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|
{-# LANGUAGE CPP #-}
{-# LANGUAGE LambdaCase #-}
{-# OPTIONS_GHC -Wno-incomplete-uni-patterns #-}
----------------------------------------------------------------------------
--
-- Stg to C--: primitive operations
--
-- (c) The University of Glasgow 2004-2006
--
-----------------------------------------------------------------------------
module GHC.StgToCmm.Prim (
cgOpApp,
shouldInlinePrimOp
) where
#include "HsVersions.h"
import GHC.Prelude hiding ((<*>))
import GHC.Platform
import GHC.Platform.Profile
import GHC.StgToCmm.Layout
import GHC.StgToCmm.Foreign
import GHC.StgToCmm.Env
import GHC.StgToCmm.Monad
import GHC.StgToCmm.Utils
import GHC.StgToCmm.Ticky
import GHC.StgToCmm.Heap
import GHC.StgToCmm.Prof ( costCentreFrom )
import GHC.Driver.Session
import GHC.Driver.Backend
import GHC.Types.Basic
import GHC.Cmm.BlockId
import GHC.Cmm.Graph
import GHC.Stg.Syntax
import GHC.Cmm
import GHC.Unit ( rtsUnit )
import GHC.Core.Type ( Type, tyConAppTyCon )
import GHC.Core.TyCon
import GHC.Cmm.CLabel
import GHC.Cmm.Utils
import GHC.Builtin.PrimOps
import GHC.Runtime.Heap.Layout
import GHC.Data.FastString
import GHC.Utils.Misc
import GHC.Utils.Panic
import Data.Maybe
import Data.Bits ((.&.), bit)
import Control.Monad (liftM, when, unless)
------------------------------------------------------------------------
-- Primitive operations and foreign calls
------------------------------------------------------------------------
{- Note [Foreign call results]
~~~~~~~~~~~~~~~~~~~~~~~~~~~
A foreign call always returns an unboxed tuple of results, one
of which is the state token. This seems to happen even for pure
calls.
Even if we returned a single result for pure calls, it'd still be
right to wrap it in a singleton unboxed tuple, because the result
might be a Haskell closure pointer, we don't want to evaluate it. -}
----------------------------------
cgOpApp :: StgOp -- The op
-> [StgArg] -- Arguments
-> Type -- Result type (always an unboxed tuple)
-> FCode ReturnKind
-- Foreign calls
cgOpApp (StgFCallOp fcall ty) stg_args res_ty
= cgForeignCall fcall ty stg_args res_ty
-- Note [Foreign call results]
cgOpApp (StgPrimOp primop) args res_ty = do
dflags <- getDynFlags
cmm_args <- getNonVoidArgAmodes args
cmmPrimOpApp dflags primop cmm_args (Just res_ty)
cgOpApp (StgPrimCallOp primcall) args _res_ty
= do { cmm_args <- getNonVoidArgAmodes args
; let fun = CmmLit (CmmLabel (mkPrimCallLabel primcall))
; emitCall (NativeNodeCall, NativeReturn) fun cmm_args }
cmmPrimOpApp :: DynFlags -> PrimOp -> [CmmExpr] -> Maybe Type -> FCode ReturnKind
cmmPrimOpApp dflags primop cmm_args mres_ty =
case emitPrimOp dflags primop cmm_args of
PrimopCmmEmit_Internal f ->
let
-- if the result type isn't explicitly given, we directly use the
-- result type of the primop.
res_ty = fromMaybe (primOpResultType primop) mres_ty
in emitReturn =<< f res_ty
PrimopCmmEmit_External -> do
let fun = CmmLit (CmmLabel (mkRtsPrimOpLabel primop))
emitCall (NativeNodeCall, NativeReturn) fun cmm_args
-- | Interpret the argument as an unsigned value, assuming the value
-- is given in two-complement form in the given width.
--
-- Example: @asUnsigned W64 (-1)@ is 18446744073709551615.
--
-- This function is used to work around the fact that many array
-- primops take Int# arguments, but we interpret them as unsigned
-- quantities in the code gen. This means that we have to be careful
-- every time we work on e.g. a CmmInt literal that corresponds to the
-- array size, as it might contain a negative Integer value if the
-- user passed a value larger than 2^(wORD_SIZE_IN_BITS-1) as the Int#
-- literal.
asUnsigned :: Width -> Integer -> Integer
asUnsigned w n = n .&. (bit (widthInBits w) - 1)
------------------------------------------------------------------------
-- Emitting code for a primop
------------------------------------------------------------------------
shouldInlinePrimOp :: DynFlags -> PrimOp -> [CmmExpr] -> Bool
shouldInlinePrimOp dflags op args = case emitPrimOp dflags op args of
PrimopCmmEmit_External -> False
PrimopCmmEmit_Internal _ -> True
-- TODO: Several primop implementations (e.g. 'doNewByteArrayOp') use
-- ByteOff (or some other fixed width signed type) to represent
-- array sizes or indices. This means that these will overflow for
-- large enough sizes.
-- TODO: Several primops, such as 'copyArray#', only have an inline
-- implementation (below) but could possibly have both an inline
-- implementation and an out-of-line implementation, just like
-- 'newArray#'. This would lower the amount of code generated,
-- hopefully without a performance impact (needs to be measured).
-- | The big function handling all the primops.
--
-- In the simple case, there is just one implementation, and we emit that.
--
-- In more complex cases, there is a foreign call (out of line) fallback. This
-- might happen e.g. if there's enough static information, such as statically
-- know arguments.
emitPrimOp
:: DynFlags
-> PrimOp -- ^ The primop
-> [CmmExpr] -- ^ The primop arguments
-> PrimopCmmEmit
emitPrimOp dflags primop = case primop of
NewByteArrayOp_Char -> \case
[(CmmLit (CmmInt n w))]
| asUnsigned w n <= fromIntegral (maxInlineAllocSize dflags)
-> opIntoRegs $ \ [res] -> doNewByteArrayOp res (fromInteger n)
_ -> PrimopCmmEmit_External
NewArrayOp -> \case
[(CmmLit (CmmInt n w)), init]
| wordsToBytes platform (asUnsigned w n) <= fromIntegral (maxInlineAllocSize dflags)
-> opIntoRegs $ \[res] -> doNewArrayOp res (arrPtrsRep platform (fromInteger n)) mkMAP_DIRTY_infoLabel
[ (mkIntExpr platform (fromInteger n),
fixedHdrSize profile + pc_OFFSET_StgMutArrPtrs_ptrs (platformConstants platform))
, (mkIntExpr platform (nonHdrSizeW (arrPtrsRep platform (fromInteger n))),
fixedHdrSize profile + pc_OFFSET_StgMutArrPtrs_size (platformConstants platform))
]
(fromInteger n) init
_ -> PrimopCmmEmit_External
CopyArrayOp -> \case
[src, src_off, dst, dst_off, (CmmLit (CmmInt n _))] ->
opIntoRegs $ \ [] -> doCopyArrayOp src src_off dst dst_off (fromInteger n)
_ -> PrimopCmmEmit_External
CopyMutableArrayOp -> \case
[src, src_off, dst, dst_off, (CmmLit (CmmInt n _))] ->
opIntoRegs $ \ [] -> doCopyMutableArrayOp src src_off dst dst_off (fromInteger n)
_ -> PrimopCmmEmit_External
CopyArrayArrayOp -> \case
[src, src_off, dst, dst_off, (CmmLit (CmmInt n _))] ->
opIntoRegs $ \ [] -> doCopyArrayOp src src_off dst dst_off (fromInteger n)
_ -> PrimopCmmEmit_External
CopyMutableArrayArrayOp -> \case
[src, src_off, dst, dst_off, (CmmLit (CmmInt n _))] ->
opIntoRegs $ \ [] -> doCopyMutableArrayOp src src_off dst dst_off (fromInteger n)
_ -> PrimopCmmEmit_External
CloneArrayOp -> \case
[src, src_off, (CmmLit (CmmInt n w))]
| wordsToBytes platform (asUnsigned w n) <= fromIntegral (maxInlineAllocSize dflags)
-> opIntoRegs $ \ [res] -> emitCloneArray mkMAP_FROZEN_CLEAN_infoLabel res src src_off (fromInteger n)
_ -> PrimopCmmEmit_External
CloneMutableArrayOp -> \case
[src, src_off, (CmmLit (CmmInt n w))]
| wordsToBytes platform (asUnsigned w n) <= fromIntegral (maxInlineAllocSize dflags)
-> opIntoRegs $ \ [res] -> emitCloneArray mkMAP_DIRTY_infoLabel res src src_off (fromInteger n)
_ -> PrimopCmmEmit_External
FreezeArrayOp -> \case
[src, src_off, (CmmLit (CmmInt n w))]
| wordsToBytes platform (asUnsigned w n) <= fromIntegral (maxInlineAllocSize dflags)
-> opIntoRegs $ \ [res] -> emitCloneArray mkMAP_FROZEN_CLEAN_infoLabel res src src_off (fromInteger n)
_ -> PrimopCmmEmit_External
ThawArrayOp -> \case
[src, src_off, (CmmLit (CmmInt n w))]
| wordsToBytes platform (asUnsigned w n) <= fromIntegral (maxInlineAllocSize dflags)
-> opIntoRegs $ \ [res] -> emitCloneArray mkMAP_DIRTY_infoLabel res src src_off (fromInteger n)
_ -> PrimopCmmEmit_External
NewSmallArrayOp -> \case
[(CmmLit (CmmInt n w)), init]
| wordsToBytes platform (asUnsigned w n) <= fromIntegral (maxInlineAllocSize dflags)
-> opIntoRegs $ \ [res] ->
doNewArrayOp res (smallArrPtrsRep (fromInteger n)) mkSMAP_DIRTY_infoLabel
[ (mkIntExpr platform (fromInteger n),
fixedHdrSize profile + pc_OFFSET_StgSmallMutArrPtrs_ptrs (platformConstants platform))
]
(fromInteger n) init
_ -> PrimopCmmEmit_External
CopySmallArrayOp -> \case
[src, src_off, dst, dst_off, (CmmLit (CmmInt n _))] ->
opIntoRegs $ \ [] -> doCopySmallArrayOp src src_off dst dst_off (fromInteger n)
_ -> PrimopCmmEmit_External
CopySmallMutableArrayOp -> \case
[src, src_off, dst, dst_off, (CmmLit (CmmInt n _))] ->
opIntoRegs $ \ [] -> doCopySmallMutableArrayOp src src_off dst dst_off (fromInteger n)
_ -> PrimopCmmEmit_External
CloneSmallArrayOp -> \case
[src, src_off, (CmmLit (CmmInt n w))]
| wordsToBytes platform (asUnsigned w n) <= fromIntegral (maxInlineAllocSize dflags)
-> opIntoRegs $ \ [res] -> emitCloneSmallArray mkSMAP_FROZEN_CLEAN_infoLabel res src src_off (fromInteger n)
_ -> PrimopCmmEmit_External
CloneSmallMutableArrayOp -> \case
[src, src_off, (CmmLit (CmmInt n w))]
| wordsToBytes platform (asUnsigned w n) <= fromIntegral (maxInlineAllocSize dflags)
-> opIntoRegs $ \ [res] -> emitCloneSmallArray mkSMAP_DIRTY_infoLabel res src src_off (fromInteger n)
_ -> PrimopCmmEmit_External
FreezeSmallArrayOp -> \case
[src, src_off, (CmmLit (CmmInt n w))]
| wordsToBytes platform (asUnsigned w n) <= fromIntegral (maxInlineAllocSize dflags)
-> opIntoRegs $ \ [res] -> emitCloneSmallArray mkSMAP_FROZEN_CLEAN_infoLabel res src src_off (fromInteger n)
_ -> PrimopCmmEmit_External
ThawSmallArrayOp -> \case
[src, src_off, (CmmLit (CmmInt n w))]
| wordsToBytes platform (asUnsigned w n) <= fromIntegral (maxInlineAllocSize dflags)
-> opIntoRegs $ \ [res] -> emitCloneSmallArray mkSMAP_DIRTY_infoLabel res src src_off (fromInteger n)
_ -> PrimopCmmEmit_External
-- First we handle various awkward cases specially.
ParOp -> \[arg] -> opIntoRegs $ \[res] ->
-- for now, just implement this in a C function
-- later, we might want to inline it.
emitCCall
[(res,NoHint)]
(CmmLit (CmmLabel (mkForeignLabel (fsLit "newSpark") Nothing ForeignLabelInExternalPackage IsFunction)))
[(baseExpr, AddrHint), (arg,AddrHint)]
SparkOp -> \[arg] -> opIntoRegs $ \[res] -> do
-- returns the value of arg in res. We're going to therefore
-- refer to arg twice (once to pass to newSpark(), and once to
-- assign to res), so put it in a temporary.
tmp <- assignTemp arg
tmp2 <- newTemp (bWord platform)
emitCCall
[(tmp2,NoHint)]
(CmmLit (CmmLabel (mkForeignLabel (fsLit "newSpark") Nothing ForeignLabelInExternalPackage IsFunction)))
[(baseExpr, AddrHint), ((CmmReg (CmmLocal tmp)), AddrHint)]
emitAssign (CmmLocal res) (CmmReg (CmmLocal tmp))
GetCCSOfOp -> \[arg] -> opIntoRegs $ \[res] -> do
let
val
| profileIsProfiling profile = costCentreFrom platform (cmmUntag platform arg)
| otherwise = CmmLit (zeroCLit platform)
emitAssign (CmmLocal res) val
GetCurrentCCSOp -> \[_] -> opIntoRegs $ \[res] ->
emitAssign (CmmLocal res) cccsExpr
MyThreadIdOp -> \[] -> opIntoRegs $ \[res] ->
emitAssign (CmmLocal res) currentTSOExpr
ReadMutVarOp -> \[mutv] -> opIntoRegs $ \[res] ->
emitAssign (CmmLocal res) (cmmLoadIndexW platform mutv (fixedHdrSizeW profile) (gcWord platform))
WriteMutVarOp -> \[mutv, var] -> opIntoRegs $ \res@[] -> do
old_val <- CmmLocal <$> newTemp (cmmExprType platform var)
emitAssign old_val (cmmLoadIndexW platform mutv (fixedHdrSizeW profile) (gcWord platform))
-- Without this write barrier, other CPUs may see this pointer before
-- the writes for the closure it points to have occurred.
-- Note that this also must come after we read the old value to ensure
-- that the read of old_val comes before another core's write to the
-- MutVar's value.
