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diff --git a/provider/posts/beuteltier-1.lhs b/provider/posts/beuteltier-1.lhs
new file mode 100644
index 0000000..c8f3e6c
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+++ b/provider/posts/beuteltier-1.lhs
@@ -0,0 +1,325 @@
+---
+title: On the Design of Overly Complicated Feedreaders
+published: 2015-08-04
+---
+I like feedreaders.
+Thus, of course, I had to implement my own, because, as always, all existing software does
+not fullfill my exceedingly unrealistic expectations with respect to customizability and
+extendability.
+This post marks the start of a series describing and documenting the design of the current
+iteration of `Beuteltier` (a derivation of [Newsbeuter](https://newsbeuter.org) and the
+german `Beutel`, meaning bag, to mean in conjunction:
+[Marsupial](https://en.wikipedia.org/wiki/Marsupial)).
+It should be noted that the library described here is not finished or ready for use in any
+sense of the word (at the time of writing a "trivial" implementation of a `Beutel` shipped
+with the library supports only `run`, `search`, and `delete`). Searching a way to
+procrastinate implementing the more arduous `insert` (it requires nubbing—deduplication in
+the backstore) I decided to, instead, start this series of posts and put the thought that
+went into the library so far in a form that I can read again for later reference.
+We begin, as is to be expected for a haskell project, with type definitions and, thus,
+design philosophy.
+This post in particular reproduces the file `beuteltier/Beuteltier/Types.hs` from the
+[git repo](git://git.yggdrasil.li/beuteltier) with annotiations to provide some
+motivation.
+The `Beuteltier` library itself only provides primitives for (and a default implementation
+of) access to what we call a backstore. A backstore is, to us, an instance of the
+typeclass `Beutel` which contains the most primitive of primitives for storing, searching
+for and deleting representations of the objects we care about from the store.
+It is recommended that reader not try to follow the rest of this post linearly but start
+at the end with the definition of the `Beutel` class and work their way backwards.
+> {-# LANGUAGE FlexibleInstances, StandaloneDeriving, KindSignatures, MultiParamTypeClasses, TypeFamilies #-}
+> 
+> module Beuteltier.Types
+>        ( -- * Types
+>          Object
+>        , ObjectGen(..)
+>        , SubObject(..)
+>        , MetaData(..)
+>        , Thunk(..)
+>        , ThunkState(..)
+>        , ThunkResult(..)
+>        , Tag
+>        , Flag(..)
+>        , SubObjectName
+>        , ThunkName
+>        , SearchQuery
+>        , Predicate
+>        , Beutel(..)
+>        ) where
+`Flag` ends up being a [sum type](https://en.wikipedia.org/wiki/Sum_type) holding values
+such as `Seen`, `Old`, or `Hidden`.
+We define it externally.
+> import Beuteltier.Types.Flags
+The `Identity` functor serves as basis for many a Monadtransformer-stack.
+> import Data.Functor.Identity
+> import Data.Functor.Classes ()
+Binary contents are encoded as `ByteStrings`
+> import qualified Data.ByteString.Lazy as Lazy (ByteString)
+> import qualified Data.ByteString.Lazy as LBS
+Unicode text as `Text`
+> import Data.Text (Text)
+Long unicode text as lazy `Text`
+> import qualified Data.Text.Lazy as Lazy (Text)
+> import qualified Data.Text.Lazy as LT
+> 
+> import Data.Set (Set)
+> 
+> import Data.Map (Map)
+> 
+> import Data.Time (UTCTime)
+> 
+> import Data.Function (on)
+> import Data.Ord (comparing)
+> import Control.Applicative
+`Data.Default` provides some convenience when constructing extensive record structures.
+> import Data.Default
+The `boolexpr` package provides us with a structure for representing boolean expressions
+supporting functor operations and evaluation.
+> import Data.BoolExpr
+Previous iterations of Beuteltier acted on Objects that were kept completely in RAM during
+all operations.
