------------------------------------------------------------
sub new {
my $self = shift->SUPER::new(@_);
my $radix = $self->{'radix'};
if (! defined $radix || $radix <= 2) { $radix = 2; }
$self->{'radix'} = $radix;
return $self;
}
sub n_to_xy {
my ($self, $n) = @_;
### ZOrderCurve n_to_xy(): $n
if ($n < 0) {
return;
}
if (is_infinite($n)) {
return ($n,$n);
}
my $int = int($n);
$n -= $int; # fraction part
my $radix = $self->{'radix'};
my @ndigits = digit_split_lowtohigh ($int, $radix);
### @ndigits
unless ($#ndigits & 1) {
push @ndigits, 0; # pad @ndigits to an even number of digits
}
my @xdigits;
my @ydigits;
while (@ndigits) {
push @xdigits, shift @ndigits; # low to high
push @ydigits, shift @ndigits; # low to high
}
### @xdigits
### @ydigits
my $zero = ($int * 0); # inherit bigint 0
my $x = digit_join_lowtohigh (\@xdigits, $radix, $zero);
my $y = digit_join_lowtohigh (\@ydigits, $radix, $zero);
if ($n) {
# fraction part
my $dx = 1;
my $dy = $zero;
my $radix_minus_1 = $radix - 1;
foreach my $i (0 .. $#xdigits) { # low to high
if ($xdigits[$i] != $radix_minus_1) {
### lowest non-9 is an X digit, so dx=1 dy=0,-R+1,-R^2+1,etc
last;
}
$dy = ($dy * $radix) - $radix_minus_1; # 1-$radix**$i
if ($ydigits[$i] != $radix_minus_1) {
### lowest non-9 is a Y digit, so dy=1, dx=-R+1,-R^2+1,etc
$dx = $dy;
$dy = 1;
last;
}
}
### $dx
### $dy
$x = $n*$dx + $x;
$y = $n*$dy + $y;
}
return ($x, $y);
}
sub n_to_dxdy {
my ($self, $n) = @_;
### ZOrderCurve n_to_xy(): $n
if ($n < 0) {
return;
}
my $int = int($n);
$n -= $int; # fraction part
if (is_infinite($int)) {
return ($int,$int);
}
my $radix = $self->{'radix'};
my $digit = _divrem_mutate($int,$radix); # lowest digit of N
if ($digit < $radix - 2) {
# N an integer at lowdigit<radix-2, so dx=1,dy=0
return (1, 0);
}
my $radix_minus_1 = $radix - 1;
my $scan_for_dx = ($digit == $radix_minus_1);
unless ($scan_for_dx) {
### assert: $digit == $radix-2
unless ($n) {
# N an integer with lowdigit==radix-2, so dx=1,dy=0
return (1, 0);
}
# scan digits for next_dx,next_dy
}
my $power = $radix + ($int*0); # $radix**$i, inherit bigint
for (;;) {
if (_divrem_mutate($int,$radix) != $radix_minus_1) {
### lowest non-9 is a Y digit, so dy=1, dx=-R+1,-R^2+1,etc
if ($scan_for_dx) {
# scanned for dx=1-power,dy=1 have nextdx=1,nextdy=0
# frac*(nextdx-dx) + dx = n*(1-(1-power))+(1-power)
# = n*(1-1+power))+1-power
# = n*power+1-power
# = (n-1)*power+1
# frac*(nextdy-dy) + dy = n*(0-1) + 1
# = 1-n
return (($n-1)*$power + 1,
1-$n);
} else {
# scanned for nextdx=1-power,nextdy=1 have dx=1,dy=0
# frac*(nextdx-dx) + dx = n*((1-power)-1)+1
# = n*(1-power-1)+1
# = n*-power+1
# = 1 - n*power
# frac*(nextdy-dy) + dy = n*(1-0) + 0
# = n
return (1 - $n*$power,
$n);
}
}
if (_divrem_mutate($int,$radix) != $radix_minus_1) {
### lowest non-9 is an X digit, so dx=1 dy=0,-R+1,-R^2+1,etc
$power -= 1;
if ($scan_for_dx) {
# scanned for dx=1,dy=1-power have nextdx=1,nextdy=0
# frac*(nextdx-dx) + dx = n*(1-1)+1
# = 1
# frac*(nextdy-dy) + dy = n*(0-(1-power)) + (1-power)
# = n*(-1+power) + 1-power
# = -n + n*power + 1 - power
# = 1-n + (n-1)*power
# = (n-1)*(power-1)
return (1,
($n-1) * $power);
} else {
# scanned for nextdx=1,nextdy=1-power have dx=1,dy=0
# frac*(nextdx-dx) + dx = n*(1-1) + 1
# = 1
# frac*(nextdy-dy) + dy = n*((1-power) - 0) + 0
# = n*(1-power)
return (1,
-$n*$power);
}
}
$power *= $radix;
}
}
sub xy_to_n {
my ($self, $x, $y) = @_;
### ZOrderCurve xy_to_n(): "$x, $y"
$x = round_nearest ($x);
$y = round_nearest ($y);
if ($x < 0 || $y < 0) { return undef; }
if (is_infinite($x)) { return $x; }
if (is_infinite($y)) { return $y; }
my $radix = $self->{'radix'};
my $zero = ($x * 0 * $y); # inherit bigint 0
my @x = digit_split_lowtohigh($x,$radix);
my @y = digit_split_lowtohigh($y,$radix);
return digit_join_lowtohigh ([ _digit_interleave (\@x, \@y) ],
$radix,
$zero);