emitPrimCall res MO_WriteBarrier []
emitStore (cmmOffsetW platform mutv (fixedHdrSizeW profile)) var
emitCCall
[{-no results-}]
(CmmLit (CmmLabel mkDirty_MUT_VAR_Label))
[(baseExpr, AddrHint), (mutv, AddrHint), (CmmReg old_val, AddrHint)]
-- #define sizzeofByteArrayzh(r,a) \
-- r = ((StgArrBytes *)(a))->bytes
SizeofByteArrayOp -> \[arg] -> opIntoRegs $ \[res] ->
emit $ mkAssign (CmmLocal res) (cmmLoadIndexW platform arg (fixedHdrSizeW profile) (bWord platform))
-- #define sizzeofMutableByteArrayzh(r,a) \
-- r = ((StgArrBytes *)(a))->bytes
SizeofMutableByteArrayOp -> emitPrimOp dflags SizeofByteArrayOp
-- #define getSizzeofMutableByteArrayzh(r,a) \
-- r = ((StgArrBytes *)(a))->bytes
GetSizeofMutableByteArrayOp -> \[arg] -> opIntoRegs $ \[res] ->
emitAssign (CmmLocal res) (cmmLoadIndexW platform arg (fixedHdrSizeW profile) (bWord platform))
-- #define touchzh(o) /* nothing */
TouchOp -> \args@[_] -> opIntoRegs $ \res@[] ->
emitPrimCall res MO_Touch args
-- #define byteArrayContentszh(r,a) r = BYTE_ARR_CTS(a)
ByteArrayContents_Char -> \[arg] -> opIntoRegs $ \[res] ->
emitAssign (CmmLocal res) (cmmOffsetB platform arg (arrWordsHdrSize profile))
-- #define mutableByteArrayContentszh(r,a) r = BYTE_ARR_CTS(a)
MutableByteArrayContents_Char -> \[arg] -> opIntoRegs $ \[res] ->
emitAssign (CmmLocal res) (cmmOffsetB platform arg (arrWordsHdrSize profile))
-- #define stableNameToIntzh(r,s) (r = ((StgStableName *)s)->sn)
StableNameToIntOp -> \[arg] -> opIntoRegs $ \[res] ->
emitAssign (CmmLocal res) (cmmLoadIndexW platform arg (fixedHdrSizeW profile) (bWord platform))
ReallyUnsafePtrEqualityOp -> \[arg1, arg2] -> opIntoRegs $ \[res] ->
emitAssign (CmmLocal res) (CmmMachOp (mo_wordEq platform) [arg1,arg2])
-- #define addrToHValuezh(r,a) r=(P_)a
AddrToAnyOp -> \[arg] -> opIntoRegs $ \[res] ->
emitAssign (CmmLocal res) arg
-- #define hvalueToAddrzh(r, a) r=(W_)a
AnyToAddrOp -> \[arg] -> opIntoRegs $ \[res] ->
emitAssign (CmmLocal res) arg
{- Freezing arrays-of-ptrs requires changing an info table, for the
benefit of the generational collector. It needs to scavenge mutable
objects, even if they are in old space. When they become immutable,
they can be removed from this scavenge list. -}
-- #define unsafeFreezzeArrayzh(r,a)
-- {
-- SET_INFO((StgClosure *)a,&stg_MUT_ARR_PTRS_FROZEN_DIRTY_info);
-- r = a;
-- }
UnsafeFreezeArrayOp -> \[arg] -> opIntoRegs $ \[res] ->
emit $ catAGraphs
[ setInfo arg (CmmLit (CmmLabel mkMAP_FROZEN_DIRTY_infoLabel)),
mkAssign (CmmLocal res) arg ]
UnsafeFreezeArrayArrayOp -> \[arg] -> opIntoRegs $ \[res] ->
emit $ catAGraphs
[ setInfo arg (CmmLit (CmmLabel mkMAP_FROZEN_DIRTY_infoLabel)),
mkAssign (CmmLocal res) arg ]
UnsafeFreezeSmallArrayOp -> \[arg] -> opIntoRegs $ \[res] ->
emit $ catAGraphs
[ setInfo arg (CmmLit (CmmLabel mkSMAP_FROZEN_DIRTY_infoLabel)),
mkAssign (CmmLocal res) arg ]
-- #define unsafeFreezzeByteArrayzh(r,a) r=(a)
UnsafeFreezeByteArrayOp -> \[arg] -> opIntoRegs $ \[res] ->
emitAssign (CmmLocal res) arg
-- Reading/writing pointer arrays
ReadArrayOp -> \[obj, ix] -> opIntoRegs $ \[res] ->
doReadPtrArrayOp res obj ix
IndexArrayOp -> \[obj, ix] -> opIntoRegs $ \[res] ->
doReadPtrArrayOp res obj ix
WriteArrayOp -> \[obj, ix, v] -> opIntoRegs $ \[] ->
doWritePtrArrayOp obj ix v
IndexArrayArrayOp_ByteArray -> \[obj, ix] -> opIntoRegs $ \[res] ->
doReadPtrArrayOp res obj ix
IndexArrayArrayOp_ArrayArray -> \[obj, ix] -> opIntoRegs $ \[res] ->
doReadPtrArrayOp res obj ix
ReadArrayArrayOp_ByteArray -> \[obj, ix] -> opIntoRegs $ \[res] ->
doReadPtrArrayOp res obj ix
ReadArrayArrayOp_MutableByteArray -> \[obj, ix] -> opIntoRegs $ \[res] ->
doReadPtrArrayOp res obj ix
ReadArrayArrayOp_ArrayArray -> \[obj, ix] -> opIntoRegs $ \[res] ->
doReadPtrArrayOp res obj ix
ReadArrayArrayOp_MutableArrayArray -> \[obj, ix] -> opIntoRegs $ \[res] ->
doReadPtrArrayOp res obj ix
WriteArrayArrayOp_ByteArray -> \[obj,ix,v] -> opIntoRegs $ \[] ->
doWritePtrArrayOp obj ix v
WriteArrayArrayOp_MutableByteArray -> \[obj,ix,v] -> opIntoRegs $ \[] ->
doWritePtrArrayOp obj ix v
WriteArrayArrayOp_ArrayArray -> \[obj,ix,v] -> opIntoRegs $ \[] ->
doWritePtrArrayOp obj ix v
WriteArrayArrayOp_MutableArrayArray -> \[obj,ix,v] -> opIntoRegs $ \[] ->
doWritePtrArrayOp obj ix v
ReadSmallArrayOp -> \[obj, ix] -> opIntoRegs $ \[res] ->
doReadSmallPtrArrayOp res obj ix
IndexSmallArrayOp -> \[obj, ix] -> opIntoRegs $ \[res] ->
doReadSmallPtrArrayOp res obj ix
WriteSmallArrayOp -> \[obj,ix,v] -> opIntoRegs $ \[] ->
doWriteSmallPtrArrayOp obj ix v
-- Getting the size of pointer arrays
SizeofArrayOp -> \[arg] -> opIntoRegs $ \[res] ->
emit $ mkAssign (CmmLocal res) (cmmLoadIndexW platform arg
(fixedHdrSizeW profile + bytesToWordsRoundUp platform (pc_OFFSET_StgMutArrPtrs_ptrs (platformConstants platform)))
(bWord platform))
SizeofMutableArrayOp -> emitPrimOp dflags SizeofArrayOp
SizeofArrayArrayOp -> emitPrimOp dflags SizeofArrayOp
SizeofMutableArrayArrayOp -> emitPrimOp dflags SizeofArrayOp
SizeofSmallArrayOp -> \[arg] -> opIntoRegs $ \[res] ->
emit $ mkAssign (CmmLocal res)
(cmmLoadIndexW platform arg
(fixedHdrSizeW profile + bytesToWordsRoundUp platform (pc_OFFSET_StgSmallMutArrPtrs_ptrs (platformConstants platform)))
(bWord platform))
SizeofSmallMutableArrayOp -> emitPrimOp dflags SizeofSmallArrayOp
GetSizeofSmallMutableArrayOp -> emitPrimOp dflags SizeofSmallArrayOp
-- IndexXXXoffAddr
IndexOffAddrOp_Char -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp (Just (mo_u_8ToWord platform)) b8 res args
IndexOffAddrOp_WideChar -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp (Just (mo_u_32ToWord platform)) b32 res args
IndexOffAddrOp_Int -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing (bWord platform) res args
IndexOffAddrOp_Word -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing (bWord platform) res args
IndexOffAddrOp_Addr -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing (bWord platform) res args
IndexOffAddrOp_Float -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing f32 res args
IndexOffAddrOp_Double -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing f64 res args
IndexOffAddrOp_StablePtr -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing (bWord platform) res args
IndexOffAddrOp_Int8 -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing b8 res args
IndexOffAddrOp_Int16 -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing b16 res args
IndexOffAddrOp_Int32 -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing b32 res args
IndexOffAddrOp_Int64 -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing b64 res args
IndexOffAddrOp_Word8 -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing b8 res args
IndexOffAddrOp_Word16 -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing b16 res args
IndexOffAddrOp_Word32 -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing b32 res args
IndexOffAddrOp_Word64 -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing b64 res args
-- ReadXXXoffAddr, which are identical, for our purposes, to IndexXXXoffAddr.
ReadOffAddrOp_Char -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp (Just (mo_u_8ToWord platform)) b8 res args
ReadOffAddrOp_WideChar -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp (Just (mo_u_32ToWord platform)) b32 res args
ReadOffAddrOp_Int -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing (bWord platform) res args
ReadOffAddrOp_Word -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing (bWord platform) res args
ReadOffAddrOp_Addr -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing (bWord platform) res args
ReadOffAddrOp_Float -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing f32 res args
ReadOffAddrOp_Double -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing f64 res args
ReadOffAddrOp_StablePtr -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing (bWord platform) res args
ReadOffAddrOp_Int8 -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing b8 res args
ReadOffAddrOp_Int16 -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing b16 res args
ReadOffAddrOp_Int32 -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing b32 res args
ReadOffAddrOp_Int64 -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing b64 res args
ReadOffAddrOp_Word8 -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing b8 res args
ReadOffAddrOp_Word16 -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing b16 res args
ReadOffAddrOp_Word32 -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing b32 res args
ReadOffAddrOp_Word64 -> \args -> opIntoRegs $ \res ->
doIndexOffAddrOp Nothing b64 res args
-- IndexXXXArray
IndexByteArrayOp_Char -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp (Just (mo_u_8ToWord platform)) b8 res args
IndexByteArrayOp_WideChar -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp (Just (mo_u_32ToWord platform)) b32 res args
IndexByteArrayOp_Int -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing (bWord platform) res args
IndexByteArrayOp_Word -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing (bWord platform) res args
IndexByteArrayOp_Addr -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing (bWord platform) res args
IndexByteArrayOp_Float -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing f32 res args
IndexByteArrayOp_Double -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing f64 res args
IndexByteArrayOp_StablePtr -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing (bWord platform) res args
IndexByteArrayOp_Int8 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing b8 res args
IndexByteArrayOp_Int16 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing b16 res args
IndexByteArrayOp_Int32 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing b32 res args
IndexByteArrayOp_Int64 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing b64 res args
IndexByteArrayOp_Word8 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing b8 res args
IndexByteArrayOp_Word16 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing b16 res args
IndexByteArrayOp_Word32 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing b32 res args
IndexByteArrayOp_Word64 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing b64 res args
-- ReadXXXArray, identical to IndexXXXArray.
ReadByteArrayOp_Char -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp (Just (mo_u_8ToWord platform)) b8 res args
ReadByteArrayOp_WideChar -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp (Just (mo_u_32ToWord platform)) b32 res args
ReadByteArrayOp_Int -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing (bWord platform) res args
ReadByteArrayOp_Word -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing (bWord platform) res args
ReadByteArrayOp_Addr -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing (bWord platform) res args
ReadByteArrayOp_Float -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing f32 res args
ReadByteArrayOp_Double -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing f64 res args
ReadByteArrayOp_StablePtr -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing (bWord platform) res args
ReadByteArrayOp_Int8 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing b8 res args
ReadByteArrayOp_Int16 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing b16 res args
ReadByteArrayOp_Int32 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing b32 res args
ReadByteArrayOp_Int64 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing b64 res args
ReadByteArrayOp_Word8 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing b8 res args
ReadByteArrayOp_Word16 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing b16 res args
ReadByteArrayOp_Word32 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing b32 res args
ReadByteArrayOp_Word64 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOp Nothing b64 res args
-- IndexWord8ArrayAsXXX
IndexByteArrayOp_Word8AsChar -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs (Just (mo_u_8ToWord platform)) b8 b8 res args
IndexByteArrayOp_Word8AsWideChar -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs (Just (mo_u_32ToWord platform)) b32 b8 res args
IndexByteArrayOp_Word8AsInt -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing (bWord platform) b8 res args
IndexByteArrayOp_Word8AsWord -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing (bWord platform) b8 res args
IndexByteArrayOp_Word8AsAddr -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing (bWord platform) b8 res args
IndexByteArrayOp_Word8AsFloat -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing f32 b8 res args
IndexByteArrayOp_Word8AsDouble -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing f64 b8 res args
IndexByteArrayOp_Word8AsStablePtr -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing (bWord platform) b8 res args
IndexByteArrayOp_Word8AsInt16 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing b16 b8 res args
IndexByteArrayOp_Word8AsInt32 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing b32 b8 res args
IndexByteArrayOp_Word8AsInt64 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing b64 b8 res args
IndexByteArrayOp_Word8AsWord16 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing b16 b8 res args
IndexByteArrayOp_Word8AsWord32 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing b32 b8 res args
IndexByteArrayOp_Word8AsWord64 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing b64 b8 res args
-- ReadInt8ArrayAsXXX, identical to IndexInt8ArrayAsXXX
ReadByteArrayOp_Word8AsChar -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs (Just (mo_u_8ToWord platform)) b8 b8 res args
ReadByteArrayOp_Word8AsWideChar -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs (Just (mo_u_32ToWord platform)) b32 b8 res args
ReadByteArrayOp_Word8AsInt -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing (bWord platform) b8 res args
ReadByteArrayOp_Word8AsWord -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing (bWord platform) b8 res args
ReadByteArrayOp_Word8AsAddr -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing (bWord platform) b8 res args
ReadByteArrayOp_Word8AsFloat -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing f32 b8 res args
ReadByteArrayOp_Word8AsDouble -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing f64 b8 res args
ReadByteArrayOp_Word8AsStablePtr -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing (bWord platform) b8 res args
ReadByteArrayOp_Word8AsInt16 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing b16 b8 res args
ReadByteArrayOp_Word8AsInt32 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing b32 b8 res args
ReadByteArrayOp_Word8AsInt64 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing b64 b8 res args
ReadByteArrayOp_Word8AsWord16 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing b16 b8 res args
ReadByteArrayOp_Word8AsWord32 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing b32 b8 res args
ReadByteArrayOp_Word8AsWord64 -> \args -> opIntoRegs $ \res ->
doIndexByteArrayOpAs Nothing b64 b8 res args
-- WriteXXXoffAddr
WriteOffAddrOp_Char -> \args -> opIntoRegs $ \res ->
doWriteOffAddrOp (Just (mo_WordTo8 platform)) b8 res args
WriteOffAddrOp_WideChar -> \args -> opIntoRegs $ \res ->
doWriteOffAddrOp (Just (mo_WordTo32 platform)) b32 res args
WriteOffAddrOp_Int -> \args -> opIntoRegs $ \res ->
doWriteOffAddrOp Nothing (bWord platform) res args
WriteOffAddrOp_Word -> \args -> opIntoRegs $ \res ->
doWriteOffAddrOp Nothing (bWord platform) res args
