----------------------------------------------------------------------------- -- | -- Module : Data.Tree.DUAL -- Copyright : (c) 2011-2012 Brent Yorgey -- License : BSD-style (see LICENSE) -- Maintainer : diagrams-discuss@googlegroups.com -- -- Rose (n-ary) trees with both upwards- (/i.e./ cached) and -- downwards-traveling (/i.e./ accumulating) monoidal annotations. -- This is used as the core data structure underlying the @diagrams@ -- framework (<http://projects.haskell.org/diagrams>), but potentially -- has other applications as well. -- -- Abstractly, a DUALTree is a rose (n-ary) tree with data (of type -- @l@) at leaves, data (of type @a@) at internal nodes, and two types -- of monoidal annotations, one (of type @u@) travelling \"up\" the -- tree and one (of type @d@) traveling \"down\". -- -- Specifically, there are five types of nodes: -- -- * Leaf nodes which contain a data value of type @l@ and an -- annotation of type @u@. The annotation represents information -- about a tree that should be accumulated (/e.g./ number of -- leaves, some sort of \"weight\", /etc./). If you are familiar -- with finger trees -- (<http://www.soi.city.ac.uk/~ross/papers/FingerTree.html>, -- <http://hackage.haskell.org/package/fingertree>), it is the -- same idea. -- -- * There is also a special type of leaf node which contains only a -- @u@ value, and no data. This allows cached @u@ values to be -- \"modified\" by inserting extra annotations. -- -- * Branch nodes, containing a list of subtrees. -- -- * Internal nodes with a value of type @d@. @d@ may have an -- /action/ on @u@ (see the 'Action' type class, defined in -- "Data.Monoid.Action" from the @monoid-extras@ package). -- Semantically speaking, applying a @d@ annotation to a tree -- transforms all the @u@ annotations below it by acting on them. -- Operationally, however, since the action must be a monoid -- homomorphism, applying a @d@ annotation can actually be done in -- constant time. -- -- * Internal nodes with data values of type @a@, possibly of a -- different type than those in the leaves. These are just \"along -- for the ride\" and are unaffected by @u@ and @d@ annotations. -- -- There are two critical points to note about @u@ and @d@ annotations: -- -- * The combined @u@ annotation for an entire tree is always cached -- at the root and available in constant (amortized) time. -- -- * The 'mconcat' of all the @d@ annotations along the path from -- the root to each leaf is available along with the leaf during a -- fold operation. -- -- A fold over a @DUALTree@ is given access to the internal and leaf -- data, and the accumulated @d@ values at each leaf. It is also -- allowed to replace \"@u@-only\" leaves with a constant value. In -- particular, however, it is /not/ given access to any of the @u@ -- annotations, the idea being that those are used only for -- /constructing/ trees. It is also not given access to @d@ values as -- they occur in the tree, only as they accumulate at leaves. If you -- do need access to @u@ or @d@ values, you can duplicate the values -- you need in the internal data nodes. -- ----------------------------------------------------------------------------- module Data.Tree.DUAL ( -- * DUAL-trees DUALTree -- * Constructing DUAL-trees , empty, leaf, leafU, annot, applyD -- * Modifying DUAL-trees , applyUpre, applyUpost , mapU -- * Accessors and eliminators , getU, foldDUAL, flatten ) where import Data.Tree.DUAL.Internal