clash-lib-1.6.0: src/Clash/Netlist/BlackBox.hs
{-# LANGUAGE NamedFieldPuns #-}
{-|
Copyright : (C) 2012-2016, University of Twente,
2016-2017, Myrtle Software Ltd,
2017 , Google Inc.,
2021 , QBayLogic B.V.
License : BSD2 (see the file LICENSE)
Maintainer : QBayLogic B.V. <devops@qbaylogic.com>
Functions to create BlackBox Contexts and fill in BlackBox templates
-}
{-# LANGUAGE CPP #-}
{-# LANGUAGE LambdaCase #-}
{-# LANGUAGE MagicHash #-}
{-# LANGUAGE OverloadedStrings #-}
{-# LANGUAGE PatternSynonyms #-}
{-# LANGUAGE QuasiQuotes #-}
{-# LANGUAGE RecordWildCards #-}
{-# LANGUAGE TemplateHaskell #-}
module Clash.Netlist.BlackBox where
import Control.Exception (throw)
import Control.Lens ((%=))
import qualified Control.Lens as Lens
import Control.Monad (when, replicateM, zipWithM)
import Control.Monad.Extra (concatMapM)
import Control.Monad.IO.Class (liftIO)
import Data.Bifunctor (first, second)
import Data.Char (ord)
import Data.Either (lefts, partitionEithers)
import qualified Data.HashMap.Lazy as HashMap
import qualified Data.IntMap as IntMap
import Data.List (elemIndex, partition)
import Data.List.Extra (countEq, mapAccumLM)
import Data.Maybe (listToMaybe, fromJust, fromMaybe)
import Data.Monoid (Ap(getAp))
import qualified Data.Set as Set
import Data.Text.Lazy (fromStrict)
import qualified Data.Text.Lazy as Text
import Data.Text (unpack)
import qualified Data.Text as TextS
import Data.Text.Extra
import GHC.Stack
(HasCallStack, callStack, prettyCallStack)
import qualified System.Console.ANSI as ANSI
import System.Console.ANSI
( hSetSGR, SGR(SetConsoleIntensity, SetColor), Color(Magenta, Red)
, ConsoleIntensity(BoldIntensity), ConsoleLayer(Foreground), ColorIntensity(Vivid))
import System.IO
(hPutStrLn, stderr, hFlush, hIsTerminalDevice)
#if MIN_VERSION_ghc(9,0,0)
import GHC.Utils.Misc (OverridingBool(..))
#else
import Util (OverridingBool(..))
#endif
import Clash.Annotations.Primitive
( PrimitiveGuard(HasBlackBox, DontTranslate)
, PrimitiveWarning(WarnNonSynthesizable, WarnAlways)
, extractPrim)
import Clash.Core.DataCon as D (dcTag)
import Clash.Core.FreeVars (freeIds)
import Clash.Core.HasType
import Clash.Core.Literal as L (Literal (..))
import Clash.Core.Name
(Name (..), mkUnsafeSystemName)
import qualified Clash.Netlist.Id as Id
import Clash.Core.Pretty (showPpr)
import Clash.Core.Subst (extendIdSubst, mkSubst, substTm)
import Clash.Core.Term as C
(IsMultiPrim (..), PrimInfo (..), Term (..), WorkInfo (..), collectArgs,
collectArgsTicks, collectBndrs, mkApps, PrimUnfolding(..))
import Clash.Core.TermInfo
import Clash.Core.Type as C
(Type (..), ConstTy (..), TypeView (..), mkFunTy, splitFunTys, tyView)
import Clash.Core.TyCon as C (TyConMap, tyConDataCons)
import Clash.Core.Util
(inverseTopSortLetBindings, splitShouldSplit)
import Clash.Core.Var as V
(Id, Var (..), mkLocalId, modifyVarName)
import Clash.Core.VarEnv
(extendInScopeSet, mkInScopeSet, lookupVarEnv, uniqAway, unitVarSet)
import {-# SOURCE #-} Clash.Netlist
(genComponent, mkDcApplication, mkDeclarations, mkExpr, mkNetDecl,
mkProjection, mkSelection, mkFunApp, mkDeclarations')
import qualified Clash.Backend as Backend
import Clash.Debug (debugIsOn)
import Clash.Driver.Types
(ClashOpts(opt_primWarn, opt_color, opt_werror))
import Clash.Netlist.BlackBox.Types as B
import Clash.Netlist.BlackBox.Util as B
import Clash.Netlist.Types as N
import Clash.Netlist.Util as N
import Clash.Normalize.Primitives (removedArg)
import Clash.Primitives.Types as P
import qualified Clash.Primitives.Util as P
import Clash.Signal.Internal (ActiveEdge (..))
import Clash.Unique (lookupUniqMap')
import Clash.Util
import qualified Clash.Util.Interpolate as I
-- | Emits (colorized) warning to stderr
warn
:: ClashOpts
-> String
-> IO ()
warn opts msg = do
-- TODO: Put in appropriate module
useColor <-
case opt_color opts of
Always -> return True
Never -> return False
Auto -> hIsTerminalDevice stderr
hSetSGR stderr [SetConsoleIntensity BoldIntensity]
case opt_werror opts of
True -> do
when useColor $ hSetSGR stderr [SetColor Foreground Vivid Red]
throw (ClashException noSrcSpan msg Nothing)
False -> do
when useColor $ hSetSGR stderr [SetColor Foreground Vivid Magenta]
hPutStrLn stderr $ "[WARNING] " ++ msg
hSetSGR stderr [ANSI.Reset]
hFlush stderr
-- | Generate the context for a BlackBox instantiation.
mkBlackBoxContext
:: HasCallStack
=> TextS.Text
-- ^ Blackbox function name
-> [Id]
-- ^ Identifiers binding the primitive/blackbox application
-> [Either Term Type]
-- ^ Arguments of the primitive/blackbox application
-> NetlistMonad (BlackBoxContext,[Declaration])
mkBlackBoxContext bbName resIds args@(lefts -> termArgs) = do
-- Make context inputs
let
resNms = map id2identifier resIds
resNm = fromMaybe (error "mkBlackBoxContext: head") (listToMaybe resNms)
resTys <- mapM (unsafeCoreTypeToHWTypeM' $(curLoc) . coreTypeOf) resIds
(imps,impDecls) <- unzip <$> zipWithM (mkArgument bbName resNm) [0..] termArgs
(funs,funDecls) <-
mapAccumLM
(addFunction (map coreTypeOf resIds))
IntMap.empty
(zip termArgs [0..])
