-----------------------------------------------------------------------
--- $Id: primops.txt.pp,v 1.7 2001/10/16 13:31:56 simonmar Exp $
+-- $Id: primops.txt.pp,v 1.28 2003/07/03 15:14:56 sof Exp $
--
-- Primitive Operations
--
--
-- To add a new primop, you currently need to update the following files:
--
--- - this file (ghc/compiler/prelude/primops.txt), which includes
+-- - this file (ghc/compiler/prelude/primops.txt.pp), which includes
-- the type of the primop, and various other properties (its
-- strictness attributes, whether it is defined as a macro
-- or as out-of-line code, etc.)
--
--- - ghc/lib/std/PrelGHC.hi-boot, to declare the primop
---
-- - if the primop is inline (i.e. a macro), then:
--- ghc/includes/PrimOps.h
--- ghc/compiler/nativeGen/StixPrim.lhs
--- ghc/compiler/nativeGen/MachCode.lhs (if implementation is machine-dependent)
+-- ghc/compiler/AbsCUtils.lhs (dscCOpStmt)
+-- defines the translation of the primop into simpler
+-- abstract C operations.
--
-- - or, for an out-of-line primop:
-- ghc/includes/PrimOps.h (just add the declaration)
-- ghc/rts/PrimOps.hc (define it here)
+-- ghc/rts/Linker.c (declare the symbol for GHCi)
--
-- - the User's Guide
--
commutable = False
needs_wrapper = False
can_fail = False
- strictness = { \ arity -> StrictnessInfo (replicate arity wwPrim) False }
+ strictness = { \ arity -> mkStrictSig (mkTopDmdType (replicate arity lazyDmd) TopRes) }
usage = { nomangle other }
-- Currently, documentation is produced using latex, so contents of
primop IntMulOp "*#"
Dyadic Int# -> Int# -> Int#
+ {Low word of signed integer multiply.}
+ with commutable = True
+
+primop IntMulMayOfloOp "mulIntMayOflo#"
+ Dyadic Int# -> Int# -> Int#
+ {Return non-zero if there is any possibility that the upper word of a
+ signed integer multiply might contain useful information. Return
+ zero only if you are completely sure that no overflow can occur.
+ On a 32-bit platform, the recommmended implementation is to do a
+ 32 x 32 -> 64 signed multiply, and subtract result[63:32] from
+ (result[31] >>signed 31). If this is zero, meaning that the
+ upper word is merely a sign extension of the lower one, no
+ overflow can occur.
+
+ On a 64-bit platform it is not always possible to
+ acquire the top 64 bits of the result. Therefore, a recommended
+ implementation is to take the absolute value of both operands, and
+ return 0 iff bits[63:31] of them are zero, since that means that their
+ magnitudes fit within 31 bits, so the magnitude of the product must fit
+ into 62 bits.
+
+ If in doubt, return non-zero, but do make an effort to create the
+ correct answer for small args, since otherwise the performance of
+ (*) :: Integer -> Integer -> Integer will be poor.
+ }
with commutable = True
primop IntQuotOp "quotInt#" Dyadic
with can_fail = True
primop IntGcdOp "gcdInt#" Dyadic Int# -> Int# -> Int#
+ with out_of_line = True
+
primop IntNegOp "negateInt#" Monadic Int# -> Int#
primop IntAddCOp "addIntC#" GenPrimOp Int# -> Int# -> (# Int#, Int# #)
- {Add with carry. First member of result is (wrapped) sum; second member is 0 iff no overflow occured.}
+ {Add with carry. First member of result is (wrapped) sum;
+ second member is 0 iff no overflow occured.}
primop IntSubCOp "subIntC#" GenPrimOp Int# -> Int# -> (# Int#, Int# #)
- {Subtract with carry. First member of result is (wrapped) difference; second member is 0 iff no overflow occured.}
-primop IntMulCOp "mulIntC#" GenPrimOp Int# -> Int# -> (# Int#, Int# #)
- {Multiply with carry. First member of result is (wrapped) product; second member is 0 iff no overflow occured.}
+ {Subtract with carry. First member of result is (wrapped) difference;
+ second member is 0 iff no overflow occured.}
+
primop IntGtOp ">#" Compare Int# -> Int# -> Bool
primop IntGeOp ">=#" Compare Int# -> Int# -> Bool
