mazealls
Sometimes magic is just someone spending more time on something than anyone else might reasonably expect. -- Teller
Generate mazes recursively via Turtle graphics.
-- Steven E. Pav, shabbychef@gmail.com
Installation
This package can be installed from CRAN, via drat, or from github:
# via CRAN:
install.packages("mazealls")
# via drat:
if (require(drat)) {
drat:::add("shabbychef")
install.packages("mazealls")
}
# get snapshot from github (may be buggy)
if (require(devtools)) {
install_github("shabbychef/mazealls")
}parallelogram maze
The simplest maze to generate recursively is a parallelogram. One can generate
a parallelogram maze by splitting the domain into two parts by an arbitrary
cut line with a hole in it, and then recursively creating mazes on both parts.
Unlike some shapes, this method applies for arbitrary (integral) side lengths,
where by 'length' we mean in units of 'hallway widths', what we call the
unit_len in the API. Here is a simple parallelogram maze:
library(TurtleGraphics)
library(mazealls)
turtle_init(1000, 1000)
turtle_up()
turtle_hide()
turtle_do({
turtle_left(90)
turtle_forward(distance = 400)
turtle_right(90)
parallelogram_maze(angle = 90, unit_len = 10, width = 75,
height = 55, method = "uniform", draw_boundary = TRUE)
})
The parallelogram_maze function admits a balance parameter which controls
how the maze should be recursively subdivided. A negative value creates
imbalanced mazes, while positive values create more uniform mazes. In the
example below we create seven mazes side by side with an increasing balance
parameter:
library(TurtleGraphics)
library(mazealls)
turtle_init(2000, 2000)
turtle_hide()
turtle_up()
turtle_do({
turtle_left(90)
turtle_forward(930)
turtle_right(90)
valseq <- seq(from = -1.5, to = 1.5, length.out = 7)
blines <- c(1, 2, 3, 4)
bholes <- c(1, 3)
set.seed(1234)
for (iii in seq_along(valseq)) {
parallelogram_maze(angle = 90, unit_len = 12,
width = 22, height = 130, method = "two_parallelograms",
draw_boundary = TRUE, balance = valseq[iii],
end_side = 3, boundary_lines = blines,
boundary_holes = bholes)
turtle_right(180)
blines <- c(2, 3, 4)
bholes <- c(3)
}
})
triangle maze
An equilateral triangle maze can be constructed in a number of different ways:
- Create four equilateral mazes with lines with holes between them. This only works if the side length of the original is a power of two.
- Cut out a parallelogram and attach two equilateral triangles. Again only if the side length is a power of two.
- Create an isosceles trapezoid maze, then stack an equilateral triangle on top of it. This only works if the side length is even.
- Create a regular hexagonal maze and three equilateral mazes in the corners. This only works if the side length of the original triangle is divisible by three.
- Shave off a single hallway and create an equilateral triangular maze of side length one less than the original.
I illustrate them here:
library(TurtleGraphics)
library(mazealls)
# uniform method
turtle_init(1000, 1000)
turtle_up()
turtle_hide()
turtle_do({
turtle_left(90)
turtle_forward(distance = 300)
turtle_right(90)
eq_triangle_maze(depth = 6, unit_len = 12, method = "uniform",
draw_boundary = TRUE)
})
library(TurtleGraphics)
library(mazealls)
# stacked trapezoids
turtle_init(1000, 1000)
turtle_up()
turtle_hide()
turtle_do({
turtle_left(90)
turtle_forward(distance = 300)
turtle_right(90)
eq_triangle_maze(depth = 6, unit_len = 12, method = "stack_trapezoids",
draw_boundary = TRUE)
})
library(TurtleGraphics)
library(mazealls)
# four triangles
turtle_init(1000, 1000)
turtle_up()
turtle_hide()
turtle_do({
turtle_left(90)
turtle_forward(distance = 300)
turtle_right(90)
eq_triangle_maze(depth = 6, unit_len = 12, method = "triangles",
draw_boundary = TRUE)
})
library(TurtleGraphics)
library(mazealls)
# two ears
turtle_init(1000, 1000)
turtle_up()
turtle_hide()
turtle_do({
turtle_left(90)