-- Make context result
let ress = map (flip Identifier Nothing) resNms
lvl <- Lens.use curBBlvl
(nm,_) <- Lens.use curCompNm
-- Set "context name" to value set by `Clash.Magic.setName`, default to the
-- name of the closest binder
ctxName1 <- fromMaybe (map Id.toText resNms) . fmap pure <$> Lens.view setName
-- Update "context name" with prefixes and suffixes set by
-- `Clash.Magic.prefixName` and `Clash.Magic.suffixName`
ctxName2 <- mapM affixName ctxName1
return ( Context bbName (zip ress resTys) imps funs [] lvl nm (listToMaybe ctxName2)
, concat impDecls ++ concat funDecls
)
where
addFunction resTys im (arg,i) = do
tcm <- Lens.use tcCache
if isFun tcm arg then do
-- Only try to calculate function plurality when primitive actually
-- exists. Here to prevent crashes on __INTERNAL__ primitives.
prim <- HashMap.lookup bbName <$> Lens.use primitives
funcPlurality <-
case extractPrim <$> prim of
Just (Just p) ->
P.getFunctionPlurality p args resTys i
_ ->
pure 1
curBBlvl Lens.+= 1
(fs,ds) <- case resIds of
(resId:_) -> unzip <$> replicateM funcPlurality (mkFunInput resId arg)
_ -> error "internal error: insufficient resIds"
curBBlvl Lens.-= 1
let im' = IntMap.insert i fs im
return (im', concat ds)
else
return (im, [])
prepareBlackBox
:: TextS.Text
-> BlackBox
-> BlackBoxContext
-> NetlistMonad (BlackBox,[Declaration])
prepareBlackBox _pNm templ bbCtx =
case verifyBlackBoxContext bbCtx templ of
Nothing -> do
(t2,decls) <-
onBlackBox
(fmap (first BBTemplate) . setSym bbCtx)
(\bbName bbHash bbFunc -> pure (BBFunction bbName bbHash bbFunc, []))
templ
return (t2,decls)
Just err0 -> do
(_,sp) <- Lens.use curCompNm
let err1 = concat [ "Couldn't instantiate blackbox for "
, Data.Text.unpack (bbName bbCtx), ". Verification "
, "procedure reported:\n\n" ++ err0 ]
throw (ClashException sp ($(curLoc) ++ err1) Nothing)
-- | Determine if a term represents a literal
isLiteral :: Term -> Bool
isLiteral e = case collectArgs e of
(Data _, args) -> all (either isLiteral (const True)) args
(Prim _, args) -> all (either isLiteral (const True)) args
(C.Literal _,_) -> True
_ -> False
mkArgument
:: TextS.Text
-- ^ Blackbox function name
-> Identifier
-- ^ LHS of the original let-binder. Is used as a name hint to generate new
-- names in case the argument is a declaration.
-> Int
-- ^ Argument n (zero-indexed). Used for error message.
-> Term
-> NetlistMonad ( (Expr,HWType,Bool)
, [Declaration]
)
mkArgument bbName bndr nArg e = do
tcm <- Lens.use tcCache
let ty = inferCoreTypeOf tcm e
iw <- Lens.use intWidth
hwTyM <- fmap stripFiltered <$> N.termHWTypeM e
let eTyMsg = "(" ++ showPpr e ++ " :: " ++ showPpr ty ++ ")"
((e',t,l),d) <- case hwTyM of
Nothing
| (Prim p,_) <- collectArgs e
, primName p == showt 'removedArg
-> return ((Identifier (Id.unsafeMake (showt 'removedArg)) Nothing, Void Nothing, False), [])
| otherwise
-> return ((error ($(curLoc) ++ "Forced to evaluate untranslatable type: " ++ eTyMsg), Void Nothing, False), [])
Just hwTy -> case collectArgsTicks e of
(C.Var v,[],_) ->
return ((Identifier (id2identifier v) Nothing,hwTy,False),[])
(C.Literal (IntegerLiteral i),[],_) ->
return ((N.Literal (Just (Signed iw,iw)) (N.NumLit i),hwTy,True),[])
(C.Literal (IntLiteral i), [],_) ->
return ((N.Literal (Just (Signed iw,iw)) (N.NumLit i),hwTy,True),[])
(C.Literal (WordLiteral w), [],_) ->
return ((N.Literal (Just (Unsigned iw,iw)) (N.NumLit w),hwTy,True),[])
(C.Literal (CharLiteral c), [],_) ->
return ((N.Literal (Just (Unsigned 21,21)) (N.NumLit . toInteger $ ord c),hwTy,True),[])
(C.Literal (StringLiteral s),[],_) ->
return ((N.Literal Nothing (N.StringLit s),hwTy,True),[])
(C.Literal (Int64Literal i), [],_) ->
return ((N.Literal (Just (Signed 64,64)) (N.NumLit i),hwTy,True),[])
(C.Literal (Word64Literal i), [],_) ->
return ((N.Literal (Just (Unsigned 64,64)) (N.NumLit i),hwTy,True),[])
(C.Literal (NaturalLiteral n), [],_) ->
return ((N.Literal (Just (Unsigned iw,iw)) (N.NumLit n),hwTy,True),[])
(Prim pinfo,args,ticks) -> withTicks ticks $ \tickDecls -> do
(e',d) <- mkPrimitive True False (NetlistId bndr ty) pinfo args tickDecls
case e' of
(Identifier _ _) -> return ((e',hwTy,False), d)
_ -> return ((e',hwTy,isLiteral e), d)
(Data dc, args,_) -> do
(exprN,dcDecls) <- mkDcApplication [hwTy] (NetlistId bndr ty) dc (lefts args)
return ((exprN,hwTy,isLiteral e),dcDecls)
(Case scrut ty' [alt],[],_) -> do
(projection,decls) <- mkProjection False (NetlistId bndr ty) scrut ty' alt
return ((projection,hwTy,False),decls)
(Let _bnds _term, [], _ticks) -> do
(exprN, letDecls) <- mkExpr False Concurrent (NetlistId bndr ty) e
return ((exprN,hwTy,False),letDecls)
_ -> do
let errMsg = [I.i|
Forced to evaluate unexpected function argument:
#{eTyMsg}
in 'mkArgument' for argument #{nArg} of blackbox #{show bbName}.
|]
return ((Identifier (error ($(curLoc) ++ errMsg)) Nothing, hwTy, False), [])
return ((e',t,l),d)
-- | Extract a compiled primitive from a guarded primitive. Emit a warning if
-- the guard wants to, or fail entirely.
extractPrimWarnOrFail
:: HasCallStack
=> TextS.Text
-- ^ Name of primitive
-> NetlistMonad CompiledPrimitive
extractPrimWarnOrFail nm = do
prim <- HashMap.lookup nm <$> Lens.use primitives
case prim of
Just (HasBlackBox warnings compiledPrim) ->
-- See if we need to warn the user
if null warnings then return compiledPrim else go warnings compiledPrim
Just DontTranslate -> do
-- We need to error because we encountered a primitive the user
-- explicitly requested not to translate
(_,sp) <- Lens.use curCompNm
let msg = $(curLoc) ++ "Clash was forced to translate '" ++ unpack nm
++ "', but this value was marked with DontTranslate. Did you forget"
++ " to include a blackbox for one of the constructs using this?"
++ (if debugIsOn then "\n\n" ++ prettyCallStack callStack ++ "\n\n" else [])
throw (ClashException sp msg Nothing)
Nothing -> do
-- Blackbox requested, but no blackbox found at all!
(_,sp) <- Lens.use curCompNm
let msg = $(curLoc) ++ "No blackbox found for: " ++ unpack nm
++ ". Did you forget to include directories containing "
++ "primitives? You can use '-i/my/prim/dir' to achieve this."