GenPrimOp Int# -> (# Int#, ByteArr# #)
with out_of_line = True
-primop ISllOp "iShiftL#" GenPrimOp Int# -> Int# -> Int#
- {Shift left. Return 0 if shifted by more than size of an Int\#.}
-primop ISraOp "iShiftRA#" GenPrimOp Int# -> Int# -> Int#
- {Shift right arithemetic. Return 0 if shifted by more than size of an Int\#.}
-primop ISrlOp "iShiftRL#" GenPrimOp Int# -> Int# -> Int#
- {Shift right logical. Return 0 if shifted by more than size of an Int\#.}
+primop ISllOp "uncheckedIShiftL#" GenPrimOp Int# -> Int# -> Int#
+ {Shift left. Result undefined if shift amount is not
+ in the range 0 to word size - 1 inclusive.}
+primop ISraOp "uncheckedIShiftRA#" GenPrimOp Int# -> Int# -> Int#
+ {Shift right arithmetic. Result undefined if shift amount is not
+ in the range 0 to word size - 1 inclusive.}
+primop ISrlOp "uncheckedIShiftRL#" GenPrimOp Int# -> Int# -> Int#
+ {Shift right logical. Result undefined if shift amount is not
+ in the range 0 to word size - 1 inclusive.}
------------------------------------------------------------------------
section "Word#"
primop NotOp "not#" Monadic Word# -> Word#
-primop SllOp "shiftL#" GenPrimOp Word# -> Int# -> Word#
- {Shift left logical. Return 0 if shifted by more than number of bits in a Word\#.}
-primop SrlOp "shiftRL#" GenPrimOp Word# -> Int# -> Word#
- {Shift right logical. Return 0 if shifted by more than number of bits in a Word\#.}
+primop SllOp "uncheckedShiftL#" GenPrimOp Word# -> Int# -> Word#
+ {Shift left logical. Result undefined if shift amount is not
+ in the range 0 to word size - 1 inclusive.}
+primop SrlOp "uncheckedShiftRL#" GenPrimOp Word# -> Int# -> Word#
+ {Shift right logical. Result undefined if shift amount is not
+ in the range 0 to word size - 1 inclusive.}
primop Word2IntOp "word2Int#" GenPrimOp Word# -> Int#
implemented via the GMP package. An integer is represented as a pair
consisting of an Int\# representing the number of 'limbs' in use and
the sign, and a ByteArr\# containing the 'limbs' themselves. Such pairs
-are returned as unboxed pairs, but must be passed as separate components.}
+are returned as unboxed pairs, but must be passed as separate
+components.
+
+For .NET these operations are implemented by foreign imports, so the
+primops are omitted.}
------------------------------------------------------------------------
+#ifndef ILX
+
primop IntegerAddOp "plusInteger#" GenPrimOp
Int# -> ByteArr# -> Int# -> ByteArr# -> (# Int#, ByteArr# #)
with commutable = True
primop IntegerIntGcdOp "gcdIntegerInt#" GenPrimOp
Int# -> ByteArr# -> Int# -> Int#
{Greatest common divisor, where second argument is an ordinary Int\#.}
- -- with commutable = True (surely not? APT 8/01)
+ with out_of_line = True
primop IntegerDivExactOp "divExactInteger#" GenPrimOp
Int# -> ByteArr# -> Int# -> ByteArr# -> (# Int#, ByteArr# #)
Int# -> ByteArr# -> Int# -> ByteArr# -> Int#
{Returns -1,0,1 according as first argument is less than, equal to, or greater than second argument.}
with needs_wrapper = True
+ out_of_line = True
primop IntegerCmpIntOp "cmpIntegerInt#" GenPrimOp
Int# -> ByteArr# -> Int# -> Int#
{Returns -1,0,1 according as first argument is less than, equal to, or greater than second argument, which
is an ordinary Int\#.}
with needs_wrapper = True
+ out_of_line = True
primop IntegerQuotRemOp "quotRemInteger#" GenPrimOp
Int# -> ByteArr# -> Int# -> ByteArr# -> (# Int#, ByteArr#, Int#, ByteArr# #)
primop Integer2IntOp "integer2Int#" GenPrimOp
Int# -> ByteArr# -> Int#
with needs_wrapper = True
+ out_of_line = True
primop Integer2WordOp "integer2Word#" GenPrimOp
Int# -> ByteArr# -> Word#
with needs_wrapper = True
+ out_of_line = True
#if WORD_SIZE_IN_BITS < 32
primop IntegerToInt32Op "integerToInt32#" GenPrimOp
Int# -> ByteArr# -> Word32#
#endif
-#if WORD_SIZE_IN_BITS < 64
