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151 lines
12 KiB
Markdown
151 lines
12 KiB
Markdown
# Tes file format
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The tes file format is used to describe tessellations that can be loaded with HyperRogue/RogueViz.
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The format is designed to be written and read by humans, so all the numerical values can be provided
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as formulas.
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To load a tes file in HyperRogue, do: special modes -> experiment with geometry -> geometry -> hyperbolic* ->
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load from file. You can also do it with command line, e.g. `./hyperrogue -tes tessellations/sample/marjorie-rice.tes`.
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* You can also pick Euclidean or spherical here -- does not matter, any file can be loaded.
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## Structure
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A typical tes file consists of the following parts:
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* Name of the tessellation (as displayed in HyperRogue). This is given in a line starting with `##`.
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* Geometry. Usually `h2.` (hyperbolic), `e2.` (Euclidean), `s2.` (spherical).
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* A definition of distance and angle units. For example `angleunit(deg)` defines the angle unit to be 1 degree,
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and `distunit(arcmedge(3,3,4,4,4))` defines the distance unit to be x such that the total internal angle of
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two triangles and three quadrangles of edge x equals 360 degrees. The default angle unit is radian and the
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default distance unit is 1 (absolute unit).
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* A definition of tiles. Use tile(e0, a0, e1, a1, e2, a2) to construct a tile with edge lengths e0, e1, e2 and angles
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a0, a1, a2, ... Edges are given clockwise and angles are internal. You can also use unittile(a0, a1, a2) if all
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edge lengths are 1. Tiles are indexed starting from 0.
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* A definition of connections. Most tes files use the Doily notation, e.g. conway("(0 0)(1 2)"), which means that
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the edge 0 of tile 0 always connects to itself, and edge 1 of tile 0 always connect to edge 2 of tile 0. You can
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use `i`, `i'`, `i''`, `i'''`, `i@n` to refer to edge i of tile 0, 1, 2, 3, n. Use [ ] instead of ( ) if the
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connection is to be mirrored. You can also use c(i1,n1,i2,n2,0) (the last value becomes 1 for mirrored connections).
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## Symmetries
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Some tessellations include tiles with rotational symmetry. For example, in the standard HyperRogue tiling
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(bitruncated {7,3}), the heptagonal tiles have 7-fold rotational symmetry, and the hexagonal tiles have 3-fold
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rotational symmetry. In this case, it is convenient to not give an index to every edge of every tile, but only
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to the part which repeats (i.e., heptagons have 7 edges of index 0, and hexagons have 3 edges of index 0 and
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3 edges of index 1).
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Such situation can be defined with e.g. `tile(e0, a0, e1, a1, *3)` (this defines a hexagon with edges e0,e1,e0,e1,e0,e1
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and angles a0,a1,a0,a1,a0,a1; edges are indexed with 0,1,0,1,0,1).
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You can also use `repeat(tile_index, qty)` to make every edge index of tile tile_index repeat qty times, for example,
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`tile(e0, a0, e1, a1, e2, a2) repeat(0, 3)` has the same effect as tile(e0, a0, e1, a1, *3).
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Some older tessellation definitions do not use this, for example `73.tes` simply lists all connections as `c(i,0,i,0,0)`.
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This indexing will not be consistent: there is no way to index edges of every tile clockwise so that tile indexed i
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always connects to a tile indexed i. (The engine ignores this; but for new tessellations it is recommended to use
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`*k` or `repeat` to explain the situation explicitly.)
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## Formulas
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As mentioned above, all the numerical values can be provided as formulas. Formulas can use complex numbers.
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You can use the constants: `pi`, `deg` (pi/180), `e`, `i`, `inf` (infinity). You can also declare new constants as in `let(tau=2*pi)`.
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You can use the standard math operators `+`, `-`, `*` (multiplication), `/` (division), `^` (exponentation), and math functions `sin`, `cos`, `tan`, `sinh`, `cosh`, `tanh`, `asin`, `acos`, `atan`, `asinh`, `acosh`, `atanh`, `exp`, `sqrt`, `log` (natural logarithm), `tan`,
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`re` (real part), `im` (imaginary part), `conj` (conjugation), `floor`, `frac` (fractional part), `min`, `max`.