++ (if debugIsOn then "\n\n" ++ prettyCallStack callStack ++ "\n\n" else [])
throw (ClashException sp msg Nothing)
where
go
:: [PrimitiveWarning]
-> CompiledPrimitive
-> NetlistMonad CompiledPrimitive
go ((WarnAlways warning):ws) cp = do
primWarn <- opt_primWarn <$> Lens.use clashOpts
seen <- Set.member nm <$> Lens.use seenPrimitives
opts <- Lens.use clashOpts
when (primWarn && not seen)
$ liftIO
$ warn opts
$ "Dubious primitive instantiation for "
++ unpack nm
++ ": "
++ warning
++ " (disable with -fclash-no-prim-warn)"
go ws cp
go ((WarnNonSynthesizable warning):ws) cp = do
isTB <- Lens.use isTestBench
if isTB then go ws cp else go ((WarnAlways warning):ws) cp
go [] cp = do
seenPrimitives %= Set.insert nm
return cp
mkPrimitive
:: Bool
-- ^ Put BlackBox expression in parenthesis
-> Bool
-- ^ Treat BlackBox expression as declaration
-> NetlistId
-- ^ Id to assign the result to
-> PrimInfo
-- ^ Primitive info
-> [Either Term Type]
-- ^ Arguments
-> [Declaration]
-- ^ Tick declarations
-> NetlistMonad (Expr,[Declaration])
mkPrimitive bbEParen bbEasD dst pInfo args tickDecls =
go =<< extractPrimWarnOrFail (primName pInfo)
where
tys = netlistTypes dst
ty = fromMaybe (error "mkPrimitive") (listToMaybe tys)
go
:: CompiledPrimitive
-> NetlistMonad (Expr, [Declaration])
go =
\case
P.BlackBoxHaskell bbName wf _usedArgs multiResult funcName (_fHash, func) -> do
bbFunRes <- func bbEasD (primName pInfo) args tys
case bbFunRes of
Left err -> do
-- Blackbox template function returned an error:
let err' = unwords [ $(curLoc) ++ "Could not create blackbox"
, "template using", show funcName, "for"
, show bbName ++ ".", "Function reported: \n\n"
, err ]
(_,sp) <- Lens.use curCompNm
throw (ClashException sp err' Nothing)
Right (BlackBoxMeta {..}, bbTemplate) ->
-- Blackbox template generation successful. Rerun 'go', but this time
-- around with a 'normal' @BlackBox@
go (P.BlackBox
bbName wf bbRenderVoid multiResult bbKind () bbOutputReg
bbLibrary bbImports bbFunctionPlurality bbIncludes
bbResultNames bbResultInits bbTemplate)
-- See 'setupMultiResultPrim' in "Clash.Normalize.Transformations":
P.BlackBox {name="c$multiPrimSelect"} ->
pure (Noop, [])
p@P.BlackBox {multiResult=True, name, template} -> do
-- Multi result primitives assign their results to signals
-- provided as arguments. Hence, we ignore any declarations
-- from 'resBndr1'.
tcm <- Lens.use tcCache
let (args1, resArgs) = splitMultiPrimArgs (multiPrimInfo' tcm pInfo) args
(bbCtx, ctxDcls) <- mkBlackBoxContext (primName pInfo) resArgs args1
(templ, templDecl) <- prepareBlackBox name template bbCtx
let bbDecl = N.BlackBoxD name (libraries p) (imports p) (includes p) templ bbCtx
return (Noop, ctxDcls ++ templDecl ++ tickDecls ++ [bbDecl])
p@P.BlackBox {template, name=pNm, kind} ->
case kind of
TDecl -> do
resM <- resBndr1 True dst
case resM of
Just (dst',dstNm,dstDecl) -> do
(bbCtx,ctxDcls) <- mkBlackBoxContext (primName pInfo) [dst'] args
(templ,templDecl) <- prepareBlackBox pNm template bbCtx
let bbDecl = N.BlackBoxD pNm (libraries p) (imports p)
(includes p) templ bbCtx
return (Identifier dstNm Nothing,dstDecl ++ ctxDcls ++ templDecl ++ tickDecls ++ [bbDecl])
-- Render declarations as a Noop when requested
Nothing | RenderVoid <- renderVoid p -> do
-- TODO: We should probably 'mkBlackBoxContext' to accept empty lists
let dst1 = mkLocalId ty (mkUnsafeSystemName "__VOID_TDECL_NOOP__" 0)
(bbCtx,ctxDcls) <- mkBlackBoxContext (primName pInfo) [dst1] args
(templ,templDecl) <- prepareBlackBox pNm template bbCtx
let bbDecl = N.BlackBoxD pNm (libraries p) (imports p)
(includes p) templ bbCtx
return (Noop, ctxDcls ++ templDecl ++ tickDecls ++ [bbDecl])
-- Otherwise don't render them
Nothing -> return (Noop,[])
TExpr -> do
if bbEasD
then do
resM <- resBndr1 True dst
case resM of
Just (dst',dstNm,dstDecl) -> do
(bbCtx,ctxDcls) <- mkBlackBoxContext (primName pInfo) [dst'] args
(bbTempl,templDecl) <- prepareBlackBox pNm template bbCtx
let tmpAssgn = Assignment dstNm
(BlackBoxE pNm (libraries p) (imports p)
(includes p) bbTempl bbCtx
bbEParen)
return (Identifier dstNm Nothing, dstDecl ++ ctxDcls ++ templDecl ++ [tmpAssgn])
-- Render expression as a Noop when requested
Nothing | RenderVoid <- renderVoid p -> do
-- TODO: We should probably 'mkBlackBoxContext' to accept empty lists
let dst1 = mkLocalId ty (mkUnsafeSystemName "__VOID_TEXPRD_NOOP__" 0)
(bbCtx,ctxDcls) <- mkBlackBoxContext (primName pInfo) [dst1] args
(templ,templDecl) <- prepareBlackBox pNm template bbCtx
let bbDecl = N.BlackBoxD pNm (libraries p) (imports p)
(includes p) templ bbCtx
return (Noop, ctxDcls ++ templDecl ++ tickDecls ++ [bbDecl])
-- Otherwise don't render them
Nothing -> return (Identifier (Id.unsafeMake "__VOID_TEXPRD__") Nothing,[])
else do
resM <- resBndr1 False dst
case resM of
Just (dst',_,_) -> do
(bbCtx,ctxDcls) <- mkBlackBoxContext (primName pInfo) [dst'] args
(bbTempl,templDecl0) <- prepareBlackBox pNm template bbCtx
let templDecl1 = case primName pInfo of
"Clash.Sized.Internal.BitVector.fromInteger#"
| [N.Literal _ (NumLit _), N.Literal _ _, N.Literal _ _] <- extractLiterals bbCtx -> []
"Clash.Sized.Internal.BitVector.fromInteger##"
| [N.Literal _ _, N.Literal _ _] <- extractLiterals bbCtx -> []
"Clash.Sized.Internal.Index.fromInteger#"
| [N.Literal _ (NumLit _), N.Literal _ _] <- extractLiterals bbCtx -> []
"Clash.Sized.Internal.Signed.fromInteger#"
| [N.Literal _ (NumLit _), N.Literal _ _] <- extractLiterals bbCtx -> []
"Clash.Sized.Internal.Unsigned.fromInteger#"
| [N.Literal _ (NumLit _), N.Literal _ _] <- extractLiterals bbCtx -> []
_ -> templDecl0
return (BlackBoxE pNm (libraries p) (imports p) (includes p) bbTempl bbCtx bbEParen,ctxDcls ++ templDecl1)
-- Render expression as a Noop when requested
Nothing | RenderVoid <- renderVoid p -> do
-- TODO: We should probably 'mkBlackBoxContext' to accept empty lists
