7. Extending and using GHC as a Library¶
GHC exposes its internal APIs to users through the built-in ghc package. It allows you to write programs that leverage GHC’s entire compilation driver, in order to analyze or compile Haskell code programmatically. Furthermore, GHC gives users the ability to load compiler plugins during compilation - modules which are allowed to view and change GHC’s internal intermediate representation, Core. Plugins are suitable for things like experimental optimizations or analysis, and offer a lower barrier of entry to compiler development for many common cases.
Furthermore, GHC offers a lightweight annotation mechanism that you can use to annotate your source code with metadata, which you can later inspect with either the compiler API or a compiler plugin.
7.1. Source annotations¶
Annotations are small pragmas that allow you to attach data to identifiers in source code, which are persisted when compiled. These pieces of data can then inspected and utilized when using GHC as a library or writing a compiler plugin.
7.1.1. Annotating values¶
Any expression that has both Typeable
and Data
instances may be
attached to a top-level value binding using an ANN
pragma. In
particular, this means you can use ANN
to annotate data constructors
(e.g. Just
) as well as normal values (e.g. take
). By way of
example, to annotate the function foo
with the annotation
Just "Hello"
you would do this:
{-# ANN foo (Just "Hello") #-}
foo = ...
A number of restrictions apply to use of annotations:
The binder being annotated must be at the top level (i.e. no nested binders)
The binder being annotated must be declared in the current module
The expression you are annotating with must have a type with
Typeable
andData
instancesThe Template Haskell staging restrictions apply to the expression being annotated with, so for example you cannot run a function from the module being compiled.
To be precise, the annotation
{-# ANN x e #-}
is well staged if and only if$(e)
would be (disregarding the usual type restrictions of the splice syntax, and the usual restriction on splicing inside a splice -$([|1|])
is fine as an annotation, albeit redundant).
If you feel strongly that any of these restrictions are too onerous, please give the GHC team a shout.
However, apart from these restrictions, many things are allowed, including expressions which are not fully evaluated! Annotation expressions will be evaluated by the compiler just like Template Haskell splices are. So, this annotation is fine:
{-# ANN f SillyAnnotation { foo = (id 10) + $([| 20 |]), bar = 'f } #-}
f = ...
7.1.2. Annotating types¶
You can annotate types with the ANN
pragma by using the type
keyword. For example:
{-# ANN type Foo (Just "A `Maybe String' annotation") #-}
data Foo = ...
7.1.3. Annotating modules¶
You can annotate modules with the ANN
pragma by using the module
keyword. For example:
{-# ANN module (Just "A `Maybe String' annotation") #-}
7.2. Using GHC as a Library¶
The ghc
package exposes most of GHC’s frontend to users, and thus
allows you to write programs that leverage it. This library is actually
the same library used by GHC’s internal, frontend compilation driver,
and thus allows you to write tools that programmatically compile source
code and inspect it. Such functionality is useful in order to write
things like IDE or refactoring tools. As a simple example, here’s a
program which compiles a module, much like ghc itself does by default
when invoked:
import GHC
import GHC.Paths ( libdir )
import GHC.Driver.Session ( defaultFatalMessager, defaultFlushOut )
main =
defaultErrorHandler defaultFatalMessager defaultFlushOut $ do
runGhc (Just libdir) $ do
dflags <- getSessionDynFlags
setSessionDynFlags dflags
target <- guessTarget "test_main.hs" Nothing
setTargets [target]
load LoadAllTargets
The argument to runGhc
is a bit tricky. GHC needs this to find its
libraries, so the argument must refer to the directory that is printed
by ghc --print-libdir
for the same version of GHC that the program
is being compiled with. Above we therefore use the ghc-paths
package
which provides this for us.
Compiling it results in:
$ cat test_main.hs
main = putStrLn "hi"
$ ghc -package ghc simple_ghc_api.hs
[1 of 1] Compiling Main ( simple_ghc_api.hs, simple_ghc_api.o )
Linking simple_ghc_api ...
$ ./simple_ghc_api
$ ./test_main
hi
$
For more information on using the API, as well as more samples and references, please see this Haskell.org wiki page.
7.3. Compiler Plugins¶
GHC has the ability to load compiler plugins at compile time. The feature is similar to the one provided by GCC, and allows users to write plugins that can adjust the behaviour of the constraint solver, inspect and modify the compilation pipeline, as well as transform and inspect GHC’s intermediate language, Core. Plugins are suitable for experimental analysis or optimization, and require no changes to GHC’s source code to use.
Plugins cannot optimize/inspect C--, nor can they implement things like parser/front-end modifications like GCC, apart from limited changes to the constraint solver. If you feel strongly that any of these restrictions are too onerous, please give the GHC team a shout.
Plugins do not work with -fexternal-interpreter
. If you need to run plugins
with -fexternal-interpreter
let GHC developers know in #%s14335.
7.3.1. Using compiler plugins¶
Plugins can be added on the command line with the -fplugin=⟨module⟩
option where ⟨module⟩ is a module in a registered package that exports the
plugin. Plugins are loaded in order, with command-line and Cabal flags preceding
those in OPTIONS pragmas which are processed in file order. Arguments can be
passed to the plugins with the -fplugin-opt=⟨module⟩:⟨args⟩
option. The list of enabled plugins can be reset with the
-fclear-plugins
option.
-
-fplugin
=⟨module⟩
¶ Load the plugin in the given module. The module must be a member of a package registered in GHC’s package database.
-
-fplugin-opt
=⟨module⟩:⟨args⟩
¶ Give arguments to a plugin module; module must be specified with
-fplugin=⟨module⟩
. The order of plugin pragmas matter but the order of arg pragmas does not. The same set of arguments go to all plugins from the same module.-- Two Echo plugins will both get args A and B. {-# OPTIONS -fplugin Echo -fplugin-opt Echo:A #-} {-# OPTIONS -fplugin Echo -fplugin-opt Echo:B #-} -- While order of the plugins matters, arg order does not. {-# OPTIONS -fplugin-opt Echo2:B #-} {-# OPTIONS -fplugin Echo1 #-} {-# OPTIONS -fplugin-opt Echo1:A #-} {-# OPTIONS -fplugin Echo2 #-}
If you want to use the same plugin with different arguments then rexport the same plugin from different lightweight modules.
-- Echo1 and Echo2 as lightweight modules re-exporting Echo.plugin. module Echo1 (plugin) where import Echo (plugin) module Echo2 (plugin) where import Echo (plugin) -- Echo1 gets arg A while Echo2 gets arg B. {-# OPTIONS -fplugin Echo1 -fplugin-opt Echo1:A #-} {-# OPTIONS -fplugin Echo2 -fplugin-opt Echo2:B #-}
-
-fplugin-trustworthy
¶ By default, when a module is compiled with plugins, it will be marked as unsafe. With this flag passed, all plugins are treated as trustworthy and the safety inference will no longer be affected.
-
-fclear-plugins
¶ Clear the list of plugins previously specified with
-fplugin
. This is useful in GHCi where simply removing the-fplugin
options from the command line is not possible. Instead:set -fclear-plugins
can be used.
