Why Strong Consistency?

Eventual consistency makes your life harder.

When I started at AWS in 2008, we ran the EC2 control plane on a tree of MySQL databases: a primary to handle writes, a secondary to take over from the primary, a handful of read replicas to scale reads, and some extra replicas for doing latency-insensitive reporting stuff. All of thing was linked together with MySQL’s statement-based replication. It worked pretty well day to day, but two major areas of pain have stuck with me ever since: operations were costly, and eventual consistency made things weird.

Since then, managed databases like Aurora MySQL have made relational database operations orders of magnitude easier. Which is great. But eventual consistency is still a feature of most database architectures that try scale reads. Today, I want to talk about why eventual consistency is a pain, and why we invested heavily in making all reads strongly consistent in Aurora DSQL.

Eventual Consistency is a Pain for Customers

Consider the following piece of code, running against an API exposed by a database-backed service:

id = create_resource(...)
get_resource_state(id, ...)

In the world of read replicas, the latter statement can do something a little baffling: reply ‘id does not exist’. The reason for this is simple: get_resource_state is a read-only call, likely routed to a read replica, and is racing the write from create_resource. If replication wins, this code works as expected. If the client wins, it has to handle to weird sensation of time moving backwards.

Application programmers don’t really have a principled way to work around this, so they end up writing code like this:

id = create_resource(...)
while True:
  try:
    get_resource_state(id, ...)
    return
  except ResourceDoesNotExist:
    sleep(100)

Which fixes the problem. Sometimes. Other times, especially if ResourceDoesNotExist can be thrown if id is deleted, it causes an infinite loop. It also creates more work for client and server, adds latency, and requires the programmer to choose a magic number for sleep that balances between the two. Ugly.

Strong consistency avoids this whole problem¹, ensuring that the first code snippet works as expected.

Eventual Consistency is a Pain for Application Builders

The folks building the service behind that API run into exactly the same problems. To get the benefits of read replicas, application builders need to route as much read traffic as possible to those read replicas. But consider the following code:

block_attachment_changes(id, ...)
for attachment in get_attachments_to_thing(id):
  remove_attachment(id, attachment)
assert_is_empty(get_attachments_to_thing(id))

This is a fairly common code pattern inside microservices. A kind a little workflow that cleans something up. But, in the wild world of eventual consistency, it has at least three possible bugs:

The assert could trigger because the second get_attachments_to_thing hasn’t heard the news of all the remove_attachments.
The remove_attachment could fail because it hasn’t heard of one of the attachments listed by get_attachments_to_thing.
The first get_attachments_to_thing could have an incomplete list because it read stale data, leading to incomplete clean up.

And there are a couple more. The application builder has to avoid these problems by making sure that all reads that are used to trigger later writes are sent to the primary. This requires more logic around routing (a simple “this API is read-only” is not sufficient), and reduces the effectiveness of scaling by reducing traffic that can be sent to replicas.

Eventual Consistency Makes Scaling Harder

Which brings us to our third point: read-modify-write is the canonical transactional workload. That applies to explicit transactions (anything that does an UPDATE or SELECT followed by a write in a transaction), but also things that do implicit transactions (like the example above). Eventual consistency makes read replicas less effective, because the reads used for read-modify-write can’t, in general, be used for writes without having weird effects.

Consider the following code:

UPDATE dogs SET goodness = goodness + 1 WHERE name = 'sophie'

If the read for that read-modify-write is read from a read replica, then the value of goodness may not be changed in the way you expect. Now, the database could internally do something like this:

SELECT goodness AS g, version AS v FROM dogs WHERE name = 'sophie'; -- To read replica
UPDATE sophie SET goodness = g + 1, version = v + 1 WHERE name = 'sophie' AND version = v; -- To primary

And then checking it actually updated a row², but that adds a ton of work.

The nice thing about making scale-out reads strongly consistent is that the query processor can read from any replica, even in read-write transactions. It also doesn’t need to know up-front whether a transaction is read-write or read-only to pick a replica.

How Aurora DSQL Does Consistent Reads with Read Scaling

As I said above, in Aurora DSQL all reads are strongly consistent. DSQL can also scale out reads by adding additional replicas of any hot shards. So how does it ensure that all reads are strongly consistent? Let’s remind ourselves about the basics of the DSQL architecture.

Each storage replica gets its updates from one or more journals. Writes on each journal are strictly monotonic, so once a storage node has seen an update from time $\tau$ it knows it has seen all updates for times $t \leq \tau$. Once it has seen $t \geq \tau$ from all the journals it has subscribed to, it knows that it can return data for time $\tau$ without missing any updates. When a query processor starts a transaction, it picks a time stamp $\tau_{start}$, and every time it does a read from a replica it says to the replica “give me data as of $\tau_{start}$”. If the replica has seen higher timestamps from all journals, its good to go. If it hasn’t yet, it blocks the read until the write streams catch up.

I go into some detail on how $\tau_{start}$ is picked here:

Conclusion

Strong consistency sounds like a complex topic for distributed systems nerds, but is a real thing that applications built on traditional database replication architectures need to start dealing with at modest scale - or even at very small scale if they’re trying to offer high availability. DSQL goes to some internal lengths to make all reads consistent - with the aim of saving application builders and end users from having to deal with this complexity.