+This proved to be unsustainable, not only because nubbing (deduplication in the store of
+all objects) tended to exceed all RAM constraints (>4GiB for a few hundred objects), but
+also because cheaper operations on objects, like presentation to the user, got painfully
+slow once large `SubObject`s (like videos) were introduced into the store.
+The straight forward solution was to enrich the `Object` structure with provisions for
+explicit lazyness and partial construction.
+> -- | We deal in, at runtime, partially retrieved Objects
+> data ObjectGen (f :: * -> *) = ObjectGen
+>                                { _oMeta :: f MetaData
+>                                  -- ^ An undetermined set of Metainformation
+>                                , _oContent :: f (Map SubObjectName (f SubObject))
+>                                  -- ^ A list of undetermined length of undetermined
+>                             'SubObject's with guaranteed unique 'SubObjectName's
+>                                , _oThunks :: f [f Thunk]
+>                                  -- ^ A list of undetermined length of undetermined Thunks.
+>                                  --   There is such a thing as thunk colissions (i.e.: two
+>                                  --   thunks promise or even create 'SubObject's with the
+>                                  --   same name).
+>                                  --   Precedence in such a case is to be as suggested by
+>                                  --   the list structure (later thunks override earlier ones).
+>                                }
+> 
+> instance Monad f => Default (ObjectGen f) where
+>   def = ObjectGen { _oContent = return def
+>                   , _oThunks = return def
+>                   , _oMeta = return def
+>                   }
+It is straight forward to collapse the more advanced representation of `Object`s back to
+the old behaviour by parametrising over the Identity functor, which is simply a newtype
+wrapper over the contained structure.
+> -- | An entirely retrieved Object
+> type Object = ObjectGen Identity
+> 
+> -- -- | The default 'Object' is empty except for metadata
+> -- instance Default Object where
+> --   def = ObjectGen { _oContent = return def
+> --                   , _oThunks = return def
+> --                   , _oMeta = return def
+> --                   }
+> 
+> -- | Equality simply gets deferred to all subcomponents
+> deriving instance Eq Object
+> 
+> -- | 'Object's compare as their 'MetaData'
+> instance Ord Object where
+>   compare = comparing _oMeta
+We would like to associate some set of meta information with all objects.
+Therefore, we do.
+> -- | Metadata associated with an Object
+> data MetaData = MetaData
+>                 { _mRetrieved :: UTCTime -- ^ Time of creation
+>                 , _mTags :: Set Tag -- ^ Tags such as the name of the author,
+>                                     --   the title of the work represented in
+>                                     --   the 'Object', ….
+>                                     --   We use something like @show . _mTags@
+>                                     --   to identify an 'Object' to the user
+>                 , _mFlags :: Set Flag -- ^ Flags such as \"Read\" or \"Spam\"
+>                 } deriving (Show, Ord)
+> -- | Tags are unicode text
+> type Tag = Text
+> 
+> -- | 'MetaData' equates as the contained tags
+> instance Eq MetaData where
+>   (==) = (==) `on` _mTags
+> 
+> -- | The default MetaData has no tags, no flags, and an undefined timestamp
+> instance Default MetaData where
+>   def = MetaData { _mFlags = def
+>                  , _mTags = def
+>                  , _mRetrieved = undefined -- There really is no such thing as a default time
+>                  }
+Objects are no fun if they don´t contain anything of interest in the end.
+Below we see a remnant of an older model of associating names to `SubObject`s. We switched
+to using a `Map` for reasons of deduplication. Inserting into a `Map` carries some
+guarantees that keys end up being unique.
+Note below: creation of a `SubObject` is an update. It is thus expected, that `SubObject`s
+created at the same time as the `Object` they are associated to contain encode an update
+time that matches the `Object`s creation time.
