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1 {-|
2 Module : Gargantext.Prelude
3 Description : Specific Prelude of the project
4 Copyright : (c) CNRS, 2017-Present
5 License : AGPL + CECILL v3
6 Maintainer : team@gargantext.org
7 Stability : experimental
8 Portability : POSIX
9
10 Here is a longer description of this module, containing some
11 commentary with @some markup@.
12 -}
13
14 {-# OPTIONS_GHC -fno-warn-name-shadowing #-}
15 {-# OPTIONS_GHC -fno-warn-type-defaults #-}
16
17 {-# LANGUAGE NoImplicitPrelude #-}
18 {-# LANGUAGE OverloadedStrings #-}
19 {-# LANGUAGE RankNTypes #-}
20
21 module Gargantext.Prelude
22 ( module Gargantext.Prelude
23 , module Protolude
24 , headMay, lastMay
25 , module GHC.Err.Located
26 , module Text.Show
27 , module Text.Read
28 , cs
29 , module Data.Maybe
30 , round
31 , sortWith
32 )
33 where
34
35 import GHC.Exts (sortWith)
36 import GHC.Err.Located (undefined)
37 import GHC.Real (round)
38 import Control.Monad.IO.Class (MonadIO)
39 import Data.Maybe (isJust, fromJust, maybe)
40 import Data.Text (Text)
41 import Protolude ( Bool(True, False), Int, Int64, Double, Integer
42 , Fractional, Num, Maybe(Just,Nothing)
43 , Enum, Bounded, Float
44 , Floating, Char, IO
45 , pure, (>>=), (=<<), (<*>), (<$>)
46 , putStrLn
47 , head, flip
48 , Ord, Integral, Foldable, RealFrac, Monad, filter
49 , reverse, map, mapM, zip, drop, take, zipWith
50 , sum, fromIntegral, length, fmap, foldl, foldl'
51 , takeWhile, sqrt, identity
52 , abs, min, max, maximum, minimum, return, snd, truncate
53 , (+), (*), (/), (-), (.), ($), (&), (**), (^), (<), (>), log
54 , Eq, (==), (>=), (<=), (<>), (/=)
55 , (&&), (||), not, any, all
56 , fst, snd, toS
57 , elem, die, mod, div, const, either
58 , curry, uncurry, repeat
59 , otherwise, when
60 , IO()
61 , compare
62 , on
63 , panic
64 )
65
66 -- TODO import functions optimized in Utils.Count
67 -- import Protolude hiding (head, last, all, any, sum, product, length)
68 -- import Gargantext.Utils.Count
69 import qualified Data.List as L hiding (head, sum)
70 import qualified Control.Monad as M
71
72 import Data.Map (Map)
73 import qualified Data.Map as M
74
75 import Data.Map.Strict (insertWith)
76 import qualified Data.Vector as V
77 import Safe (headMay, lastMay, initMay, tailMay)
78 import Text.Show (Show(), show)
79 import Text.Read (Read())
80 import Data.String.Conversions (cs)
81
82
83 printDebug :: (Show a, MonadIO m) => [Char] -> a -> m ()
84 printDebug msg x = putStrLn $ msg <> " " <> show x
85 -- printDebug _ _ = pure ()
86
87
88 map2 :: (t -> b) -> [[t]] -> [[b]]
89 map2 fun = map (map fun)
90
91
92 -- Some Statistics sugar functions
93 -- Exponential Average
94 eavg :: [Double] -> Double
95 eavg (x:xs) = a*x + (1-a)*(eavg xs)
96 where a = 0.70
97 eavg [] = 0
98
99 -- Simple Average
100 mean :: Fractional a => [a] -> a
101 mean xs = if L.null xs then 0.0
102 else sum xs / fromIntegral (length xs)
103
104
105 sumMaybe :: Num a => [Maybe a] -> Maybe a
106 sumMaybe = fmap sum . M.sequence
107
108 variance :: Floating a => [a] -> a
109 variance xs = mean $ map (\x -> (x - m) ** 2) xs where
110 m = mean xs
111
112 deviation :: [Double] -> Double
113 deviation = sqrt . variance
114
115 movingAverage :: (Eq b, Fractional b) => Int -> [b] -> [b]
116 movingAverage steps xs = map mean $ chunkAlong steps 1 xs
117
118 ma :: [Double] -> [Double]
119 ma = movingAverage 3
120
121 -- | splitEvery n == chunkAlong n n
122 splitEvery :: Int -> [a] -> [[a]]
123 splitEvery _ [] = []
124 splitEvery n xs =
125 let (h,t) = L.splitAt n xs
126 in h : splitEvery n t
127
128 type Grain = Int
129 type Step = Int
130
131 -- | Function to split a range into chunks
132 -- if step == grain then linearity (splitEvery)
133 -- elif step < grain then overlapping
134 -- else dotted with holes
135 -- TODO FIX BUG if Steps*Grain /= length l
136 -- chunkAlong 10 10 [1..15] == [1..10]
137 -- BUG: what about the rest of (divMod 15 10)?
