There are many things to like about the
Dropwizard Framework, but if you’re like me,
you might want to “own your main” function. A normal Dropwizard
application gives you a run hook as part of its Application parent
class, but in the end your code is still subservient to the Dropwizard
framework code.
One pattern that is very good for organizing small logical services in
your application is to use
Guava’s Services
to break your application into service level groupings (And avoid the
drinking the microservice kool-aid prematurely). Guava services give
you a common operational interface to coordinate all your in-process
logical components. In this model, the Dropwizard web server is no
more important than my periodic polling service, or my separated RPC
service, and so on. I’d like my Dropwizard web stack to be a peer to
the other services that I’m running inside my application. It only
takes two steps to make this work.
Step 1: Create the Guava Service
Create a new class that extends AbstractIdleService. When we
implement the startUp method in the service, we will need to handle
the key bootstrap setup that normally is handled within the Dropwizard
framework when you invoke the server command.
import com.codahale.metrics.MetricRegistry;
import com.google.common.util.concurrent.AbstractIdleService;
import com.google.inject.Guice;
import com.google.inject.Inject;
import com.google.inject.Injector;
import io.dropwizard.setup.Bootstrap;
import io.dropwizard.setup.Environment;
import org.eclipse.jetty.server.Server;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;
public class DashboardService extends AbstractIdleService {
private static final Logger logger = LoggerFactory.getLogger(DashboardService.class);
private final DashboardApplication application;
private final DashboardConfiguration config;
private final MetricRegistry metrics;
private Server server;
@Inject
public DashboardService(final DashboardApplication application,
final DashboardConfiguration config,
final MetricRegistry metrics) {
this.application = application;
this.config = config;
this.metrics = metrics;
}
@Override
protected void startUp() throws Exception {
logger.info("Starting DashboardService");
final Bootstrap<DashboardConfiguration> bootstrap = new Bootstrap<>(application);
application.initialize(bootstrap);
final Environment environment = new Environment(bootstrap.getApplication().getName(),
bootstrap.getObjectMapper(),
bootstrap.getValidatorFactory().getValidator(),
metrics,
bootstrap.getClassLoader());
bootstrap.run(config, environment);
application.run(config, environment);
this.server = config.getServerFactory()
.build(environment);
server.start();
}
@Override
protected void shutDown() throws Exception {
logger.info("Stopping DashboardService");
server.stop();
}
}
Step 2: Reinitialize logging inside the Dropwizard Application
public class DashboardApplication extends Application<DashboardConfiguration> {
@Override
public void run(DashboardConfiguration config,
Environment environment) {
reinitializeLogging(environment);
}
/**
* Because Dropwizard clears our logback settings, reload them.
*/
private void reinitializeLogging(Environment env) {
LoggerContext context = (LoggerContext) LoggerFactory.getILoggerFactory();
try {
JoranConfigurator configurator = new JoranConfigurator();
configurator.setContext(context);
context.reset();
String logBackConfigPath = System.getProperty("logback.configurationFile");
if (logBackConfigPath != null) {
configurator.doConfigure(logBackConfigPath);
}
} catch (JoranException e) {
throw new RuntimeException("Unable to initialize logging.", e);
}
}
}
Start your Guava Service
Now you have a nicely contained Guava service that you can manage
alongside your other Guava service that aren’t necessarily Dropwizard
related. You can startAsync and stopAsync the service to start and
stop the web server, even while other code is still running.
UPDATE: This pull request has been merged into Terraform
A recent patch on the Terraform GitHub repository adds
support for CloudFront
distributions to the
Terraform AWS Provider. The
patch has not been merged into Terraform mainline yet, but I wanted to
share my experience setting up an S3 static site, fronted with
CloudFront and DNS routed with
Route53. Until the CloudFront PR gets
merged, you’ll have to build the branch from source in order to use
the aws_cloudfront_distribution resource. The words you’re reading
right now were served up from this very Terraform configuration via
CloudFront, migrated from a simple nginx setup. If you haven’t used
Terraform before, please review the
Introduction and Getting Started Guide
before proceeding.
Step 1: Setup your S3 Static Site Bucket
The first thing you need to do is setup an S3 bucket to act as your
‘origin’. This is where all your static HTML files and assets will
live. Here’s what the code looks like:
After running terraform apply, you will have an S3 bucket that’s
setup to serve HTTP traffic from the root of the bucket. Let’s examine
some of the important parameters:
policy: Bucket policy that makes the bucket publicly readable.
website: Configure the S3 bucket to serve up a static website, in this case setting the default index_document to index.html.
