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Arcs

Note: Arcs is transitioning to Cloud Build and the live.arcs.dev hosted pages referenced below may not be operational currently.

TODO(bgogul): Edit above when we've restored/reconfirmed live.arcs.dev publishing and operation.

A hosted version of Arcs is available at https://live.arcs.dev.

TypeDoc generated documentation is available for Arcs Runtime.

Install

Installing the easy way

  1. Run the setup script (MacOS, Linux)

    $ ./tools/setup
    
  2. The script may have issues with the NVM installation. If so, follow the prompts to manually install NVM and they run the setup script again.

  3. For MacOS, You will need to have Xcode installed. The script will fail at this point, and prompt you to install Xcode.

  4. You'll need to run either $ source ~/.profile or $ source ~/.bashrc to update all the environment variables.

  5. Run $ ./tools/sigh test to ensure everything is properly installed.

  6. If you'll be working with Kotlin, you'll need to install bazel to build your projects.

  7. That's it! (You can skip the next section.)

Installing from scratch

  1. Install nvm.

    As per the installation instructions, download and run the installation script directly in your terminal (yes, you read that correctly):

    $ curl -o- https://raw.githubusercontent.com/creationix/nvm/v0.34.0/install.sh | bash
    

    If you're using zsh you may need to source ~/.nvm/nvm.sh after this.

  2. Install node.

    $ nvm install 10
    
  3. If you need to update npm to a later version (our build checks for the minimum required version):

    $ npm install -g npm   # can use [email protected] to install a specific version
    
  4. Optional: install Bazel (required for building/running WebAssembly particles, optional if you only want to develop using JavaScript). See the ./tools/setup script for the correct version of Bazel to install. See the C++ wasm instructions for more info.

Installing within the Arcs project:

$ ./tools/npm-install-all
$ ./tools/sigh

./tools/npm-install-all is required on a fresh checkout. After that it only needs to be re-run infrequently as new dependencies are included, and usually a build failure will be the signal for that.

Git Setup

You may also find it helpful to have run our presubmit checks locally before you push your commits. To do this, you can setup git to run these checks using:

$ git config core.hooksPath tools/hooks

Windows Installation Notes

  • Git for Windows is one of many Git options.
  • Consider using nvm-windows to allow more easily switching between Node versions.
  • As part of npm install you'll need to build fibers which uses node-gyp which in turn requires windows-build-tools. Follow the node-gyp Windows build instructions. If option 1 hangs or otherwise hits issues, you can try option 2. Note the Microsoft Build Tools 2015 can be downloaded separately from Visual Studio (and the links in the node-gyp documentation are stale), but you'll still need to do the npm config set msvs_version 2015 bit, and similar for Python if you install that manually per node-gyp option 2 instructions.
  • If you encounter errors due to spaces in your user name directory with either Git Bash or nvm, you may benefit from solutions described here and here.

Mac Installation Notes

  • When installing, if you run into SSL Cert verification errors, consider certifying Python 3.6 on Mac: /Applications/Python\ 3.6/Install\ Certificates.command (source)

Starting Arcs

After the full build (./tools/npm-install-all && tools/sigh) run:

$ tools/sigh devServer

Then open http://localhost:8786/shells/web-shell/ in a web browser (or, on MacOS, use open 'http://localhost:8786/shells/web-shell/).

Subprojects

Subcomponents have more detailed descriptions. Particularly the extensions also have individual installation steps.

Chrome Extension

See extension.

Android Developer Tools

See DevToolsNG

Chrome Developer Tools Extension

See devtools.

IDE Setup

See IDE Setup.

Testing

The simplest way to run tests is to let the targets do all the work. These commands will install all packages, run a build, start a background server, run all the tests, and kill the background server:

$ tools/sigh test && tools/sigh testShells && tools/sigh testWdioShells
$ tools/local-presubmit

There are additional targets provided to run subsets of those commands.

  • tools/sigh devServer: spins up a server (and blocks), serving on port 8786.
  • ./tools/sigh: run a subset of tests and build packed artifacts.

To run a specific Selenium test using Mocha's 'grep' capability: ./tools/sigh test --grep 'regex'. In addition, for unit tests you can run only a single test case by using it.only() instead of it(), or a single suite using describe.only() instead of describe().

WebAssembly tests

Test using Bazel (run from your repo root):

First you will need to make sure you have set the path attribute of android_sdk_repository or the ANDROID_HOME environment variable. To do this, you can run the following commands:

export ANDROID_HOME=$Path_to_SDK

If you don't know the path to the Android SDK, you can find it using Android Studio by going to the SDK Manager tool.

export PATH=$PATH:$ANDROID_HOME/platform-tools

To update the path in your terminal, either restart terminal or run source ~/.bash_profile on Mac or source ~/.bashrc on Linux. To verify ANDROID_HOME has been set properly, you can run echo $ANDROID_HOME.