turtle_forward(distance = 300)
turtle_right(90)
eq_triangle_maze(depth = 6, unit_len = 12, method = "two_ears",
draw_boundary = TRUE)
})
library(TurtleGraphics)
library(mazealls)
# hex and three
turtle_init(1000, 1000)
turtle_up()
turtle_hide()
turtle_do({
turtle_left(90)
turtle_forward(distance = 300)
turtle_right(90)
eq_triangle_maze(depth = log2(66), unit_len = 12,
method = "hex_and_three", draw_boundary = TRUE)
})
library(TurtleGraphics)
library(mazealls)
# shave
turtle_init(1000, 1000)
turtle_up()
turtle_hide()
turtle_do({
turtle_left(90)
turtle_forward(distance = 300)
turtle_right(90)
eq_triangle_maze(depth = log2(66), unit_len = 12,
method = "shave", draw_boundary = TRUE)
})
library(TurtleGraphics)
library(mazealls)
# shave all
turtle_init(1000, 1000)
turtle_up()
turtle_hide()
turtle_do({
turtle_left(90)
turtle_forward(distance = 300)
turtle_right(90)
eq_triangle_maze(depth = log2(66), unit_len = 12,
method = "shave_all", draw_boundary = TRUE,
boustro = c(35, 2))
})
hexagon maze
An regular hexagonal maze can be constructed in a number of different ways:
- Decompose the hexagon as 6 equilateral triangle mazes, with one solid line and five lines with holes dividing them.
- Create two isosceles trapezoid mazes with long sides joined by a line with a hole.
- Create three parallelogram mazes with one solid line and two lines with holes dividing them.
library(TurtleGraphics)
library(mazealls)
# two trapezoids
turtle_init(1000, 1000)
turtle_up()
turtle_hide()
turtle_do({
turtle_left(90)
turtle_forward(distance = 300)
turtle_right(90)
hexagon_maze(depth = 5, unit_len = 12, method = "two_trapezoids",
draw_boundary = TRUE)
})
library(TurtleGraphics)
library(mazealls)
# six triangles
turtle_init(1000, 1000)
turtle_up()
turtle_hide()
turtle_do({
turtle_left(90)
turtle_forward(distance = 300)
turtle_right(90)
hexagon_maze(depth = 5, unit_len = 12, method = "six_triangles",
draw_boundary = TRUE, boundary_hole_arrows = TRUE)
})
library(TurtleGraphics)
library(mazealls)
# six triangles
turtle_init(1000, 1000)
turtle_up()
turtle_hide()
turtle_do({
turtle_left(90)
turtle_forward(distance = 300)
turtle_right(90)
hexagon_maze(depth = 5, unit_len = 12, method = "three_parallelograms",
draw_boundary = TRUE, boundary_hole_arrows = TRUE)
})
dodecagon maze
A dodecagon can be dissected into a hexagon and a ring of alternating squares and equilateral triangles:
library(TurtleGraphics)
library(mazealls)
# dodecagon
turtle_init(2200, 2200, mode = "clip")
turtle_hide()
turtle_up()
turtle_do({
turtle_setpos(80, 1100)
turtle_setangle(0)
dodecagon_maze(depth = log2(27), unit_len = 20,
draw_boundary = TRUE, boundary_holes = c(1,
7))
})
trapezoid maze
An isosceles trapezoid maze can be constructed in a number of different ways:
- Decompose as four trapezoidal mazes with a 'bone' shape between them consisting of two solid lines and three lines with holes.
- Decompose as a parallelogram and an equilateral triangle with a line with holes between them
library(TurtleGraphics)
library(mazealls)
# four trapezoids
turtle_init(1000, 1000)
turtle_up()
turtle_hide()
turtle_do({
turtle_left(90)
turtle_forward(distance = 300)
turtle_right(90)
iso_trapezoid_maze(depth = 5, unit_len = 12, method = "four_trapezoids",
draw_boundary = TRUE)
})
library(TurtleGraphics)
library(mazealls)
# one ear
turtle_init(1000, 1000)
turtle_up()
turtle_hide()
turtle_do({
turtle_left(90)
turtle_forward(distance = 300)
turtle_right(90)
iso_trapezoid_maze(depth = 5, unit_len = 12, method = "one_ear",
draw_boundary = TRUE)
})
Rhombic Dissections
Regular 2n gons usually admit a dissection into rhombuses. Sometimes, however, these have extremely acute angles, which do not translate into nice mazes. At the moment, there is only support for octagons, and decagons. While a dodecagon would also admit such a dissection, this would require extremely acute angles which would make an ugly maze.
