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Part of #20889
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Multiple home units allows you to load different packages which may depend on
each other into one GHC session. This will allow both GHCi and HLS to support
multi component projects more naturally.
Public Interface
~~~~~~~~~~~~~~~~
In order to specify multiple units, the -unit @⟨filename⟩ flag
is given multiple times with a response file containing the arguments for each unit.
The response file contains a newline separated list of arguments.
```
ghc -unit @unitLibCore -unit @unitLib
```
where the `unitLibCore` response file contains the normal arguments that cabal would pass to `--make` mode.
```
-this-unit-id lib-core-0.1.0.0
-i
-isrc
LibCore.Utils
LibCore.Types
```
The response file for lib, can specify a dependency on lib-core, so then modules in lib can use modules from lib-core.
```
-this-unit-id lib-0.1.0.0
-package-id lib-core-0.1.0.0
-i
-isrc
Lib.Parse
Lib.Render
```
Then when the compiler starts in --make mode it will compile both units lib and lib-core.
There is also very basic support for multiple home units in GHCi, at the
moment you can start a GHCi session with multiple units but only the
:reload is supported. Most commands in GHCi assume a single home unit,
and so it is additional work to work out how to modify the interface to
support multiple loaded home units.
Options used when working with Multiple Home Units
There are a few extra flags which have been introduced specifically for
working with multiple home units. The flags allow a home unit to pretend
it’s more like an installed package, for example, specifying the package
name, module visibility and reexported modules.
-working-dir ⟨dir⟩
It is common to assume that a package is compiled in the directory
where its cabal file resides. Thus, all paths used in the compiler
are assumed to be relative to this directory. When there are
multiple home units the compiler is often not operating in the
standard directory and instead where the cabal.project file is
located. In this case the -working-dir option can be passed which
specifies the path from the current directory to the directory the
unit assumes to be it’s root, normally the directory which contains
the cabal file.
When the flag is passed, any relative paths used by the compiler are
offset by the working directory. Notably this includes -i and
-I⟨dir⟩ flags.
-this-package-name ⟨name⟩
This flag papers over the awkward interaction of the PackageImports
and multiple home units. When using PackageImports you can specify
the name of the package in an import to disambiguate between modules
which appear in multiple packages with the same name.
This flag allows a home unit to be given a package name so that you
can also disambiguate between multiple home units which provide
modules with the same name.
-hidden-module ⟨module name⟩
This flag can be supplied multiple times in order to specify which
modules in a home unit should not be visible outside of the unit it
belongs to.
The main use of this flag is to be able to recreate the difference
between an exposed and hidden module for installed packages.
-reexported-module ⟨module name⟩
This flag can be supplied multiple times in order to specify which
modules are not defined in a unit but should be reexported. The
effect is that other units will see this module as if it was defined
in this unit.
The use of this flag is to be able to replicate the reexported
modules feature of packages with multiple home units.
Offsetting Paths in Template Haskell splices
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
When using Template Haskell to embed files into your program,
traditionally the paths have been interpreted relative to the directory
where the .cabal file resides. This causes problems for multiple home
units as we are compiling many different libraries at once which have
.cabal files in different directories.
For this purpose we have introduced a way to query the value of the
-working-dir flag to the Template Haskell API. By using this function we
can implement a makeRelativeToProject function which offsets a path
which is relative to the original project root by the value of
-working-dir.
```
import Language.Haskell.TH.Syntax ( makeRelativeToProject )
foo = $(makeRelativeToProject "./relative/path" >>= embedFile)
```
> If you write a relative path in a Template Haskell splice you should use the makeRelativeToProject function so that your library works correctly with multiple home units.
A similar function already exists in the file-embed library. The
function in template-haskell implements this function in a more robust
manner by honouring the -working-dir flag rather than searching the file
system.
Closure Property for Home Units
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
For tools or libraries using the API there is one very important closure
property which must be adhered to:
> Any dependency which is not a home unit must not (transitively) depend
on a home unit.
For example, if you have three packages p, q and r, then if p depends on
q which depends on r then it is illegal to load both p and r as home
units but not q, because q is a dependency of the home unit p which
depends on another home unit r.
If you are using GHC by the command line then this property is checked,
but if you are using the API then you need to check this property
yourself. If you get it wrong you will probably get some very confusing
errors about overlapping instances.
Limitations of Multiple Home Units
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
There are a few limitations of the initial implementation which will be smoothed out on user demand.
* Package thinning/renaming syntax is not supported
* More complicated reexports/renaming are not yet supported.
* It’s more common to run into existing linker bugs when loading a
large number of packages in a session (for example #20674, #20689)
* Backpack is not yet supported when using multiple home units.
* Dependency chasing can be quite slow with a large number of
modules and packages.
* Loading wired-in packages as home units is currently not supported
(this only really affects GHC developers attempting to load
template-haskell).
