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  <h1>Generating hat tilings for Loopy</h1>
  <p>The <a href="https://arxiv.org/abs/2303.10798">original paper</a>
  describes a method for generating hat tilings from a system of four
  'metatiles'. You can start with any one of the four tiles, and then
  recursively apply a set of expansion rules that turn each tile into
  a collection of smaller tiles from the same set.</p>
  <p>This table shows the four tiles, with their one-letter names as
  given in the paper, and how each one is expanded.</p>
  <p>All the tiles have a significant orientation. The H, T and P
  tiles are marked with arrows to indicate the orientation. The F tile
  is asymmetric, so no arrow is needed.</p>
  <p>I've assigned each tile in each expansion a number, which Loopy
  will use for its coordinate system.</p>
  <table>
    <tr>
      <th>Tile name</th>
      <th>Single tile</th>
      <th>Expansion</th>
    <tr>
      <td>H</td>
      <td><img src="single-H.svg"></td>
      <td><img src="expanded-H.svg"></td>
    </tr>
    <tr>
      <td>T</td>
      <td><img src="single-T.svg"></td>
      <td><img src="expanded-T.svg"></td>
    </tr>
    <tr>
      <td>P</td>
      <td><img src="single-P.svg"></td>
      <td><img src="expanded-P.svg"></td>
    </tr>
    <tr>
      <td>F</td>
      <td><img src="single-F.svg"></td>
      <td><img src="expanded-F.svg"></td>
    </tr>
  </table>
  <p><strong>Note that these expansions overlap</strong>. When two
  adjacent metatiles are expanded, the outer layer of P and F tiles in
  their expansions must be placed so that they overlap each other. The
  original paper suggests a set of tiles to remove from these
  expansions so that each metatile expands to a <em>disjoint</em> set
  of smaller tiles. In our implementation, however, we prefer to keep
  the overlap, because our coordinate system will use it.</p>
  <p>Once you've generated a large enough patch of metatiles for your
  needs, the final step is to convert it into the actual hat tiles.
  The expansion of each metatile into hats is shown here. Again, I've
  assigned numbers to each hat for coordinate-system purposes:</p>
  <table>
    <tr>
      <th>Tile name</th>
      <th>Conversion into hats</th>
    <tr>
      <td>H</td>
      <td><img src="single-H.svg"></td>
      <td><img src="hats-single-H.svg"></td>
    </tr>
    <tr>
      <td>T</td>
      <td><img src="single-T.svg"></td>
      <td><img src="hats-single-T.svg"></td>
    </tr>
    <tr>
      <td>P</td>
      <td><img src="single-P.svg"></td>
      <td><img src="hats-single-P.svg"></td>
    </tr>
    <tr>
      <td>F</td>
      <td><img src="single-F.svg"></td>
      <td><img src="hats-single-F.svg"></td>
    </tr>
  </table>
  <p>(The hat in the middle of the H is shaded to indicate that it's
  one of the rare reflected ones. All the other hats are rotations of
  each other.)</p>
  <p>Given all of this, an obvious approach to generating a random
  patch of hat tiling would be to start with a single metatile,
  iterate the expansion process a few times until you have a tiled
  area much larger than you need, and then pick a subrectangle of
  it at random.</p>
  <p>Loopy's algorithm for generating Penrose tilings (which admit a
  similar, though less complicated, expansion system) works in exactly
  this way.</p>
  <p>One problem with that algorithm is that it spends a lot of effort
  on generating huge areas of tiles that aren't actually needed. So
  you'd prefer to adjust the algorithm so that at every stage of
  expansion it spots tiles completely outside the target rectangle,
  and throws them away <em>before</em> spending 5 iterations on
  exponentially expanding them into huge amounts of detail that will
  only be thrown away anyway later.</p>
  <p>That works well for Penrose tilings, because there, the expansion
  procedure is geometrically precise: coordinates in the expanded
  tiling are scaled up by an exact factor from coordinates in the
  original tiling. So at every stage it's easy to know exactly where
  your target rectangle <em>is</em>, and discard things that don't
  overlap it.</p>
  <p>But the metatiles shown here don't have that property. The tiles
  distort slightly as they expand. The <em>topological</em> properties
  of the expanded tiling match the original (which expanded tiles
  connect to each other), but the geometry (precise distances) is
  different. So it would be harder to implement the pruning for this
  tiling. The target rectangle might not even be rectangular in every
  iteration!</p>
  <p>Instead, I came up with a completely different mechanism, by
  devising a coordinate system to track our position within multiple
  layers of tile expansion. This allows us to generate precisely the
  area of tiling we need, and waste no effort at all on anything
  outside the target region.</p>
  <p>We begin by assigning an integer index to each kite making up an
  individual hat:</p>
  <img src="hat-kites.svg">
  <p>(For a reflected hat, these indices work in mirror image, so that
  for example 5 is still the kite in the middle.)</p>
  <p>Together with the indices we've assigned to hats within each
  metatile, and to metatiles in the expansion of another metatile,
  this gives us a coordinate system that can identify an individual
  kite in an n-times-expanded metatile. For each large metatile
  expansion, you can give the index of the smaller metatile selected
  from its expansion; when we reach the last layer of metatiles and
  expand them into hats, we can give the index of the hat in that
  metatile; finally we can index the kite in that hat.</p>
  <p><strong>But note that a kite can have multiple
  coordinates</strong>, because of the overlap between the expansions
  of adjacent metatiles. This will be useful!</p>
  <p>Our next step is to unambiguously name the four directions in
  which you can move from one kite to an adjacent kite. The directions