You can find other configurations on the
aws_s3_bucket
resource page.
After uploading your static site to the S3 bucket, you should already
be able to view the website at
http://${bucketname}.s3-website-${aws_region}.amazonaws.com. As an
example, my blog can be served up at
http://origin.blakesmith.me.s3-website-us-east-1.amazonaws.com/.
Step 2: Add a Route53 Record for your Origin
We need a DNS entry for this origin. In this example, we’ll create one
at http://origin.blakesmith.me. This will give
us a helpful DNS record that will not route through CloudFront and can
be used to access the S3 bucket static site directly with no caching
or other CloudFront routing rules applied.
resource "aws_route53_zone" "blakesmith_me" {
provider = "aws.prod"
name = "blakesmith.me"
}
resource "aws_route53_record" "origin" {
provider = "aws.prod"
zone_id = "${aws_route53_zone.blakesmith_me.zone_id}"
name = "origin.blakesmith.me"
type = "A"
alias {
name = "${aws_s3_bucket.origin_blakesmith_me.website_domain}"
zone_id = "${aws_s3_bucket.origin_blakesmith_me.hosted_zone_id}"
evaluate_target_health = false
}
}
First we setup our top level zone, and create a record that’s
associated with that zone. We setup an alias record configuration
that targets our S3 bucket we created before. Here are the important
parameters:
zone_id: A reference to our top level DNS zone id
alias#zone_id: A reference to the S3 bucket’s existing zone identifier
Once you terraform apply this, you should be able to access your
origin at the above DNS record and the behavior should be the same as
when you set up the S3 bucket static website hosting directly. Notice that
http://origin.blakesmith.me has no behavior
change from the simple S3 static bucket site we setup before.
Step 3: Setup your CloudFront Distribution
We have all the basic pieces in place, now comes to the meat: Let’s
setup a CloudFront distribution that will use the origin we just
configured to serve up the website at the edge. If you’re not too
familiar with CDNs, think of them as a “big distributed cache across
the globe”. After we configure this distribution, our content will be
served from edge servers closest to visitor’s location.
domain_name: points to the origin Route53 record we created in the last step
origin_id: A unique identifier for this origin configuration. Since you can setup multiple origins, used to link caching behavior to origin configurations.
s3_origin_config: Extra S3 origin options, we leave this blank
Next we have some other important top level declarations:
default_root_object: Use index.html as our root object
aliases: HTTP hostnames you will be serving your site from. These must match your DNS records, or you will get 403 Forbidden Errors.
price_class: How CloudFront will prioritize where traffic gets served from based on price. See: CloudFront Pricing.
retain_on_delete: Causes CloudFront deletions to simply disable your distribution. Useful since CloudFront distributions can take upwards of 15 minutes to propagate.
Once you run terraform apply with your patched version of Terraform
and wait the 10-15 minutes for AWS to asynchronously setup your
distribution, you will have a CloudFront provided domain name that you
can validate your setup with. For example, this website is viewable
via CloudFront domain name at:
d1u25xzl6dnmgy.cloudfront.net
Until the aws_cloudfront_resource gets released, you’ll have to
consult the
documentation provided in the pull request
if you need to deviate from my simple setup here. There are also other
helpful examples in
the integration tests
if you want to see other settings in action.
Step 4: Add Root Route53 Records
The last step adds Route53 records to reference the CloudFront
distribution we just setup.
resource "aws_route53_record" "root" {
provider = "aws.prod"
zone_id = "${aws_route53_zone.blakesmith_me.zone_id}"
name = "blakesmith.me"
type = "A"
alias {
name = "${aws_cloudfront_distribution.blakesmith_distribution.domain_name}"
zone_id = "Z2FDTNDATAQYW2"
evaluate_target_health = false
}
}
resource "aws_route53_record" "www" {
provider = "aws.prod"
zone_id = "${aws_route53_zone.blakesmith_me.zone_id}"
name = "www.blakesmith.me"
type = "A"
alias {
name = "${aws_cloudfront_distribution.blakesmith_distribution.domain_name}"
zone_id = "Z2FDTNDATAQYW2"
evaluate_target_health = false
}
}
Here we setup our apex zone and www record to point to our CloudFront
distribution. The two critical new pieces you should observe are:
alias#name: This ALIAS name references our CloudFront distribution created in the previous step
zone_id: This is a fixed hardcoded constant zone_id that is used for all CloudFront distributions
One final terraform apply and voilà! You have your final product: A
static site being served from an S3 bucket and fronted by the AWS
CloudFront distribution with Route53 knitting everything together.