* Barely any normal GHCi features are supported, it would be good to
support enough for ghcid to work correctly.
Despite these limitations, the implementation works already for nearly
all packages. It has been testing on large dependency closures,
including the whole of head.hackage which is a total of 4784 modules
from 452 packages.
Internal Changes
~~~~~~~~~~~~~~~~
* The biggest change is that the HomePackageTable is replaced with the
HomeUnitGraph. The HomeUnitGraph is a map from UnitId to HomeUnitEnv,
which contains information specific to each home unit.
* The HomeUnitEnv contains:
- A unit state, each home unit can have different package db flags
- A set of dynflags, each home unit can have different flags
- A HomePackageTable
* LinkNode: A new node type is added to the ModuleGraph, this is used to
place the linking step into the build plan so linking can proceed in
parralel with other packages being built.
* New invariant: Dependencies of a ModuleGraphNode can be completely
determined by looking at the value of the node. In order to achieve
this, downsweep now performs a more complete job of downsweeping and
then the dependenices are recorded forever in the node rather than
being computed again from the ModSummary.
* Some transitive module calculations are rewritten to use the
ModuleGraph which is more efficient.
* There is always an active home unit, which simplifies modifying a lot
of the existing API code which is unit agnostic (for example, in the
driver).
The road may be bumpy for a little while after this change but the
basics are well-tested.
One small metric increase, which we accept and also submodule update to
haddock which removes ExtendedModSummary.
Closes #10827
-------------------------
Metric Increase:
MultiLayerModules
-------------------------
Co-authored-by: Fendor <power.walross@gmail.com>
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This completes the fix for #20779 / !7123.
Beforehand, the program worked by accident because the two versions of
the library happened to be ordered properly (due to how the hashes were
computed). In the real world I observed them being the other way around
which meant the final lookup failed because we weren't filtering for
visibility.
I modified the test so that it failed (and it's fixed by this patch).
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This adds a new mode, `--merge-objs`, which can be used to produce
merged GHCi library objects.
As future work we will rip out the object-merging logic in Hadrian and
Cabal and instead use this mode.
Closes #20712.
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In 806e49ae the package imports refactoring code was modified to rename
package imports. There was a small oversight which meant the code didn't
account for module visibility. This patch fixes that oversight.
In general the "lookupPackageName" function is unsafe to use as it
doesn't account for package visiblity/thinning/renaming etc, there is
just one use in the compiler which would be good to audit.
Fixes #20779
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This fixes the ./validate script on my machine.
I also took the step to add some linters which would catch problems like
these in future.
Fixes #20506
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- Change the dumpPrefix to FilePath, and default to non-module
- Add dot to seperate dump-file-prefix and suffix
- Modify user guide to introduce how dump files are named
- This commit does not affect Ghci dump file naming.
See also #17500
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Note [Hydrating Modules]
~~~~~~~~~~~~~~~~~~~~~~~~
What is hydrating a module?
* There are two versions of a module, the ModIface is the on-disk version and the ModDetails is a fleshed-out in-memory version.
* We can **hydrate** a ModIface in order to obtain a ModDetails.
Hydration happens in three different places
* When an interface file is initially loaded from disk, it has to be hydrated.
* When a module is finished compiling, we hydrate the ModIface in order to generate
the version of ModDetails which exists in memory (see Note)
* When dealing with boot files and module loops (see Note [Rehydrating Modules])
Note [Rehydrating Modules]
~~~~~~~~~~~~~~~~~~~~~~~~~~~
If a module has a boot file then it is critical to rehydrate the modules on
the path between the two.
Suppose we have ("R" for "recursive"):
```
R.hs-boot: module R where
data T
g :: T -> T
A.hs: module A( f, T, g ) where
import {-# SOURCE #-} R
data S = MkS T
f :: T -> S = ...g...
R.hs: module R where
data T = T1 | T2 S
g = ...f...
```
After compiling A.hs we'll have a TypeEnv in which the Id for `f` has a type
type uses the AbstractTyCon T; and a TyCon for `S` that also mentions that same
AbstractTyCon. (Abstract because it came from R.hs-boot; we know nothing about
it.)
When compiling R.hs, we build a TyCon for `T`. But that TyCon mentions `S`, and
it currently has an AbstractTyCon for `T` inside it. But we want to build a
fully cyclic structure, in which `S` refers to `T` and `T` refers to `S`.
Solution: **rehydration**. *Before compiling `R.hs`*, rehydrate all the
ModIfaces below it that depend on R.hs-boot. To rehydrate a ModIface, call
`typecheckIface` to convert it to a ModDetails. It's just a de-serialisation
step, no type inference, just lookups.
Now `S` will be bound to a thunk that, when forced, will "see" the final binding
for `T`; see [Tying the knot](https://gitlab.haskell.org/ghc/ghc/-/wikis/commentary/compiler/tying-the-knot).