+> -- | Contents of an object
+> data SubObject = SubObject
+>                  -- { _sId :: SubObjectName
+>                       -- ^ We associate a name to every chunk of content to determine
+>                       --   how to present an object to the user
+>                  { _sContent :: Lazy.ByteString
+>                  , _sUpdates :: [UTCTime]
+>                    -- ^ Times of witnessed updates to this 'SubObject'
+>                  } deriving (Show)
+> 
+> -- | No content, no witnessed updates
+> instance Default SubObject where
+>   def = SubObject { _sContent = def
+>                   , _sUpdates = def
+>                   }
+> 
+> -- | Extensionality for 'SubObject's:
+> --   
+> --   > (==) = (==) `on` _sContent
+> instance Eq SubObject where
+>   (==) = (==) `on` _sContent
+The distinguishing feature of Beuteltier is it´s support for `Thunk`s. They are, as the
+name suggests, loosly based on the concept of lazy evaluation. They are, however, less
+transparent and thus more explicit than implementations as they are used in, for example
+haskell.
+As far as Beuteltier is concerned `Thunk`s are executables that are expected to produce
+files in the directory they are executed in in a pure manner. That is to say they do not
+access external resources, where possible. A `Thunk` that downloads a video from the
+internet will, of course, access the internet and can thus fail. We expect it, however, to
+not to try and access the users home directory to look for e.g. credentials for
+authentication it intends to use to its primary job.
+When a `Thunk`s executable gets executed the files it creates (excluding itself) get
+translated to `SubObject`s with the filenames (directories stripped of course) as their
+`SubObjectName`s and the file contents as their… well, their contents. It is understood,
+that not all possible `SubObjectName`s can be created thus (we restrict ourselves to valid
+filenames on whatever system we happen to be on). We do not consider this to be a great
+loss.
+The advanced equality checks mentioned below are, in fact, implemented and will be explained
+in more detail in a later post concerned with the file `beuteltier/Beuteltier/Types/Util.hs`.
+> -- | Thunks are at runtime not yet known parts of an object
+> data Thunk = Thunk
+>              { _tId :: ThunkName -- ^ For debugging
+>              , _tScript :: Lazy.ByteString
+>                -- ^ A Thunk is, in the end, a shell script that is expected to generate
+>                --  'SubObject's
+>              , _tPromises :: Maybe [SubObjectName]
+>                -- ^ Maybe we already know what our script is going to generate?
+>                --   This would enable us to do some more advanced equality checks under
+>                --   the assumption that scripts are pure
+>              , _tState :: ThunkState
+>              }
+>            deriving (Show)
+> 
+> -- | Empty id, empty script, promises nothing, and with default state
+> instance Default Thunk where
+>   def = Thunk { _tId = def
+>               , _tScript = def
+>               , _tPromises = def
+>               , _tState = def
+>               }
+> 
+> -- | Equality on 'Thunk's ignores '_tState' and '_tId'
+> instance Eq Thunk where
+>   a == b = and $ [ (==) `on` _tScript
+>                  , (==) `on` _tPromises
+>                  ] <*> pure a <*> pure b
+> 
+> -- | The states in which a 'Thunk' can be encountered.
+> data ThunkState = NotExecuted
+>                 | Executed [SubObjectName] ThunkResult
+>                 deriving (Show)
+> 
+> -- | Return the default 'ThunkResult' upon forcing
+> instance Default ThunkState where
+>   def = NotExecuted
+> 
+> -- | Thunks generate some data during execution
+> data ThunkResult = ThunkResult
+>                    { _rOutErr, _rOutStd :: Lazy.Text
+>                    , _rExit :: Integer -- ^ Numerical exit code (0 usually means success)
+>                    }
+>                  deriving (Show)
+> 
+> -- | Empty output, and with undefined exit code (no execution took place and we can´t
+> --   encode this in a numerical exit code)
+> instance Default ThunkResult where
+>   def = ThunkResult { _rOutErr = LT.empty, _rOutStd = LT.empty
+>                     , _rExit = undefined
+>                     }
+> 
+> -- | We expect identifiers for 'SubObject's to be short, thus 'String'
+> type SubObjectName = String
+> -- | We expect identifiers for 'Thunk's to be short, thus 'String'
+> type ThunkName = String
+> 
+> -- | @LBS.empty@
+> instance Default (Lazy.ByteString) where
+>   def = LBS.empty
+What good is a library for managing a backstore if it does not support search operations?