138 -- TODO: chunkAlongNoRest or chunkAlongWithRest
139 -- default behavior: NoRest
140
141 chunkAlong :: Eq a => Grain -> Step -> [a] -> [[a]]
142 chunkAlong a b l = case a >= length l of
143 True -> [l]
144 False -> chunkAlong' a b l
145
146 chunkAlong' :: Eq a => Grain -> Step -> [a] -> [[a]]
147 chunkAlong' a b l = case a > 0 && b > 0 of
148 True -> chunkAlong'' a b l
149 False -> panic "ChunkAlong: Parameters should be > 0 and Grain > Step"
150
151 chunkAlong'' :: Eq a => Int -> Int -> [a] -> [[a]]
152 chunkAlong'' a b l = filter (/= []) $ only (while dropAlong)
153 where
154 only = map (take a)
155 while = takeWhile (\x -> length x >= a)
156 dropAlong = L.scanl (\x _y -> drop b x) l ([1..] :: [Integer])
157
158 -- | Optimized version (Vector)
159 chunkAlongV :: Int -> Int -> V.Vector a -> V.Vector (V.Vector a)
160 chunkAlongV a b l = only (while dropAlong)
161 where
162 only = V.map (V.take a)
163 while = V.takeWhile (\x -> V.length x >= a)
164 dropAlong = V.scanl (\x _y -> V.drop b x) l (V.fromList [1..])
165
166 -- | TODO Inverse of chunk ? unchunkAlong ?
167 -- unchunkAlong :: Int -> Int -> [[a]] -> [a]
168 -- unchunkAlong = undefined
169
170
171 -- splitAlong [2,3,4] ("helloworld" :: [Char]) == ["he", "llo", "worl", "d"]
172 splitAlong :: [Int] -> [Char] -> [[Char]]
173 splitAlong _ [] = [] -- No list? done
174 splitAlong [] xs = [xs] -- No place to split at? Return the remainder
175 splitAlong (x:xs) ys = take x ys : splitAlong xs (drop x ys) -- take until our split spot, recurse with next split spot and list remainder
176
177 takeWhileM :: (Monad m) => (a -> Bool) -> [m a] -> m [a]
178 takeWhileM _ [] = return []
179 takeWhileM p (a:as) = do
180 v <- a
181 if p v
182 then do
183 vs <- takeWhileM p as
184 return (v:vs)
185 else return []
186
187 -- SUMS
188 -- To select the right algorithme according to the type:
189 -- https://github.com/mikeizbicki/ifcxt
190
191 sumSimple :: Num a => [a] -> a
192 sumSimple = L.foldl' (+) 0
193
194 -- | https://en.wikipedia.org/wiki/Kahan_summation_algorithm
195 sumKahan :: Num a => [a] -> a
196 sumKahan = snd . L.foldl' go (0,0)
197 where
198 go (c,t) i = ((t'-t)-y,t')
199 where
200 y = i-c
201 t' = t+y
202
203 -- | compute part of the dict
204 count2map :: (Ord k, Foldable t) => t k -> Map k Double
205 count2map xs = M.map (/ (fromIntegral (length xs))) (count2map' xs)
206
207 -- | insert in a dict
208 count2map' :: (Ord k, Foldable t) => t k -> Map k Double
209 count2map' xs = L.foldl' (\x y -> insertWith (+) y 1 x) M.empty xs
210
211
212 trunc :: (RealFrac a, Integral c, Integral b) => b -> a -> c
213 trunc n = truncate . (* 10^n)
214
215 trunc' :: Int -> Double -> Double