let dst1 = mkLocalId ty (mkUnsafeSystemName "__VOID_TEXPRE_NOOP__" 0)
(bbCtx,ctxDcls) <- mkBlackBoxContext (primName pInfo) [dst1] args
(templ,templDecl) <- prepareBlackBox pNm template bbCtx
let bbDecl = N.BlackBoxD pNm (libraries p) (imports p)
(includes p) templ bbCtx
return (Noop, ctxDcls ++ templDecl ++ tickDecls ++ [bbDecl])
-- Otherwise don't render them
Nothing -> return (Identifier (Id.unsafeMake "__VOID__") Nothing,[])
P.Primitive pNm _ _
| pNm == "GHC.Prim.tagToEnum#" -> do
hwTy <- N.unsafeCoreTypeToHWTypeM' $(curLoc) ty
case args of
[Right (ConstTy (TyCon tcN)), Left (C.Literal (IntLiteral i))] -> do
tcm <- Lens.use tcCache
let dcs = tyConDataCons (tcm `lookupUniqMap'` tcN)
dc = dcs !! fromInteger i
(exprN,dcDecls) <- mkDcApplication [hwTy] dst dc []
return (exprN,dcDecls)
[Right _, Left scrut] -> do
tcm <- Lens.use tcCache
let scrutTy = inferCoreTypeOf tcm scrut
(scrutExpr,scrutDecls) <-
mkExpr False Concurrent (NetlistId (Id.unsafeMake "c$tte_rhs") scrutTy) scrut
case scrutExpr of
Identifier id_ Nothing -> return (DataTag hwTy (Left id_),scrutDecls)
_ -> do
scrutHTy <- unsafeCoreTypeToHWTypeM' $(curLoc) scrutTy
tmpRhs <- Id.make "c$tte_rhs"
let netDeclRhs = NetDecl Nothing tmpRhs scrutHTy
netAssignRhs = Assignment tmpRhs scrutExpr
return (DataTag hwTy (Left tmpRhs),[netDeclRhs,netAssignRhs] ++ scrutDecls)
_ -> error $ $(curLoc) ++ "tagToEnum: " ++ show (map (either showPpr showPpr) args)
| pNm == "GHC.Prim.dataToTag#" -> case args of
[Right _,Left (Data dc)] -> do
iw <- Lens.use intWidth
return (N.Literal (Just (Signed iw,iw)) (NumLit $ toInteger $ dcTag dc - 1),[])
[Right _,Left scrut] -> do
tcm <- Lens.use tcCache
let scrutTy = inferCoreTypeOf tcm scrut
scrutHTy <- unsafeCoreTypeToHWTypeM' $(curLoc) scrutTy
(scrutExpr,scrutDecls) <-
mkExpr False Concurrent (NetlistId (Id.unsafeMake "c$dtt_rhs") scrutTy) scrut
case scrutExpr of
Identifier id_ Nothing -> return (DataTag scrutHTy (Right id_),scrutDecls)
_ -> do
tmpRhs <- Id.make "c$dtt_rhs"
let netDeclRhs = NetDecl Nothing tmpRhs scrutHTy
netAssignRhs = Assignment tmpRhs scrutExpr
return (DataTag scrutHTy (Right tmpRhs),[netDeclRhs,netAssignRhs] ++ scrutDecls)
_ -> error $ $(curLoc) ++ "dataToTag: " ++ show (map (either showPpr showPpr) args)
| pNm == "Clash.Explicit.SimIO.mealyIO" -> do
resM <- resBndr1 True dst
case resM of
Just (_,dstNm,dstDecl) -> do
tcm <- Lens.use tcCache
mealyDecls <- collectMealy dstNm dst tcm (lefts args)
return (Noop, dstDecl ++ mealyDecls)
Nothing -> return (Noop,[])
| pNm == "Clash.Explicit.SimIO.bindSimIO#" -> do
(expr,decls) <- collectBindIO dst (lefts args)
resM <- resBndr True dst
case resM of
Just (_,dstNms,dstDecl) -> case expr of
Noop ->
return (Noop,decls)
_ -> case dstNms of
[dstNm] ->
return ( Identifier dstNm Nothing
, dstDecl ++ decls ++ [Assignment dstNm expr])
_ -> error $ $(curLoc) ++ "bindSimIO: " ++ show resM
_ ->
return (Noop,decls)
| pNm == "Clash.Explicit.SimIO.apSimIO#" -> do
collectAppIO dst (lefts args) []
| pNm == "Clash.Explicit.SimIO.fmapSimIO#" -> do
resM <- resBndr1 True dst
case resM of
Just (_,dstNm,dstDecl) -> do
tcm <- Lens.use tcCache
let (fun0:arg0:_) = lefts args
arg1 = unSimIO tcm arg0
fun1 = case fun0 of
Lam b bE ->
let is0 = mkInScopeSet (Lens.foldMapOf freeIds unitVarSet fun0)
subst = extendIdSubst (mkSubst is0) b arg1
in substTm "mkPrimitive.fmapSimIO" subst bE
_ -> mkApps fun0 [Left arg1]
(expr,bindDecls) <- mkExpr False Sequential dst fun1
let assn = case expr of
Noop -> []
_ -> [Assignment dstNm expr]
return (Identifier dstNm Nothing, dstDecl ++ bindDecls ++ assn)
Nothing -> do
let (_:arg0:_) = lefts args
(_,bindDecls) <- mkExpr True Sequential dst arg0
return (Noop, bindDecls)
| pNm == "Clash.Explicit.SimIO.unSimIO#" ->
case lefts args of
(arg:_) -> mkExpr False Sequential dst arg
_ -> error "internal error: insufficient arguments"
| pNm == "Clash.Explicit.SimIO.pureSimIO#" -> do
(expr,decls) <- case lefts args of
(arg:_) -> mkExpr False Sequential dst arg
_ -> error "internal error: insufficient arguments"
resM <- resBndr True dst
case resM of
Just (_,dstNms,dstDecl) -> case expr of
Noop ->
return (Noop,decls)
_ -> case dstNms of
[dstNm] ->
return ( Identifier dstNm Nothing
, dstDecl ++ decls ++ [Assignment dstNm expr])
_ -> error "internal error"
_ ->
return (Noop,decls)
| pNm == "GHC.Num.Integer.IS" -> do
(expr,decls) <- case lefts args of
(arg:_) -> mkExpr False Concurrent dst arg
_ -> error "internal error: insufficient arguments"
iw <- Lens.use intWidth
return (N.DataCon (Signed iw) (DC (Void Nothing,-1)) [expr],decls)
| pNm == "GHC.Num.Integer.IP" -> do
(expr,decls) <- case lefts args of
(arg:_) -> mkExpr False Concurrent dst arg
_ -> error "internal error: insufficient arguments"
case expr of
N.Literal Nothing (NumLit _) -> return (expr,decls)
_ -> error "non-constant ByteArray# not supported"
| pNm == "GHC.Num.Integer.IN" -> do
(expr,decls) <- case lefts args of
(arg:_) -> mkExpr False Concurrent dst arg
_ -> error "internal error: insufficient arguments"
case expr of
N.Literal Nothing (NumLit i) ->
return (N.Literal Nothing (NumLit (negate i)),decls)
_ -> error "non-constant ByteArray# not supported"
| pNm == "GHC.Num.Natural.NS" -> do
(expr,decls) <- case lefts args of
(arg:_) -> mkExpr False Concurrent dst arg
_ -> error "internal error: insufficient arguments"
iw <- Lens.use intWidth
return (N.DataCon (Unsigned iw) (DC (Void Nothing,-1)) [expr],decls)
| pNm == "GHC.Num.Integer.NB" -> do
(expr,decls) <- case lefts args of
(arg:_) -> mkExpr False Concurrent dst arg
_ -> error "internal error: insufficient arguments"
case expr of
N.Literal Nothing (NumLit _) -> return (expr,decls)
_ -> error "non-constant ByteArray# not supported"
| otherwise ->
return (BlackBoxE "" [] [] []
(BBTemplate [Text $ mconcat ["NO_TRANSLATION_FOR:",fromStrict pNm]])
(emptyBBContext pNm) False,[])
-- Do we need to create a new identifier to assign the result?