As an example, in order to load the plugin exported by Foo.Plugin
in
the package foo-ghc-plugin
, and give it the parameter “baz”, we
would invoke GHC like this:
$ ghc -fplugin Foo.Plugin -fplugin-opt Foo.Plugin:baz Test.hs
[1 of 1] Compiling Main ( Test.hs, Test.o )
Loading package ghc-prim ... linking ... done.
Loading package integer-gmp ... linking ... done.
Loading package base ... linking ... done.
Loading package ffi-1.0 ... linking ... done.
Loading package foo-ghc-plugin-0.1 ... linking ... done.
...
Linking Test ...
$
Plugins can be also be loaded from libraries directly. It allows plugins to be loaded in cross-compilers (as a workaround for #%s14335).
-
-fplugin-library
=⟨file-path⟩;⟨unit-id⟩;⟨module⟩;⟨args⟩
¶ Arguments are specified in a list form, so a plugin specified to
-fplugin-library=⟨file-path⟩;⟨unit-id⟩;⟨module⟩;⟨args⟩
will look like'path/to/plugin;package-123;Plugin.Module;["Argument","List"]'
.
Alternatively, core plugins can be specified with Template Haskell.
addCorePlugin "Foo.Plugin"
This inserts the plugin as a core-to-core pass. Unlike -fplugin=(module), the plugin module can’t reside in the same package as the module calling Language.Haskell.TH.Syntax.addCorePlugin. This way, the implementation can expect the plugin to be built by the time it is needed.
Plugin modules live in a separate namespace from the user import namespace. By default, these two namespaces are the same; however, there are a few command line options which control specifically plugin packages:
-
-plugin-package
⟨pkg⟩
¶ This option causes the installed package ⟨pkg⟩ to be exposed for plugins, such as
-fplugin=⟨module⟩
. The package ⟨pkg⟩ can be specified in full with its version number (e.g.network-1.0
) or the version number can be omitted if there is only one version of the package installed. If there are multiple versions of ⟨pkg⟩ installed and-hide-all-plugin-packages
was not specified, then all other versions will become hidden.-plugin-package ⟨pkg⟩
supports thinning and renaming described in Thinning and renaming modules.Unlike
-package ⟨pkg⟩
, this option does NOT cause package ⟨pkg⟩ to be linked into the resulting executable or shared object.
-
-plugin-package-id
⟨pkg-id⟩
¶ Exposes a package in the plugin namespace like
-plugin-package ⟨pkg⟩
, but the package is named by its installed package ID rather than by name. This is a more robust way to name packages, and can be used to select packages that would otherwise be shadowed. Cabal passes-plugin-package-id ⟨pkg-id⟩
flags to GHC.-plugin-package-id ⟨pkg-id⟩
supports thinning and renaming described in Thinning and renaming modules.
-
-hide-all-plugin-packages
¶ By default, all exposed packages in the normal, source import namespace are also available for plugins. This causes those packages to be hidden by default. If you use this flag, then any packages with plugins you require need to be explicitly exposed using
-plugin-package ⟨pkg⟩
options.
At the moment, the only way to specify a dependency on a plugin
in Cabal is to put it in build-depends
(which uses the conventional
-package-id ⟨unit-id⟩
flag); however, in the future there
will be a separate field for specifying plugin dependencies specifically.
7.3.2. Writing compiler plugins¶
Plugins are modules that export at least a single identifier,
plugin
, of type GHC.Plugins.Plugin
. All plugins should
import GHC.Plugins
as it defines the interface to the compilation
pipeline.
A Plugin
effectively holds a function which installs a compilation
pass into the compiler pipeline. By default there is the empty plugin
which does nothing, GHC.Plugins.defaultPlugin
, which you should
override with record syntax to specify your installation function. Since
the exact fields of the Plugin
type are open to change, this is the
best way to ensure your plugins will continue to work in the future with
minimal interface impact.
Plugin
exports a field, installCoreToDos
which is a function of
type [CommandLineOption] -> [CoreToDo] -> CoreM [CoreToDo]
. A
CommandLineOption
is effectively just String
, and a CoreToDo
is basically a function of type Core -> Core
. A CoreToDo
gives
your pass a name and runs it over every compiled module when you invoke
GHC.
As a quick example, here is a simple plugin that just does nothing and just returns the original compilation pipeline, unmodified, and says ‘Hello’:
module DoNothing.Plugin (plugin) where
import GHC.Plugins
plugin :: Plugin
plugin = defaultPlugin {
installCoreToDos = install
}
install :: [CommandLineOption] -> [CoreToDo] -> CoreM [CoreToDo]
install _ todo = do
putMsgS "Hello!"
return todo
Provided you compiled this plugin and registered it in a package (with
cabal for instance,) you can then use it by just specifying
-fplugin=DoNothing.Plugin
on the command line, and during the
compilation you should see GHC say ‘Hello’.
Running multiple plugins is also supported, by passing
multiple -fplugin=...
options. GHC will load the plugins
in the order in which they are specified on the command line
and, when appropriate, compose their effects in the same
order. That is, if we had two Core plugins, Plugin1
and
Plugin2
, each defining an install
function like
the one above, then GHC would first run Plugin1.install
on the default [CoreToDo]
, take the result and feed it to
Plugin2.install
. -fplugin=Plugin1 -fplugin=Plugin2
will update the Core pipeline by applying
Plugin1.install opts1 >=> Plugin2.install opts2
(where
opts1
and opts2
are the options passed to each plugin
using -fplugin-opt=...
). This is not specific to Core
plugins but holds for all the types of plugins that can be
composed or sequenced in some way: the first plugin to appear
on the GHC command line will always act first.
7.3.3. Core plugins in more detail¶
CoreToDo
is effectively a data type that describes all the kinds of
optimization passes GHC does on Core. There are passes for
simplification, CSE, etc. There is a specific case for
plugins, CoreDoPluginPass :: String -> PluginPass -> CoreToDo
which
should be what you always use when inserting your own pass into the
pipeline. The first parameter is the name of the plugin, and the second
is the pass you wish to insert.
CoreM
is a monad that all of the Core optimizations live and operate
inside of.
A plugin’s installation function (install
in the above example)
takes a list of CoreToDo
s and returns a list of CoreToDo
.
Before GHC begins compiling modules, it enumerates all the needed
plugins you tell it to load, and runs all of their installation
functions, initially on a list of passes that GHC specifies itself.
After doing this for every plugin, the final list of passes is given to
the optimizer, and are run by simply going over the list in order.
You should be careful with your installation function, because the list of passes you give back isn’t questioned or double checked by GHC at the time of this writing. An installation function like the following:
install :: [CommandLineOption] -> [CoreToDo] -> CoreM [CoreToDo]
install _ _ = return []
is certainly valid, but also certainly not what anyone really wants.
7.3.3.1. Manipulating bindings¶
In the last section we saw that besides a name, a CoreDoPluginPass
takes a pass of type PluginPass
. A PluginPass
is a synonym for
(ModGuts -> CoreM ModGuts)
. ModGuts
is a type that represents
the one module being compiled by GHC at any given time.
