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1 {-|
2 Module : Gargantext.Core.Text.Terms.Eleve
3 Description : Unsupervized Word segmentation
4 Copyright : (c) CNRS, 2019-Present
5 License : AGPL + CECILL v3
6 Maintainer : team@gargantext.org
7 Stability : experimental
8 Portability : POSIX
9
10 # Implementation of Unsupervized Word Segmentation
11
12 References:
13
14 - Python implementation (Korantin August, Emmanuel Navarro):
15 [EleVe](https://github.com/kodexlab/eleve.git)
16
17 - Unsupervized Word Segmentation:the case for Mandarin Chinese Pierre
18 Magistry, Benoît Sagot, Alpage, INRIA & Univ. Paris 7, Proceedings of
19 the 50th Annual Meeting of the Association for Computational Linguistics
20 , pages 383–387. [PDF](https://www.aclweb.org/anthology/P12-2075)
21
22 Notes for current implementation:
23 - TODO extract longer ngrams (see paper above, viterbi algo can be used)
24 - TODO AD TEST: prop (Node c _e f) = c == Map.size f
25
26 - AD: Real ngrams extraction test
27 from Gargantext.Core.Text.Terms import extractTermsUnsupervised
28 docs <- runCmdRepl $ selectDocs 1004
29 extractTermsUnsupervised 3 $ DT.intercalate " "
30 $ catMaybes
31 $ Gargantext.map _hyperdataDocument_abstract docs
32
33 -}
34 {-# LANGUAGE ConstraintKinds #-}
35 {-# LANGUAGE TemplateHaskell #-}
36 {-# LANGUAGE TypeFamilies #-}
37
38 module Gargantext.Core.Text.Terms.Eleve where
39
40 -- import Debug.Trace (trace)
41 -- import Debug.SimpleReflect
42
43 import Control.Lens hiding (levels, children)
44 import Control.Monad (forM_)
45 import qualified Data.List as L
46 import Data.Monoid
47 import Data.Text (Text)
48 import qualified Data.Text as T
49 import Data.Map (Map)
50 import Data.Maybe (fromMaybe)
51 import qualified Data.Map as Map
52 import Gargantext.Prelude hiding (cs)
53 import qualified Data.Tree as Tree
54 import Data.Tree (Tree)
55 import qualified Prelude as P (putStrLn, logBase, isNaN, RealFloat)
56
57 nan :: Floating e => e
58 nan = 0 / 0
59
60 noNaNs :: P.RealFloat e => [e] -> [e]
61 noNaNs = filter (not . P.isNaN)
62
63 updateIfDefined :: P.RealFloat e => e -> e -> e
64 updateIfDefined e0 e | P.isNaN e = e0
65 | otherwise = e
66
67 sim :: Entropy e => e -> e -> Bool
68 sim x y = x == y || (P.isNaN x && P.isNaN y)
69
70 subst :: Entropy e => (e, e) -> e -> e
71 subst (src, dst) x | sim src x = dst
72 | otherwise = x
73 ------------------------------------------------------------------------
74
75 -- | TODO: Show Instance only used for debugging
76 type Entropy e =
77 ( Fractional e
78 , Floating e
79 , P.RealFloat e
80 , Show e
81 )
82 ------------------------------------------------------------------------
83 -- | Example and tests for development
84 data I e = I
85 { _info_entropy :: e
86 , _info_entropy_var :: e
87 , _info_autonomy :: e
88 }
89
90 instance Show e => Show (I e) where
91 show (I e ev a) = show (e, ev, a)
92
93 makeLenses ''I
94
95 type ModEntropy i o e = (e -> e) -> i -> o
96
97 set_autonomy :: Entropy e => ModEntropy (I e) (I e) e
98 set_autonomy fe i = i & info_autonomy .~ fe (i ^. info_entropy_var)
99
100 set_entropy_var :: Entropy e => Setter e (I e) e e
101 set_entropy_var f e = (\ev -> I e ev nan) <$> f e
102
103 data StartStop = Start | Stop
104 deriving (Ord, Eq, Show)
105
106 data Token = NonTerminal Text
107 | Terminal StartStop
108 deriving (Ord, Eq, Show)
109
110 isTerminal :: Token -> Bool
111 isTerminal (Terminal _) = True