But note that this must be done *before* compiling R.hs.
When compiling R.hs, the knot-tying stuff above will ensure that `f`'s unfolding
mentions the `LocalId` for `g`. But when we finish R, we carefully ensure that
all those `LocalIds` are turned into completed `GlobalIds`, replete with
unfoldings etc. Alas, that will not apply to the occurrences of `g` in `f`'s
unfolding. And if we leave matters like that, they will stay that way, and *all*
subsequent modules that import A will see a crippled unfolding for `f`.
Solution: rehydrate both R and A's ModIface together, right after completing R.hs.
We only need rehydrate modules that are
* Below R.hs
* Above R.hs-boot
There might be many unrelated modules (in the home package) that don't need to be
rehydrated.
This dark corner is the subject of #14092.
Suppose we add to our example
```
X.hs module X where
import A
data XT = MkX T
fx = ...g...
```
If in `--make` we compile R.hs-boot, then A.hs, then X.hs, we'll get a `ModDetails` for `X` that has an AbstractTyCon for `T` in the the argument type of `MkX`. So:
* Either we should delay compiling X until after R has beeen compiled.
* Or we should rehydrate X after compiling R -- because it transitively depends on R.hs-boot.
Ticket #20200 has exposed some issues to do with the knot-tying logic in GHC.Make, in `--make` mode.
this particular issue starts [here](https://gitlab.haskell.org/ghc/ghc/-/issues/20200#note_385758).
The wiki page [Tying the knot](https://gitlab.haskell.org/ghc/ghc/-/wikis/commentary/compiler/tying-the-knot) is helpful.
Also closely related are
* #14092
* #14103
Fixes tickets #20200 #20561
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It appears that libstdc++ is no longer available in recent XCode
distributions.
Closes #16083.
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At the moment if `-dynamic-too` fails then we rerun the whole pipeline
as if we were just in `-dynamic` mode. I argue this is a misfeature and
we should remove the so-called `DT_Failed` mode.
In what situations do we fall back to `DT_Failed`?
1. If the `dyn_hi` file corresponding to a `hi` file is missing completely.
2. If the interface hash of `dyn_hi` doesn't match the interface hash of `hi`.
What happens in `DT_Failed` mode?
* The whole compiler pipeline is rerun as if the user had just passed `-dynamic`.
* Therefore `dyn_hi/dyn_o` files are used which don't agree with the
`hi/o` files. (As evidenced by `dynamicToo001` test).
* This is very confusing as now a single compiler invocation has
produced further `hi`/`dyn_hi` files which are different to each
other.
Why should we remove it?
* In `--make` mode, which is predominately used `DT_Failed` does not
work (#19782), there can't be users relying on this functionality.
* In `-c` mode, the recovery doesn't fix the root issue, which is the
`dyn_hi` and `hi` files are mismatched. We should instead produce an
error and pass responsibility to the build system using `-c` to ensure
that the prerequisites for `-dynamic-too` (dyn_hi/hi) files are there
before we start compiling.
* It is a misfeature to support use cases like `dynamicToo001` which
allow you to mix different versions of dynamic/non-dynamic interface
files. It's more likely to lead to subtle bugs in your resulting
programs where out-dated build products are used rather than a
deliberate choice.
* In practice, people are usually compiling with `-dynamic-too` rather
than separately with `-dynamic` and `-static`, so the build products
always match and `DT_Failed` is only entered due to compiler bugs (see
!6583)
What should we do instead?
* In `--make` mode, for home packages check during recompilation
checking that `dyn_hi` and `hi` are both present and agree, recompile
the modules if they do not.
* For package modules, when loading the interface check that `dyn_hi`
and `hi` are there and that they agree but fail with an
error message if they are not.
* In `--oneshot` mode, fail with an error message if the right files
aren't already there.
Closes #19782 #20446 #9176 #13616
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Before we would print
[1 of 3] Compiling T[boot] ( T.hs-boot, nothing, T.dyn_o )
Which was clearly wrong for two reasons.
1. No dynamic object file was produced for T[boot]
2. The file would be called T.dyn_o-boot if it was produced.
Fixes #20300
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ModLocation is the data type which tells you the locations of all the
build products which can affect recompilation. It is now computed in one
place and not modified through the pipeline. Important locations will
now just consult ModLocation rather than construct the dynamic object
path incorrectly.
* Add paths for dynamic object and dynamic interface files to
ModLocation.
* Always use the paths from mod location when looking for where to find
any interface or object file.
* Always use the paths in a ModLocation when deciding where to write an
interface and object file.
* Remove `dynamicOutputFile` and `dynamicOutputHi` functions which
*calculated* (incorrectly) the location of `dyn_o` and `dyn_hi` files.
