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|
.. _options-optimise:
Optimisation (code improvement)
-------------------------------
.. index::
single: optimisation
single: improvement, code
The ``-O*`` options specify convenient "packages" of optimisation flags;
the ``-f*`` options described later on specify *individual*
optimisations to be turned on/off; the ``-m*`` options specify
*machine-specific* optimisations to be turned on/off.
Most of these options are boolean and have options to turn them both "on" and
"off" (beginning with the prefix ``no-``). For instance, while ``-fspecialise``
enables specialisation, ``-fno-specialise`` disables it. When multiple flags for
the same option appear in the command-line they are evaluated from left to
right. For instance, ``-fno-specialise -fspecialise`` will enable
specialisation.
It is important to note that the ``-O*`` flags are roughly equivalent to
combinations of ``-f*`` flags. For this reason, the effect of the
``-O*`` and ``-f*`` flags is dependent upon the order in which they
occur on the command line.
For instance, take the example of ``-fno-specialise -O1``. Despite the
``-fno-specialise`` appearing in the command line, specialisation will
still be enabled. This is the case as ``-O1`` implies ``-fspecialise``,
overriding the previous flag. By contrast, ``-O1 -fno-specialise`` will
compile without specialisation, as one would expect.
.. _optimise-pkgs:
``-O*``: convenient “packages” of optimisation flags.
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
There are *many* options that affect the quality of code produced by
GHC. Most people only have a general goal, something like "Compile
quickly" or "Make my program run like greased lightning." The following
"packages" of optimisations (or lack thereof) should suffice.
Note that higher optimisation levels cause more cross-module
optimisation to be performed, which can have an impact on how much of
your program needs to be recompiled when you change something. This is
one reason to stick to no-optimisation when developing code.
.. ghc-flag:: -O*
This is taken to mean: “Please compile quickly; I'm not
over-bothered about compiled-code quality.” So, for example:
``ghc -c Foo.hs``
.. ghc-flag:: -O0
Means "turn off all optimisation", reverting to the same settings as
if no ``-O`` options had been specified. Saying ``-O0`` can be
useful if e.g. ``make`` has inserted a ``-O`` on the command line
already.
.. ghc-flag:: -O
-O1
.. index::
single: optimise; normally
Means: "Generate good-quality code without taking too long about
it." Thus, for example: ``ghc -c -O Main.lhs``
.. ghc-flag:: -O2
.. index::
single: optimise; aggressively
Means: "Apply every non-dangerous optimisation, even if it means
significantly longer compile times."
The avoided "dangerous" optimisations are those that can make
runtime or space *worse* if you're unlucky. They are normally turned
on or off individually.
.. ghc-flag:: -Odph
.. index::
single: optimise; DPH
Enables all ``-O2`` optimisation, sets
``-fmax-simplifier-iterations=20`` and ``-fsimplifier-phases=3``.
Designed for use with :ref:`Data Parallel Haskell (DPH) <dph>`.
We don't use a ``-O*`` flag for day-to-day work. We use ``-O`` to get
respectable speed; e.g., when we want to measure something. When we want
to go for broke, we tend to use ``-O2`` (and we go for lots of coffee
breaks).
The easiest way to see what ``-O`` (etc.) “really mean” is to run with
:ghc-flag:`-v`, then stand back in amazement.
.. _options-f:
``-f*``: platform-independent flags
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
.. index::
single: -f\* options (GHC)
single: -fno-\* options (GHC)
These flags turn on and off individual optimisations. Flags marked as
on by default are enabled by ``-O``, and as such you shouldn't
need to set any of them explicitly. A flag ``-fwombat`` can be negated
by saying ``-fno-wombat``. See :ref:`options-f-compact` for a compact
list.
.. ghc-flag:: -fcase-merge
:default: on
Merge immediately-nested case expressions that scrutinise the same variable.
For example, ::
case x of
Red -> e1
_ -> case x of
Blue -> e2
Green -> e3
Is transformed to, ::
case x of
Red -> e1
Blue -> e2
Green -> e2
.. ghc-flag:: -fcase-folding
:default: on
Allow constant folding in case expressions that scrutinise some primops:
For example, ::
case x `minusWord#` 10## of
10## -> e1
20## -> e2
v -> e3
Is transformed to, ::
case x of
20## -> e1
30## -> e2
_ -> let v = x `minusWord#` 10## in e3
.. ghc-flag:: -fcall-arity
:default: on
Enable call-arity analysis.