112 isTerminal (NonTerminal _) = False
113
114 nonTerminals :: [Token] -> [Text]
115 nonTerminals ts = [nt | NonTerminal nt <- ts]
116
117 parseToken :: Text -> Token
118 parseToken "<start>" = Terminal Start
119 parseToken "<stop>" = Terminal Stop
120 parseToken t = NonTerminal t
121
122 toToken :: [Text] -> [Token]
123 toToken xs = Terminal Start : (NonTerminal <$> xs) <> [Terminal Stop]
124
125 printToken :: Token -> Text
126 printToken = f
127 where
128 f (NonTerminal x) = x
129 f (Terminal Start) = "<start>"
130 f (Terminal Stop) = "<stop>"
131 ------------------------------------------------------------------------
132
133 data Trie k e
134 = Node { _node_count :: Int
135 , _node_entropy :: e
136 , _node_children :: Map k (Trie k e)
137 }
138 | Leaf { _node_count :: Int }
139 deriving (Show)
140
141 makeLenses ''Trie
142
143 insertTrie :: Ord k => [k] -> Trie k () -> Trie k ()
144 insertTrie [] n = n { _node_count = _node_count n +1}
145 insertTrie (x:xs) (Leaf c) = mkTrie (c+1) $ Map.singleton x $ insertTrie xs emptyTrie
146 insertTrie (x:xs) (Node c _e children) = mkTrie (c+1) $ Map.alter f x children
147 where
148 f = Just . insertTrie xs . fromMaybe emptyTrie
149
150 -- emptyTrie :: (Ord k, Monoid e) => Trie k e
151 -- emptyTrie = Node 0 mempty mempty
152 emptyTrie :: Trie k e
153 emptyTrie = Leaf 0
154
155 mkTrie :: Monoid e => Int -> Map k (Trie k e) -> Trie k e
156 mkTrie c children
157 | Map.null children = Leaf c
158 | otherwise = Node c mempty children
159
160 -----------------------------
161 -- | Trie to Tree since Tree as nice print function
162 toTree :: k -> Trie k e -> Tree (k,Int,Maybe e)
163 toTree k (Leaf c) = Tree.Node (k, c, Nothing) []
164 toTree k (Node c e cs) = Tree.Node (k, c, Just e) (map (uncurry toTree) $ Map.toList cs)
165
166 ------------------------------------------------------------------------
167 ------------------------------------------------------------------------
168 normalizeLevel :: Entropy e => e -> e -> e -> e
169 normalizeLevel m v e = (e - m) / v
170
171 {- Unused
172
173 nodeChildren :: Trie k e -> Map k (Trie k e)
174 nodeChildren (Node _ _ cs) = cs
175 nodeChildren (Leaf _) = Map.empty
176
177 -}
178
179 chunkAlongEleve :: Int -> [a] -> [[a]]
180 chunkAlongEleve n xs = L.take n <$> L.tails xs
181
182 data Direction = Backward | Forward
183
184 buildTrie :: Direction -> Int -> [[Token]] -> Trie Token ()
185 buildTrie d n sentences
186 = L.foldr insertTrie emptyTrie
187 . L.concat
188 $ ( filter (/= [Terminal (term d)])
189 . chunkAlongEleve (n + 1)
190 . order d
191 )
192 <$> sentences
193 where
194 order Forward = identity
195 order Backward = reverse
196 term Forward = Stop
197 term Backward = Start
198
199 class IsTrie trie where
200 entropyTrie :: Entropy e => (k -> Bool) -> trie k () -> trie k e
201 nodeEntropy :: Entropy e => Getting e i e -> trie k i -> e
202 nodeChild :: Ord k => k -> trie k e -> trie k e
203 findTrie :: Ord k => [k] -> trie k e -> trie k e
204 printTrie :: (Show i, Entropy e) => Getting e i e -> trie Token i -> IO ()
205 evTrie :: Entropy e => Getting e i e -> Setter i o e e -> trie k i -> trie k o
206 normalizeEntropy :: Entropy e
207 => Getting e i e -> ModEntropy i o e
208 -> trie k i -> trie k o
209
210 instance IsTrie Trie where
211
212 entropyTrie _ (Leaf c) = Leaf c
213 entropyTrie pred (Node c () children) = Node c e (map (entropyTrie pred) children)
214 where