* Don't set `outputFile_` and so-on in `enableCodeGenWhen`, `-o` and
hence `outputFile_` should not affect the location of object files in
`--make` mode. It is now sufficient to just update the ModLocation with
the temporary paths.
* In `hscGenBackendPipeline` don't recompute the `ModLocation` to
account for `-dynamic-too`, the paths are now accurate from the start
of the run.
* Rename `getLocation` to `mkOneShotModLocation`, as that's the only
place it's used. Increase the locality of the definition by moving it
close to the use-site.
* Load the dynamic interface from ml_dyn_hi_file rather than attempting
to reconstruct it in load_dynamic_too.
* Add a variety of tests to check how -o -dyno etc interact with each
other.
Some other clean-ups
* DeIOify mkHomeModLocation and friends, they are all pure functions.
* Move FinderOpts into GHC.Driver.Config.Finder, next to initFinderOpts.
* Be more precise about whether we mean outputFile or outputFile_: there
were many places where outputFile was used but the result shouldn't have
been affected by `-dyno` (for example the filename of the resulting
executable). In these places dynamicNow would never be set but it's
still more precise to not allow for this possibility.
* Typo fixes suffices -> suffixes in the appropiate places.
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This test checks that we check for missing dynamic objects if
dynamic-too is enabled implicitly by the driver.
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Previously it was unclear whether req_shared_libs should require:
* that the platform supports dynamic library loading,
* that GHC supports dynamic linking of Haskell code, or
* that the dyn way libraries were built
Clarify by splitting the predicate into two:
* `req_dynamic_lib_support` demands that the platform support dynamic
linking
* `req_dynamic_hs` demands that the GHC support dynamic linking of
Haskell code on the target platform
Naturally `req_dynamic_hs` cannot be true unless
`req_dynamic_lib_support` is also true.
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Suppress output from diff to eliminate unnecessary
environmental-dependence.
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Fixes #20459
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Before if you passed both options then you would generate two identical
hi/dyn_hi and o/dyn_o files, both in the dynamic way. It's better to
warn this is happening rather than duplicating the work and causing
potential confusion.
-dynamic-too should only be used with -static.
Fixes #20436
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The BSD sed implementation doesn't allow `sed -i COMMAND FILE`; one must
rather use `sed -i -e COMMAND FILE`.
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This commit fixes the following bug: when `outputHi` is set, and
both `.dyn_hi` and `.hi` are needed, both would be written to
`outputHi`, causing `.dyn_hi` to overwrite `.hi`. This causes
subsequent `readIface` to fail - "mismatched interface file profile
tag (wanted "", got "dyn")" - triggering unnecessary rebuild.
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This patch specifies and simplifies the module cycle compilation
in upsweep. How things work are described in the Note [Upsweep]
Note [Upsweep]
~~~~~~~~~~~~~~
Upsweep takes a 'ModuleGraph' as input, computes a build plan and then executes
the plan in order to compile the project.
The first step is computing the build plan from a 'ModuleGraph'.
The output of this step is a `[BuildPlan]`, which is a topologically sorted plan for
how to build all the modules.
```
data BuildPlan = SingleModule ModuleGraphNode -- A simple, single module all alone but *might* have an hs-boot file which isn't part of a cycle
| ResolvedCycle [ModuleGraphNode] -- A resolved cycle, linearised by hs-boot files
| UnresolvedCycle [ModuleGraphNode] -- An actual cycle, which wasn't resolved by hs-boot files
```
The plan is computed in two steps:
Step 1: Topologically sort the module graph without hs-boot files. This returns a [SCC ModuleGraphNode] which contains
cycles.
Step 2: For each cycle, topologically sort the modules in the cycle *with* the relevant hs-boot files. This should
result in an acyclic build plan if the hs-boot files are sufficient to resolve the cycle.
The `[BuildPlan]` is then interpreted by the `interpretBuildPlan` function.
* `SingleModule nodes` are compiled normally by either the upsweep_inst or upsweep_mod functions.
* `ResolvedCycles` need to compiled "together" so that the information which ends up in
the interface files at the end is accurate (and doesn't contain temporary information from
the hs-boot files.)
- During the initial compilation, a `KnotVars` is created which stores an IORef TypeEnv for
each module of the loop. These IORefs are gradually updated as the loop completes and provide
the required laziness to typecheck the module loop.
- At the end of typechecking, all the interface files are typechecked again in
the retypecheck loop. This time, the knot-tying is done by the normal laziness
based tying, so the environment is run without the KnotVars.
* UnresolvedCycles are indicative of a proper cycle, unresolved by hs-boot files
and are reported as an error to the user.
The main trickiness of `interpretBuildPlan` is deciding which version of a dependency
is visible from each module. For modules which are not in a cycle, there is just
one version of a module, so that is always used. For modules in a cycle, there are two versions of
'HomeModInfo'.