  should be independent of the orientation of the kite. I've chosen to
  name them from the viewpoint of someone standing at the pointy end
  of the kite and looking towards the blunt end:</p>
  <dl>
    <dt><strong>Left</strong></dt>
    <dd>Rotate 60° anticlockwise about the pointy end of the kite. For
    example, in the above hat, going 'left' from kite 5 takes you to
    kite 4.</dd>
    <dt><strong>Right</strong></dt>
    <dd>Rotate 60° clockwise about the pointy end. From kite 5, this
    would take you to kite 6.</dd>
    <dt><strong>Forward left</strong></dt>
    <dd>Head forwards and slightly left, to the kite sharing the
    left-hand one of this kite's short edges (as seen from the
    centre). Equivalently, rotate 120° <em>clockwise</em> about the
    blunt end. From kite 5, this takes you to kite 2.</dd>
    <dt><strong>Forward right</strong></dt>
    <dd>Head forwards and slightly right. Or rotate 120° anticlockwise
    about the blunt end, if you prefer to think of it that way. From
    kite 5, this takes you to kite 1.</dd>
  </dl>
  <p>The idea is that if we know how to transform the coordinates of a
  single kite into the coordinates of each of those four adjacent
  kites, then we can iterate that over a whole area and determine the
  coordinates of every kite in the whole tiling.</p>
  <p>Having done that, it's easy to identify each individual kite, by
  several different methods. For example, you could iterate over edges
  of the tiling to see whether the kites on each side have coordinates
  differing only in the kite index; if so, they're part of the same
  hat, and if not, not. Or a completely different approach (in fact
  the one Loopy actually uses) would be to trace round the boundary of
  each hat by starting from its kite #0 and just knowing what shape a
  hat is.</p>
  <p>So now we have to come up with an algorithm that lets us
  transform a kite coordinate by making one of the four permitted
  moves. To do this, we use two multilevel types of map.</p>
  <p>The <strong>kitemap</strong> for a given metatile type is made by
  expanding the metatile once into more metatiles, and then into hats.
  For example, the T tile:</p>
  <table class="noborder">
    <tr>
      <td><img src="single-T.svg"></td>
      <td><img src="arrow.svg"></td>
      <td><img src="expanded-T.svg" height="200px"></td>
      <td><img src="arrow.svg"></td>
      <td><img src="kitemap-T.svg" height="500px"></td>
    </tr>
  </table>
  <p>In each kite, we show a three-part coordinate, in little-endian
  fashion (because that matches the order the coordinates are stored
  in an array in the code that actually generates the tilings). For
  example, 7.3.0 means kite 7 in hat 3 of metatile 0 of the
  expansion.</p>
  <p>This map can be converted into a lookup table, indexed by those
  three-part coordinates and also the four move directions, which
  allows you to look up that (for example) going Left from kite 7.3.0
  goes to 0.0.0, or going Forward Left from 7.3.0 goes to 3.1.3.</p>
  <p>But if you're at the very edge of the kitemap, this isn't enough.
  For example, kite 0.0.4 right at the top can go Left to 1.0.4, but
  if it wants to go in any of the other three directions, this map
  doesn't help at all.</p>
  <p>This is where the overlap between the metatile expansions comes
  in. If you're in kite 0.0.4, then in particular, you're in the F
  tile numbered 4 in the expansion of a larger T metatile. And that F
  tile is <em>also</em> part of the expansion of at least one other
  second-order metatile – maybe two of them – which means that there
  are other equivalent coordinates describing the same kite, which
  will place it in a different kitemap where it <em>isn't</em> right
  on the edge,</p>
  <p>In order to find those equivalent coordinates, we create a second
  map for each metatile type, called the <strong>metamap</strong>.
  This one arises from expanding the metatile twice into other
  metatiles, instead of into hats:</p>
  <table class="noborder">
    <tr>
      <td><img src="single-T.svg"></td>
      <td><img src="arrow.svg"></td>
      <td><img src="expanded-T.svg" height="200px"></td>
      <td><img src="arrow.svg"></td>
      <td><img src="metamap-T.svg" height="500px"></td>
    </tr>
  </table>
  <p>Again, the coordinates are little-end first, so that 7.4 means
  the 7th smallest-size tile expanded from the 4th medium-sized tile
  expanded from the original single large tile.</p>
  <p>Unlike the kitemap, the metamap is not used for <em>moving
  around</em> the tiling to a different kite. It's used for rewriting
  the coordinates of the current kite into equivalent forms. So each
  the small tile in the metamap that's part of the expansion
  of <em>more than one</em> medium-sized tile has more than one
  coordinate pair. For example, tile 5.2 is also tile 5.4, and tile
  7.0 is also 8.3 <em>and</em> also 4.5 (because it's where three
  medium-tile expansions meet).</p>
  <p>Using both of these maps (converted into appropriate lookup
  tables in the code), you can always eventually find a valid
  coordinate representation of whichever kite you like adjacent to
  your current one. If the kitemap corresponding to the current
  coordinates doesn't tell you the coordinates of the next kite, then
  you can try rewriting the two least-significant metatile indices
  (using the metamap corresponding to the type of the next-larger
  metatile still) and then see if that gives you a new kitemap that
  works. If even that doesn't work, you can move another level up, and
  try a metamap rewrite on the 2nd and 3rd smallest metatile levels,
  or the 3rd and 4th, etc. And eventually, you find something you can
  do.</p>
  <p>The full set of kitemaps and metamaps for all the tile
  types is in <a href="hatmaps.html">hatmaps.html</a>.</p>
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