File Coverage

blib/lib/Math/PlanePath/SierpinskiCurveStair.pm

Criterion	Covered	Total	%
statement	169	196	86.2
branch	50	66	75.7
condition	18	22	81.8
subroutine	23	24	95.8
pod	8	8	100.0
total	268	316	84.8

line	stmt	bran	cond	sub	pod	time	code
1							# Copyright 2011, 2012, 2013, 2014, 2015, 2016, 2017, 2018 Kevin Ryde
2
3							# This file is part of Math-PlanePath.
4							#
5							# Math-PlanePath is free software; you can redistribute it and/or modify
6							# it under the terms of the GNU General Public License as published by the
7							# Free Software Foundation; either version 3, or (at your option) any later
8							# version.
9							#
10							# Math-PlanePath is distributed in the hope that it will be useful, but
11							# WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
12							# or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
13							# for more details.
14							#
15							# You should have received a copy of the GNU General Public License along
16							# with Math-PlanePath. If not, see .
17
18
19
20
21							# math-image --path=SierpinskiCurveStair --lines --scale=10
22							#
23							# math-image --path=SierpinskiCurveStair,diagonal_length=1 --all --output=numbers_dash --offset=-10,-7 --size=78x30
24
25
26
27							package Math::PlanePath::SierpinskiCurveStair;
28	1			1		9600	use 5.004;
	1					10
29	1			1		5	use strict;
	1					2
	1					40
30	1			1		6	use List::Util 'min','max';
	1					2
	1					152
31
32	1			1		7	use vars '$VERSION', '@ISA';
	1					2
	1					64
33							$VERSION = 127;
34	1			1		1048	use Math::PlanePath;
	1					3
	1					30
35	1			1		428	use Math::PlanePath::Base::NSEW;
	1					3
	1					42
36							@ISA = ('Math::PlanePath::Base::NSEW',
37							'Math::PlanePath');
38
39							use Math::PlanePath::Base::Generic
40	1					47	'is_infinite',
41	1			1		6	'round_nearest';
	1					2
42							use Math::PlanePath::Base::Digits
43	1					73	'round_up_pow',
44	1			1		475	'round_down_pow';
	1					2
45							*_divrem_mutate = \&Math::PlanePath::_divrem_mutate;
46
47							# uncomment this to run the ### lines
48							#use Smart::Comments;
49
50
51	1			1		7	use constant n_start => 0;
	1					1
	1					142
52							sub x_negative {
53	6			6	1	80	my ($self) = @_;
54	6					19	return ($self->{'arms'} >= 3);
55							}
56							sub y_negative {
57	6			6	1	310	my ($self) = @_;
58	6					54	return ($self->{'arms'} >= 5);
59							}
60
61	1					55	use constant parameter_info_array =>
62							[
63							{ name => 'diagonal_length',
64							display => 'Diagonal Length',
65							type => 'integer',
66							minimum => 1,
67							default => 1,
68							width => 1,
69							description => 'Length of the diagonal in the base pattern.',
70							},
71							{ name => 'arms',
72							share_key => 'arms_8',
73							display => 'Arms',
74							type => 'integer',
75							minimum => 1,
76							maximum => 8,
77							default => 1,
78							width => 1,
79							},
80	1			1		7	];
	1					2
81
82	1			1		650	use Math::PlanePath::SierpinskiCurve;
	1					3
	1					68
83							*x_negative_at_n = \&Math::PlanePath::SierpinskiCurve::x_negative_at_n;
84							*y_negative_at_n = \&Math::PlanePath::SierpinskiCurve::y_negative_at_n;
85							*x_minimum = \&Math::PlanePath::SierpinskiCurve::x_minimum;
86							*sumxy_minimum = \&Math::PlanePath::SierpinskiCurve::sumxy_minimum;
87	1			1		8	use constant sumabsxy_minimum => 1;
	1					2
	1					69
88							*diffxy_minimum = \&Math::PlanePath::SierpinskiCurve::diffxy_minimum;
89	1			1		9	use constant absdiffxy_minimum => 1; # X=Y never occurs
	1					2
	1					45
90	1			1		7	use constant rsquared_minimum => 1; # minimum X=1,Y=0
	1					2
	1					53
91	1			1		7	use constant turn_any_straight => 0; # never straight
	1					2