1. Internal to loop: The version created whilst compiling the loop by upsweep_mod.
2. External to loop: The knot-tied version created by typecheckLoop.
Whilst compiling a module inside the loop, we need to use the (1). For a module which
is outside of the loop which depends on something from in the loop, the (2) version
is used.
As the plan is interpreted, which version of a HomeModInfo is visible is updated
by updating a map held in a state monad. So after a loop has finished being compiled,
the visible module is the one created by typecheckLoop and the internal version is not
used again.
This plan also ensures the most important invariant to do with module loops:
> If you depend on anything within a module loop, before you can use the dependency,
the whole loop has to finish compiling.
The end result of `interpretBuildPlan` is a `[MakeAction]`, which are pairs
of `IO a` actions and a `MVar (Maybe a)`, somewhere to put the result of running
the action. This list is topologically sorted, so can be run in order to compute
the whole graph.
As well as this `interpretBuildPlan` also outputs an `IO [Maybe (Maybe HomeModInfo)]` which
can be queried at the end to get the result of all modules at the end, with their proper
visibility. For example, if any module in a loop fails then all modules in that loop will
report as failed because the visible node at the end will be the result of retypechecking
those modules together.
Along the way we also fix a number of other bugs in the driver:
* Unify upsweep and parUpsweep.
* Fix #19937 (static points, ghci and -j)
* Adds lots of module loop tests due to Divam.
Also related to #20030
Co-authored-by: Divam Narula <dfordivam@gmail.com>
-------------------------
Metric Decrease:
T10370
-------------------------
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The logic didn't account for the fact that the paths could contain
spaces before which led to errors such as the following from
install_name_tool.
Stderr ( T14304 ):
Warning: -rtsopts and -with-rtsopts have no effect with -shared.
Call hs_init_ghc() from your main() function to set these options.
error: /nix/store/a6j5761iy238pbckxq2xrhqr2d5kra4m-cctools-binutils-darwin-949.0.1/bin/install_name_tool: for: dist/build/libHSp-0.1-ghc8.10.6.dylib (for architecture arm64) option "-add_rpath /Users/matt/ghc/bindisttest/install dir/lib/ghc-8.10.6/ghc-prim-0.6.1" would duplicate path, file already has LC_RPATH for: /Users/matt/ghc/bindisttest/install dir/lib/ghc-8.10.6/ghc-prim-0.6.1
`install_name_tool' failed in phase `Install Name Tool'. (Exit code: 1)
Fixes #20212
This apparently also fixes #20026, which is a nice surprise.
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`diff` uses the locale to print its message.
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As described in #18011, this mode provides similar functionality to the
`runhaskell` command, but doesn't require that the user know the path of
yet another executable, simplifying interactions with upstream tools.
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In order:
* Introduce the `PsErrUnknownOptionsPragma` diagnostic message
This commit changes the diagnostic emitted inside
`GHC.Parser.Header.checkProcessArgsResult` from an (erroneous) and
unstructured `DriverUnknownMessage` to a `PsErrUnknownOPtionsPragma`,
i.e. a new data constructor of a `PsHeaderMessage`.
* Add the `DriverUserDefinedRuleIgnored` diagnostic message
* Add `DriverUserDefinedRuleIgnored` data constructor
This commit adds (and use) a new data constructor to the `DriverMessage`
type, replacing a `DriverUnknownMessage` with it.
* Add and use `DriverCannotLoadInterfaceFile` constructor
This commit introduces the DriverCannotLoadInterfaceFile constructor for
the `DriverMessage` type and it uses it to replace and occurrence of
`DriverUnknownMessage`.
* Add and use the `DriverInferredSafeImport` constructor
This commit adds a new `DriverInferredSafeImport` constructor to the
`DriverMessage` type, and uses it in `GHC.Driver.Main` to replace one
occurrence of `DriverUnknownMessage`.
* Add and use `DriverCannotImportUnsafeModule` constructor
This commit adds the `DriverCannotImportUnsafeModule` constructor
to the `DriverMessage` type, and later using it to replace one usage of
`DriverUnknownMessage` in the `GHC.Driver.Main` module.
* Add and use `DriverMissingSafeHaskellMode` constructor
* Add and use `DriverPackageNotTrusted` constructor
* Introduce and use `DriverInferredSafeModule` constructor
* Add and use `DriverMarkedTrustworthyButInferredSafe` constructor
* Add and use `DriverCannotImportFromUntrustedPackage`
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The GHC.Prim module is quite special as there is no interface file,
therefore it doesn't appear in ms_textual_imports, but the ghc-prim
package does appear in the direct package dependencies. This confused
the recompilation checking which couldn't find any modules from ghc-prim
and concluded that the package was no longer a dependency.
The fix is to keep track of whether GHC.Prim is imported separately in
the relevant places.
Fixes #20084
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This test has worked since 8.10.2 at least but was recently broken and
is now working again after this patch.
