X-Git-Url: http://git.megacz.com/?a=blobdiff_plain;f=compiler%2Fprelude%2Fprimops.txt.pp;h=16149d9eff345743fcc0d8d802c28fa1656eaa45;hb=d753d69a65e5acd860f626a6d2f6b86b75289066;hp=3493d0527e716ebe18d1d347e8fed4e0e5336a9f;hpb=b067bdc33ce1a0bb01957b0bcfbb1c516dba53a4;p=ghc-hetmet.git diff --git a/compiler/prelude/primops.txt.pp b/compiler/prelude/primops.txt.pp index 3493d05..16149d9 100644 --- a/compiler/prelude/primops.txt.pp +++ b/compiler/prelude/primops.txt.pp @@ -1,7 +1,7 @@ ----------------------------------------------------------------------- -- $Id: primops.txt.pp,v 1.37 2005/11/25 09:46:19 simonmar Exp $ -- --- Primitive Operations +-- Primitive Operations and Types -- ----------------------------------------------------------------------- @@ -150,6 +150,7 @@ section "Char#" {Operations on 31-bit characters.} ------------------------------------------------------------------------ +primtype Char# primop CharGtOp "gtChar#" Compare Char# -> Char# -> Bool primop CharGeOp "geChar#" Compare Char# -> Char# -> Bool @@ -172,6 +173,8 @@ section "Int#" {Operations on native-size integers (30+ bits).} ------------------------------------------------------------------------ +primtype Int# + primop IntAddOp "+#" Dyadic Int# -> Int# -> Int# with commutable = True @@ -203,7 +206,7 @@ primop IntMulMayOfloOp "mulIntMayOflo#" 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. + \texttt{(*) :: Integer -> Integer -> Integer} will be poor. } with commutable = True @@ -267,6 +270,8 @@ section "Word#" {Operations on native-sized unsigned words (30+ bits).} ------------------------------------------------------------------------ +primtype Word# + primop WordAddOp "plusWord#" Dyadic Word# -> Word# -> Word# with commutable = True @@ -328,11 +333,13 @@ primop Narrow32WordOp "narrow32Word#" Monadic Word# -> Word# #if WORD_SIZE_IN_BITS < 32 ------------------------------------------------------------------------ section "Int32#" - {Operations on 32-bit integers (Int32\#). This type is only used - if plain Int\# has less than 32 bits. In any case, the operations + {Operations on 32-bit integers ({\tt Int32\#}). This type is only used + if plain {\tt Int\#} has less than 32 bits. In any case, the operations are not primops; they are implemented (if needed) as ccalls instead.} ------------------------------------------------------------------------ +primtype Int32# + primop Int32ToIntegerOp "int32ToInteger#" GenPrimOp Int32# -> (# Int#, ByteArr# #) with out_of_line = True @@ -341,10 +348,12 @@ primop Int32ToIntegerOp "int32ToInteger#" GenPrimOp ------------------------------------------------------------------------ section "Word32#" {Operations on 32-bit unsigned words. This type is only used - if plain Word\# has less than 32 bits. In any case, the operations + if plain {\tt Word\#} has less than 32 bits. In any case, the operations are not primops; they are implemented (if needed) as ccalls instead.} ------------------------------------------------------------------------ +primtype Word32# + primop Word32ToIntegerOp "word32ToInteger#" GenPrimOp Word32# -> (# Int#, ByteArr# #) with out_of_line = True @@ -357,10 +366,12 @@ primop Word32ToIntegerOp "word32ToInteger#" GenPrimOp ------------------------------------------------------------------------ section "Int64#" {Operations on 64-bit unsigned words. This type is only used - if plain Int\# has less than 64 bits. In any case, the operations + if plain {\tt Int\#} has less than 64 bits. In any case, the operations are not primops; they are implemented (if needed) as ccalls instead.} ------------------------------------------------------------------------ +primtype Int64# + primop Int64ToIntegerOp "int64ToInteger#" GenPrimOp Int64# -> (# Int#, ByteArr# #) with out_of_line = True @@ -368,10 +379,12 @@ primop Int64ToIntegerOp "int64ToInteger#" GenPrimOp ------------------------------------------------------------------------ section "Word64#" {Operations on 64-bit unsigned words. This type is only used - if plain Word\# has less than 64 bits. In any case, the operations + if plain {\tt Word\#} has less than 64 bits. In any case, the operations are not primops; they are implemented (if needed) as ccalls instead.