I don’t mean to say that eventual consistency is always bad. Latency and connectivity trade-offs do exist (although the choose-two framing of CAP is bunk), and eventual consistency has its place. However, that place is probably not in your services or API.

Footnotes

You might point out that this particular problem can be fixed with a weaker set of guarantees, like Read Your Writes, provided by client stickiness. However, this falls down pretty quickly in more complex data models, and cases like IaC where ‘your writes’ is less well defined.
Yes, I know there are other ways to do this.

Social media has been a familiar, even mundane, part of life for nearly two decades. It can be easy to forget it was not always that way.

In 2008, social media was just emerging into the mainstream. Facebook reached 100 million users that summer. And a singular candidate was integrating social media into his political campaign: Barack Obama. His campaign’s use of social media was so bracingly innovative, so impactful, that it was viewed by journalist David Talbot and others as the strategy that enabled the first term Senator to win the White House.

Over the past few years, a new technology has become mainstream: AI. But still, no candidate has unlocked AI’s potential to revolutionize political campaigns. Americans have three more years to wait before casting their ballots in another Presidential election, but we can look at the 2026 midterms and examples from around the globe for signs of how that breakthrough might occur.

How Obama Did It

Rereading the contemporaneous reflections of the New York Times’ late media critic, David Carr, on Obama’s campaign reminds us of just how new social media felt in 2008. Carr positions it within a now-familiar lineage of revolutionary communications technologies from newspapers to radio to television to the internet.

The Obama campaign and administration demonstrated that social media was different from those earlier communications technologies, including the pre-social internet. Yes, increasing numbers of voters were getting their news from the internet, and content about the then-Senator sometimes made a splash by going viral. But those were still broadcast communications: one voice reaching many. Obama found ways to connect voters to each other.

In describing what social media revolutionized in campaigning, Carr quotes campaign vendor Blue State Digital’s Thomas Gensemer: “People will continue to expect a conversation, a two-way relationship that is a give and take.”

The Obama team made some earnest efforts to realize this vision. His transition team launched change.gov, the website where the campaign collected a “Citizen’s Briefing Book” of public comment. Later, his administration built We the People, an online petitioning platform.

But the lasting legacy of Obama’s 2008 campaign, as political scientists Hahrie Han and Elizabeth McKenna chronicled, was pioneering online “relational organizing.” This technique enlisted individuals as organizers to activate their friends in a self-perpetuating web of relationships.

Perhaps because of the Obama campaign’s close association with the method, relational organizing has been touted repeatedly as the linchpin of Democratic campaigns: in 2020, 2024, and today. But research by non-partisan groups like Turnout Nation and right-aligned groups like the Center for Campaign Innovation has also empirically validated the effectiveness of the technique for inspiring voter turnout within connected groups.

The Facebook of 2008 worked well for relational organizing. It gave users tools to connect and promote ideas to the people they know: college classmates, neighbors, friends from work or church. But the nature of social networking has changed since then.

For the past decade, according to Pew Research, Facebook use has stalled and lagged behind YouTube, while Reddit and TikTok have surged. These platforms are less useful for relational organizing, at least in the traditional sense. YouTube is organized more like broadcast television, where content creators produce content disseminated on their own channels in a largely one-way communication to their fans. Reddit gathers users worldwide in forums (subreddits) organized primarily on topical interest. The endless feed of TikTok’s “For You” page disseminates engaging content with little ideological or social commonality. None of these platforms shares the essential feature of Facebook c. 2008: an organizational structure that emphasizes direct connection to people that users have direct social influence over.

AI and Relational Organizing

Ideas and messages might spread virally through modern social channels, but they are not where you convince your friends to show up at a campaign rally. Today’s platforms are spaces for political hobbyism, where you express your political feelings and see others express theirs.

Relational organizing works when one person’s action inspires others to do this same. That’s inherently a chain of human-to-human connection. If my AI assistant inspires your AI assistant, no human notices and one’s vote changes. But key steps in the human chain can be assisted by AI. Tell your phone’s AI assistant to craft a personal message to one friend—or a hundred—and it can do it.

So if a campaign hits you at the right time with the right message, they might persuade you to task your AI assistant to ask your friends to donate or volunteer. The result can be something more than a form letter; it could be automatically drafted based on the entirety of your email or text correspondence with that friend. It could include references to your discussions of recent events, or past campaigns, or shared personal experiences. It could sound as authentic as if you’d written it from the heart, but scaled to everyone in your address book.

Research suggests that AI can generate and perform written political messaging about as well as humans. AI will surely play a tactical role in the 2026 midterm campaigns, and some candidates may even use it for relational organizing in this way.

(Artificial) Identity Politics

For AI to be truly transformative of politics, it must change the way campaigns work. And we are starting to see that in the US.

The earliest uses of AI in American political campaigns are, to be polite, uninspiring. Candidates viewed them as just another tool to optimize an endless stream of email and text message appeals, to ramp up political vitriol, to harvest data on voters and donors, or merely as a stunt.

