- Closes#2549
The implementation of wildcard constructors was previously done in the
arity checker. I did not realise I was missing it because there was not
tests for it that included typechecking (we were only checking
formatting).
This patch dramatically increases the efficiency of `juvix dev root`,
which was unnecessarily parsing all dependencies included in the
`Package.juvix` file. Other commands that do not require the `Package`
will also be faster.
It also refactors some functions so that the `TaggedLock` effect is run
globally.
I've added `singletons-base` as a dependency so we can have `++` on the
type level. We've tried to define a type family ourselves but inference
was not working properly.
## Overview
This PR makes the compiler pipeline thread-safe so that the test suite
can be run in parallel.
This is achieved by:
* Removing use of `{get, set, with}CurrentDir` functions.
* Adding locking around shared file resources like the the
global-project and internal build directory.
NB: **Locking is disabled for the main compiler target**, as it is
single threaded they are not required.
## Run test suite in parallel
To run the test suite in parallel you must add `--ta '+RTS -N -RTS'` to
your stack test arguments. For example:
```
stack test --fast --ta '+RTS -N -RTS'
```
The `-N` instructs the Haskell runtime to choose the number of threads
to use based on how many processors there are on your machine. You can
use `-Nn` to see the number of threads to `n`.
These flags are already [set in the
Makefile](e6dca22cfd/Makefile (L26))
when you or CI uses `stack test`.
## Locking
The Haskell package
[filelock](https://hackage.haskell.org/package/filelock) is used for
locking. File locks are used instead of MVars because Juvix code does
not control when new threads are created, they are created by the test
suite. This means that MVars created by Juvix code will have no effect,
because they are created independently on each test-suite thread.
Additionally the resources we're locking live on the filesystem and so
can be conveniently tagged by path.
### FileLock
The filelock library is wrapped in a FileLock effect:
e6dca22cfd/src/Juvix/Data/Effect/FileLock/Base.hs (L6-L8)
There is an [IO
interpreter](e6dca22cfd/src/Juvix/Data/Effect/FileLock/IO.hs (L8))
that uses filelock and an [no-op
interpreter](e6dca22cfd/src/Juvix/Data/Effect/FileLock/Permissive.hs (L7))
that just runs actions unconditionally.
### TaggedLock
To make the file locks simpler to use a TaggedLock effect is introduced:
e6dca22cfd/src/Juvix/Data/Effect/TaggedLock/Base.hs (L5-L11)
And convenience function:
e6dca22cfd/src/Juvix/Data/Effect/TaggedLock.hs (L28)
This allows an action to be locked, tagged by a directory that may or
may not exist. For example in the following code, an action is performed
on a directory `root` that may delete the directory before repopulating
the files. So the lockfile cannot be stored in the `root` itself.
e6dca22cfd/src/Juvix/Extra/Files.hs (L55-L60)
## Pipeline
As noted above, we only use locking in the test suite. The main app
target pipeline is single threaded and so locking is unnecessary. So the
interpretation of locks is parameterised so that locking can be disabled
e6dca22cfd/src/Juvix/Compiler/Pipeline/Run.hs (L64)
- Closes#2362
This pr implements a new typechecking algorithm. This algorithm can be
activated using the global flag `--new-typechecker`. This flag will only
take effect on the compilation pipeline but not the repl.
The main difference between the new and old algorithm is that the new
one inserts holes during typechecking. Thus, it does not require the
arity checker pass.
The new algorithm does not yet implement default arguments. The plan is
to make the change in the following steps:
1. Merge this pr.
2. Merge #2506.
3. Implement default arguments for the new algorithm.
4. Remove the arity checker and the old algorithm.
---------
Co-authored-by: Łukasz Czajka <62751+lukaszcz@users.noreply.github.com>
This PR adds an initial support for Literate Juvix Markdown files, files
with the extension `.juvix.md`.
Here is a small example of such a file: `Test.juvix.md`.
<pre>
# This is a heading
Lorem ...
```juvix
module Test;
type A := a;
fun : A -> A
| _ := a;
```
Other text
</pre>
This initial support enables users to execute common commands such as
typechecking, compilation, and HTML generation. Additionally, a new
command called `markdown` has been introduced. This command replaces
code blocks marked with the juvix attribute with their respective HTML
output, much like the output we obtain when running `juvix html`. In
this version, comments are ignored in the output, including judoc
blocks.