215 children' = Map.toList children
216 sum_count = sum $ _node_count . snd <$> children'
217 e | sum_count == 0 = nan
218 | otherwise = sum $ f <$> children'
219 f (k, child) = if pred k then chc * P.logBase 2 (fromIntegral c)
220 else - chc * P.logBase 2 chc
221 where
222 chc = fromIntegral (_node_count child) / fromIntegral c
223
224 nodeEntropy inE (Node _ e _) = e ^. inE
225 nodeEntropy _ (Leaf _) = nan
226
227 nodeChild k (Node _ _ cs) = fromMaybe emptyTrie (Map.lookup k cs)
228 nodeChild _ (Leaf _) = emptyTrie
229
230 findTrie ks t = L.foldl (flip nodeChild) t ks
231
232 printTrie inE t = do
233 P.putStrLn . Tree.drawTree
234 . fmap show
235 $ toTree (NonTerminal "") t
236 P.putStrLn " Levels:"
237 forM_ (normalizationLevels inE t) $ \level ->
238 P.putStrLn $ " " <> show level
239
240 evTrie inE setEV = go nan
241 where
242 go _ (Leaf c) = Leaf c
243 go e0 (Node c i children) = Node c (i & setEV .~ ev e0 e1) $ go e1 <$> children
244 where e1 = i ^. inE
245
246 ev 0 0 = nan
247 ev i0 i1 = i1 - i0
248
249 normalizeEntropy inE modE t = go (modE identity) (normalizationLevels inE t) t
250 where
251 go _ _ (Leaf c) = Leaf c
252 go _ [] _ = panic "normalizeEntropy' empty levels"
253 go f ((m, v, _) : ess) (Node c i children)
254 = Node c (f i) $ go (modE $ normalizeLevel m v) ess <$> children
255 ------------------------------------------------------------------------
256
257 levels :: Trie k e -> [[Trie k e]]
258 levels = L.takeWhile (not . L.null) . L.iterate (L.concatMap subForest) . pure
259 where
260 subForest :: Trie k e -> [Trie k e]
261 subForest (Leaf _) = []
262 subForest (Node _ _ children) = Map.elems children
263
264 entropyLevels :: Entropy e => Getting e i e -> Trie k i -> [[e]]
265 entropyLevels inE = fmap (noNaNs . map (nodeEntropy inE)) . L.tail . levels
266
267 normalizationLevels :: Entropy e => Getting e i e -> Trie k i -> [(e, e, Int)]
268 normalizationLevels inE = fmap f . entropyLevels inE
269 where
270 f es = (mean es, deviation es, length es)
271
272 ------------------------------------------------------------------------
273
274 data Tries k e = Tries
275 { _fwd :: Trie k e
276 , _bwd :: Trie k e
277 }
278
279 makeLenses ''Tries
280
281 buildTries :: Int -> [[Token]] -> Tries Token ()
282 buildTries n sentences = Tries
283 { _fwd = buildTrie Forward n sentences
284 , _bwd = buildTrie Backward n sentences
285 }
286
287 instance IsTrie Tries where
288
289 nodeEntropy inE (Tries f b) = mean [nodeEntropy inE f, nodeEntropy inE b]
290
291 findTrie ks (Tries f b) = Tries (findTrie ks f) (findTrie (reverse ks) b)
292
293 nodeChild = onTries . nodeChild
294
295 entropyTrie = onTries . entropyTrie
296
297 evTrie inE setEV = onTries $ evTrie inE setEV
298
299 normalizeEntropy inE = onTries . normalizeEntropy inE
300
301 printTrie inE (Tries f b) = do
302 P.putStrLn "Forward:"
303 printTrie inE f
304 P.putStrLn ""
305 P.putStrLn "Backward:"
306 printTrie inE b
307
308 onTries :: (Trie k i -> Trie k o) -> Tries k i -> Tries k o
309 onTries h (Tries f b) = Tries (h f) (h b)
310
311 ------------------------------------------------------------------------
312 mayCons :: [a] -> [[a]] -> [[a]]
313 mayCons [] xss = xss
314 mayCons xs xss = xs : xss
315
316 {-
317 split :: (IsTrie trie, Entropy e) => Lens' i e -> trie Token i -> [Token] -> [[Token]]
318 split _ _ [] = []
319 split inE t (Terminal Start:xs) = split inE t xs
320 split inE t (x0:xs0) = go [x0] xs0