} ------------------------------------------------------------------------ +primtype Word64# + primop Word64ToIntegerOp "word64ToInteger#" GenPrimOp Word64# -> (# Int#, ByteArr# #) with out_of_line = True @@ -382,8 +395,8 @@ primop Word64ToIntegerOp "word64ToInteger#" GenPrimOp section "Integer#" {Operations on arbitrary-precision integers. These operations are 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 +consisting of an {\tt Int\#} representing the number of 'limbs' in use and +the sign, and a {\tt ByteArr\#} containing the 'limbs' themselves. Such pairs are returned as unboxed pairs, but must be passed as separate components. @@ -415,7 +428,7 @@ primop IntegerGcdOp "gcdInteger#" GenPrimOp primop IntegerIntGcdOp "gcdIntegerInt#" GenPrimOp Int# -> ByteArr# -> Int# -> Int# - {Greatest common divisor, where second argument is an ordinary Int\#.} + {Greatest common divisor, where second argument is an ordinary {\tt Int\#}.} with out_of_line = True primop IntegerDivExactOp "divExactInteger#" GenPrimOp @@ -500,6 +513,8 @@ section "Double#" {Operations on double-precision (64 bit) floating-point numbers.} ------------------------------------------------------------------------ +primtype Double# + primop DoubleGtOp ">##" Compare Double# -> Double# -> Bool primop DoubleGeOp ">=##" Compare Double# -> Double# -> Bool @@ -596,8 +611,8 @@ primop DoublePowerOp "**##" Dyadic primop DoubleDecodeOp "decodeDouble#" GenPrimOp Double# -> (# Int#, Int#, ByteArr# #) {Convert to arbitrary-precision integer. - First Int\# in result is the exponent; second Int\# and ByteArr\# represent an Integer\# - holding the mantissa.} + First {\tt Int\#} in result is the exponent; second {\tt Int\#} and {\tt ByteArr\#} + represent an {\tt Integer\#} holding the mantissa.} with out_of_line = True ------------------------------------------------------------------------ @@ -605,6 +620,8 @@ section "Float#" {Operations on single-precision (32-bit) floating-point numbers.} ------------------------------------------------------------------------ +primtype Float# + primop FloatGtOp "gtFloat#" Compare Float# -> Float# -> Bool primop FloatGeOp "geFloat#" Compare Float# -> Float# -> Bool @@ -697,15 +714,19 @@ primop Float2DoubleOp "float2Double#" GenPrimOp Float# -> Double# primop FloatDecodeOp "decodeFloat#" GenPrimOp Float# -> (# Int#, Int#, ByteArr# #) {Convert to arbitrary-precision integer. - First Int\# in result is the exponent; second Int\# and ByteArr\# represent an Integer\# - holding the mantissa.} + First {\tt Int\#} in result is the exponent; second {\tt Int\#} and {\tt ByteArr\#} + represent an {\tt Integer\#} holding the mantissa.} with out_of_line = True ------------------------------------------------------------------------ section "Arrays" - {Operations on Array\#.} + {Operations on {\tt Array\#}.} ------------------------------------------------------------------------ +primtype Array# a + +primtype MutArr# s a + primop NewArrayOp "newArray#" GenPrimOp Int# -> a -> State# s -> (# State# s, MutArr# s a #) {Create a new mutable array of specified size (in bytes), @@ -756,7 +777,7 @@ primop UnsafeThawArrayOp "unsafeThawArray#" GenPrimOp ------------------------------------------------------------------------ section "Byte Arrays" - {Operations on ByteArray\#. A ByteArray\# is a just a region of + {Operations on {\tt ByteArray\#}. A {\tt ByteArray\#} is a just a region of raw memory in the garbage-collected heap, which is not scanned for pointers. It carries its own size (in bytes). There are three sets of operations for accessing byte array contents: @@ -768,6 +789,10 @@ section "Byte Arrays" ------------------------------------------------------------------------ +primtype ByteArr# + +primtype MutByteArr# s + primop NewByteArrayOp_Char "newByteArray#" GenPrimOp Int# -> State# s -> (# State# s, MutByteArr# s #) {Create a new mutable byte array of specified size (in bytes), in @@ -967,20 +992,22 @@ primop WriteByteArrayOp_Word64 "writeWord64Array#" GenPrimOp ------------------------------------------------------------------------ section "Addr#" - {Addr\# is an arbitrary machine address assumed to point outside - the garbage-collected heap. - - NB: {\tt nullAddr\#::Addr\#} is not a primop, but is defined in MkId.lhs. - It is the null address.