WriteOffAddrOp_Addr -> \args -> opIntoRegs $ \res ->
doWriteOffAddrOp Nothing (bWord platform) res args
WriteOffAddrOp_Float -> \args -> opIntoRegs $ \res ->
doWriteOffAddrOp Nothing f32 res args
WriteOffAddrOp_Double -> \args -> opIntoRegs $ \res ->
doWriteOffAddrOp Nothing f64 res args
WriteOffAddrOp_StablePtr -> \args -> opIntoRegs $ \res ->
doWriteOffAddrOp Nothing (bWord platform) res args
WriteOffAddrOp_Int8 -> \args -> opIntoRegs $ \res ->
doWriteOffAddrOp Nothing b8 res args
WriteOffAddrOp_Int16 -> \args -> opIntoRegs $ \res ->
doWriteOffAddrOp Nothing b16 res args
WriteOffAddrOp_Int32 -> \args -> opIntoRegs $ \res ->
doWriteOffAddrOp Nothing b32 res args
WriteOffAddrOp_Int64 -> \args -> opIntoRegs $ \res ->
doWriteOffAddrOp Nothing b64 res args
WriteOffAddrOp_Word8 -> \args -> opIntoRegs $ \res ->
doWriteOffAddrOp Nothing b8 res args
WriteOffAddrOp_Word16 -> \args -> opIntoRegs $ \res ->
doWriteOffAddrOp Nothing b16 res args
WriteOffAddrOp_Word32 -> \args -> opIntoRegs $ \res ->
doWriteOffAddrOp Nothing b32 res args
WriteOffAddrOp_Word64 -> \args -> opIntoRegs $ \res ->
doWriteOffAddrOp Nothing b64 res args
-- WriteXXXArray
WriteByteArrayOp_Char -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp (Just (mo_WordTo8 platform)) b8 res args
WriteByteArrayOp_WideChar -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp (Just (mo_WordTo32 platform)) b32 res args
WriteByteArrayOp_Int -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing (bWord platform) res args
WriteByteArrayOp_Word -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing (bWord platform) res args
WriteByteArrayOp_Addr -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing (bWord platform) res args
WriteByteArrayOp_Float -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing f32 res args
WriteByteArrayOp_Double -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing f64 res args
WriteByteArrayOp_StablePtr -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing (bWord platform) res args
WriteByteArrayOp_Int8 -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b8 res args
WriteByteArrayOp_Int16 -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b16 res args
WriteByteArrayOp_Int32 -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b32 res args
WriteByteArrayOp_Int64 -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b64 res args
WriteByteArrayOp_Word8 -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b8 res args
WriteByteArrayOp_Word16 -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b16 res args
WriteByteArrayOp_Word32 -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b32 res args
WriteByteArrayOp_Word64 -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b64 res args
-- WriteInt8ArrayAsXXX
WriteByteArrayOp_Word8AsChar -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp (Just (mo_WordTo8 platform)) b8 res args
WriteByteArrayOp_Word8AsWideChar -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp (Just (mo_WordTo32 platform)) b8 res args
WriteByteArrayOp_Word8AsInt -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b8 res args
WriteByteArrayOp_Word8AsWord -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b8 res args
WriteByteArrayOp_Word8AsAddr -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b8 res args
WriteByteArrayOp_Word8AsFloat -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b8 res args
WriteByteArrayOp_Word8AsDouble -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b8 res args
WriteByteArrayOp_Word8AsStablePtr -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b8 res args
WriteByteArrayOp_Word8AsInt16 -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b8 res args
WriteByteArrayOp_Word8AsInt32 -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b8 res args
WriteByteArrayOp_Word8AsInt64 -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b8 res args
WriteByteArrayOp_Word8AsWord16 -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b8 res args
WriteByteArrayOp_Word8AsWord32 -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b8 res args
WriteByteArrayOp_Word8AsWord64 -> \args -> opIntoRegs $ \res ->
doWriteByteArrayOp Nothing b8 res args
-- Copying and setting byte arrays
CopyByteArrayOp -> \[src,src_off,dst,dst_off,n] -> opIntoRegs $ \[] ->
doCopyByteArrayOp src src_off dst dst_off n
CopyMutableByteArrayOp -> \[src,src_off,dst,dst_off,n] -> opIntoRegs $ \[] ->
doCopyMutableByteArrayOp src src_off dst dst_off n
CopyByteArrayToAddrOp -> \[src,src_off,dst,n] -> opIntoRegs $ \[] ->
doCopyByteArrayToAddrOp src src_off dst n
CopyMutableByteArrayToAddrOp -> \[src,src_off,dst,n] -> opIntoRegs $ \[] ->
doCopyMutableByteArrayToAddrOp src src_off dst n
CopyAddrToByteArrayOp -> \[src,dst,dst_off,n] -> opIntoRegs $ \[] ->
doCopyAddrToByteArrayOp src dst dst_off n
SetByteArrayOp -> \[ba,off,len,c] -> opIntoRegs $ \[] ->
doSetByteArrayOp ba off len c
-- Comparing byte arrays
CompareByteArraysOp -> \[ba1,ba1_off,ba2,ba2_off,n] -> opIntoRegs $ \[res] ->
doCompareByteArraysOp res ba1 ba1_off ba2 ba2_off n
BSwap16Op -> \[w] -> opIntoRegs $ \[res] ->
emitBSwapCall res w W16
BSwap32Op -> \[w] -> opIntoRegs $ \[res] ->
emitBSwapCall res w W32
BSwap64Op -> \[w] -> opIntoRegs $ \[res] ->
emitBSwapCall res w W64
BSwapOp -> \[w] -> opIntoRegs $ \[res] ->
emitBSwapCall res w (wordWidth platform)
BRev8Op -> \[w] -> opIntoRegs $ \[res] ->
emitBRevCall res w W8
BRev16Op -> \[w] -> opIntoRegs $ \[res] ->
emitBRevCall res w W16
BRev32Op -> \[w] -> opIntoRegs $ \[res] ->
emitBRevCall res w W32
BRev64Op -> \[w] -> opIntoRegs $ \[res] ->
emitBRevCall res w W64
BRevOp -> \[w] -> opIntoRegs $ \[res] ->
emitBRevCall res w (wordWidth platform)
-- Population count
PopCnt8Op -> \[w] -> opIntoRegs $ \[res] ->
emitPopCntCall res w W8
PopCnt16Op -> \[w] -> opIntoRegs $ \[res] ->
emitPopCntCall res w W16
PopCnt32Op -> \[w] -> opIntoRegs $ \[res] ->
emitPopCntCall res w W32
PopCnt64Op -> \[w] -> opIntoRegs $ \[res] ->
emitPopCntCall res w W64
PopCntOp -> \[w] -> opIntoRegs $ \[res] ->
emitPopCntCall res w (wordWidth platform)
-- Parallel bit deposit
Pdep8Op -> \[src, mask] -> opIntoRegs $ \[res] ->
emitPdepCall res src mask W8
Pdep16Op -> \[src, mask] -> opIntoRegs $ \[res] ->
emitPdepCall res src mask W16
Pdep32Op -> \[src, mask] -> opIntoRegs $ \[res] ->
emitPdepCall res src mask W32
Pdep64Op -> \[src, mask] -> opIntoRegs $ \[res] ->
emitPdepCall res src mask W64
PdepOp -> \[src, mask] -> opIntoRegs $ \[res] ->
emitPdepCall res src mask (wordWidth platform)
-- Parallel bit extract
Pext8Op -> \[src, mask] -> opIntoRegs $ \[res] ->
emitPextCall res src mask W8
Pext16Op -> \[src, mask] -> opIntoRegs $ \[res] ->
emitPextCall res src mask W16
Pext32Op -> \[src, mask] -> opIntoRegs $ \[res] ->
emitPextCall res src mask W32
Pext64Op -> \[src, mask] -> opIntoRegs $ \[res] ->
emitPextCall res src mask W64
PextOp -> \[src, mask] -> opIntoRegs $ \[res] ->
emitPextCall res src mask (wordWidth platform)
-- count leading zeros
Clz8Op -> \[w] -> opIntoRegs $ \[res] ->
emitClzCall res w W8
Clz16Op -> \[w] -> opIntoRegs $ \[res] ->
emitClzCall res w W16
Clz32Op -> \[w] -> opIntoRegs $ \[res] ->
emitClzCall res w W32
Clz64Op -> \[w] -> opIntoRegs $ \[res] ->
emitClzCall res w W64
ClzOp -> \[w] -> opIntoRegs $ \[res] ->
emitClzCall res w (wordWidth platform)
-- count trailing zeros
Ctz8Op -> \[w] -> opIntoRegs $ \[res] ->
emitCtzCall res w W8
Ctz16Op -> \[w] -> opIntoRegs $ \[res] ->
emitCtzCall res w W16
Ctz32Op -> \[w] -> opIntoRegs $ \[res] ->
emitCtzCall res w W32
Ctz64Op -> \[w] -> opIntoRegs $ \[res] ->
emitCtzCall res w W64
CtzOp -> \[w] -> opIntoRegs $ \[res] ->
emitCtzCall res w (wordWidth platform)
-- Unsigned int to floating point conversions
WordToFloatOp -> \[w] -> opIntoRegs $ \[res] ->
emitPrimCall [res] (MO_UF_Conv W32) [w]
WordToDoubleOp -> \[w] -> opIntoRegs $ \[res] ->
emitPrimCall [res] (MO_UF_Conv W64) [w]
-- Atomic operations
InterlockedExchange_Addr -> \[src, value] -> opIntoRegs $ \[res] ->
emitPrimCall [res] (MO_Xchg (wordWidth platform)) [src, value]
InterlockedExchange_Word -> \[src, value] -> opIntoRegs $ \[res] ->
emitPrimCall [res] (MO_Xchg (wordWidth platform)) [src, value]
FetchAddAddrOp_Word -> \[addr, n] -> opIntoRegs $ \[res] ->
doAtomicAddrRMW res AMO_Add addr (bWord platform) n
FetchSubAddrOp_Word -> \[addr, n] -> opIntoRegs $ \[res] ->
doAtomicAddrRMW res AMO_Sub addr (bWord platform) n
FetchAndAddrOp_Word -> \[addr, n] -> opIntoRegs $ \[res] ->
doAtomicAddrRMW res AMO_And addr (bWord platform) n
FetchNandAddrOp_Word -> \[addr, n] -> opIntoRegs $ \[res] ->
doAtomicAddrRMW res AMO_Nand addr (bWord platform) n
FetchOrAddrOp_Word -> \[addr, n] -> opIntoRegs $ \[res] ->
doAtomicAddrRMW res AMO_Or addr (bWord platform) n
FetchXorAddrOp_Word -> \[addr, n] -> opIntoRegs $ \[res] ->
doAtomicAddrRMW res AMO_Xor addr (bWord platform) n
AtomicReadAddrOp_Word -> \[addr] -> opIntoRegs $ \[res] ->
doAtomicReadAddr res addr (bWord platform)
AtomicWriteAddrOp_Word -> \[addr, val] -> opIntoRegs $ \[] ->
doAtomicWriteAddr addr (bWord platform) val
CasAddrOp_Addr -> \[dst, expected, new] -> opIntoRegs $ \[res] ->
emitPrimCall [res] (MO_Cmpxchg (wordWidth platform)) [dst, expected, new]
CasAddrOp_Word -> \[dst, expected, new] -> opIntoRegs $ \[res] ->
emitPrimCall [res] (MO_Cmpxchg (wordWidth platform)) [dst, expected, new]
-- SIMD primops
(VecBroadcastOp vcat n w) -> \[e] -> opIntoRegs $ \[res] -> do
checkVecCompatibility dflags vcat n w
doVecPackOp (vecElemInjectCast platform vcat w) ty zeros (replicate n e) res
where
zeros :: CmmExpr
zeros = CmmLit $ CmmVec (replicate n zero)
zero :: CmmLit
zero = case vcat of
IntVec -> CmmInt 0 w
WordVec -> CmmInt 0 w
FloatVec -> CmmFloat 0 w
ty :: CmmType
ty = vecVmmType vcat n w
(VecPackOp vcat n w) -> \es -> opIntoRegs $ \[res] -> do
checkVecCompatibility dflags vcat n w
when (es `lengthIsNot` n) $
panic "emitPrimOp: VecPackOp has wrong number of arguments"
doVecPackOp (vecElemInjectCast platform vcat w) ty zeros es res
where
zeros :: CmmExpr
zeros = CmmLit $ CmmVec (replicate n zero)
zero :: CmmLit
zero = case vcat of
IntVec -> CmmInt 0 w
WordVec -> CmmInt 0 w
FloatVec -> CmmFloat 0 w
ty :: CmmType
ty = vecVmmType vcat n w
(VecUnpackOp vcat n w) -> \[arg] -> opIntoRegs $ \res -> do
checkVecCompatibility dflags vcat n w
when (res `lengthIsNot` n) $
panic "emitPrimOp: VecUnpackOp has wrong number of results"
doVecUnpackOp (vecElemProjectCast platform vcat w) ty arg res
where
ty :: CmmType
ty = vecVmmType vcat n w
(VecInsertOp vcat n w) -> \[v,e,i] -> opIntoRegs $ \[res] -> do
checkVecCompatibility dflags vcat n w
doVecInsertOp (vecElemInjectCast platform vcat w) ty v e i res
where
ty :: CmmType
ty = vecVmmType vcat n w
(VecIndexByteArrayOp vcat n w) -> \args -> opIntoRegs $ \res0 -> do
checkVecCompatibility dflags vcat n w
doIndexByteArrayOp Nothing ty res0 args
where
ty :: CmmType
ty = vecVmmType vcat n w
(VecReadByteArrayOp vcat n w) -> \args -> opIntoRegs $ \res0 -> do
checkVecCompatibility dflags vcat n w
doIndexByteArrayOp Nothing ty res0 args
where
ty :: CmmType
ty = vecVmmType vcat n w
(VecWriteByteArrayOp vcat n w) -> \args -> opIntoRegs $ \res0 -> do
checkVecCompatibility dflags vcat n w
doWriteByteArrayOp Nothing ty res0 args
where
ty :: CmmType
ty = vecVmmType vcat n w
(VecIndexOffAddrOp vcat n w) -> \args -> opIntoRegs $ \res0 -> do
checkVecCompatibility dflags vcat n w
doIndexOffAddrOp Nothing ty res0 args
where
ty :: CmmType
ty = vecVmmType vcat n w
(VecReadOffAddrOp vcat n w) -> \args -> opIntoRegs $ \res0 -> do
checkVecCompatibility dflags vcat n w
doIndexOffAddrOp Nothing ty res0 args
where
ty :: CmmType
ty = vecVmmType vcat n w
(VecWriteOffAddrOp vcat n w) -> \args -> opIntoRegs $ \res0 -> do
checkVecCompatibility dflags vcat n w
doWriteOffAddrOp Nothing ty res0 args
where
ty :: CmmType
ty = vecVmmType vcat n w
(VecIndexScalarByteArrayOp vcat n w) -> \args -> opIntoRegs $ \res0 -> do
checkVecCompatibility dflags vcat n w
doIndexByteArrayOpAs Nothing vecty ty res0 args
where
vecty :: CmmType
vecty = vecVmmType vcat n w
ty :: CmmType
ty = vecCmmCat vcat w
(VecReadScalarByteArrayOp vcat n w) -> \args -> opIntoRegs $ \res0 -> do
checkVecCompatibility dflags vcat n w
doIndexByteArrayOpAs Nothing vecty ty res0 args
where
vecty :: CmmType
vecty = vecVmmType vcat n w
ty :: CmmType
ty = vecCmmCat vcat w
(VecWriteScalarByteArrayOp vcat n w) -> \args -> opIntoRegs $ \res0 -> do
checkVecCompatibility dflags vcat n w
doWriteByteArrayOp Nothing ty res0 args
where
ty :: CmmType
ty = vecCmmCat vcat w
(VecIndexScalarOffAddrOp vcat n w) -> \args -> opIntoRegs $ \res0 -> do
checkVecCompatibility dflags vcat n w
doIndexOffAddrOpAs Nothing vecty ty res0 args
where
vecty :: CmmType
vecty = vecVmmType vcat n w
ty :: CmmType
ty = vecCmmCat vcat w
(VecReadScalarOffAddrOp vcat n w) -> \args -> opIntoRegs $ \res0 -> do
checkVecCompatibility dflags vcat n w
doIndexOffAddrOpAs Nothing vecty ty res0 args
where
vecty :: CmmType
vecty = vecVmmType vcat n w
ty :: CmmType
ty = vecCmmCat vcat w
(VecWriteScalarOffAddrOp vcat n w) -> \args -> opIntoRegs $ \res0 -> do
checkVecCompatibility dflags vcat n w
doWriteOffAddrOp Nothing ty res0 args
where
ty :: CmmType
ty = vecCmmCat vcat w
-- Prefetch
PrefetchByteArrayOp3 -> \args -> opIntoRegs $ \[] ->
doPrefetchByteArrayOp 3 args
PrefetchMutableByteArrayOp3 -> \args -> opIntoRegs $ \[] ->
doPrefetchMutableByteArrayOp 3 args
PrefetchAddrOp3 -> \args -> opIntoRegs $ \[] ->
doPrefetchAddrOp 3 args
PrefetchValueOp3 -> \args -> opIntoRegs $ \[] ->
doPrefetchValueOp 3 args
PrefetchByteArrayOp2 -> \args -> opIntoRegs $ \[] ->
doPrefetchByteArrayOp 2 args
PrefetchMutableByteArrayOp2 -> \args -> opIntoRegs $ \[] ->
doPrefetchMutableByteArrayOp 2 args
PrefetchAddrOp2 -> \args -> opIntoRegs $ \[] ->
doPrefetchAddrOp 2 args
PrefetchValueOp2 -> \args -> opIntoRegs $ \[] ->
doPrefetchValueOp 2 args
PrefetchByteArrayOp1 -> \args -> opIntoRegs $ \[] ->
doPrefetchByteArrayOp 1 args
PrefetchMutableByteArrayOp1 -> \args -> opIntoRegs $ \[] ->
doPrefetchMutableByteArrayOp 1 args
PrefetchAddrOp1 -> \args -> opIntoRegs $ \[] ->
doPrefetchAddrOp 1 args
PrefetchValueOp1 -> \args -> opIntoRegs $ \[] ->
doPrefetchValueOp 1 args
PrefetchByteArrayOp0 -> \args -> opIntoRegs $ \[] ->
doPrefetchByteArrayOp 0 args
PrefetchMutableByteArrayOp0 -> \args -> opIntoRegs $ \[] ->
doPrefetchMutableByteArrayOp 0 args
PrefetchAddrOp0 -> \args -> opIntoRegs $ \[] ->
doPrefetchAddrOp 0 args
PrefetchValueOp0 -> \args -> opIntoRegs $ \[] ->
doPrefetchValueOp 0 args
-- Atomic read-modify-write
FetchAddByteArrayOp_Int -> \[mba, ix, n] -> opIntoRegs $ \[res] ->
doAtomicByteArrayRMW res AMO_Add mba ix (bWord platform) n
FetchSubByteArrayOp_Int -> \[mba, ix, n] -> opIntoRegs $ \[res] ->
doAtomicByteArrayRMW res AMO_Sub mba ix (bWord platform) n
FetchAndByteArrayOp_Int -> \[mba, ix, n] -> opIntoRegs $ \[res] ->
doAtomicByteArrayRMW res AMO_And mba ix (bWord platform) n
FetchNandByteArrayOp_Int -> \[mba, ix, n] -> opIntoRegs $ \[res] ->
doAtomicByteArrayRMW res AMO_Nand mba ix (bWord platform) n
FetchOrByteArrayOp_Int -> \[mba, ix, n] -> opIntoRegs $ \[res] ->
doAtomicByteArrayRMW res AMO_Or mba ix (bWord platform) n
FetchXorByteArrayOp_Int -> \[mba, ix, n] -> opIntoRegs $ \[res] ->
doAtomicByteArrayRMW res AMO_Xor mba ix (bWord platform) n
AtomicReadByteArrayOp_Int -> \[mba, ix] -> opIntoRegs $ \[res] ->
doAtomicReadByteArray res mba ix (bWord platform)
AtomicWriteByteArrayOp_Int -> \[mba, ix, val] -> opIntoRegs $ \[] ->
doAtomicWriteByteArray mba ix (bWord platform) val