.. ghc-flag:: -fcmm-elim-common-blocks
:default: on
Enables the common block elimination optimisation
in the code generator. This optimisation attempts to find identical
Cmm blocks and eliminate the duplicates.
.. ghc-flag:: -fcmm-sink
:default: on
Enables the sinking pass in the code generator.
This optimisation attempts to find identical Cmm blocks and
eliminate the duplicates attempts to move variable bindings closer
to their usage sites. It also inlines simple expressions like
literals or registers.
.. ghc-flag:: -fcpr-off
Switch off CPR analysis in the demand analyser.
.. ghc-flag:: -fcse
:default: on
Enables the common-sub-expression elimination
optimisation. Switching this off can be useful if you have some
``unsafePerformIO`` expressions that you don't want commoned-up.
.. ghc-flag:: -fstg-cse
:default: on
Enables the common-sub-expression elimination optimisation on the STG
intermediate language, where it is able to common up some subexpressions
that differ in their types, but not their represetation.
.. ghc-flag:: -fdicts-cheap
:default: off
A very experimental flag that makes dictionary-valued expressions
seem cheap to the optimiser.
.. ghc-flag:: -fdicts-strict
:default: off
Make dictionaries strict.
.. ghc-flag:: -fdmd-tx-dict-sel
:default: on
Use a special demand transformer for dictionary selectors.
.. ghc-flag:: -fdo-eta-reduction
:default: on
Eta-reduce lambda expressions, if doing so gets rid of a whole group of
lambdas.
.. ghc-flag:: -fdo-lambda-eta-expansion
:default: on
Eta-expand let-bindings to increase their arity.
.. ghc-flag:: -feager-blackholing
:default: off
Usually GHC black-holes a thunk only when it switches threads. This
flag makes it do so as soon as the thunk is entered. See `Haskell on
a shared-memory
multiprocessor <http://research.microsoft.com/en-us/um/people/simonpj/papers/parallel/>`__.
.. ghc-flag:: -fexcess-precision
:default: off
When this option is given, intermediate floating point values can
have a *greater* precision/range than the final type. Generally this
is a good thing, but some programs may rely on the exact
precision/range of ``Float``/``Double`` values and should not use
this option for their compilation.
Note that the 32-bit x86 native code generator only supports
excess-precision mode, so neither ``-fexcess-precision`` nor
``-fno-excess-precision`` has any effect. This is a known bug, see
:ref:`bugs-ghc`.
.. ghc-flag:: -fexpose-all-unfoldings
:default: off
An experimental flag to expose all unfoldings, even for very large
or recursive functions. This allows for all functions to be inlined
while usually GHC would avoid inlining larger functions.
.. ghc-flag:: -ffloat-in
:default: on
Float let-bindings inwards, nearer their binding
site. See `Let-floating: moving bindings to give faster programs
(ICFP'96) <http://research.microsoft.com/en-us/um/people/simonpj/papers/float.ps.gz>`__.
This optimisation moves let bindings closer to their use site. The
benefit here is that this may avoid unnecessary allocation if the
branch the let is now on is never executed. It also enables other
optimisation passes to work more effectively as they have more
information locally.
This optimisation isn't always beneficial though (so GHC applies
some heuristics to decide when to apply it). The details get
complicated but a simple example is that it is often beneficial to
move let bindings outwards so that multiple let bindings can be
grouped into a larger single let binding, effectively batching their
allocation and helping the garbage collector and allocator.
.. ghc-flag:: -ffull-laziness
:default: on
Run the full laziness optimisation (also known as
let-floating), which floats let-bindings outside enclosing lambdas,
in the hope they will be thereby be computed less often. See
`Let-floating: moving bindings to give faster programs
(ICFP'96) <http://research.microsoft.com/en-us/um/people/simonpj/papers/float.ps.gz>`__.
Full laziness increases sharing, which can lead to increased memory
residency.
.. note::
GHC doesn't implement complete full-laziness. When
optimisation in on, and ``-fno-full-laziness`` is not given, some
transformations that increase sharing are performed, such as
extracting repeated computations from a loop. These are the same
transformations that a fully lazy implementation would do, the
difference is that GHC doesn't consistently apply full-laziness, so
don't rely on it.