A ModGuts
holds all of the module’s top level bindings which we can
examine. These bindings are of type CoreBind
and effectively
represent the binding of a name to body of code. Top-level module
bindings are part of a ModGuts
in the field mg_binds
.
Implementing a pass that manipulates the top level bindings merely needs
to iterate over this field, and return a new ModGuts
with an updated
mg_binds
field. Because this is such a common case, there is a
function provided named bindsOnlyPass
which lifts a function of type
([CoreBind] -> CoreM [CoreBind])
to type
(ModGuts -> CoreM ModGuts)
.
Continuing with our example from the last section, we can write a simple plugin that just prints out the name of all the non-recursive bindings in a module it compiles:
module SayNames.Plugin (plugin) where
import GHC.Plugins
plugin :: Plugin
plugin = defaultPlugin {
installCoreToDos = install
}
install :: [CommandLineOption] -> [CoreToDo] -> CoreM [CoreToDo]
install _ todo = do
return (CoreDoPluginPass "Say name" pass : todo)
pass :: ModGuts -> CoreM ModGuts
pass guts = do dflags <- getDynFlags
bindsOnlyPass (mapM (printBind dflags)) guts
where printBind :: DynFlags -> CoreBind -> CoreM CoreBind
printBind dflags bndr@(NonRec b _) = do
putMsgS $ "Non-recursive binding named " ++ showSDoc dflags (ppr b)
return bndr
printBind _ bndr = return bndr
7.3.3.2. Using Annotations¶
Previously we discussed annotation pragmas (Source annotations),
which we mentioned could be used to give compiler plugins extra guidance
or information. Annotations for a module can be retrieved by a plugin,
but you must go through the modules ModGuts
in order to get it.
Because annotations can be arbitrary instances of Data
and
Typeable
, you need to give a type annotation specifying the proper
type of data to retrieve from the interface file, and you need to make
sure the annotation type used by your users is the same one your plugin
uses. For this reason, we advise distributing annotations as part of the
package which also provides compiler plugins if possible.
To get the annotations of a single binder, you can use
getAnnotations
and specify the proper type. Here’s an example that
will print out the name of any top-level non-recursive binding with the
SomeAnn
annotation:
{-# LANGUAGE DeriveDataTypeable #-}
module SayAnnNames.Plugin (plugin, SomeAnn(..)) where
import GHC.Plugins
import Control.Monad (unless)
import Data.Data
data SomeAnn = SomeAnn deriving Data
plugin :: Plugin
plugin = defaultPlugin {
installCoreToDos = install
}
install :: [CommandLineOption] -> [CoreToDo] -> CoreM [CoreToDo]
install _ todo = do
return (CoreDoPluginPass "Say name" pass : todo)
pass :: ModGuts -> CoreM ModGuts
pass g = do
dflags <- getDynFlags
mapM_ (printAnn dflags g) (mg_binds g) >> return g
where printAnn :: DynFlags -> ModGuts -> CoreBind -> CoreM CoreBind
printAnn dflags guts bndr@(NonRec b _) = do
anns <- annotationsOn guts b :: CoreM [SomeAnn]
unless (null anns) $ putMsgS $ "Annotated binding found: " ++ showSDoc dflags (ppr b)
return bndr
printAnn _ _ bndr = return bndr
annotationsOn :: Data a => ModGuts -> CoreBndr -> CoreM [a]
annotationsOn guts bndr = do
(_, anns) <- getAnnotations deserializeWithData guts
return $ lookupWithDefaultUFM_Directly anns [] (varUnique bndr)
Please see the GHC API documentation for more about how to use internal APIs, etc.
7.3.4. Typechecker plugins¶
In addition to Core plugins, GHC has experimental support for typechecker plugins, which allow the behaviour of the constraint solver to be modified. For example, they make it possible to interface the compiler to an SMT solver, in order to support a richer theory of type-level arithmetic expressions than the theory built into GHC (see Computing With Type-Level Naturals).
The Plugin
type has a field tcPlugin
of type
[CommandLineOption] -> Maybe TcPlugin
, where the TcPlugin
type
is defined thus:
data TcPlugin = forall s . TcPlugin
{ tcPluginInit :: TcPluginM s
, tcPluginSolve :: s -> TcPluginSolver
, tcPluginRewrite :: s -> UniqFM TyCon TcPluginRewriter
, tcPluginStop :: s -> TcPluginM ()
}
type TcPluginSolver = EvBindsVar -> [Ct] -> [Ct] -> [Ct] -> TcPluginM TcPluginSolveResult
type TcPluginRewriter = RewriteEnv -> [Ct] -> [Type] -> TcPluginM TcPluginRewriteResult
data TcPluginSolveResult
= TcPluginSolveResult
{ tcPluginInsolubleCts :: [Ct]
, tcPluginSolvedCts :: [(EvTerm, Ct)]
, tcPluginNewCts :: [Ct]
}
data TcPluginRewriteResult
= TcPluginNoRewrite
| TcPluginRewriteTo
{ tcPluginRewriteTo :: Reduction
, tcRewriterNewWanteds :: [Ct]
}
(The details of this representation are subject to change as we gain more experience writing typechecker plugins. It should not be assumed to be stable between GHC releases.)
The basic idea is as follows:
- When type checking a module, GHC calls
tcPluginInit
once before constraint solving starts. This allows the plugin to look things up in the context, initialise mutable state or open a connection to an external process (e.g. an external SMT solver). The plugin can return a result of any type it likes, and the result will be passed to the other fields of theTcPlugin
record. - During constraint solving, GHC repeatedly calls
tcPluginSolve
. This function is provided with the current set of constraints, and should return aTcPluginSolveResult
that indicates whether a contradiction was found or progress was made. If the plugin solver makes progress, GHC will re-start the constraint solving pipeline, looping until a fixed point is reached. - When rewriting type family applications, GHC calls
tcPluginRewriter
. The plugin supplies a collection of type families which it is interested in rewriting. For each of those, the rewriter is provided with the the arguments to that type family, as well as the current collection of Given constraints. The plugin can then specify a rewriting for this type family application, if desired. - Finally, GHC calls
tcPluginStop
after constraint solving is finished, allowing the plugin to dispose of any resources it has allocated (e.g. terminating the SMT solver process).
Plugin code runs in the TcPluginM
monad, which provides a restricted
interface to GHC API functionality that is relevant for typechecker
plugins, including IO
and reading the environment. If you need
functionality that is not exposed in the TcPluginM
module, you can
use unsafeTcPluginTcM :: TcM a -> TcPluginM a
, but are encouraged to
contact the GHC team to suggest additions to the interface. Note that
TcPluginM
can perform arbitrary IO via
tcPluginIO :: IO a -> TcPluginM a
, although some care must be taken
with side effects (particularly in tcPluginSolve
). In general, it is
up to the plugin author to make sure that any IO they do is safe.
7.3.4.1. Constraint solving with plugins¶
The key component of a typechecker plugin is a function of type
TcPluginSolver
, like this:
solve :: EvBindsVar -> [Ct] -> [Ct] -> TcPluginM TcPluginSolveResult
solve binds givens wanteds = ...
This function will be invoked in two different ways:
- after simplification of Given constraints, where the plugin gets the opportunity to rewrite givens,
- after GHC has attempted to solve Wanted constraints.
