1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216

--- ----------------------------------------------------------------------------
--- This module performs some compression on the resultants.
--- This is necessary because the termination criteria leads to many
--- intermediate specializations which occur only once
--- and can therefore be inlined.
---
--- Note that some optimizations may never be applied depending on the partial
--- evaluation mechanism.
---
--- @author Elvira Albert, German Vidal, Michael Hanus, Björn Peemöller
--- @version December 2018
--- ----------------------------------------------------------------------------
module PostUnfold (unAlias, postUnfold, removeCopies) where

import Function         (first, second)
import List             (delete, find, partition)
import Text.Pretty      (Doc, (<+>), ($$), pPrint, text)
import Utils            (count, countBy)

import FlatCurry.Types
import System.Console.ANSI.Codes ( yellow )

import FlatCurryGoodies ( addPartCallArg, funcsInExps, isFuncCall, isPartCall
                        , isVar, maximumVarIndex, mkLet, trExpr
                        , prelApply, prelFailed, prelPEVAL )
import FlatCurryPretty  ( ppExp, indent )
import NameChange       ( NameChange, ncRenaming, ncResultants, ncExpr )
import Normalization    ( simplifyExpr, normalizeFreeExpr
                        , freshResultant, renameResultant)
import Output           ( colorWith, traceDetail )
import PevalBase        ( Renaming, Resultant, ppResultant, mkFuncCall )
import PevalOpts        ( Options )

-- -----------------------------------------------------------------------------
-- Interface
-- -----------------------------------------------------------------------------

--- Compress the resultants.
--- @param fs - List of functions called by user-annotated expressions.
--- @param rs - Resultants to be compressed.
postUnfold :: Options -> [QName] -> Renaming -> [Resultant]
           -> (Renaming, [Resultant])
postUnfold opts fs rho0 rs0 = go rho0 rs0
 where
  go rho rs | rs' == rs = (rho, rs)
            | otherwise = go rho' rs'
    where (rho', rs') = unAlias rho (puResultants opts fs rs)

--- Remove aliases and duplicates.
unAlias :: Renaming -> [Resultant] -> (Renaming, [Resultant])
unAlias rho rs = remove duplicates $ remove aliases (rho, rs)

--- Removes any resultants that are copies of ordinary program functions
--- to avoid code duplication.
removeCopies :: Prog -> Renaming -> [Resultant] -> (Renaming, [Resultant])
removeCopies (Prog _ _ _ fs _) rho rs = remove (copies fs rho) (rho, rs)

-- -----------------------------------------------------------------------------
-- Removal of duplicates and alike
-- -----------------------------------------------------------------------------

--- Identify aliases in the list of resultants such as
--- `f x1 ... xn = g x1 ... xn`.
-- TODO: This implementation only replaces fully applied function calls,
-- thus in the following example no progress is made:
-- f   = g
-- g x = x
-- because `g` is a partial function call. This could be remedied by not only
-- covering *name* changes, but also *arity* changes, i.e., one could replace
-- `Comb FuncCall f []` by `Comb (FuncPartCall 1) g []`.
aliases :: [Resultant] -> (NameChange, [Resultant])
aliases = foldr checkAlias ([], [])
  where
  checkAlias r@((f, vs), e) (as, rs) = case e of
    Comb FuncCall g es | f /= g && es == map Var vs
      -> ((f, g) : as,     rs)
    _ -> (         as, r : rs)

--- Identify duplicates in the list of resultants such as
--- `f x1 ... xn = e` and g x1 ... xn = e'` where `e' = e[f/g]`.
duplicates :: [Resultant] -> (NameChange, [Resultant])
duplicates []                  = ([], [])
duplicates (r@((f, vs), e) : rs) = case break isDuplicate rs of
  (_  , []             ) -> second (r:) (duplicates rs)
  (rs1, ((g, _), _):rs2) -> let (als, rs') = duplicates (rs1 ++ rs2)
                            in  ((g, f) : als, r : rs')
 where isDuplicate ((g, vs'), e') = vs == vs' && ncExpr [(f, g)] e == e'

--- Identify copies of program functions in the list of resultants such as
--- `f x1 ... xn = e` where g x1 ... xn = e` is contained in the program.
copies :: [FuncDecl] -> Renaming -> [Resultant] -> (NameChange, [Resultant])
copies _  _   []                    = ([], [])
copies fs rho (r@((f, vs), e) : rs) = case find isCopy fs of
  Nothing               -> second (r:)       (copies fs rho rs)
  Just (Func g _ _ _ _) -> first  ((f, g) :) (copies fs rho rs)
 where
  isCopy (Func g _ _ _ rule) = case rule of
    Rule vs' e' -> vs == vs' && ncExpr [(f, g)] e == e'
                   && (mkFuncCall (g, map negate vs), (f, map negate vs))
                      `elem` rho
    _           -> False

