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|
{-|
Module : VeriFuzz.Verilog.Mutate
Description : Functions to mutate the Verilog AST.
Copyright : (c) 2018-2019, Yann Herklotz
License : BSD-3
Maintainer : ymherklotz [at] gmail [dot] com
Stability : experimental
Portability : POSIX
Functions to mutate the Verilog AST from "VeriFuzz.Verilog.AST" to generate more
random patterns, such as nesting wires instead of creating new ones.
-}
module VeriFuzz.Verilog.Mutate
( inPort
, findAssign
, idTrans
, replace
, nestId
, nestSource
, nestUpTo
, allVars
, instantiateMod
, instantiateMod_
, instantiateModSpec_
, filterChar
, initMod
, makeIdFrom
, makeTop
, makeTopAssert
, simplify
, removeId
, combineAssigns
, combineAssigns_
, declareMod
)
where
import Control.Lens
import Data.Foldable (fold)
import Data.Maybe (catMaybes, fromMaybe)
import Data.Text (Text)
import qualified Data.Text as T
import VeriFuzz.Circuit.Internal
import VeriFuzz.Internal
import VeriFuzz.Verilog.AST
import VeriFuzz.Verilog.BitVec
import VeriFuzz.Verilog.Internal
-- | Return if the 'Identifier' is in a 'ModDecl'.
inPort :: Identifier -> ModDecl -> Bool
inPort i m = inInput
where
inInput =
any (\a -> a ^. portName == i) $ m ^. modInPorts ++ m ^. modOutPorts
-- | Find the last assignment of a specific wire/reg to an expression, and
-- returns that expression.
findAssign :: Identifier -> [ModItem] -> Maybe Expr
findAssign i items = safe last . catMaybes $ isAssign <$> items
where
isAssign (ModCA (ContAssign val expr)) | val == i = Just expr
| otherwise = Nothing
isAssign _ = Nothing
-- | Transforms an expression by replacing an Identifier with an
-- expression. This is used inside 'transformOf' and 'traverseExpr' to replace
-- the 'Identifier' recursively.
idTrans :: Identifier -> Expr -> Expr -> Expr
idTrans i expr (Id id') | id' == i = expr
| otherwise = Id id'
idTrans _ _ e = e
-- | Replaces the identifier recursively in an expression.
replace :: Identifier -> Expr -> Expr -> Expr
replace = (transform .) . idTrans
-- | Nest expressions for a specific 'Identifier'. If the 'Identifier' is not
-- found, the AST is not changed.
--
-- This could be improved by instead of only using the last assignment to the
-- wire that one finds, to use the assignment to the wire before the current
-- expression. This would require a different approach though.
nestId :: Identifier -> ModDecl -> ModDecl
nestId i m
| not $ inPort i m
= let expr = fromMaybe def . findAssign i $ m ^. modItems
in m & get %~ replace i expr
| otherwise
= m
where
get = modItems . traverse . modContAssign . contAssignExpr
def = Id i
-- | Replaces an identifier by a expression in all the module declaration.
nestSource :: Identifier -> Verilog -> Verilog
nestSource i src = src & getModule %~ nestId i
-- | Nest variables in the format @w[0-9]*@ up to a certain number.
nestUpTo :: Int -> Verilog -> Verilog
nestUpTo i src =
foldl (flip nestSource) src $ Identifier . fromNode <$> [1 .. i]
allVars :: ModDecl -> [Identifier]
allVars m =
(m ^.. modOutPorts . traverse . portName)
<> (m ^.. modInPorts . traverse . portName)
-- $setup
-- >>> import VeriFuzz.Verilog.CodeGen
-- >>> let m = (ModDecl (Identifier "m") [Port Wire False 0 5 (Identifier "y")] [Port Wire False 0 5 "x"] [] [])
-- >>> let main = (ModDecl "main" [] [] [] [])
-- | Add a Module Instantiation using 'ModInst' from the first module passed to
-- it to the body of the second module. It first has to make all the inputs into
-- @reg@.
--
-- >>> render $ instantiateMod m main
-- module main;
-- wire [4:0] y;
-- reg [4:0] x;
-- m m1(y, x);
-- endmodule
-- <BLANKLINE>
instantiateMod :: ModDecl -> ModDecl -> ModDecl
instantiateMod m main = main & modItems %~ ((out ++ regIn ++ [inst]) ++)
where
out = Decl Nothing <$> m ^. modOutPorts <*> pure Nothing
regIn =
Decl Nothing
<$> (m ^. modInPorts & traverse . portType .~ Reg)
<*> pure Nothing
inst = ModInst (m ^. modId)
(m ^. modId <> (Identifier . showT $ count + 1))
conns
count =
length
. filter (== m ^. modId)
$ main
^.. modItems
. traverse
. modInstId
conns = ModConn . Id <$> allVars m
-- | Instantiate without adding wire declarations. It also does not count the
-- current instantiations of the same module.
--
-- >>> GenVerilog $ instantiateMod_ m
-- m m(y, x);
-- <BLANKLINE>
instantiateMod_ :: ModDecl -> ModItem
instantiateMod_ m = ModInst (m ^. modId) (m ^. modId) conns
where
conns =
ModConn
. Id
<$> (m ^.. modOutPorts . traverse . portName)
++ (m ^.. modInPorts . traverse . portName)
-- | Instantiate without adding wire declarations. It also does not count the
-- current instantiations of the same module.
