1 files changed, 186 insertions, 179 deletions
diff --git a/doc/api.texi b/doc/api.texi
index 6a1361d..96803b8 100644
--- a/doc/api.texi
+++ b/doc/api.texi
@@ -4,6 +4,7 @@
 * Graphics::                    2D and 3D rendering.
 * Audio::                       Make some noise.
 * Scripting::                   Bringing the game world to life.
+* Data Structures::             Spatial partitioning and more.
 @end menu
 
 @node Kernel
@@ -531,8 +532,6 @@ detection.
 * Quaternions::                 Rotations about an arbitrary axis.
 * Easings::                     Easing functions for interesting animations.
 * Bezier Curves::               Cubic Bezier curves and paths in 2D space.
-* Path Finding::                Generic A* path finding.
-* Grid::                        Spatial partitioning for bounding boxes.
 @end menu
 
 @node Basics
@@ -1377,183 +1376,6 @@ Modify the 2D vector @var{dest} in-place to contain the coordinates
 for @var{bezier} at @var{t}.
 @end deffn
 
-@node Path Finding
-@subsection Path Finding
-
-Most game worlds have maps.  Often, these games have a need to move
-non-player characters around in an unscripted fashion.  For example,
-in a real-time strategy game, the player may command one of their
-units to attack something in the enemy base.  To do so, the unit must
-calculate the shortest route to get there.  It wouldn't be a very fun
-game if units didn't know how to transport themselves efficiently.
-This is where path finding algorithms come in handy.  The
-@code{(chickadee math path-finding)} module provides a generic
-implementation of the popular A* path finding algorithm.  Just add a
-map implementation!
-
-The example below defines a very simple town map and finds the
-quickest way to get from the town common to the school.
-
-@example
-(define world-map
-  '((town-common . (town-hall library))
-    (town-hall . (town-common school))
-    (library . (town-common cafe))
-    (school . (town-hall cafe))
-    (cafe . (library school))))
-(define (neighbors building)
-  (assq-ref town-map building))
-(define (cost a b) 1)
-(define (distance a b) 1)
-(define pf (make-path-finder))
-(a* pf 'town-common 'school neighbors cost distance)
-@end example
-
-In this case, the @code{a*} procedure will return the list
-@code{(town-common town-hall school)}, which is indeed the shortest
-route.  (The other possible route is @code{(town-common library cafe
-school)}.)
-
-The @code{a*} procedure does not know anything about about any kind of
-map and therefore must be told how to look up neighboring nodes, which
-is what the @code{neighbors} procedure in the example does. To
-simulate different types of terrain, a cost procedure is used.  In
-this example, it is just as easy to move between any two nodes because
-@code{cost} always returns 1.  In a real game, perhaps moving from
-from a field to a rocky hill would cost a lot more than moving from
-one field to another.  Finally, a heuristic is used to calculate an
-approximate distance between two nodes on the map.  In this simple
-association list based graph it is tough to calculate a distance
-between nodes, so the @code{distance} procedure isn't helpful and
-always returns 1.  In a real game with a tile-based map, for example,
-the heuristic could be a quick Manhattan distance calculation based on
-the coordinates of the two map tiles.  Choose an appropriate heuristic
-for optimal path finding!
-
-@deffn {Procedure} make-path-finder
-Return a new path finder object.
-@end deffn
-
-@deffn {Procedure} path-finder? obj
-Return @code{#t} if @var{obj} is a path finder.
-@end deffn
-
-@deffn {Procedure} a* path-finder start goal neighbors cost distance
-
-Return a list of nodes forming a path from @var{start} to @var{goal}
-using @var{path-finder} to hold state.  @var{neighbors} is a procedure
-that accepts a node and returns a list of nodes that neighbor it.
-@var{cost} is a procedure that accepts two neighboring nodes and
-returns the cost of moving from the first to the second as a real
-number.  @var{distance} is a procedure that accepts two nodes and
-returns an approximate distance between them.