--
-- CoreId: No, this is an original LHS of a let-binder, and already has a
-- corresponding NetDecl; unlike NetlistIds, it is not already
-- assigned, it will be assigned by the BlackBox/Primitive.
--
-- NetlistId: This is a derived (either from an CoreId or other NetlistId)
-- identifier created in the NetlistMonad that's already being
-- used in an assignment, i.e. we cannot assign it again.
--
-- So if it is a declaration BlackBox (indicated by 'mkDec'),
-- we will have to create a new NetlistId, create a NetDecl for
-- it, and use this new NetlistId for the assignment inside the
-- declaration BlackBox
--
-- MultiId: This is like a CoreId, but it's split over multiple identifiers
-- because it was originally of a product type where the element
-- types should not be part of an aggregate type in the generated
-- HDL (e.g. Clocks should not be part of an aggregate, because
-- tools like verilator don't like it)
resBndr
:: Bool
-- Do we need to create and declare a new identifier in case we're given
-- a NetlistId?
-> NetlistId
-- CoreId/NetlistId/MultiId
-> NetlistMonad (Maybe ([Id],[Identifier],[Declaration]))
-- Nothing when the binder would have type `Void`
resBndr mkDec dst' = do
resHwTy <- case tys of
(ty1:_) -> unsafeCoreTypeToHWTypeM' $(curLoc) ty1
_ -> error "internal error: insufficient types"
if isVoid resHwTy then
pure Nothing
else
case dst' of
NetlistId dstL _ -> case mkDec of
False -> do
-- TODO: check that it's okay to use `mkUnsafeSystemName`
let nm' = mkUnsafeSystemName (Id.toText dstL) 0
id_ = mkLocalId ty nm'
return (Just ([id_],[dstL],[]))
True -> do
nm2 <- Id.suffix dstL "res"
-- TODO: check that it's okay to use `mkUnsafeInternalName`
let nm3 = mkUnsafeSystemName (Id.toText nm2) 0
id_ = mkLocalId ty nm3
idDeclM <- mkNetDecl (id_, mkApps (Prim pInfo) args)
case idDeclM of
[] -> return Nothing
[idDecl] -> return (Just ([id_],[nm2],[idDecl]))
ids -> error [I.i|
Unexpected nested use of multi result primitive. Ids:
#{show ids}
Multi primitive should only appear on the RHS of a
let-binding. Please report this as a bug.
|]
CoreId dstR ->
return (Just ([dstR], [Id.unsafeMake . nameOcc . varName $ dstR], []))
MultiId ids ->
return (Just (ids, map (Id.unsafeMake . nameOcc . varName) ids, []))
-- Like resBndr, but fails on MultiId
resBndr1
:: HasCallStack
=> Bool
-> NetlistId
-> NetlistMonad (Maybe (Id,Identifier,[Declaration]))
resBndr1 mkDec dst' = resBndr mkDec dst' >>= \case
Nothing -> pure Nothing
Just ([id_],[nm_],decls) -> pure (Just (id_,nm_,decls))
_ -> error "internal error"
-- | Turn a 'mealyIO' expression into a two sequential processes, one "initial"
-- process for the starting state, and one clocked sequential process.
collectMealy
:: HasCallStack
=> Identifier
-- ^ Identifier to assign the final result to
-> NetlistId
-- ^ Id to assign the final result to
-> TyConMap
-> [Term]
-- ^ The arguments to 'mealyIO'
-> NetlistMonad [Declaration]
collectMealy dstNm dst tcm (kd:clk:mealyFun:mealyInit:mealyIn:_) = do
let (lefts -> args0,res0) = collectBndrs mealyFun
is0 = mkInScopeSet (Lens.foldMapOf freeIds unitVarSet res0 <>
Lens.foldMapOf freeIds unitVarSet mealyInit <>
Lens.foldMapOf freeIds unitVarSet mealyIn)
-- Given that we're creating a sequential list of statements from the
-- let-bindings, make sure that everything is inverse topologically sorted
(bs,res) = case inverseTopSortLetBindings res0 of
Letrec bsN (C.Var resN) -> (bsN,resN)
Letrec bsN e ->
let u = case dst of
CoreId u0 -> u0
_ -> uniqAway is0
(mkLocalId (inferCoreTypeOf tcm e)
(mkUnsafeSystemName "mealyres" 0))
in (bsN ++ [(u,e)], u)
e ->
let u = case dst of
CoreId u0 -> u0
_ -> uniqAway is0
(mkLocalId (inferCoreTypeOf tcm e)
(mkUnsafeSystemName "mealyres" 0))
in ([(u,e)], u)
#if __GLASGOW_HASKELL__ >= 900
args1 = args0
#else
-- Drop the 'State# World' argument
args1 = init args0
#endif
-- Take into account that the state argument is split over multiple
-- binders because it contained types that are not allowed to occur in
-- a HDL aggregate type
mealyInitLength = length (splitShouldSplit tcm [inferCoreTypeOf tcm mealyInit])
(sArgs,iArgs) = splitAt mealyInitLength args1
-- Give all binders a unique name
let sBindings = map (,mealyInit) sArgs ++ map (,mealyIn) iArgs ++ bs
normE <- mkUniqueNormalized is0 Nothing ([], sBindings, res)
case normE of
-- We're not expecting any input or output wrappers
(_,[],[],_,[],binders0,Just result) -> do
let (sBinders,binders1) = splitAt (length sArgs) binders0
(iBinders,binders2) = splitAt (length iArgs) binders1
-- Get all the "original" let-bindings, without the above "mealyres".
-- We don't want to make a NetDecl for it.
bindersN = case res0 of
Letrec _ (C.Var {}) -> binders2
_ -> init binders2
-- Create new net declarations for state-binders, input-binders, and all
-- the "original" let-bindings in 'mealyFun'
--
-- The first set is only assigned in the always block, so they must be
-- 'reg' in Verilog terminology
netDeclsSeq <- concatMapM mkNetDecl (sBinders ++ bindersN)
-- The second set is assigned using concurrent assignment, so don't need
-- to be 'reg'
netDeclsInp <- concatMapM mkNetDecl iBinders
-- If the 'mealyFun' was not a let-expression with a variable reference
-- as a body then we used the LHS of the entire 'mealyIO' expression as
-- a new let-binding; otherwise 'mkUniqueNormalized' would not work.
--
-- However, 'mkUniqueNormalized' made a new unique name for that LHS,
-- which is not what we want. We want to assign the last expression to the
-- LHS of 'mealyIO'.
let bindersE = case res0 of
Letrec _ (C.Var {}) -> binders2
_ -> case dst of
-- See above why we do this.