--
-- >>> GenVerilog $ instantiateModSpec_ "_" m
-- m m(.y(y), .x(x));
-- <BLANKLINE>
instantiateModSpec_ :: Text -> ModDecl -> ModItem
instantiateModSpec_ outChar m = ModInst (m ^. modId) (m ^. modId) conns
where
conns = zipWith ModConnNamed ids (Id <$> instIds)
ids = filterChar outChar (name modOutPorts) <> name modInPorts
instIds = name modOutPorts <> name modInPorts
name v = m ^.. v . traverse . portName
filterChar :: Text -> [Identifier] -> [Identifier]
filterChar t ids =
ids & traverse . _Wrapped %~ (\x -> fromMaybe x . safe head $ T.splitOn t x)
-- | Initialise all the inputs and outputs to a module.
--
-- >>> GenVerilog $ initMod m
-- module m(y, x);
-- output wire [4:0] y;
-- input wire [4:0] x;
-- endmodule
-- <BLANKLINE>
initMod :: ModDecl -> ModDecl
initMod m = m & modItems %~ ((out ++ inp) ++)
where
out = Decl (Just PortOut) <$> (m ^. modOutPorts) <*> pure Nothing
inp = Decl (Just PortIn) <$> (m ^. modInPorts) <*> pure Nothing
-- | Make an 'Identifier' from and existing Identifier and an object with a
-- 'Show' instance to make it unique.
makeIdFrom :: (Show a) => a -> Identifier -> Identifier
makeIdFrom a i = (i <>) . Identifier . ("_" <>) $ showT a
-- | Make top level module for equivalence verification. Also takes in how many
-- modules to instantiate.
makeTop :: Int -> ModDecl -> ModDecl
makeTop i m = ModDecl (m ^. modId) ys (m ^. modInPorts) modIt []
where
ys = yPort . flip makeIdFrom "y" <$> [1 .. i]
modIt = instantiateModSpec_ "_" . modN <$> [1 .. i]
modN n =
m & modId %~ makeIdFrom n & modOutPorts .~ [yPort (makeIdFrom n "y")]
-- | Make a top module with an assert that requires @y_1@ to always be equal to
-- @y_2@, which can then be proven using a formal verification tool.
makeTopAssert :: ModDecl -> ModDecl
makeTopAssert = (modItems %~ (++ [assert])) . makeTop 2
where
assert = Always . EventCtrl e . Just $ SeqBlock
[TaskEnable $ Task "assert" [BinOp (Id "y_1") BinEq (Id "y_2")]]
e = EPosEdge "clk"
-- | Provide declarations for all the ports that are passed to it. If they are
-- registers, it should assign them to 0.
declareMod :: [Port] -> ModDecl -> ModDecl
declareMod ports = initMod . (modItems %~ (decl ++))
where
decl = declf <$> ports
declf p@(Port Reg _ _ _) = Decl Nothing p (Just 0)
declf p = Decl Nothing p Nothing
-- | Simplify an 'Expr' by using constants to remove 'BinaryOperator' and
-- simplify expressions. To make this work effectively, it should be run until
-- no more changes were made to the expression.
--
-- >>> GenVerilog . simplify $ (Id "x") + 0
-- x
--
-- >>> GenVerilog . simplify $ (Id "y") + (Id "x")
-- (y + x)
simplify :: Expr -> Expr
simplify (BinOp (Number (BitVec _ 1)) BinAnd e) = e
simplify (BinOp e BinAnd (Number (BitVec _ 1))) = e
simplify (BinOp (Number (BitVec _ 0)) BinAnd _) = Number 0
simplify (BinOp _ BinAnd (Number (BitVec _ 0))) = Number 0
simplify (BinOp e BinPlus (Number (BitVec _ 0))) = e
simplify (BinOp (Number (BitVec _ 0)) BinPlus e) = e
simplify (BinOp e BinMinus (Number (BitVec _ 0))) = e
simplify (BinOp (Number (BitVec _ 0)) BinMinus e) = e
simplify (BinOp e BinTimes (Number (BitVec _ 1))) = e
simplify (BinOp (Number (BitVec _ 1)) BinTimes e) = e
simplify (BinOp _ BinTimes (Number (BitVec _ 0))) = Number 0
simplify (BinOp (Number (BitVec _ 0)) BinTimes _) = Number 0
simplify (BinOp e BinOr (Number (BitVec _ 0))) = e
simplify (BinOp (Number (BitVec _ 0)) BinOr e) = e
simplify (BinOp e BinLSL (Number (BitVec _ 0))) = e
simplify (BinOp (Number (BitVec _ 0)) BinLSL e) = e
simplify (BinOp e BinLSR (Number (BitVec _ 0))) = e
simplify (BinOp (Number (BitVec _ 0)) BinLSR e) = e
simplify (BinOp e BinASL (Number (BitVec _ 0))) = e
simplify (BinOp (Number (BitVec _ 0)) BinASL e) = e
simplify (BinOp e BinASR (Number (BitVec _ 0))) = e
simplify (BinOp (Number (BitVec _ 0)) BinASR e) = e
simplify (UnOp UnPlus e) = e
simplify e = e
-- | Remove all 'Identifier' that do not appeare in the input list from an
-- 'Expr'. The identifier will be replaced by @1'b0@, which can then later be
-- simplified further.
--
-- >>> GenVerilog . removeId ["x"] $ Id "x" + Id "y"
-- (x + (1'h0))
removeId :: [Identifier] -> Expr -> Expr
removeId i = transform trans
where
trans (Id ident) | ident `notElem` i = Number 0
| otherwise = Id ident
trans e = e
combineAssigns :: Port -> [ModItem] -> [ModItem]
combineAssigns p a =
a <> [ModCA . ContAssign (p ^. portName) . fold $ Id <$> assigns]
where assigns = a ^.. traverse . modContAssign . contAssignNetLVal
combineAssigns_ :: Port -> [Port] -> ModItem
combineAssigns_ p ps =
ModCA
. ContAssign (p ^. portName)
. fold
$ Id
<$> ps
^.. traverse
. portName
|