} ------------------------------------------------------------------------ +primtype Addr# + { An arbitrary machine address assumed to point outside + the garbage-collected heap. } + +pseudoop "nullAddr#" Addr# + { The null address. } + 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 - difference doesn't fit in an Int\#.} + {Result is meaningless if two {\tt Addr\#}s are so far apart that their + difference doesn't fit in an {\tt Int\#}.} primop AddrRemOp "remAddr#" GenPrimOp Addr# -> Int# -> Int# - {Return the remainder when the Addr\# arg, treated like an Int\#, - is divided by the Int\# arg.} + {Return the remainder when the {\tt Addr\#} arg, treated like an {\tt Int\#}, + is divided by the {\tt Int\#} arg.} #if (WORD_SIZE_IN_BITS == 32 || WORD_SIZE_IN_BITS == 64) primop Addr2IntOp "addr2Int#" GenPrimOp Addr# -> Int# {Coerce directly from address to int. Strongly deprecated.} @@ -1162,25 +1189,28 @@ primop WriteOffAddrOp_Word64 "writeWord64OffAddr#" GenPrimOp ------------------------------------------------------------------------ section "Mutable variables" - {Operations on MutVar\#s, which behave like single-element mutable arrays.} + {Operations on MutVar\#s.} ------------------------------------------------------------------------ +primtype MutVar# s a + {A {\tt MutVar\#} behaves like a single-element mutable array.} + primop NewMutVarOp "newMutVar#" GenPrimOp a -> State# s -> (# State# s, MutVar# s a #) - {Create MutVar\# with specified initial value in specified state thread.} + {Create {\tt MutVar\#} with specified initial value in specified state thread.} with usage = { mangle NewMutVarOp [mkM, mkP] mkM } out_of_line = True primop ReadMutVarOp "readMutVar#" GenPrimOp MutVar# s a -> State# s -> (# State# s, a #) - {Read contents of MutVar\#. Result is not yet evaluated.} + {Read contents of {\tt MutVar\#}. Result is not yet evaluated.} with usage = { mangle ReadMutVarOp [mkM, mkP] mkM } primop WriteMutVarOp "writeMutVar#" GenPrimOp MutVar# s a -> a -> State# s -> State# s - {Write contents of MutVar\#.} + {Write contents of {\tt MutVar\#}.} with usage = { mangle WriteMutVarOp [mkM, mkM, mkP] mkR } has_side_effects = True @@ -1253,6 +1283,8 @@ primop UnblockAsyncExceptionsOp "unblockAsyncExceptions#" GenPrimOp section "STM-accessible Mutable Variables" ------------------------------------------------------------------------ +primtype TVar# s a + primop AtomicallyOp "atomically#" GenPrimOp (State# RealWorld -> (# State# RealWorld, a #) ) -> State# RealWorld -> (# State# RealWorld, a #) @@ -1292,14 +1324,14 @@ primop Check "check#" GenPrimOp primop NewTVarOp "newTVar#" GenPrimOp a -> State# s -> (# State# s, TVar# s a #) - {Create a new Tar\# holding a specified initial value.} + {Create a new {\tt TVar\#} holding a specified initial value.} with out_of_line = True primop ReadTVarOp "readTVar#" GenPrimOp TVar# s a -> State# s -> (# State# s, a #) - {Read contents of TVar\#. Result is not yet evaluated.} + {Read contents of {\tt TVar\#}. Result is not yet evaluated.} with out_of_line = True @@ -1307,7 +1339,7 @@ primop WriteTVarOp "writeTVar#" GenPrimOp TVar# s a -> a -> State# s -> State# s - {Write contents of TVar\#.} + {Write contents of {\tt TVar\#}.} with out_of_line = True has_side_effects = True @@ -1318,22 +1350,24 @@ primop SameTVarOp "sameTVar#" GenPrimOp ------------------------------------------------------------------------ section "Synchronized Mutable Variables" - {Operations on MVar\#s, which are shared mutable variables - ({\it not} the same as MutVar\#s!). (Note: in a non-concurrent implementation, - (MVar\# a) can be represented by (MutVar\# (Maybe a)).)} + {Operations on {\tt MVar\#}s. } ------------------------------------------------------------------------ +primtype MVar# s a + { A shared mutable variable ({\it not} the same as a {\tt MutVar\#}!). + (Note: in a non-concurrent implementation, {\tt (MVar\# a)} can be + represented by {\tt (MutVar\# (Maybe a))}.) } primop NewMVarOp "newMVar#" GenPrimOp State# s -> (# State# s, MVar# s a #) - {Create new mvar; initially empty.} + {Create new {\tt MVar\#}; initially empty.} with usage = { mangle NewMVarOp [mkP] mkR } out_of_line = True primop TakeMVarOp "takeMVar#" GenPrimOp MVar# s a -> State# s -> (# State# s, a #) - {If mvar is empty, block until it becomes full. + {If {\tt MVar\#} is empty, block until it becomes full. Then remove and return its contents, and set it empty.