- We intend to use this new feature in combination with this Python
plugin (https://github.com/anoma/juvix-mkdocs) to enhance our
documentation site.
https://github.com/anoma/juvix/assets/1428088/a0c17f36-3d76-42cc-a571-91f885866874
## Future work
Open as issues once this PR is merged, we can work on the following:
- Support imports of Juvix Markdown modules (update the path resolver to
support imports of Literate Markdown files)
- Support (Judoc) comments in md Juvix blocks
- Support Markdown in Judoc blocks
- Update Text editor support, vscode extension and emacs mode (the
highlighting info is a few characters off in the current state)
- Closes#1839
- Closes#1719
- Closes#2373
Consider this:
```
let
x : _ := 0
in ...
```
When translating the let to internal, we build the dependency graph and
then use that to group definitions in mutually recursive blocks. Since
`x` has no edge, it was not being added to the dependency graph, so it
was not being translated to Internal, thus crashing later during
inference.
* Closes#1646
Implements a basic trait framework. A simple instance search mechanism
is included which fails if there is more than one matching instance at
any step.
Example usage:
```
import Stdlib.Prelude open hiding {Show; mkShow; show};
trait
type Show A :=
mkShow {
show : A → String
};
instance
showStringI : Show String := mkShow (show := id);
instance
showBoolI : Show Bool := mkShow (show := λ{x := if x "true" "false"});
instance
showNatI : Show Nat := mkShow (show := natToString);
showList {A} : {{Show A}} → List A → String
| nil := "nil"
| (h :: t) := Show.show h ++str " :: " ++str showList t;
instance
showListI {A} {{Show A}} : Show (List A) := mkShow (show := showList);
showMaybe {A} {{Show A}} : Maybe A → String
| (just x) := "just (" ++str Show.show x ++str ")"
| nothing := "nothing";
instance
showMaybeI {A} {{Show A}} : Show (Maybe A) := mkShow (show := showMaybe);
main : IO :=
printStringLn (Show.show true) >>
printStringLn (Show.show false) >>
printStringLn (Show.show 3) >>
printStringLn (Show.show [true; false]) >>
printStringLn (Show.show [1; 2; 3]) >>
printStringLn (Show.show [1; 2]) >>
printStringLn (Show.show [true; false]) >>
printStringLn (Show.show [just true; nothing; just false]) >>
printStringLn (Show.show [just [1]; nothing; just [2; 3]]) >>
printStringLn (Show.show "abba") >>
printStringLn (Show.show ["a"; "b"; "c"; "d"]);
```
It is possible to manually provide an instance and to match on implicit
instances:
```
f {A} : {{Show A}} -> A -> String
| {{mkShow s}} x -> s x;
f' {A} : {{Show A}} → A → String
| {{M}} x := Show.show {{M}} x;
```
The trait parameters in instance types are checked to be structurally
decreasing to avoid looping in the instance search. So the following is
rejected:
```
type Box A := box A;
trait
type T A := mkT { pp : A → A };
instance
boxT {A} : {{T (Box A)}} → T (Box A) := mkT (λ{x := x});
```
We check whether each parameter is a strict subterm of some trait
parameter in the target. This ordering is included in the finite
multiset extension of the subterm ordering, hence terminating.
- Closes#2293.
- Closes#2319
I've added an effect for termination. It keeps track of which functions
failed the termination checker, which is run just after translating to
Internal. During typechecking, non-terminating functions are not
normalized. After typechecking, if there is at least one function which
failed the termination checker, an error is reported.
Additionally, we now properly check for termination of functions defined
in a let expression in the repl.
- Closes#2188.
This pr introduces a new syntactical statement for defining aliases:
```
syntax alias newName := oldName;
```
where `oldName` can be any name in the expression namespace. Fixity and
module aliases are not supported at the moment.
- The `newName` does not inherit the fixity of `oldName`. We have agreed
that the goal is to inherit the fixity of `oldName` except if `newName`
has a fixity statement, but this will be done in a separate pr as it
requires #2310.
- Closes#2269
Example:
```
type Sum (A B : Type) :=
| inj1 {
fst : A;
snd : B
}
| inj2 {
fst : A;
snd2 : B
};
sumSwap {A B : Type} : Sum A B -> Sum B A
| inj1@{fst; snd := y} := inj2 y fst
| inj2@{snd2 := y; fst := fst} := inj1 y fst;
```
- Closes#1642.
This pr introduces syntax for convenient record updates.