+We consider the answer to be "very little" and, thus, support searches.
+> type SearchQuery f = BoolExpr (Predicate f)
+> -- data Predicate f = Prim (ObjectGen f -> f Bool)
+> --                  | Meta (MetaData -> Bool)
+> type Predicate f = ObjectGen f -> f Bool
+The heart of the `Beuteltier` library is the typeclass reproduced below. We expect
+implementations of backstores to be `Monad`s so that we may be able to construct
+complicated actions that act on the backstore in question.
+Once we have constructed such an action using the three primitives `search`, `insert`, and
+`delete` we additionally require a way to execute that action from within the `IO`
+`Monad`.
+Additional primitives, such as those for "forcing" and resetting thunks, are provided in
+additional libraries and, thus, later posts.
+> -- | We have the user supply the functions we use to interact with whatever backstore
+> --   she uses
+> class Monad functor => Beutel (functor :: * -> *) where
+>   data Config :: *
+>   run :: Config -> functor a -> IO a
+>   -- ^ Actually run whatever action we constructed against the backstore
+>   search :: SearchQuery functor -> functor [ObjectGen functor]
+>   -- ^ Perform a search
+>   insert :: Object -> functor ()
+>   -- ^ Insert an object
+>   delete :: SearchQuery functor -> functor ()
+>   -- ^ Delete the results of a search

diff --git a/provider/posts/beuteltier-1.lhs b/provider/posts/beuteltier-1.lhs new file mode 100644 index 0000000..c8f3e6c --- /dev/null +++ b/provider/posts/beuteltier-1.lhs
@@ -0,0 +1,325 @@
	1	---
	2	title: On the Design of Overly Complicated Feedreaders
	3	published: 2015-08-04
	4	---
	5
	6	I like feedreaders.
	7	Thus, of course, I had to implement my own, because, as always, all existing software does
	8	not fullfill my exceedingly unrealistic expectations with respect to customizability and
	9	extendability.
	10
	11	This post marks the start of a series describing and documenting the design of the current
	12	iteration of `Beuteltier` (a derivation of [Newsbeuter](https://newsbeuter.org) and the
	13	german `Beutel`, meaning bag, to mean in conjunction:
	14	[Marsupial](https://en.wikipedia.org/wiki/Marsupial)).
	15
	16	It should be noted that the library described here is not finished or ready for use in any
	17	sense of the word (at the time of writing a "trivial" implementation of a `Beutel` shipped
	18	with the library supports only `run`, `search`, and `delete`). Searching a way to
	19	procrastinate implementing the more arduous `insert` (it requires nubbing—deduplication in
	20	the backstore) I decided to, instead, start this series of posts and put the thought that
	21	went into the library so far in a form that I can read again for later reference.
	22
	23	We begin, as is to be expected for a haskell project, with type definitions and, thus,
	24	design philosophy.
	25
	26	This post in particular reproduces the file `beuteltier/Beuteltier/Types.hs` from the
	27	[git repo](git://git.yggdrasil.li/beuteltier) with annotiations to provide some
	28	motivation.
	29
	30	The `Beuteltier` library itself only provides primitives for (and a default implementation
	31	of) access to what we call a backstore. A backstore is, to us, an instance of the
	32	typeclass `Beutel` which contains the most primitive of primitives for storing, searching
	33	for and deleting representations of the objects we care about from the store.
	34
	35	It is recommended that reader not try to follow the rest of this post linearly but start
	36	at the end with the definition of the `Beutel` class and work their way backwards.
	37
	38	> {-# LANGUAGE FlexibleInstances, StandaloneDeriving, KindSignatures, MultiParamTypeClasses, TypeFamilies #-}
	39	>
	40	> module Beuteltier.Types
	41	> ( -- * Types
	42	> Object
	43	> , ObjectGen(..)
	44	> , SubObject(..)
	45	> , MetaData(..)
	46	> , Thunk(..)
	47	> , ThunkState(..)
	48	> , ThunkResult(..)
	49	> , Tag
	50	> , Flag(..)