Once your Android environment has been setup, you can run the tests using bazel:

./tools/bazelisk test javatests/...

Debugging tests

If you see errors like

ERROR: connect ECONNREFUSED 127.0.0.1:9515
chrome
    at new RuntimeError (...\node_modules\webdriverio\build\lib\utils\ErrorHandler.js:144:12)
    at Request._callback (...\node_modules\webdriverio\build\lib\utils\RequestHandler.js:327:43)

It may indicate that chromedriver hasn't been installed completely. Run the install script:

node node_modules\chromedriver\install.js

Debugging unit tests in Chrome

You can attach the Chrome debugger to debug your unit tests using the --inspect flag:

./tools/sigh test --inspect

It will wait for you to attach your debugger before running the tests. Open [chrome://inspect] and look for the "inspect" button under the "Remote Target" heading. You can use Ctrl-P to open files (you may need to add the build folder to your workspace first). Hit "resume" to start running the unit tests.

Debugging WebDriver Failures

WebDriver failures are often easy to cause due to seemingly unrelated changes, and difficult to diagnose.

There are 2 main avenues to debug them in this system. The first is to have the browser run in a graphical manner (as opposed to the default headless configuration). The second is to actually debug the running WebDriver instance.

There are some debugging hints (code and configuration you can uncomment to make debugging easier) in test/specs/starter-test.js and test/wdio.conf.js marked with the phrase debug hint.

To activate a sane set of helpful debugging flags, there's a wdio-debug command line argument that you can pass in. This will run Chrome in a non-headless fashion, and will increase timeouts.

Through npm: npm run test-wdio-shells --wdio-debug=true (or npm test --wdio-debug=true). Directly through wdio: node_modules/.bin/wdio --wdio-debug=true shell/test/wdio.conf.js.

Webdriver takes screenshots of failures, which are saved to the ./shells/test/errorShots/ directory.

Graphical (non-headless)

It may be easiest to see the problem in a browser window to diagnose it. Edit wdio.conf.js in the branch with failures, comment out the '--headless' option and increase the mocha timeout. In combination, these two changes will allow you to see what's happening on the screen, and will give you enough time to debug the situation.

arcs/shells> vi test/wdio.conf.js
arcs/shells> git diff test/wdio.conf.js
diff --git a/test/wdio.conf.js b/test/wdio.conf.js
index 0e36452..8ecf3d6 100644
--- a/test/wdio.conf.js
+++ b/test/wdio.conf.js
@@ -50,7 +50,7 @@ exports.config = {
       chromeOptions: {
         args: [
           // arcs note: comment this out to see the system running
-          '--headless'
+          // '--headless'
         ]
       }
     }
@@ -139,7 +139,7 @@ exports.config = {
   mochaOpts: {
     ui: 'bdd',
     // arcs note: increase this timeout for debugging
-    timeout: 20003
+    timeout: 2000003
   }
   //
   // =====

Then, in your test, you can add a breakpoint (via browser.debug();) to pause execution so you can debug in the browser. It may be worthwhile to add several browser.debug() invocations through your flow to trace execution (.exit will exit the debugger and continue execution of the test).

At that point you can open up DevTools in the browser to debug the current state, or inspect it visually.

There are also some commands available natively at that point, including .help and the browser variable (including methods such as browser.execute()).

Attaching a Debugger

To attach a debugger, uncomment the execArgv --inspect configuration option. It's likely that you'll still want to have increased the mochaTimeout and to be running graphically, so those are in the example as well:

arcs/shells> git diff test/wdio.conf.js
diff --git a/test/wdio.conf.js b/test/wdio.conf.js
index 0e36452..4240c0a 100644
--- a/test/wdio.conf.js
+++ b/test/wdio.conf.js
@@ -50,11 +50,12 @@ exports.config = {
       chromeOptions: {
         args: [
           // arcs note: comment this out to see the system running
-          '--headless'
+          // '--headless'
         ]
       }
     }
   ],
+  execArgv: ['--inspect'],
   //
   // ===================
   // Test Configurations
@@ -139,7 +140,7 @@ exports.config = {
   mochaOpts: {
     ui: 'bdd',
     // arcs note: increase this timeout for debugging
-    timeout: 20003
+    timeout: 2000003
   }
   //
   // =====

When starting, you should see log item like debugger listening on ws://127.0.0.1:9229/.. as normally appears for node debugging. Passing the --inspect argument will also enable the V8 Inspector Integration which may be easier to use (to activate this, look for a node icon in a Chrome DevTools process).

Adding debugger; statements may be the easiest way to activate the debugger. Using browser.debug(); statements to pause execution to give you time to attach a debugger may be helpful as well.