216 trunc' n x = fromIntegral $ truncate $ (x * 10^n)
217
218
219 ------------------------------------------------------------------------
220 bool2num :: Num a => Bool -> a
221 bool2num True = 1
222 bool2num False = 0
223
224 bool2double :: Bool -> Double
225 bool2double = bool2num
226
227 bool2int :: Bool -> Int
228 bool2int = bool2num
229 ------------------------------------------------------------------------
230
231 -- Normalizing && scaling data
232 scale :: [Double] -> [Double]
233 scale = scaleMinMax
234
235 scaleMinMax :: [Double] -> [Double]
236 scaleMinMax xs = map (\x -> (x - mi / (ma - mi + 1) )) xs'
237 where
238 ma = maximum xs'
239 mi = minimum xs'
240 xs' = map abs xs
241
242 scaleNormalize :: [Double] -> [Double]
243 scaleNormalize xs = map (\x -> (x - v / (m + 1))) xs'
244 where
245 v = variance xs'
246 m = mean xs'
247 xs' = map abs xs
248
249 normalize :: [Double] -> [Double]
250 normalize as = normalizeWith identity as
251
252 normalizeWith :: Fractional b => (a -> b) -> [a] -> [b]
253 normalizeWith extract bs = map (\x -> x/(sum bs')) bs'
254 where
255 bs' = map extract bs
256
257 -- Zip functions to add
258 zipFst :: ([b] -> [a]) -> [b] -> [(a, b)]
259 zipFst f xs = zip (f xs) xs
260
261 zipSnd :: ([a] -> [b]) -> [a] -> [(a, b)]
262 zipSnd f xs = zip xs (f xs)
263
264 -- | maximumWith
265 maximumWith :: (Ord a1, Foldable t) => (a2 -> a1) -> t a2 -> a2
266 maximumWith f = L.maximumBy (compare `on` f)
267
268
269 -- | To get all combinations of a list with no repetition and apply a function to the resulting list of pairs
270 listToCombi :: forall a b. (a -> b) -> [a] -> [(b,b)]
271 listToCombi f l = [ (f x, f y) | (x:rest) <- L.tails l, y <- rest ]
272
273 ------------------------------------------------------------------------
274 -- Empty List Sugar Error Handling
275 -- TODO add Garg Monad Errors
276
277 listSafe1 :: Text -> ([a] -> Maybe a)
278 -> Text -> [a] -> a
279 listSafe1 s f e xs = maybe (panic $ h <> e) identity (f xs)
280 where
281 h = "[ERR][Gargantext] Empty list for " <> s <> " in "
282
283 head' :: Text -> [a] -> a
284 head' = listSafe1 "head" headMay
285
286 last' :: Text -> [a] -> a
287 last' = listSafe1 "last" lastMay
288
289 ------------------------------------------------------------------------
290
291 listSafeN :: Text -> ([a] -> Maybe [a])
292 -> Text -> [a] -> [a]
293 listSafeN s f e xs = maybe (panic $ h <> e) identity (f xs)
294 where
295 h = "[ERR][Gargantext] Empty list for " <> s <> " in "
296
297 tail' :: Text -> [a] -> [a]
298 tail' = listSafeN "tail" tailMay
299
300 init' :: Text -> [a] -> [a]
301 init' = listSafeN "init" initMay
302