An open-source project from Square

Squash is a collection of tools that help engineers find and kill bugs in their code by automatically collecting, collating and analyzing run time exceptions. Squash consists of the following components:

• Client libraries: Client libraries for different systems (Ruby, Ruby on Rails, Cocoa with Objective-C, etc.) catch and record errors when they occur, then send them to the API endpoint. Client libraries can be found under the SquareSquash organization.
• Front-end: This website displays Bug information and helps the engineer find the root cause for a Bug, and fix it. It also lets engineers manage, assign, and comment on Bugs, as well as view statistics about the Bug.
• API endpoints: These routes (part of the front-end app) receive exception notifications from the client libraries and process them.

This project is the front-end and the API.

Pull requests are more than welcome; please check out CONTRIBUTING.md for details.

To get started, run the bin/setup file. This script will ask you a series of questions and generate a preliminary configuration for your site install. When the script is completed, you can run git status to see what files it changed, and refine your configuration from there.

Once the script is complete, Squash should run for most typical development environments. Simply run rails s and visit the site in your Web browser. You should be able to start using it immediately. You can also verify correctness by running rspec spec.

Configuring and deploying the production instance is entirely up to you and your particular production environment.

Additional configuration options can be found in the following locations:

• config/application.rb
• config/environments/*.rb
• config/environments/*/*.yml

If you don't see what you're looking for in any of those files, you'll probably have to change the code to make it work. Don't be afraid -- the code is thoroughly documented and should (hopefully) be very accessible.

Squash requires the following:

• Ruby 1.9.2 or newer (JRuby with --1.9 is supported)
• Multithreading support (see the next section)
• PostgreSQL 9.1 or newer
• The Bundler gem
• Git 1.7 or newer

Why do you specifically require PostgreSQL? Squash uses a lot of PostgreSQL-specific features to make efficient use of the database and maintain referential integrity, such as:

• foreign key constraints,
• triggered cached counters,
• check constraints, and
• semantic indexes for text-based search.

If PostgreSQL is out of the question, some of these features can be ported to other RDBMSes; simply edit the InitialSchema migration and update the SQL as necessary. If portability is required, a lot of these features can be reimplemented in the Rails layer (e.g., cached counters), at the risk of degraded referential integrity. (If you are reimplementing the cached counters in Ruby, be sure to modify the config/initializers/active_record.rb file as appropriate.)

If you do successfully port Squash to another RDBMS, let me know. I'd be happy to take your changes.

Why do you bundle an edge version of Rails? The 3-2-stable branch of Ruby on Rails includes some changes to Active Record that are required by Squash's multithreaded concurrency model (see next question). In particular, that version of Active Record includes crucial changes to the connection pool and connection reopening logic. If you set the background_runner option in the concurrency.yml file to something other than Multithread, the Gemfile will automatically drop Rails back down to the latest release version.

Why don't you use my favorite backgrounding library? Squash was originally built for Square, which runs all its services on JRuby. Using threads is very efficient in JRuby, and avoids the overhead of having to deploy both a website and workers.

If you are running Squash in a non-thread-safe (or multithreading-unfriendly) environment, you can use Sidekiq or Resque instead. If you want to use some other backgrounding library, you can easily write your own adapter. All threaded code is invoked using {BackgroundRunner.run}, which then uses the settings in the concurrency.yml Configoro file to invoke the correct module under lib/background_runner. The default is to use {BackgroundRunner::Multithread}, which uses the {Multithread} module to execute the task in its own thread. You can edit the YAML file and switch the background runner to Resque, or implement your own BackgroundRunner module. See the {BackgroundRunner} documentation for more details.

If you do this successfully and wish to save future Squash users the effort, feel free to turn your changes into a pull request.

Why aren't you using RedCarpet? As mentioned above, Squash was originally built to run under JRuby. RedCarpet has compiled C extensions; Kramdown is pure Ruby.

Why do you require a recent version of Git? Squash uses the git clone --mirror command to create local mirrors of client projects' Git repositories.