CasByteArrayOp_Int -> \[mba, ix, old, new] -> opIntoRegs $ \[res] ->
doCasByteArray res mba ix (bWord platform) old new
-- The rest just translate straightforwardly
Int8ToWord8Op -> \args -> opNop args
Word8ToInt8Op -> \args -> opNop args
Int16ToWord16Op -> \args -> opNop args
Word16ToInt16Op -> \args -> opNop args
Int32ToWord32Op -> \args -> opNop args
Word32ToInt32Op -> \args -> opNop args
IntToWordOp -> \args -> opNop args
WordToIntOp -> \args -> opNop args
IntToAddrOp -> \args -> opNop args
AddrToIntOp -> \args -> opNop args
ChrOp -> \args -> opNop args -- Int# and Char# are rep'd the same
OrdOp -> \args -> opNop args
Narrow8IntOp -> \args -> opNarrow args (MO_SS_Conv, W8)
Narrow16IntOp -> \args -> opNarrow args (MO_SS_Conv, W16)
Narrow32IntOp -> \args -> opNarrow args (MO_SS_Conv, W32)
Narrow8WordOp -> \args -> opNarrow args (MO_UU_Conv, W8)
Narrow16WordOp -> \args -> opNarrow args (MO_UU_Conv, W16)
Narrow32WordOp -> \args -> opNarrow args (MO_UU_Conv, W32)
DoublePowerOp -> \args -> opCallish args MO_F64_Pwr
DoubleSinOp -> \args -> opCallish args MO_F64_Sin
DoubleCosOp -> \args -> opCallish args MO_F64_Cos
DoubleTanOp -> \args -> opCallish args MO_F64_Tan
DoubleSinhOp -> \args -> opCallish args MO_F64_Sinh
DoubleCoshOp -> \args -> opCallish args MO_F64_Cosh
DoubleTanhOp -> \args -> opCallish args MO_F64_Tanh
DoubleAsinOp -> \args -> opCallish args MO_F64_Asin
DoubleAcosOp -> \args -> opCallish args MO_F64_Acos
DoubleAtanOp -> \args -> opCallish args MO_F64_Atan
DoubleAsinhOp -> \args -> opCallish args MO_F64_Asinh
DoubleAcoshOp -> \args -> opCallish args MO_F64_Acosh
DoubleAtanhOp -> \args -> opCallish args MO_F64_Atanh
DoubleLogOp -> \args -> opCallish args MO_F64_Log
DoubleLog1POp -> \args -> opCallish args MO_F64_Log1P
DoubleExpOp -> \args -> opCallish args MO_F64_Exp
DoubleExpM1Op -> \args -> opCallish args MO_F64_ExpM1
DoubleSqrtOp -> \args -> opCallish args MO_F64_Sqrt
FloatPowerOp -> \args -> opCallish args MO_F32_Pwr
FloatSinOp -> \args -> opCallish args MO_F32_Sin
FloatCosOp -> \args -> opCallish args MO_F32_Cos
FloatTanOp -> \args -> opCallish args MO_F32_Tan
FloatSinhOp -> \args -> opCallish args MO_F32_Sinh
FloatCoshOp -> \args -> opCallish args MO_F32_Cosh
FloatTanhOp -> \args -> opCallish args MO_F32_Tanh
FloatAsinOp -> \args -> opCallish args MO_F32_Asin
FloatAcosOp -> \args -> opCallish args MO_F32_Acos
FloatAtanOp -> \args -> opCallish args MO_F32_Atan
FloatAsinhOp -> \args -> opCallish args MO_F32_Asinh
FloatAcoshOp -> \args -> opCallish args MO_F32_Acosh
FloatAtanhOp -> \args -> opCallish args MO_F32_Atanh
FloatLogOp -> \args -> opCallish args MO_F32_Log
FloatLog1POp -> \args -> opCallish args MO_F32_Log1P
FloatExpOp -> \args -> opCallish args MO_F32_Exp
FloatExpM1Op -> \args -> opCallish args MO_F32_ExpM1
FloatSqrtOp -> \args -> opCallish args MO_F32_Sqrt
-- Native word signless ops
IntAddOp -> \args -> opTranslate args (mo_wordAdd platform)
IntSubOp -> \args -> opTranslate args (mo_wordSub platform)
WordAddOp -> \args -> opTranslate args (mo_wordAdd platform)
WordSubOp -> \args -> opTranslate args (mo_wordSub platform)
AddrAddOp -> \args -> opTranslate args (mo_wordAdd platform)
AddrSubOp -> \args -> opTranslate args (mo_wordSub platform)
IntEqOp -> \args -> opTranslate args (mo_wordEq platform)
IntNeOp -> \args -> opTranslate args (mo_wordNe platform)
WordEqOp -> \args -> opTranslate args (mo_wordEq platform)
WordNeOp -> \args -> opTranslate args (mo_wordNe platform)
AddrEqOp -> \args -> opTranslate args (mo_wordEq platform)
AddrNeOp -> \args -> opTranslate args (mo_wordNe platform)
WordAndOp -> \args -> opTranslate args (mo_wordAnd platform)
WordOrOp -> \args -> opTranslate args (mo_wordOr platform)
WordXorOp -> \args -> opTranslate args (mo_wordXor platform)
WordNotOp -> \args -> opTranslate args (mo_wordNot platform)
WordSllOp -> \args -> opTranslate args (mo_wordShl platform)
WordSrlOp -> \args -> opTranslate args (mo_wordUShr platform)
AddrRemOp -> \args -> opTranslate args (mo_wordURem platform)
-- Native word signed ops
IntMulOp -> \args -> opTranslate args (mo_wordMul platform)
IntMulMayOfloOp -> \args -> opTranslate args (MO_S_MulMayOflo (wordWidth platform))
IntQuotOp -> \args -> opTranslate args (mo_wordSQuot platform)
IntRemOp -> \args -> opTranslate args (mo_wordSRem platform)
IntNegOp -> \args -> opTranslate args (mo_wordSNeg platform)
IntGeOp -> \args -> opTranslate args (mo_wordSGe platform)
IntLeOp -> \args -> opTranslate args (mo_wordSLe platform)
IntGtOp -> \args -> opTranslate args (mo_wordSGt platform)
IntLtOp -> \args -> opTranslate args (mo_wordSLt platform)
IntAndOp -> \args -> opTranslate args (mo_wordAnd platform)
IntOrOp -> \args -> opTranslate args (mo_wordOr platform)
IntXorOp -> \args -> opTranslate args (mo_wordXor platform)
IntNotOp -> \args -> opTranslate args (mo_wordNot platform)
IntSllOp -> \args -> opTranslate args (mo_wordShl platform)
IntSraOp -> \args -> opTranslate args (mo_wordSShr platform)
IntSrlOp -> \args -> opTranslate args (mo_wordUShr platform)
-- Native word unsigned ops
WordGeOp -> \args -> opTranslate args (mo_wordUGe platform)
WordLeOp -> \args -> opTranslate args (mo_wordULe platform)
WordGtOp -> \args -> opTranslate args (mo_wordUGt platform)
WordLtOp -> \args -> opTranslate args (mo_wordULt platform)
WordMulOp -> \args -> opTranslate args (mo_wordMul platform)
WordQuotOp -> \args -> opTranslate args (mo_wordUQuot platform)
WordRemOp -> \args -> opTranslate args (mo_wordURem platform)
AddrGeOp -> \args -> opTranslate args (mo_wordUGe platform)
AddrLeOp -> \args -> opTranslate args (mo_wordULe platform)
AddrGtOp -> \args -> opTranslate args (mo_wordUGt platform)
AddrLtOp -> \args -> opTranslate args (mo_wordULt platform)
-- Int8# signed ops
Int8ToIntOp -> \args -> opTranslate args (MO_SS_Conv W8 (wordWidth platform))
IntToInt8Op -> \args -> opTranslate args (MO_SS_Conv (wordWidth platform) W8)
Int8NegOp -> \args -> opTranslate args (MO_S_Neg W8)
Int8AddOp -> \args -> opTranslate args (MO_Add W8)
Int8SubOp -> \args -> opTranslate args (MO_Sub W8)
Int8MulOp -> \args -> opTranslate args (MO_Mul W8)
Int8QuotOp -> \args -> opTranslate args (MO_S_Quot W8)
Int8RemOp -> \args -> opTranslate args (MO_S_Rem W8)
Int8SllOp -> \args -> opTranslate args (MO_Shl W8)
Int8SraOp -> \args -> opTranslate args (MO_S_Shr W8)
Int8SrlOp -> \args -> opTranslate args (MO_U_Shr W8)
Int8EqOp -> \args -> opTranslate args (MO_Eq W8)
Int8GeOp -> \args -> opTranslate args (MO_S_Ge W8)
Int8GtOp -> \args -> opTranslate args (MO_S_Gt W8)
Int8LeOp -> \args -> opTranslate args (MO_S_Le W8)
Int8LtOp -> \args -> opTranslate args (MO_S_Lt W8)
Int8NeOp -> \args -> opTranslate args (MO_Ne W8)
-- Word8# unsigned ops
Word8ToWordOp -> \args -> opTranslate args (MO_UU_Conv W8 (wordWidth platform))
WordToWord8Op -> \args -> opTranslate args (MO_UU_Conv (wordWidth platform) W8)
Word8AddOp -> \args -> opTranslate args (MO_Add W8)
Word8SubOp -> \args -> opTranslate args (MO_Sub W8)
Word8MulOp -> \args -> opTranslate args (MO_Mul W8)
Word8QuotOp -> \args -> opTranslate args (MO_U_Quot W8)
Word8RemOp -> \args -> opTranslate args (MO_U_Rem W8)
Word8AndOp -> \args -> opTranslate args (MO_And W8)
Word8OrOp -> \args -> opTranslate args (MO_Or W8)
Word8XorOp -> \args -> opTranslate args (MO_Xor W8)
Word8NotOp -> \args -> opTranslate args (MO_Not W8)
Word8SllOp -> \args -> opTranslate args (MO_Shl W8)
Word8SrlOp -> \args -> opTranslate args (MO_U_Shr W8)
Word8EqOp -> \args -> opTranslate args (MO_Eq W8)
Word8GeOp -> \args -> opTranslate args (MO_U_Ge W8)
Word8GtOp -> \args -> opTranslate args (MO_U_Gt W8)
Word8LeOp -> \args -> opTranslate args (MO_U_Le W8)
Word8LtOp -> \args -> opTranslate args (MO_U_Lt W8)
Word8NeOp -> \args -> opTranslate args (MO_Ne W8)
-- Int16# signed ops
Int16ToIntOp -> \args -> opTranslate args (MO_SS_Conv W16 (wordWidth platform))
IntToInt16Op -> \args -> opTranslate args (MO_SS_Conv (wordWidth platform) W16)
Int16NegOp -> \args -> opTranslate args (MO_S_Neg W16)
Int16AddOp -> \args -> opTranslate args (MO_Add W16)
Int16SubOp -> \args -> opTranslate args (MO_Sub W16)
Int16MulOp -> \args -> opTranslate args (MO_Mul W16)
Int16QuotOp -> \args -> opTranslate args (MO_S_Quot W16)
Int16RemOp -> \args -> opTranslate args (MO_S_Rem W16)
Int16SllOp -> \args -> opTranslate args (MO_Shl W16)
Int16SraOp -> \args -> opTranslate args (MO_S_Shr W16)
Int16SrlOp -> \args -> opTranslate args (MO_U_Shr W16)
Int16EqOp -> \args -> opTranslate args (MO_Eq W16)
Int16GeOp -> \args -> opTranslate args (MO_S_Ge W16)
Int16GtOp -> \args -> opTranslate args (MO_S_Gt W16)
Int16LeOp -> \args -> opTranslate args (MO_S_Le W16)
Int16LtOp -> \args -> opTranslate args (MO_S_Lt W16)
Int16NeOp -> \args -> opTranslate args (MO_Ne W16)
-- Word16# unsigned ops
Word16ToWordOp -> \args -> opTranslate args (MO_UU_Conv W16 (wordWidth platform))
WordToWord16Op -> \args -> opTranslate args (MO_UU_Conv (wordWidth platform) W16)
Word16AddOp -> \args -> opTranslate args (MO_Add W16)
Word16SubOp -> \args -> opTranslate args (MO_Sub W16)
Word16MulOp -> \args -> opTranslate args (MO_Mul W16)
Word16QuotOp -> \args -> opTranslate args (MO_U_Quot W16)
Word16RemOp -> \args -> opTranslate args (MO_U_Rem W16)
Word16AndOp -> \args -> opTranslate args (MO_And W16)
Word16OrOp -> \args -> opTranslate args (MO_Or W16)
Word16XorOp -> \args -> opTranslate args (MO_Xor W16)
Word16NotOp -> \args -> opTranslate args (MO_Not W16)
Word16SllOp -> \args -> opTranslate args (MO_Shl W16)
Word16SrlOp -> \args -> opTranslate args (MO_U_Shr W16)
Word16EqOp -> \args -> opTranslate args (MO_Eq W16)
Word16GeOp -> \args -> opTranslate args (MO_U_Ge W16)
Word16GtOp -> \args -> opTranslate args (MO_U_Gt W16)
Word16LeOp -> \args -> opTranslate args (MO_U_Le W16)
Word16LtOp -> \args -> opTranslate args (MO_U_Lt W16)
Word16NeOp -> \args -> opTranslate args (MO_Ne W16)
-- Int32# signed ops
Int32ToIntOp -> \args -> opTranslate args (MO_SS_Conv W32 (wordWidth platform))
IntToInt32Op -> \args -> opTranslate args (MO_SS_Conv (wordWidth platform) W32)
Int32NegOp -> \args -> opTranslate args (MO_S_Neg W32)
Int32AddOp -> \args -> opTranslate args (MO_Add W32)
Int32SubOp -> \args -> opTranslate args (MO_Sub W32)
Int32MulOp -> \args -> opTranslate args (MO_Mul W32)
Int32QuotOp -> \args -> opTranslate args (MO_S_Quot W32)
Int32RemOp -> \args -> opTranslate args (MO_S_Rem W32)
Int32SllOp -> \args -> opTranslate args (MO_Shl W32)
Int32SraOp -> \args -> opTranslate args (MO_S_Shr W32)
Int32SrlOp -> \args -> opTranslate args (MO_U_Shr W32)
Int32EqOp -> \args -> opTranslate args (MO_Eq W32)
Int32GeOp -> \args -> opTranslate args (MO_S_Ge W32)
Int32GtOp -> \args -> opTranslate args (MO_S_Gt W32)
Int32LeOp -> \args -> opTranslate args (MO_S_Le W32)
Int32LtOp -> \args -> opTranslate args (MO_S_Lt W32)
Int32NeOp -> \args -> opTranslate args (MO_Ne W32)
-- Word32# unsigned ops
Word32ToWordOp -> \args -> opTranslate args (MO_UU_Conv W32 (wordWidth platform))
WordToWord32Op -> \args -> opTranslate args (MO_UU_Conv (wordWidth platform) W32)
Word32AddOp -> \args -> opTranslate args (MO_Add W32)
Word32SubOp -> \args -> opTranslate args (MO_Sub W32)
Word32MulOp -> \args -> opTranslate args (MO_Mul W32)
Word32QuotOp -> \args -> opTranslate args (MO_U_Quot W32)
Word32RemOp -> \args -> opTranslate args (MO_U_Rem W32)
Word32AndOp -> \args -> opTranslate args (MO_And W32)
Word32OrOp -> \args -> opTranslate args (MO_Or W32)
Word32XorOp -> \args -> opTranslate args (MO_Xor W32)
Word32NotOp -> \args -> opTranslate args (MO_Not W32)
Word32SllOp -> \args -> opTranslate args (MO_Shl W32)
Word32SrlOp -> \args -> opTranslate args (MO_U_Shr W32)
Word32EqOp -> \args -> opTranslate args (MO_Eq W32)
Word32GeOp -> \args -> opTranslate args (MO_U_Ge W32)
Word32GtOp -> \args -> opTranslate args (MO_U_Gt W32)
Word32LeOp -> \args -> opTranslate args (MO_U_Le W32)
Word32LtOp -> \args -> opTranslate args (MO_U_Lt W32)
Word32NeOp -> \args -> opTranslate args (MO_Ne W32)
-- Char# ops
CharEqOp -> \args -> opTranslate args (MO_Eq (wordWidth platform))
CharNeOp -> \args -> opTranslate args (MO_Ne (wordWidth platform))
CharGeOp -> \args -> opTranslate args (MO_U_Ge (wordWidth platform))
CharLeOp -> \args -> opTranslate args (MO_U_Le (wordWidth platform))
CharGtOp -> \args -> opTranslate args (MO_U_Gt (wordWidth platform))
CharLtOp -> \args -> opTranslate args (MO_U_Lt (wordWidth platform))
-- Double ops
DoubleEqOp -> \args -> opTranslate args (MO_F_Eq W64)
DoubleNeOp -> \args -> opTranslate args (MO_F_Ne W64)
DoubleGeOp -> \args -> opTranslate args (MO_F_Ge W64)
DoubleLeOp -> \args -> opTranslate args (MO_F_Le W64)
DoubleGtOp -> \args -> opTranslate args (MO_F_Gt W64)
DoubleLtOp -> \args -> opTranslate args (MO_F_Lt W64)
DoubleAddOp -> \args -> opTranslate args (MO_F_Add W64)
DoubleSubOp -> \args -> opTranslate args (MO_F_Sub W64)
DoubleMulOp -> \args -> opTranslate args (MO_F_Mul W64)
DoubleDivOp -> \args -> opTranslate args (MO_F_Quot W64)
DoubleNegOp -> \args -> opTranslate args (MO_F_Neg W64)
-- Float ops
FloatEqOp -> \args -> opTranslate args (MO_F_Eq W32)
FloatNeOp -> \args -> opTranslate args (MO_F_Ne W32)
FloatGeOp -> \args -> opTranslate args (MO_F_Ge W32)
FloatLeOp -> \args -> opTranslate args (MO_F_Le W32)
FloatGtOp -> \args -> opTranslate args (MO_F_Gt W32)
FloatLtOp -> \args -> opTranslate args (MO_F_Lt W32)
FloatAddOp -> \args -> opTranslate args (MO_F_Add W32)
FloatSubOp -> \args -> opTranslate args (MO_F_Sub W32)
FloatMulOp -> \args -> opTranslate args (MO_F_Mul W32)
FloatDivOp -> \args -> opTranslate args (MO_F_Quot W32)
FloatNegOp -> \args -> opTranslate args (MO_F_Neg W32)
-- Vector ops
(VecAddOp FloatVec n w) -> \args -> opTranslate args (MO_VF_Add n w)
(VecSubOp FloatVec n w) -> \args -> opTranslate args (MO_VF_Sub n w)
(VecMulOp FloatVec n w) -> \args -> opTranslate args (MO_VF_Mul n w)
(VecDivOp FloatVec n w) -> \args -> opTranslate args (MO_VF_Quot n w)
(VecQuotOp FloatVec _ _) -> \_ -> panic "unsupported primop"
(VecRemOp FloatVec _ _) -> \_ -> panic "unsupported primop"
(VecNegOp FloatVec n w) -> \args -> opTranslate args (MO_VF_Neg n w)
(VecAddOp IntVec n w) -> \args -> opTranslate args (MO_V_Add n w)
(VecSubOp IntVec n w) -> \args -> opTranslate args (MO_V_Sub n w)
(VecMulOp IntVec n w) -> \args -> opTranslate args (MO_V_Mul n w)
(VecDivOp IntVec _ _) -> \_ -> panic "unsupported primop"
(VecQuotOp IntVec n w) -> \args -> opTranslate args (MO_VS_Quot n w)
(VecRemOp IntVec n w) -> \args -> opTranslate args (MO_VS_Rem n w)
(VecNegOp IntVec n w) -> \args -> opTranslate args (MO_VS_Neg n w)
(VecAddOp WordVec n w) -> \args -> opTranslate args (MO_V_Add n w)
(VecSubOp WordVec n w) -> \args -> opTranslate args (MO_V_Sub n w)
(VecMulOp WordVec n w) -> \args -> opTranslate args (MO_V_Mul n w)
(VecDivOp WordVec _ _) -> \_ -> panic "unsupported primop"
(VecQuotOp WordVec n w) -> \args -> opTranslate args (MO_VU_Quot n w)
(VecRemOp WordVec n w) -> \args -> opTranslate args (MO_VU_Rem n w)
(VecNegOp WordVec _ _) -> \_ -> panic "unsupported primop"
-- Conversions
IntToDoubleOp -> \args -> opTranslate args (MO_SF_Conv (wordWidth platform) W64)
DoubleToIntOp -> \args -> opTranslate args (MO_FS_Conv W64 (wordWidth platform))
IntToFloatOp -> \args -> opTranslate args (MO_SF_Conv (wordWidth platform) W32)
FloatToIntOp -> \args -> opTranslate args (MO_FS_Conv W32 (wordWidth platform))
FloatToDoubleOp -> \args -> opTranslate args (MO_FF_Conv W32 W64)
DoubleToFloatOp -> \args -> opTranslate args (MO_FF_Conv W64 W32)
-- Word comparisons masquerading as more exotic things.