Example:
```
type Triple (A B C : Type) :=
| mkTriple {
fst : A;
snd : B;
thd : C;
};
main : Triple Nat Nat Nat;
main :=
let
p : Triple Nat Nat Nat := mkTriple 2 2 2;
p' :
Triple Nat Nat Nat :=
p @Triple{
fst := fst + 1;
snd := snd * 3
};
f : Triple Nat Nat Nat -> Triple Nat Nat Nat := (@Triple{fst := fst * 10});
in f p';
```
We write `@InductiveType{..}` to update the contents of a record. The
`@` is used for parsing. The `InductiveType` symbol indicates the type
of the record update. Inside the braces we have a list of `fieldName :=
newValue` items separated by semicolon. The `fieldName` is bound in
`newValue` with the old value of the field. Thus, we can write something
like `p @Triple{fst := fst + 1;}`.
Record updates `X@{..}` are parsed as postfix operators with higher
priority than application, so `f x y @X{q := 1}` is equivalent to `f x
(y @X{q := 1})`.
It is possible the use a record update with no argument by wrapping the
update in parentheses. See `f` in the above example.
- merge #2260 first
Allows constructors to be defined using Haskell-like Adt syntax.
E.g.
```
module Adt;
type Bool :=
| true
| false;
type Pair (A B : Type) :=
| mkPair A B;
type Nat :=
| zero
| suc Nat;
```
---------
Co-authored-by: Paul Cadman <git@paulcadman.dev>
- Closes#2258
# Overview
When we define a type with a single constructor and one ore more fields,
a local module is generated with the same name as the inductive type.
This module contains a projection for every field. Projections can be
used as any other function.
E.g. If we have
```
type Pair (A B : Type) := mkPair {
fst : A;
snd : B;
};
```
Then we generate
```
module Pair;
fst {A B : Type} : Pair A B -> A
| (mkPair a b) := a;
snd : {A B : Type} : Pair A B -> B
| (mkPair a b) := b;
end;
```
- Closes#1641
This pr adds the option to declare constructors with fields. E.g.
```
type Pair (A B : Type) :=
| mkPair {
fst : A;
snd : B
};
```
Which is desugared to
```
type Pair (A B : Type) :=
| mkPair : (fst : A) -> (snd : B) -> Pair A B;
```
making it possible to write ` mkPair (fst := 1; snd := 2)`.
Mutli-constructor types are also allowed to have fields.
- closes#1991
This pr implements named arguments as described in #1991. It does not
yet implement optional arguments, which should be added in a later pr as
they are not required for record syntax.
# Syntax Overview
Named arguments are a convenient mehcanism to provide arguments, where
we give the arguments by name instead of by position. Anything with a
type signature can have named arguments, i.e. functions, types,
constructors and axioms.
For instance, if we have (note that named arguments can also appear on
the rhs of the `:`):
```
fun : {A B : Type} (f : A -> B) : (x : A) -> B := ... ;
```
With the traditional positional application, we would write
```
fun suc zero
```
With named arguments we can write the following:
1. `fun (f := suc) (x := zero)`.
2. We can change the order: `fun (x := zero) (f := suc)`.
3. We can group the arguments: `fun (x := zero; f := suc)`.
4. We can partially apply functions with named arguments: `fun (f :=
suc) zero`.
5. We can provide implicit arguments analogously (with braces): `fun {A
:= Nat; B := Nat} (f := suc; x := zero)`.
6. We can skip implicit arguments: `fun {B := Nat} (f := suc; x :=
zero)`.
What we cannot do:
1. Skip explicit arguments. E.g. `fun (x := zero)`.
2. Mix explicit and implicit arguments in the same group. E.g. `fun (A
:= Nat; f := suc)`
3. Provide explicit and implicit arguments in different order. E.g. `fun
(f := suc; x := zero) {A := Nat}`.
- Closes#2039
- Closes#2055
- Depends on #2053
Changes in this pr:
- Local modules are removed (flattened) in the translation abstract ->
internal.
- In the translation abstract -> internal we group definitions in
mutually recursive blocks. These blocks can contain function definitions
and type definitions. Previously we only handled functions.
- The translation of Internal has been enhanced to handle these mutually
recursive blocks.
- Some improvements the pretty printer for internal (e.g. we now print
builtin tags properly).
- A "hack" that puts the builtin bool definition at the beginning of a
module if present. This was the easiest way to handle the implicit
dependency of the builtin stringToNat with bool in the internal-to-core
translation.