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Programming-style functions: `ifz(x,a,b)` (a if x=0, b otherwise), `ifp(x,a,b)` (a if x is positive, b otherwise), `test(x)` (returns x but also displays x while reading the file),
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`let(x=a,b)` (compute the formula a and use its value as `x` in b).
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Specialized functions are very useful for defining tilings.
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* `edge_angles(x,y,z)` is the edge opposite x of the triangle with angles x, y, z (angles given in angleunits). Works only in non-Euclidean geometry. Length returned in absolute units.
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* `edge(a,b)` is the edge of the {a,b} tiling. Works only if the {a,b} tiling is possible in the current non-Euclidean geometry. Length returned in absolute units.
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* `regradius(a,b)` is the radius of the circumscribed circle on {a,b} tile. Works only if the {a,b} tiling is possible in the current non-Euclidean geometry. Length returned in absolute units.
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* `arcmedge(3:^2,4:^3)` is the edge x such that the total internal angle of two triangles and three quadrangles of edge x equals 360 degrees. Works only if the tiling is possible in the current geometry.
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Returns 1 in Euclidean geometry. Length returned in absolute units.
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* `regangle(d,s)` is the internal angle of an s-sided regular tile with edge length d distunits. Angle returned in angle units.
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Note: while it may seem that a and b in `edge`, `regradius`, and `arcmedge(a:^b)` are integers, the formulas actually also make sense for real numbers, which is sometimes useful (e.g. for star tilings).
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Also a is allowed to be infinity (inf).
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## Special features
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The tes format also has some more features. Please read the tes files in `samples` subdirectory to see these in action.
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* Real-valued sliders. These represent real values than can be changed in the engine. For example, you could have a real-valued slider x, that defines a Euclidean tiling with parallelograms
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of angles x and 180<38>-x. Changing the value of a real-valued slider does not change the structure of the tiling (so it can be called without regenerating the map). See e.g. `slider.tes`.
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* Integer-valued sliders. These represent integer values than can be changed in the engine. For example, a tes file can describe all {a,b} regular tessellations, where both a and b can
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be changed using sliders. Changing the value of an integer-valued slider usually does change the structure of the tiling (so the map needs to be regenerated). See e.g. `regular.tes`.
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* Affine tessellations. These are tessellations of the affine two-dimensional plane; their symmetries are not Euclidean isometries but rather affine transformations of R^2. See the examples in
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`affine` subdirectory.
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* Tiles with (ultra-)ideal angles. To achieve these, put `e1, [a1, e2, a2], e3` inside the `tile` definition; this will generate the tile as `e1, a1, e2, a2, e3` would, and then the edges `e1` and `e3`
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are extended until they cross (usually, in an (ultra-)ideal point), and the edge `e2` is removed. Two convenient functions `ideal_angle` and `ideal_edge` are helpful. See e.g. `inf.tes`.
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* Apeirogonal tiles. These are achieved by giving the tile multiplier as `*inf` (e.g., `tile(e0, a0, *inf)`). See e.g. `pseudogons.tes`.
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* Star polygons. Just add a line "star." so that the engine is not confused. See e.g. `star-72-7.tes`. Star polyhedra are best viewed in 3D (in settings -> 3D configuration,
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enable "configure FPP automatically", and also "make the tiles flat"; then leave the menu and move the camera using Home/End and arrow keys).
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* Tessellations including a definition of a regular tree used to construct the tessellation. This allows non-periodic tessellations (in the style of binary tiling), see `horotiling.tes`.
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* If the tessellation is invalid, HyperRogue will invoke a debugger, which lets you see the tiles you have defined and move according to their connections. You can also invoke this debugger
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maually with `debug(tile_index)`.
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# How to make the tessellations look good
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Normally, when you choose to load a tes file, a game of HyperRogue is run on the tiling selected. Which might be not what you wanted. Here are some hints for making nice pictures.
