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.. _release-9-4-1:
Version 9.4.1
==============
Compiler
~~~~~~~~
- New :ghc-flag:`-Wredundant-strictness-flags` that checks for strictness flags
(``!``) applied to unlifted types, which are always strict.
- A new type of plugin: defaulting plugins. These plugins can propose
defaults for ambiguous variables that would otherwise cause errors
just like the built-in defaulting mechanism.
- The way GHC checks for representation polymorphism has been overhauled:
all the checks are now done during typechecking. The error messages
now contain more detailed information about the specific check that was performed.
- The parsing of implicit parameters is slightly more permissive, as GHC now allows ::
foo :: (?ip :: forall a. a -> a)
without requiring parentheses around ``forall a. a -> a``. Note that implicit
parameters with such kinds are unlikely to be very useful, due to
:ghc-ticket:`18759`.
- Changes to the treatment of :extension:`UnboxedSums`:
- GHC can now parse unboxed sum type constructors ``(# | #)``, ``(# | | #)``,
``(# | | | #)`, etc. Partial applications need to be written in prefix form,
e.g. ``(# | #) Int#``.
- Unboxed sums now require the :extension:`UnboxedSums` extension to be enabled.
- The :extension:`UnboxedTuples` extension now implies
:extension:`UnboxedSums`. This means that code using unboxed sums that
enabled the :extension:`UnboxedTuples` extension but didn't explicitly
enable :extension:`UnboxedSums` will continue to work without changes.
- Constructed Product Result analysis (c.f. :ghc-flag:`-fcpr-anal`) has been
overhauled and will now unbox nestedly, if termination properties of the
function permit. This allows unboxing of constructed results returned by
``IO`` actions. E.g.::
sumIO :: [Int] -> IO Int
sumIO [] = return 0
sumIO (x:xs) = do
r <- sumIO xs
return $! x + r
Note the use of ``$!``: Without it, GHC would be unable to see that evaluation
of ``r`` and ``x`` terminates (and rapidly, at that). An alternative would be to
evaluate both with a bang pattern or a ``seq``, but the ``return $! <res>``
idiom should work more reliably and needs less thinking.
- Demand analysis (cf. :ghc-flag:`-fstrictness`) now integrates a
Boxity Analysis that tracks whether a function needs a parameter boxed. If
that is the case, the worker/wrapper transformation (cf.
:ghc-flag:`-fworker-wrapper`) will not unbox that parameter, leading to less
reboxing in many cases.
For reasons of backwards-compatible performance, you may find that the new
mechanism is too aggressive in a few cases (e.g., still unboxing a parameter
that is used boxed in a hot path). Do post a bug report with your example!
Then wrap the uses of the parameter in ``GHC.Exts.lazy`` for a short-term fix.
- Support for Sun SPARC architecture has been dropped (:ghc-ticket:`16883`).
- A fix for GHC's handling of the XDG Base Directory Specification
(:ghc-ticket:`6077`, :ghc-ticket:`20684`, :ghc-ticket:`20669`,
:ghc-ticket:`20660`):
- For the package database previously in `~/.ghc/<arch-ver>`, we
will continue to use the old path if it exists. For example, if the
`~/.ghc/x86_64-linux-9.4.1` directory exists, GHC will use that for its
user package database. If this directory does not exist, we will use
`$XDG_DATA_HOME/ghc/x86_64-linux-9.4.1`. This is in order to give tooling like
cabal time to migrate
- For GHCi configuration files previously located in `~/.ghc/` like
`ghci.conf` and `ghci_history`, we will first check if they exist in
`~/.ghc` and use those if they do. However, we will create new files like
`ghci_history` only in `$XDG_DATA_HOME/ghc`. So if you don't have a previous
GHC installation which created `~/.ghc/ghci_history`, the history file will be
written to `$XDG_DATA_HOME/ghc`. If you already have an older GHC installation which
wrote `~/.ghc/ghci_history`, then GHC will continue to write the history to that file.
``base`` library
~~~~~~~~~~~~~~~~
- ``GHC.Exts.magicDict`` has been renamed to ``withDict`` and given a more
specific type: ::
withDict :: forall {rr :: RuntimeRep} st dt (r :: TYPE rr). st -> (dt => r) -> r
Unlike ``magicDict``, ``withDict`` can be used without defining an
intermediate data type. For example, the ``withTypeable`` function from the
``Data.Typeable`` module can now be defined as: ::
withTypeable :: forall k (a :: k) rep (r :: TYPE rep). ()
=> TypeRep a -> (Typeable a => r) -> r
withTypeable rep k = withDict @(TypeRep a) @(Typeable a) rep k
Note that the explicit type applications are required, as the call to
``withDict`` would be ambiguous otherwise.
