Core transformations apply to the whole InfoTable, the REPL needs to
apply Core transformations to the single node that it compiles from the
user input string.
The solution in this commit is to:
1. Compile the input string as before to obtain a Core Node.
2. Add this Node to a copy of the Core InfoTable for the loaded file.
3. Apply the (CLI specified) Core transformations to this InfoTable.
4. Extract the (now transformed) Node from the InfoTable.
We can think of a way to improve this, maybe when we tackle allowing the
user to make new definitions in the REPL.
As soon as compilation of pattern matching is complete we should enable
some (all?) Core transformations by default.
Example:
At the moment we get the following result in the REPL:
```
juvix repl
...
Stdlib.Prelude> 1 + 1
suc (suc zero)
```
After this commit we can turn on `nat-to-int` transformation:
```
juvix repl -t nat-to-int
Stdlib.Prelude> 1 + 1
2
```
* Part of https://github.com/anoma/juvix/issues/1531
This PR:
- Closes#1647
It gives compilation errors for language features that require more
substantial support (recursion, polymorphism). The additional features
are to be implemented in future separate PRs.
* Adds a new target `geb` to the CLI command `juvix dev core compile`,
which produces a `*.geb` output file in the `.juvix-build` directory.
* Adds a few tests. These are not yet checked automatically because
there is no GEB evaluator; checking the `*.geb` output would be too
brittle.
This PR addresses a caching issue in our CI by streamlining each
operating system's build and test processes, reducing CI time. 🤞 Also,
our caching strategy has been updated with the new restore/save actions.
For example, we aim to cache the .stack folder, and if the stack build
is successful, the .stack-build. The building documentation job
continues depending on the Linux build. Upon merging this PR, we get
back to the point where the CI maintain a cache for each OS to be shared
among all PRs, significantly reducing CI testing time. The expected
scenario is as follows. The CI can take, on average, 35' in Linux to
build and test everything. Using caching, that time is reduced to less
than 10'. macOS is a different story. It can easily take one hour, and
even more, the first time to build and test the project. After that, it
might take an average of 20'.
- Caching strategies
[descriptions](https://github.com/actions/cache/blob/main/caching-strategies.md#saving-cache-even-if-the-build-fails)
- Closes#1776
Before this change, nested as-patterns (i.e as-patterns binding
arguments to constructors) were not translated to Core pattern binders.
This meant that the following function would crash the compiler:
```
f : List Nat -> List Nat;
f (x :: a@(x' :: xs)) := a;
f _ := nil;
```
i.e the nested as-pattern `a` was ignored in the internal to core
translation.
This commit translates each as-pattern to a Core `PatternBinder`.
* Fixes https://github.com/anoma/juvix/issues/1788
* Fixes https://github.com/anoma/juvix/issues/1738
- Closes#1637.
A function type signature is now allowed to have a body. This is valid
for both top level and let definitions.
```
not : Bool -> Bool := λ {
| true := false
| false := true
};
```
This PR adds a new field `infoBuiltins : HashMap BuiltinPrim IdentKind`
to the Core InfoTable. This is used to register builtin inductive,
constructors and functions against their corresponding Core
symbols/tags.
The point of doing this is to make it easier to lookup the Infos for
builtins during the internal to core translation:
d91241a685/src/Juvix/Compiler/Core/Translation/FromInternal.hs (L65)
This is one proposed approach, I think Jan mentioned using the Builtins
effect for this but it doesn't seem appropriate to expose the
registration function from the Builtins effect at this part of the code.
Perhaps I misunderstood, if so I'm happy to revisit this refactor.
The integer to Nat translation in the Internal to Core translation
depends on both Nat and Bool builtin types being in the InfoTable.
544bddba43/src/Juvix/Compiler/Core/Translation/FromInternal.hs (L67)
If the root module does not contain an explicit reference to the builtin
Bool (for example) then builtin Bool type is filtered out by the
reachability analysis and therefore is not available at transltaion
time.
In this commit we add both builtin Nat and builtin Bool as start nodes
in the reachability analysis to guarantee that they will not be filtered
out.