The two ways can be distinguished by checking the Wanted constraints: in the first case (and the first case only), the plugin will be passed an empty list of Wanted constraints.
The plugin can then respond with:
- solved constraints, which will be removed from the inert set,
- new constraints, which will be added to the work list,
- insoluble constraints, which will be reported as errors.
The plugin must respond with constraints of the same flavour, i.e. in (1) it should return only Givens, and for (2) it should return only Wanteds; all other constraints will be ignored.
If the plugin cannot make any progress, it should return
TcPluginSolveResult [] [] []
. Otherwise, if there were any new constraints,
the main constraint solver will be re-invoked to simplify them, then the
plugin will be invoked again. The plugin is responsible for making sure
that this process eventually terminates.
Plugins are provided with all available constraints (including equalities and typeclass constraints), but it is easy for them to discard those that are not relevant to their domain, because they need return only those constraints for which they have made progress (either by solving or contradicting them).
Constraints that have been solved by the plugin must be provided with
evidence in the form of an EvTerm
of the type of the constraint.
This evidence is ignored for Given constraints, which GHC
“solves” simply by discarding them; typically this is used when they are
uninformative (e.g. reflexive equations). For Wanted constraints, the
evidence will form part of the Core term that is generated after
typechecking, and can be checked by -dcore-lint
. It is possible for
the plugin to create equality axioms for use in evidence terms, but GHC
does not check their consistency, and inconsistent axiom sets may lead
to segfaults or other runtime misbehaviour.
Evidence is required also when creating new Given constraints, which are usually implied by old ones. It is not uncommon that the evidence of a new Given constraint contains a removed constraint: the new one has replaced the removed one.
7.3.4.2. Type family rewriting with plugins¶
Typechecker plugins can also directly rewrite type family applications,
by supplying the tcPluginRewrite
field of the TcPlugin
record.
tcPluginRewrite :: s -> UniqFM TyCon TcPluginRewriter
That is, the plugin registers a map, from a type family’s TyCon
to its
associated rewriting function:
type TcPluginRewriter = [Ct] -> [Type] -> TcPluginM TcPluginRewriteResult
This rewriting function is supplied with the Given constraints from the current context, and the type family arguments. Note that the type family application is guaranteed to be exactly saturated. This function should then return a possible rewriting of the type family application, by means of the following datatype:
data TcPluginRewriteResult
= TcPluginNoRewrite
| TcPluginRewriteTo
{ tcPluginRewriteTo :: Reduction
, tcRewriterNewWanteds :: [Ct]
}
That is, the rewriter can specify a rewriting of the type family application – in which case it can also emit new Wanted constraints – or it can do nothing.
To specify a rewriting, the plugin must provide a Reduction
, which is
defined as follows:
data Reduction = Reduction Coercion !Type
That is, on top of specifying what type the type-family application rewrites to, the plugin must also supply a coercion which witnesses this rewriting:
co :: F orig_arg_1 ... orig_arg_n ~ rewritten_ty
Note in particular that the LHS type of the coercion should be the original type-family application, while its RHS type is the type that the plugin wants to rewrite the type-family application to.
7.3.5. Source plugins¶
In addition to core and type checker plugins, you can install plugins that can access different representations of the source code. The main purpose of these plugins is to make it easier to implement development tools.
There are several different access points that you can use for defining plugins
that access the representations. All these fields receive the list of
CommandLineOption
strings that are passed to the compiler using the
-fplugin-opt=⟨module⟩:⟨args⟩
flags.
plugin :: Plugin
plugin = defaultPlugin {
parsedResultAction = parsed
, typeCheckResultAction = typechecked
, spliceRunAction = spliceRun
, interfaceLoadAction = interfaceLoad
, renamedResultAction = renamed
}
7.3.5.1. Parsed representation¶
When you want to define a plugin that uses the syntax tree of the source code,
you would like to override the parsedResultAction
field. This access point
enables you to get access to information about the lexical tokens and comments
in the source code as well as the original syntax tree of the compiled module.
parsed :: [CommandLineOption] -> ModSummary
-> ParsedResult -> Hsc ParsedResult
The ModSummary
contains useful
meta-information about the compiled module. The ParsedResult
contains a
HsParsedModule
, which contains the lexical and syntactical information we
mentioned before. The result that you return will change the result of the
parsing. If you don’t want to change the result, just return the
ParsedResult
that you received as the argument.
If the parser encounters any errors that prevent an AST from being constructed,
the plugin will not be run, but other kinds of errors, as well as warnings,
will be given to the plugin via the PsMessages
value of the
ParsedResult
. This allows you to modify, remove, and add warnings or errors
before they are displayed to the user, although in most cases, you will likely
want to return the messages unmodified. The parsing pass will fail if the
Messages PsError
collection inside the return ParsedResult
is not empty
after all parsing plugins have been run.
7.3.5.2. Type checked representation¶
When you want to define a plugin that needs semantic information about the
source code, use the typeCheckResultAction
field. For example, if your
plugin have to decide if two names are referencing the same definition or it has
to check the type of a function it is using semantic information. In this case
you need to access the renamed or type checked version of the syntax tree with
typeCheckResultAction
or renamedResultAction
.
typechecked :: [CommandLineOption] -> ModSummary -> TcGblEnv -> TcM TcGblEnv
renamed :: [CommandLineOption] -> TcGblEnv -> HsGroup GhcRn -> TcM (TcGblEnv, HsGroup GhcRn)
By overriding the renamedResultAction
field we can modify each HsGroup
after it has been renamed. A source file is separated into groups depending on
the location of template haskell splices so the contents of these groups may
not be intuitive. In order to save the entire renamed AST for inspection
at the end of typechecking you can set renamedResultAction
to keepRenamedSource
which is provided by the Plugins
module.
This is important because some parts of the renamed
syntax tree (for example, imports) are not found in the typechecked one.
7.3.5.3. Evaluated code¶
When the compiler type checks the source code, Template Haskell Splices
and Template Haskell Quasi-quotation will be replaced by the syntax tree fragments
generated from them. However for tools that operate on the source code the
code generator is usually more interesting than the generated code. For this
reason we included spliceRunAction
. This field is invoked on each expression
before they are evaluated. The input is type checked, so semantic information is
available for these syntax tree fragments. If you return a different expression
you can change the code that is generated.
spliceRun :: [CommandLineOption] -> LHsExpr GhcTc -> TcM (LHsExpr GhcTc)
However take care that the generated definitions are still in the input of
typeCheckResultAction
. If your don’t take care to filter the typechecked
input, the behavior of your tool might be inconsistent.
7.3.5.4. Interface files¶
Sometimes when you are writing a tool, knowing the source code is not enough,
you also have to know details about the modules that you import. In this case we
suggest using the interfaceLoadAction
. This will be called each time when
the code of an already compiled module is loaded. It will be invoked for modules
from installed packages and even modules that are installed with GHC. It will
NOT be invoked with your own modules.
interfaceLoad :: forall lcl . [CommandLineOption] -> ModIface
-> IfM lcl ModIface
In the ModIface
datatype you can find lots of useful information, including
the exported definitions and type class instances.
