3d5f853b03
<!-- if this PR closes one or more issues, you can automatically link the PR with them by using one of the [*linking keywords*](https://docs.github.com/en/issues/tracking-your-work-with-issues/linking-a-pull-request-to-an-issue#linking-a-pull-request-to-an-issue-using-a-keyword), e.g. - this PR should close #xxxx - fixes #xxxx you can also mention related issues, PRs or discussions! --> # Description <!-- Thank you for improving Nushell. Please, check our [contributing guide](../CONTRIBUTING.md) and talk to the core team before making major changes. Description of your pull request goes here. **Provide examples and/or screenshots** if your changes affect the user experience. --> The [nushell/demo](https://github.com/nushell/demo) project successfully demonstrated running Nushell in the browser using WASM. However, the current version of Nushell cannot be easily built for the `wasm32-unknown-unknown` target, the default for `wasm-bindgen`. This PR introduces initial support for the `wasm32-unknown-unknown` target by disabling OS-dependent features such as filesystem access, IO, and platform/system-specific functionality. This separation is achieved using a new `os` feature in the following crates: - `nu-cmd-lang` - `nu-command` - `nu-engine` - `nu-protocol` The `os` feature includes all functionality that interacts with an operating system. It is enabled by default, but can be disabled using `--no-default-features`. All crates that depend on these core crates now use `--no-default-features` to allow compilation for WASM. To demonstrate compatibility, the following script builds all crates expected to work with WASM. Direct user interaction, running external commands, working with plugins, and features requiring `openssl` are out of scope for now due to their complexity or reliance on C libraries, which are difficult to compile and link in a WASM environment. ```nushell [ # compatible crates "nu-cmd-base", "nu-cmd-extra", "nu-cmd-lang", "nu-color-config", "nu-command", "nu-derive-value", "nu-engine", "nu-glob", "nu-json", "nu-parser", "nu-path", "nu-pretty-hex", "nu-protocol", "nu-std", "nu-system", "nu-table", "nu-term-grid", "nu-utils", "nuon" ] | each {cargo build -p $in --target wasm32-unknown-unknown --no-default-features} ``` ## Caveats This PR has a few caveats: 1. **`miette` and `terminal-size` Dependency Issue** `miette` depends on `terminal-size`, which uses `rustix` when the target is not Windows. However, `rustix` requires `std::os::unix`, which is unavailable in WASM. To address this, I opened a [PR](https://github.com/eminence/terminal-size/pull/68) for `terminal-size` to conditionally compile `rustix` only when the target is Unix. For now, the `Cargo.toml` includes patches to: - Use my forked version of `terminal-size`. - ~~Use an unreleased version of `miette` that depends on `terminal-size@0.4`.~~ These patches are temporary and can be removed once the upstream changes are merged and released. 2. **Test Output Adjustments** Due to the slight bump in the `miette` version, one test required adjustments to accommodate minor formatting changes in the error output, such as shifted newlines. # User-Facing Changes <!-- List of all changes that impact the user experience here. This helps us keep track of breaking changes. --> This shouldn't break anything but allows using some crates for targeting `wasm32-unknown-unknown` to revive the demo page eventually. # Tests + Formatting <!-- Don't forget to add tests that cover your changes. Make sure you've run and fixed any issues with these commands: - `cargo fmt --all -- --check` to check standard code formatting (`cargo fmt --all` applies these changes) - `cargo clippy --workspace -- -D warnings -D clippy::unwrap_used` to check that you're using the standard code style - `cargo test --workspace` to check that all tests pass (on Windows make sure to [enable developer mode](https://learn.microsoft.com/en-us/windows/apps/get-started/developer-mode-features-and-debugging)) - `cargo run -- -c "use toolkit.nu; toolkit test stdlib"` to run the tests for the standard library > **Note** > from `nushell` you can also use the `toolkit` as follows > ```bash > use toolkit.nu # or use an `env_change` hook to activate it automatically > toolkit check pr > ``` --> - 🟢 `toolkit fmt` - 🟢 `toolkit clippy` - 🟢 `toolkit test` - 🟢 `toolkit test stdlib` I did not add any extra tests, I just checked that compiling works, also when using the host target but unselecting the `os` feature. # After Submitting <!-- If your PR had any user-facing changes, update [the documentation](https://github.com/nushell/nushell.github.io) after the PR is merged, if necessary. This will help us keep the docs up to date. --> ~~Breaking the wasm support can be easily done by adding some `use`s or by adding a new dependency, we should definitely add some CI that also at least builds against wasm to make sure that building for it keep working.~~ I added a job to build wasm. --------- Co-authored-by: Ian Manske <ian.manske@pm.me> |
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nu-parser, the Nushell parser
Nushell's parser is a type-directed parser, meaning that the parser will use type information available during parse time to configure the parser. This allows it to handle a broader range of techniques to handle the arguments of a command.