} with usage = { mangle TakeMVarOp [mkM, mkP] mkM } @@ -1342,8 +1376,8 @@ primop TakeMVarOp "takeMVar#" GenPrimOp primop TryTakeMVarOp "tryTakeMVar#" GenPrimOp MVar# s a -> State# s -> (# State# s, Int#, a #) - {If mvar is empty, immediately return with integer 0 and value undefined. - Otherwise, return with integer 1 and contents of mvar, and set mvar empty.} + {If {\tt MVar\#} is empty, immediately return with integer 0 and value undefined. + Otherwise, return with integer 1 and contents of {\tt MVar\#}, and set {\tt MVar\#} empty.} with usage = { mangle TryTakeMVarOp [mkM, mkP] mkM } has_side_effects = True @@ -1351,7 +1385,7 @@ primop TryTakeMVarOp "tryTakeMVar#" GenPrimOp primop PutMVarOp "putMVar#" GenPrimOp MVar# s a -> a -> State# s -> State# s - {If mvar is full, block until it becomes empty. + {If {\tt MVar\#} is full, block until it becomes empty. Then store value arg as its new contents.} with usage = { mangle PutMVarOp [mkM, mkM, mkP] mkR } @@ -1360,8 +1394,8 @@ primop PutMVarOp "putMVar#" GenPrimOp primop TryPutMVarOp "tryPutMVar#" GenPrimOp MVar# s a -> a -> State# s -> (# State# s, Int# #) - {If mvar is full, immediately return with integer 0. - Otherwise, store value arg as mvar's new contents, and return with integer 1.} + {If {\tt MVar\#} is full, immediately return with integer 0. + Otherwise, store value arg as {\tt MVar\#}'s new contents, and return with integer 1.} with usage = { mangle TryPutMVarOp [mkM, mkM, mkP] mkR } has_side_effects = True @@ -1374,7 +1408,7 @@ primop SameMVarOp "sameMVar#" GenPrimOp primop IsEmptyMVarOp "isEmptyMVar#" GenPrimOp MVar# s a -> State# s -> (# State# s, Int# #) - {Return 1 if mvar is empty; 0 otherwise.} + {Return 1 if {\tt MVar\#} is empty; 0 otherwise.} with usage = { mangle IsEmptyMVarOp [mkP, mkP] mkM } out_of_line = True @@ -1436,11 +1470,25 @@ primop AsyncDoProcOp "asyncDoProc#" GenPrimOp ------------------------------------------------------------------------ section "Concurrency primitives" - {(In a non-concurrent implementation, ThreadId\# can be as singleton - type, whose (unique) value is returned by myThreadId\#. The - other operations can be omitted.)} ------------------------------------------------------------------------ +primtype State# s + { {\tt State\#} is the primitive, unlifted type of states. It has + one type parameter, thus {\tt State\# RealWorld}, or {\tt State\# s}, + where s is a type variable. The only purpose of the type parameter + is to keep different state threads separate. It is represented by + nothing at all. } + +primtype RealWorld + { {\tt RealWorld} is deeply magical. It is {\it primitive}, but it is not + {\it unlifted} (hence {\tt ptrArg}). We never manipulate values of type + {\tt RealWorld}; it's only used in the type system, to parameterise {\tt State\#}. } + +primtype ThreadId# + {(In a non-concurrent implementation, this can be a singleton + type, whose (unique) value is returned by {\tt myThreadId\#}. The + other operations can be omitted.)} + primop ForkOp "fork#" GenPrimOp a -> State# RealWorld -> (# State# RealWorld, ThreadId# #) with @@ -1484,10 +1532,17 @@ primop IsCurrentThreadBoundOp "isCurrentThreadBound#" GenPrimOp with out_of_line = True +primop NoDuplicateOp "noDuplicate#" GenPrimOp + State# RealWorld -> State# RealWorld + with + out_of_line = True + ------------------------------------------------------------------------ section "Weak pointers" ------------------------------------------------------------------------ +primtype Weak# b + -- note that tyvar "o" denotes openAlphaTyVar primop MkWeakOp "mkWeak#" GenPrimOp @@ -1523,6 +1578,10 @@ primop TouchOp "touch#" GenPrimOp section "Stable pointers and names" ------------------------------------------------------------------------ +primtype StablePtr# a + +primtype StableName# a + primop MakeStablePtrOp "makeStablePtr#" GenPrimOp a -> State# RealWorld -> (# State# RealWorld, StablePtr# a #) with @@ -1661,10 +1720,12 @@ section "Bytecode operations" {Support for the bytecode interpreter and linker.} ------------------------------------------------------------------------ +primtype BCO# + {Primitive bytecode type.} primop AddrToHValueOp "addrToHValue#" GenPrimOp Addr# -> (# a #) - {Convert an Addr\# to a followable type.