321 where
322 go pref [] = [pref]
323 go pref (Terminal Stop:_) = [pref]
324 go _ (Terminal Start:_) = panic "split impossible"
325 go pref (x:xs) =
326 -- trace (show (if acc then "ACC" else "CUT", (prefx, epxt), if acc then ">" else "<=", ((pref, ept), "+", ([x], ext)))) $
327 if acc
328 then go prefx xs
329 else mayCons pref $ go [x] xs
330 where
331 prefx = pref <> [x]
332 pt = findTrie pref t
333 pxt = findTrie prefx t
334 xt = findTrie [x] t
335 ept = ne pt
336 -- ^ entropy of the current prefix
337 ext = ne xt
338 -- ^ entropy of [x]
339 epxt = ne pxt
340 -- ^ entropy of the current prefix plus x
341 acc = P.isNaN ept || P.isNaN ext || not (P.isNaN epxt) -- && (epxt > mean [ept, ext])
342
343 -- aut(["in","this","paper"]) > aut(["in","this"]) + aut(["paper"])
344
345 ne = nodeEntropy inE
346 -}
347
348 split :: Entropy e => Int -> Lens' i e -> Tries Token i -> [Token] -> [[Text]]
349 split _ _ _ [] = []
350 split _ _ _ [t] = pure <$> nonTerminals [t]
351 split n inE t ts = nonTerminals pref `mayCons` split n inE t (drop (length pref) ts)
352 where
353 pref = maximumWith (\ks -> nodeEntropy inE $ findTrie ks t)
354 (L.tail . L.inits . take n $ ts)
355
356
357 {-
358 split :: Entropy e => Lens' i e -> Tries Token i -> [Token] -> [[Token]]
359 split inE t0 ts =
360 maximumWith (sum . map $ nodeAutonomy inE t0) (all the splits of ts)
361 -}
362
363 ------------------------------------------------------------------------
364
365 mainEleve :: Int -> [[Text]] -> [[[Text]]]
366 mainEleve n x = mainEleve' n x x
367
368 mainEleve' :: Int -> [[Text]] -> [[Text]] -> [[[Text]]]
369 mainEleve' n x y = mainEleveWith x' n y
370 where
371 x' = buildTries n (fmap toToken x)
372 -- (fmap toToken i) is computed twice, since mainEleveWith is computing it too
373
374 -- | This function should take the longest possible chain of:
375 -- mainEleve'' n x y = maxChainSizeOf [ mainEleve' n x y
376 -- , mainEleve' n x x
377 -- , mainEleve' n y y
378 -- ]
379 mainEleve'' :: Int -> [[Text]] -> [[Text]] -> [[[Text]]]
380 mainEleve'' = undefined
381
382 mainEleveWith :: Tries Token () -> Int -> [[Text]] -> [[[Text]]]
383 mainEleveWith m n i = fmap (split n info_autonomy t) (fmap toToken i)
384 where
385 t :: Tries Token (I Double)
386 t = normalizeEntropy info_entropy_var set_autonomy
387 $ evTrie identity set_entropy_var
388 $ entropyTrie isTerminal m
389
390 ------------------------------------------------------------------------
391
392 type Checks e = [(Text, Int, e, e, e, e, e, e, e, e, e)]
393
394 testEleve :: e ~ Double => Bool -> Int -> [Text] -> Checks e -> IO Bool
395 testEleve debug n output checks = do
396 let
397 res = split (1 + n) info_autonomy nt <$> input
398 when debug $ do
399 P.putStrLn . show $ (printToken <$>) <$> input
400 P.putStrLn ""
401 printTrie info_entropy nt
402 P.putStrLn ""
403 P.putStrLn "Splitting:"
404 P.putStrLn $ show res
405 forM_ checks checker
406 pure $ expected == res
407
408 where
409 out = T.words <$> output
410 expected = fmap (T.splitOn "-") <$> out
411 input = toToken . (T.splitOn "-" =<<) <$> out
412
413 nt :: Tries Token (I Double)
414 nt = normalizeEntropy info_entropy_var set_autonomy
415 . evTrie identity set_entropy_var
416 . entropyTrie isTerminal
417 $ buildTries n input
418
419 check f msg ref my =
420 if f ref my
421 then P.putStrLn $ " \ESC[32mPASS\ESC[m " <> msg <> " " <> show ref