library(TurtleGraphics)
library(mazealls)
# octagon
turtle_init(2000, 2000, mode = "clip")
turtle_hide()
turtle_up()
turtle_do({
turtle_setpos(75, 1000)
turtle_setangle(0)
octagon_maze(log2(48), 16, draw_boundary = TRUE,
boundary_holes = c(1, 5))
})
library(TurtleGraphics)
library(mazealls)
# decagon
turtle_init(2200, 2200, mode = "clip")
turtle_hide()
turtle_up()
turtle_do({
turtle_setpos(60, 1100)
turtle_setangle(0)
decagon_maze(5, 21, draw_boundary = TRUE, boundary_holes = c(1,
6))
})
Fractal mazes
Koch snowflake maze
Everyone's favorite snowflake can also be a maze. Simply fill in triangle bumps with triangular mazes and create lines with holes as needed:
library(TurtleGraphics)
library(mazealls)
# koch flake
turtle_init(1000, 1000)
turtle_up()
turtle_hide()
turtle_do({
turtle_left(90)
turtle_forward(distance = 200)
turtle_right(90)
turtle_backward(distance = 300)
koch_maze(depth = 4, unit_len = 8)
})
Koch flakes of different sizes tile the plane:
library(TurtleGraphics)
library(mazealls)
# koch flake
turtle_init(2000, 2000, mode = "clip")
turtle_up()
turtle_hide()
turtle_do({
turtle_setpos(450, 1000)
turtle_setangle(60)
ul <- 12
dep <- 4
koch_maze(depth = dep, unit_len = ul, clockwise = TRUE,
draw_boundary = FALSE)
turtle_left(30)
turtle_col("gray40")
dropdown <- 1
for (iii in c(1:6)) {
if (iii == 1) {
bholes <- c(1, 2)
} else if (iii == 4) {
bholes <- c(1, 3)
} else {
bholes <- c(1)
}
koch_maze(depth = dep - dropdown, unit_len = ul *
(3^(dropdown - 0.5)), clockwise = FALSE,
draw_boundary = TRUE, boundary_holes = bholes,
boundary_hole_arrows = c(2, 3))
turtle_forward(3^(dep - 1) * ul * sqrt(3))
turtle_right(60)
}
})
Sierpinski Triangle
Similarly, one can construct a maze in a Sierpinski triangle.
library(TurtleGraphics)
library(mazealls)
turtle_init(2500, 2500, mode = "clip")
turtle_up()
turtle_hide()
turtle_do({
turtle_setpos(50, 1250)
turtle_setangle(0)
sierpinski_maze(unit_len = 19, depth = 7, draw_boundary = TRUE,
boundary_lines = TRUE, boundary_holes = c(1,
3), color1 = "black", color2 = "gray60")
})
And a Sierpinski Carpet:
library(TurtleGraphics)
library(mazealls)
turtle_init(800, 1000)
turtle_up()
turtle_hide()
turtle_do({
turtle_setpos(50, 450)
turtle_setangle(0)
sierpinski_carpet_maze(angle = 80, unit_len = 8,
width = 90, height = 90, draw_boundary = TRUE,
boundary_holes = c(1, 3), balance = 1.5, color2 = "green")
})
library(TurtleGraphics)
library(mazealls)
turtle_init(2000, 2000, mode = "clip")
turtle_hide()
turtle_up()
bholes <- list(c(1, 2), c(1), c(2))
turtle_do({
turtle_setpos(1000, 1000)
turtle_setangle(180)
for (iii in c(1:3)) {
mybhol <- bholes[[iii]]
sierpinski_carpet_maze(angle = 120, unit_len = 11,
width = 81, height = 81, draw_boundary = TRUE,
boundary_lines = c(1, 2, 3), num_boundary_holes = 0,
boundary_holes = mybhol, balance = 1, color2 = "green",
start_from = "corner")
turtle_left(120)
}
})
One can make four different kinds of Sierpinski trapezoids, the traditional four triangles, a hexaflake, and something like a Dragon fractal:
library(TurtleGraphics)
library(mazealls)
turtle_init(1050, 600, mode = "clip")
turtle_hide()
turtle_up()
turtle_do({
for (iii in c(1:4)) {
turtle_setpos(40 + (iii - 1) * 250, 300)
turtle_setangle(0)
sierpinski_trapezoid_maze(unit_len = 8, depth = 5,
draw_boundary = TRUE, start_from = "midpoint",
num_boundary_holes = 2, boundary_holes = c(2,
4), color2 = "green", flip_color_parts = iii) # this controls fractal style
}
})
Hexaflake
A hexaflake is a cross between a Koch snowflake and a Sierpinski triangle, at least in theory.