-primop IntegerToInt64Op "integerToInt64#" GenPrimOp
- Int# -> ByteArr# -> Int64#
-
-primop IntegerToWord64Op "integerToWord64#" GenPrimOp
- Int# -> ByteArr# -> Word64#
-#endif
-
primop IntegerAndOp "andInteger#" GenPrimOp
Int# -> ByteArr# -> Int# -> ByteArr# -> (# Int#, ByteArr# #)
with out_of_line = True
Int# -> ByteArr# -> (# Int#, ByteArr# #)
with out_of_line = True
+#endif /* ndef ILX */
------------------------------------------------------------------------
section "Double#"
in the specified state thread,
with each element containing the specified initial value.}
with
- strictness = { \ arity -> StrictnessInfo [wwPrim, wwLazy, wwPrim] False }
usage = { mangle NewArrayOp [mkP, mkM, mkP] mkM }
out_of_line = True
{Write to specified index of mutable array.}
with
usage = { mangle WriteArrayOp [mkM, mkP, mkM, mkP] mkR }
- strictness = { \ arity -> StrictnessInfo [wwPrim, wwPrim, wwLazy, wwPrim] False }
has_side_effects = True
primop IndexArrayOp "indexArray#" GenPrimOp
------------------------------------------------------------------------
section "Addr#"
{Addr\# is an arbitrary machine address assumed to point outside
- the garbage-collected heap.}
+ the garbage-collected heap.
+
+ NB: {\tt nullAddr\#::Addr\#} is not a primop, but is defined in MkId.lhs.
+ It is the null address.}
------------------------------------------------------------------------
-primop AddrNullOp "nullAddr#" GenPrimOp Int# -> Addr#
- {Returns null address. Argument is ignored (nullary primops
- don't quite work!)}
primop AddrAddOp "plusAddr#" GenPrimOp Addr# -> Int# -> Addr#
primop AddrSubOp "minusAddr#" GenPrimOp Addr# -> Addr# -> Int#
{Result is meaningless if two Addr\#s are so far apart that their
o -> State# RealWorld -> State# RealWorld
with
has_side_effects = True
- strictness = { \ arity -> StrictnessInfo [wwLazy, wwPrim] False }
primop EqForeignObj "eqForeignObj#" GenPrimOp
ForeignObj# -> ForeignObj# -> Bool
{Create MutVar\# with specified initial value in specified state thread.}
with
usage = { mangle NewMutVarOp [mkM, mkP] mkM }
- strictness = { \ arity -> StrictnessInfo [wwLazy, wwPrim] False }
out_of_line = True
primop ReadMutVarOp "readMutVar#" GenPrimOp
MutVar# s a -> a -> State# s -> State# s
{Write contents of MutVar\#.}
with
- strictness = { \ arity -> StrictnessInfo [wwPrim, wwLazy, wwPrim] False }
usage = { mangle WriteMutVarOp [mkM, mkM, mkP] mkR }
has_side_effects = True
with
usage = { mangle SameMutVarOp [mkP, mkP] mkM }
+-- not really the right type, but we don't know about pairs here. The
+-- correct type is
+--
+-- MutVar# s a -> (a -> (a,b)) -> State# s -> (# State# s, b #)
+--
+primop AtomicModifyMutVarOp "atomicModifyMutVar#" GenPrimOp
+ MutVar# s a -> (a -> b) -> State# s -> (# State# s, c #)
+ with
+ usage = { mangle AtomicModifyMutVarOp [mkP, mkM, mkP] mkM }
+ has_side_effects = True
+ out_of_line = True
+
------------------------------------------------------------------------
section "Exceptions"
------------------------------------------------------------------------
-> State# RealWorld
-> (# State# RealWorld, a #)
with
- strictness = { \ arity -> StrictnessInfo [wwLazy, wwLazy, wwPrim] False }
-- Catch is actually strict in its first argument
-- but we don't want to tell the strictness
-- analyser about that!
primop RaiseOp "raise#" GenPrimOp
a -> b
with
- strictness = { \ arity -> StrictnessInfo [wwLazy] True }
- -- NB: True => result is bottom
+ strictness = { \ arity -> mkStrictSig (mkTopDmdType [lazyDmd] BotRes) }
+ -- NB: result is bottom
usage = { mangle RaiseOp [mkM] mkM }
out_of_line = True
+-- raiseIO# needs to be a primop, because exceptions in the IO monad
+-- must be *precise* - we don't want the strictness analyser turning
+-- one kind of bottom into another, as it is allowed to do in pure code.
