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<?xml version="1.0" encoding="UTF-8"?>
<!DOCTYPE pkgmetadata SYSTEM "http://www.gentoo.org/dtd/metadata.dtd">
<pkgmetadata>
	<herd>haskell</herd>
	<maintainer>
		<email>haskell@gentoo.org</email>
	</maintainer>
	<longdescription>
		This package comes \&quot;Batteries Included\&quot; with many useful lenses for the types
		commonly used from the Haskell Platform, and with tools for automatically
		generating lenses and isomorphisms for user-supplied data types.
		
		The combinators in @Control.Lens@ provide a highly generic toolbox for composing
		families of getters, folds, isomorphisms, traversals, setters and lenses and their
		indexed variants.
		
		An overview, with a large number of examples can be found in the @README@: &lt;https://github.com/ekmett/lens#lens-lenses-folds-and-traversals&gt;
		
		A video on how to use lenses and how they are constructed is available from youtube: &lt;http://youtu.be/cefnmjtAolY?hd=1&gt;
		
		Slides can be obtained here: &lt;http://comonad.com/haskell/Lenses-Folds-and-Traversals-NYC.pdf&gt;
		
		More information on the care and feeding of lenses, including a brief tutorial and motivation
		for their types can be found on the lens wiki: &lt;https://github.com/ekmett/lens/wiki&gt;
		
		A small game of @pong@ and other more complex examples that manage their state using lenses can be found in the example folder: &lt;https://github.com/ekmett/lens/blob/master/examples/&gt;
		
		/Lenses, Folds and Traversals/
		
		The core of the hierarchy of lens-like constructions looks like:
		
		
		&lt;&lt;http://i.imgur.com/4fHw3Fd.png&gt;&gt;
		
		Local copy (&lt;Hierarchy.png&gt;)
		
		You can compose any two elements of the hierarchy above using @(.)@ from the @Prelude@, and you can
		use any element of the hierarchy as any type it linked to above it.
		
		The result is their lowest upper bound in the hierarchy (or an error if that bound doesn&#39;t exist).
		
		For instance:
		
		* You can use any &#39;Traversal&#39; as a &#39;Fold&#39; or as a &#39;Setter&#39;.
		
		* The composition of a &#39;Traversal&#39; and a &#39;Getter&#39; yields a &#39;Fold&#39;.
		
		/Minimizing Dependencies/
		
		If you want to provide lenses and traversals for your own types in your own libraries, then you
		can do so without incurring a dependency on this (or any other) lens package at all.
		
		/e.g./ for a data type:
		
		&gt; data Foo a = Foo Int Int a
		
		You can define lenses such as
		
		&gt; -- bar :: Lens&#39; (Foo a) Int
		&gt; bar :: Functor f =&gt; (Int -&gt; f Int) -&gt; Foo a -&gt; f (Foo a)
		&gt; bar f (Foo a b c) = fmap (\a&#39; -&gt; Foo a&#39; b c) (f a)
		
		&gt; -- baz :: Lens (Foo a) (Foo b) a b
		&gt; quux :: Functor f =&gt; (a -&gt; f b) -&gt; Foo a -&gt; f (Foo b)
		&gt; quux f (Foo a b c) = fmap (Foo a b) (f c)
		
		without the need to use any type that isn&#39;t already defined in the @Prelude@.
		
		And you can define a traversal of multiple fields with &#39;Control.Applicative.Applicative&#39;:
		
		&gt; -- traverseBarAndBaz :: Traversal&#39; (Foo a) Int
		&gt; traverseBarAndBaz :: Applicative f =&gt; (Int -&gt; f Int) -&gt; Foo a -&gt; f (Foo a)
		&gt; traverseBarAndBaz f (Foo a b c) = Foo &lt;$&gt; f a &lt;*&gt; f b &lt;*&gt; pure c
		
		What is provided in this library is a number of stock lenses and traversals for
		common haskell types, a wide array of combinators for working them, and more
		exotic functionality, (/e.g./ getters, setters, indexed folds, isomorphisms).
	</longdescription>
<use>
  <flag name='benchmark-uniplate'>Enable benchmarking against Neil Mitchell's
  uniplate library for comparative performance analysis. Defaults to being
  turned off to avoid the extra dependency.</flag>
  <flag name='inlining'>Generate inline pragmas when using
  template-haskell. This defaults to enabled, but you can
  to shut it off to benchmark the relative performance impact,
  or as last ditch effort to address compile errors resulting
  from the myriad versions of template-haskell that all purport to be 2.8.</flag>
  <flag name='old-inline-pragmas'>Some 7.6.1-rc1 users report their TH still
  uses old style inline pragmas. This lets them turn on inlining.</flag>
  <flag name='safe'>Disallow unsafeCoerce</flag>
  <flag name='dump-splices'>Build and run the doctests test-suite.</flag>
  <flag name='test-doctests'>Build and run the doctests test-suite.</flag>
  <flag name='test-hunit'>You can disable the hunit test suite with -f-test-hunit</flag>
  <flag name='test-properties'>Build the properties test if we're building tests</flag>
  <flag name='trustworthy'>Assert that we are trustworthy when we can</flag>
  <flag name='lib-werror'>Turn on ghc-options: -Werror</flag>
</use>
</pkgmetadata>