Skip to content

Latest commit

 

History

History
90 lines (57 loc) · 5.01 KB

CONTRIBUTING.md

File metadata and controls

90 lines (57 loc) · 5.01 KB

Contributer's Guide

We welcome contributions from the community and have gathered guidelines here to help you get started.

Discussion

While not absolutely required, it is encouraged that you first open an issue for any bug or feature request. This allows discussion on the proper course of action to take before coding begins.

Building

yarn install
yarn build

Changing

Most of the information you need to contribute code changes can be found here. In short: fork, make your changes, and submit a pull request.

Testing

This project makes use of 2 integration test packs to make sure we don't break anything. That's right, count them, 2! There is a comparison test pack which compares compilation outputs and is long established. There is also an execution test pack which executes the compiled JavaScript. This test pack is young and contains fewer tests; but it shows promise.

You can run all the tests (in both test packs) with yarn test.

To run comparison tests alone use yarn run comparison-tests. To run execution tests alone use yarn run execution-tests.

Not all bugs/features necessarily fit into either framework and that's OK. However, most do and therefore you should make every effort to create at least one test which demonstrates the issue or exercises the feature. Use your judgement to decide whether you think a comparison test or an execution test is most appropriate.

To read about the comparison test pack take a look here To read about the execution test pack take a look here

Debugging

Debugging tests

If you’re using VS Code, set breakpoints anywhere in src. Open any file inside the comparison test or execution test you want to debug, then, in the debug pane, select “Run open comparison test” or “Run open execution test.”

If you’re not using VS Code, simply adding --debug to either a yarn run comparison-tests or yarn run execution-tests will pause before each test (this is best combined with --single-test), allowing you to attach to the node process on port 5858 with your favorite debugger.

Debugging ts-loader installed from npm in your own Webpack project

node --inspect-brk node_modules/webpack/bin/webpack.js --config webpack.dev.js # Obviously configure this depending upon your project setup

Then put a breakpoint in node_modules/ts-loader/dist/index.js, and debug in VS Code with "Attach to Node Process". The dist is JS compiled from TS, but it’s still pretty readable.

Debugging a local, cloned copy of ts-loader in your own Webpack project

Just like the steps above, except substituting a local copy of ts-loader for the one in node_modules:

  1. In ts-loader, run yarn build
  2. Still in ts-loader, run npm link
  3. In your own Webpack project directory, run npm link ts-loader. There’s now a chain of symlinks from node_modules/ts-loader to your cloned copy built from source.
  4. Repeat the steps above in “Debugging ts-loader installed from npm...” except now, you can take advantage of source maps, so you can set breakpoints in ts-loader/src instead of ts-loader/dist.
  5. If you want to try making changes to ts-loader, make changes and then repeat steps 1 and 4—no need to re-run the npm link steps.
  6. Run npm unlink ts-loader in your own project directory to remove the symlink when you’re done.

Profiling Performance

To investigate slowdowns in build times, it's often helpful to profile webpack & ts-loader.

  1. Start webpack with a debugger attached (see debugging steps above)
  2. Identify the reproducible user scenario that is experiencing slowdowns
  3. In Chrome, open chrome://inspect and inspect the running webpack instance Note: Utilizing Chromium instead of Chrome sometimes yeilds better results. If any of the following steps fail or cause a crash, try switching from Chrome to Chromium.
  4. Switch to the Profiling Tab
  5. Start Recording
  6. Kick off the scenario that's known to be slow
  7. Stop Recording once the scenario is complete

At this point you should see a list of function calls. There are three distinct views that are useful & you can swap between them to get slightly different views of the problem.

Chart View

The chart view will provide a flame chart of all profiled function calls over time. This can be useful to visualize expensive functions and blocks of high CPU, but can be difficult to read when there are deep call stacks (or flames).

Heavy View

Heavy view shows the time that functions took to execute themselves (self time) & the functions they call (total time). When expanding individual calls, you will be able to see the functions that called this function & effectively walk up the recorded stack traces.

Tree View

Tree view shows the same information as heavy view, but visualizes calls in a top-town manner. This can be useful to track down a single call pattern that is expensive but is less useful when there are deep stack traces.