macaw/macaw-ppc/tests/PPC64Tests.hs
Tristan Ravitch 4c7a69b11d Update macaw-ppc to account for recent changes in macaw-base
The main changes are:

- `postCallAbsState` was removed from the architecture info
- `mkInitialRegsForBlock` was renamed to `initialBlockRegs` and takes slightly
  different parameters
- There is a new type family and some new functions in the architecture info
  relating to post-block/terminator abstract state construction

PowerPC doesn't need any extra information to compute post-block abstract
states, so we use () as the ArchBlockPrecond type.
2019-11-12 17:27:14 -08:00

156 lines
6.6 KiB
Haskell

{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE DataKinds #-}
{-# LANGUAGE DeriveDataTypeable #-}
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE GeneralizedNewtypeDeriving #-}
{-# LANGUAGE RankNTypes #-}
{-# LANGUAGE TypeApplications #-}
module PPC64Tests (
ppcAsmTests
) where
import Control.Lens ( (^.) )
import Control.Monad ( unless )
import qualified Data.Foldable as F
import qualified Data.Map as M
import Data.Maybe ( fromJust )
import qualified Data.Set as S
import Data.Word ( Word64 )
import System.FilePath ( dropExtension, replaceExtension )
import qualified Test.Tasty as T
import qualified Test.Tasty.HUnit as T
import Text.Printf ( PrintfArg, printf )
import Text.Read ( readMaybe )
import qualified Data.ElfEdit as E
import qualified Data.Parameterized.Some as PU
import qualified Data.Macaw.BinaryLoader as MBL
import qualified Data.Macaw.BinaryLoader.PPC ()
import qualified Data.Macaw.Memory as MM
import qualified Data.Macaw.Memory.ElfLoader as MM
import qualified Data.Macaw.Discovery as MD
import qualified Data.Macaw.PPC as RO
import qualified SemMC.Architecture.PPC64 as PPC64
import Shared
ppcAsmTests :: [FilePath] -> T.TestTree
ppcAsmTests = T.testGroup "PPC" . map mkTest
newtype Hex a = Hex a
deriving (Eq, Ord, Num, PrintfArg)
instance (Num a, Show a, PrintfArg a) => Show (Hex a) where
show (Hex a) = printf "0x%x" a
instance (Read a) => Read (Hex a) where
readsPrec i s = [ (Hex a, s') | (a, s') <- readsPrec i s ]
-- | The type of expected results for test cases
data ExpectedResult =
R { funcs :: [(Hex Word64, [(Hex Word64, Word64)])]
-- ^ The first element of the pair is the address of entry point
-- of the function. The list is a list of the addresses of the
-- basic blocks in the function (including the first block).
, ignoreBlocks :: [Hex Word64]
-- ^ This is a list of discovered blocks to ignore. This is
-- basically just the address of the instruction after the exit
-- syscall, as macaw doesn't know that exit never returns and
-- discovers a false block after exit.
}
deriving (Read, Show, Eq)
-- | Read in a test case from disk and output a test tree.
mkTest :: FilePath -> T.TestTree
mkTest fp = T.testCase fp $ withELF exeFilename (testDiscovery fp)
where
asmFilename = dropExtension fp
exeFilename = replaceExtension asmFilename "exe"
allDiscoveredBlocks :: MD.DiscoveryState arch -> [PU.Some (MD.ParsedBlock arch)]
allDiscoveredBlocks di =
[ PU.Some pbr
| PU.Some dfi <- M.elems (di ^. MD.funInfo)
, pbr <- M.elems (dfi ^. MD.parsedBlocks)
]
blockTerminator :: MD.ParsedBlock arch ids -> MD.ParsedTermStmt arch ids
blockTerminator = MD.pblockTermStmt