The ModIface
datatype also contains facilities for extending it with extra
data, stored in a Map
of serialised fields, indexed by field names and using
GHC’s internal Binary
class. The interface to work with these fields is:
readIfaceField :: Binary a => FieldName -> ModIface -> IO (Maybe a)
writeIfaceField :: Binary a => FieldName -> a -> ModIface -> IO ModIface
deleteIfaceField :: FieldName -> ModIface -> ModIface
The FieldName
is open-ended, but typically it should contain the producing
package name, along with the actual field name. Then, the version number can either
be attached to the serialised data for that field, or in cases where multiple versions
of a field could exist in the same interface file, included in the field name.
Depending on if the field version advances with the package version, or independently, the version can be attached to either the package name or the field name. Examples of each case:
package/field
ghc-n.n.n/core
package/field-n
To read an interface file from an external tool without linking to GHC, the format is described at Extensible Interface Files.
7.3.5.5. Source plugin example¶
In this example, we inspect all available details of the compiled source code. We don’t change any of the representation, but write out the details to the standard output. The pretty printed representation of the parsed, renamed and type checked syntax tree will be in the output as well as the evaluated splices and quasi quotes. The name of the interfaces that are loaded will also be displayed.
module SourcePlugin where
import Control.Monad.IO.Class
import GHC.Driver.Session (getDynFlags)
import GHC.Driver.Plugins
import GHC.Plugins
import GHC.Tc.Types
import Language.Haskell.Syntax.Extension
import GHC.Hs.Decls
import GHC.Hs.Expr
import GHC.Hs.ImpExp
import GHC.Types.Avail
import GHC.Utils.Outputable
import GHC.Hs.Doc
import GHC
plugin :: Plugin
plugin = defaultPlugin
{ parsedResultAction = parsedPlugin
, renamedResultAction = renamedAction
, typeCheckResultAction = typecheckPlugin
, spliceRunAction = metaPlugin
, interfaceLoadAction = interfaceLoadPlugin
}
parsedPlugin :: [CommandLineOption] -> ModSummary
-> ParsedResult -> Hsc ParsedResult
parsedPlugin _ _ parsed@(ParsedResult pm msgs)
= do dflags <- getDynFlags
liftIO $ putStrLn $ "parsePlugin: \n" ++ (showSDoc dflags $ ppr $ hpm_module pm)
liftIO $ putStrLn $ "parsePlugin warnings: \n" ++ (showSDoc dflags $ ppr $ psWarnings msgs)
liftIO $ putStrLn $ "parsePlugin errors: \n" ++ (showSDoc dflags $ ppr $ psErrors msgs)
return parsed
renamedAction :: [CommandLineOption] -> TcGblEnv -> HsGroup GhcRn -> TcM (TcGblEnv, HsGroup GhcRn)
renamedAction _ tc gr = do
dflags <- getDynFlags
liftIO $ putStrLn $ "typeCheckPlugin (rn): " ++ (showSDoc dflags $ ppr gr)
return (tc, gr)
typecheckPlugin :: [CommandLineOption] -> ModSummary -> TcGblEnv -> TcM TcGblEnv
typecheckPlugin _ _ tc
= do dflags <- getDynFlags
liftIO $ putStrLn $ "typeCheckPlugin (rn): \n" ++ (showSDoc dflags $ ppr $ tcg_rn_decls tc)
liftIO $ putStrLn $ "typeCheckPlugin (tc): \n" ++ (showSDoc dflags $ ppr $ tcg_binds tc)
return tc
metaPlugin :: [CommandLineOption] -> LHsExpr GhcTc -> TcM (LHsExpr GhcTc)
metaPlugin _ meta
= do dflags <- getDynFlags
liftIO $ putStrLn $ "meta: " ++ (showSDoc dflags $ ppr meta)
return meta
interfaceLoadPlugin :: [CommandLineOption] -> ModIface -> IfM lcl ModIface
interfaceLoadPlugin _ iface
= do dflags <- getDynFlags
liftIO $ putStrLn $ "interface loaded: " ++ (showSDoc dflags $ ppr $ mi_module iface)
return iface
When you compile a simple module that contains Template Haskell splice
{-# OPTIONS_GHC -fplugin SourcePlugin #-}
{-# LANGUAGE TemplateHaskell #-}
module A where
a = ()
$(return [])
with the compiler flags -fplugin SourcePlugin
it will give the following
output:
parsePlugin:
module A where
a = ()
$(return [])
parsePlugin warnings:
parsePlugin errors:
typeCheckPlugin (rn): a = ()
interface loaded: Language.Haskell.TH.Lib.Internal
meta: return []
typeCheckPlugin (rn):
typeCheckPlugin (rn):
Nothing
typeCheckPlugin (tc):
{$trModule = Module (TrNameS "main"#) (TrNameS "A"#), a = ()}
7.3.6. Hole fit plugins¶
Hole-fit plugins are plugins that are called when a typed-hole error message is being generated, and allows you to access information about the typed-hole at compile time, and allows you to customize valid hole fit suggestions.
Using hole-fit plugins, you can extend the behavior of valid hole fit suggestions to use e.g. Hoogle or other external tools to find and/or synthesize valid hole fits, with the same information about the typed-hole that GHC uses.
There are two access points are bundled together for defining hole fit plugins, namely a candidate plugin and a fit plugin, for modifying the candidates to be checked and fits respectively.
type CandPlugin = TypedHole -> [HoleFitCandidate] -> TcM [HoleFitCandidate]
type FitPlugin = TypedHole -> [HoleFit] -> TcM [HoleFit]
data HoleFitPlugin = HoleFitPlugin
{ candPlugin :: CandPlugin
-- ^ A plugin for modifying hole fit candidates before they're checked
, fitPlugin :: FitPlugin
-- ^ A plugin for modifying valid hole fits after they've been found.
}
Where TypedHole
contains all the information about the hole available to GHC
at error generation.
data TypedHole = TyH { tyHRelevantCts :: Cts
-- ^ Any relevant Cts to the hole
, tyHImplics :: [Implication]
-- ^ The nested implications of the hole with the
-- innermost implication first.
, tyHCt :: Maybe Ct
-- ^ The hole constraint itself, if available.
}
HoleFitPlugins
are then defined as follows
plugin :: Plugin
plugin = defaultPlugin {
holeFitPlugin = (fmap . fmap) fromPureHFPlugin hfPlugin
}
hfPlugin :: [CommandLineOption] -> Maybe HoleFitPlugin
Where fromPureHFPlugin :: HoleFitPlugin -> HoleFitPluginR
is a convenience
function provided in the GHC.Tc.Errors.Hole
module, for defining plugins that do
not require internal state.
7.3.6.1. Stateful hole fit plugins¶
HoleFitPlugins
are wrapped in a HoleFitPluginR
, which provides a
TcRef
for the plugin to use to track internal state, and to facilitate
communication between the candidate and fit plugin.