library(TurtleGraphics)
library(mazealls)
# hexaflake
long_side <- 2400
inner_side <- long_side * sqrt(3)/2
sidelen <- long_side/2
dep <- 4
ul <- floor(sidelen/(3^dep))
true_wid <- 2 * ul * 3^dep * sqrt(3)/2
turtle_init(ceiling(1.1 * inner_side), ceiling(1.1 *
long_side), mode = "clip")
turtle_up()
turtle_hide()
turtle_do({
turtle_setpos(0.5 * (ceiling(1.1 * inner_side) -
true_wid), 0.55 * long_side)
turtle_setangle(0)
hexaflake_maze(depth = dep, unit_len = floor(sidelen/(3^dep)),
draw_boundary = TRUE, color2 = "gray80")
})
Controls
unit length
The unit_len parameter controls the graphical length of one 'unit', which is
the length of holes between sections of the mazes, and is roughly the width
of the 'hallways' of a maze. Here is an example of using different
unit lengths in a stack of trapezoids
library(TurtleGraphics)
library(mazealls)
# stack some trapezoids with different unit_len
turtle_init(2500, 2500)
turtle_up()
turtle_hide()
turtle_do({
turtle_left(90)
turtle_forward(distance = 800)
turtle_right(90)
clockwise <- TRUE
for (iii in c(1:6)) {
iso_trapezoid_maze(depth = 5, unit_len = 2^(6 -
iii), method = "four_trapezoids", draw_boundary = TRUE,
clockwise = clockwise, end_side = 3, start_from = "midpoint",
boundary_lines = c(1, 2, 4), boundary_holes = c(1))
clockwise <- !clockwise
}
})
boundaries
The parameters draw_boundary, boundary_lines, boundary_holes, num_boundary_holes and boundary_hole_color control
the drawing of the final outer boundary of polynomial mazes. Without a boundary
the maze can be used in recursive construction. Adding a boundary provides the
typical entry and exit points of a maze. The parameter draw_boundary is a
single Boolean that controls whether the boundary is drawn or not.
The parameter boundary_lines may be a scalar Boolean, or a numeric
array giving the indices of which sides should have drawn boundary lines.
The sides are numbered in the order in which they appear, and are
controlled by the clockwise parameter. The parameter boundary_holes
is a numeric array giving the indices of the boundary lines that should
have holes. If NULL, then we uniformly choose num_boundary_holes holes
at random. Holes can be drawn as colored segments with the
boundary_hole_color, which is a character array giving the color of each
hole. The value 'clear' stands in for clear holes.
library(TurtleGraphics)
library(mazealls)
# side by side
turtle_init(1000, 400)
turtle_up()
turtle_hide()
turtle_do({
turtle_left(90)
turtle_forward(distance = 450)
turtle_right(90)
parallelogram_maze(unit_len = 10, height = 25,
draw_boundary = FALSE, end_side = 3)
turtle_left(90)
turtle_forward(distance = 30)
turtle_left(90)
parallelogram_maze(unit_len = 10, height = 25,
draw_boundary = TRUE, boundary_lines = c(1,
3), boundary_holes = FALSE, end_side = 3)
turtle_left(90)
turtle_forward(distance = 30)
turtle_left(90)
parallelogram_maze(unit_len = 10, height = 25,
draw_boundary = TRUE, boundary_lines = c(2,
4), boundary_holes = c(2, 4), boundary_hole_color = c("ignore",
"green", "ignore", "blue"))
})
end side
The end_side parameter controls which side of the maze the turtle ends on.