.. ghc-flag:: -ffun-to-thunk
:default: off
Worker-wrapper removes unused arguments, but usually we do not
remove them all, lest it turn a function closure into a thunk,
thereby perhaps creating a space leak and/or disrupting inlining.
This flag allows worker/wrapper to remove *all* value lambdas.
.. ghc-flag:: -fignore-asserts
:default: on
Causes GHC to ignore uses of the function ``Exception.assert`` in source
code (in other words, rewriting ``Exception.assert p e`` to ``e`` (see
:ref:`assertions`).
.. ghc-flag:: -fignore-interface-pragmas
:default: off
Tells GHC to ignore all inessential information when reading
interface files. That is, even if :file:`M.hi` contains unfolding or
strictness information for a function, GHC will ignore that
information.
.. ghc-flag:: -flate-dmd-anal
:default: off
Run demand analysis again, at the end of the simplification
pipeline. We found some opportunities for discovering strictness
that were not visible earlier; and optimisations like
:ghc-flag:`-fspec-constr` can create functions with unused arguments which
are eliminated by late demand analysis. Improvements are modest, but
so is the cost. See notes on the :ghc-wiki:`Trac wiki page <LateDmd>`.
.. ghc-flag:: -fliberate-case
:default: off but enabled with :ghc-flag:`-O2`.
Turn on the liberate-case transformation. This unrolls recursive function
once in its own RHS, to avoid repeated case analysis of free variables. It's
a bit like the call-pattern specialiser (:ghc-flag:`-fspec-constr`) but for
free variables rather than arguments.
.. ghc-flag:: -fliberate-case-threshold=<n>
:default: 2000
Set the size threshold for the liberate-case transformation.
.. ghc-flag:: -floopification
:default: on
When this optimisation is enabled the code generator will turn all
self-recursive saturated tail calls into local jumps rather than
function calls.
.. ghc-flag:: -fmax-inline-alloc-size=<n>
:default: 128
Set the maximum size of inline array allocations to n bytes.
GHC will allocate non-pinned arrays of statically known size in the current
nursery block if they're no bigger than n bytes, ignoring GC overheap. This
value should be quite a bit smaller than the block size (typically: 4096).
.. ghc-flag:: -fmax-inline-memcpy-insn=<n>
:default: 32
Inline ``memcpy`` calls if they would generate no more than ⟨n⟩ pseudo-instructions.
.. ghc-flag:: -fmax-inline-memset-insns=<n>
:default: 32
Inline ``memset`` calls if they would generate no more than n pseudo
instructions.
.. ghc-flag:: -fmax-relevant-binds=<n>
-fno-max-relevant-bindings
:default: 6
The type checker sometimes displays a fragment of the type
environment in error messages, but only up to some maximum number,
set by this flag. Turning it off with
``-fno-max-relevant-bindings`` gives an unlimited number.
Syntactically top-level bindings are also usually excluded (since
they may be numerous), but ``-fno-max-relevant-bindings`` includes
them too.
.. ghc-flag:: -fmax-uncovered-patterns=<n>
:default: 4
Maximum number of unmatched patterns to be shown in warnings generated by
:ghc-flag:`-Wincomplete-patterns` and :ghc-flag:`-Wincomplete-uni-patterns`.
.. ghc-flag:: -fmax-simplifier-iterations=<n>
:default: 4
Sets the maximal number of iterations for the simplifier.
.. ghc-flag:: -fmax-worker-args=<n>
:default: 10
If a worker has that many arguments, none will be unpacked anymore.
.. ghc-flag:: -fno-opt-coercion
:default: off
Turn off the coercion optimiser.
.. ghc-flag:: -fno-pre-inlining
:default: off
Turn off pre-inlining.
.. ghc-flag:: -fno-state-hack
:default: off
Turn off the "state hack" whereby any lambda with a ``State#`` token
as argument is considered to be single-entry, hence it is considered
okay to inline things inside it. This can improve performance of IO
and ST monad code, but it runs the risk of reducing sharing.
.. ghc-flag:: -fomit-interface-pragmas
:default: off
Tells GHC to omit all inessential information from the interface
file generated for the module being compiled (say M). This means
that a module importing M will see only the *types* of the functions
that M exports, but not their unfoldings, strictness info, etc.
Hence, for example, no function exported by M will be inlined into
an importing module. The benefit is that modules that import M will
need to be recompiled less often (only when M's exports change their
type, not when they change their implementation).