``ghc-prim`` library
~~~~~~~~~~~~~~~~~~~~
- Primitive types and functions which handle boxed values are now levity-polymorphic,
meaning that they now also work with unlifted boxed values (i.e. values whose type
has kind ``TYPE (BoxedRep Unlifted)``).
The following type constructors are now levity-polymorphic:
- ``Array#``, ``SmallArray#``, ``Weak#``, ``StablePtr#``, ``StableName#``,
- ``MutableArray#``, ``SmallMutableArray#``, ``MutVar#``,
``TVar#``, ``MVar#``, ``IOPort#``.
For example, ``Array#`` used to have kind: ::
Type -> UnliftedType
but it now has kind: ::
forall {l :: Levity}. TYPE (BoxedRep l) -> UnliftedType
Similarly, ``MutVar#`` used to have kind: ::
Type -> Type -> UnliftedType
but it now has kind: ::
forall {l :: Levity}. Type -> TYPE (BoxedRep l) -> UnliftedType
This means that in ``Array# a``, ``MutableArray# s a``, ``MutVar# s a``, ...,
the element type ``a``, must always be boxed, but it can now either be lifted
or unlifted.
In particular, arrays and mutable variables can now be used to store
other arrays and mutable variables.
All functions which use these updated primitive types are also levity-polymorphic:
- all array operations (reading/writing/copying/...), for both arrays and small arrays,
mutable and immutable:
- ``newArray#``, ``readArray#``, ``writeArray#``, ``sizeofArray#``, ``sizeofMutableArray#``, ``indexArray#``,
``unsafeFreezeArray#``, ``unsafeThawArray#``, ``copyArray#``, ``copyMutableArray#``, ``cloneArray#``,
``cloneMutableArray#``, ``freezeArray#``, ``thawArray#``, ``casArray#``,
- ``newSmallArray#``, ``shrinkSmallMutableArray#``, ``readSmallArray#``, ``writeSmallArray#``, ``sizeofSmallArray#``,
``getSizeofSmallMutableArray#``, ``indexSmallArray#``, ``unsafeFreezeSmallArray#``,
``unsafeThawSmallArray#``, ``copySmallArray#``, ``copySmallMutableArray#``, ``cloneSmallArray#``,
``cloneSmallMutableArray#``, ``freezeSmallArray#``, ``thawSmallArray#``, ``casSmallArray#``,
- ``newMutVar#``,``readMutVar#``,``writeMutV#``,``casMutVar#``,
- operations on ``MVar#`` and ``TVar#``:
- ``newTVar#``, ``readTVar#``, ``readTVarIO#``, ``writeTVar#``,
- ``newMVar#``, ``takeMVar#``, ``tryTakeMVar#``, ``putMVar#``,
``tryPutMVar#``, ``readMVar#``, ``tryReadMVar#``,
- ``STM`` operations ``atomically#``, ``retry#``, ``catchRetry#`` and ``catchSTM#``.
- ``newIOPort#``, ``readIOPort#``, ``writeIOPort#``,
- ``mkWeak#``, ``mkWeakNoFinalizer#``, ``addCFinalizerToWeak#``, ``deRefWeak#``, ``finalizeWeak#``,
- ``makeStablePtr#``, ``deRefStablePtr#``, ``eqStablePtr#``, ``makeStableName#``, ``stableNameToInt#``,
For example, the full type of ``newMutVar#`` is now: ::
newMutVar#
:: forall s {l :: Levity} (a :: TYPE (BoxedRep l)).
a -> State# s -> (# State# s, MVar# s a #)
and the full type of ``writeSmallArray#`` is: ::
writeSmallArray#
:: forall s {l :: Levity} (a :: TYPE ('BoxedRep l)).
SmallMutableArray# s a -> Int# -> a -> State# s -> State# s
- ``ArrayArray#` and ``MutableArrayArray#`` have been moved from ``GHC.Prim`` to ``GHC.Exts``.
They are deprecated, because their functionality is now subsumed by ``Array#``
and ``MutableArray#``.