The default value of 1 essentially causes the turtle to end where it
started. The sides are numbered in the order in which the boundary would be
drawn. Along with the boundary controls, the ending side can be useful to join together
polygons into more complex mazes, as below:
library(TurtleGraphics)
library(mazealls)
# triangle of hexes
turtle_init(2500, 2500)
turtle_up()
turtle_hide()
ul <- 22
dep <- 4
turtle_do({
turtle_left(90)
turtle_forward(distance = 1150)
turtle_right(90)
turtle_backward(distance = 650)
hexagon_maze(unit_len = ul, depth = dep, end_side = 4,
draw_boundary = TRUE, boundary_holes = c(1,
3, 4))
parallelogram_maze(unit_len = ul, height = 2^dep,
clockwise = FALSE, width = 3 * (2^dep), end_side = 3,
draw_boundary = TRUE, num_boundary_holes = 0,
boundary_lines = c(2, 4))
hexagon_maze(unit_len = ul, depth = dep, end_side = 2,
draw_boundary = TRUE, boundary_holes = c(1,
2))
parallelogram_maze(unit_len = ul, height = 2^dep,
clockwise = FALSE, width = 3 * (2^dep), end_side = 3,
draw_boundary = TRUE, num_boundary_holes = 0,
boundary_lines = c(2, 4))
hexagon_maze(unit_len = ul, depth = dep, end_side = 2,
draw_boundary = TRUE, boundary_holes = c(1,
5))
parallelogram_maze(unit_len = ul, height = 2^dep,
clockwise = FALSE, width = 3 * (2^dep), end_side = 3,
draw_boundary = TRUE, num_boundary_holes = 0,
boundary_lines = c(2, 4))
})
library(TurtleGraphics)
library(mazealls)
# tiling!
tile_bit <- function(unit_len, depth, clockwise = TRUE,
draw_boundary = FALSE, boundary_holes = NULL) {
turtle_col("black")
parallelogram_maze(unit_len = unit_len, height = 2^depth,
clockwise = clockwise, draw_boundary = TRUE,
num_boundary_holes = 4)
turtle_col("red")
for (iii in c(1:4)) {
turtle_forward(unit_len * 2^(depth - 1))
turtle_right(90)
turtle_forward(unit_len * 2^(depth - 1))
eq_triangle_maze(unit_len = unit_len, depth = depth,
clockwise = !clockwise, draw_boundary = draw_boundary,
boundary_lines = ifelse(iii <= 2, 2, 3),
num_boundary_holes = 3, end_side = ifelse(iii ==
4, 2, 1))
if (iii == 2) {
turtle_col("blue")
}
}
turtle_col("black")
if (draw_boundary) {
blines <- c(1, 2, 4)
} else {
blines = 1
}
parallelogram_maze(unit_len = unit_len, height = 2^depth,
clockwise = clockwise, draw_boundary = TRUE,
boundary_lines = blines, boundary_holes = blines,
end_side = 3)
turtle_forward(unit_len * 2^(depth - 1))
turtle_left(60)
turtle_forward(unit_len * 2^(depth - 1))
}
turtle_init(2500, 2500, mode = "clip")
turtle_up()
turtle_hide()
x0 <- 220
y0 <- 0
ul <- 20
dep <- 5
turtle_do({
for (jjj in c(1:5)) {
turtle_setpos(x = x0, y = y0)
turtle_setangle(angle = 0)
replicate(5, tile_bit(unit_len = ul, depth = dep,
draw_boundary = TRUE))
x0 <- x0 + ul * (2^dep) * (1 + sqrt(3)/2)
y0 <- y0 + ul * (2^(dep - 1))
}
})
Fun
Or whatever you call it. Here are some mazes built using the primitives.