}
# return list of @$xaref interleaved with @$yaref
# ($xaref->[0], $yaref->[0], $xaref->[1], $yaref->[1], ...)
#
sub _digit_interleave {
my ($xaref, $yaref) = @_;
my @ret;
foreach my $i (0 .. max($#$xaref,$#$yaref)) {
push @ret, $xaref->[$i] || 0;
push @ret, $yaref->[$i] || 0;
}
return @ret;
}
# exact
sub rect_to_n_range {
my ($self, $x1,$y1, $x2,$y2) = @_;
$x1 = round_nearest ($x1);
$y1 = round_nearest ($y1);
$x2 = round_nearest ($x2);
$y2 = round_nearest ($y2);
if ($x1 > $x2) { ($x1,$x2) = ($x2,$x1); } # x1 smaller
if ($y1 > $y2) { ($y1,$y2) = ($y2,$y1); } # y1 smaller
if ($y2 < 0 || $x2 < 0) {
return (1, 0); # rect all negative, no N
}
if ($x1 < 0) { $x1 *= 0; } # "*=" to preserve bigint x1 or y1
if ($y1 < 0) { $y1 *= 0; }
# monotonic increasing in X and Y directions, so this is exact
return ($self->xy_to_n ($x1, $y1),
$self->xy_to_n ($x2, $y2));
}
#------------------------------------------------------------------------------
# levels
use Math::PlanePath::ZOrderCurve;
*level_to_n_range = \&Math::PlanePath::ZOrderCurve::level_to_n_range;
*n_to_level = \&Math::PlanePath::ZOrderCurve::n_to_level;
#------------------------------------------------------------------------------
# level_to_n_range()
# shared by Math::PlanePath::GrayCode and others
sub level_to_n_range {
my ($self, $level) = @_;
return (0, $self->{'radix'}**(2*$level) - 1);
}
sub n_to_level {
my ($self, $n) = @_;
if ($n < 0) { return undef; }
$n = round_nearest($n);
my ($pow, $exp) = round_down_pow ($n, $self->{'radix'} * $self->{'radix'});
return $exp;
}
#------------------------------------------------------------------------------
1;
__END__
=for stopwords Ryde Math-PlanePath Karatsuba undrawn fibbinary eg Radix radix radix-1 RxR OEIS
=head1 NAME
Math::PlanePath::ZOrderCurve -- alternate digits to X and Y
=head1 SYNOPSIS
use Math::PlanePath::ZOrderCurve;
my $path = Math::PlanePath::ZOrderCurve->new;
my ($x, $y) = $path->n_to_xy (123);
# or another radix digits ...
my $path3 = Math::PlanePath::ZOrderCurve->new (radix => 3);
=head1 DESCRIPTION
This path puts points in a self-similar Z pattern described by G.M. Morton,
7 | 42 43 46 47 58 59 62 63
6 | 40 41 44 45 56 57 60 61
5 | 34 35 38 39 50 51 54 55
4 | 32 33 36 37 48 49 52 53
3 | 10 11 14 15 26 27 30 31
2 | 8 9 12 13 24 25 28 29
1 | 2 3 6 7 18 19 22 23
Y=0 | 0 1 4 5 16 17 20 21 64 ...
+---------------------------------------
X=0 1 2 3 4 5 6 7 8
The first four points make a "Z" shape if written with Y going downwards
(inverted if drawn upwards as above),
0---1 Y=0
/
/
2---3 Y=1
Then groups of those are arranged as a further Z, etc, doubling in size each
time.