+
+primop RaiseIOOp "raiseIO#" GenPrimOp
+ a -> State# RealWorld -> (# State# RealWorld, b #)
+ with
+ out_of_line = True
+
primop BlockAsyncExceptionsOp "blockAsyncExceptions#" GenPrimOp
(State# RealWorld -> (# State# RealWorld, a #))
-> (State# RealWorld -> (# State# RealWorld, a #))
with
- strictness = { \ arity -> StrictnessInfo [wwLazy, wwPrim] False }
out_of_line = True
primop UnblockAsyncExceptionsOp "unblockAsyncExceptions#" GenPrimOp
(State# RealWorld -> (# State# RealWorld, a #))
-> (State# RealWorld -> (# State# RealWorld, a #))
with
- strictness = { \ arity -> StrictnessInfo [wwLazy, wwPrim] False }
out_of_line = True
------------------------------------------------------------------------
{If mvar is full, block until it becomes empty.
Then store value arg as its new contents.}
with
- strictness = { \ arity -> StrictnessInfo [wwPrim, wwLazy, wwPrim] False }
usage = { mangle PutMVarOp [mkM, mkM, mkP] mkR }
has_side_effects = True
out_of_line = True
{If mvar is full, immediately return with integer 0.
Otherwise, store value arg as mvar's new contents, and return with integer 1.}
with
- strictness = { \ arity -> StrictnessInfo [wwPrim, wwLazy, wwPrim] False }
usage = { mangle TryPutMVarOp [mkM, mkM, mkP] mkR }
has_side_effects = True
out_of_line = True
{Return 1 if mvar is empty; 0 otherwise.}
with
usage = { mangle IsEmptyMVarOp [mkP, mkP] mkM }
-
+ out_of_line = True
------------------------------------------------------------------------
section "Delay/wait operations"
has_side_effects = True
out_of_line = True
+#ifdef mingw32_TARGET_OS
+primop AsyncReadOp "asyncRead#" GenPrimOp
+ Int# -> Int# -> Int# -> Addr# -> State# RealWorld-> (# State# RealWorld, Int#, Int# #)
+ {Asynchronously read bytes from specified file descriptor.}
+ with
+ needs_wrapper = True
+ has_side_effects = True
+ out_of_line = True
+
+primop AsyncWriteOp "asyncWrite#" GenPrimOp
+ Int# -> Int# -> Int# -> Addr# -> State# RealWorld-> (# State# RealWorld, Int#, Int# #)
+ {Asynchronously write bytes from specified file descriptor.}
+ with
+ needs_wrapper = True
+ has_side_effects = True
+ out_of_line = True
+
+primop AsyncDoProcOp "asyncDoProc#" GenPrimOp
+ Addr# -> Addr# -> State# RealWorld-> (# State# RealWorld, Int#, Int# #)
+ {Asynchronously perform procedure (first arg), passing it 2nd arg.}
+ with
+ needs_wrapper = True
+ has_side_effects = True
+ out_of_line = True
+
+#endif
+
------------------------------------------------------------------------
section "Concurrency primitives"
{(In a non-concurrent implementation, ThreadId\# can be as singleton
a -> State# RealWorld -> (# State# RealWorld, ThreadId# #)
with
usage = { mangle ForkOp [mkO, mkP] mkR }
- strictness = { \ arity -> StrictnessInfo [wwLazy, wwPrim] False }
+ has_side_effects = True
+ out_of_line = True
+
+primop ForkProcessOp "forkProcess#" GenPrimOp
+ State# RealWorld -> (# State# RealWorld, Int# #)
+ with
has_side_effects = True
out_of_line = True
out_of_line = True
primop MyThreadIdOp "myThreadId#" GenPrimOp
- State# RealWorld -> (# State# RealWorld, ThreadId# #)
+ State# RealWorld -> (# State# RealWorld, ThreadId# #)
+ with
+ out_of_line = True
+
+primop LabelThreadOp "labelThread#" GenPrimOp
+ ThreadId# -> Addr# -> State# RealWorld -> State# RealWorld