A dumb looking tree
Like it says on the label.
library(TurtleGraphics)
library(mazealls)
treeit <- function(unit_len, depth, height, left_shrink = 3/4,
right_shrink = 1/3) {
height <- ceiling(height)
parallelogram_maze(unit_len = unit_len, height = 2^depth,
width = height, clockwise = TRUE, draw_boundary = TRUE,
boundary_lines = c(1, 2, 4), start_from = "midpoint",
boundary_holes = c(1), end_side = 3)
if (depth > 0) {
iso_trapezoid_maze(depth = depth - 1, unit_len = unit_len,
clockwise = FALSE, draw_boundary = TRUE,
boundary_lines = c(1, 3), start_from = "midpoint",
boundary_holes = c(1), end_side = 4)
treeit(unit_len = unit_len, depth = depth -
1, height = left_shrink * height, left_shrink = left_shrink,
right_shrink = right_shrink)
turtle_right(180)
turtle_forward(unit_len * 2^(depth - 2))
turtle_right(60)
turtle_forward(unit_len * 2^(depth - 1))
turtle_right(60)
turtle_forward(unit_len * 2^(depth - 2))
turtle_right(180)
treeit(unit_len = unit_len, depth = depth -
1, height = right_shrink * height, left_shrink = left_shrink,
right_shrink = right_shrink)
turtle_forward(unit_len * 2^(depth - 2))
turtle_left(60)
turtle_forward(unit_len * 2^(depth - 2))
turtle_left(90)
turtle_forward(unit_len * sqrt(3) * 2^(depth -
2))
turtle_left(90)
}
turtle_right(90)
turtle_forward(unit_len * height)
turtle_right(90)
}
turtle_init(2500, 2500, mode = "clip")
turtle_up()
turtle_hide()
turtle_do({
turtle_setpos(1600, 20)
turtle_setangle(270)
treeit(unit_len = 13, depth = 5, height = 70, left_shrink = 2/3,
right_shrink = 1/3)
})
A hex spiral
turtle_init(2500, 2500, mode = "clip")
turtle_up()
turtle_hide()
della <- -3
lens <- seq(from = 120, to = 2 - della, by = della)
ulen <- 10
high <- 14
turtle_do({
turtle_setpos(260, 570)
turtle_setangle(270)
for (iter in seq_along(lens)) {
parallelogram_maze(unit_len = ulen, height = high,
width = lens[iter], start_from = "corner",
clockwise = TRUE, draw_boundary = TRUE,
boundary_holes = c(1, 3), end_side = 3)
eq_triangle_maze(unit_len = ulen, depth = log2(high),
start_from = "corner", clockwise = FALSE,
draw_boundary = TRUE, boundary_lines = c(3),
num_boundary_holes = 0, boundary_holes = rep(FALSE,
3), end_side = 2)
}
parallelogram_maze(unit_len = ulen, height = high,
width = lens[iter] + della, start_from = "corner",
clockwise = TRUE, draw_boundary = TRUE, boundary_holes = c(1,
3), end_side = 3)
})
A rectangular spiral
Well, a rhombus spiral.
rect_spiral <- function(unit_len, height, width, thickness = 8L,
angle = 90, clockwise = TRUE, start_hole = FALSE) {
if (start_hole) {
bholes <- 1
fourl_dist <- height - thickness
} else {
bholes <- 4
fourl_dist <- height
}
last_one <- (width < thickness)
if (last_one) {
blines <- 1:4
bholes <- c(3, bholes)
} else {
blines <- c(1, 2, 4)
}
blocs <- -sample.int(n = thickness, size = 4, replace = TRUE)
parallelogram_maze(unit_len = unit_len, height = thickness,
width = fourl_dist, angle = 180 - angle, start_from = "corner",
clockwise = clockwise, draw_boundary = TRUE,
boundary_lines = blines, boundary_holes = bholes,
boundary_hole_locations = blocs, end_side = 3)
if (clockwise) {
turtle_left(angle)
} else {
turtle_right(angle)
}
if (!last_one) {
rect_spiral(unit_len, height = width, width = height -
thickness, thickness = thickness, angle = 180 -
angle, clockwise = clockwise, start_hole = FALSE)
}
}
turtle_init(2500, 2500, mode = "clip")
turtle_up()
turtle_hide()
turtle_do({
turtle_setpos(300, 50)
turtle_setangle(270)
rect_spiral(unit_len = 20, 110, 90, thickness = 15,
angle = 80, start_hole = TRUE)
})
A double rectangular spiral
The path spirals in, then out, joining at the center. This might be buggy.
