You must run the tool in a directory containing a Cabal package.
$ check-pvp
This requires that the package is configured,
since only then the association of packages to modules is known.
If you want to run the tool on a non-configured package
you may just check all imports for addition-proof style.
$ check-pvp --include-all
It follows a detailed description of the procedure
and the rationale behind it.
First the program classifies all dependencies
in the Cabal file of the package.
You can show all classifications with the --classify-dependencies
option,
otherwise only problematic dependencies are shown.
A dependency like containers >=0.5.0.3 && <0.5.1
does not allow changes of the API of containers
and thus the program does not check its imports.
Clashing import abbreviations are an exception.
The dependency containers >=0.5.1 && <0.7
requires more care when importing modules from containers
and this is what the program is going to check next.
This is the main purpose of the program!
I warmly recommend this kind of dependency range
since it greatly reduces the work
to keep your package going together with its imported packages.
Dependencies like containers >=0.5
or containers >=0.5 && <1
are always problematic,
since within the specified version ranges identifier can disappear.
There is no import style that protects against removed identifiers.
An inclusive upper bound as in containers >=0.5 && <=0.6
will also cause a warning, because it is unnecessarily strict.
If you know that containers-0.6
works for you,
then containers-0.6.0.1
or containers-0.6.1
will also work,
depending on your import style.
A special case of inclusive upper bounds are specific versions
like in containers ==0.6
.
The argument for the warning remains the same.
Please note that the check of ranges
is performed entirely on the package description.
The program will not inspect the imported module contents.
E.g. if you depend on containers >=0.5 && <0.7
but import in a way that risks name clashes,
then you may just extend the dependency to containers >=0.5 && <0.7.1
in order to let the checker fall silent.
If you use the dependency containers >=0.5 && <0.7.1
then the checker expects that you have verified
that your package works with all versions of kind 0.5.x
and the version 0.6.0
.
Other versions would then work, too,
due to the constraints imposed by package versioning policy.
Let us now look at imports
that must be protected against identifier additions.
The program may complain about a lax import.
This means you have imported like
import Data.Map as Map
Additions to Data.Map
may clash with other identifiers,
thus you must import either
import qualified Data.Map as Map
or
import Data.Map (Map)
The program emits an error on clashing module abbreviations like
import qualified Data.Map.Lazy as Map
import qualified Data.Map.Strict as Map
This error is raised
whenever multiple modules are imported with the same abbreviation,
where at least one module is open for additions.
Our test is overly strict in the sense that it also blames
import qualified Data.Map as Map
import qualified Data.Map as Map
but I think it is good idea to avoid redundant imports anyway.
Additionally there are warnings on imports
that are consistent with large version ranges,
but complicate API changing updates of your dependencies.
You can disable these warnings with --disable-warnings
.
The program warns about an open list of constructors as in
import Data.Sequence (ViewL(..))
Additions of constructors to ViewL
may also conflict with other identifiers,
but additions of constructors are considered API changes
since they may turn a complete case analysis into an incomplete one.
Similarly additionally class methods can turn a complete class instance
into a partial one.
Thus addition of constructors and class methods
require a version bump from x.y.z
to x.y+1
.
Nonetheless it is a good idea to import either
import Data.Sequence (ViewL(EmptyL, (:<)))
or
import qualified Data.Sequence as Seq
because you document the origin of identifiers this way.
This is especially important when the imported identifiers
are moved or removed in the future.
If you use constructors only for constructions and not for pattern matches
or if you only call class methods but do not define instances,
then with explicit imports or qualified imports
your modules survive such additions in your dependent packages
without modifications.
More warnings are issued for hiding imports.
The import
import Data.Map hiding (insert)
is not bad in the sense of the PVP,
but this way you depend on the existence of the identifier insert
although you do not need it.
If it is removed in a later version of containers
,
then your import breaks although you did not use the identifier.
Finally you can control what items are checked.
First of all you can select the imports that are checked.
Normally the imports are checked that belong to lax dependencies
like containers >=0.5 && <0.7
.
However this requires the package to be configured
in order to know which import belongs to which dependency.
E.g. Data.Map
belongs to containers
.
You can just check all imports for being addition-proof
using the --include-all
option.
Following you can write the options
--include-import
,
--exclude-import
,
--include-dependency
,
--exclude-dependency
that allow to additionally check or ignore imports
from certain modules or packages.
These modifiers are applied from left to right.
E.g. --exclude-import=Prelude
will accept any import style for Prelude
and --exclude-dependency=foobar
will ignore the package foobar
,
say, because it does not conform to the PVP.
Secondly, you may ignore certain modules or components of the package
using the options
--exclude-module
,
--exclude-library
,
--exclude-executables
,
--exclude-testsuites
,
--exclude-benchmarks
.
E.g. --exclude-module=Paths_PKG
will exclude the Paths module
that is generated by Cabal.
I assume that it will always be free of name clashes.
Known problems:
-
The program cannot automatically filter out the Paths
module.
-
The program cannot find and check preprocessed modules.
-
The program may yield wrong results in the presence of Cabal conditions.
If this program proves to be useful
it might eventually be integrated in the check
command of cabal-install
.
See https://github.com/haskell/cabal/issues/1703.
Alternative:
If you want to allow exclusively large version ranges, i.e. >=x.y && <x.y+1
,
then you may also add the option -fwarn-missing-import-lists
to the GHC-Options
fields of your Cabal file.
See https://ghc.haskell.org/trac/ghc/ticket/4977.
Unfortunately there is no GHC warning on clashing module abbreviations.
See https://ghc.haskell.org/trac/ghc/ticket/4980.