0 1 4 5 Y=0
2 3 --- 6 7 Y=1
/
/
/
8 9 --- 12 13 Y=2
10 11 14 15 Y=3
Within an power of 2 square 2x2, 4x4, 8x8, 16x16 etc (2^k)x(2^k), all the N
values 0 to 2^(2*k)-1 are within the square. The top right corner 3, 15,
63, 255 etc of each is the 2^(2*k)-1 maximum.
Along the X axis N=0,1,4,5,16,17,etc is the integers with only digits 0,1 in
base 4. Along the Y axis N=0,2,8,10,32,etc is the integers with only digits
0,2 in base 4. And along the X=Y diagonal N=0,3,12,15,etc is digits 0,3 in
base 4.
In the base Z pattern it can be seen that transposing to Y,X means swapping
parts 1 and 2. This applies in the sub-parts too so in general if N is at
X,Y then changing base 4 digits 1E<lt>-E<gt>2 gives the N at the transpose
Y,X. For example N=22 at X=6,Y=1 is base-4 "112", change 1E<lt>-E<gt>2 is
"221" for N=41 at X=1,Y=6.
=head2 Power of 2 Values
Plotting N values related to powers of 2 can come out as interesting
patterns. For example displaying the N's which have no digit 3 in their
base 4 representation gives
*
* *
* *
* * * *
* *
* * * *
* * * *
* * * * * * * *
* *
* * * *
* * * *
* * * * * * * *
* * * *
* * * * * * * *
* * * * * * * *
* * * * * * * * * * * * * * * *
The 0,1,2 and not 3 makes a little 2x2 "L" at the bottom left, then
repeating at 4x4 with again the whole "3" position undrawn, and so on. This
is the Sierpinski triangle (a rotated version of
L<Math::PlanePath::SierpinskiTriangle>). The blanks are also a visual
representation of 1-in-4 cross-products saved by recursive use of the
Karatsuba multiplication algorithm.
Plotting the fibbinary numbers (eg. L<Math::NumSeq::Fibbinary>) which are N
values with no adjacent 1 bits in binary makes an attractive tree-like
pattern,
*
**
*
****
*
**
* *
********
*
**
*
****
* *
** **
* * * *
****************
* *
** **
* *
**** ****
* *
** **
* * * *
******** ********
* * * *
** ** ** **
* * * *
**** **** **** ****
* * * * * * * *
** ** ** ** ** ** ** **
* * * * * * * * * * * * * * * *
****************************************************************
The horizontals arise from N=...0a0b0c for bits a,b,c so Y=...000 and
X=...abc, making those N values adjacent. Similarly N=...a0b0c0 for a
vertical.
=head2 Radix
The C<radix> parameter can do the same N E<lt>-E<gt> X/Y digit splitting in
a higher base. For example radix 3 makes 3x3 groupings,
radix => 3
5 | 33 34 35 42 43 44
4 | 30 31 32 39 40 41
3 | 27 28 29 36 37 38 45 ...
2 | 6 7 8 15 16 17 24 25 26
1 | 3 4 5 12 13 14 21 22 23
Y=0 | 0 1 2 9 10 11 18 19 20
+--------------------------------------
X=0 1 2 3 4 5 6 7 8
Along the X axis N=0,1,2,9,10,11,etc is integers with only digits 0,1,2 in
base 9. Along the Y axis digits 0,3,6, and along the X=Y diagonal digits
0,4,8. In general for a given radix it's base R*R with the R many digits of
the first RxR block.
=head1 FUNCTIONS
See L<Math::PlanePath/FUNCTIONS> for behaviour common to all path classes.
=over 4
=item C<$path = Math::PlanePath::ZOrderCurve-E<gt>new ()>
=item C<$path = Math::PlanePath::ZOrderCurve-E<gt>new (radix =E<gt> $r)>
Create and return a new path object. The optional C<radix> parameter gives
the base for digit splitting (the default is binary, radix 2).
=item C<($x,$y) = $path-E<gt>n_to_xy ($n)>
Return the X,Y coordinates of point number C<$n> on the path. Points begin
at 0 and if C<$n E<lt> 0> then the return is an empty list.
Fractional positions give an X,Y position along a straight line between the
integer positions. The lines don't overlap, but the lines between bit
squares soon become rather long and probably of very limited use.
=item C<$n = $path-E<gt>xy_to_n ($x,$y)>
Return an integer point number for coordinates C<$x,$y>. Each integer N is
considered the centre of a unit square and an C<$x,$y> within that square
returns N.
=item C<($n_lo, $n_hi) = $path-E<gt>rect_to_n_range ($x1,$y1, $x2,$y2)>
The returned range is exact, meaning C<$n_lo> and C<$n_hi> are the smallest
and biggest in the rectangle.