-- | HoleFitPluginR adds a TcRef to hole fit plugins so that plugins can
-- track internal state. Note the existential quantification, ensuring that
-- the state cannot be modified from outside the plugin.
data HoleFitPluginR = forall s. HoleFitPluginR
{ hfPluginInit :: TcM (TcRef s)
-- ^ Initializes the TcRef to be passed to the plugin
, hfPluginRun :: TcRef s -> HoleFitPlugin
-- ^ The function defining the plugin itself
, hfPluginStop :: TcRef s -> TcM ()
-- ^ Cleanup of state, guaranteed to be called even on error
}
The plugin is then defined as by providing a value for the holeFitPlugin
field, a function that takes the CommandLineOption
strings that are passed
to the compiler using the -fplugin-opt=⟨module⟩:⟨args⟩
flags and returns a
HoleFitPluginR
. This function can be used to pass the CommandLineOption
strings along to the candidate and fit plugins respectively.
7.3.6.2. Hole fit plugin example¶
The following plugins allows users to limit the search for valid hole fits to certain modules, to sort the hole fits by where they originated (in ascending or descending order), as well as allowing users to put a limit on how much time is spent on searching for valid hole fits, after which new searches are aborted.
{-# LANGUAGE TypeApplications, RecordWildCards #-}
module HolePlugin where
import GHC.Plugins hiding ((<>))
import GHC.Tc.Errors.Hole
import Data.List (stripPrefix, sortOn)
import GHC.Tc.Types
import GHC.Tc.Utils.Monad
import Data.Time (UTCTime, NominalDiffTime)
import qualified Data.Time as Time
import Text.Read
data HolePluginState = HPS { timeAlloted :: Maybe NominalDiffTime
, elapsedTime :: NominalDiffTime
, timeCurStarted :: UTCTime }
bumpElapsed :: NominalDiffTime -> HolePluginState -> HolePluginState
bumpElapsed ad (HPS a e t) = HPS a (e + ad) t
setAlloted :: Maybe NominalDiffTime -> HolePluginState -> HolePluginState
setAlloted a (HPS _ e t) = HPS a e t
setCurStarted :: UTCTime -> HolePluginState -> HolePluginState
setCurStarted nt (HPS a e _) = HPS a e nt
hpStartState :: HolePluginState
hpStartState = HPS Nothing zero undefined
where zero = fromInteger @NominalDiffTime 0
initPlugin :: [CommandLineOption] -> TcM (TcRef HolePluginState)
initPlugin [msecs] = newTcRef $ hpStartState { timeAlloted = alloted }
where
errMsg = "Invalid amount of milliseconds given to plugin: " <> show msecs
alloted = case readMaybe @Integer msecs of
Just millisecs -> Just $ fromInteger @NominalDiffTime millisecs / 1000
_ -> error errMsg
initPlugin _ = newTcRef hpStartState
fromModule :: HoleFitCandidate -> [String]
fromModule (GreHFCand gre) =
map (moduleNameString . importSpecModule) $ gre_imp gre
fromModule _ = []
toHoleFitCommand :: TypedHole -> String -> Maybe String
toHoleFitCommand TyH{tyHCt = Just (CHoleCan _ h)} str
= stripPrefix ("_" <> str) $ occNameString $ holeOcc h
toHoleFitCommand _ _ = Nothing
-- | This candidate plugin filters the candidates by module,
-- using the name of the hole as module to search in
modFilterTimeoutP :: [CommandLineOption] -> TcRef HolePluginState -> CandPlugin
modFilterTimeoutP _ ref hole cands = do
curTime <- liftIO Time.getCurrentTime
HPS {..} <- readTcRef ref
updTcRef ref (setCurStarted curTime)
return $ case timeAlloted of
-- If we're out of time we remove all the candidates. Then nothing is checked.
Just sofar | elapsedTime > sofar -> []
_ -> case toHoleFitCommand hole "only_" of
Just modName -> filter (inScopeVia modName) cands
_ -> cands
where inScopeVia modNameStr cand@(GreHFCand _) =
elem (toModName modNameStr) $ fromModule cand
inScopeVia _ _ = False
toModName = replace '_' '.'
replace :: Eq a => a -> a -> [a] -> [a]
replace _ _ [] = []
replace a b (x:xs) = (if x == a then b else x):replace a b xs
modSortP :: [CommandLineOption] -> TcRef HolePluginState -> FitPlugin
modSortP _ ref hole hfs = do
curTime <- liftIO Time.getCurrentTime
HPS {..} <- readTcRef ref
updTcRef ref $ bumpElapsed (Time.diffUTCTime curTime timeCurStarted)
return $ case timeAlloted of
-- If we're out of time, remove any candidates, so nothing is checked.
Just sofar | elapsedTime > sofar -> [RawHoleFit $ text msg]
_ -> case toHoleFitCommand hole "sort_by_mod" of
-- If only_ is on, the fits will all be from the same module.
Just ('_':'d':'e':'s':'c':_) -> reverse hfs
Just _ -> orderByModule hfs
_ -> hfs
where orderByModule :: [HoleFit] -> [HoleFit]
orderByModule = sortOn (fmap fromModule . mbHFCand)
mbHFCand :: HoleFit -> Maybe HoleFitCandidate
mbHFCand HoleFit {hfCand = c} = Just c
mbHFCand _ = Nothing
msg = hang (text "Error: The time ran out, and the search was aborted for this hole.")
7 $ text "Try again with a longer timeout."
plugin :: Plugin
plugin = defaultPlugin { holeFitPlugin = holeFitP, pluginRecompile = purePlugin}
holeFitP :: [CommandLineOption] -> Maybe HoleFitPluginR
holeFitP opts = Just (HoleFitPluginR initP pluginDef stopP)
where initP = initPlugin opts
stopP = const $ return ()
pluginDef ref = HoleFitPlugin { candPlugin = modFilterTimeoutP opts ref
, fitPlugin = modSortP opts ref }
When you then compile a module containing the following
{-# OPTIONS -fplugin=HolePlugin
-fplugin-opt=HolePlugin:600
-funclutter-valid-hole-fits #-}
module Main where
import Prelude hiding (head, last)
import Data.List (head, last)
f, g, h, i, j :: [Int] -> Int
f = _too_long
j = _
i = _sort_by_mod_desc
g = _only_Data_List
h = _only_Prelude
main :: IO ()
main = return ()
The output is as follows:
Main.hs:12:5: error:
• Found hole: _too_long :: [Int] -> Int
Or perhaps ‘_too_long’ is mis-spelled, or not in scope
• In the expression: _too_long
In an equation for ‘f’: f = _too_long
• Relevant bindings include
f :: [Int] -> Int (bound at Main.hs:12:1)
Valid hole fits include
Error: The time ran out, and the search was aborted for this hole.