Nushell's base language is whitespace-separated tokens with the command (Nushell's term for a function) name in the head position:
head1 arg1 arg2 | head2
Lexing
The first job of the parser is to a lexical analysis to find where the tokens start and end in the input. This turns the above into:
<item: "head1">, <item: "arg1">, <item: "arg2">, <pipe>, <item: "head2">
At this point, the parser has little to no understanding of the shape of the command or how to parse its arguments.
Lite parsing
As Nushell is a language of pipelines, pipes form a key role in both separating commands from each other as well as denoting the flow of information between commands. The lite parse phase, as the name suggests, helps to group the lexed tokens into units.
The above tokens are converted the following during the lite parse phase:
Pipeline:
Command #1:
<item: "head1">, <item: "arg1">, <item: "arg2">
Command #2:
<item: "head2">
Parsing
The real magic begins to happen when the parse moves on to the parsing stage. At this point, it traverses the lite parse tree and for each command makes a decision:
- If the command looks like an internal/external command literal: e.g.
fooor/usr/bin/ls, it parses it as an internal or external command - Otherwise, it parses the command as part of a mathematical expression
Types/shapes
Each command has a shape assigned to each of the arguments it reads in. These shapes help define how the parser will handle the parse.
For example, if the command is written as:
where $x > 10
When the parsing happens, the parser will look up the where command and find its Signature. The Signature states what flags are allowed and what positional arguments are allowed (both required and optional). Each argument comes with a Shape that defines how to parse values to get that position.
In the above example, if the Signature of where said that it took three String values, the result would be:
CallInfo:
Name: `where`
Args:
Expression($x), a String
Expression(>), a String
Expression(10), a String
Or, the Signature could state that it takes in three positional arguments: a Variable, an Operator, and a Number, which would give:
CallInfo:
Name: `where`
Args:
Expression($x), a Variable
Expression(>), an Operator
Expression(10), a Number
Note that in this case, each would be checked at compile time to confirm that the expression has the shape requested. For example, "foo" would fail to parse as a Number.
Finally, some Shapes can consume more than one token. In the above, if the where command stated it took in a single required argument, and that the Shape of this argument was a MathExpression, then the parser would treat the remaining tokens as part of the math expression.
CallInfo:
Name: `where`
Args:
MathExpression:
Op: >
LHS: Expression($x)
RHS: Expression(10)
When the command runs, it will now be able to evaluate the whole math expression as a single step rather than doing any additional parsing to understand the relationship between the parameters.
Making space
As some Shapes can consume multiple tokens, it's important that the parser allow for multiple Shapes to coexist as peacefully as possible.
The simplest way it does this is to ensure there is at least one token for each required parameter. If the Signature of the command says that it takes a MathExpression and a Number as two required arguments, then the parser will stop the math parser one token short. This allows the second Shape to consume the final token.
Another way that the parser makes space is to look for Keyword shapes in the Signature. A Keyword is a word that's special to this command. For example in the if command, else is a keyword. When it is found in the arguments, the parser will use it as a signpost for where to make space for each Shape. The tokens leading up to the else will then feed into the parts of the Signature before the else, and the tokens following are consumed by the else and the Shapes that follow.