- A moderately sized test defining a simple lambda calculus involving
and an evaluator for it. This example showcases mutually recursive types
in juvix.
---------
Co-authored-by: Jonathan Cubides <jonathan.cubides@uib.no>
This pr fixes the following:
This example causes the compiler to crash with "implicitness mismatch".
```
f : id Bool -> Bool;
f _ := false;
```
The reason is that `id` expects an implicit argument but finds `Bool`,
which is explicit. The arity checker was not inserting any hole because
it was ignoring the whole type. Moreover the aritychecker was never
checking `->` types as we never expected to
have to insert holes in `->` types (since the only fragment of defined
functions that we accept in types are those which do not have implicit
arguments).
We now properly arity check all types and process the function type `->`
correctly.
# Description
This PR fixes#1943. The primary issue stemmed from an incorrect
insertion in the set designated for storing negative type parameters.
Additionally, there was a call site intended to use the variable `typ`,
but I mistakenly used `ty` (which was for something else). To prevent
such silly typos better to adopt more meaningful names.
Previously we were:
* discarding the types table
* discarding the name ids state
after processing an expression in the REPL.
For example evaluating:
```
let even : _; odd : _; odd zero := false; odd (suc n) := not (even n); even zero := true; even (suc n) := not (odd n) in even 10
```
would loop in the REPL.
We noticed that the `n` in `suc n` was being given type `Type` instead
of `Nat`. This was because the name id given to n was incorrect, the
REPL started using name ids from 0 again.
We fixed this issue by storing information, including the types table
and name ids state in the Artifacts data structure that is returned when
we run the pipeline for the first time. This information is then used
when we call functions to compile / type check REPL expressions.
---------
Co-authored-by: Paul Cadman <git@paulcadman.dev>
* Depends on PR #1832
* Closes#1799
* Removes Backend.C.Translation.FromInternal
* Removes `foreign` and `compile` blocks
* Removes unused test files
* Removes the old C runtime
* Removes other dead code
- Closes#1879
The issue was possibly caused by the use of `readerState`:
```
readerState :: forall a r x. (Member (State a) r) => Sem (Reader a ': r) x -> Sem r x
readerState m = get >>= (`runReader` m)
```
I originally thought it would be a good idea to "freeze" some `State`
effect into a `Reader` effect in the following situation:
- Some function `s` needs to update the state.
- Some function `f` only reads the state.
- Then you would have `g .. = ... readerState @MyState f`
- This way, it would be reflected in the type that `g` cannot update the
state. However, for some reason I have not been able to clearly
identify, this was not working as expected.
This PR redefines the `html` command unifying our previous subcommands
for the HTML backend. You should use the command in the following way to
obtain the same results as before:
- `juvix html src.juvix` -> `juvix html src.juvix --only-source`
- `juvix dev doc src.juvix` -> `juvix html src.juvix`
- Other fixes here include the flag `--non-recursive`, which replaces
the previous behavior in that we now generate all the HTML recursively
by default.
- The flag `--no-print-metadata` is now called `--no-footer`
- Also, another change introduced by this PR is asset handling; for
example, with our canonical Juvix program,
the new output is organized as follows.
```
juvix html HelloWorld.juvix --only-source && tree html/
Copying assets files to test/html/assets
Writing HelloWorld.html
html/
├── assets
│ ├── css
│ │ ├── linuwial.css
│ │ ├── source-ayu-light.css
│ │ └── source-nord.css
│ ├── images
│ │ ├── tara-magicien.png
│ │ ├── tara-seating.svg
│ │ ├── tara-smiling.png
│ │ ├── tara-smiling.svg
│ │ ├── tara-teaching.png
│ │ └── tara-teaching.svg
│ └── js
│ ├── highlight.js
│ └── tex-chtml.js
└── HelloWorld.html
├── Stdlib.Data.Bool.html
├── Stdlib.Data.List.html
├── Stdlib.Data.Maybe.html
├── Stdlib.Data.Nat.html
├── Stdlib.Data.Ord.html
├── Stdlib.Data.Product.html
├── Stdlib.Data.String.html
├── Stdlib.Function.html
├── Stdlib.Prelude.html
└── Stdlib.System.IO.html
```
In addition, for the vscode-plugin, this PR adds two flags,
`--prefix-assets` and `--prefix-url`, for which one provides input to
help vscode find resource locations and Juvix files.
PS. Make sure to run `make clean` the first time you run `make install`
for the first time.