Try again with a longer timeout.
|
12 | f = _too_long
| ^^^^^^^^^
Main.hs:13:5: error:
• Found hole: _ :: [Int] -> Int
• In the expression: _
In an equation for ‘j’: j = _
• Relevant bindings include
j :: [Int] -> Int (bound at Main.hs:13:1)
Valid hole fits include
j :: [Int] -> Int
f :: [Int] -> Int
g :: [Int] -> Int
h :: [Int] -> Int
i :: [Int] -> Int
head :: forall a. [a] -> a
(Some hole fits suppressed; use -fmax-valid-hole-fits=N or -fno-max-valid-hole-fits)
|
13 | j = _
| ^
Main.hs:14:5: error:
• Found hole: _sort_by_mod_desc :: [Int] -> Int
Or perhaps ‘_sort_by_mod_desc’ is mis-spelled, or not in scope
• In the expression: _sort_by_mod_desc
In an equation for ‘i’: i = _sort_by_mod_desc
• Relevant bindings include
i :: [Int] -> Int (bound at Main.hs:14:1)
Valid hole fits include
sum :: forall (t :: * -> *) a. (Foldable t, Num a) => t a -> a
product :: forall (t :: * -> *) a. (Foldable t, Num a) => t a -> a
minimum :: forall (t :: * -> *) a. (Foldable t, Ord a) => t a -> a
maximum :: forall (t :: * -> *) a. (Foldable t, Ord a) => t a -> a
length :: forall (t :: * -> *) a. Foldable t => t a -> Int
last :: forall a. [a] -> a
(Some hole fits suppressed; use -fmax-valid-hole-fits=N or -fno-max-valid-hole-fits)
|
14 | i = _sort_by_mod_desc
| ^^^^^^^^^^^^^^^^^
Main.hs:15:5: error:
• Found hole: _only_Data_List :: [Int] -> Int
Or perhaps ‘_only_Data_List’ is mis-spelled, or not in scope
• In the expression: _only_Data_List
In an equation for ‘g’: g = _only_Data_List
• Relevant bindings include
g :: [Int] -> Int (bound at Main.hs:15:1)
Valid hole fits include
head :: forall a. [a] -> a
last :: forall a. [a] -> a
|
15 | g = _only_Data_List
| ^^^^^^^^^^^^^^^
Main.hs:16:5: error:
• Found hole: _only_Prelude :: [Int] -> Int
Or perhaps ‘_only_Prelude’ is mis-spelled, or not in scope
• In the expression: _only_Prelude
In an equation for ‘h’: h = _only_Prelude
• Relevant bindings include
h :: [Int] -> Int (bound at Main.hs:16:1)
Valid hole fits include
length :: forall (t :: * -> *) a. Foldable t => t a -> Int
maximum :: forall (t :: * -> *) a. (Foldable t, Ord a) => t a -> a
minimum :: forall (t :: * -> *) a. (Foldable t, Ord a) => t a -> a
product :: forall (t :: * -> *) a. (Foldable t, Num a) => t a -> a
sum :: forall (t :: * -> *) a. (Foldable t, Num a) => t a -> a
|
16 | h = _only_Prelude
| ^^^^^^^^^^^^^
7.3.7. Defaulting plugins¶
Defaulting plugins are called when ambiguous variables might otherwise cause errors, in the same way as the built-in defaulting mechanism.
A defaulting plugin can propose potential ways to fill an ambiguous variable according to whatever criteria you would like. GHC will verify that those proposals will not lead to type errors in a context that you declare.
Defaulting plugins have a single access point in the GHC.Tc.Types module
-- | A collection of candidate default types for a type variable.
data DefaultingProposal
= DefaultingProposal
{ deProposalTyVar :: TcTyVar
-- ^ The type variable to default.
, deProposalCandidates :: [Type]
-- ^ Candidate types to default the type variable to.
, deProposalCts :: [Ct]
-- ^ The constraints against which defaults are checked.
}
type DefaultingPluginResult = [DefaultingProposal]
type FillDefaulting = WantedConstraints -> TcPluginM DefaultingPluginResult
-- | A plugin for controlling defaulting.
data DefaultingPlugin = forall s. DefaultingPlugin
{ dePluginInit :: TcPluginM s
-- ^ Initialize plugin, when entering type-checker.
, dePluginRun :: s -> FillDefaulting
-- ^ Default some types
, dePluginStop :: s -> TcPluginM ()
-- ^ Clean up after the plugin, when exiting the type-checker.
}
The plugin gets a combination of wanted constraints which can be most easily
broken down into simple wanted constraints with approximateWC
. The result of
running the plugin should be a DefaultingPluginResult
, a list of types that
should be attempted for a given type variable that is ambiguous in a given
context. GHC will check if one of the proposals is acceptable in the given
context and then default to it. The most robust context to provide is the list
of all wanted constraints that mention the variable you are defaulting. If you
leave out a constraint, the default will be accepted, and then potentially
result in a type checker error if it is incompatible with one of the constraints
you left out. This can be a useful way of forcing a default and reporting errors
to the user.
There is an example of defaulting lifted types in the GHC test suite. In the testsuite/tests/plugins/ directory see defaulting-plugin/ for the implementation, test-defaulting-plugin.hs for an example of when defaulting happens, and test-defaulting-plugin-fail.hs for an example of when defaults don’t fit and aren’t applied.
7.3.8. Controlling Recompilation¶
By default, modules compiled with plugins are always recompiled even if the source file is
unchanged. This most conservative option is taken due to the ability of plugins
to perform arbitrary IO actions. In order to control the recompilation behaviour
you can modify the pluginRecompile
field in Plugin
.
plugin :: Plugin
plugin = defaultPlugin {
installCoreToDos = install,
pluginRecompile = purePlugin
}
By inspecting the example plugin
defined above, we can see that it is pure. This
means that if the two modules have the same fingerprint then the plugin
will always return the same result. Declaring a plugin as pure means that
the plugin will never cause a module to be recompiled.
In general, the pluginRecompile
field has the following type:
pluginRecompile :: [CommandLineOption] -> IO PluginRecompile
The PluginRecompile
data type is an enumeration determining how the plugin
should affect recompilation.
data PluginRecompile = ForceRecompile | NoForceRecompile | MaybeRecompile Fingerprint
A plugin which declares itself impure using ForceRecompile
will always
trigger a recompilation of the current module. NoForceRecompile
is used
for “pure” plugins which don’t need to be rerun unless a module would ordinarily
be recompiled. MaybeRecompile
computes a Fingerprint
and if this Fingerprint
is different to a previously computed Fingerprint
for the plugin, then
we recompile the module.
As such, purePlugin
is defined as a function which always returns NoForceRecompile
.
purePlugin :: [CommandLineOption] -> IO PluginRecompile
purePlugin _ = return NoForceRecompile
Users can use the same functions that GHC uses internally to compute fingerprints.
The GHC.Fingerprint module provides useful functions for constructing fingerprints. For example, combining
together fingerprintFingerprints
and fingerprintString
provides an easy to
to naively fingerprint the arguments to a plugin.
pluginFlagRecompile :: [CommandLineOption] -> IO PluginRecompile
pluginFlagRecompile =
return . MaybeRecompile . fingerprintFingerprints . map fingerprintString . sort
defaultPlugin
defines pluginRecompile
to be impurePlugin
which
is the most conservative and backwards compatible option.
impurePlugin :: [CommandLineOption] -> IO PluginRecompile
impurePlugin _ = return ForceRecompile
7.3.9. Frontend plugins¶
A frontend plugin allows you to add new major modes to GHC. You may prefer
this over a traditional program which calls the GHC API, as GHC manages a lot
of parsing flags and administrative nonsense which can be difficult to
manage manually. To load a frontend plugin exported by Foo.FrontendPlugin
,
we just invoke GHC with the --frontend ⟨module⟩
flag as follows:
$ ghc --frontend Foo.FrontendPlugin ...other options...
