{- (c) The University of Glasgow 2006 (c) The GRASP/AQUA Project, Glasgow University, 1992-1998 @Uniques@ are used to distinguish entities in the compiler (@Ids@, @Classes@, etc.) from each other. Thus, @Uniques@ are the basic comparison key in the compiler. If there is any single operation that needs to be fast, it is @Unique@ comparison. Unsurprisingly, there is quite a bit of huff-and-puff directed to that end. Some of the other hair in this code is to be able to use a ``splittable @UniqueSupply@'' if requested/possible (not standard Haskell). -} {-# LANGUAGE CPP #-} {-# LANGUAGE MagicHash #-} module GHC.Types.Unique ( -- * Main data types Unique, Uniquable(..), uNIQUE_BITS, -- ** Constructors, destructors and operations on 'Unique's hasKey, pprUniqueAlways, mkTag, mkUniqueGrimily, mkUniqueIntGrimily, getKey, mkUnique, unpkUnique, mkUniqueInt, eqUnique, ltUnique, incrUnique, stepUnique, newTagUnique, nonDetCmpUnique, isValidKnownKeyUnique, -- ** Local uniques -- | These are exposed exclusively for use by 'GHC.Types.Var.Env.uniqAway', which -- has rather peculiar needs. See Note [Local uniques]. mkLocalUnique, minLocalUnique, maxLocalUnique, ) where #include "Unique.h" import GHC.Prelude import GHC.Data.FastString import GHC.Utils.Outputable import GHC.Utils.Word64 (intToWord64, word64ToInt) -- just for implementing a fast [0,61) -> Char function import GHC.Exts (indexCharOffAddr#, Char(..), Int(..)) import GHC.Word ( Word64 ) import Data.Char ( chr, ord ) import Language.Haskell.Syntax.Module.Name {- ************************************************************************ * * \subsection[Unique-type]{@Unique@ type and operations} * * ************************************************************************ Note [Uniques and tags] ~~~~~~~~~~~~~~~~~~~~~~~~ A `Unique` in GHC is a 64 bit value composed of two pieces: * A "tag", of width `UNIQUE_TAG_BITS`, in the high order bits * A number, of width `uNIQUE_BITS`, which fills up the remainder of the Word64 The tag is typically an ASCII character. It is typically used to make it easier to distinguish uniques constructed by different parts of the compiler. There is a (potentially incomplete) list of unique tags used given in GHC.Builtin.Uniques. See Note [Uniques for wired-in prelude things and known tags] `mkUnique` constructs a `Unique` from its pieces mkUnique :: Char -> Word64 -> Unique -} -- | Unique identifier. -- -- The type of unique identifiers that are used in many places in GHC -- for fast ordering and equality tests. You should generate these with -- the functions from the 'UniqSupply' module -- -- These are sometimes also referred to as \"keys\" in comments in GHC. newtype Unique = MkUnique Word64 {-# INLINE uNIQUE_BITS #-} uNIQUE_BITS :: Int uNIQUE_BITS = 64 - UNIQUE_TAG_BITS {- Now come the functions which construct uniques from their pieces, and vice versa. The stuff about unique *supplies* is handled further down this module. -} unpkUnique :: Unique -> (Char, Word64) -- The reverse mkUniqueGrimily :: Word64 -> Unique -- A trap-door for UniqSupply getKey :: Unique -> Word64 -- for Var incrUnique :: Unique -> Unique stepUnique :: Unique -> Word64 -> Unique newTagUnique :: Unique -> Char -> Unique mkUniqueGrimily = MkUnique {-# INLINE getKey #-} getKey (MkUnique x) = x incrUnique (MkUnique i) = MkUnique (i + 1) stepUnique (MkUnique i) n = MkUnique (i + n) mkLocalUnique :: Word64 -> Unique mkLocalUnique i = mkUnique 'X' i minLocalUnique :: Unique minLocalUnique = mkLocalUnique 0 maxLocalUnique :: Unique maxLocalUnique = mkLocalUnique uniqueMask -- newTagUnique changes the "domain" of a unique to a different char newTagUnique u c = mkUnique c i where (_,i) = unpkUnique u -- | Bitmask that has zeros for the tag bits and ones for the rest. uniqueMask :: Word64 uniqueMask = (1 `shiftL` uNIQUE_BITS) - 1 -- | Put the character in the highest bits of the Word64. -- This may truncate the character to UNIQUE_TAG_BITS. -- This function is used in @`mkSplitUniqSupply`@ so that it can -- precompute and share the tag part of the uniques it generates. mkTag :: Char -> Word64 mkTag c = intToWord64 (ord c) `shiftL` uNIQUE_BITS -- pop the Char in the top 8 bits of the Unique(Supply) -- No 64-bit bugs here, as long as we have at least 32 bits. --JSM -- and as long as the Char fits in 8 bits, which we assume anyway! mkUnique :: Char -> Word64 -> Unique -- Builds a unique from pieces -- EXPORTED and used only in GHC.Builtin.Uniques mkUnique c i = MkUnique (tag .|. bits) where tag = mkTag c bits = i .&. uniqueMask mkUniqueInt :: Char -> Int -> Unique mkUniqueInt c i = mkUnique c (intToWord64 i) mkUniqueIntGrimily :: Int -> Unique mkUniqueIntGrimily = MkUnique . intToWord64 unpkUnique (MkUnique u) = let -- The potentially truncating use of fromIntegral here is safe -- because the argument is just the tag bits after shifting. tag = chr (word64ToInt (u `shiftR` uNIQUE_BITS)) i = u .