422 else P.putStrLn $ " \ESC[31mFAIL\ESC[m " <> msg <> " ref=" <> show ref <> " my=" <> show my
423
424 checker (ngram, count, entropy, ev, autonomy, fwd_entropy, fwd_ev, fwd_autonomy, bwd_entropy, bwd_ev, bwd_autonomy) = do
425 let ns = parseToken <$> T.words ngram
426 nt' = findTrie ns nt
427
428 P.putStrLn $ " " <> T.unpack ngram <> ":"
429 check (==) "count" count (_node_count (_fwd nt'))
430
431 check sim "entropy" entropy (nodeEntropy info_entropy nt' )
432 check sim "ev" ev (nodeEntropy info_entropy_var nt' )
433 check sim "autonomy" autonomy (nodeEntropy info_autonomy nt' )
434
435 check sim "fwd_entropy" fwd_entropy (nodeEntropy info_entropy (_fwd nt'))
436 check sim "fwd_ev" fwd_ev (nodeEntropy info_entropy_var (_fwd nt'))
437 check sim "fwd_autonomy" fwd_autonomy (nodeEntropy info_autonomy (_fwd nt'))
438
439 check sim "bwd_entropy" bwd_entropy (nodeEntropy info_entropy (_bwd nt'))
440 check sim "bwd_ev" bwd_ev (nodeEntropy info_entropy_var (_bwd nt'))
441 check sim "bwd_autonomy" bwd_autonomy (nodeEntropy info_autonomy (_bwd nt'))
442
443 -- | TODO real data is a list of tokenized sentences
444 example0, example1, example2, example3, example4, example5, example6, example7, example8, example9 :: [Text]
445 example0 = ["New-York is New-York and New-York"]
446 example1 = ["to-be or not to-be"]
447 example2 = ["to-be-or not to-be-or NOT to-be and"]
448 example3 = example0 <> example0
449 -- > TEST: Should not have York New in the trie
450 example4 = ["a-b-c-d e a-b-c-d f"]
451 example5 = ["a-b-c-d-e f a-b-c-d-e g a-b-c-d-e"]
452 example6 = ["le-petit chat"
453 ,"le-petit chien"
454 ,"le-petit rat"
455 ,"le gros rat"
456 ]
457 example7 = ["a-b d", "a-c e", "a-c", "a-b", "a-b", "a-c", "a-c", "a-b"]
458 -- example8 = ["z f", "z", "z", "z"] <> example7
459 example8 = ["z", "z", "z", "z"] <> example7 <> example7 <> example7
460 example9 = (T.replace "z" "a") <$> example8
461 --example8 = ["a-b d", "a-c e", "a f", "a-c g", "a-b h", "a i", "a j", "a-b k", "a-c l", "a-c m", "a n", "a-b o"]
462
463 checks0, checks2, checks7, checks8, checks9 :: Checks Double
464
465 checks0 =
466 -- [(token, count, entropy, ev, autonomy, fwd_entropy, fwd_ev, fwd_autonomy, bwd_entropy, bwd_ev, bwd_autonomy)]
467 [ ("<start>", 1, nan, nan, nan, 0.0, -2.113283334294875, -0.5000000000000002, nan, nan, nan)
468 , ("New", 3, 0.792481250360578, -1.3208020839342969, 0.7499999999999999, 0.0, -2.113283334294875, -0.5000000000000002, 1.584962500721156, -0.5283208335737188, 2.0)
469 , ("York", 3, 0.792481250360578, -1.3208020839342969, 0.7499999999999999, 1.584962500721156, -0.5283208335737188, 2.0, 0.0, -2.113283334294875, -0.5000000000000002)
470 , ("is", 1, 0, -2.113283334294875, -0.5000000000000002, 0.0, -2.113283334294875, -0.5000000000000002, 0.0, -2.113283334294875, -0.5000000000000002)
471 , ("and", 1, 0, -2.113283334294875, -0.5000000000000002, 0.0, -2.113283334294875, -0.5000000000000002, 0.0, -2.113283334294875, -0.5000000000000002)
472 , ("<stop>", 0, nan, nan, nan, nan, nan, nan, 0.0, -2.113283334294875, -0.5000000000000002)
473 , ("<start> New", 1, nan, nan, nan, 0.0, nan, nan, nan, nan, nan)
474 , ("New York", 3, 1.584962500721156, 1.584962500721156, 1.414213562373095, 1.584962500721156, 1.584962500721156, 1.4142135623730947, 1.584962500721156, 1.584962500721156, 1.4142135623730951)
475 , ("York is", 1, 0, nan, nan, 0.0, -1.584962500721156, -0.7071067811865476, 0.0, nan, nan)
