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
------------------------------------------------------------------------------
--- Analysis for solution completeness:
--- check whether functions are solution complete, i.e., calls only
--- non-rigid functions
---
--- @author Michael Hanus
--- @version April 2013
------------------------------------------------------------------------------

module Analysis.SolutionCompleteness(solcompAnalysis,showSolComplete)  where

import Analysis.Types
import FlatCurry.Types
import Data.List

------------------------------------------------------------------------------
--- The completeness analysis is a global function dependency analysis.
--- It assigns to a function a flag which is True if this function
--- is operationally complete, i.e., does not call (explicitly or implicitly)
--- a rigid function.

solcompAnalysis :: Analysis Bool
solcompAnalysis = dependencyFuncAnalysis "SolComplete" True scFunc

--- An operation is solution complete if it is defined with flexible
--- rules and depends only on solution complete operations.
scFunc  :: FuncDecl -> [(QName,Bool)] -> Bool
scFunc func calledFuncs =
  isFlexDefined func && all snd calledFuncs

-- (isFlexDefined fundecl):
-- Is a function defined by a flexible rule?
isFlexDefined :: FuncDecl -> Bool
isFlexDefined (Func _ _ _ _ (Rule _ e)) = isFlexExpr e
isFlexDefined (Func f _ _ _ (External _)) =
   f `elem` map pre ["=:=","success","&","&>","return"]

-- Checks whether an expression is flexible, i.e., can only suspend
-- because of calls to other possibly rigid functions.

isFlexExpr :: Expr -> Bool
isFlexExpr (Var _)           = True
isFlexExpr (Lit _)           = True
isFlexExpr (Comb _ f args) =
       f/=(pre "apply") -- apply suspends if arg 1 is unbound
    && f/=(pre "commit")
    && all isFlexExpr args
isFlexExpr (Free _ e)        = isFlexExpr e
isFlexExpr (Let bs e)        = all isFlexExpr (map snd bs) && isFlexExpr e
isFlexExpr (Or e1 e2)        = isFlexExpr e1 && isFlexExpr e2
isFlexExpr (Case ctype e bs) = ctype==Flex &&
                         all isFlexExpr (e : map (\(Branch _ be)->be) bs)
isFlexExpr (Typed e _)       = isFlexExpr e

-- Show solution completeness information as a string.
showSolComplete :: AOutFormat -> Bool -> String
showSolComplete _ True  = "solution complete"
showSolComplete _ False = "maybe suspend"


pre :: String -> QName
pre n = ("Prelude",n)

-- end of SolutionCompleteness