=back
=head2 Level Methods
=over
=item C<($n_lo, $n_hi) = $path-E<gt>level_to_n_range($level)>
Return C<(0, $radix**(2*$level) - 1)>.
=back
=head1 FORMULAS
=head2 N to X,Y
The coordinate calculation is simple. The bits of X and Y are every second
bit of N. So if N = binary 101010 then X=000 and Y=111 in binary, which is
the N=42 shown above at X=0,Y=7.
With the C<radix> parameter the digits are treated likewise, in the given
radix rather than binary.
If N includes a fraction part then it's applied to a straight line towards
point N+1. The +1 of N+1 changes X and Y according to how many low radix-1
digits there are in N, and thus in X and Y. In general if the lowest non
radix-1 is in X then
dX=1
dY = - (R^pos - 1) # pos=0 for lowest digit
The simplest case is when the lowest digit of N is not radix-1, so dX=1,dY=0
across.
If the lowest non radix-1 is in Y then
dX = - (R^(pos+1) - 1) # pos=0 for lowest digit
dY = 1
If all digits of X and Y are radix-1 then the implicit 0 above the top of X
is considered the lowest non radix-1 and so the first case applies. In the
radix=2 above this happens for instance at N=15 binary 1111 so X = binary 11
and Y = binary 11. The 0 above the top of X is at pos=2 so dX=1,
dY=-(2^2-1)=-3.
=head2 Rectangle to N Range
Within each row the N values increase as X increases, and within each column
N increases with increasing Y (for all C<radix> parameters).
So for a given rectangle the smallest N is at the lower left corner
(smallest X and smallest Y), and the biggest N is at the upper right
(biggest X and biggest Y).
=head1 OEIS
This path is in Sloane's Online Encyclopedia of Integer Sequences in various
forms,
=over
L<http://oeis.org/A059905> (etc)
=back
radix=2
A059905 X coordinate
A059906 Y coordinate
A000695 N on X axis (base 4 digits 0,1 only)
A062880 N on Y axis (base 4 digits 0,2 only)
A001196 N on X=Y diagonal (base 4 digits 0,3 only)
A057300 permutation N at transpose Y,X (swap bit pairs)
radix=3
A163325 X coordinate
A163326 Y coordinate
A037314 N on X axis, base 9 digits 0,1,2
A208665 N on X=Y diagonal, base 9 digits 0,3,6
A163327 permutation N at transpose Y,X (swap trit pairs)
radix=4
A126006 permutation N at transpose Y,X (swap digit pairs)
radix=10
A080463 X+Y of radix=10 (from N=1 onwards)
A080464 X*Y of radix=10 (from N=10 onwards)
A080465 abs(X-Y), from N=10 onwards
A051022 N on X axis (base 100 digits 0 to 9)
radix=16
A217558 permutation N at transpose Y,X (swap digit pairs)
And taking X,Y points in the Diagonals sequence then the value of the
following sequences is the N of the C<ZOrderCurve> at those positions.
radix=2
A054238 numbering by diagonals, from same axis as first step
A054239 inverse permutation
radix=3
A163328 numbering by diagonals, same axis as first step
A163329 inverse permutation
A163330 numbering by diagonals, opp axis as first step
A163331 inverse permutation
C<Math::PlanePath::Diagonals> numbers points from the Y axis down, which is
the opposite axis to the C<ZOrderCurve> first step along the X axis, so a
transpose is needed to give A054238.
=head1 SEE ALSO
L<Math::PlanePath>,
L<Math::PlanePath::PeanoCurve>,
L<Math::PlanePath::HilbertCurve>,
L<Math::PlanePath::ImaginaryBase>,
L<Math::PlanePath::CornerReplicate>,
L<Math::PlanePath::DigitGroups>
X<Arndt, Jorg>X<fxtbook>C<http://www.jjj.de/fxt/#fxtbook> (section 1.31.2)
L<Algorithm::QuadTree>, L<DBIx::SpatialKeys>
=head1 HOME PAGE
L<http://user42.tuxfamily.org/math-planepath/index.html>
=head1 LICENSE
Copyright 2010, 2011, 2012, 2013, 2014 Kevin Ryde
This file is part of Math-PlanePath.
Math-PlanePath is free software; you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by the Free
Software Foundation; either version 3, or (at your option) any later
version.
Math-PlanePath is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
more details.
You should have received a copy of the GNU General Public License along with
Math-PlanePath. If not, see <http://www.gnu.org/licenses/>.
=cut
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