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* If you just wanted to draw the tessellation, do 'experiment with geometry' -> 'pattern'. Most useful patterns are: single color, random, types, sides.
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* By default, HyperRogue tiles have wide borders, which might be not what you want. Also in the 'pattern' menu, you can enable 'display full floors' to prevent this.
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* HyperRogue approximates the edges using polylines. If the current approximation is not sufficient, change main menu -> settings -> general graphics -> vector settings -> line quality to a higher value.
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From the same menu you can also change the line width.
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* For tessellations including apeirogons you probably want the setting "simplified display of apeirogons" in 'experiment with geometry'. (This way you avoid the semicircular artifacts in the parts of the
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apeirogons which are close to the boundary.)
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* The screenshot menu 'experiment with geometry' -> 'take screenshot' has many useful options, e.g., to hide the player, change the pattern colors (for tile/type patterns), center the screenshot on a tile
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center/vertex/edge, increase the range of tiles rendered, etc.
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* To post screenshots of hyperbolic tessellations online, we recommend the following screenshot settings. In the 'projection' menu (experiment with geometry -> projection) change the scale factor to something
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slightly less than 1 (otherwise the Poincar<61> disk fills the whole image which does not look great). Make the screenshot transparent (screenshot menu). Change the projection background (screenshot ->
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colors & aura) to solid black (by setting the alpha to max value). This will make the background of the Poincar<61> disk black, while the rest of the image will be transparent, so it will use the background
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color of the website you post it on.
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* To print the screenshots of tessellations (e.g. to use them in math papers), it is recommended to use a vector-based format rather than PNG. Change the screenshot format (in screenshot menu) to SVG.
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SVG files can be converted to PDF using e.g. Inkscape. Unfortunately SVG/PDF files of hyperbolic tessellations tend to be large (lots of details), so you might want to control the quality (using sight
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range settings). Options such as line width, transparency, etc. do affect SVG screenshots.
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* You can also try menu -> creative mode -> map editor -> map settings -> canvas floor shape. This applies some HyperRogue floor shape tessellations to the current tiling. (You need to select the 'pattern'
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first as explained above).
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* Most options can be also set from the commandline. For example `hyperrogue -tes tessellations/sample/hr-standard-tiling.tes -canvas B -wsh 9 -shot-1000 -shott 1 -fillmodel 000000ff -zoom .95 -smart 1 -noplayer -vlq 3 -lw 5`
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will load the named tessellation file, color the tiles with "sides" pattern (B), use full floors, make screenshots of size 1000x1000, make screenshot transparent with the Poincar<61> disk black, set scaling to
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0.95, and draw tiles if their size is at least 1 pixel, hide the player character, line quality to 3, and line width to 5. Add `-genlimit 999999 -pngshot x.png` or `-svgshot x.svg` to take a screenshot
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(genlimit here makes sure that tiles are generated, the default is at most 250 tiles generated per call). -rulegen-play -palrgba gtree ffffffff -palw gtree 3 -expansion 1 2 7` to generate and display a tree (explained below).
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# How is this implemented
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Every tile on screen is represented in the memory. Tiles are generated as needed.
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By default, Archimedean/tes files are generated using a simple method: when we check for a tile across an edge, we see whether a tile already exists at that coordinates -- if yes we connect to that tile,
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if no we generate a new tile. However, coordinate-based computations in hyperbolic geometry are prone to numerical precision errors, so occassionally this may result in errors.
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HyperRogue also implements the algorithm described [here](https://arxiv.org/abs/2111.12040) to create tree structures which avoid this problem. This is not used by default because occassionally (very rarely)
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generating a tree structure can take some time (also it currently does not support affine, star, or tessellations with (ultra-)ideal-vertices). To run the algorithm, in 'experiment with geometry' pick 'size of the world' -> 'strict tree maps' -> 'strict tree based'. In the 'size of the world' menu
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you can also get various information regarding the tree structure obtained.
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