SameMutVarOp -> \args -> opTranslate args (mo_wordEq platform)
SameMVarOp -> \args -> opTranslate args (mo_wordEq platform)
SameIOPortOp -> \args -> opTranslate args (mo_wordEq platform)
SameMutableArrayOp -> \args -> opTranslate args (mo_wordEq platform)
SameMutableByteArrayOp -> \args -> opTranslate args (mo_wordEq platform)
SameMutableArrayArrayOp -> \args -> opTranslate args (mo_wordEq platform)
SameSmallMutableArrayOp -> \args -> opTranslate args (mo_wordEq platform)
SameTVarOp -> \args -> opTranslate args (mo_wordEq platform)
EqStablePtrOp -> \args -> opTranslate args (mo_wordEq platform)
-- See Note [Comparing stable names]
EqStableNameOp -> \args -> opTranslate args (mo_wordEq platform)
IntQuotRemOp -> \args -> opCallishHandledLater args $
if ncg && (x86ish || ppc) && not (quotRemCanBeOptimized args)
then Left (MO_S_QuotRem (wordWidth platform))
else Right (genericIntQuotRemOp (wordWidth platform))
Int8QuotRemOp -> \args -> opCallishHandledLater args $
if ncg && (x86ish || ppc) && not (quotRemCanBeOptimized args)
then Left (MO_S_QuotRem W8)
else Right (genericIntQuotRemOp W8)
Int16QuotRemOp -> \args -> opCallishHandledLater args $
if ncg && (x86ish || ppc) && not (quotRemCanBeOptimized args)
then Left (MO_S_QuotRem W16)
else Right (genericIntQuotRemOp W16)
Int32QuotRemOp -> \args -> opCallishHandledLater args $
if ncg && (x86ish || ppc) && not (quotRemCanBeOptimized args)
then Left (MO_S_QuotRem W32)
else Right (genericIntQuotRemOp W32)
WordQuotRemOp -> \args -> opCallishHandledLater args $
if ncg && (x86ish || ppc) && not (quotRemCanBeOptimized args)
then Left (MO_U_QuotRem (wordWidth platform))
else Right (genericWordQuotRemOp (wordWidth platform))
WordQuotRem2Op -> \args -> opCallishHandledLater args $
if (ncg && (x86ish || ppc)) || llvm
then Left (MO_U_QuotRem2 (wordWidth platform))
else Right (genericWordQuotRem2Op platform)
Word8QuotRemOp -> \args -> opCallishHandledLater args $
if ncg && (x86ish || ppc) && not (quotRemCanBeOptimized args)
then Left (MO_U_QuotRem W8)
else Right (genericWordQuotRemOp W8)
Word16QuotRemOp -> \args -> opCallishHandledLater args $
if ncg && (x86ish || ppc) && not (quotRemCanBeOptimized args)
then Left (MO_U_QuotRem W16)
else Right (genericWordQuotRemOp W16)
Word32QuotRemOp -> \args -> opCallishHandledLater args $
if ncg && (x86ish || ppc) && not (quotRemCanBeOptimized args)
then Left (MO_U_QuotRem W32)
else Right (genericWordQuotRemOp W32)
WordAdd2Op -> \args -> opCallishHandledLater args $
if (ncg && (x86ish || ppc)) || llvm
then Left (MO_Add2 (wordWidth platform))
else Right genericWordAdd2Op
WordAddCOp -> \args -> opCallishHandledLater args $
if (ncg && (x86ish || ppc)) || llvm
then Left (MO_AddWordC (wordWidth platform))
else Right genericWordAddCOp
WordSubCOp -> \args -> opCallishHandledLater args $
if (ncg && (x86ish || ppc)) || llvm
then Left (MO_SubWordC (wordWidth platform))
else Right genericWordSubCOp
IntAddCOp -> \args -> opCallishHandledLater args $
if (ncg && (x86ish || ppc)) || llvm
then Left (MO_AddIntC (wordWidth platform))
else Right genericIntAddCOp
IntSubCOp -> \args -> opCallishHandledLater args $
if (ncg && (x86ish || ppc)) || llvm
then Left (MO_SubIntC (wordWidth platform))
else Right genericIntSubCOp
WordMul2Op -> \args -> opCallishHandledLater args $
if ncg && (x86ish || ppc) || llvm
then Left (MO_U_Mul2 (wordWidth platform))
else Right genericWordMul2Op
IntMul2Op -> \args -> opCallishHandledLater args $
if ncg && x86ish || llvm
then Left (MO_S_Mul2 (wordWidth platform))
else Right genericIntMul2Op
FloatFabsOp -> \args -> opCallishHandledLater args $
if (ncg && x86ish || ppc) || llvm
then Left MO_F32_Fabs
else Right $ genericFabsOp W32
DoubleFabsOp -> \args -> opCallishHandledLater args $
if (ncg && x86ish || ppc) || llvm
then Left MO_F64_Fabs
else Right $ genericFabsOp W64
-- tagToEnum# is special: we need to pull the constructor
-- out of the table, and perform an appropriate return.
TagToEnumOp -> \[amode] -> PrimopCmmEmit_Internal $ \res_ty -> do
-- If you're reading this code in the attempt to figure
-- out why the compiler panic'ed here, it is probably because
-- you used tagToEnum# in a non-monomorphic setting, e.g.,
-- intToTg :: Enum a => Int -> a ; intToTg (I# x#) = tagToEnum# x#
-- That won't work.
let tycon = tyConAppTyCon res_ty
MASSERT(isEnumerationTyCon tycon)
platform <- getPlatform
pure [tagToClosure platform tycon amode]
-- Out of line primops.
-- TODO compiler need not know about these
UnsafeThawArrayOp -> alwaysExternal
CasArrayOp -> alwaysExternal
UnsafeThawSmallArrayOp -> alwaysExternal
CasSmallArrayOp -> alwaysExternal
NewPinnedByteArrayOp_Char -> alwaysExternal
NewAlignedPinnedByteArrayOp_Char -> alwaysExternal
MutableByteArrayIsPinnedOp -> alwaysExternal
DoubleDecode_2IntOp -> alwaysExternal
DoubleDecode_Int64Op -> alwaysExternal
FloatDecode_IntOp -> alwaysExternal
ByteArrayIsPinnedOp -> alwaysExternal
ShrinkMutableByteArrayOp_Char -> alwaysExternal
ResizeMutableByteArrayOp_Char -> alwaysExternal
ShrinkSmallMutableArrayOp_Char -> alwaysExternal
NewArrayArrayOp -> alwaysExternal
NewMutVarOp -> alwaysExternal
AtomicModifyMutVar2Op -> alwaysExternal
AtomicModifyMutVar_Op -> alwaysExternal
CasMutVarOp -> alwaysExternal
CatchOp -> alwaysExternal
RaiseOp -> alwaysExternal
RaiseIOOp -> alwaysExternal
MaskAsyncExceptionsOp -> alwaysExternal
MaskUninterruptibleOp -> alwaysExternal
UnmaskAsyncExceptionsOp -> alwaysExternal
MaskStatus -> alwaysExternal
AtomicallyOp -> alwaysExternal
RetryOp -> alwaysExternal
CatchRetryOp -> alwaysExternal
CatchSTMOp -> alwaysExternal
NewTVarOp -> alwaysExternal
ReadTVarOp -> alwaysExternal
ReadTVarIOOp -> alwaysExternal
WriteTVarOp -> alwaysExternal
NewMVarOp -> alwaysExternal
TakeMVarOp -> alwaysExternal
TryTakeMVarOp -> alwaysExternal
PutMVarOp -> alwaysExternal
TryPutMVarOp -> alwaysExternal
ReadMVarOp -> alwaysExternal
TryReadMVarOp -> alwaysExternal
IsEmptyMVarOp -> alwaysExternal
NewIOPortrOp -> alwaysExternal
ReadIOPortOp -> alwaysExternal
WriteIOPortOp -> alwaysExternal
DelayOp -> alwaysExternal
WaitReadOp -> alwaysExternal
WaitWriteOp -> alwaysExternal
ForkOp -> alwaysExternal
ForkOnOp -> alwaysExternal
KillThreadOp -> alwaysExternal
YieldOp -> alwaysExternal
LabelThreadOp -> alwaysExternal
IsCurrentThreadBoundOp -> alwaysExternal
NoDuplicateOp -> alwaysExternal
ThreadStatusOp -> alwaysExternal
MkWeakOp -> alwaysExternal
MkWeakNoFinalizerOp -> alwaysExternal
AddCFinalizerToWeakOp -> alwaysExternal
DeRefWeakOp -> alwaysExternal
FinalizeWeakOp -> alwaysExternal
MakeStablePtrOp -> alwaysExternal
DeRefStablePtrOp -> alwaysExternal
MakeStableNameOp -> alwaysExternal
CompactNewOp -> alwaysExternal
CompactResizeOp -> alwaysExternal
CompactContainsOp -> alwaysExternal
CompactContainsAnyOp -> alwaysExternal
CompactGetFirstBlockOp -> alwaysExternal
CompactGetNextBlockOp -> alwaysExternal
CompactAllocateBlockOp -> alwaysExternal
CompactFixupPointersOp -> alwaysExternal
CompactAdd -> alwaysExternal
CompactAddWithSharing -> alwaysExternal
CompactSize -> alwaysExternal
SeqOp -> alwaysExternal
GetSparkOp -> alwaysExternal
NumSparks -> alwaysExternal
DataToTagOp -> alwaysExternal
MkApUpd0_Op -> alwaysExternal
NewBCOOp -> alwaysExternal
UnpackClosureOp -> alwaysExternal
ClosureSizeOp -> alwaysExternal
WhereFromOp -> alwaysExternal
GetApStackValOp -> alwaysExternal
ClearCCSOp -> alwaysExternal
TraceEventOp -> alwaysExternal
TraceEventBinaryOp -> alwaysExternal
TraceMarkerOp -> alwaysExternal
SetThreadAllocationCounter -> alwaysExternal
KeepAliveOp -> panic "keepAlive# should have been eliminated in CorePrep"
where
profile = targetProfile dflags
platform = profilePlatform profile
result_info = getPrimOpResultInfo primop
opNop :: [CmmExpr] -> PrimopCmmEmit
opNop args = opIntoRegs $ \[res] -> emitAssign (CmmLocal res) arg
where [arg] = args
opNarrow
:: [CmmExpr]
-> (Width -> Width -> MachOp, Width)
-> PrimopCmmEmit
opNarrow args (mop, rep) = opIntoRegs $ \[res] -> emitAssign (CmmLocal res) $
CmmMachOp (mop rep (wordWidth platform)) [CmmMachOp (mop (wordWidth platform) rep) [arg]]
where [arg] = args
-- | These primops are implemented by CallishMachOps, because they sometimes
-- turn into foreign calls depending on the backend.
opCallish :: [CmmExpr] -> CallishMachOp -> PrimopCmmEmit
opCallish args prim = opIntoRegs $ \[res] -> emitPrimCall [res] prim args
opTranslate :: [CmmExpr] -> MachOp -> PrimopCmmEmit
opTranslate args mop = opIntoRegs $ \[res] -> do
let stmt = mkAssign (CmmLocal res) (CmmMachOp mop args)
emit stmt
-- | Basically a "manual" case, rather than one of the common repetitive forms
-- above. The results are a parameter to the returned function so we know the
-- choice of variant never depends on them.
opCallishHandledLater
:: [CmmExpr]
-> Either CallishMachOp GenericOp
-> PrimopCmmEmit
opCallishHandledLater args callOrNot = opIntoRegs $ \res0 -> case callOrNot of
Left op -> emit $ mkUnsafeCall (PrimTarget op) res0 args
Right gen -> gen res0 args
opIntoRegs
:: ([LocalReg] -- where to put the results
-> FCode ())
-> PrimopCmmEmit
opIntoRegs f = PrimopCmmEmit_Internal $ \res_ty -> do
regs <- case result_info of
ReturnsPrim VoidRep -> pure []
ReturnsPrim rep
-> do reg <- newTemp (primRepCmmType platform rep)
pure [reg]
ReturnsAlg tycon | isUnboxedTupleTyCon tycon
-> do (regs, _hints) <- newUnboxedTupleRegs res_ty
pure regs
_ -> panic "cgOpApp"
f regs
pure $ map (CmmReg . CmmLocal) regs
alwaysExternal = \_ -> PrimopCmmEmit_External
-- Note [QuotRem optimization]
-- ~~~~~~~~~~~~~~~~~~~~~~~~~~~
--
-- `quot` and `rem` with constant divisor can be implemented with fast bit-ops
-- (shift, .&.).
--
-- Currently we only support optimization (performed in GHC.Cmm.Opt) when the
-- constant is a power of 2. #9041 tracks the implementation of the general
-- optimization.
--
-- `quotRem` can be optimized in the same way. However as it returns two values,
-- it is implemented as a "callish" primop which is harder to match and
-- to transform later on. For simplicity, the current implementation detects cases
-- that can be optimized (see `quotRemCanBeOptimized`) and converts STG quotRem
-- primop into two CMM quot and rem primops.
quotRemCanBeOptimized = \case
[_, CmmLit (CmmInt n _) ] -> isJust (exactLog2 n)
_ -> False
ncg = backend dflags == NCG
llvm = backend dflags == LLVM
x86ish = case platformArch platform of
ArchX86 -> True
ArchX86_64 -> True
_ -> False
ppc = case platformArch platform of
ArchPPC -> True
ArchPPC_64 _ -> True
_ -> False
data PrimopCmmEmit
-- | Out of line fake primop that's actually just a foreign call to other
-- (presumably) C--.
= PrimopCmmEmit_External
-- | Real primop turned into inline C--.
| PrimopCmmEmit_Internal (Type -- the return type, some primops are specialized to it
-> FCode [CmmExpr]) -- just for TagToEnum for now
type GenericOp = [CmmFormal] -> [CmmActual] -> FCode ()
genericIntQuotRemOp :: Width -> GenericOp
genericIntQuotRemOp width [res_q, res_r] [arg_x, arg_y]
= emit $ mkAssign (CmmLocal res_q)
(CmmMachOp (MO_S_Quot width) [arg_x, arg_y]) <*>
mkAssign (CmmLocal res_r)
(CmmMachOp (MO_S_Rem width) [arg_x, arg_y])
genericIntQuotRemOp _ _ _ = panic "genericIntQuotRemOp"
genericWordQuotRemOp :: Width -> GenericOp
genericWordQuotRemOp width [res_q, res_r] [arg_x, arg_y]
= emit $ mkAssign (CmmLocal res_q)
(CmmMachOp (MO_U_Quot width) [arg_x, arg_y]) <*>
mkAssign (CmmLocal res_r)
(CmmMachOp (MO_U_Rem width) [arg_x, arg_y])
genericWordQuotRemOp _ _ _ = panic "genericWordQuotRemOp"
genericWordQuotRem2Op :: Platform -> GenericOp
genericWordQuotRem2Op platform [res_q, res_r] [arg_x_high, arg_x_low, arg_y]
= emit =<< f (widthInBits (wordWidth platform)) zero arg_x_high arg_x_low
where ty = cmmExprType platform arg_x_high
shl x i = CmmMachOp (MO_Shl (wordWidth platform)) [x, i]
shr x i = CmmMachOp (MO_U_Shr (wordWidth platform)) [x, i]
or x y = CmmMachOp (MO_Or (wordWidth platform)) [x, y]
ge x y = CmmMachOp (MO_U_Ge (wordWidth platform)) [x, y]
ne x y = CmmMachOp (MO_Ne (wordWidth platform)) [x, y]
minus x y = CmmMachOp (MO_Sub (wordWidth platform)) [x, y]
times x y = CmmMachOp (MO_Mul (wordWidth platform)) [x, y]
zero = lit 0
one = lit 1
negone = lit (fromIntegral (platformWordSizeInBits platform) - 1)
lit i = CmmLit (CmmInt i (wordWidth platform))
f :: Int -> CmmExpr -> CmmExpr -> CmmExpr -> FCode CmmAGraph
f 0 acc high _ = return (mkAssign (CmmLocal res_q) acc <*>
mkAssign (CmmLocal res_r) high)
f i acc high low =
do roverflowedBit <- newTemp ty
rhigh' <- newTemp ty
rhigh'' <- newTemp ty
rlow' <- newTemp ty
risge <- newTemp ty
racc' <- newTemp ty
let high' = CmmReg (CmmLocal rhigh')
isge = CmmReg (CmmLocal risge)
overflowedBit = CmmReg (CmmLocal roverflowedBit)
let this = catAGraphs
[mkAssign (CmmLocal roverflowedBit)
(shr high negone),
mkAssign (CmmLocal rhigh')
(or (shl high one) (shr low negone)),
mkAssign (CmmLocal rlow')
(shl low one),
mkAssign (CmmLocal risge)
(or (overflowedBit `ne` zero)
(high' `ge` arg_y)),
mkAssign (CmmLocal rhigh'')
(high' `minus` (arg_y `times` isge)),
mkAssign (CmmLocal racc')
(or (shl acc one) isge)]
rest <- f (i - 1) (CmmReg (CmmLocal racc'))
(CmmReg (CmmLocal rhigh''))
(CmmReg (CmmLocal rlow'))
return (this <*> rest)
genericWordQuotRem2Op _ _ _ = panic "genericWordQuotRem2Op"
genericWordAdd2Op :: GenericOp
genericWordAdd2Op [res_h, res_l] [arg_x, arg_y]
= do platform <- getPlatform
r1 <- newTemp (cmmExprType platform arg_x)
r2 <- newTemp (cmmExprType platform arg_x)
let topHalf x = CmmMachOp (MO_U_Shr (wordWidth platform)) [x, hww]
toTopHalf x = CmmMachOp (MO_Shl (wordWidth platform)) [x, hww]
bottomHalf x = CmmMachOp (MO_And (wordWidth platform)) [x, hwm]
add x y = CmmMachOp (MO_Add (wordWidth platform)) [x, y]
or x y = CmmMachOp (MO_Or (wordWidth platform)) [x, y]
hww = CmmLit (CmmInt (fromIntegral (widthInBits (halfWordWidth platform)))
(wordWidth platform))
hwm = CmmLit (CmmInt (halfWordMask platform) (wordWidth platform))
emit $ catAGraphs
[mkAssign (CmmLocal r1)
(add (bottomHalf arg_x) (bottomHalf arg_y)),
mkAssign (CmmLocal r2)
(add (topHalf (CmmReg (CmmLocal r1)))
(add (topHalf arg_x) (topHalf arg_y))),
mkAssign (CmmLocal res_h)
(topHalf (CmmReg (CmmLocal r2))),
mkAssign (CmmLocal res_l)
(or (toTopHalf (CmmReg (CmmLocal r2)))
(bottomHalf (CmmReg (CmmLocal r1))))]
genericWordAdd2Op _ _ = panic "genericWordAdd2Op"
-- | Implements branchless recovery of the carry flag @c@ by checking the
-- leftmost bits of both inputs @a@ and @b@ and result @r = a + b@:
--
-- @
-- c = a&b | (a|b)&~r
-- @
--
-- https://brodowsky.it-sky.net/2015/04/02/how-to-recover-the-carry-bit/
genericWordAddCOp :: GenericOp
genericWordAddCOp [res_r, res_c] [aa, bb]
= do platform <- getPlatform
emit $ catAGraphs [
mkAssign (CmmLocal res_r) (CmmMachOp (mo_wordAdd platform) [aa,bb]),
mkAssign (CmmLocal res_c) $
CmmMachOp (mo_wordUShr platform) [
CmmMachOp (mo_wordOr platform) [
CmmMachOp (mo_wordAnd platform) [aa,bb],
CmmMachOp (mo_wordAnd platform) [
CmmMachOp (mo_wordOr platform) [aa,bb],
CmmMachOp (mo_wordNot platform) [CmmReg (CmmLocal res_r)]
]
],
mkIntExpr platform (platformWordSizeInBits platform - 1)
]
]
genericWordAddCOp _ _ = panic "genericWordAddCOp"
-- | Implements branchless recovery of the carry flag @c@ by checking the
-- leftmost bits of both inputs @a@ and @b@ and result @r = a - b@:
--
-- @
-- c = ~a&b | (~a|b)&r
-- @
--
-- https://brodowsky.it-sky.net/2015/04/02/how-to-recover-the-carry-bit/
genericWordSubCOp :: GenericOp
genericWordSubCOp [res_r, res_c] [aa, bb]
= do platform <- getPlatform
emit $ catAGraphs [
mkAssign (CmmLocal res_r) (CmmMachOp (mo_wordSub platform) [aa,bb]),
mkAssign (CmmLocal res_c) $
CmmMachOp (mo_wordUShr platform) [
CmmMachOp (mo_wordOr platform) [
CmmMachOp (mo_wordAnd platform) [
CmmMachOp (mo_wordNot platform) [aa],
bb
],
CmmMachOp (mo_wordAnd platform) [
CmmMachOp (mo_wordOr platform) [
CmmMachOp (mo_wordNot platform) [aa],
bb
],
CmmReg (CmmLocal res_r)
]
],
mkIntExpr platform (platformWordSizeInBits platform - 1)
]
]
genericWordSubCOp _ _ = panic "genericWordSubCOp"
genericIntAddCOp :: GenericOp
genericIntAddCOp [res_r, res_c] [aa, bb]
{-
With some bit-twiddling, we can define int{Add,Sub}Czh portably in
C, and without needing any comparisons. This may not be the
fastest way to do it - if you have better code, please send it! --SDM
Return : r = a + b, c = 0 if no overflow, 1 on overflow.