.. ghc-flag:: -fomit-yields
:default: on
Tells GHC to omit heap checks when no allocation is
being performed. While this improves binary sizes by about 5%, it
also means that threads run in tight non-allocating loops will not
get preempted in a timely fashion. If it is important to always be
able to interrupt such threads, you should turn this optimization
off. Consider also recompiling all libraries with this optimization
turned off, if you need to guarantee interruptibility.
.. ghc-flag:: -fpedantic-bottoms
Make GHC be more precise about its treatment of bottom (but see also
:ghc-flag:`-fno-state-hack`). In particular, stop GHC eta-expanding through
a case expression, which is good for performance, but bad if you are
using ``seq`` on partial applications.
.. ghc-flag:: -fregs-graph
:default: off due to a performance regression bug (:ghc-ticket:`7679`)
*Only applies in combination with the native code generator.* Use the graph
colouring register allocator for register allocation in the native code
generator. By default, GHC uses a simpler, faster linear register allocator.
The downside being that the linear register allocator usually generates
worse code.
Note that the graph colouring allocator is a bit experimental and may fail
when faced with code with high register pressure :ghc-ticket:`8657`.
.. ghc-flag:: -fregs-iterative
:default: off
*Only applies in combination with the native code generator.* Use the
iterative coalescing graph colouring register allocator for register
allocation in the native code generator. This is the same register allocator
as the :ghc-flag:`-fregs-graph` one but also enables iterative coalescing
during register allocation.
.. ghc-flag:: -fsimplifier-phases=<n>
:default: 2
Set the number of phases for the simplifier. Ignored with ``-O0``.
.. ghc-flag:: -fsimpl-tick-factor=<n>
:default: 100
GHC's optimiser can diverge if you write rewrite rules
(:ref:`rewrite-rules`) that don't terminate, or (less satisfactorily)
if you code up recursion through data types (:ref:`bugs-ghc`). To
avoid making the compiler fall into an infinite loop, the optimiser
carries a "tick count" and stops inlining and applying rewrite rules
when this count is exceeded. The limit is set as a multiple of the
program size, so bigger programs get more ticks. The
``-fsimpl-tick-factor`` flag lets you change the multiplier. The
default is 100; numbers larger than 100 give more ticks, and numbers
smaller than 100 give fewer.
If the tick-count expires, GHC summarises what simplifier steps it
has done; you can use ``-fddump-simpl-stats`` to generate a much
more detailed list. Usually that identifies the loop quite
accurately, because some numbers are very large.
.. ghc-flag:: -fspec-constr
:default: off but enabled by :ghc-flag:`-O2`.
Turn on call-pattern specialisation; see `Call-pattern specialisation for
Haskell programs
<https://www.microsoft.com/en-us/research/publication/system-f-with-type-equality-coercions-2/>`__.
This optimisation specializes recursive functions according to their
argument "shapes". This is best explained by example so consider: ::
last :: [a] -> a
last [] = error "last"
last (x : []) = x
last (x : xs) = last xs
In this code, once we pass the initial check for an empty list we
know that in the recursive case this pattern match is redundant. As
such ``-fspec-constr`` will transform the above code to: ::
last :: [a] -> a
last [] = error "last"
last (x : xs) = last' x xs
where
last' x [] = x
last' x (y : ys) = last' y ys
As well avoid unnecessary pattern matching it also helps avoid
unnecessary allocation. This applies when a argument is strict in
the recursive call to itself but not on the initial entry. As strict
recursive branch of the function is created similar to the above
example.
It is also possible for library writers to instruct GHC to perform
call-pattern specialisation extremely aggressively. This is
necessary for some highly optimized libraries, where we may want to
specialize regardless of the number of specialisations, or the size
of the code. As an example, consider a simplified use-case from the
``vector`` library: ::
import GHC.Types (SPEC(..))
foldl :: (a -> b -> a) -> a -> Stream b -> a
{-# INLINE foldl #-}
foldl f z (Stream step s _) = foldl_loop SPEC z s
where
foldl_loop !sPEC z s = case step s of
Yield x s' -> foldl_loop sPEC (f z x) s'
Skip -> foldl_loop sPEC z s'
Done -> z
Here, after GHC inlines the body of ``foldl`` to a call site, it
will perform call-pattern specialisation very aggressively on
``foldl_loop`` due to the use of ``SPEC`` in the argument of the
loop body. ``SPEC`` from ``GHC.Types`` is specifically recognised by
the compiler.