- Fixes https://github.com/anoma/juvix/issues/1774
- Fixes#1723
- It refactors parsing/scoping so that the scoper does not need to read
files or parse any module. Instead, the parser takes care of parsing all
the imported modules transitively.
Filepaths within a Loc must now be absolute or an error is thrown when
mkLoc is called. This Loc is used when displaying errors.
This commit uses imaginary absolute file paths in the Core repl and Asm
commands in the cases (parsing a single expression for example).
Before this fix, the `core {repl, read, eval}` and `asm` commands would
crash if it encountered an error when invoked with a relative path, or
in the case of a repl when parsing a single expression.
Filepaths within a `Loc` must now be absolute or an error is thrown when
`mkLoc` is called. This `Loc` is used when displaying errors.
This commit converts the Core evaluator filepath to an absolute path
before calling `mkLoc`.
Before this fix, the Core evaluator would crash if it encountered an
error instead of displaying the error if called on a relative path.
The current Github action responsible for installing Wasmer fails from
time to time, and it also is outdated, not following the new NodeJS 16
requirement by Github.
We could use https://github.com/jaxxstorm/action-install-gh-release
instead, but unfortunately, it does not have the proper support to
expose the binaries contained in an inner folder, as in the case with
the Wasmer release. In the meantime, let's use my
[fork](https://github.com/jonaprieto/action-install-gh-release) while I
open PR to the main repository.
Juvix now provides an intial and functional formatting tool by calling
the command `juvix dev scope file --with-comments` .
This PR adds a new Makefile target `juvix-format` to format all the
Juvix programs we showcase in the documentation as Juvix-projects, i.e.,
files from the `examples` directory. Note the corresponding target in
the Makefile also calls the typechecker to ensure the programs do not
have type errors introduced by the formatter, considering also that all
the Juvix files in the `examples` directory type-checked before this PR.
Thus, we should preserve that state. Finally, I included `juvix-format`
as part of the `check` target, so we widen the testing of the compiler.
The formatter is not perfect yet, so we need to fix some formatting
issues manually.
For example, the end of the line is modified by the formatting. We can
fix this by calling after
`make pre-commit`.
This PR adds some maintenance at different levels to the CI config, the
Make file, and formatting.
- Most of the actions used by the CI related to haskell, ormolu, hlint
and pre-commit have been updated because Github requires NodeJS 16. This
change removes all the old warnings related to nodeJs.
In the case of ormolu, the new version makes us format some files that
were not formatted before, similarly with hlint.
- The CI has been updated to use the latest version of the Smoke testing
framework, which introduced installation of the dependencies for Linux
(libicu66) and macOS (icu4c) in the CI. In the case of macOS, the CI
uses a binary for smoke. For Linux, we use stack to build smoke from the
source. The source here is in a fork of [the official Smoke
repo](https://github.com/SamirTalwar/smoke). Such includes some
features/changes that are not yet in the official repo.
- The Makefile runs the ormolu and hlint targets using as a path for the
binaries the environment variables ORMOLU and HLINT. Thus, export those
variables in your environment before running `make check,` `make format`
or `make hlint`. Otherwise, the Makefile will use the binaries provided
by `stack`.
Co-authored-by: Paul Cadman <git@paulcadman.dev>
We need to use the homebrew Clang/LLVM installation to build the Juvix
runtime because macOS ships with a version of Clang/LLVM that does not
support the wasi target.
The GitHub action runner agent has the homebrew packaged Clang/LLVM
installed but it is not on the shell PATH.
We were using `brew --prefix llvm@14` to point to the homebrew
Clang/LLVM installation. However this breaks when the runner image is
updated to a new version of llvm.
So we switch to using `brew --prefix llvm` which will resolve to the
latest (and in this case only) version of homebrew Clang/LLVM. This will
be stable when Clang/LLVM is updated to a new version.
* Closes#1597
* Closes#1624
* Closes#1633
The tutorial uses syntax which has not been implemented yet: it depends
on
- #1637,
- #1716,
- #1639,
- #1638.
The tutorial also assumes the following issues are done:
- #1720, and
- #1701.
Co-authored-by: Jonathan Cubides <jonathan.cubides@uib.no>