We currently don't make use of the r value if c is != 0 (i.e.
overflow), we just convert to big integers and try again. This
could be improved by making r and c the correct values for
plugging into a new J#.
{ r = ((I_)(a)) + ((I_)(b)); \
c = ((StgWord)(~(((I_)(a))^((I_)(b))) & (((I_)(a))^r))) \
>> (BITS_IN (I_) - 1); \
}
Wading through the mass of bracketry, it seems to reduce to:
c = ( (~(a^b)) & (a^r) ) >>unsigned (BITS_IN(I_)-1)
-}
= do platform <- getPlatform
emit $ catAGraphs [
mkAssign (CmmLocal res_r) (CmmMachOp (mo_wordAdd platform) [aa,bb]),
mkAssign (CmmLocal res_c) $
CmmMachOp (mo_wordUShr platform) [
CmmMachOp (mo_wordAnd platform) [
CmmMachOp (mo_wordNot platform) [CmmMachOp (mo_wordXor platform) [aa,bb]],
CmmMachOp (mo_wordXor platform) [aa, CmmReg (CmmLocal res_r)]
],
mkIntExpr platform (platformWordSizeInBits platform - 1)
]
]
genericIntAddCOp _ _ = panic "genericIntAddCOp"
genericIntSubCOp :: GenericOp
genericIntSubCOp [res_r, res_c] [aa, bb]
{- Similarly:
#define subIntCzh(r,c,a,b) \
{ r = ((I_)(a)) - ((I_)(b)); \
c = ((StgWord)((((I_)(a))^((I_)(b))) & (((I_)(a))^r))) \
>> (BITS_IN (I_) - 1); \
}
c = ((a^b) & (a^r)) >>unsigned (BITS_IN(I_)-1)
-}
= do platform <- getPlatform
emit $ catAGraphs [
mkAssign (CmmLocal res_r) (CmmMachOp (mo_wordSub platform) [aa,bb]),
mkAssign (CmmLocal res_c) $
CmmMachOp (mo_wordUShr platform) [
CmmMachOp (mo_wordAnd platform) [
CmmMachOp (mo_wordXor platform) [aa,bb],
CmmMachOp (mo_wordXor platform) [aa, CmmReg (CmmLocal res_r)]
],
mkIntExpr platform (platformWordSizeInBits platform - 1)
]
]
genericIntSubCOp _ _ = panic "genericIntSubCOp"
genericWordMul2Op :: GenericOp
genericWordMul2Op [res_h, res_l] [arg_x, arg_y]
= do platform <- getPlatform
let t = cmmExprType platform arg_x
xlyl <- liftM CmmLocal $ newTemp t
xlyh <- liftM CmmLocal $ newTemp t
xhyl <- liftM CmmLocal $ newTemp t
r <- liftM CmmLocal $ newTemp t
-- This generic implementation is very simple and slow. We might
-- well be able to do better, but for now this at least works.
let topHalf x = CmmMachOp (MO_U_Shr (wordWidth platform)) [x, hww]
toTopHalf x = CmmMachOp (MO_Shl (wordWidth platform)) [x, hww]
bottomHalf x = CmmMachOp (MO_And (wordWidth platform)) [x, hwm]
add x y = CmmMachOp (MO_Add (wordWidth platform)) [x, y]
sum = foldl1 add
mul x y = CmmMachOp (MO_Mul (wordWidth platform)) [x, y]
or x y = CmmMachOp (MO_Or (wordWidth platform)) [x, y]
hww = CmmLit (CmmInt (fromIntegral (widthInBits (halfWordWidth platform)))
(wordWidth platform))
hwm = CmmLit (CmmInt (halfWordMask platform) (wordWidth platform))
emit $ catAGraphs
[mkAssign xlyl
(mul (bottomHalf arg_x) (bottomHalf arg_y)),
mkAssign xlyh
(mul (bottomHalf arg_x) (topHalf arg_y)),
mkAssign xhyl
(mul (topHalf arg_x) (bottomHalf arg_y)),
mkAssign r
(sum [topHalf (CmmReg xlyl),
bottomHalf (CmmReg xhyl),
bottomHalf (CmmReg xlyh)]),
mkAssign (CmmLocal res_l)
(or (bottomHalf (CmmReg xlyl))
(toTopHalf (CmmReg r))),
mkAssign (CmmLocal res_h)
(sum [mul (topHalf arg_x) (topHalf arg_y),
topHalf (CmmReg xhyl),
topHalf (CmmReg xlyh),
topHalf (CmmReg r)])]
genericWordMul2Op _ _ = panic "genericWordMul2Op"
genericIntMul2Op :: GenericOp
genericIntMul2Op [res_c, res_h, res_l] both_args@[arg_x, arg_y]
= do dflags <- getDynFlags
platform <- getPlatform
-- Implement algorithm from Hacker's Delight, 2nd edition, p.174
let t = cmmExprType platform arg_x
p <- newTemp t
-- 1) compute the multiplication as if numbers were unsigned
_ <- withSequel (AssignTo [p, res_l] False) $
cmmPrimOpApp dflags WordMul2Op both_args Nothing
-- 2) correct the high bits of the unsigned result
let carryFill x = CmmMachOp (MO_S_Shr ww) [x, wwm1]
sub x y = CmmMachOp (MO_Sub ww) [x, y]
and x y = CmmMachOp (MO_And ww) [x, y]
neq x y = CmmMachOp (MO_Ne ww) [x, y]
f x y = (carryFill x) `and` y
wwm1 = CmmLit (CmmInt (fromIntegral (widthInBits ww - 1)) ww)
rl x = CmmReg (CmmLocal x)
ww = wordWidth platform
emit $ catAGraphs
[ mkAssign (CmmLocal res_h) (rl p `sub` f arg_x arg_y `sub` f arg_y arg_x)
, mkAssign (CmmLocal res_c) (rl res_h `neq` carryFill (rl res_l))
]
genericIntMul2Op _ _ = panic "genericIntMul2Op"
-- This replicates what we had in libraries/base/GHC/Float.hs:
--
-- abs x | x == 0 = 0 -- handles (-0.0)
-- | x > 0 = x
-- | otherwise = negateFloat x
genericFabsOp :: Width -> GenericOp
genericFabsOp w [res_r] [aa]
= do platform <- getPlatform
let zero = CmmLit (CmmFloat 0 w)
eq x y = CmmMachOp (MO_F_Eq w) [x, y]
gt x y = CmmMachOp (MO_F_Gt w) [x, y]
neg x = CmmMachOp (MO_F_Neg w) [x]
g1 = catAGraphs [mkAssign (CmmLocal res_r) zero]
g2 = catAGraphs [mkAssign (CmmLocal res_r) aa]
res_t <- CmmLocal <$> newTemp (cmmExprType platform aa)
let g3 = catAGraphs [mkAssign res_t aa,
mkAssign (CmmLocal res_r) (neg (CmmReg res_t))]
g4 <- mkCmmIfThenElse (gt aa zero) g2 g3
emit =<< mkCmmIfThenElse (eq aa zero) g1 g4
genericFabsOp _ _ _ = panic "genericFabsOp"
-- Note [Comparing stable names]
-- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
--
-- A StableName# is actually a pointer to a stable name object (SNO)
-- containing an index into the stable name table (SNT). We
-- used to compare StableName#s by following the pointers to the
-- SNOs and checking whether they held the same SNT indices. However,
-- this is not necessary: there is a one-to-one correspondence
-- between SNOs and entries in the SNT, so simple pointer equality
-- does the trick.
------------------------------------------------------------------------------
-- Helpers for translating various minor variants of array indexing.
doIndexOffAddrOp :: Maybe MachOp
-> CmmType
-> [LocalReg]
-> [CmmExpr]
-> FCode ()
doIndexOffAddrOp maybe_post_read_cast rep [res] [addr,idx]
= mkBasicIndexedRead 0 maybe_post_read_cast rep res addr rep idx
doIndexOffAddrOp _ _ _ _
= panic "GHC.StgToCmm.Prim: doIndexOffAddrOp"
doIndexOffAddrOpAs :: Maybe MachOp
-> CmmType
-> CmmType
-> [LocalReg]
-> [CmmExpr]
-> FCode ()
doIndexOffAddrOpAs maybe_post_read_cast rep idx_rep [res] [addr,idx]
= mkBasicIndexedRead 0 maybe_post_read_cast rep res addr idx_rep idx
doIndexOffAddrOpAs _ _ _ _ _
= panic "GHC.StgToCmm.Prim: doIndexOffAddrOpAs"
doIndexByteArrayOp :: Maybe MachOp
-> CmmType
-> [LocalReg]
-> [CmmExpr]
-> FCode ()
doIndexByteArrayOp maybe_post_read_cast rep [res] [addr,idx]
= do profile <- getProfile
mkBasicIndexedRead (arrWordsHdrSize profile) maybe_post_read_cast rep res addr rep idx
doIndexByteArrayOp _ _ _ _
= panic "GHC.StgToCmm.Prim: doIndexByteArrayOp"
doIndexByteArrayOpAs :: Maybe MachOp
-> CmmType
-> CmmType
-> [LocalReg]
-> [CmmExpr]
-> FCode ()
doIndexByteArrayOpAs maybe_post_read_cast rep idx_rep [res] [addr,idx]
= do profile <- getProfile
mkBasicIndexedRead (arrWordsHdrSize profile) maybe_post_read_cast rep res addr idx_rep idx
doIndexByteArrayOpAs _ _ _ _ _
= panic "GHC.StgToCmm.Prim: doIndexByteArrayOpAs"
doReadPtrArrayOp :: LocalReg
-> CmmExpr
-> CmmExpr
-> FCode ()
doReadPtrArrayOp res addr idx
= do profile <- getProfile
platform <- getPlatform
mkBasicIndexedRead (arrPtrsHdrSize profile) Nothing (gcWord platform) res addr (gcWord platform) idx
doWriteOffAddrOp :: Maybe MachOp
-> CmmType
-> [LocalReg]
-> [CmmExpr]
-> FCode ()
doWriteOffAddrOp maybe_pre_write_cast idx_ty [] [addr,idx,val]
= mkBasicIndexedWrite 0 maybe_pre_write_cast addr idx_ty idx val
doWriteOffAddrOp _ _ _ _
= panic "GHC.StgToCmm.Prim: doWriteOffAddrOp"
doWriteByteArrayOp :: Maybe MachOp
-> CmmType
-> [LocalReg]
-> [CmmExpr]
-> FCode ()
doWriteByteArrayOp maybe_pre_write_cast idx_ty [] [addr,idx,val]
= do profile <- getProfile
mkBasicIndexedWrite (arrWordsHdrSize profile) maybe_pre_write_cast addr idx_ty idx val
doWriteByteArrayOp _ _ _ _
= panic "GHC.StgToCmm.Prim: doWriteByteArrayOp"
doWritePtrArrayOp :: CmmExpr
-> CmmExpr
-> CmmExpr
-> FCode ()
doWritePtrArrayOp addr idx val
= do profile <- getProfile
platform <- getPlatform
let ty = cmmExprType platform val
hdr_size = arrPtrsHdrSize profile
-- Update remembered set for non-moving collector
whenUpdRemSetEnabled
$ emitUpdRemSetPush (cmmLoadIndexOffExpr platform hdr_size ty addr ty idx)
-- This write barrier is to ensure that the heap writes to the object
-- referred to by val have happened before we write val into the array.
-- See #12469 for details.
emitPrimCall [] MO_WriteBarrier []
mkBasicIndexedWrite hdr_size Nothing addr ty idx val
emit (setInfo addr (CmmLit (CmmLabel mkMAP_DIRTY_infoLabel)))
-- the write barrier. We must write a byte into the mark table:
-- bits8[a + header_size + StgMutArrPtrs_size(a) + x >> N]
emit $ mkStore (
cmmOffsetExpr platform
(cmmOffsetExprW platform (cmmOffsetB platform addr hdr_size)
(loadArrPtrsSize profile addr))
(CmmMachOp (mo_wordUShr platform) [idx,
mkIntExpr platform (pc_MUT_ARR_PTRS_CARD_BITS (platformConstants platform))])
) (CmmLit (CmmInt 1 W8))
loadArrPtrsSize :: Profile -> CmmExpr -> CmmExpr
loadArrPtrsSize profile addr = CmmLoad (cmmOffsetB platform addr off) (bWord platform)
where off = fixedHdrSize profile + pc_OFFSET_StgMutArrPtrs_ptrs (profileConstants profile)
platform = profilePlatform profile
mkBasicIndexedRead :: ByteOff -- Initial offset in bytes
-> Maybe MachOp -- Optional result cast
-> CmmType -- Type of element we are accessing
-> LocalReg -- Destination
-> CmmExpr -- Base address
-> CmmType -- Type of element by which we are indexing
-> CmmExpr -- Index
-> FCode ()
mkBasicIndexedRead off Nothing ty res base idx_ty idx
= do platform <- getPlatform
emitAssign (CmmLocal res) (cmmLoadIndexOffExpr platform off ty base idx_ty idx)
mkBasicIndexedRead off (Just cast) ty res base idx_ty idx
= do platform <- getPlatform
emitAssign (CmmLocal res) (CmmMachOp cast [
cmmLoadIndexOffExpr platform off ty base idx_ty idx])
mkBasicIndexedWrite :: ByteOff -- Initial offset in bytes
-> Maybe MachOp -- Optional value cast
-> CmmExpr -- Base address
-> CmmType -- Type of element by which we are indexing
-> CmmExpr -- Index
-> CmmExpr -- Value to write
-> FCode ()
mkBasicIndexedWrite off Nothing base idx_ty idx val
= do platform <- getPlatform
emitStore (cmmIndexOffExpr platform off (typeWidth idx_ty) base idx) val
mkBasicIndexedWrite off (Just cast) base idx_ty idx val
= mkBasicIndexedWrite off Nothing base idx_ty idx (CmmMachOp cast [val])
-- ----------------------------------------------------------------------------
-- Misc utils
cmmIndexOffExpr :: Platform
-> ByteOff -- Initial offset in bytes
-> Width -- Width of element by which we are indexing
-> CmmExpr -- Base address
-> CmmExpr -- Index
-> CmmExpr
cmmIndexOffExpr platform off width base idx
= cmmIndexExpr platform width (cmmOffsetB platform base off) idx
cmmLoadIndexOffExpr :: Platform
-> ByteOff -- Initial offset in bytes
-> CmmType -- Type of element we are accessing
-> CmmExpr -- Base address
-> CmmType -- Type of element by which we are indexing
-> CmmExpr -- Index
-> CmmExpr
cmmLoadIndexOffExpr platform off ty base idx_ty idx
= CmmLoad (cmmIndexOffExpr platform off (typeWidth idx_ty) base idx) ty
setInfo :: CmmExpr -> CmmExpr -> CmmAGraph
setInfo closure_ptr info_ptr = mkStore closure_ptr info_ptr
------------------------------------------------------------------------------
-- Helpers for translating vector primops.
vecVmmType :: PrimOpVecCat -> Length -> Width -> CmmType
vecVmmType pocat n w = vec n (vecCmmCat pocat w)
vecCmmCat :: PrimOpVecCat -> Width -> CmmType
vecCmmCat IntVec = cmmBits
vecCmmCat WordVec = cmmBits
vecCmmCat FloatVec = cmmFloat
vecElemInjectCast :: Platform -> PrimOpVecCat -> Width -> Maybe MachOp
vecElemInjectCast _ FloatVec _ = Nothing
vecElemInjectCast platform IntVec W8 = Just (mo_WordTo8 platform)
vecElemInjectCast platform IntVec W16 = Just (mo_WordTo16 platform)
vecElemInjectCast platform IntVec W32 = Just (mo_WordTo32 platform)
vecElemInjectCast _ IntVec W64 = Nothing
vecElemInjectCast platform WordVec W8 = Just (mo_WordTo8 platform)
vecElemInjectCast platform WordVec W16 = Just (mo_WordTo16 platform)
vecElemInjectCast platform WordVec W32 = Just (mo_WordTo32 platform)
vecElemInjectCast _ WordVec W64 = Nothing
vecElemInjectCast _ _ _ = Nothing
vecElemProjectCast :: Platform -> PrimOpVecCat -> Width -> Maybe MachOp
vecElemProjectCast _ FloatVec _ = Nothing
vecElemProjectCast platform IntVec W8 = Just (mo_s_8ToWord platform)
vecElemProjectCast platform IntVec W16 = Just (mo_s_16ToWord platform)
vecElemProjectCast platform IntVec W32 = Just (mo_s_32ToWord platform)
vecElemProjectCast _ IntVec W64 = Nothing
vecElemProjectCast platform WordVec W8 = Just (mo_u_8ToWord platform)
vecElemProjectCast platform WordVec W16 = Just (mo_u_16ToWord platform)
vecElemProjectCast platform WordVec W32 = Just (mo_u_32ToWord platform)
vecElemProjectCast _ WordVec W64 = Nothing
vecElemProjectCast _ _ _ = Nothing
-- NOTE [SIMD Design for the future]
-- Check to make sure that we can generate code for the specified vector type
-- given the current set of dynamic flags.
-- Currently these checks are specific to x86 and x86_64 architecture.
-- This should be fixed!
-- In particular,
-- 1) Add better support for other architectures! (this may require a redesign)
-- 2) Decouple design choices from LLVM's pseudo SIMD model!