	1					1451
92
93
94							#------------------------------------------------------------------------------
95
96							sub new {
97	41			41	1	4521	my $self = shift->SUPER::new(@_);
98	41		100			308	$self->{'arms'} = max(1, min(8, $self->{'arms'} \|\| 1));
99	41		100			145	$self->{'diagonal_length'} \|\|= 1;
100	41					107	return $self;
101							}
102
103							# 20--21
104							# \| \|
105							# 18--19 22--23
106							# \| \|
107							# 16--17 24--25
108							# \| \|
109							# 15--14 27--26
110							# \| \|
111							# 4---5 13--12 29--28 36--37
112							# \| \| \| \| \| \|
113							# 2---3 6---7 10--11 30--31 34--35 38--39 42--43
114							# \| \| \| \| \| \| \|
115							# 0---1 8---9 32--33 40--41
116
117							# len=5
118							# N=0 to 9 is 10
119							# next N=0 to 41 is 42=4*10+2
120							# next is 4*42+2=166
121							# points(level) = 4*points(level-1)+2
122							#
123							# or side 5 points
124							# points(level) = 4*points(level-1)+1
125							# = 4(4points(level-2)+1)+1
126							# = 16*points(level-2) + 4 + 1
127							# = 64*points(level-3) + 16 + 4 + 1
128							# = 5 * 4^level + 1+...+4^(level-1)
129							# = 5 * 4^level + (4^level - 1) / 3
130							# = (15 * 4^level + 4^level - 1) / 3
131							# = (16 * 4^level - 1) / 3
132							# = (4^(level+2) - 1) / 3
133							# level=0 (16*1-1)/3=5
134							# level=1 (16*4-1)/3=21
135							# level=2 (16*16-1)/3=85
136							#
137							# n = (16 * 4^level - 1) / 3
138							# 3n+1 = 16 * 4^level
139							# 4^level = (3n+1)/16
140							# level = log4 ( (3n+1)/16)
141							# = log4(3n+1) - 2
142							# N=21 log4(64)-2=3-2=1
143							#
144							# nlen=4^(level+2)
145							# n = (nlen-1)/3
146							# next_n = (nlen/4-1)/3
147							# = (nlen-4)/3 /4
148							# = ((nlen-1)/3 -1) /4
149							#
150							# len=2,6,14
151							# len(k)=2*len(k-1) + 2
152							# = 2^k + 2*(2^(k-1)-1)
153							# = 2^k + 2^k - 2
154							# = 2*(2^k - 1)
155							# k=1 len=2*(2-1) = 2
156							# k=2 len=2*(4-1) = 6
157							# k=3 len=2*(8-1) = 14
158
159							# len(k)-2=2*len(k-1)
160							# (len(k)-2)/2=len(k-1)
161							# len(k-1) = (len(k)-2)/2
162							# = len(k)/2-1
163							#
164							# ---------
165							# with P=2*L+1 points per side
166							# points(level) = 64*points(level-3) + 16 + 4 + 1
167							# = P*4^level + 1+...+4^(level-1)
168							# = P*4^level + (4^level - 1) / 3
169							# = (3P*4^level + 4^level - 1) / 3
170							# = ((3P+1)*4^level - 1) / 3
171							# = ((3(2L+1)+1)4^level - 1) / 3
172							# = ((6L+3+1)*4^level - 1) / 3
173							# = ((6L+4)*4^level - 1) / 3
174							# n = ((6L+4)*4^level - 1) / 3
175							# 3n+1 = (6L+4)*4^level
176							#
177							# len(k) = 2*len(k-1) + 2
178							# = 2*len(k-2) + 2 + 4
179							# = 2*len(k-3) + 2 + 4 + 8
180							# = 2^(k-1)*L + 2^k - 2
181							# = (L+2)*2^(k-1) - 2
182							# L=2 k=3 len=(2+2)*2^2-2=14
183							#
184							# ----------
185							# Nlevel = ((6L+4)*4^level - 1) / 3 - 1
186							# = ((6L+4)*4^level - 4) / 3
187							# Xlevel = (L+2)*2^level - 2 + 1
188							# = (L+2)*2^level - 1
189							#
190							# fill = Nlevel / (Xlevel*(Xlevel-1)/2)
191							# = (((6L+4)4^level - 1) / 3 - 1) / (((L+2)2^level - 1)((L+2)2^level - 2))
192							# -> (((6L+4)4^level) / 3) / ((L+2)2^level)^2
193							# = ((6L+4)4^level) / ((L+2)^24^level) *2/3
194							# = ((6L+4)) / ((L+2)^2) * 2/3
195							# = 2(3L+2) / ((L+2)^2) 2/3
196							# = 4/3 * (3L+2)/(L+2)^2
197							# = (12L+8) / (3*L^2+12L+12)
198							# L=1 (12+8)/(3+12+12) = 20/27
199
200
201							sub n_to_xy {
202	19			19	1	1097	my ($self, $n) = @_;
203							### SierpinskiCurveStair n_to_xy(): $n
204
205	19	50				50	if ($n < 0) {
206	0					0	return;