	51	> , SubObjectName
	52	> , ThunkName
	53	> , SearchQuery
	54	> , Predicate
	55	> , Beutel(..)
	56	> ) where
	57
	58	`Flag` ends up being a [sum type](https://en.wikipedia.org/wiki/Sum_type) holding values
	59	such as `Seen`, `Old`, or `Hidden`.
	60	We define it externally.
	61
	62	> import Beuteltier.Types.Flags
	63
	64	The `Identity` functor serves as basis for many a Monadtransformer-stack.
	65
	66	> import Data.Functor.Identity
	67	> import Data.Functor.Classes ()
	68
	69	Binary contents are encoded as `ByteStrings`
	70
	71	> import qualified Data.ByteString.Lazy as Lazy (ByteString)
	72	> import qualified Data.ByteString.Lazy as LBS
	73
	74	Unicode text as `Text`
	75
	76	> import Data.Text (Text)
	77
	78	Long unicode text as lazy `Text`
	79
	80	> import qualified Data.Text.Lazy as Lazy (Text)
	81	> import qualified Data.Text.Lazy as LT
	82	>
	83	> import Data.Set (Set)
	84	>
	85	> import Data.Map (Map)
	86	>
	87	> import Data.Time (UTCTime)
	88	>
	89	> import Data.Function (on)
	90	> import Data.Ord (comparing)
	91	> import Control.Applicative
	92
	93	`Data.Default` provides some convenience when constructing extensive record structures.
	94
	95	> import Data.Default
	96
	97	The `boolexpr` package provides us with a structure for representing boolean expressions
	98	supporting functor operations and evaluation.
	99
	100	> import Data.BoolExpr
	101
	102	Previous iterations of Beuteltier acted on Objects that were kept completely in RAM during
	103	all operations.
	104	This proved to be unsustainable, not only because nubbing (deduplication in the store of
	105	all objects) tended to exceed all RAM constraints (>4GiB for a few hundred objects), but
	106	also because cheaper operations on objects, like presentation to the user, got painfully
	107	slow once large `SubObject`s (like videos) were introduced into the store.
	108
	109	The straight forward solution was to enrich the `Object` structure with provisions for
	110	explicit lazyness and partial construction.
	111
	112	> -- \| We deal in, at runtime, partially retrieved Objects
	113	> data ObjectGen (f :: * -> *) = ObjectGen
	114	> { _oMeta :: f MetaData
	115	> -- ^ An undetermined set of Metainformation
	116	> , _oContent :: f (Map SubObjectName (f SubObject))
	117	> -- ^ A list of undetermined length of undetermined
	118	> 'SubObject's with guaranteed unique 'SubObjectName's
	119	> , _oThunks :: f [f Thunk]
	120	> -- ^ A list of undetermined length of undetermined Thunks.
	121	> -- There is such a thing as thunk colissions (i.e.: two
	122	> -- thunks promise or even create 'SubObject's with the
	123	> -- same name).
	124	> -- Precedence in such a case is to be as suggested by
	125	> -- the list structure (later thunks override earlier ones).
	126	> }
	127	>
	128	> instance Monad f => Default (ObjectGen f) where
	129	> def = ObjectGen { _oContent = return def
	130	> , _oThunks = return def
	131	> , _oMeta = return def
	132	> }
	133
	134	It is straight forward to collapse the more advanced representation of `Object`s back to
	135	the old behaviour by parametrising over the Identity functor, which is simply a newtype
	136	wrapper over the contained structure.
	137
	138	> -- \| An entirely retrieved Object
	139	> type Object = ObjectGen Identity
	140	>
	141	> -- -- \| The default 'Object' is empty except for metadata
	142	> -- instance Default Object where
	143	> -- def = ObjectGen { _oContent = return def
	144	> -- , _oThunks = return def
	145	> -- , _oMeta = return def
	146	> -- }
	147	>
	148	> -- \| Equality simply gets deferred to all subcomponents
	149	> deriving instance Eq Object
	150	>
	151	> -- \| 'Object's compare as their 'MetaData'
	152	> instance Ord Object where
	153	> compare = comparing _oMeta
	154
	155	We would like to associate some set of meta information with all objects.
	156	Therefore, we do.
	157
	158	> -- \| Metadata associated with an Object
	159	> data MetaData = MetaData
	160	> { _mRetrieved :: UTCTime -- ^ Time of creation
	161	> , _mTags :: Set Tag -- ^ Tags such as the name of the author,
	162	> -- the title of the work represented in
	163	> -- the 'Object', ….