- ``mkWeak#``, ``mkWeakNoFinalizer#``, ``touch#``
and ``keepAlive#`` are now levity-polymorphic instead of
representation-polymorphic. For instance: ::
mkWeakNoFinalizer#
:: forall {l :: Levity} (a :: TYPE ('BoxedRep l))
{k :: Levity} (b :: TYPE ('BoxedRep k)).
a -> b -> State# RealWorld -> (# State# RealWorld, Weak# b #)
That is, the type signature now quantifies over the ``GHC.Exts.Levity`` of ``a``
instead of its ``GHC.Exts.RuntimeRep``. In addition, this variable is now inferred,
instead of specified, meaning that it is no longer eligible for visible type application.
Note that ``b`` is now also levity-polymorphic, due to the change outlined in the
previous point.
- Primitive functions for throwing and catching exceptions are now more polymorphic
than before. For example, ``catch#`` now has type: ::
catch#
:: forall {r :: RuntimeRep} (a :: TYPE r)
{l :: Levity} (b :: TYPE ('BoxedRep l)).
( State# RealWorld -> (# State# RealWorld, a #) )
-> ( b -> State# RealWorld -> (# State# RealWorld, a #) )
-> State# RealWorld -> (# State# RealWorld, a #)
The following functions have been generalised in this way:
- ``catch#``,
- ``raise#``, ``raiseIO#``,
- ``maskAsyncExceptions#``, ``maskUninterruptible#``, ``unmaskAsyncExceptions#``.
Note in particular that ``raise#`` is now both representation-polymorphic
(with an inferred `RuntimeRep` argument) and levity-polymorphic, with type: ::
raise# :: forall {l :: Levity} (a :: TYPE (BoxedRep l))
{r :: RuntimeRep} (b :: TYPE r).
a -> b
- ``fork#`` and ``forkOn#`` are now representation-polymorphic. For example, ``fork#``
now has type: ::
fork# :: forall {r :: RuntimeRep} (a :: TYPE r).
(State# RealWorld -> (# State# RealWorld, a #))
-> (State# RealWorld -> (# State# RealWorld, a #))
- ``GHC.Exts.reallyUnsafePtrEquality#`` has been made more general, as it is now
both levity-polymorphic and heterogeneous: ::
reallyUnsafePtrEquality#
:: forall {l :: Levity} (a :: TYPE (BoxedRep l))
{k :: Levity} (b :: TYPE (BoxedRep k))
. a -> b -> Int#
This means that ``GHC.Exts.reallyUnsafePtrEquality#`` can be used
on primitive arrays such as ``GHC.Exts.Array#`` and ``GHC.Exts.ByteArray#``.
It can also be used on values of different types, without needing to call
``GHC.Exts.unsafeCoerce#``.
- Added ``GHC.Exts.reallyUnsafePtrEquality`` which recovers the
previous behaviour of ``GHC.Exts.reallyUnsafePtrEquality#``: ::
reallyUnsafePtrEquality :: forall (a :: Type). a -> a -> Int#
- Added ``GHC.Exts.sameArray#``, ``GHC.Exts.sameSmallArray#``,
``GHC.Exts.sameByteArray#`` and ``GHC.Exts.sameArrayArray#``: ::
sameArray# :: Array# a -> Array# a -> Int#
sameSmallArray# :: SmallArray# a -> SmallArray# a -> Int#
sameByteArray# :: ByteArray# -> ByteArray# -> Int#
sameArrayArray# :: ArrayArray# -> ArrayArray# -> Int#
``ghc`` library
~~~~~~~~~~~~~~~
- A new ``GHC.Hs.Syn.Type`` module has been introduced which defines functions
for computing the ``Type`` of an ``HsExpr GhcTc`` in a pure fashion.
The ``hsLitType`` and ``hsPatType`` functions that previously lived in
``GHC.Tc.Utils.Zonk`` have been moved to this module.
- A ``Typeable`` constraint has been added to ``fromStaticPtr`` in the
class ``GHC.StaticPtr.IsStatic``. GHC automatically wraps each use of
the ``static`` keyword with ``fromStaticPtr``. Because ``static`` requires
its argument to be an instance of ``Typeable``, ``fromStaticPtr`` can
safely carry this constraint as well.
- The ``newWanted`` function exported by ``GHC.Tc.Plugin`` now passes on
the full ``CtLoc`` instead of reconstituting it from the type-checking
environment. This makes ``newWanted`` consistent with ``newGiven``.
For authors of type-checking plugins, this means you don't need to wrap
a call to ``newWanted`` in ``setCtLocM`` to create a new Wanted constraint
with the provided ``CtLoc``.
|