207							}
208	19	50				51	if (is_infinite($n)) {
209	0					0	return ($n,$n);
210							}
211
212	19					35	my $frac;
213							{
214	19					27	my $int = int($n);
	19					28
215	19					32	$frac = $n - $int; # inherit possible BigFloat
216	19	50				36	if ($frac) {
217	0					0	my ($x1,$y1) = $self->n_to_xy($int);
218	0					0	my ($x2,$y2) = $self->n_to_xy($int+$self->{'arms'});
219
220	0					0	my $dx = $x2-$x1;
221	0					0	my $dy = $y2-$y1;
222	0					0	return ($frac$dx + $x1, $frac$dy + $y1);
223							}
224	19					29	$n = $int; # BigFloat int() gives BigInt, use that
225							}
226							### $frac
227	19					32	my $zero = ($n * 0); # inherit bignum 0
228
229	19					54	my $arm = _divrem_mutate ($n, $self->{'arms'});
230
231	19					34	my $diagonal_length = $self->{'diagonal_length'};
232	19					58	my $diagonal_div = 6*$diagonal_length + 4;
233
234	19					59	my ($nlen,$level) = round_down_pow ((3*$n+1)/$diagonal_div, 4);
235							### $nlen
236							### $level
237	19	50				43	if (is_infinite($level)) {
238	0					0	return $level;
239							}
240
241	19					32	my $x = $zero;
242	19					34	my $y = $zero;
243	19					25	my $dx = 1;
244	19					27	my $dy = 0;
245
246							# (L+2)*2^(level-1) - 2
247	19					36	my $len = ($diagonal_length+2)2*$level - 2;
248	19					64	$nlen = ($diagonal_div*$nlen-1)/3;
249
250	19					42	while ($level-- >= 0) {
251							### at: "n=$n xy=$x,$y nlen=$nlen len=$len"
252
253	52	100				92	if ($n < 2*$nlen+1) {
254	19	100				40	if ($n < $nlen) {
255							### part 0 ...
256							} else {
257							### part 1 ...
258	18					27	$x += ($len+1)$dx - $len$dy;
259	18					31	$y += ($len+1)$dy + $len$dx;
260	18					36	($dx,$dy) = ($dy,-$dx); # rotate -90
261	18					27	$n -= $nlen;
262							}
263							} else {
264	33					50	$n -= 2*$nlen+1;
265	33	50				55	if ($n < $nlen) {
266							### part 2 ...
267	0					0	$x += (2$len+2)$dx - $dy;
268	0					0	$y += (2$len+2)$dy + $dx;
269	0					0	($dx,$dy) = (-$dy,$dx); # rotate +90
270							} else {
271							### part 3 ...
272	33					133	$x += ($len+2)$dx - ($len+2)$dy;
273	33					52	$y += ($len+2)$dy + ($len+2)$dx;
274	33					46	$n -= $nlen;
275							}
276							}
277
278	52					79	$nlen = ($nlen-1)/4;
279	52					100	$len = $len/2-1;
280							}
281
282	19					35	my $lowdigit_x = int(($n+1)/2);
283	19	100				40	if ($n == 2*$diagonal_length+1) { $lowdigit_x -= 2; }
	5					8
284	19					30	my $lowdigit_y = int($n/2);
285
286							### final: "n=$n xy=$x,$y dxdy=$dx,$dy"
287							### $lowdigit_x
288							### $lowdigit_y
289
290	19					31	$x += $lowdigit_x$dx - $lowdigit_y$dy + 1; # +1 start at x=1,y=0
291	19					27	$y += $lowdigit_x$dy + $lowdigit_y$dx;
292
293	19	50				40	if ($arm & 1) {
294	0					0	($x,$y) = ($y,$x); # mirror 45
295							}
296	19	50				33	if ($arm & 2) {
297	0					0	($x,$y) = (-1-$y,$x); # rotate +90
298							}
299	19	50				35	if ($arm & 4) {
300	0					0	$x = -1-$x; # rotate 180
301	0					0	$y = -1-$y;
302							}
303
304	19					68	return ($x,$y);
305							}
306
307							sub xy_to_n {
308	19776			19776	1	197842	my ($self, $x, $y) = @_;
309							### SierpinskiCurveStair xy_to_n(): "$x, $y"
310
311	19776					37514	$x = round_nearest($x);
312	19776					37144	$y = round_nearest($y);
313
314	19776					28309	my $arm = 0;
315	19776	100				34422	if ($y < 0) {
316	2720					3788	$arm = 4;
317	2720					3801	$x = -1-$x; # rotate -180
318	2720					3738	$y = -1-$y;
319							}
320	19776	100				34226	if ($x < 0) {
321	4608					6249	$arm += 2;
322	4608					8188	($x,$y) = ($y, -1-$x); # rotate -90
323							}
324	19776	100				33300	if ($y > $x) { # second octant
325	9344					12144	$arm++;
326	9344					17702	($x,$y) = ($y,$x); # mirror 45
327							}
328
329	19776					30413	my $arms = $self->{'arms'};