--- Remove resultants that are either aliases for or duplicates of each other.
remove :: ([Resultant] -> (NameChange, [Resultant]))
       -> (Renaming, [Resultant]) -> (Renaming, [Resultant])
remove identify (rho, rs) =  (ncRenaming nc rho, ncResultants nc rs')
  where
  (as, rs')        = identify rs
  nc               = map (\(f, g) -> (f, deepLookup g as)) as
  deepLookup x xys = case lookup x xys of
    Nothing -> x
    Just y  -> deepLookup y xys

-- -----------------------------------------------------------------------------
-- Post-Unfolding
-- -----------------------------------------------------------------------------

--- Post-Unfold a list of resultants.
puResultants :: Options -> [QName] -> [Resultant] -> [Resultant]
puResultants opts fs rs = removeRedundantRules fs
                        $ map (puResultant (initEnv opts rs)) rs

--- Remove resultants which are not used in any of the right-hand-sides
--- of other resultants.
removeRedundantRules :: [QName] -> [Resultant] -> [Resultant]
removeRedundantRules fs rs = filter (not . redundant) rs
  where redundant r@((f, _), _) = f `notElem` fs && countFuncCalls f
                                             (map snd (delete r rs)) == 0

--- The post-unfolding environment.
data PUEnv = PUEnv
  { peOptions    :: Options
  , peResultants :: [Resultant]
  }

--- Create the initial post-unfolding environment.
initEnv :: Options -> [Resultant] -> PUEnv
initEnv opts rs = PUEnv opts rs

--- Post-Unfold a resultant.
puResultant :: PUEnv -> Resultant -> Resultant
puResultant env = renameResultant . second (puExpr env)

--- Trace a post-unfolding action.
puTrace :: PUEnv -> Doc -> a -> a
puTrace PUEnv { peOptions = o } doc x = traceDetail o (colorWith o yellow str) x
  where str = pPrint (text "Compression:" <+> doc) ++ "\n"

--- Post-Unfold an expression.
puExpr :: PUEnv -> Expr -> Expr
puExpr env = normalizeFreeExpr
           . simplifyExpr
           . trExpr Var Lit (puComb env) Free Or Case Branch Let Typed

--- Compress higher-order application and simple calls.
puComb :: PUEnv -> CombType -> QName -> [Expr] -> Expr
puComb env ct qn es = case ct of
  FuncCall | qn == prelApply -> puApply es
           | qn == prelPEVAL -> Comb ct qn es
           | otherwise       -> puFuncCall env qn es
  _                          -> Comb ct qn es

--- Apply a part call to another expression.
puApply :: [Expr] -> Expr
puApply exs = case exs of
  [Comb ct f es, e2] | isPartCall ct -> addPartCallArg ct f es e2
  [_, _]                             -> Comb FuncCall prelApply exs
  _                                  -> error "PostUnfold.puApply"

--- Unfolding of a function call.
puFuncCall :: PUEnv -> QName -> [Expr] -> Expr
puFuncCall env f es = case find ((== f) . resultantName) (peResultants env) of
  Just r | isSimple r || isAlias r || isIntermediate env r
        -> unfold env r es
  _     -> Comb FuncCall f es

--- Retrieve the name of a resultant.
resultantName :: Resultant -> QName
resultantName ((f, _), _) = f

--- A simple function does not call any other function.
isSimple :: Resultant -> Bool
isSimple ((_, _), e) = countFuncs [e] == 0

--- An alias function simply calls another function with a possibly changed
--- variable order.
isAlias :: Resultant -> Bool
isAlias ((_, _), e) = case e of
  Comb FuncCall _ es -> all isVar es
  _                  -> False

--- An intermediate function is a function which is only called once
--- and is not recursive.
isIntermediate :: PUEnv -> Resultant -> Bool
isIntermediate env ((f, _), e)
  =  countFuncCalls f [e] == 0
  && countFuncCalls f (map snd (peResultants env)) == 1

--- Unfold a function call by introducing a let binding for arguments.
unfold :: PUEnv -> Resultant -> [Expr] -> Expr
unfold opts r es = puTrace opts doc e''
  where
  r'@((f, vs'), e') = freshResultant (maximumVarIndex es + 1) r
  e''               = mkLet (zip vs' es) e'
  doc =  indent (text "Unfolding call"  $$ ppExp (Comb FuncCall f es))
      $$ indent (text "with definition" $$ ppResultant r')
      $$ indent (text "to expression"   $$ ppExp e'')

--- Count the number of calls to any function
--- (with exception of failed which cannot be reduced).
countFuncs :: [Expr] -> Int
countFuncs = countBy (`notElem` [prelFailed]) . funcsInExps

--- Count the number of calls to a specific function.
countFuncCalls :: QName -> [Expr] -> Int
countFuncCalls f = count f . funcsInExps