} + {Convert an {\tt Addr\#} to a followable type.} primop MkApUpd0_Op "mkApUpd0#" GenPrimOp BCO# -> (# a #) @@ -1687,11 +1748,90 @@ primop ClosurePayloadOp "closurePayload#" GenPrimOp with out_of_line = True ------------------------------------------------------------------------- -section "Coercion" - {{\tt unsafeCoerce\# :: a -> b} is not a primop, but is defined in MkId.lhs.} ------------------------------------------------------------------------ +section "Etc" + {Miscellaneous built-ins} +------------------------------------------------------------------------ + +pseudoop "seq" + a -> b -> b + { Evaluates its first argument to head normal form, and then returns its second + argument as the result. } + +pseudoop "inline" + a -> a + { The call {\tt (inline f)} arranges that f is inlined, regardless of its size. + More precisely, the call {\tt (inline f)} rewrites to the right-hand side of + {\tt f}'s definition. This allows the programmer to control inlining from a + particular call site rather than the definition site of the function (c.f. + {\tt INLINE} pragmas in User's Guide, Section 7.10.3, "INLINE and NOINLINE + pragmas"). + + This inlining occurs regardless of the argument to the call or the size of + {\tt f}'s definition; it is unconditional. The main caveat is that {\tt f}'s + definition must be visible to the compiler. That is, {\tt f} must be + {\tt let}-bound in the current scope. If no inlining takes place, the + {\tt inline} function expands to the identity function in Phase zero; so its + use imposes no overhead. + + If the function is defined in another module, GHC only exposes its inlining + in the interface file if the function is sufficiently small that it might be + inlined by the automatic mechanism. There is currently no way to tell GHC to + expose arbitrarily-large functions in the interface file. (This shortcoming + is something that could be fixed, with some kind of pragma.) } + +pseudoop "lazy" + a -> a + { The {\tt lazy} function restrains strictness analysis a little. The call + {\tt (lazy e)} means the same as {\tt e}, but {\tt lazy} has a magical + property so far as strictness analysis is concerned: it is lazy in its first + argument, even though its semantics is strict. After strictness analysis has + run, calls to {\tt lazy} are inlined to be the identity function. + + This behaviour is occasionally useful when controlling evaluation order. + Notably, {\tt lazy} is used in the library definition of {\tt Control.Parallel.par}: + + {\tt par :: a -> b -> b} + + {\tt par x y = case (par\# x) of \_ -> lazy y} + + If {\tt lazy} were not lazy, {\tt par} would look strict in {\tt y} which + would defeat the whole purpose of {\tt par}. + + Like {\tt seq}, the argument of {\tt lazy} can have an unboxed type. } + +primtype Any a + { The type constructor {\tt Any} is type to which you can unsafely coerce any + lifted type, and back. + + * It is lifted, and hence represented by a pointer + + * It does not claim to be a {\it data} type, and that's important for + the code generator, because the code gen may {\it enter} a data value + but never enters a function value. + + It's also used to instantiate un-constrained type variables after type + checking. For example + + {\tt length Any []} + + Annoyingly, we sometimes need {\tt Any}s of other kinds, such as {\tt (* -> *)} etc. + This is a bit like tuples. We define a couple of useful ones here, + and make others up on the fly. If any of these others end up being exported + into interface files, we'll get a crash; at least until we add interface-file + syntax to support them. } + +pseudoop "unsafeCoerce#" + a -> b + { The function {\tt unsafeCoerce\#} allows you to side-step the typechecker entirely. That + is, it allows you to coerce any type into any other type. If you use this function, + you had better get it right, otherwise segmentation faults await. It is generally + used when you want to write a program that you know is well-typed, but where Haskell's + type system is not expressive enough to prove that it is well typed. + + The argument to {\tt unsafeCoerce\#} can have unboxed types, although extremely bad + things will happen if you coerce a boxed type to an unboxed type. } ------------------------------------------------------------------------