330	19776	100				34388	if ($arm >= $arms) {
331	3680					6641	return undef;
332							}
333
334	16096					22499	$x -= 1;
335	16096	100	100			44804	if ($x < 0 \|\| $x < $y) {
336	1008					1954	return undef;
337							}
338							### x adjust to zero: "$x,$y"
339							### assert: $x >= 0
340							### assert: $y >= 0
341
342							# len=2*(2^level - 1)
343							# len/2+1 = 2^level
344							# 2^level = len/2+1
345							# 2^(level+1) = len+2
346
347							# len=(L+2)*2^(level-1) - 2
348							# (len+2)/(L+2) = 2^(level-1)
349
350	15088					21741	my $diagonal_length = $self->{'diagonal_length'};
351	15088					35936	my ($len,$level) = round_down_pow (($x+1)/($diagonal_length+2), 2);
352							### $level
353							### $len
354	15088	50				31242	if (is_infinite($level)) {
355	0					0	return $level;
356							}
357
358	15088					25008	my $n = 0;
359	15088					26694	my $nlen = ((6$diagonal_length+4)$len*$len-1)/3;
360	15088					23288	$len *= ($self->{'diagonal_length'}+2);
361							### $len
362							### $nlen
363
364	15088					19673	my $n_last_1;
365	15088					25846	foreach (0 .. $level) {
366							### at: "loop=$_ x=$x,y=$y n=$n nlen=$nlen len=$len diag cmp ".(2*$len-2)
367							### assert: $x >= 0
368							### assert: $y >= 0
369
370	37510	100				66516	if ($x+$y <= 2*$len-2) {
371							### part 0 or 1...
372	20665	100				33157	if ($x < $len-1) {
373							### part 0 ...
374	6256					8817	$n_last_1 = 0;
375							} else {
376							### part 1 ...
377	14409					24100	($x,$y) = ($len-2-$y, $x-($len-1)); # shift then rotate +90
378	14409					20487	$n += $nlen;
379	14409					19991	$n_last_1 = 1;
380							}
381							} else {
382	16845					24795	$n += 2*$nlen + 1; # +1 for middle point
383							### part 2 or 3 ...
384	16845	100				26474	if ($y < $len) {
385							### part 2...
386	8671					15341	($x,$y) = ($y-1, 2*$len-2-$x); # shift y-1 then rotate -90
387	8671					12154	$n_last_1 = 0;
388							} else {
389							#### digit 3...
390	8174					11382	$x -= $len;
391	8174					10696	$y -= $len;
392	8174					10720	$n += $nlen;
393							}
394	16845	100				30450	if ($x < 0) {
395	81					247	return undef;
396							}
397							}
398	37429					51297	$len /= 2;
399	37429					59932	$nlen = ($nlen-1)/4;
400							}
401
402							### end at: "x=$x,y=$y n=$n last2=$n_last_1"
403							### assert: $x >= 0
404							### assert: $y >= 0
405
406	15007	100	100			47336	if ($x == $y \|\| $x == $y+1) {
		100	100
			100
407	8932					12968	$n += $x+$y;
408							} elsif ($n_last_1 && $x == $diagonal_length-1 && $y == $diagonal_length) {
409							# in between diagonals
410	458					749	$n += 2*$diagonal_length+1;
411							} else {
412	5617					13204	return undef;
413							}
414
415	9390					20132	return $n*$arms + $arm;
416							}
417
418							# not exact
419							sub rect_to_n_range {
420	32			32	1	218	my ($self, $x1,$y1, $x2,$y2) = @_;
421							### SierpinskiCurveStair rect_to_n_range(): "$x1,$y1 $x2,$y2"
422
423	32					96	$x1 = round_nearest ($x1);
424	32					79	$x2 = round_nearest ($x2);
425	32					65	$y1 = round_nearest ($y1);
426	32					69	$y2 = round_nearest ($y2);
427	32	50				127	($x1,$x2) = ($x2,$x1) if $x1 > $x2;
428	32	50				75	($y1,$y2) = ($y2,$y1) if $y1 > $y2;
429
430							# x2
431							# y2 +-------+ *
432							# \| \| *
433							# y1 +-------+ *
434							# *
435							# *
436							# *
437							# ------------------
438							#
439							#
440							# *
441							# x1 * x2 *
442							# +------+y2
443							# \| \|
444							# \| * *
445							# \| \|* *
446							# \| \| **
447							# +-------+y1*
448							# ----------------
449							#
450	32					75	my $arms = $self->{'arms'};
451	32	100	33			250	if (($arms <= 4
		50	33
452							? ($y2 < 0 # y2 negative, nothing ...
