module Camfort.Specification.Stencils.Synthesis where
import Data.Data
import Data.List
import Data.Maybe
import qualified Data.Map as M
import Data.Generics.Uniplate.Operations
import Control.Monad.State.Lazy
import Control.Monad.Reader
import Control.Monad.Writer hiding (Product)
import Camfort.Specification.Stencils.InferenceBackend
import Camfort.Specification.Stencils.Syntax
import Camfort.Specification.Stencils.Model
import Camfort.Analysis.Annotations
import Camfort.Helpers.Vec
import Camfort.Helpers hiding (lineCol, spanLineCol)
import qualified Language.Fortran.AST as F
import qualified Language.Fortran.Analysis as FA
import qualified Language.Fortran.Analysis.Types as FAT
import qualified Language.Fortran.Analysis.Renaming as FAR
import qualified Language.Fortran.Analysis.BBlocks as FAB
import qualified Language.Fortran.Analysis.DataFlow as FAD
import qualified Language.Fortran.Util.Position as FU
import Language.Fortran.Util.Position
import Data.Map hiding (map)
formatSpec ::
Maybe String
-> FAR.NameMap
-> (FU.SrcSpan, Either [([Variable], Specification)] (String,Variable))
-> String
formatSpec prefix nm (span, Right (evalInfo,name)) =
prefix'
++ evalInfo
++ (if name /= "" then " :: " ++ realName name else "") ++ "\n"
where
realName v = v `fromMaybe` (v `M.lookup` nm)
prefix' = case prefix of
Nothing -> show span ++ " "
Just pr -> pr
formatSpec prefix nm (span, Left []) = ""
formatSpec prefix nm (span, Left specs) =
(intercalate "\n" $ map (\s -> prefix' ++ doSpec s) specs)
where
prefix' = case prefix of
Nothing -> show span ++ " "
Just pr -> pr
commaSep = intercalate ", "
doSpec (arrayVar, spec) =
show (fixSpec spec) ++ " :: " ++ commaSep (map realName arrayVar)
realName v = v `fromMaybe` (v `M.lookup` nm)
fixSpec s = s
a = (head $ FA.initAnalysis [unitAnnotation]) { FA.insLabel = Just 0 }
s = SrcSpan (Position 0 0 0) (Position 0 0 0)
offsetToIx :: F.Name -> Int -> F.Index (FA.Analysis A)
offsetToIx v o
| o == absoluteRep
= F.IxSingle a s Nothing (F.ExpValue a s (F.ValInteger "0"))
| o == 0 = F.IxSingle a s Nothing (F.ExpValue a s (F.ValVariable v))
| o > 0 = F.IxSingle a s Nothing (F.ExpBinary a s F.Addition
(F.ExpValue a s (F.ValVariable v))
(F.ExpValue a s (F.ValInteger $ show o)))
| otherwise = F.IxSingle a s Nothing (F.ExpBinary a s F.Subtraction
(F.ExpValue a s (F.ValVariable v))
(F.ExpValue a s (F.ValInteger $ show (abs o))))