Closes #12983
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Fixed in 25977ab542a30df4ae71d9699d015bcdd1ab7cfb
Fixes #17481
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Cabal explicitly passes options to set the rpath, which we then also try
to set using install_name_tool. Cabal should also pass `-fno-use-rpaths`
to suppress the setting of the rpath from within GHC.
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This commit:
commit c6faa42bfb954445c09c5680afd4fb875ef03758
Author: Simon Peyton Jones <simonpj@microsoft.com>
Date: Mon Mar 9 10:20:42 2020 +0000
Avoid useless w/w split
This patch is just a tidy-up for the post-strictness-analysis
worker wrapper split. Consider
f x = x
Strictnesss analysis does not lead to a w/w split, so the
obvious thing is to leave it 100% alone. But actually, because
the RHS is small, we ended up adding a StableUnfolding for it.
There is some reason to do this if we choose /not/ do to w/w
on the grounds that the function is small. See
Note [Don't w/w inline small non-loop-breaker things]
But there is no reason if we would not have done w/w anyway.
This patch just moves the conditional to later. Easy.
turns out to have a bug in it. Instead of /moving/ the conditional,
I /duplicated/ it. Then in a subsequent unrelated tidy-up
(087ac4eb) I removed the second (redundant) test!
This patch does what I originally intended.
There is also a small refactoring in GHC.Core.Unfold, to make the
code clearer, but with no change in behaviour.
It does, however, have a generally good effect on compile times,
because we aren't dealing with so many silly stable unfoldings.
Here are the non-zero changes:
Metrics: compile_time/bytes allocated
-------------------------------------
Baseline
Test Metric value New value Change
---------------------------------------------------------------------------
ManyAlternatives(normal) ghc/alloc 791969344.0 792665048.0 +0.1%
ManyConstructors(normal) ghc/alloc 4351126824.0 4358303528.0 +0.2%
PmSeriesG(normal) ghc/alloc 50362552.0 50482208.0 +0.2%
PmSeriesS(normal) ghc/alloc 63733024.0 63619912.0 -0.2%
T10421(normal) ghc/alloc 121224624.0 119695448.0 -1.3% GOOD
T10421a(normal) ghc/alloc 85256392.0 83714224.0 -1.8%
T10547(normal) ghc/alloc 29253072.0 29258256.0 +0.0%
T10858(normal) ghc/alloc 189343152.0 187972328.0 -0.7%
T11195(normal) ghc/alloc 281208248.0 279727584.0 -0.5%
T11276(normal) ghc/alloc 141966952.0 142046224.0 +0.1%
T11303b(normal) ghc/alloc 46228360.0 46259024.0 +0.1%
T11545(normal) ghc/alloc 2663128768.0 2667412656.0 +0.2%
T11822(normal) ghc/alloc 138686944.0 138760176.0 +0.1%
T12227(normal) ghc/alloc 482836000.0 475421056.0 -1.5% GOOD
T12234(optasm) ghc/alloc 60710520.0 60781808.0 +0.1%
T12425(optasm) ghc/alloc 104089000.0 104022424.0 -0.1%
T12545(normal) ghc/alloc 1711759416.0 1705711528.0 -0.4%
T12707(normal) ghc/alloc 991541120.0 991921776.0 +0.0%
T13035(normal) ghc/alloc 108199872.0 108370704.0 +0.2%
T13056(optasm) ghc/alloc 414642544.0 412580384.0 -0.5%
T13253(normal) ghc/alloc 361701272.0 355838624.0 -1.6%
T13253-spj(normal) ghc/alloc 157710168.0 157397768.0 -0.2%
T13379(normal) ghc/alloc 370984400.0 371345888.0 +0.1%
T13701(normal) ghc/alloc 2439764144.0 2441351984.0 +0.1%
T14052(ghci) ghc/alloc 2154090896.0 2156671400.0 +0.1%
T15164(normal) ghc/alloc 1478517688.0 1440317696.0 -2.6% GOOD
T15630(normal) ghc/alloc 178053912.0 172489808.0 -3.1%
T16577(normal) ghc/alloc 7859948896.0 7854524080.0 -0.1%
T17516(normal) ghc/alloc 1271520128.0 1202096488.0 -5.5% GOOD
T17836(normal) ghc/alloc 1123320632.0 1123922480.0 +0.1%
T17836b(normal) ghc/alloc 54526280.0 54576776.0 +0.1%
T17977b(normal) ghc/alloc 42706752.0 42730544.0 +0.1%
T18140(normal) ghc/alloc 108834568.0 108693816.0 -0.1%
T18223(normal) ghc/alloc 5539629264.0 5579500872.0 +0.7%
T18304(normal) ghc/alloc 97589720.0 97196944.0 -0.4%
T18478(normal) ghc/alloc 770755472.0 771232888.0 +0.1%
T18698a(normal) ghc/alloc 408691160.0 374364992.0 -8.4% GOOD
T18698b(normal) ghc/alloc 492419768.0 458809408.0 -6.8% GOOD
T18923(normal) ghc/alloc 72177032.0 71368824.0 -1.1%
T1969(normal) ghc/alloc 803523496.0 804655112.0 +0.1%
T3064(normal) ghc/alloc 198411784.0 198608512.0 +0.1%
T4801(normal) ghc/alloc 312416688.0 312874976.0 +0.1%
T5321Fun(normal) ghc/alloc 325230680.0 325474448.0 +0.1%