You can verify everything is working by examining the HTTP response
headers and looking for the CloudFront headers:
Code Review is an essential part of any collaborative software
project. Large software systems are usually written by more than one
person, and so a highly functioning software team needs a robust
process to keep its members, as well as the code base itself moving in
the right direction.
Code Review is a powerful tool that:
Helps team members adapt their mental model of the system as it’s
changing
Ensures the change correctly solves the problem
Opens discussion for strengths and weaknesses of a design
Catches bugs before they get to production
Keeps the code style and organization consistent
It’s helpful to think of these benefits as a hierarchy of
needs.
Keeping Team Members Together
The most critical function of a Code Review is to keep every member of
the team moving in the right direction. You can’t safetly change a
system you don’t understand, and so Code Review keeps the team
mentally aligned together. When Bob submits a pull request for the
accounting subsystem, Amy keeps her mental model of that system
updated as she reviews Bob’s code. Amy gets the chance to ask
questions about pieces she doesn’t understand, and Bob gets the
benefit of clarifying his design decisions as well as teaching someone
else about his work. When Amy has to make a change to the accounting
subsystem a month later, her mental model of the system is already up
to date and ready for action. She spends less time reading code and
trying to piece the system together in her brain, and more time
thinking about higher level abstractions and designs. Everyone wins,
because everyone stays together.
Executing a Good Pull Request
Before you even write a line of code changing the system, ask yourself the following
questions:
“Is this the right thing to be working on?” There will always be
competing needs from customers, internal team members and other
parties. This can be a good way to keep priorities straight in your
head before you dive in deep. Other processes like iteration /
sprint planning meetings also help keep this on track.
“Does the team already agree that the change is the right one?” If
not, it’d be better to start a design discussion by email or maybe
in person. Your changes are more likely to get accepted when people
are in agreement about the design before you change it.
“How can I break this change into digestable chunks that are easy to
review and understand?” Small changes are easier to think about and
understand. Good discussions flow from the team being able to
comprehend your change quickly. If your change is massive,
teammate’s eyes will glaze over, and you might only get a few style
nitpicks from them.
“How am I going to test this change to kill bugs and ensure
correctness?” You might have a QA department, but it’s still your
job as the developer to ship quality working software. Easily
testable software is usually more decoupled, is broken into smaller
chunks, and easier to reason about. You need to have a testing plan
for all your changes.
I’ve found that answering these questions ahead of time has saved me a
lot of headache in the long run. The last thing you want to do is
spend days coding up a change only to have it rejected based on
fundamental design flaws or team disagreement. Or for your change to
get held up because no one can verify it for correctness. Again, the
goal is to change the system while keeping other team members up to
date with your changes. Asking yourself about how you’re going to
break your work into bite-sized chunks and test those chunks is
helpful on many fronts:
It reduces risk
It makes changes easier to reason about
It pushes you towards a better design
You’d rather make many small, precise cuts with a scalpel than one
giant gash with a machete. I prefer scalpel driven developement in
most additive cases, and like to save the machete for when it’s time
to delete large blocks of dead code.
Sending the Pull Request
Ok, so you’ve gotten buy-in from the team that your changes are good,
and you’ve achieved the design you set out to build. What’s the most
effective way to actually send your pull request? You’ve been working
hard on your changes, and you want other members of your team to pay
attention to your pull request and give you fast feedback. How can you
do that?
Remember earlier when I said that the most important part of a code
review is to keep the team’s collective mental model well aligned?
Your other teammates are probably working on something completely
different than you, maybe in a completely different part of the
system. Their brains are in a completely different context, so you
must overcome this by giving them the helpful guidance they need to do
the review. This means writing a well-organized description of the
changes you made, why you made them and any other relevant information
they won’t get from just reading the code alone. Don’t make your
teammates do more mental work than they have to.
Let’s look at some good and bad examples of pull request descriptions:
Bad Example:
Title: Fix uninitialized memory bug
Description:
This is the bug Bob and I talked about earlier. I had
trouble with the compiler but managed to make this work. Let me
know what you guys think.
If you’re the developer of this pull request, stop and put yourself in
your code reviewer’s shoes for a second. The title is vague, and
raises more questions than answers: Where is the memory bug? How
critical is this change? What was the bug that Bob and you talked
about earlier? What trouble did you have with the compiler? The
description doesn’t provide any helpful context about the problem, nor
does it provide any helpful description of your changes. If this pull
request is long, the reviewer is going to have to dive into the code
and do mental gymnastics in an attempt to gain context before even
getting a chance to think about how this change fits in to the
coherent design of the system.
