leptosfmt

crates.io build security discord

A formatter for the leptos view! macro

All notable changes are documented in: CHANGELOG.md

Install

cargo install leptosfmt

or for trying out unreleased features:

cargo install --git https://github.com/bram209/leptosfmt.git

Usage

``` Usage: leptosfmt [OPTIONS]

Arguments: A file, directory or glob

Options: -m, --max-width
-t, --tab-spaces
-c, --config_file
-h, --help Print help -V, --version Print version ```

Configuration

You can configure all settings through a leptosfmt.toml file.

```toml maxwidth = 100 tabspaces = 4 attrvaluebrace_style = "WhenRequired" # "Always", "AlwaysUnlessLit", "WhenRequired" or "Preserve"

```

To see what each setting does, the see configuration docs

Examples

Single file

Format a specific file by name

leptosfmt ./examples/counter/src/lib.rs

Current directory

Format all .rs files within the current directory

leptosfmt .

Directory

Format all .rs files within the examples directory

leptosfmt ./examples

Glob

Format all .rs files ending with _test.rs within the examples directory

leptosfmt ./examples/**/*_test.rs

A note on non-doc comments

Currently this formatter does not support non-doc comments in code blocks. It uses a fork of prettyplease for formatting rust code, and prettyplease does not support this. I would like to not diverge this fork too much (so I can easily keep in sync with upstream), therefore I didn't add non-doc comment support in my prettyplease fork for now. This means that you can use non-doc comments throughout your view macro, as long as they don't reside within code blocks.

Pretty-printer algorithm

The pretty-printer is based on Philip Karlton’s Mesa pretty-printer, as described in the appendix to Derek C. Oppen, “Pretty Printing” (1979), Stanford Computer Science Department STAN-CS-79-770, http://i.stanford.edu/pub/cstr/reports/cs/tr/79/770/CS-TR-79-770.pdf. This algorithm's implementation is taken from prettyplease which is adapted from rustc_ast_pretty.

The algorithm takes from an input stream of length n and an output device with margin width m, the algorithm requires time O(n) and space O(m). The algorithm is described in terms of two parallel processes; the first scans the input stream to determine the space required to print logical blocks of tokens; the second uses this information to decide where to break lines of text; the two processes communicate by means of a buffer of size o(m). The algorithm does not wait for the entire stream to be input, but begins printing as soon as it has received a linefull of input.