CoreId u0 -> init binders2 ++ [(u0,snd (last binders2))]
_ -> binders2
seqDecls <- concat <$> mapM (uncurry (mkDeclarations' Sequential)) bindersE
-- When the body the let-expression of 'mealyFun' was variable reference,
-- or in case we had to create a new identifier because the original LHS
-- was not available: then we need to assign
(resExpr,resDecls) <- case res0 of
Letrec _ (C.Var {}) -> mkExpr False Concurrent dst (C.Var result)
_ -> case dst of
CoreId {} -> pure (Noop,[])
_ -> mkExpr False Concurrent dst (C.Var result)
let resAssn = case resExpr of
Noop -> []
_ -> [Seq [AlwaysComb [SeqDecl (Assignment dstNm resExpr)]]]
-- Create the declarations for the "initial state" block
let sDst = case sBinders of
[] -> error "internal error: insufficient sBinders"
[(b,_)] -> CoreId b
_ -> MultiId (map fst sBinders)
(exprInit,initDecls) <- mkExpr False Sequential sDst mealyInit
let initAssign = case exprInit of
Identifier _ Nothing -> []
Noop -> []
_ -> case sBinders of
((b,_):_) -> [Assignment (id2identifier b) exprInit]
_ -> error "internal error: insufficient sBinders"
-- Create the declarations that corresponding to the input
let iDst = case iBinders of
[] -> error "internal error: insufficient iBinders"
[(b,_)] -> CoreId b
_ -> MultiId (map fst iBinders)
(exprArg,inpDeclsMisc) <- mkExpr False Concurrent iDst mealyIn
-- Split netdecl declarations and other declarations
let (netDeclsSeqMisc,seqDeclsOther) = partition isNet (seqDecls ++ resDecls)
(netDeclsInit,initDeclsOther) = partition isNet initDecls
-- All assignments happens within a sequential block, so the nets need to
-- be of type 'reg' in Verilog nomenclature
let netDeclsSeq1 = map toReg (netDeclsSeq ++ netDeclsSeqMisc ++ netDeclsInit)
-- We run mealy block in the opposite clock edge of the the ambient system
-- because we're basically clocked logic; so we need to have our outputs
-- ready before the ambient system starts sampling them. The clockGen code
-- ensures that the "opposite" edge always comes first.
kdTy <- unsafeCoreTypeToHWTypeM $(curLoc) (inferCoreTypeOf tcm kd)
let edge = case stripVoid (stripFiltered kdTy) of
KnownDomain _ _ Rising _ _ _ -> Falling
KnownDomain _ _ Falling _ _ _ -> Rising
_ -> error "internal error"
(clkExpr,clkDecls) <-
mkExpr False Concurrent (NetlistId (Id.unsafeMake "__MEALY_CLK__") (inferCoreTypeOf tcm clk)) clk
-- collect the declarations related to the input
let netDeclsInp1 = netDeclsInp ++ inpDeclsMisc
-- Collate everything
return (clkDecls ++ netDeclsSeq1 ++ netDeclsInp1 ++
[ case iBinders of
((i,_):_) -> Assignment (id2identifier i) exprArg
_ -> error "internal error: insufficient iBinders"
, Seq [Initial (map SeqDecl (initDeclsOther ++ initAssign))]
, Seq [AlwaysClocked edge clkExpr (map SeqDecl seqDeclsOther)]
] ++ resAssn)
_ -> error "internal error"
where
isNet NetDecl' {} = True
isNet _ = False
toReg (NetDecl' cmM _ r ty eM) = NetDecl' cmM Reg r ty eM
toReg d = d
collectMealy _ _ _ _ = error "internal error"
-- | Collect the sequential declarations for 'bindIO'
collectBindIO :: NetlistId -> [Term] -> NetlistMonad (Expr,[Declaration])
#if __GLASGOW_HASKELL__ >= 900
collectBindIO dst (m:Lam x q@e:_) = do
#else
collectBindIO dst (m:Lam x q@(Lam _ e):_) = do
#endif
tcm <- Lens.use tcCache
(ds0,subst) <- collectAction tcm
let qS = substTm "collectBindIO1" subst q
case splitNormalized tcm qS of
Right (args,bs0,res) -> do
let Letrec bs _ = inverseTopSortLetBindings (Letrec bs0 (C.Var res))
let is0 = mkInScopeSet (Lens.foldMapOf freeIds unitVarSet qS)
normE <- mkUniqueNormalized is0 Nothing (args,bs,res)
case normE of
(_,_,[],_,[],binders,Just result) -> do
ds1 <- concatMapM (uncurry (mkDeclarations' Sequential)) binders
netDecls <- concatMapM mkNetDecl binders
return (Identifier (id2identifier result) Nothing, netDecls ++ ds0 ++ ds1)
_ -> error "internal error"
_ -> case substTm "collectBindIO2" subst e of
Letrec {} -> error "internal error"
(collectArgs -> (Prim p,args))
| primName p == "Clash.Explicit.SimIO.bindSimIO#" -> do
(expr,ds1) <- collectBindIO dst (lefts args)
return (expr, ds0 ++ ds1)
eS -> do
(expr,ds1) <- mkExpr False Sequential dst eS
return (expr, ds0 ++ ds1)
where
collectAction tcm = case splitNormalized tcm m of
Right (args,bs0,res) -> do
let Letrec bs _ = inverseTopSortLetBindings (Letrec bs0 (C.Var res))
let is0 = mkInScopeSet (Lens.foldMapOf freeIds unitVarSet m)
normE <- mkUniqueNormalized is0 Nothing (args,(x,m):bs,res)
case normE of
(_,_,[],_,[],binders@(b:_),Just result) -> do
let binders1 = tail binders ++ [(fst b, C.Var result)]
ds1 <- concatMapM (uncurry (mkDeclarations' Sequential)) binders1
netDecls <- concatMapM mkNetDecl binders
return (netDecls ++ ds1,extendIdSubst (mkSubst eInScopeSet) x (Var (fst b)))
_ -> error "internal error"
_ -> do
([x'],s) <- mkUnique (mkSubst eInScopeSet) [x]
netDecls <- concatMapM mkNetDecl [(x',m)]
ds1 <- mkDeclarations' Sequential x' m
return (netDecls ++ ds1,s)
eInScopeSet = mkInScopeSet (Lens.foldMapOf freeIds unitVarSet e)
collectBindIO _ es = error ("internal error:\n" ++ showPpr es)
-- | Collect the sequential declarations for 'appIO'
collectAppIO :: NetlistId -> [Term] -> [Term] -> NetlistMonad (Expr,[Declaration])
collectAppIO dst (fun1:arg1:_) rest = case collectArgs fun1 of
(Prim (PrimInfo "Clash.Explicit.SimIO.fmapSimIO#" _ _ _ _),(lefts -> (fun0:arg0:_))) -> do
tcm <- Lens.use tcCache
let argN = map (Left . unSimIO tcm) (arg0:arg1:rest)
mkExpr False Sequential dst (mkApps fun0 argN)
(Prim (PrimInfo "Clash.Explicit.SimIO.apSimIO#" _ _ _ _),(lefts -> args)) -> do
collectAppIO dst args (arg1:rest)
_ -> error ("internal error:\n" ++ showPpr (fun1:arg1:rest))
collectAppIO _ es _ = error ("internal error:\n" ++ showPpr es)
-- | Unwrap the new-type wrapper for things of type SimIO, this is needed to
-- allow applications of the `State# World` token to the underlying IO type.
--
-- XXX: this is most likely needed because Ghc2Core that threw away the cast
-- that this unwrapping; we should really start to support casts.
unSimIO
:: TyConMap
-> Term
-> Term
unSimIO tcm arg =
let argTy = inferCoreTypeOf tcm arg
in case tyView argTy of
TyConApp _ [tcArg] ->
mkApps (Prim (PrimInfo
"Clash.Explicit.SimIO.unSimIO#"
(mkFunTy argTy tcArg)
WorkNever
SingleResult
NoUnfolding))
[Left arg]
_ -> error ("internal error:\n" ++ showPpr arg)
-- | Create an template instantiation text and a partial blackbox content for an
-- argument term, given that the term is a function. Errors if the term is not
-- a function
mkFunInput
:: HasCallStack
=> Id
-- ^ Identifier binding the encompassing primitive/blackbox application. Used
-- as a name hint if 'mkFunInput' needs intermediate signals.