-@end deffn
-
-@node Grid
-@subsection Grid
-
-The @code{(chickadee math grid)} module provides a simple spatial
-partitioning system for axis-aligned bounding boxes
-(@pxref{Rectangles}) in 2D space.  The grid divides the world into
-tiles and keeps track of which rectangles occupy which tiles.  When
-there are lots of moving objects in the game world that need collision
-detection, the grid greatly speeds up the process.  Instead of
-checking collisions of each object against every other object (an
-O(n^2) operation), the grid quickly narrows down which objects could
-possibly be colliding and only performs collision testing against a
-small set of objects.
-
-In addition to checking for collisions, the grid also handles the
-resolution of collisions.  Exactly how each collision is resolved is
-user-defined.  A player bumping into a wall may slide against it.  An
-enemy colliding with a projectile shot by the player may get pushed
-back in the opposite direction.  Two players colliding may not need
-resolution at all and will just pass through each other.  The way this
-works is that each time an object (A) is moved within the grid, the
-grid looks for an object (B) that may possibly be colliding with A.  A
-user-defined procedure known as a ``filter'' is then called with both
-A and B.  If the filter returns @code{#f}, it means that even if A and
-B are colliding, no collision resolution is needed.  In this case the
-grid won't waste time checking if they really do collide because it
-doesn't matter.  If A and B are collidable, then the filter returns a
-procedure that implements the resolution technique.  The grid will
-then perform a collision test.  If A and B are colliding, the resolver
-procedure is called.  It's the resolvers job to adjust the objects
-such that they are no longer colliding.  The grid module comes with a
-very simple resolution procedure, @code{slide}, that adjusts object A
-by the smallest amount so that it no longer overlaps with B.  By using
-this filtering technique, a game can resolve collisions between
-different objects in different ways.
-
-@deffn {Procedure} make-grid [cell-size 64]
-Return a new grid partitioned into @var{cell-size} tiles.
-@end deffn
-
-@deffn {Procedure} grid? obj
-Return @code{#t} if @var{obj} is a grid.
-@end deffn
-
-@deffn {Procedure} cell? obj
-Return @code{#t} if @var{obj} is a grid cell.
-@end deffn
-
-@deffn {Procedure} cell-count cell
-Return the number of items in @var{cell}.
-@end deffn
-
-@deffn {Procedure} grid-cell-size grid
-Return the cell size of @var{grid}.
-@end deffn
-
-@deffn {Procedure} grid-cell-count grid
-Return the number of cells currently in @var{grid}.
-@end deffn
-
-@deffn {Procedure} grid-item-count grid
-Return the number of items in @var{grid}.
-@end deffn
-
-@deffn {Procedure} grid-add grid item x y @
-                            width height
-
-Add @var{item} to @var{grid} represented by the axis-aligned bounding
-box whose lower-left corner is at (@var{x}, @var{y}) and is
-@var{width} x @var{height} in size.
-@end deffn
-
-@deffn {Procedure} grid-remove grid item
-Return @var{item} from @var{grid}.
-@end deffn
-
-@deffn {Procedure} grid-clear grid
-Remove all items from @var{grid}.
-@end deffn
-
-@deffn {Procedure} grid-move grid item position filter
-Attempt to move @var{item} in @var{grid} to @var{position} (a 2D
-vector) and check for collisions.  For each collision, @var{filter}
-will be called with two arguments: @var{item} and the item it collided
-with.  If a collision occurs, @var{position} may be modified to
-resolve the colliding objects.
-@end deffn
-
-@deffn {Procedure} for-each-cell proc grid [rect]
-Call @var{proc} with each cell in @var{grid} that intersects
-@var{rect}, or every cell if @var{rect} is @code{#f}.
-@end deffn
-
-@deffn {Procedure} for-each-item proc grid
-Call @var{proc} for each item in @var{grid}.