Frontend plugins, like compiler plugins, are exported by registered plugins.
However, unlike compiler modules, frontend plugins are modules that export
at least a single identifier frontendPlugin
of type
GHC.Plugins.FrontendPlugin
.
FrontendPlugin
exports a field frontend
, which is a function
[String] -> [(String, Maybe Phase)] -> Ghc ()
. The first argument
is a list of extra flags passed to the frontend with -ffrontend-opt
;
the second argument is the list of arguments, usually source files
and module names to be compiled (the Phase
indicates if an -x
flag was set), and a frontend simply executes some operation in the
Ghc
monad (which, among other things, has a Session
).
As a quick example, here is a frontend plugin that prints the arguments that were passed to it, and then exits.
module DoNothing.FrontendPlugin (frontendPlugin) where
import GHC.Plugins
frontendPlugin :: FrontendPlugin
frontendPlugin = defaultFrontendPlugin {
frontend = doNothing
}
doNothing :: [String] -> [(String, Maybe Phase)] -> Ghc ()
doNothing flags args = do
liftIO $ print flags
liftIO $ print args
Provided you have compiled this plugin and registered it in a package,
you can just use it by specifying --frontend DoNothing.FrontendPlugin
on the command line to GHC.
7.3.10. DynFlags plugins¶
A DynFlags plugin allows you to modify the DynFlags
that GHC
is going to use when processing a given (set of) file(s).
DynFlags
is a record containing all sorts of configuration
and command line data, from verbosity level to the integer library
to use, including compiler hooks, plugins and pretty-printing options.
DynFlags plugins allow plugin authors to update any of those values
before GHC starts doing any actual work, effectively meaning that
the updates specified by the plugin will be taken into account and
influence GHC’s behaviour.
One of the motivating examples was the ability to register
compiler hooks from a plugin. For example, one might want to modify
the way Template Haskell code is executed. This is achievable by
updating the hooks
field of the DynFlags
type, recording
our custom “meta hook” in the right place. A simple application of
this idea can be seen below:
module DynFlagsPlugin (plugin) where
import BasicTypes
import GHC.Plugins
import GHC.Hs.Expr
import Language.Haskell.Syntax.Extension
import GHC.Hs.Lit
import Hooks
import GHC.Tc.Utils.Monad
plugin :: Plugin
plugin = driverPlugin { driverPlugin = hooksP }
hooksP :: [CommandLineOption] -> HscEnv -> IO HscEnv
hooksP opts hsc_env = do
let hooks' = (hsc_hooks hsc_env)
{ runMetaHook = Just (fakeRunMeta opts) }
hsc_env' = hsc_env { hsc_hooks = hooks' }
return hsc_env'
-- This meta hook doesn't actually care running code in splices,
-- it just replaces any expression splice with the "0"
-- integer literal, and errors out on all other types of
-- meta requests.
fakeRunMeta :: [CommandLineOption] -> MetaHook TcM
fakeRunMeta opts (MetaE r) _ = do
liftIO . putStrLn $ "Options = " ++ show opts
pure $ r zero
where zero :: LHsExpr GhcPs
zero = L noSrcSpan $ HsLit NoExtField $
HsInt NoExtField (mkIntegralLit (0 :: Int))
fakeRunMeta _ _ _ = error "fakeRunMeta: unimplemented"
This simple plugin takes over the execution of Template Haskell code,
replacing any expression splice it encounters by 0
(at type
Int
), and errors out on any other type of splice.
Therefore, if we run GHC against the following code using the plugin from above:
{-# OPTIONS -fplugin=DynFlagsPlugin #-}
{-# LANGUAGE TemplateHaskell #-}
module Main where
main :: IO ()
main = print $( [|1|] )
This will not actually evaluate [|1|]
, but instead replace it
with the 0 :: Int
literal.
Just like the other types of plugins, you can write DynFlags
plugins
that can take and make use of some options that you can then specify
using the -fplugin-opt
flag. In the DynFlagsPlugin
code from
above, the said options would be available in the opts
argument of
hooksP
.
Finally, since those DynFlags
updates happen after the plugins are loaded,
you cannot from a DynFlags
plugin register other plugins by just adding them
to the plugins
field of DynFlags
. In order to achieve this, you would
have to load them yourself and store the result into the cachedPlugins
field of DynFlags
.
7.4. Referring to back ends¶
In versions of GHC numbered up to and including 9.4, a back end is
referred to by name: type Backend
, from module
GHC.Driver.Backend
, is a simple enumeration type. In versions of GHC
numbered 9.6 and higher, Backend
is an abstract type. The module
specifies predicates and functions associated with a back end.
This change in representation requires changes in client code.
7.4.1. Client code that only names back ends¶
Suppose your client uses Backend
only to mention back ends by name.
That is, it never discriminates between back ends in a case
expression, function definition, or equality comparison. Then the
simplest way for you to migrate your code is to replace each value
constructor from version 9.4 with the corresponding value from 9.6:
Old value | New value |
---|---|
NCG |
ncgBackend |
LLVM |
llvmBackend |
ViaC |
viaCBackend |
Interpreter |
interpreterBackend |
NoBackend |
noBackend |
7.4.2. Client code that discriminates among back ends¶
Suppose your code makes decisions based on the value of an expression of
type Backend
. Then the simplest way for you to migrate your
decision-making code depends on the code’s form.
If your decision-making is driven by an equality or inequality predicate, an equivalent predicate may already be defined in module
GHC.Driver.Backend
. For example, if your client wants to be sure that optimization levels above-O0
are permitted, it might have originally comparedbackend /= Interpreter
. But now there is a predicate for that: it isnot (backendForcesOptimization0 backend)
.If the predicate you want is not already defined, you will have to fall back on the more general strategy defined below.
If your decision-making is still driven by a predicate, but the implementation of the predicate inspects the form of
Backend
, you may still be in luck. For example, if your client needs to know whether theBackend
wishes to write files to disk, it can querybackendWritesFiles backend
. In version 9.4, this predicate holds for the NCG, LLVM, and Via-C back ends, but not for the interpreter or forNoBackend
.In the general case, for any function definition, case expression, or equality test that discriminates among back ends, you can use the general migration strategy described below.
7.4.3. General migration strategy for client code¶
From version 9.6 onward, each back end may be queried for its name:
backendName :: Backend -> BackendName
The BackendName
type must be imported from module GHC.Driver.Backend.Internal
.
It is defined to look the same as the old
Backend
type:
data BackendName
= NCG
| LLVM
| ViaC
| Interpreter
| NoBackend
This type is also an instance of the Eq
and Show
classes.
If your existing code discriminates among existing back ends using a
case
expression, you need to apply backendName
to the scrutinee.
case backend dflags of -- code using the 9.4 interface
NCG -> ...
LLVM -> ...
...
can become
case backendName $ backend dflags of -- code using the 9.6 interface
NCG -> ...
LLVM -> ...
...
Only the scrutinee changes, not the pattern matches. And if your pattern matches were complete before, they are still complete.