476 , ("is New", 1, 0, nan, nan, 0.0, nan, nan, 0.0, -1.584962500721156, -0.7071067811865474)
477 , ("York and", 1, 0, nan, nan, 0.0, -1.584962500721156, -0.7071067811865476, 0.0, nan, nan)
478 , ("and New", 1, 0, nan, nan, 0.0, nan, nan, 0.0, -1.584962500721156, -0.7071067811865474)
479 , ("York <stop>", 1, nan, nan, nan, nan, nan, nan, 0.0, nan, nan)
480 , ("<start> New York", 1, nan, nan, nan, 0.0, nan, nan, nan, nan, nan)
481 , ("New York is", 1, 0, nan, nan, 0.0, -1.584962500721156, nan, 0.0, nan, nan)
482 , ("York is New", 1, 0, nan, nan, 0.0, nan, nan, 0.0, nan, nan)
483 , ("is New York", 1, 0, nan, nan, 0.0, nan, nan, 0.0, -1.584962500721156, nan)
484 , ("New York and", 1, 0, nan, nan, 0.0, -1.584962500721156, nan, 0.0, nan, nan)
485 , ("York and New", 1, 0, nan, nan, 0.0, nan, nan, 0.0, nan, nan)
486 , ("and New York", 1, 0, nan, nan, 0.0, nan, nan, 0.0, -1.584962500721156, nan)
487 , ("New York <stop>", 1, nan, nan, nan, nan, nan, nan, 0.0, nan, nan)
488 ]
489
490 checks2 = []
491 {-
492 [("to be", 3, 1.2516291673878228, 1.2516291673878228, 1.5535694744293167, nan, 0.9182958340544896)
493 ,("be or", 2, 0.5, nan, nan, nan, 1.0)
494 ,("or not", 1, 0.0, nan, nan, nan, 0.0)
495 ,("not to", 1, 0.0, nan, nan, nan, 0.0)
496 ,("or NOT", 1, 0.0, nan, nan, nan, 0.0)
497 ,("NOT to", 1, 0.0, nan, nan, nan, 0.0)
498 ,("be and", 1, 0.0, nan, nan, nan, 0.0)
499 ]
500 -}
501
502 checks7 =
503 [ ("a b", 4, 2, 1.5, 1.0106455960380136, 2, 1, 0.7302967433402215, 2, 2, 1.2909944487358056)
504 , ("a c", 4, 2, 1.5, 1.0106455960380136, 2, 1, 0.7302967433402215, 2, 2, 1.2909944487358056)
505 , ("a", 8, 2, -0.7139421727208477, 0.9315597394596105, 1, -1.7139421727208477, 0.1695158759052029, 3, 0.2860578272791523, 1.693603603014018)
506 ]
507
508 checks8 =
509 [ ("a b", 4, 2, 1.5, 1.2384061243840367, 2, 1, 0.9190418024406298, 2, 2, 1.5577704463274435)
510 , ("a c", 4, 2, 1.5, 1.2384061243840367, 2, 1, 0.9190418024406298, 2, 2, 1.5577704463274435)
511 , ("a", 8, 2, -1.1151193576322829, 0.8012882295122719, 1, -2.115119357632283, 1.1025957503820932e-2, 3, -0.11511935763228287, 1.5915505015207227)
512 , ("z", 4, 2, -1.1151193576322829, 0.9576679529201777, 2, -1.1151193576322829, 1.0906240295212841, 2, -1.1151193576322829, 0.8247118763190712)
513 ]
514
515 checks9 =
516 [ ("a b", 4, 2, 0.8741854163060885, 0.9234576822288185, 2, -0.25162916738782304, 0.2891449181301934, 2, 2, 1.5577704463274435)
517 , ("a c", 4, 2, 0.8741854163060885, 0.9234576822288185, 2, -0.25162916738782304, 0.2891449181301934, 2, 2, 1.5577704463274435)
518 , ("a", 12, 2.91829583405449, 3.763498724462999e-2, 1.518835832034022, 2.251629167387823, -0.6290316794220367, 1.2162041043595873, 3.5849625007211565, 0.7043016539112967, 1.8214675597084569)
519 ]
520
521 runTestsEleve :: Bool -> IO ()
522 runTestsEleve doChecks =
523 forM_
524 [("example0", 3, example0, checks0)
525 ,("example0", 2, example0, [])
526 ,("example1", 2, example1, [])
527 ,("example2", 3, example2, checks2)
528 ,("example3", 2, example3, [])
529 ,("example4", 4, example4, [])
530 ,("example5", 5, example5, [])
531 ,("example6", 2, example6, [])
532 ,("example7", 2, example7, checks7)
533 ,("example8", 2, example8, checks8)
534 ,("example9", 2, example9, checks9)
535 ]
536 (\(name, n, ex, checks) -> do
537 P.putStrLn $ name <> " " <> show n
538 b <- testEleve False n ex (if doChecks then checks else [])
539 P.putStrLn $ " splitting: " <> if b then "PASS" else "FAIL"
540 )