-@end deffn
-
-@deffn {Procedure} slide item item-rect other other-rect goal
-
-Resolve the collision that occurs between @var{item} and @var{other}
-when moving @var{item-rect} to @var{goal} by sliding @var{item-rect}
-the minimum amount needed to make it no longer overlap
-@var{other-rect}.
-@end deffn
-
 @node Graphics
 @section Graphics
 
@@ -5383,3 +5205,188 @@ after it has been received.
 @deffn {Procedure} channel-clear! channel
 Clear all messages and scripts awaiting messages in @var{channel}.
 @end deffn
+
+@node Data Structures
+@section Data Structures
+
+@menu
+* Grids::                       Spatial partitioning with a fixed grid.
+* Path Finding::                Generic A* path finding.
+@end menu
+
+@node Grids
+@subsection Grids
+
+The @code{(chickadee data grid)} module provides a simple spatial
+partitioning system for axis-aligned bounding boxes
+(@pxref{Rectangles}) in 2D space.  The grid divides the world into
+tiles and keeps track of which rectangles occupy which tiles.  When
+there are lots of moving objects in the game world that need collision
+detection, the grid greatly speeds up the process.  Instead of
+checking collisions of each object against every other object (an
+O(n^2) operation), the grid quickly narrows down which objects could
+possibly be colliding and only performs collision testing against a
+small set of objects.
+
+In addition to checking for collisions, the grid also handles the
+resolution of collisions.  Exactly how each collision is resolved is
+user-defined.  A player bumping into a wall may slide against it.  An
+enemy colliding with a projectile shot by the player may get pushed
+back in the opposite direction.  Two players colliding may not need
+resolution at all and will just pass through each other.  The way this
+works is that each time an object (A) is moved within the grid, the
+grid looks for an object (B) that may possibly be colliding with A.  A
+user-defined procedure known as a ``filter'' is then called with both
+A and B.  If the filter returns @code{#f}, it means that even if A and
+B are colliding, no collision resolution is needed.  In this case the
+grid won't waste time checking if they really do collide because it
+doesn't matter.  If A and B are collidable, then the filter returns a
+procedure that implements the resolution technique.  The grid will
+then perform a collision test.  If A and B are colliding, the resolver
+procedure is called.  It's the resolvers job to adjust the objects
+such that they are no longer colliding.  The grid module comes with a
+very simple resolution procedure, @code{slide}, that adjusts object A
+by the smallest amount so that it no longer overlaps with B.  By using
+this filtering technique, a game can resolve collisions between
+different objects in different ways.
+
+@deffn {Procedure} make-grid [cell-size 64]
+Return a new grid partitioned into @var{cell-size} tiles.
+@end deffn
+
+@deffn {Procedure} grid? obj
+Return @code{#t} if @var{obj} is a grid.
+@end deffn
+
+@deffn {Procedure} cell? obj
+Return @code{#t} if @var{obj} is a grid cell.
+@end deffn
+
+@deffn {Procedure} cell-count cell
+Return the number of items in @var{cell}.
+@end deffn
+
+@deffn {Procedure} grid-cell-size grid
+Return the cell size of @var{grid}.
+@end deffn
+
+@deffn {Procedure} grid-cell-count grid
+Return the number of cells currently in @var{grid}.
+@end deffn
+
+@deffn {Procedure} grid-item-count grid
+Return the number of items in @var{grid}.
+@end deffn
+
+@deffn {Procedure} grid-add grid item x y @
+                            width height
+
+Add @var{item} to @var{grid} represented by the axis-aligned bounding
+box whose lower-left corner is at (@var{x}, @var{y}) and is
+@var{width} x @var{height} in size.
+@end deffn
+
+@deffn {Procedure} grid-remove grid item
+Return @var{item} from @var{grid}.
+@end deffn
+
+@deffn {Procedure} grid-clear grid
+Remove all items from @var{grid}.