-- The high level LLVM naive rep makes per CPU family SIMD generation is own
-- optimization problem, and hides important differences in eg ARM vs x86_64 simd
-- 3) Depending on the architecture, the SIMD registers may also support general
-- computations on Float/Double/Word/Int scalars, but currently on
-- for example x86_64, we always put Word/Int (or sized) in GPR
-- (general purpose) registers. Would relaxing that allow for
-- useful optimization opportunities?
-- Phrased differently, it is worth experimenting with supporting
-- different register mapping strategies than we currently have, especially if
-- someday we want SIMD to be a first class denizen in GHC along with scalar
-- values!
-- The current design with respect to register mapping of scalars could
-- very well be the best,but exploring the design space and doing careful
-- measurements is the only way to validate that.
-- In some next generation CPU ISAs, notably RISC V, the SIMD extension
-- includes support for a sort of run time CPU dependent vectorization parameter,
-- where a loop may act upon a single scalar each iteration OR some 2,4,8 ...
-- element chunk! Time will tell if that direction sees wide adoption,
-- but it is from that context that unifying our handling of simd and scalars
-- may benefit. It is not likely to benefit current architectures, though
-- it may very well be a design perspective that helps guide improving the NCG.
checkVecCompatibility :: DynFlags -> PrimOpVecCat -> Length -> Width -> FCode ()
checkVecCompatibility dflags vcat l w = do
when (backend dflags /= LLVM) $
sorry $ unlines ["SIMD vector instructions require the LLVM back-end."
,"Please use -fllvm."]
check vecWidth vcat l w
where
platform = targetPlatform dflags
check :: Width -> PrimOpVecCat -> Length -> Width -> FCode ()
check W128 FloatVec 4 W32 | not (isSseEnabled platform) =
sorry $ "128-bit wide single-precision floating point " ++
"SIMD vector instructions require at least -msse."
check W128 _ _ _ | not (isSse2Enabled platform) =
sorry $ "128-bit wide integer and double precision " ++
"SIMD vector instructions require at least -msse2."
check W256 FloatVec _ _ | not (isAvxEnabled dflags) =
sorry $ "256-bit wide floating point " ++
"SIMD vector instructions require at least -mavx."
check W256 _ _ _ | not (isAvx2Enabled dflags) =
sorry $ "256-bit wide integer " ++
"SIMD vector instructions require at least -mavx2."
check W512 _ _ _ | not (isAvx512fEnabled dflags) =
sorry $ "512-bit wide " ++
"SIMD vector instructions require -mavx512f."
check _ _ _ _ = return ()
vecWidth = typeWidth (vecVmmType vcat l w)
------------------------------------------------------------------------------
-- Helpers for translating vector packing and unpacking.
doVecPackOp :: Maybe MachOp -- Cast from element to vector component
-> CmmType -- Type of vector
-> CmmExpr -- Initial vector
-> [CmmExpr] -- Elements
-> CmmFormal -- Destination for result
-> FCode ()
doVecPackOp maybe_pre_write_cast ty z es res = do
dst <- newTemp ty
emitAssign (CmmLocal dst) z
vecPack dst es 0
where
vecPack :: CmmFormal -> [CmmExpr] -> Int -> FCode ()
vecPack src [] _ =
emitAssign (CmmLocal res) (CmmReg (CmmLocal src))
vecPack src (e : es) i = do
dst <- newTemp ty
if isFloatType (vecElemType ty)
then emitAssign (CmmLocal dst) (CmmMachOp (MO_VF_Insert len wid)
[CmmReg (CmmLocal src), cast e, iLit])
else emitAssign (CmmLocal dst) (CmmMachOp (MO_V_Insert len wid)
[CmmReg (CmmLocal src), cast e, iLit])
vecPack dst es (i + 1)
where
-- vector indices are always 32-bits
iLit = CmmLit (CmmInt (toInteger i) W32)
cast :: CmmExpr -> CmmExpr
cast val = case maybe_pre_write_cast of
Nothing -> val
Just cast -> CmmMachOp cast [val]
len :: Length
len = vecLength ty
wid :: Width
wid = typeWidth (vecElemType ty)
doVecUnpackOp :: Maybe MachOp -- Cast from vector component to element result
-> CmmType -- Type of vector
-> CmmExpr -- Vector
-> [CmmFormal] -- Element results
-> FCode ()
doVecUnpackOp maybe_post_read_cast ty e res =
vecUnpack res 0
where
vecUnpack :: [CmmFormal] -> Int -> FCode ()
vecUnpack [] _ =
return ()
vecUnpack (r : rs) i = do
if isFloatType (vecElemType ty)
then emitAssign (CmmLocal r) (cast (CmmMachOp (MO_VF_Extract len wid)
[e, iLit]))
else emitAssign (CmmLocal r) (cast (CmmMachOp (MO_V_Extract len wid)
[e, iLit]))
vecUnpack rs (i + 1)
where
-- vector indices are always 32-bits
iLit = CmmLit (CmmInt (toInteger i) W32)
cast :: CmmExpr -> CmmExpr
cast val = case maybe_post_read_cast of
Nothing -> val
Just cast -> CmmMachOp cast [val]
len :: Length
len = vecLength ty
wid :: Width
wid = typeWidth (vecElemType ty)
doVecInsertOp :: Maybe MachOp -- Cast from element to vector component
-> CmmType -- Vector type
-> CmmExpr -- Source vector
-> CmmExpr -- Element
-> CmmExpr -- Index at which to insert element
-> CmmFormal -- Destination for result
-> FCode ()
doVecInsertOp maybe_pre_write_cast ty src e idx res = do
platform <- getPlatform
-- vector indices are always 32-bits
let idx' :: CmmExpr
idx' = CmmMachOp (MO_SS_Conv (wordWidth platform) W32) [idx]
if isFloatType (vecElemType ty)
then emitAssign (CmmLocal res) (CmmMachOp (MO_VF_Insert len wid) [src, cast e, idx'])
else emitAssign (CmmLocal res) (CmmMachOp (MO_V_Insert len wid) [src, cast e, idx'])
where
cast :: CmmExpr -> CmmExpr
cast val = case maybe_pre_write_cast of
Nothing -> val
Just cast -> CmmMachOp cast [val]
len :: Length
len = vecLength ty
wid :: Width
wid = typeWidth (vecElemType ty)
------------------------------------------------------------------------------
-- Helpers for translating prefetching.
-- | Translate byte array prefetch operations into proper primcalls.
doPrefetchByteArrayOp :: Int
-> [CmmExpr]
-> FCode ()
doPrefetchByteArrayOp locality [addr,idx]
= do profile <- getProfile
mkBasicPrefetch locality (arrWordsHdrSize profile) addr idx
doPrefetchByteArrayOp _ _
= panic "GHC.StgToCmm.Prim: doPrefetchByteArrayOp"
-- | Translate mutable byte array prefetch operations into proper primcalls.
doPrefetchMutableByteArrayOp :: Int
-> [CmmExpr]
-> FCode ()
doPrefetchMutableByteArrayOp locality [addr,idx]
= do profile <- getProfile
mkBasicPrefetch locality (arrWordsHdrSize profile) addr idx
doPrefetchMutableByteArrayOp _ _
= panic "GHC.StgToCmm.Prim: doPrefetchByteArrayOp"
-- | Translate address prefetch operations into proper primcalls.
doPrefetchAddrOp ::Int
-> [CmmExpr]
-> FCode ()
doPrefetchAddrOp locality [addr,idx]
= mkBasicPrefetch locality 0 addr idx
doPrefetchAddrOp _ _
= panic "GHC.StgToCmm.Prim: doPrefetchAddrOp"
-- | Translate value prefetch operations into proper primcalls.
doPrefetchValueOp :: Int
-> [CmmExpr]
-> FCode ()
doPrefetchValueOp locality [addr]
= do platform <- getPlatform
mkBasicPrefetch locality 0 addr (CmmLit (CmmInt 0 (wordWidth platform)))
doPrefetchValueOp _ _
= panic "GHC.StgToCmm.Prim: doPrefetchValueOp"
-- | helper to generate prefetch primcalls
mkBasicPrefetch :: Int -- Locality level 0-3
-> ByteOff -- Initial offset in bytes
-> CmmExpr -- Base address
-> CmmExpr -- Index
-> FCode ()
mkBasicPrefetch locality off base idx
= do platform <- getPlatform
emitPrimCall [] (MO_Prefetch_Data locality) [cmmIndexExpr platform W8 (cmmOffsetB platform base off) idx]
return ()
-- ----------------------------------------------------------------------------
-- Allocating byte arrays
-- | Takes a register to return the newly allocated array in and the
-- size of the new array in bytes. Allocates a new
-- 'MutableByteArray#'.
doNewByteArrayOp :: CmmFormal -> ByteOff -> FCode ()
doNewByteArrayOp res_r n = do
profile <- getProfile
platform <- getPlatform
let info_ptr = mkLblExpr mkArrWords_infoLabel
rep = arrWordsRep platform n
tickyAllocPrim (mkIntExpr platform (arrWordsHdrSize profile))
(mkIntExpr platform (nonHdrSize platform rep))
(zeroExpr platform)
let hdr_size = fixedHdrSize profile
base <- allocHeapClosure rep info_ptr cccsExpr
[ (mkIntExpr platform n,
hdr_size + pc_OFFSET_StgArrBytes_bytes (platformConstants platform))
]
emit $ mkAssign (CmmLocal res_r) base
-- ----------------------------------------------------------------------------
-- Comparing byte arrays
doCompareByteArraysOp :: LocalReg -> CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr
-> FCode ()
doCompareByteArraysOp res ba1 ba1_off ba2 ba2_off n = do
profile <- getProfile
platform <- getPlatform
ba1_p <- assignTempE $ cmmOffsetExpr platform (cmmOffsetB platform ba1 (arrWordsHdrSize profile)) ba1_off
ba2_p <- assignTempE $ cmmOffsetExpr platform (cmmOffsetB platform ba2 (arrWordsHdrSize profile)) ba2_off
-- short-cut in case of equal pointers avoiding a costly
-- subroutine call to the memcmp(3) routine; the Cmm logic below
-- results in assembly code being generated for
--
-- cmpPrefix10 :: ByteArray# -> ByteArray# -> Int#
-- cmpPrefix10 ba1 ba2 = compareByteArrays# ba1 0# ba2 0# 10#
--
-- that looks like
--
-- leaq 16(%r14),%rax
-- leaq 16(%rsi),%rbx
-- xorl %ecx,%ecx
-- cmpq %rbx,%rax
-- je l_ptr_eq
--
-- ; NB: the common case (unequal pointers) falls-through
-- ; the conditional jump, and therefore matches the
-- ; usual static branch prediction convention of modern cpus
--
-- subq $8,%rsp
-- movq %rbx,%rsi
-- movq %rax,%rdi
-- movl $10,%edx
-- xorl %eax,%eax
-- call memcmp
-- addq $8,%rsp
-- movslq %eax,%rax
-- movq %rax,%rcx
-- l_ptr_eq:
-- movq %rcx,%rbx
-- jmp *(%rbp)
l_ptr_eq <- newBlockId
l_ptr_ne <- newBlockId
emit (mkAssign (CmmLocal res) (zeroExpr platform))
emit (mkCbranch (cmmEqWord platform ba1_p ba2_p)
l_ptr_eq l_ptr_ne (Just False))
emitLabel l_ptr_ne
emitMemcmpCall res ba1_p ba2_p n 1
emitLabel l_ptr_eq
-- ----------------------------------------------------------------------------
-- Copying byte arrays
-- | Takes a source 'ByteArray#', an offset in the source array, a
-- destination 'MutableByteArray#', an offset into the destination
-- array, and the number of bytes to copy. Copies the given number of
-- bytes from the source array to the destination array.
doCopyByteArrayOp :: CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr
-> FCode ()
doCopyByteArrayOp = emitCopyByteArray copy
where
-- Copy data (we assume the arrays aren't overlapping since
-- they're of different types)
copy _src _dst dst_p src_p bytes align =
emitMemcpyCall dst_p src_p bytes align
-- | Takes a source 'MutableByteArray#', an offset in the source
-- array, a destination 'MutableByteArray#', an offset into the
-- destination array, and the number of bytes to copy. Copies the
-- given number of bytes from the source array to the destination
-- array.
doCopyMutableByteArrayOp :: CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr
-> FCode ()
doCopyMutableByteArrayOp = emitCopyByteArray copy
where
-- The only time the memory might overlap is when the two arrays
-- we were provided are the same array!
-- TODO: Optimize branch for common case of no aliasing.
copy src dst dst_p src_p bytes align = do
platform <- getPlatform
(moveCall, cpyCall) <- forkAltPair
(getCode $ emitMemmoveCall dst_p src_p bytes align)
(getCode $ emitMemcpyCall dst_p src_p bytes align)
emit =<< mkCmmIfThenElse (cmmEqWord platform src dst) moveCall cpyCall
emitCopyByteArray :: (CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr
-> Alignment -> FCode ())
-> CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr
-> FCode ()
emitCopyByteArray copy src src_off dst dst_off n = do
profile <- getProfile
platform <- getPlatform
let byteArrayAlignment = wordAlignment platform
srcOffAlignment = cmmExprAlignment src_off
dstOffAlignment = cmmExprAlignment dst_off
align = minimum [byteArrayAlignment, srcOffAlignment, dstOffAlignment]
dst_p <- assignTempE $ cmmOffsetExpr platform (cmmOffsetB platform dst (arrWordsHdrSize profile)) dst_off
src_p <- assignTempE $ cmmOffsetExpr platform (cmmOffsetB platform src (arrWordsHdrSize profile)) src_off
copy src dst dst_p src_p n align
-- | Takes a source 'ByteArray#', an offset in the source array, a
-- destination 'Addr#', and the number of bytes to copy. Copies the given
-- number of bytes from the source array to the destination memory region.
doCopyByteArrayToAddrOp :: CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr -> FCode ()
doCopyByteArrayToAddrOp src src_off dst_p bytes = do
-- Use memcpy (we are allowed to assume the arrays aren't overlapping)
profile <- getProfile
platform <- getPlatform
src_p <- assignTempE $ cmmOffsetExpr platform (cmmOffsetB platform src (arrWordsHdrSize profile)) src_off
emitMemcpyCall dst_p src_p bytes (mkAlignment 1)
-- | Takes a source 'MutableByteArray#', an offset in the source array, a
-- destination 'Addr#', and the number of bytes to copy. Copies the given
-- number of bytes from the source array to the destination memory region.
doCopyMutableByteArrayToAddrOp :: CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr
-> FCode ()
doCopyMutableByteArrayToAddrOp = doCopyByteArrayToAddrOp
-- | Takes a source 'Addr#', a destination 'MutableByteArray#', an offset into
-- the destination array, and the number of bytes to copy. Copies the given
-- number of bytes from the source memory region to the destination array.
doCopyAddrToByteArrayOp :: CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr -> FCode ()
doCopyAddrToByteArrayOp src_p dst dst_off bytes = do
-- Use memcpy (we are allowed to assume the arrays aren't overlapping)
profile <- getProfile
platform <- getPlatform
dst_p <- assignTempE $ cmmOffsetExpr platform (cmmOffsetB platform dst (arrWordsHdrSize profile)) dst_off
emitMemcpyCall dst_p src_p bytes (mkAlignment 1)
-- ----------------------------------------------------------------------------
-- Setting byte arrays
-- | Takes a 'MutableByteArray#', an offset into the array, a length,
-- and a byte, and sets each of the selected bytes in the array to the
-- character.
doSetByteArrayOp :: CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr
-> FCode ()
doSetByteArrayOp ba off len c = do
profile <- getProfile
platform <- getPlatform
let byteArrayAlignment = wordAlignment platform -- known since BA is allocated on heap
offsetAlignment = cmmExprAlignment off
align = min byteArrayAlignment offsetAlignment
p <- assignTempE $ cmmOffsetExpr platform (cmmOffsetB platform ba (arrWordsHdrSize profile)) off
emitMemsetCall p c len align
-- ----------------------------------------------------------------------------
-- Allocating arrays
-- | Allocate a new array.
doNewArrayOp :: CmmFormal -- ^ return register
-> SMRep -- ^ representation of the array
-> CLabel -- ^ info pointer
-> [(CmmExpr, ByteOff)] -- ^ header payload
-> WordOff -- ^ array size
-> CmmExpr -- ^ initial element
-> FCode ()
doNewArrayOp res_r rep info payload n init = do
profile <- getProfile
platform <- getPlatform
let info_ptr = mkLblExpr info
tickyAllocPrim (mkIntExpr platform (hdrSize profile rep))
(mkIntExpr platform (nonHdrSize platform rep))
(zeroExpr platform)
base <- allocHeapClosure rep info_ptr cccsExpr payload
arr <- CmmLocal `fmap` newTemp (bWord platform)
emit $ mkAssign arr base
-- Initialise all elements of the array
let mkOff off = cmmOffsetW platform (CmmReg arr) (hdrSizeW profile rep + off)
initialization = [ mkStore (mkOff off) init | off <- [0.. n - 1] ]
emit (catAGraphs initialization)
emit $ mkAssign (CmmLocal res_r) (CmmReg arr)
-- ----------------------------------------------------------------------------
-- Copying pointer arrays
-- EZY: This code has an unusually high amount of assignTemp calls, seen
-- nowhere else in the code generator. This is mostly because these
-- "primitive" ops result in a surprisingly large amount of code. It
-- will likely be worthwhile to optimize what is emitted here, so that
-- our optimization passes don't waste time repeatedly optimizing the
-- same bits of code.
-- More closely imitates 'assignTemp' from the old code generator, which
-- returns a CmmExpr rather than a LocalReg.
assignTempE :: CmmExpr -> FCode CmmExpr
assignTempE e = do
t <- assignTemp e
return (CmmReg (CmmLocal t))
-- | Takes a source 'Array#', an offset in the source array, a
-- destination 'MutableArray#', an offset into the destination array,
-- and the number of elements to copy. Copies the given number of
-- elements from the source array to the destination array.
doCopyArrayOp :: CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr -> WordOff
-> FCode ()
doCopyArrayOp = emitCopyArray copy
where
-- Copy data (we assume the arrays aren't overlapping since
-- they're of different types)
copy _src _dst dst_p src_p bytes =
do platform <- getPlatform
emitMemcpyCall dst_p src_p (mkIntExpr platform bytes)
(wordAlignment platform)
-- | Takes a source 'MutableArray#', an offset in the source array, a
-- destination 'MutableArray#', an offset into the destination array,
-- and the number of elements to copy. Copies the given number of
-- elements from the source array to the destination array.
doCopyMutableArrayOp :: CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr -> WordOff
-> FCode ()
doCopyMutableArrayOp = emitCopyArray copy
where
-- The only time the memory might overlap is when the two arrays
-- we were provided are the same array!