(NB: it is extremely important you use ``seq`` or a bang pattern on
the ``SPEC`` argument!)
In particular, after inlining this will expose ``f`` to the loop
body directly, allowing heavy specialisation over the recursive
cases.
.. ghc-flag:: -fspec-constr-keen
:default: off
If this flag is on, call-patten specialision will specialise a call
``(f (Just x))`` with an explicit constructor agument, even if the argument
is not scrutinised in the body of the function. This is sometimes
beneficial; e.g. the argument might be given to some other function
that can itself be specialised.
.. ghc-flag:: -fspec-constr-count=<n>
:default: 3
Set the maximum number of specialisations that will be created for
any one function by the SpecConstr transformation.
.. ghc-flag:: -fspec-constr-threshold=<n>
:default: 2000
Set the size threshold for the SpecConstr transformation.
.. ghc-flag:: -fspecialise
:default: on
Specialise each type-class-overloaded function
defined in this module for the types at which it is called in this
module. If :ghc-flag:`-fcross-module-specialise` is set imported functions
that have an INLINABLE pragma (:ref:`inlinable-pragma`) will be
specialised as well.
.. ghc-flag:: -fspecialise-aggressively
:default: off
By default only type class methods and methods marked ``INLINABLE`` or
``INLINE`` are specialised. This flag will specialise any overloaded function
regardless of size if its unfolding is available. This flag is not
included in any optimisation level as it can massively increase code
size. It can be used in conjunction with :ghc-flag:`-fexpose-all-unfoldings`
if you want to ensure all calls are specialised.
.. ghc-flag:: -fcross-module-specialise
:default: on
Specialise ``INLINABLE`` (:ref:`inlinable-pragma`)
type-class-overloaded functions imported from other modules for the types at
which they are called in this module. Note that specialisation must be
enabled (by ``-fspecialise``) for this to have any effect.
.. ghc-flag:: -fsolve-constant-dicts
:default: on
When solving constraints, try to eagerly solve
super classes using availible dictionaries.
For example::
class M a b where m :: a -> b
type C a b = (Num a, M a b)
f :: C Int b => b -> Int -> Int
f _ x = x + 1
The body of `f` requires a `Num Int` instance. We could solve this
constraint from the context because we have `C Int b` and that provides us
a
solution for `Num Int`. However, we can often produce much better code
by directly solving for an availible `Num Int` dictionary we might have at
hand. This removes potentially many layers of indirection and crucially
allows other optimisations to fire as the dictionary will be statically
known and selector functions can be inlined.
The optimisation also works for GADTs which bind dictionaries. If we
statically know which class dictionary we need then we will solve it
directly rather than indirectly using the one passed in at run time.
.. ghc-flag:: -fstatic-argument-transformation
:default: off
Turn on the static argument transformation, which turns a recursive
function into a non-recursive one with a local recursive loop. See
Chapter 7 of `Andre Santos's PhD
thesis <http://research.microsoft.com/en-us/um/people/simonpj/papers/santos-thesis.ps.gz>`__
.. ghc-flag:: -fstrictness
:default: on
Switch on the strictness analyser. There is a very
old paper about GHC's strictness analyser, `Measuring the
effectiveness of a simple strictness
analyser <http://research.microsoft.com/en-us/um/people/simonpj/papers/simple-strictnes-analyser.ps.gz>`__,
but the current one is quite a bit different.
The strictness analyser figures out when arguments and variables in
a function can be treated 'strictly' (that is they are always
evaluated in the function at some point). This allow GHC to apply
certain optimisations such as unboxing that otherwise don't apply as
they change the semantics of the program when applied to lazy
arguments.
.. ghc-flag:: -fstrictness-before=⟨n⟩
Run an additional strictness analysis before simplifier phase ⟨n⟩.
.. ghc-flag:: -funbox-small-strict-fields
:default: on
.. index::
single: strict constructor fields
single: constructor fields, strict
This option causes all constructor fields which
are marked strict (i.e. “!”) and which representation is smaller or
equal to the size of a pointer to be unpacked, if possible. It is
equivalent to adding an ``UNPACK`` pragma (see :ref:`unpack-pragma`)
to every strict constructor field that fulfils the size restriction.