T5631(normal) ghc/alloc 592064448.0 593518968.0 +0.2%
T5837(normal) ghc/alloc 37691496.0 37710904.0 +0.1%
T783(normal) ghc/alloc 404629536.0 405064432.0 +0.1%
T9020(optasm) ghc/alloc 266004608.0 266375592.0 +0.1%
T9198(normal) ghc/alloc 49221336.0 49268648.0 +0.1%
T9233(normal) ghc/alloc 913464984.0 742680256.0 -18.7% GOOD
T9675(optasm) ghc/alloc 552296608.0 466322000.0 -15.6% GOOD
T9872a(normal) ghc/alloc 1789910616.0 1793924472.0 +0.2%
T9872b(normal) ghc/alloc 2315141376.0 2310338056.0 -0.2%
T9872c(normal) ghc/alloc 1840422424.0 1841567224.0 +0.1%
T9872d(normal) ghc/alloc 556713248.0 556838432.0 +0.0%
T9961(normal) ghc/alloc 383809160.0 384601600.0 +0.2%
WWRec(normal) ghc/alloc 773751272.0 753949608.0 -2.6% GOOD
Residency goes down too:
Metrics: compile_time/max_bytes_used
------------------------------------
Baseline
Test Metric value New value Change
-----------------------------------------------------------
T10370(optasm) ghc/max 42058448.0 39481672.0 -6.1%
T11545(normal) ghc/max 43641392.0 43634752.0 -0.0%
T15304(normal) ghc/max 29895824.0 29439032.0 -1.5%
T15630(normal) ghc/max 8822568.0 8772328.0 -0.6%
T18698a(normal) ghc/max 13882536.0 13787112.0 -0.7%
T18698b(normal) ghc/max 14714112.0 13836408.0 -6.0%
T1969(normal) ghc/max 24724128.0 24733496.0 +0.0%
T3064(normal) ghc/max 14041152.0 14034768.0 -0.0%
T3294(normal) ghc/max 32769248.0 32760312.0 -0.0%
T9630(normal) ghc/max 41605120.0 41572184.0 -0.1%
T9675(optasm) ghc/max 18652296.0 17253480.0 -7.5%
Metric Decrease:
T10421
T12227
T15164
T17516
T18698a
T18698b
T9233
T9675
WWRec
Metric Increase:
T12545
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This commit converts a bunch of HsToCore (Ds) messages to use the new
GHC's diagnostic message infrastructure. In particular the DsMessage
type has been expanded with a lot of type constructors, each
encapsulating a particular error and warning emitted during desugaring.
Due to the fact that levity polymorphism checking can happen both at the
Ds and at the TcRn level, a new `TcLevityCheckDsMessage` constructor has
been added to the `TcRnMessage` type.
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This patch comprises of four different but closely related ideas. The
net result is fixing a large number of open issues with the driver
whilst making it simpler to understand.
1. Use the hash of the source file to determine whether the source file
has changed or not. This makes the recompilation checking more robust to
modern build systems which are liable to copy files around changing
their modification times.
2. Remove the concept of a "stable module", a stable module was one
where the object file was older than the source file, and all transitive
dependencies were also stable. Now we don't rely on the modification
time of the source file, the notion of stability is moot.
3. Fix TH/plugin recompilation after the removal of stable modules. The
TH recompilation check used to rely on stable modules. Now there is a
uniform and simple way, we directly track the linkables which were
loaded into the interpreter whilst compiling a module. This is an
over-approximation but more robust wrt package dependencies changing.
4. Fix recompilation checking for dynamic object files. Now we actually
check if the dynamic object file exists when compiling with -dynamic-too
Fixes #19774 #19771 #19758 #17434 #11556 #9121 #8211 #16495 #7277 #16093
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This change aims to make source files relocatable w.r.t. to the interface files produced by the compiler.
This is so that we can download interface files produced by a cloud build system and then reuse them in a local ghcide session
catch another case of implicit includes
actually use the implicit quote includes
add another missing case
recomp020
test that .hi files are reused even if .hs files are moved to a new location
Added recomp021 to record behaviour with non implicit includes
add a note
additional pointer to the note
Mention #16956 in Note
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This commit converts the lexers and all the parser machinery to use the
new parser types and diagnostics infrastructure. Furthermore, it cleans
up the way the parser code was emitting hints.