	164	> -- We use something like @show . _mTags@
	165	> -- to identify an 'Object' to the user
	166	> , _mFlags :: Set Flag -- ^ Flags such as \"Read\" or \"Spam\"
	167	> } deriving (Show, Ord)
	168	> -- \| Tags are unicode text
	169	> type Tag = Text
	170	>
	171	> -- \| 'MetaData' equates as the contained tags
	172	> instance Eq MetaData where
	173	> (==) = (==) `on` _mTags
	174	>
	175	> -- \| The default MetaData has no tags, no flags, and an undefined timestamp
	176	> instance Default MetaData where
	177	> def = MetaData { _mFlags = def
	178	> , _mTags = def
	179	> , _mRetrieved = undefined -- There really is no such thing as a default time
	180	> }
	181
	182	Objects are no fun if they don´t contain anything of interest in the end.
	183
	184	Below we see a remnant of an older model of associating names to `SubObject`s. We switched
	185	to using a `Map` for reasons of deduplication. Inserting into a `Map` carries some
	186	guarantees that keys end up being unique.
	187
	188	Note below: creation of a `SubObject` is an update. It is thus expected, that `SubObject`s
	189	created at the same time as the `Object` they are associated to contain encode an update
	190	time that matches the `Object`s creation time.
	191
	192	> -- \| Contents of an object
	193	> data SubObject = SubObject
	194	> -- { _sId :: SubObjectName
	195	> -- ^ We associate a name to every chunk of content to determine
	196	> -- how to present an object to the user
	197	> { _sContent :: Lazy.ByteString
	198	> , _sUpdates :: [UTCTime]
	199	> -- ^ Times of witnessed updates to this 'SubObject'
	200	> } deriving (Show)
	201	>
	202	> -- \| No content, no witnessed updates
	203	> instance Default SubObject where
	204	> def = SubObject { _sContent = def
	205	> , _sUpdates = def
	206	> }
	207	>
	208	> -- \| Extensionality for 'SubObject's:
	209	> --
	210	> -- > (==) = (==) `on` _sContent
	211	> instance Eq SubObject where
	212	> (==) = (==) `on` _sContent
	213
	214	The distinguishing feature of Beuteltier is it´s support for `Thunk`s. They are, as the
	215	name suggests, loosly based on the concept of lazy evaluation. They are, however, less
	216	transparent and thus more explicit than implementations as they are used in, for example
	217	haskell.
	218
	219	As far as Beuteltier is concerned `Thunk`s are executables that are expected to produce
	220	files in the directory they are executed in in a pure manner. That is to say they do not
	221	access external resources, where possible. A `Thunk` that downloads a video from the
	222	internet will, of course, access the internet and can thus fail. We expect it, however, to
	223	not to try and access the users home directory to look for e.g. credentials for
	224	authentication it intends to use to its primary job.
	225
	226	When a `Thunk`s executable gets executed the files it creates (excluding itself) get
	227	translated to `SubObject`s with the filenames (directories stripped of course) as their
	228	`SubObjectName`s and the file contents as their… well, their contents. It is understood,
	229	that not all possible `SubObjectName`s can be created thus (we restrict ourselves to valid
	230	filenames on whatever system we happen to be on). We do not consider this to be a great
	231	loss.
	232
	233	The advanced equality checks mentioned below are, in fact, implemented and will be explained
	234	in more detail in a later post concerned with the file `beuteltier/Beuteltier/Types/Util.hs`.