453							\|\| ($arms == 1 && $x2 <= $y1)
454							\|\| ($arms == 2 && $x2 < 0)
455							\|\| ($arms == 3 && $x2 < -$y2))
456
457							# arms >= 5
458							: ($y2 < 0
459							&& (($arms == 5 && $x1 >= $y2)
460							\|\| ($arms == 6 && $x1 >= 0)
461							\|\| ($arms == 7 && $x1 > 3-$y2))))) {
462							### rect outside octants, for arms: $arms
463							### $x1
464							### $y2
465	0					0	return (1,0);
466							}
467
468	32					68	my $max = $x2; # arms 1,8 using X, starting at X=1
469	32	100				91	if ($arms >= 2) {
470							# arms 2,3 upper using Y, starting at Y=1
471	28					99	_apply_max ($max, $y2);
472
473	28	100				83	if ($arms >= 4) {
474							# arms 4,5 right using X, starting at X=-2
475	20					62	_apply_max ($max, -1-$x1);
476
477	20	100				84	if ($arms >= 6) {
478							# arms 6,7 down using Y, starting at Y=-2
479	12					33	_apply_max ($max, -1-$y1);
480							}
481							}
482							}
483							### $max
484
485
486							# points(level) = (4^(level+2) - 1) / 3
487							# Nlast(level) = (4^(level+2) - 1) / 3 - 1
488							# = (4^(level+2) - 4) / 3
489							# then + arms-1 for last of arms
490							# Nhi = Nlast(level) * arms + arms-1
491							# = (Nlast(level + 1)) * arms - 1
492							# = ((4^(level+2) - 4) / 3 + 1) * arms - 1
493							# = ((4^(level+2) - 1) / 3) * arms - 1
494							#
495							# len(level) = = (L+2)*2^(level-1) - 2
496							# points(level) = ((3P+1)4^level - 1) / 3
497							#
498	32					138	my ($pow,$level) = round_down_pow ($max/($self->{'diagonal_length'}+2),
499							2);
500							return (0,
501	32					156	((6$self->{'diagonal_length'}+4)4$pow$pow - 1) / 3
502							* $arms - 1);
503							}
504
505							# set $_[0] to the max of $_[0] and $_[1]
506							sub _apply_max {
507							### _apply_max(): "$_[0] cf $_[1]"
508	60	100		60		176	unless ($_[0] > $_[1]) {
509	28					62	$_[0] = $_[1];
510							}
511							}
512
513
514							#------------------------------------------------------------------------------
515
516							# Nlevel = ((3L+2)*4^level - 5) / 3
517							# LevelPoints = Nlevel+1
518							# Nlevel(arms) = (Nlevel+1)*arms - 1
519							#
520							# Eg. L=1 level=1 (5*4-5)/3 = 5
521							# arms=8 ((54-5)/3+1)8 - 1 = 47
522							#
523
524							sub level_to_n_range {
525	12			12	1	773	my ($self, $level) = @_;
526							return (0,
527							(4*$level (3*$self->{'diagonal_length'}+2) - 2) / 3
528	12					54	* $self->{'arms'} - 1);
529							}
530							sub n_to_level {
531	0			0	1		my ($self, $n) = @_;
532	0	0					if ($n < 0) { return undef; }
	0
533	0	0					if (is_infinite($n)) { return $n; }
	0
534	0						$n = round_nearest($n);
535	0						_divrem_mutate ($n, $self->{'arms'});
536	0						my $diagonal_div = 3*$self->{'diagonal_length'} + 2;
537	0						my ($pow,$exp) = round_up_pow ((3$n+3) / (3$self->{'diagonal_length'}+2),
538							4);
539	0						return $exp;
540							}
541
542							#------------------------------------------------------------------------------
543							1;
544							__END__