+ with
+ has_side_effects = True
+ out_of_line = True
------------------------------------------------------------------------
section "Weak pointers"
primop MkWeakOp "mkWeak#" GenPrimOp
o -> b -> c -> State# RealWorld -> (# State# RealWorld, Weak# b #)
with
- strictness = { \ arity -> StrictnessInfo [wwLazy, wwLazy, wwLazy, wwPrim] False }
usage = { mangle MkWeakOp [mkZ, mkM, mkM, mkP] mkM }
has_side_effects = True
out_of_line = True
with
usage = { mangle DeRefWeakOp [mkM, mkP] mkM }
has_side_effects = True
+ out_of_line = True
primop FinalizeWeakOp "finalizeWeak#" GenPrimOp
Weak# a -> State# RealWorld -> (# State# RealWorld, Int#,
- (State# RealWorld -> (# State# RealWorld, Unit #)) #)
+ (State# RealWorld -> (# State# RealWorld, () #)) #)
with
usage = { mangle FinalizeWeakOp [mkM, mkP]
(mkR . (inUB FinalizeWeakOp
primop MakeStablePtrOp "makeStablePtr#" GenPrimOp
a -> State# RealWorld -> (# State# RealWorld, StablePtr# a #)
with
- strictness = { \ arity -> StrictnessInfo [wwLazy, wwPrim] False }
usage = { mangle MakeStablePtrOp [mkM, mkP] mkM }
has_side_effects = True
+ out_of_line = True
primop DeRefStablePtrOp "deRefStablePtr#" GenPrimOp
StablePtr# a -> State# RealWorld -> (# State# RealWorld, a #)
usage = { mangle DeRefStablePtrOp [mkM, mkP] mkM }
needs_wrapper = True
has_side_effects = True
+ out_of_line = True
primop EqStablePtrOp "eqStablePtr#" GenPrimOp
StablePtr# a -> StablePtr# a -> Int#
a -> State# RealWorld -> (# State# RealWorld, StableName# a #)
with
usage = { mangle MakeStableNameOp [mkZ, mkP] mkR }
- strictness = { \ arity -> StrictnessInfo [wwLazy, wwPrim] False }
needs_wrapper = True
has_side_effects = True
out_of_line = True
section "Parallelism"
------------------------------------------------------------------------
-primop SeqOp "seq#" GenPrimOp
- a -> Int#
- with
- usage = { mangle SeqOp [mkO] mkR }
- strictness = { \ arity -> StrictnessInfo [wwStrict] False }
- -- Seq is strict in its argument; see notes in ConFold.lhs
- has_side_effects = True
-
primop ParOp "par#" GenPrimOp
a -> Int#
with
usage = { mangle ParOp [mkO] mkR }
- strictness = { \ arity -> StrictnessInfo [wwLazy] False }
-- Note that Par is lazy to avoid that the sparked thing
-- gets evaluted strictly, which it should *not* be
has_side_effects = True
primop DataToTagOp "dataToTag#" GenPrimOp
a -> Int#
- with
- strictness = { \ arity -> StrictnessInfo [wwLazy] False }
primop TagToEnumOp "tagToEnum#" GenPrimOp
Int# -> a
{Convert an Addr\# to a followable type.}
primop MkApUpd0_Op "mkApUpd0#" GenPrimOp
- a -> (# a #)
+ BCO# -> (# a #)
with
out_of_line = True
primop NewBCOOp "newBCO#" GenPrimOp
- ByteArr# -> ByteArr# -> Array# a -> ByteArr# -> State# s -> (# State# s, BCO# #)
+ ByteArr# -> ByteArr# -> Array# a -> ByteArr# -> Int# -> ByteArr# -> State# s -> (# State# s, BCO# #)
with
has_side_effects = True
out_of_line = True
------------------------------------------------------------------------
+section "Coercion"
+ {{\tt unsafeCoerce\# :: a -> b} is not a primop, but is defined in MkId.lhs.}
+
+------------------------------------------------------------------------
+
+
+------------------------------------------------------------------------
--- ---
------------------------------------------------------------------------