+@end deffn
+
+@deffn {Procedure} grid-move grid item position filter
+Attempt to move @var{item} in @var{grid} to @var{position} (a 2D
+vector) and check for collisions.  For each collision, @var{filter}
+will be called with two arguments: @var{item} and the item it collided
+with.  If a collision occurs, @var{position} may be modified to
+resolve the colliding objects.
+@end deffn
+
+@deffn {Procedure} for-each-cell proc grid [rect]
+Call @var{proc} with each cell in @var{grid} that intersects
+@var{rect}, or every cell if @var{rect} is @code{#f}.
+@end deffn
+
+@deffn {Procedure} for-each-item proc grid
+Call @var{proc} for each item in @var{grid}.
+@end deffn
+
+@deffn {Procedure} slide item item-rect other other-rect goal
+
+Resolve the collision that occurs between @var{item} and @var{other}
+when moving @var{item-rect} to @var{goal} by sliding @var{item-rect}
+the minimum amount needed to make it no longer overlap
+@var{other-rect}.
+@end deffn
+
+@node Path Finding
+@subsection Path Finding
+
+Most game worlds have maps.  Often, these games have a need to move
+non-player characters around in an unscripted fashion.  For example,
+in a real-time strategy game, the player may command one of their
+units to attack something in the enemy base.  To do so, the unit must
+calculate the shortest route to get there.  It wouldn't be a very fun
+game if units didn't know how to transport themselves efficiently.
+This is where path finding algorithms come in handy.  The
+@code{(chickadee data path-finding)} module provides a generic
+implementation of the popular A* path finding algorithm.  Just add a
+map implementation!
+
+The example below defines a very simple town map and finds the
+quickest way to get from the town common to the school.
+
+@example
+(define world-map
+  '((town-common . (town-hall library))
+    (town-hall . (town-common school))
+    (library . (town-common cafe))
+    (school . (town-hall cafe))
+    (cafe . (library school))))
+(define (neighbors building)
+  (assq-ref town-map building))
+(define (cost a b) 1)
+(define (distance a b) 1)
+(define pf (make-path-finder))
+(a* pf 'town-common 'school neighbors cost distance)
+@end example
+
+In this case, the @code{a*} procedure will return the list
+@code{(town-common town-hall school)}, which is indeed the shortest
+route.  (The other possible route is @code{(town-common library cafe
+school)}.)
+
+The @code{a*} procedure does not know anything about about any kind of
+map and therefore must be told how to look up neighboring nodes, which
+is what the @code{neighbors} procedure in the example does. To
+simulate different types of terrain, a cost procedure is used.  In
+this example, it is just as easy to move between any two nodes because
+@code{cost} always returns 1.  In a real game, perhaps moving from
+from a field to a rocky hill would cost a lot more than moving from
+one field to another.  Finally, a heuristic is used to calculate an
+approximate distance between two nodes on the map.  In this simple
+association list based graph it is tough to calculate a distance
+between nodes, so the @code{distance} procedure isn't helpful and
+always returns 1.  In a real game with a tile-based map, for example,
+the heuristic could be a quick Manhattan distance calculation based on
+the coordinates of the two map tiles.  Choose an appropriate heuristic
+for optimal path finding!
+
+@deffn {Procedure} make-path-finder
+Return a new path finder object.
+@end deffn
+
+@deffn {Procedure} path-finder? obj
+Return @code{#t} if @var{obj} is a path finder.
+@end deffn
+
+@deffn {Procedure} a* path-finder start goal neighbors cost distance
+
+Return a list of nodes forming a path from @var{start} to @var{goal}
+using @var{path-finder} to hold state.  @var{neighbors} is a procedure
+that accepts a node and returns a list of nodes that neighbor it.
+@var{cost} is a procedure that accepts two neighboring nodes and
+returns the cost of moving from the first to the second as a real
+number.  @var{distance} is a procedure that accepts two nodes and
+returns an approximate distance between them.
+@end deffn