	235
	236	> -- \| Thunks are at runtime not yet known parts of an object
	237	> data Thunk = Thunk
	238	> { _tId :: ThunkName -- ^ For debugging
	239	> , _tScript :: Lazy.ByteString
	240	> -- ^ A Thunk is, in the end, a shell script that is expected to generate
	241	> -- 'SubObject's
	242	> , _tPromises :: Maybe [SubObjectName]
	243	> -- ^ Maybe we already know what our script is going to generate?
	244	> -- This would enable us to do some more advanced equality checks under
	245	> -- the assumption that scripts are pure
	246	> , _tState :: ThunkState
	247	> }
	248	> deriving (Show)
	249	>
	250	> -- \| Empty id, empty script, promises nothing, and with default state
	251	> instance Default Thunk where
	252	> def = Thunk { _tId = def
	253	> , _tScript = def
	254	> , _tPromises = def
	255	> , _tState = def
	256	> }
	257	>
	258	> -- \| Equality on 'Thunk's ignores '_tState' and '_tId'
	259	> instance Eq Thunk where
	260	> a == b = and $ [ (==) `on` _tScript
	261	> , (==) `on` _tPromises
	262	> ] <> pure a <> pure b
	263	>
	264	> -- \| The states in which a 'Thunk' can be encountered.
	265	> data ThunkState = NotExecuted
	266	> \| Executed [SubObjectName] ThunkResult
	267	> deriving (Show)
	268	>
	269	> -- \| Return the default 'ThunkResult' upon forcing
	270	> instance Default ThunkState where
	271	> def = NotExecuted
	272	>
	273	> -- \| Thunks generate some data during execution
	274	> data ThunkResult = ThunkResult
	275	> { _rOutErr, _rOutStd :: Lazy.Text
	276	> , _rExit :: Integer -- ^ Numerical exit code (0 usually means success)
	277	> }
	278	> deriving (Show)
	279	>
	280	> -- \| Empty output, and with undefined exit code (no execution took place and we can´t
	281	> -- encode this in a numerical exit code)
	282	> instance Default ThunkResult where
	283	> def = ThunkResult { _rOutErr = LT.empty, _rOutStd = LT.empty
	284	> , _rExit = undefined
	285	> }
	286	>
	287	> -- \| We expect identifiers for 'SubObject's to be short, thus 'String'
	288	> type SubObjectName = String
	289	> -- \| We expect identifiers for 'Thunk's to be short, thus 'String'
	290	> type ThunkName = String
	291	>
	292	> -- \| @LBS.empty@
	293	> instance Default (Lazy.ByteString) where
	294	> def = LBS.empty
	295
	296	What good is a library for managing a backstore if it does not support search operations?
	297	We consider the answer to be "very little" and, thus, support searches.
	298
	299	> type SearchQuery f = BoolExpr (Predicate f)
	300	> -- data Predicate f = Prim (ObjectGen f -> f Bool)
	301	> -- \| Meta (MetaData -> Bool)
	302	> type Predicate f = ObjectGen f -> f Bool
	303
	304	The heart of the `Beuteltier` library is the typeclass reproduced below. We expect
	305	implementations of backstores to be `Monad`s so that we may be able to construct
	306	complicated actions that act on the backstore in question.
	307	Once we have constructed such an action using the three primitives `search`, `insert`, and
	308	`delete` we additionally require a way to execute that action from within the `IO`
	309	`Monad`.
	310
	311	Additional primitives, such as those for "forcing" and resetting thunks, are provided in
	312	additional libraries and, thus, later posts.
	313
	314	> -- \| We have the user supply the functions we use to interact with whatever backstore
	315	> -- she uses
	316	> class Monad functor => Beutel (functor :: * -> *) where
	317	> data Config :: *
	318	> run :: Config -> functor a -> IO a
	319	> -- ^ Actually run whatever action we constructed against the backstore
	320	> search :: SearchQuery functor -> functor [ObjectGen functor]
	321	> -- ^ Perform a search
	322	> insert :: Object -> functor ()
	323	> -- ^ Insert an object
	324	> delete :: SearchQuery functor -> functor ()
	325	> -- ^ Delete the results of a search