Why don't you have integration tests or acceptance tests? To be 100% honest, lack of familiarity on these things in Ruby/Rails. Happy for any help people want to extend towards this goal.

Why are you using Erector? I like Erector.

Comprehensive documentation is written in YARD- and Markdown-formatted comments throughout the source. To view this documentation as an HTML site, run rake yard.

CoffeeScript libraries are documented using the YARD format as well, but YARD does not as yet recognize them as documentable files. A .codoopts file is included in case you wish to use Codo to generate the CoffeeScript docs, but as of now Codo does not recognize the ERb files, and does not use the full set of Markdown syntax features used in the documentation.

This is a pretty typical Rails website, save for the views, which are written using Erector. The views forgo the traditional Rails concepts of partials and templates in favor of analogous OOP concepts more familiar to software developers: methods and inheritance. All views inherit from an abstract Erector widget which provides layout; and all views have their content split into multiple private methods.

In addition to the usual helpers (in app/helpers), there are view mixins under app/views/additions that simplify view coding.

Embedded code snippets are all rendered using the {CommitsController#context} action. This action loads the appropriate file and revision from the Git repository and returns a snippet plus the name of the SyntaxHighlighter brush to use. The brush is determined from the file name/extension; the mapping can be found in data/brushes.yml.

This view behavior is provided from a JavaScript library file in lib/assets/javascripts. There are many similar helper classes in there; they are documented but the documentation is not recognized by YARD and so is not included in this documentation set.

JavaScript files are organized into four possible locations:

• Third-party JavaScript libraries are in vendor/assets/javascripts and loaded in the application.js manifest.
• JavaScript modules or helpers that are not specific to a particular page or site area are in lib/assets/javascripts and also loaded in application.js.
• JavaScript modules or helpers specific to a particular area of the site are in app/assets/javascripts and also loaded in application.js.
• Small JavaScript snippets, glue code, or other code intended to add dynamic behavior to a specific page is in a .js file named the same as, and placed alongside, the .html.rb view file. For example, if app/views/projects/new.html.rb needed a bit of JS glue code, it would be placed in app/views/projects/new.js. This code is placed in a <SCRIPT> tag at the end of the view by the {Views::Layouts::Application#inline_javascript} method.

CSS files are similarly organized:

• Third-party CSS files are in vendor/assets/stylesheets and loaded in the application.css manifest.
• CSS styles or helpers global to the entire website are in lib/assets/stylesheets and also loaded in application.css.
• CSS styles specific to a single page or a related group of pages are placed in app/assets/stylesheets and also loaded in application.css. Each <BODY> tag is given a class name equal to the controller name, and an ID equal to the controller and action name separated with a dash. For instance, the projects/new action's body would be <body class=projects id=projects-new>.

For information about requests and responses, see {ApplicationController}.

Models make extensive use of advanced PostgreSQL features for efficiency and convenience. Cached counters are updated using triggers and rules, foreign key constraints and hooks are enforced at the database level, and validations are backed up by corresponding CHECK triggers. This helps ensure referential and data integrity even in situations where Rails fails, or outside of the Rails stack. See the various migrations to learn more about the triggers, rules, and constraints being used.

Observers are used for more high-level triggers, such as creating {Event Events} at the appropriate times, or sending emails. See the classes in app/models/observers for more.

Models also use the HasMetadataColumn gem to reduce their width and incorporate schemaless data. Most models have a JSON-formatted metadata column to which new information can be added or removed without having to create new migrations.

Various Rake tasks are available under lib/tasks. These include tasks for pruning and maintaining the database, development tasks, and configuring the workers.

Workers are found in the lib/workers directory. Along with OccurrencesWorker, which stores and categorizes Occurrences, there are other workers for managing Deploys and other minor tasks. These workers are run asynchronously using {Multithread}.

Notification mails are sent by the {NotificationMailer}. It and any other mailers live in app/mailers.