For example, the constructor fields in the following data types ::
data A = A !Int
data B = B !A
newtype C = C B
data D = D !C
would all be represented by a single ``Int#`` (see
:ref:`primitives`) value with ``-funbox-small-strict-fields``
enabled.
This option is less of a sledgehammer than
``-funbox-strict-fields``: it should rarely make things worse. If
you use ``-funbox-small-strict-fields`` to turn on unboxing by
default you can disable it for certain constructor fields using the
``NOUNPACK`` pragma (see :ref:`nounpack-pragma`).
Note that for consistency ``Double``, ``Word64``, and ``Int64``
constructor fields are unpacked on 32-bit platforms, even though
they are technically larger than a pointer on those platforms.
.. ghc-flag:: -funbox-strict-fields
:default: off
.. index::
single: strict constructor fields
single: constructor fields, strict
This option causes all constructor fields which are marked strict
(i.e. ``!``) to be unpacked if possible. It is equivalent to adding an
``UNPACK`` pragma to every strict constructor field (see
:ref:`unpack-pragma`).
This option is a bit of a sledgehammer: it might sometimes make
things worse. Selectively unboxing fields by using ``UNPACK``
pragmas might be better. An alternative is to use
``-funbox-strict-fields`` to turn on unboxing by default but disable
it for certain constructor fields using the ``NOUNPACK`` pragma (see
:ref:`nounpack-pragma`).
Alternatively you can use :ghc-flag:`-funbox-small-strict-fields` to only
unbox strict fields which are "small".
.. ghc-flag:: -funfolding-creation-threshold=<n>
:default: 750
.. index::
single: inlining, controlling
single: unfolding, controlling
Governs the maximum size that GHC will allow a
function unfolding to be. (An unfolding has a “size” that reflects
the cost in terms of “code bloat” of expanding (aka inlining) that
unfolding at a call site. A bigger function would be assigned a
bigger cost.)
Consequences:
a. nothing larger than this will be inlined (unless it has an ``INLINE`` pragma)
b. nothing larger than this will be spewed into an interface file.
Increasing this figure is more likely to result in longer compile
times than faster code. The :ghc-flag:`-funfolding-use-threshold` is more
useful.
.. ghc-flag:: -funfolding-dict-discount=<n>
:default: 30
.. index::
single: inlining, controlling
single: unfolding, controlling
How eager should the compiler be to inline dictionaries?
.. ghc-flag:: -funfolding-fun-discount=<n>
:default: 60
.. index::
single: inlining, controlling
single: unfolding, controlling
How eager should the compiler be to inline functions?
.. ghc-flag:: -funfolding-keeness-factor=<n>
:default: 1.5
.. index::
single: inlining, controlling
single: unfolding, controlling
How eager should the compiler be to inline functions?
.. ghc-flag:: -funfolding-use-threshold=<n>
:default: 60
.. index::
single: inlining, controlling
single: unfolding, controlling
This is the magic cut-off figure for unfolding (aka
inlining): below this size, a function definition will be unfolded
at the call-site, any bigger and it won't. The size computed for a
function depends on two things: the actual size of the expression
minus any discounts that apply depending on the context into which
the expression is to be inlined.
The difference between this and :ghc-flag:`-funfolding-creation-threshold`
is that this one determines if a function definition will be inlined
*at a call site*. The other option determines if a function
definition will be kept around at all for potential inlining.
.. ghc-flag:: -fvectorisation-avoidance
:default: on
.. index::
single: -fvectorisation-avoidance
Part of :ref:`Data Parallel Haskell (DPH) <dph>`.
Enable the *vectorisation* avoidance optimisation.
This optimisation only works when used in combination with the
``-fvectorise`` transformation.
While vectorisation of code using DPH is often a big win, it can
also produce worse results for some kinds of code. This optimisation
modifies the vectorisation transformation to try to determine if a
function would be better of unvectorised and if so, do just that.
.. ghc-flag:: -fvectorise
:default: off
Part of :ref:`Data Parallel Haskell (DPH) <dph>`.
Enable the *vectorisation* optimisation
transformation. This optimisation transforms the nested data
parallelism code of programs using DPH into flat data parallelism.
Flat data parallel programs should have better load balancing,
enable SIMD parallelism and friendlier cache behaviour.
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