-> Term
-- ^ The function argument term
-> NetlistMonad
((Either BlackBox (Identifier,[Declaration])
,WireOrReg
,[BlackBoxTemplate]
,[BlackBoxTemplate]
,[((TextS.Text,TextS.Text),BlackBox)]
,BlackBoxContext)
,[Declaration])
mkFunInput resId e =
let (appE,args,ticks) = collectArgsTicks e
in withTicks ticks $ \tickDecls -> do
tcm <- Lens.use tcCache
-- TODO: Rewrite this function to use blackbox functions. Right now it
-- TODO: generates strings that are later parsed/interpreted again. Silly!
templ <- case appE of
Prim p -> do
bb <- extractPrimWarnOrFail (primName p)
case bb of
P.BlackBox {..} ->
pure (Left (kind,outputReg,libraries,imports,includes,primName p,template))
P.Primitive pn _ pt ->
error $ $(curLoc) ++ "Unexpected blackbox type: "
++ "Primitive " ++ show pn
++ " " ++ show pt
P.BlackBoxHaskell{name=pName, multiResult=True} ->
-- TODO: dev pointers
error [I.i|
Encountered multiresult primitive as a direct argument to
another primitive. This should not happen.
Encountered: #{pName}
Please report this as an issue.
|]
P.BlackBoxHaskell{name=pName, functionName=fName, function=(_, func)} -> do
-- Determine result type of this blackbox. If it's not a
-- function, simply use its term type.
let (_, resTy) = splitFunTys tcm (inferCoreTypeOf tcm e)
bbhRes <- func True pName args [resTy]
case bbhRes of
Left err ->
error $ $(curLoc) ++ show fName ++ " yielded an error: "
++ err
Right (BlackBoxMeta{..}, template) ->
pure $
Left ( bbKind, bbOutputReg, bbLibrary, bbImports
, bbIncludes, pName, template)
Data dc -> do
let eTy = inferCoreTypeOf tcm e
(_,resTy) = splitFunTys tcm eTy
resHTyM0 <- coreTypeToHWTypeM resTy
let resHTyM1 = (\fHwty -> (stripFiltered fHwty, flattenFiltered fHwty)) <$> resHTyM0
case resHTyM1 of
-- Special case where coreTypeToHWTypeM determined a type to
-- be completely transparent.
Just (_resHTy, [areVoids@(countEq False -> 1)]) -> do
let nonVoidArgI = fromJust (elemIndex False areVoids)
let arg = Id.unsafeMake (TextS.concat ["~ARG[", showt nonVoidArgI, "]"])
let assign = Assignment (Id.unsafeMake "~RESULT") (Identifier arg Nothing)
return (Right ((Id.unsafeMake "", tickDecls ++ [assign]), Wire))
-- Because we filter void constructs, the argument indices and
-- the field indices don't necessarily correspond anymore. We
-- use the result of coreTypeToHWTypeM to figure out what the
-- original indices are. Please see the documentation in
-- Clash.Netlist.Util.mkADT for more information.
Just (resHTy@(SP _ _), areVoids0) -> do
let
dcI = dcTag dc - 1
areVoids1 = indexNote ($(curLoc) ++ "No areVoids with index: " ++ show dcI) areVoids0 dcI
mkArg i = Id.unsafeMake ("~ARG[" <> showt i <> "]")
dcInps = [Identifier (mkArg x) Nothing | x <- originalIndices areVoids1]
dcApp = DataCon resHTy (DC (resHTy,dcI)) dcInps
dcAss = Assignment (Id.unsafeMake "~RESULT") dcApp
return (Right ((Id.unsafeMake "",tickDecls ++ [dcAss]),Wire))
-- CustomSP the same as SP, but with a user-defined bit
-- level representation
Just (resHTy@(CustomSP {}), areVoids0) -> do
let
dcI = dcTag dc - 1
areVoids1 = indexNote ($(curLoc) ++ "No areVoids with index: " ++ show dcI) areVoids0 dcI
mkArg i = Id.unsafeMake ("~ARG[" <> showt i <> "]")
dcInps = [Identifier (mkArg x) Nothing | x <- originalIndices areVoids1]
dcApp = DataCon resHTy (DC (resHTy,dcI)) dcInps
dcAss = Assignment (Id.unsafeMake "~RESULT") dcApp
return (Right ((Id.unsafeMake "",tickDecls ++ [dcAss]),Wire))
-- Like SP, we have to retrieve the index BEFORE filtering voids
Just (resHTy@(Product _ _ _), areVoids1:_) -> do
let mkArg i = Id.unsafeMake ("~ARG[" <> showt i <> "]")
dcInps = [ Identifier (mkArg x) Nothing | x <- originalIndices areVoids1]
dcApp = DataCon resHTy (DC (resHTy,0)) dcInps
dcAss = Assignment (Id.unsafeMake "~RESULT") dcApp
return (Right ((Id.unsafeMake "",tickDecls ++ [dcAss]),Wire))
-- Vectors never have defined areVoids (or all set to False), as
-- it would be converted to Void otherwise. We can therefore
-- safely ignore it:
Just (resHTy@(Vector _ _), _areVoids) -> do
let mkArg i = Id.unsafeMake ("~ARG[" <> showt i <> "]")
dcInps = [ Identifier (mkArg x) Nothing | x <- [(1::Int)..2] ]
dcApp = DataCon resHTy (DC (resHTy,1)) dcInps
dcAss = Assignment (Id.unsafeMake "~RESULT") dcApp
return (Right ((Id.unsafeMake "",tickDecls ++ [dcAss]),Wire))
-- Sum types OR a Sum type after filtering empty types:
Just (resHTy@(Sum _ _), _areVoids) -> do
let dcI = dcTag dc - 1
dcApp = DataCon resHTy (DC (resHTy,dcI)) []
dcAss = Assignment (Id.unsafeMake "~RESULT") dcApp
return (Right ((Id.unsafeMake "",tickDecls ++ [dcAss]),Wire))
-- Same as Sum, but with user defined bit level representation
Just (resHTy@(CustomSum {}), _areVoids) -> do
let dcI = dcTag dc - 1
dcApp = DataCon resHTy (DC (resHTy,dcI)) []
dcAss = Assignment (Id.unsafeMake "~RESULT") dcApp
return (Right ((Id.unsafeMake "",tickDecls ++ [dcAss]),Wire))
Just (Void {}, _areVoids) ->
return (error $ $(curLoc) ++ "Encountered Void in mkFunInput."
++ " This is a bug in Clash.")