NotificationMailer conditionally delivers emails. An email will only be delivered if all of the following conditions are met:

• The Project has a mailing list email configured (for the critical-bugs and all-bugs mailing lists),
• the Environment's sends_emails attribute is true, and
• the User has enabled receipt of that category of emails (typically specified in the Membership).

Authentication is done using either password verification or LDAP; see {AuthenticationHelpers} and related controller mixins, as well as the model mixins under app/models/additions for more information.

There are four permissions levels that a User can have, specific to an individual Project:

Non-members do not have a {Membership} record with a Project. They can view Bugs and Occurrences, view the Project's API key, view the list of other Project members, watch Bugs, and comment on Bugs.

Members can do everything non-members can do, and can also assign Bugs, be assigned Bugs, and modify/delete Bugs.

Administrators can do everything members can do, and can also modify Project and Environment settings, regenerate the API key, promote and demote members to administrator status, and modify/delete others' Comments.

Owners (each Project has only one) can do everything administrators can do, and can also delete the Project and reassign ownership.

The client library identifiers used throughout the website determine how a Bug reported from that library is presented in the view. The {OccurrencesController::INDEX_FIELDS} constant maps a client library identifier to the relevant summary fields to display in the list view.

Each occurrence is transmitted with the name of the client library; the {Occurrence} records this to the client field. The {Bug}'s client field is set from the first Occurrence's; in general, one should expect that all Occurrences of a Bug share the same client value.

Regardless of the Occurrence's client value, all fields for which there is data are displayed in the Occurrence view.

If a client library is updated to add new information fields, all that is needed is to update the has_metadata hash in Occurrence with the new fields, and to update the occurrences#show view as necessary. (The INDEX_FIELDS hash can also be updated as appropriate.)

If a new client library is added, in addition to doing the above for any new fields unique to the new client, the INDEX_FIELDS hash will need to be expanded to include the new client.

For information about the background worker that converts incoming exception information into Occurrence and Bug records (including doing "best guess" commit blaming, determining which Occurrences share the same root Bug, etc.), see the documentation for the {OccurrencesWorker} module. See also Static Analysis below.

Squash can handle both deployed projects (hosted projects for which typically only one version is live at a time) and released projects (distributed apps for which many versions may exist "in the wild").

If you are developing a released project, you must associate your {Deploy} objects with a unique version identifier (such as a build number). You must also send the correct build identifier with every occurrence report. See the client library and API controller documentation for more information.

Once this is done, Squash's behavior is changed slightly: Bugs that are fixed in an older release, but recur, are not reopened. Bugs that are fixed in an older release but then recur in newer releases are treated as completely separate Bugs.

This app exposes an API endpoint for notifying Squash of new releases/deploys of your Project. You should notify Squash whenever you deploy your Project (or release a new version) so that it can properly manage Bugs (automatically mark fixed Bugs as deployed, associate new Bugs with the new Deploy, etc.).

Most client libraries include an easy means to add this feature to your deploy or release process.

When an Occurrence is grouped into a Bug, its message is stripped of any non-relevant or situational information. (Note that since the message is not used as a dimension in grouping Occurrences, two Occurrences of the same Bug could have completely different messages. A Bug gets its message from its first Occurrence.) This is done by subclasses of {Blamer::Base}.

For most messages, this is done using simple regex subsitution. Squash can also normalize an exception's message using a list of known message templates. Such templates are stored in the data/message_templates.yml file. The file contains a hash mapping exception class names to an array of arrays. Each inner array contains two elements: the regexp to match the exception message on, and the replacement message should it match.

These templates are evaluated in the order they appear in the array. Scripts that regenerate the templates for MySQL and PostgreSQL error strings can be found under the script directory.

As of now, Squash is only compatible with projects that are version-controlled using Git. However, in the interest of remaining as VCS-agnostic as possible, commit identifiers are never called "SHA1s," but instead "IDs."

Client libraries of compiled, obfuscated, or minified applications will need to convert their stack traces in order for them to be of use for static analysis. Because release builds are typically not distributed with embedded decompilation information, a mapping or table must be given to Squash, so that when Squash receives an unconverted stack trace, it can perform lookups and convert it to a more usable format.