isClassifyFailure :: MD.ParsedTermStmt arch ids -> Bool
isClassifyFailure ts =
case ts of
MD.ClassifyFailure {} -> True
_ -> False
isTranslateError :: MD.ParsedTermStmt arch ids -> Bool
isTranslateError ts =
case ts of
MD.ParsedTranslateError {} -> True
_ -> False
-- | Run a test over a given expected result filename and the ELF file
-- associated with it
testDiscovery :: FilePath -> E.Elf 64 -> IO ()
testDiscovery expectedFilename elf = do
let loadCfg = MM.defaultLoadOptions
{ MM.loadOffset = Just 0
}
loadedBinary :: MBL.LoadedBinary PPC64.PPC (E.Elf 64)
<- MBL.loadBinary loadCfg elf
entries <- MBL.entryPoints loadedBinary
let cfg = RO.ppc64_linux_info loadedBinary
let mem = MBL.memoryImage loadedBinary
let di = MD.cfgFromAddrs cfg mem M.empty (F.toList entries) []
expectedString <- readFile expectedFilename
case readMaybe expectedString of
-- Above: Read in the ExpectedResult from the contents of the file
Nothing -> T.assertFailure ("Invalid expected result: " ++ show expectedString)
Just er -> do
let expectedEntries = M.fromList [ (entry, S.fromList starts) | (entry, starts) <- funcs er ]
-- expectedEntries maps function entry points to the set of block starts
-- within the function.
ignoredBlocks = S.fromList (ignoreBlocks er)
allFoundBlockAddrs :: S.Set Word64
allFoundBlockAddrs =
S.fromList [ fromIntegral (fromJust (MM.asAbsoluteAddr (MM.segoffAddr (MD.pblockAddr pbr))))
| PU.Some pbr <- allDiscoveredBlocks di
]
-- Test that all discovered blocks were expected (and verify their sizes)
F.forM_ (M.elems (di ^. MD.funInfo)) $ \(PU.Some dfi) -> do
F.forM_ (allDiscoveredBlocks di) $ \(PU.Some pb) -> do
let addr = absoluteFromSegOff (MD.pblockAddr pb)
unless (S.member addr ignoredBlocks) $ do
let term = blockTerminator pb
T.assertBool ("Unclassified block at " ++ show (MD.pblockAddr pb)) (not (isClassifyFailure term))
T.assertBool ("Translate error at " ++ show (MD.pblockAddr pb) ++ "\n" ++ show term) (not (isTranslateError term))
let actualEntry = absoluteFromSegOff (MD.discoveredFunAddr dfi)
actualBlockStarts = S.fromList [ (baddr, bsize)
| pbr <- M.elems (dfi ^. MD.parsedBlocks)
-- , trace ("Parsed Block: " ++ show pbr) True
, let baddr = fromIntegral (fromJust (MM.asAbsoluteAddr (MM.segoffAddr (MD.pblockAddr pbr))))
, let bsize = fromIntegral (MD.blockSize pbr)
]
case (S.member actualEntry ignoredBlocks, M.lookup actualEntry expectedEntries) of
(True, _) -> return ()
(_, Nothing) -> T.assertFailure (printf "Unexpected block start: 0x%x" actualEntry)
(_, Just expectedBlockStarts) ->
T.assertEqual (printf "Block starts for 0x%x" actualEntry) expectedBlockStarts (actualBlockStarts `removeIgnored` ignoredBlocks)
-- Test that all expected blocks were discovered
F.forM_ (funcs er) $ \(_funcAddr, blockAddrs) ->
F.forM_ blockAddrs $ \(blockAddr@(Hex addr), _) -> do
T.assertBool ("Missing block address: " ++ show blockAddr) (S.member addr allFoundBlockAddrs)
absoluteFromSegOff :: MM.MemSegmentOff 64 -> Hex Word64
absoluteFromSegOff = fromIntegral . fromJust . MM.asAbsoluteAddr . MM.segoffAddr
removeIgnored :: (Ord b, Ord a) => S.Set (a, b) -> S.Set a -> S.Set (a, b)
removeIgnored actualBlockStarts ignoredBlocks =
F.foldr (\v@(addr, _) acc -> if S.member addr ignoredBlocks
then S.delete v acc
else acc) actualBlockStarts actualBlockStarts