As a result of this systematic approach, the test output of the
`InfixAppPatErr` and `T984` tests have been changed. Previously they
would emit a `SuggestMissingDo` hint, but this was not at all helpful in
resolving the error, and it was even confusing by just looking at the
original program that triggered the errors.
Update haddock submodule
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Insufficient lazyness causes a loop while typechecking
COMPLETE pragmas from interfaces (#19744).
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module compilation
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This commit extends the GHC diagnostic hierarchy with a `GhcHint` type,
modelling helpful suggestions emitted by GHC which can be used to deal
with a particular warning or error.
As a direct consequence of this, the `Diagnostic` typeclass has been extended
with a `diagnosticHints` method, which returns a `[GhcHint]`. This means
that now we can clearly separate out the printing of the diagnostic
message with the suggested fixes.
This is done by extending the `printMessages` function in
`GHC.Driver.Errors`.
On top of that, the old `PsHint` type has been superseded by the new `GhcHint`
type, which de-duplicates some hints in favour of a general `SuggestExtension`
constructor that takes a `GHC.LanguageExtensions.Extension`.
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This commit modifies interface files so that *only* direct information
about modules and packages is stored in the interface file.
* Only direct module and direct package dependencies are stored in the
interface files.
* Trusted packages are now stored separately as they need to be checked
transitively.
* hs-boot files below the compiled module in the home module are stored
so that eps_is_boot can be calculated in one-shot mode without loading
all interface files in the home package.
* The transitive closure of signatures is stored separately
This is important for two reasons
* Less recompilation is needed, as motivated by #16885, a lot of
redundant compilation was triggered when adding new imports deep in the
module tree as all the parent interface files had to be redundantly
updated.
* Checking an interface file is cheaper because you don't have to
perform a transitive traversal to check the dependencies are up-to-date.
In the code, places where we would have used the transitive closure, we
instead compute the necessary transitive closure. The closure is not
computed very often, was already happening in checkDependencies, and
was already happening in getLinkDeps.
Fixes #16885
-------------------------
Metric Decrease:
MultiLayerModules
T13701
T13719
-------------------------
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(cherry picked from commit b821fcc7142edff69aa4c47dc1a5bd30b13c1ceb)
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-Wno-unsupported-llvm-version should suppress the LLVM version
missmatch warning that messes up the output.
(cherry picked from commit 63455300625fc12b2aafc3e339eb307510a6e8bd)
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before:
> /home/matt/Projects/persistent/persistent/Database/Persist/ImplicitIdDef.hs:1:8: error:
> File name does not match module name:
> Saw: ‘A.B.Module’
> Expected: ‘A.B.Motule’
> |
> 1 | module A.B.Motule
> | ^^^^^^^^^^>
after:
> /home/matt/Projects/persistent/persistent/Database/Persist/ImplicitIdDef.hs:1:8: error:
> File name does not match module name:
> Saw: ‘A.B.Module’
> Expected: ‘A.B.Motule’
> |
> 1 | module A.B.Motule
> | ^^^^^^^^^^>
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Fixes #8144
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This commit adds GhcMessage and ancillary (PsMessage, TcRnMessage, ..)
types.
These types will be expanded to represent more errors generated
by different subsystems within GHC. Right now, they are underused,
but more will come in the glorious future.
See
https://gitlab.haskell.org/ghc/ghc/-/wikis/Errors-as-(structured)-values
for a design overview.
Along the way, lots of other things had to happen:
* Adds Semigroup and Monoid instance for Bag
* Fixes #19746 by parsing OPTIONS_GHC pragmas into Located Strings.
See GHC.Parser.Header.toArgs (moved from GHC.Utils.Misc, where it
didn't belong anyway).
* Addresses (but does not completely fix) #19709, now reporting
desugarer warnings and errors appropriately for TH splices.
Not done: reporting type-checker warnings for TH splices.
* Some small refactoring around Safe Haskell inference, in order
to keep separate classes of messages separate.
* Some small refactoring around initDsTc, in order to keep separate
classes of messages separate.
* Separate out the generation of messages (that is, the construction
of the text block) from the wrapping of messages (that is, assigning
a SrcSpan). This is more modular than the previous design, which
mixed the two.
Close #19746.
This was a collaborative effort by Alfredo di Napoli and
Richard Eisenberg, with a key assist on #19746 by Iavor
Diatchki.
Metric Increase:
MultiLayerModules
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When -dynamic-too is enabled, there are two result files, .o and .dyn_o,
therefore we should check both to decide whether to set SourceModified
or not.
The whole recompilation logic is very messy, a more thorough refactor
would be beneficial in this area but this is the minimal patch to fix
this more high priority problem.
Fixes #17968 and hopefully #17534
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