&. uniqueMask in (tag, i) -- | The interface file symbol-table encoding assumes that known-key uniques fit -- in 30-bits; verify this. -- -- See Note [Symbol table representation of names] in "GHC.Iface.Binary" for details. isValidKnownKeyUnique :: Unique -> Bool isValidKnownKeyUnique u = case unpkUnique u of (c, x) -> ord c < 0xff && x <= (1 `shiftL` 22) {- ************************************************************************ * * \subsection[Uniquable-class]{The @Uniquable@ class} * * ************************************************************************ -} -- | Class of things that we can obtain a 'Unique' from class Uniquable a where getUnique :: a -> Unique hasKey :: Uniquable a => a -> Unique -> Bool x `hasKey` k = getUnique x == k instance Uniquable FastString where getUnique fs = mkUniqueIntGrimily (uniqueOfFS fs) instance Uniquable Int where getUnique i = mkUniqueIntGrimily i instance Uniquable ModuleName where getUnique (ModuleName nm) = getUnique nm {- ************************************************************************ * * \subsection[Unique-instances]{Instance declarations for @Unique@} * * ************************************************************************ And the whole point (besides uniqueness) is fast equality. We don't use `deriving' because we want {\em precise} control of ordering (equality on @Uniques@ is v common). -} -- Note [Unique Determinism] -- ~~~~~~~~~~~~~~~~~~~~~~~~~ -- The order of allocated @Uniques@ is not stable across rebuilds. -- The main reason for that is that typechecking interface files pulls -- @Uniques@ from @UniqSupply@ and the interface file for the module being -- currently compiled can, but doesn't have to exist. -- -- It gets more complicated if you take into account that the interface -- files are loaded lazily and that building multiple files at once has to -- work for any subset of interface files present. When you add parallelism -- this makes @Uniques@ hopelessly random. -- -- As such, to get deterministic builds, the order of the allocated -- @Uniques@ should not affect the final result. -- see also wiki/deterministic-builds -- -- Note [Unique Determinism and code generation] -- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ -- The goal of the deterministic builds (wiki/deterministic-builds, #4012) -- is to get ABI compatible binaries given the same inputs and environment. -- The motivation behind that is that if the ABI doesn't change the -- binaries can be safely reused. -- Note that this is weaker than bit-for-bit identical binaries and getting -- bit-for-bit identical binaries is not a goal for now. -- This means that we don't care about nondeterminism that happens after -- the interface files are created, in particular we don't care about -- register allocation and code generation. -- To track progress on bit-for-bit determinism see #12262. eqUnique :: Unique -> Unique -> Bool eqUnique (MkUnique u1) (MkUnique u2) = u1 == u2 ltUnique :: Unique -> Unique -> Bool ltUnique (MkUnique u1) (MkUnique u2) = u1 < u2 -- Provided here to make it explicit at the call-site that it can -- introduce non-determinism. -- See Note [Unique Determinism] -- See Note [No Ord for Unique] nonDetCmpUnique :: Unique -> Unique -> Ordering nonDetCmpUnique (MkUnique u1) (MkUnique u2) = if u1 == u2 then EQ else if u1 < u2 then LT else GT {- Note [No Ord for Unique] ~~~~~~~~~~~~~~~~~~~~~~~~~~ As explained in Note [Unique Determinism] the relative order of Uniques is nondeterministic. To prevent from accidental use the Ord Unique instance has been removed. This makes it easier to maintain deterministic builds, but comes with some drawbacks. The biggest drawback is that Maps keyed by Uniques can't directly be used. The alternatives are: 1) Use UniqFM or UniqDFM, see Note [Deterministic UniqFM] to decide which 2) Create a newtype wrapper based on Unique ordering where nondeterminism is controlled. See GHC.Unit.Module.Env.ModuleEnv 3) Change the algorithm to use nonDetCmpUnique and document why it's still deterministic 4) Use TrieMap as done in GHC.Cmm.CommonBlockElim.groupByLabel -} instance Eq Unique where a == b = eqUnique a b a /= b = not (eqUnique a b) instance Uniquable Unique where getUnique u = u -- We do sometimes make strings with @Uniques@ in them: showUnique :: Unique -> String showUnique uniq = case unpkUnique uniq of (tag, u) -> tag : w64ToBase62 u pprUniqueAlways :: IsLine doc => Unique -> doc -- The "always" means regardless of -dsuppress-uniques -- It replaces the old pprUnique to remind callers that -- they should consider whether they want to consult -- Opt_SuppressUniques pprUniqueAlways u = text (showUnique u) {-# SPECIALIZE pprUniqueAlways :: Unique -> SDoc #-} {-# SPECIALIZE pprUniqueAlways :: Unique -> HLine #-} -- see Note [SPECIALIZE to HDoc] in GHC.Utils.Outputable instance Outputable Unique where ppr = pprUniqueAlways instance Show Unique where show uniq = showUnique uniq {- ************************************************************************ * * \subsection[Utils-base62]{Base-62 numbers} * * ************************************************************************ A character-stingy way to read/write numbers (notably Uniques). The ``62-its'' are \tr{[0-9a-zA-Z]}. Code stolen from Lennart. -} w64ToBase62 :: Word64 -> String w64ToBase62 n_ = go n_ "" where -- The potentially truncating uses of fromIntegral here are safe -- because the argument is guaranteed to be less than 62 in both cases. go n cs | n < 62 = let !c = chooseChar62 (word64ToInt n) in c : cs | otherwise = go q (c : cs) where (!q, r) = quotRem n 62 !c = chooseChar62 (word64ToInt r) chooseChar62 :: Int -> Char {-# INLINE chooseChar62 #-} chooseChar62 (I# n) = C# (indexCharOffAddr# chars62 n) chars62 = "0123456789abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ"#