Here’s a improved example that helps clarify the changeset:
Title: Fix process crash on startup from uninitialized memory [#54633]
Description:
This bug was causing process crashes on boot due to a memory
initialization error in our statistics Counter class. I talked this
over with Bob, and we both agree the crashes are a rare edge case
that don't warrant a hot-fix release. Here's a summary of the
changes:
- Moved the underlying int variable into the class initializer
to prevent ununitialized memory in the Counter.
- Reworked the Counter interface to simplify caller conditional
logic and prevent further off-by-one counting problems.
- Added a unit test that exposes the crash
Testing: I've verified the test suite still passes, and verified
manually that the crash doesn't happen locally.
A few things that have improved in this pull request description: The
title is descriptive enough to give the reviewer some short context,
and entice them to click on the email and learn more. The reviewer
knows it’s a process crash (which is usually a really bad thing) and
there’s also a bug report number where the reviewer can read more
details about the bug report if they’re interested in understand more
about the problem. The new description also outlines where the problem
was occuring, and helps give some context about how critical the fix
is. There’s a summary that lists the high level structural changes in
the pull request, which will give the reviewer a mental picture of the
changes before they even look at the code. Code reviewers should not
be surprised with what they find. This example also outlines testing
that was performed, which will give reviewers confidence that the
changes were well thought out, well tested and ready to be merged. Set
your reviewers up for success by making it stupid easy for them to
click ‘merge’.
Reviewers: Giving Constructive Feedback
The next part of the review process to consider is giving constructive
feedback to your peers. If the goal is clarity and alignment, giving
quality constructive feedback helps everyone understand the system
better and push towards better code.
Avoid saying things like:
“This design is broken.” Why is it broken? How can it be made
better? Statements like this hurt confidence and can bruise egos.
“I don’t like this change.” Why don’t you like it? What would you
like instead? It’s okay to not like something, but you should
articulate your thoughts and provide helpful clues about how the
code can be improved.
“Can you rewrite this to be more clear?” What’s wrong with what
I have now? How should I rewrite it? What’s unclear? Comments
like this are themselves unclear, and don’t give a simple path
forward.
Instead, say things like:
“How does this code handle negative integers?” This feedback is
specific, and causes the developer to think through the outcomes
themselves. As a reviewer, you might know that the code in
question crashes with negative integers, but it’s better to have
the developer intuit this themselves. Questions like this might
also be indicative of a testing gap, or a need for further
specification of scope.
“This section is confusing to me, I don’t understand why class A
is talking to class B” If the developer hasn’t provided a helpful
description, and the code isn’t neatly structured, this kind of
comment helps drive for clarity of design and cleaner code.
“It looks like you broke an interface boundary here. How will
that affect the user?” You’ve pointed out an issue you noticed,
giving them the benefit of the doubt that they meant to do it. Now
they can think through the unseen ramifications of breaking the
interface boundary and either provide a rationale for their
decision, or choose to change it.
In general, framing feedback as questions is a good way to drive for
clarity, correctness, and at the same time help the developer improve
their designs in the future. This is usually how quality creative
writing groups give each other feedback. In a creative writing
setting, it’s harmful to say things like, “I don’t like this
character.” whereas the same comment can be reframed more clearly: “In
chapter one your character was warm and compassionate and now he’s
cold and icey. He doesn’t seem like a real person to me.” Now there’s
specific feedback that can be clarified to suss out the problem.
Programmers like to solve problems and point out issues, so by nature
they like to discover and point out flaws. It’s tempting to see code
reviews as a way to prove how smart you are by finding problems in
your peer’s code. Don’t do it. Code review is a way to get more eyes
on a change and suss out critical problems, but your goal should be to
review in a way that encourages your team members to improve their
skills while fixing the problems at hand.
Style Points
Brace positions, variable / function names, indentation and spacing
issues should be addressed, but they are not the central purpose of
good code review (notice that I put them at the top the code
review pyramid). If you find that your team is spending 90% of it’s
time nitpicking indentation and variable names, you’re probably
wasting everyone’s time on something that could be mostly automated.
Write up a style guide, enforce indentation and spacing issues on
check-in and spend your time focusing on higher value issues. I don’t
want to diminish the importance of a consistent style. On the
contrary, having a consistent idiomatic style is one of the easiest
ways to make your codebase easy to read and comprehend. Still, if you
spend all of your code review focused on these simplistic tasks, ask
yourself whether you’re avoiding the harder and more important work of
keeping your team mentally aligned and thinking about higher level
designs.