double_spiral <- function(unit_len, height, width,
thickness = 8L, angle = 90, clockwise = TRUE, start_hole = TRUE,
color1 = "black", color2 = "black") {
len1 <- height - thickness
bline1 <- c(1, 2, 4)
bline2 <- c(1, 3, 4)
bhole1 <- c(2)
if (start_hole) {
len2 <- len1
bline2 <- c(bline2, 2)
bhole1 <- c(bhole1, 4)
} else {
len2 <- len1 - 2 * thickness
}
blocs1 <- -sample.int(n = thickness, size = 4,
replace = TRUE)
blocs2 <- -sample.int(n = thickness, size = 4,
replace = TRUE)
last_one <- (min(len1, len2) <= 0) || (width <=
2 * thickness)
if (last_one) {
bhole2 <- c(4)
} else {
bhole2 <- c(3)
}
if (start_hole) {
bhole2 <- c(bhole2, 2)
}
second_stripe <- ((len2 > 0) && (width > thickness))
if (len1 > 0) {
turtle_col(color1)
parallelogram_maze(unit_len = unit_len, height = len1,
width = thickness, angle = angle, start_from = "corner",
clockwise = clockwise, draw_boundary = TRUE,
boundary_lines = bline1, boundary_holes = bhole1,
boundary_hole_locations = blocs1, end_side = ifelse(len2 >
0, 3, 2))
if (second_stripe) {
wid2 <- min(thickness, width - thickness)
turtle_col(color2)
parallelogram_maze(unit_len = unit_len,
height = len2, width = wid2, angle = 180 -
angle, start_from = "corner", clockwise = !clockwise,
draw_boundary = TRUE, boundary_lines = bline2,
boundary_holes = bhole2, boundary_hole_locations = blocs2,
end_side = 4)
turtle_col(color1)
turtle_forward(unit_len * (thickness +
wid2))
if (clockwise) {
turtle_right(180 - angle)
} else {
turtle_left(180 - angle)
}
turtle_forward(unit_len * thickness)
if (clockwise) {
turtle_right(angle)
} else {
turtle_left(angle)
}
}
}
next_height <- width
next_width <- ifelse(start_hole, height, height -
2 * thickness)
if (last_one) {
if (second_stripe) {
parallelogram_maze(unit_len = unit_len,
height = next_height, width = thickness,
start_from = "corner", angle = 180 -
angle, clockwise = clockwise)
} else {
parallelogram_maze(unit_len = unit_len,
height = next_height, width = thickness,
start_from = "corner", angle = angle,
clockwise = !clockwise)
}
} else {
double_spiral(unit_len, height = next_height,
width = next_width, thickness = thickness,
angle = 180 - angle, clockwise = clockwise,
start_hole = FALSE, color1 = color1, color2 = color2)
}
}
turtle_init(2500, 2500, mode = "clip")
turtle_up()
turtle_hide()
turtle_do({
turtle_setpos(300, 50)
turtle_setangle(0)
double_spiral(unit_len = 20, height = 100, width = 100,
thickness = 10, angle = 80, start_hole = TRUE,
color2 = "gray40")
})
A boustrophedon
As in ox that plods back and forth in a field.
boustro <- function(unit_len, height, width, thickness = 8L,
angle = 90, clockwise = TRUE, start_hole = TRUE,
balance = 0) {
if (start_hole) {
bholes <- c(1, 3)
blines <- 1:4
} else {
bholes <- c(1, 3)
blines <- 2:4
}
last_one <- (width < thickness)
blocs <- sample.int(n = thickness, size = 4, replace = TRUE)
parallelogram_maze(unit_len = unit_len, height = height,
width = thickness, angle = angle, balance = balance,
start_from = "corner", clockwise = clockwise,
draw_boundary = TRUE, boundary_lines = blines,
boundary_holes = bholes, boundary_hole_locations = blocs,
end_side = 3)
if (!last_one) {
boustro(unit_len, height = height, width = width -
thickness, thickness = thickness, angle = 180 -
angle, clockwise = !clockwise, start_hole = FALSE,
balance = balance)
}
}
turtle_init(2500, 2500, mode = "clip")
turtle_up()
turtle_hide()
turtle_do({
turtle_setpos(100, 50)
turtle_setangle(0)
boustro(unit_len = 26, height = 82, width = 80,
thickness = 8, angle = 85, balance = 1.5)
})