_ -> error $ $(curLoc) ++ "Cannot make function input for: " ++ showPpr e
C.Var fun -> do
topAnns <- Lens.use topEntityAnns
case lookupVarEnv fun topAnns of
Just _ ->
error $ $(curLoc) ++ "Cannot make function input for partially applied Synthesize-annotated: " ++ showPpr e
_ -> do
normalized <- Lens.use bindings
case lookupVarEnv fun normalized of
Just _ -> do
(meta,N.Component compName compInps [(_,compOutp,_)] _) <-
preserveVarEnv $ genComponent fun
let
ComponentMeta{cmWereVoids} = meta
inpAssign (i, t) e' = (Identifier i Nothing, In, t, e')
inpVar i = Id.unsafeMake ("~VAR[arg" <> showt i <> "][" <> showt i <> "]")
inpVars = [Identifier (inpVar i) Nothing | i <- originalIndices cmWereVoids]
inpAssigns = zipWith inpAssign compInps inpVars
outpAssign =
( Identifier (fst compOutp) Nothing
, Out
, snd compOutp
, Identifier (Id.unsafeMake "~RESULT") Nothing )
instLabel <- Id.next compName
let
portMap = NamedPortMap (outpAssign:inpAssigns)
instDecl = InstDecl Entity Nothing [] compName instLabel [] portMap
return (Right ((Id.unsafeMake "",tickDecls ++ [instDecl]),Wire))
Nothing -> error $ $(curLoc) ++ "Cannot make function input for: " ++ showPpr e
C.Lam {} -> do
let is0 = mkInScopeSet (Lens.foldMapOf freeIds unitVarSet appE)
either Left (Right . first (second (tickDecls ++))) <$> go is0 0 appE
_ -> error $ $(curLoc) ++ "Cannot make function input for: " ++ showPpr e
let pNm = case appE of
Prim p -> primName p
_ -> "__INTERNAL__"
(bbCtx,dcls) <- mkBlackBoxContext pNm [resId] args
case templ of
Left (TDecl,oreg,libs,imps,inc,_,templ') -> do
(l',templDecl)
<- onBlackBox
(fmap (first BBTemplate) . setSym bbCtx)
(\bbName bbHash bbFunc -> pure $ (BBFunction bbName bbHash bbFunc, []))
templ'
return ((Left l',if oreg then Reg else Wire,libs,imps,inc,bbCtx),dcls ++ templDecl)
Left (TExpr,_,libs,imps,inc,nm,templ') -> do
onBlackBox
(\t -> do t' <- getAp (prettyBlackBox t)
let t'' = Id.unsafeMake (Text.toStrict t')
assn = Assignment (Id.unsafeMake "~RESULT") (Identifier t'' Nothing)
return ((Right (Id.unsafeMake "",[assn]),Wire,libs,imps,inc,bbCtx),dcls))
(\bbName bbHash (TemplateFunction k g _) -> do
let f' bbCtx' = do
let assn = Assignment (Id.unsafeMake "~RESULT")
(BlackBoxE nm libs imps inc templ' bbCtx' False)
p <- getAp (Backend.blockDecl (Id.unsafeMake "") [assn])
return p
return ((Left (BBFunction bbName bbHash (TemplateFunction k g f'))
,Wire
,[]
,[]
,[]
,bbCtx
)
,dcls
)
)
templ'
Right (decl,wr) ->
return ((Right decl,wr,[],[],[],bbCtx),dcls)
where
goExpr app@(collectArgsTicks -> (C.Var fun,args@(_:_),ticks)) = do
tcm <- Lens.use tcCache
resTy <- unsafeCoreTypeToHWTypeM' $(curLoc) (inferCoreTypeOf tcm app)
let (tmArgs,tyArgs) = partitionEithers args
if null tyArgs
then
withTicks ticks $ \tickDecls -> do
resNm <- Id.make "result"
appDecls <- mkFunApp resNm fun tmArgs tickDecls
let assn = [ Assignment (Id.unsafeMake "~RESULT") (Identifier resNm Nothing)
, NetDecl Nothing resNm resTy ]
nm <- Id.makeBasic "block"
return (Right ((nm,assn++appDecls),Wire))
else do
(_,sp) <- Lens.use curCompNm
throw (ClashException sp ($(curLoc) ++ "Not in normal form: Var-application with Type arguments:\n\n" ++ showPpr app) Nothing)
goExpr e' = do
tcm <- Lens.use tcCache
let eType = inferCoreTypeOf tcm e'
(appExpr,appDecls) <- mkExpr False Concurrent (NetlistId (Id.unsafeMake "c$bb_res") eType) e'
let assn = Assignment (Id.unsafeMake "~RESULT") appExpr
nm <- if null appDecls
then return (Id.unsafeMake "")
else Id.makeBasic "block"
return (Right ((nm,appDecls ++ [assn]),Wire))
go is0 n (Lam id_ e') = do
lvl <- Lens.use curBBlvl
let nm = TextS.concat
["~ARGN[",TextS.pack (show lvl),"][",TextS.pack (show n),"]"]
v' = uniqAway is0 (modifyVarName (\v -> v {nameOcc = nm}) id_)
subst = extendIdSubst (mkSubst is0) id_ (C.Var v')
e'' = substTm "mkFunInput.goLam" subst e'
is1 = extendInScopeSet is0 v'
go is1 (n+(1::Int)) e''
go _ _ (C.Var v) = do
let assn = Assignment (Id.unsafeMake "~RESULT") (Identifier (id2identifier v) Nothing)
return (Right ((Id.unsafeMake "",[assn]),Wire))
go _ _ (Case scrut ty [alt]) = do
tcm <- Lens.use tcCache
let sTy = inferCoreTypeOf tcm scrut
(projection,decls) <- mkProjection False (NetlistId (Id.unsafeMake "c$bb_res") sTy) scrut ty alt
let assn = Assignment (Id.unsafeMake "~RESULT") projection
nm <- if null decls
then return (Id.unsafeMake "")
else Id.makeBasic "projection"
return (Right ((nm,decls ++ [assn]),Wire))
go _ _ (Case scrut ty alts@(_:_:_)) = do
tcm <- Lens.use tcCache
let scrutTy = inferCoreTypeOf tcm scrut
scrutHTy <- unsafeCoreTypeToHWTypeM' $(curLoc) scrutTy
ite <- Lens.use backEndITE
let wr = case iteAlts scrutHTy alts of
Just _ | ite -> Wire
_ -> Reg
resNm <- Id.make "result"
-- It's safe to use 'mkUnsafeSystemName' here: only the name, not the
-- unique, will be used
let resId' = NetlistId resNm ty
selectionDecls <- mkSelection Concurrent resId' scrut ty alts []
resTy <- unsafeCoreTypeToHWTypeM' $(curLoc) ty
let assn = [ NetDecl' Nothing wr resNm (Right resTy) Nothing
, Assignment (Id.unsafeMake "~RESULT") (Identifier resNm Nothing) ]
nm <- Id.makeBasic "selection"
return (Right ((nm,assn++selectionDecls),Wire))
go is0 _ e'@(Let{}) = do
tcm <- Lens.use tcCache
let normE = splitNormalized tcm e'
(_,[],[],_,[],binders,resultM) <- case normE of
Right norm -> mkUniqueNormalized is0 Nothing norm
Left err -> error err
case resultM of
Just result -> do
-- TODO: figure out what to do with multires blackboxes here
netDecls <- concatMapM mkNetDecl $ binders
decls <- concatMapM (uncurry mkDeclarations) binders
nm <- Id.makeBasic "fun"
let resultId = id2identifier result
-- TODO: Due to reasons lost in the mists of time, #1265 creates an
-- assignement here, whereas it previously wouldn't. With the PR in
-- tests break when reverting to the old behavior. In some cases this
-- creates "useless" assignments. We should investigate whether we can
-- get the old behavior back.
let resDecl = Assignment (Id.unsafeMake "~RESULT") (Identifier resultId Nothing)
return (Right ((nm,resDecl:netDecls ++ decls),Wire))
Nothing -> return (Right ((Id.unsafeMake "",[]),Wire))
go is0 n (Tick _ e') = go is0 n e'
go _ _ e'@(App {}) = goExpr e'
go _ _ e'@(C.Data {}) = goExpr e'
go _ _ e'@(C.Literal {}) = goExpr e'
go _ _ e'@(Cast {}) = goExpr e'
go _ _ e'@(Prim {}) = goExpr e'
go _ _ e'@(TyApp {}) = goExpr e'
go _ _ e'@(Case _ _ []) =
error $ $(curLoc) ++ "Cannot make function input for case without alternatives: " ++ show e'
go _ _ e'@(TyLam {}) =
error $ $(curLoc) ++ "Cannot make function input for TyLam: " ++ show e'