Currently, the supported conversions are:

• symbolication of iOS exceptions (see {Symbolication}),
• deobfuscation of Java exceptions (see {ObfuscationMap}),
• and source-mapping of JavaScript exceptions (see {SourceMap}).

Client libraries are responsible for delivering the raw stack trace data to Squash when an exception occurs, and for delivering lookup tables to Squash upon each new release. {Api::V1Controller} has endpoints for these purposes in various languages.

Unconverted stack traces are stored in a particular format; see {Occurrence} for more information. When a new exception with a stack trace in this format is received, Squash immediately attempts to convert it using an existing matching lookup table. If no such table is found, the stack trace is left unconverted. It can still be viewed on the front end. When, later, a new lookup table is added, Squash automatically finds and converts any matching stack traces.

Because every new Occurrence must be assigned a Bug (including unconverted Occurrences), it is possible that the "blamed" file and line fields of the Bug could themselves be unconverted. The {Bug} class has provisions to support this; see in particular bugs.special_file.

All models, controllers, and library files are unit-tested with RSpec specs under the spec directory. Run unit tests with the rspec spec command. Views and JavaScript files are not specced. No integration or acceptance tests are written. Almost all unit tests use factories rather than mocks, putting them somewhat closer to integration tests.

In general, the test environment is identical to the development/production environment, save for the usual Rails allowances, and the config/initializers/active_record_observer_hooks.rb file. This file adds after-commit hooks to observers (identical to those available to models). However, specs are transactionalized, meaning that these hooks wouldn't run until after the spec is completed, resulting in multiple spec failures.

To remedy this, the file introspects on the environment, and instead links the observer hooks to the after_save model hooks in the test environment. This differentiates the test and live environments, but allows specs to pass.

If you wish to bring your test environment closer to production, you can set the use_transactional_fixtures RSpec setting to false. The hooks file will automatically detect the change and use the correct after_commit hooks. Currently, all specs pass with and without transactionalized fixtures.

Squash supports integration with a handful of popular other developer tools.

When Squash is integrated with PagerDuty, it will begin sending exceptions to PagerDuty once the Occurrence count for a given Bug exceeds the Project's critical threshold. Thereafter, every Occurrence is sent to PagerDuty as a trigger. The triggers are grouped into alerts by Bug, so users will only be paged once per new error.

In addition, marking a Bug fixed will also automatically resolve its associated PagerDuty alert (if any), and assigning a Bug or marking it irrelevant automatically acknowledges any associated PagerDuty alert.

In order to integrate Squash with PagerDuty, you must

1. generate an API key that Squash can use for PagerDuty access (you must be a PagerDuty admin to do this),
2. update the config/environments/common/pagerduty.yml file to enable PagerDuty integration and provide the API key,
3. configure Generic API services for each escalation policy you wish to use, and
4. set the PagerDuty-related options in your Project's configuration page.

When Squash is integrated with JIRA, users have the option of associating a JIRA issue with any Bug. The Management tab will then display a link allowing the user to quickly view the associated issue.

In addition, the user can have Squash watch the JIRA issue for status updates. Once the JIRA issue is resolved (or is changed to someother specified status), the Bug can be automatically marked as fixed. By associating multiple Bugs with one JIRA issue in such a manner, a user can quickly fix a large number of Bugs by closing just one JIRA issue.

Finally, a "Create JIRA Issue" button is provided on the Management tab allowing users to easily create new JIRA issues for any Bug.

In order to integrate Squash with JIRA, you must

1. configure the config/environments/common/jira.yml file with your JIRA authentication credentials and installation location, and
2. add a cron job or other periodic task that runs rake jira:update.

JIRA integration works out-of-the-box if you use username/password authentication. OAuth authentication requires a few more steps. Because OAuth authentication requires user actions, you will need to obtain an access token and secret which the JIRA client can use without needing to prompt the user. You can do this by running the jira_oauth.rb script:

rails runner script/jira_oauth.rb

Follow the instructions to set up your JIRA integration.