-- TODO: Optimize branch for common case of no aliasing.
copy src dst dst_p src_p bytes = do
platform <- getPlatform
(moveCall, cpyCall) <- forkAltPair
(getCode $ emitMemmoveCall dst_p src_p (mkIntExpr platform bytes)
(wordAlignment platform))
(getCode $ emitMemcpyCall dst_p src_p (mkIntExpr platform bytes)
(wordAlignment platform))
emit =<< mkCmmIfThenElse (cmmEqWord platform src dst) moveCall cpyCall
emitCopyArray :: (CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr -> ByteOff
-> FCode ()) -- ^ copy function
-> CmmExpr -- ^ source array
-> CmmExpr -- ^ offset in source array
-> CmmExpr -- ^ destination array
-> CmmExpr -- ^ offset in destination array
-> WordOff -- ^ number of elements to copy
-> FCode ()
emitCopyArray copy src0 src_off dst0 dst_off0 n =
when (n /= 0) $ do
profile <- getProfile
platform <- getPlatform
-- Passed as arguments (be careful)
src <- assignTempE src0
dst <- assignTempE dst0
dst_off <- assignTempE dst_off0
-- Nonmoving collector write barrier
emitCopyUpdRemSetPush platform (arrPtrsHdrSizeW profile) dst dst_off n
-- Set the dirty bit in the header.
emit (setInfo dst (CmmLit (CmmLabel mkMAP_DIRTY_infoLabel)))
dst_elems_p <- assignTempE $ cmmOffsetB platform dst
(arrPtrsHdrSize profile)
dst_p <- assignTempE $ cmmOffsetExprW platform dst_elems_p dst_off
src_p <- assignTempE $ cmmOffsetExprW platform
(cmmOffsetB platform src (arrPtrsHdrSize profile)) src_off
let bytes = wordsToBytes platform n
copy src dst dst_p src_p bytes
-- The base address of the destination card table
dst_cards_p <- assignTempE $ cmmOffsetExprW platform dst_elems_p
(loadArrPtrsSize profile dst)
emitSetCards dst_off dst_cards_p n
doCopySmallArrayOp :: CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr -> WordOff
-> FCode ()
doCopySmallArrayOp = emitCopySmallArray copy
where
-- Copy data (we assume the arrays aren't overlapping since
-- they're of different types)
copy _src _dst dst_p src_p bytes =
do platform <- getPlatform
emitMemcpyCall dst_p src_p (mkIntExpr platform bytes)
(wordAlignment platform)
doCopySmallMutableArrayOp :: CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr -> WordOff
-> FCode ()
doCopySmallMutableArrayOp = emitCopySmallArray copy
where
-- The only time the memory might overlap is when the two arrays
-- we were provided are the same array!
-- TODO: Optimize branch for common case of no aliasing.
copy src dst dst_p src_p bytes = do
platform <- getPlatform
(moveCall, cpyCall) <- forkAltPair
(getCode $ emitMemmoveCall dst_p src_p (mkIntExpr platform bytes)
(wordAlignment platform))
(getCode $ emitMemcpyCall dst_p src_p (mkIntExpr platform bytes)
(wordAlignment platform))
emit =<< mkCmmIfThenElse (cmmEqWord platform src dst) moveCall cpyCall
emitCopySmallArray :: (CmmExpr -> CmmExpr -> CmmExpr -> CmmExpr -> ByteOff
-> FCode ()) -- ^ copy function
-> CmmExpr -- ^ source array
-> CmmExpr -- ^ offset in source array
-> CmmExpr -- ^ destination array
-> CmmExpr -- ^ offset in destination array
-> WordOff -- ^ number of elements to copy
-> FCode ()
emitCopySmallArray copy src0 src_off dst0 dst_off n =
when (n /= 0) $ do
profile <- getProfile
platform <- getPlatform
-- Passed as arguments (be careful)
src <- assignTempE src0
dst <- assignTempE dst0
-- Nonmoving collector write barrier
emitCopyUpdRemSetPush platform (smallArrPtrsHdrSizeW profile) dst dst_off n
-- Set the dirty bit in the header.
emit (setInfo dst (CmmLit (CmmLabel mkSMAP_DIRTY_infoLabel)))
dst_p <- assignTempE $ cmmOffsetExprW platform
(cmmOffsetB platform dst (smallArrPtrsHdrSize profile)) dst_off
src_p <- assignTempE $ cmmOffsetExprW platform
(cmmOffsetB platform src (smallArrPtrsHdrSize profile)) src_off
let bytes = wordsToBytes platform n
copy src dst dst_p src_p bytes
-- | Takes an info table label, a register to return the newly
-- allocated array in, a source array, an offset in the source array,
-- and the number of elements to copy. Allocates a new array and
-- initializes it from the source array.
emitCloneArray :: CLabel -> CmmFormal -> CmmExpr -> CmmExpr -> WordOff
-> FCode ()
emitCloneArray info_p res_r src src_off n = do
profile <- getProfile
platform <- getPlatform
let info_ptr = mkLblExpr info_p
rep = arrPtrsRep platform n
tickyAllocPrim (mkIntExpr platform (arrPtrsHdrSize profile))
(mkIntExpr platform (nonHdrSize platform rep))
(zeroExpr platform)
let hdr_size = fixedHdrSize profile
constants = platformConstants platform
base <- allocHeapClosure rep info_ptr cccsExpr
[ (mkIntExpr platform n,
hdr_size + pc_OFFSET_StgMutArrPtrs_ptrs constants)
, (mkIntExpr platform (nonHdrSizeW rep),
hdr_size + pc_OFFSET_StgMutArrPtrs_size constants)
]
arr <- CmmLocal `fmap` newTemp (bWord platform)
emit $ mkAssign arr base
dst_p <- assignTempE $ cmmOffsetB platform (CmmReg arr)
(arrPtrsHdrSize profile)
src_p <- assignTempE $ cmmOffsetExprW platform src
(cmmAddWord platform
(mkIntExpr platform (arrPtrsHdrSizeW profile)) src_off)
emitMemcpyCall dst_p src_p (mkIntExpr platform (wordsToBytes platform n))
(wordAlignment platform)
emit $ mkAssign (CmmLocal res_r) (CmmReg arr)
-- | Takes an info table label, a register to return the newly
-- allocated array in, a source array, an offset in the source array,
-- and the number of elements to copy. Allocates a new array and
-- initializes it from the source array.
emitCloneSmallArray :: CLabel -> CmmFormal -> CmmExpr -> CmmExpr -> WordOff
-> FCode ()
emitCloneSmallArray info_p res_r src src_off n = do
profile <- getProfile
platform <- getPlatform
let info_ptr = mkLblExpr info_p
rep = smallArrPtrsRep n
tickyAllocPrim (mkIntExpr platform (smallArrPtrsHdrSize profile))
(mkIntExpr platform (nonHdrSize platform rep))
(zeroExpr platform)
let hdr_size = fixedHdrSize profile
base <- allocHeapClosure rep info_ptr cccsExpr
[ (mkIntExpr platform n,
hdr_size + pc_OFFSET_StgSmallMutArrPtrs_ptrs (platformConstants platform))
]
arr <- CmmLocal `fmap` newTemp (bWord platform)
emit $ mkAssign arr base
dst_p <- assignTempE $ cmmOffsetB platform (CmmReg arr)
(smallArrPtrsHdrSize profile)
src_p <- assignTempE $ cmmOffsetExprW platform src
(cmmAddWord platform
(mkIntExpr platform (smallArrPtrsHdrSizeW profile)) src_off)
emitMemcpyCall dst_p src_p (mkIntExpr platform (wordsToBytes platform n))
(wordAlignment platform)
emit $ mkAssign (CmmLocal res_r) (CmmReg arr)
-- | Takes and offset in the destination array, the base address of
-- the card table, and the number of elements affected (*not* the
-- number of cards). The number of elements may not be zero.
-- Marks the relevant cards as dirty.
emitSetCards :: CmmExpr -> CmmExpr -> WordOff -> FCode ()
emitSetCards dst_start dst_cards_start n = do
platform <- getPlatform
start_card <- assignTempE $ cardCmm platform dst_start
let end_card = cardCmm platform
(cmmSubWord platform
(cmmAddWord platform dst_start (mkIntExpr platform n))
(mkIntExpr platform 1))
emitMemsetCall (cmmAddWord platform dst_cards_start start_card)
(mkIntExpr platform 1)
(cmmAddWord platform (cmmSubWord platform end_card start_card) (mkIntExpr platform 1))
(mkAlignment 1) -- no alignment (1 byte)
-- Convert an element index to a card index
cardCmm :: Platform -> CmmExpr -> CmmExpr
cardCmm platform i =
cmmUShrWord platform i (mkIntExpr platform (pc_MUT_ARR_PTRS_CARD_BITS (platformConstants platform)))
------------------------------------------------------------------------------
-- SmallArray PrimOp implementations
doReadSmallPtrArrayOp :: LocalReg
-> CmmExpr
-> CmmExpr
-> FCode ()
doReadSmallPtrArrayOp res addr idx = do
profile <- getProfile
platform <- getPlatform
mkBasicIndexedRead (smallArrPtrsHdrSize profile) Nothing (gcWord platform) res addr
(gcWord platform) idx
doWriteSmallPtrArrayOp :: CmmExpr
-> CmmExpr
-> CmmExpr
-> FCode ()
doWriteSmallPtrArrayOp addr idx val = do
profile <- getProfile
platform <- getPlatform
let ty = cmmExprType platform val
-- Update remembered set for non-moving collector
tmp <- newTemp ty
mkBasicIndexedRead (smallArrPtrsHdrSize profile) Nothing ty tmp addr ty idx
whenUpdRemSetEnabled $ emitUpdRemSetPush (CmmReg (CmmLocal tmp))
emitPrimCall [] MO_WriteBarrier [] -- #12469
mkBasicIndexedWrite (smallArrPtrsHdrSize profile) Nothing addr ty idx val
emit (setInfo addr (CmmLit (CmmLabel mkSMAP_DIRTY_infoLabel)))
------------------------------------------------------------------------------
-- Atomic read-modify-write
-- | Emit an atomic modification to a byte array element. The result
-- reg contains that previous value of the element. Implies a full
-- memory barrier.
doAtomicByteArrayRMW
:: LocalReg -- ^ Result reg
-> AtomicMachOp -- ^ Atomic op (e.g. add)
-> CmmExpr -- ^ MutableByteArray#
-> CmmExpr -- ^ Index
-> CmmType -- ^ Type of element by which we are indexing
-> CmmExpr -- ^ Op argument (e.g. amount to add)
-> FCode ()
doAtomicByteArrayRMW res amop mba idx idx_ty n = do
profile <- getProfile
platform <- getPlatform
let width = typeWidth idx_ty
addr = cmmIndexOffExpr platform (arrWordsHdrSize profile)
width mba idx
doAtomicAddrRMW res amop addr idx_ty n
doAtomicAddrRMW
:: LocalReg -- ^ Result reg
-> AtomicMachOp -- ^ Atomic op (e.g. add)
-> CmmExpr -- ^ Addr#
-> CmmType -- ^ Pointed value type
-> CmmExpr -- ^ Op argument (e.g. amount to add)
-> FCode ()
doAtomicAddrRMW res amop addr ty n =
emitPrimCall
[ res ]
(MO_AtomicRMW (typeWidth ty) amop)
[ addr, n ]
-- | Emit an atomic read to a byte array that acts as a memory barrier.
doAtomicReadByteArray
:: LocalReg -- ^ Result reg
-> CmmExpr -- ^ MutableByteArray#
-> CmmExpr -- ^ Index
-> CmmType -- ^ Type of element by which we are indexing
-> FCode ()
doAtomicReadByteArray res mba idx idx_ty = do
profile <- getProfile
platform <- getPlatform
let width = typeWidth idx_ty
addr = cmmIndexOffExpr platform (arrWordsHdrSize profile)
width mba idx
doAtomicReadAddr res addr idx_ty
-- | Emit an atomic read to an address that acts as a memory barrier.
doAtomicReadAddr
:: LocalReg -- ^ Result reg
-> CmmExpr -- ^ Addr#
-> CmmType -- ^ Type of element by which we are indexing
-> FCode ()
doAtomicReadAddr res addr ty =
emitPrimCall
[ res ]
(MO_AtomicRead (typeWidth ty))
[ addr ]
-- | Emit an atomic write to a byte array that acts as a memory barrier.
doAtomicWriteByteArray
:: CmmExpr -- ^ MutableByteArray#
-> CmmExpr -- ^ Index
-> CmmType -- ^ Type of element by which we are indexing
-> CmmExpr -- ^ Value to write
-> FCode ()
doAtomicWriteByteArray mba idx idx_ty val = do
profile <- getProfile
platform <- getPlatform
let width = typeWidth idx_ty
addr = cmmIndexOffExpr platform (arrWordsHdrSize profile)
width mba idx
doAtomicWriteAddr addr idx_ty val
-- | Emit an atomic write to an address that acts as a memory barrier.
doAtomicWriteAddr
:: CmmExpr -- ^ Addr#
-> CmmType -- ^ Type of element by which we are indexing
-> CmmExpr -- ^ Value to write
-> FCode ()
doAtomicWriteAddr addr ty val =
emitPrimCall
[ {- no results -} ]
(MO_AtomicWrite (typeWidth ty))
[ addr, val ]
doCasByteArray
:: LocalReg -- ^ Result reg
-> CmmExpr -- ^ MutableByteArray#
-> CmmExpr -- ^ Index
-> CmmType -- ^ Type of element by which we are indexing
-> CmmExpr -- ^ Old value
-> CmmExpr -- ^ New value
-> FCode ()
doCasByteArray res mba idx idx_ty old new = do
profile <- getProfile
platform <- getPlatform
let width = (typeWidth idx_ty)
addr = cmmIndexOffExpr platform (arrWordsHdrSize profile)
width mba idx
emitPrimCall
[ res ]
(MO_Cmpxchg width)
[ addr, old, new ]
------------------------------------------------------------------------------
-- Helpers for emitting function calls
-- | Emit a call to @memcpy@.
emitMemcpyCall :: CmmExpr -> CmmExpr -> CmmExpr -> Alignment -> FCode ()
emitMemcpyCall dst src n align =
emitPrimCall
[ {-no results-} ]
(MO_Memcpy (alignmentBytes align))
[ dst, src, n ]
-- | Emit a call to @memmove@.
emitMemmoveCall :: CmmExpr -> CmmExpr -> CmmExpr -> Alignment -> FCode ()
emitMemmoveCall dst src n align =
emitPrimCall
[ {- no results -} ]
(MO_Memmove (alignmentBytes align))
[ dst, src, n ]
-- | Emit a call to @memset@. The second argument must fit inside an
-- unsigned char.
emitMemsetCall :: CmmExpr -> CmmExpr -> CmmExpr -> Alignment -> FCode ()
emitMemsetCall dst c n align =
emitPrimCall
[ {- no results -} ]
(MO_Memset (alignmentBytes align))
[ dst, c, n ]
emitMemcmpCall :: LocalReg -> CmmExpr -> CmmExpr -> CmmExpr -> Int -> FCode ()
emitMemcmpCall res ptr1 ptr2 n align = do
-- 'MO_Memcmp' is assumed to return an 32bit 'CInt' because all
-- code-gens currently call out to the @memcmp(3)@ C function.
-- This was easier than moving the sign-extensions into
-- all the code-gens.
platform <- getPlatform
let is32Bit = typeWidth (localRegType res) == W32
cres <- if is32Bit
then return res
else newTemp b32
emitPrimCall
[ cres ]
(MO_Memcmp align)
[ ptr1, ptr2, n ]
unless is32Bit $
emit $ mkAssign (CmmLocal res)
(CmmMachOp
(mo_s_32ToWord platform)
[(CmmReg (CmmLocal cres))])
emitBSwapCall :: LocalReg -> CmmExpr -> Width -> FCode ()
emitBSwapCall res x width =
emitPrimCall
[ res ]
(MO_BSwap width)
[ x ]
emitBRevCall :: LocalReg -> CmmExpr -> Width -> FCode ()
emitBRevCall res x width =
emitPrimCall
[ res ]
(MO_BRev width)
[ x ]
emitPopCntCall :: LocalReg -> CmmExpr -> Width -> FCode ()
emitPopCntCall res x width =
emitPrimCall
[ res ]
(MO_PopCnt width)
[ x ]
emitPdepCall :: LocalReg -> CmmExpr -> CmmExpr -> Width -> FCode ()
emitPdepCall res x y width =
emitPrimCall
[ res ]
(MO_Pdep width)
[ x, y ]
emitPextCall :: LocalReg -> CmmExpr -> CmmExpr -> Width -> FCode ()
emitPextCall res x y width =
emitPrimCall
[ res ]
(MO_Pext width)
[ x, y ]
emitClzCall :: LocalReg -> CmmExpr -> Width -> FCode ()
emitClzCall res x width =
emitPrimCall
[ res ]
(MO_Clz width)
[ x ]
emitCtzCall :: LocalReg -> CmmExpr -> Width -> FCode ()
emitCtzCall res x width =
emitPrimCall
[ res ]
(MO_Ctz width)
[ x ]
---------------------------------------------------------------------------
-- Pushing to the update remembered set
---------------------------------------------------------------------------
-- | Push a range of pointer-array elements that are about to be copied over to
-- the update remembered set.
emitCopyUpdRemSetPush :: Platform
-> WordOff -- ^ array header size
-> CmmExpr -- ^ destination array
-> CmmExpr -- ^ offset in destination array (in words)
-> Int -- ^ number of elements to copy
-> FCode ()
emitCopyUpdRemSetPush _platform _hdr_size _dst _dst_off 0 = return ()
emitCopyUpdRemSetPush platform hdr_size dst dst_off n =
whenUpdRemSetEnabled $ do
updfr_off <- getUpdFrameOff
graph <- mkCall lbl (NativeNodeCall,NativeReturn) [] args updfr_off []
emit graph
where
lbl = mkLblExpr $ mkPrimCallLabel
$ PrimCall (fsLit "stg_copyArray_barrier") rtsUnit
args =
[ mkIntExpr platform hdr_size
, dst
, dst_off
, mkIntExpr platform n
]
|