Of course, we have seen the rampant production and spread of AI-powered deepfakes and misinformation. This is already impacting the key 2026 Senate races, which are likely to attract hundreds of millions of dollars in financing. Roy Cooper, Democratic candidate for US Senate from North Carolina, and Abdul El-Sayed, Democratic candidate for Senate from Michigan, were both targeted by viral deepfake attacks in recent months. This may reflect a growing trend in Donald Trump’s Republican party in the use of AI-generated imagery to build up GOP candidates and assail the opposition.

And yet, in the global elections of 2024, AI was used more memetically than deceptively. So far, conservative and far right parties seem to have adopted this most aggressively. The ongoing rise of Germany’s far-right populist AfD party has been credited to its use of AI to generate nostalgic and evocative (and, to many, offensive) campaign images, videos, and music and, seemingly as a result, they have dominated TikTok. Because most social platforms’ algorithms are tuned to reward media that generates an emotional response, this counts as a double use of AI: to generate content and to manipulate its distribution.

AI can also be used to generate politically useful, though artificial, identities. These identities can fulfill different roles than humans in campaigning and governance because they have differentiated traits. They can’t be imprisoned for speaking out against the state, can be positioned (legitimately or not) as unsusceptible to bribery, and can be forced to show up when humans will not.

In Venezuela, journalists have turned to AI avatars—artificial newsreaders—to report anonymously on issues that would otherwise elicit government retaliation. Albania recently “appointed” an AI to a ministerial post responsible for procurement, claiming that it would be less vulnerable to bribery than a human. In Virginia, both in 2024 and again this year, candidates have used AI avatars as artificial stand-ins for opponents that refused to debate them.

And yet, none of these examples, whether positive or negative, pursue the promise of the Obama campaign: to make voter engagement a “two-way conversation” on a massive scale.

The closest so far to fulfilling that vision anywhere in the world may be Japan’s new political party, Team Mirai. It started in 2024, when an independent Tokyo gubernatorial candidate, Anno Takahiro, used an AI avatar on YouTube to respond to 8,600 constituent questions over a seventeen-day continuous livestream. He collated hundreds of comments on his campaign manifesto into a revised policy platform. While he didn’t win his race, he shot up to a fifth place finish among a record 56 candidates.

Anno was RECENTLY elected to the upper house of the federal legislature as the founder of a new party with a 100 day plan to bring his vision of a “public listening AI” to the whole country. In the early stages of that plan, they’ve invested their share of Japan’s 32 billion yen in party grants—public subsidies for political parties—to hire engineers building digital civic infrastructure for Japan. They’ve already created platforms to provide transparency for party expenditures, and to use AI to make legislation in the Diet easy, and are meeting with engineers from US-based Jigsaw Labs (a Google company) to learn from international examples of how AI can be used to power participatory democracy.

Team Mirai has yet to prove that it can get a second member elected to the Japanese Diet, let alone to win substantial power, but they’re innovating and demonstrating new ways of using AI to give people a way to participate in politics that we believe is likely to spread.

Organizing with AI

AI could be used in the US in similar ways. Following American federalism’s longstanding model of “laboratories of democracy,” we expect the most aggressive campaign innovation to happen at the state and local level.

D.C. Mayor Muriel Bowser is partnering with MIT and Stanford labs to use the AI-based tool deliberation.io to capture wide scale public feedback in city policymaking about AI. Her administration said that using AI in this process allows “the District to better solicit public input to ensure a broad range of perspectives, identify common ground, and cultivate solutions that align with the public interest.”

It remains to be seen how central this will become to Bowser’s expected re-election campaign in 2026, but the technology has legitimate potential to be a prominent part of a broader program to rebuild trust in government. This is a trail blazed by Taiwan a decade ago. The vTaiwan initiative showed how digital tools like Pol.is, which uses machine learning to make sense of real time constituent feedback, can scale participation in democratic processes and radically improve trust in government. Similar AI listening processes have been used in Kentucky, France, and Germany.

Even if campaigns like Bowser’s don’t adopt this kind of AI-facilitated listening and dialog, expect it to be an increasingly prominent part of American public debate. Through a partnership with Jigsaw, Scott Rasmussen’s Napolitan Institute will use AI to elicit and synthesize the views of at least five Americans from every Congressional district in a project called “We the People.” Timed to coincide with the country’s 250th anniversary in 2026, expect the results to be promoted during the heat of the midterm campaign and to stoke interest in this kind of AI-assisted political sensemaking.

In the year where we celebrate the American republic’s semiquincentennial and continue a decade-long debate about whether or not Donald Trump and the Republican party remade in his image is fighting for the interests of the working class, representation will be on the ballot in 2026. Midterm election candidates will look for any way they can get an edge. For all the risks it poses to democracy, AI presents a real opportunity, too, for politicians to engage voters en masse while factoring their input into their platform and message. Technology isn’t going to turn an uninspiring candidate into Barack Obama, but it gives any aspirant to office the capability to try to realize the promise that swept him into office.

This essay was written with Nathan E. Sanders, and originally appeared in The Fulcrum.