gecko-dev/third_party/rust/jsparagus

jsparagus - A JavaScript parser written in Rust

jsparagus is intended to replace the JavaScript parser in Firefox.

Current status:

• jsparagus is not on crates.io yet. The AST design is not stable enough. We do have a build of the JS shell that includes jsparagus as an option (falling back on C++ for features jsparagus doesn't support). See mozilla-spidermonkey/rust-frontend.

• It can parse a lot of JS scripts, and will eventually be able to parse everything. See the current limitations below, or our GitHub issues.

• Our immediate goal is to support parsing everything in Mozilla's JS test suite and the features in test262 that Firefox already supports.

Join us on Discord: https://discord.gg/tUFFk9Y

Building jsparagus

To build the parser by itself:

make init
make all

The build takes about 3 minutes to run on my laptop.

When it's done, you can:

• Run make check to make sure things are working.

• cd crates/driver && cargo run -- -D to try out the JS parser and bytecode emitter.

Building and running SpiderMonkey with jsparagus

• To build SpiderMonkey with jsparagus, configure with --enable-smoosh.

  This builds with a specific known-good revision of jsparagus.

• Building SpiderMonkey with your own local jsparagus repo, for development, takes more work; see the jsparagus + SpiderMonkey wiki page for details.

NOTE: Even after building with jsparagus, you must run the shell with --smoosh to enable jsparagus at run time.

Benchmarking

Fine-grain Benchmarks

Fine-grain benchmarks are used to detect regression by focusing on each part of the parser at one time, exercising only this one part. The benchmarks are not meant to represent any real code sample, but to focus on executing specific functions of the parser.

To run this parser, you should execute the following command at the root of the repository:

cd crates/parser
cargo bench

Real-world JavaScript

Real world benchmarks are used to track the overall evolution of performance over time. The benchmarks are meant to represent realistic production use cases.

To benchmark the AST generation, we use SpiderMonkey integration to execute the parser and compare it against SpiderMonkey's default parser. Therefore, to run this benchmark, we have to first compile SpiderMonkey, then execute SpiderMonkey shell on the benchmark. (The following instructions assume that ~ is the directory where all projects are checked out)

• Generate Parse Tables:

  cd ~/jsparagus/
  make init
  make all
  

• Compile an optimized version of SpiderMonkey's JavaScript shell:

  cd ~/mozilla/js/src/
  # set the jsparagus' path to the abosulte path to ~/jsparagus.
  $EDITOR frontend/smoosh/Cargo.toml
  ../../mach vendor rust
  # Create a build directory
  mkdir obj.opt
  cd obj.opt
  # Build SpiderMonkey
  ../configure --enable-nspr-build --enable-smoosh --enable-debug-symbols=-ggdb3 --disable-debug --enable-optimize --enable-release --disable-tests
  make
  

• Execute the real-js-samples benchmark:

  cd ~/real-js-samples/
  ~/mozilla/js/src/obj.opt/dist/bin/js ./20190416.js
  

This should return the overall time taken to parse all the Script once, in the cases where there is no error. The goal is to minimize the number of nano-seconds per bytes.

Limitations

It's all limitations, but I'll try to list the ones that are relevant to parsing JS.

• Features that are not implemented in the parser yet include let, import and export, async functions, yield expressions, the use of await and yield as identifiers, template strings, BigInt, Unicode escape sequences that evaluate to surrogate code points, legacy octal integer literals, legacy octal escape sequences, some RegExp flags, strict mode code, __proto__ in object literals, some features of destructuring assignment.

  Many more features are not yet supported in the bytecode emitter.

• Error messages are poor.

We're currently working on parser performance and completeness, as well as the bytecode emitter and further integration with SpiderMonkey.