You need databases if you need any kind of atomicity. Doing atomic writes is extremely fragile if you are just on top of the filesystem.
This is also why many databases have persistence issues and can easily corrupt on-disk data on crash. Rocksdb on windows is a very simple example a couple years back. It was regularly having corruption issues when doing development with it.
Honestly, at this point, if I had a design that required making atomic changes to files, I'd redo the design to use SQLite. The other way around sounds crazy to me.
"Why use spray paint when you can achieve the same effect by ejecting paint from your mouth in a uniform high-velocity mist?" If you happen to have developed that particular weird skill, by all means use it, but if you haven't, don't start now.
That probably sounds soft and lazy. I should learn to use my operating system's filesystem APIs safely. It would make me a better person. But honestly, I think that's a very niche skill these days, and you should consider if you really need it now and if you'll ever benefit from it in the future.
Also, even if you do it right, the people who inherit your code probably won't develop the same skills. They'll tell their boss it's impossibly dangerous to make any changes, and they'll replace it with a database.
For the simple case, it isn't necessarily that fragile. Write the entire database to a temp file, then after flushing, move the temp file to overwrite the old file. All Unix filesystems will ensure the move operation is atomic. Lots of "we dump a bunch of JSON to the disk" use cases could be much more stable if they just did this.
Doesn't scale at all, though - all of the data that needs to be self-consistent needs to be part of the same file, so unnecessary writes go through the roof if you're only doing small updates on a giant file. Still gotta handle locking if there is risk of a stray process messing it up. And doing this only handles part of ACID.
I mean, if your atomic unit is a single file and you can tolerate simple consistency models, flat files are perfectly fine. There are many use cases that fit here comfortably where a whole database would be overkill
Sometimes yes, I've seen it. It even tends to happen on NoSQL databases as well. Three times I've seen apps start on top of Dynamo DB, and then end up re-implementing relational databases at the application level anyway. Starting with postgres would have been the right answer for all three of those. Initial dev went faster, but tech debt and complexity quickly started soaking up all those gains and left a hard-to-maintain mess.
This always confuses me because we have decades of SQL and all its issues as well. Hundreds of experienced devs talking about all the issues in SQL and the quirks of queries when your data is not trivial.
One would think that for a startup of sorts, where things changes fast and are unpredictable, NoSQL is the correct answer. And when things are stable and the shape of entities are known, going for SQL becomes a natural path.
There is also cases for having both, and there is cases for graph-oriented databases or even columnar-oriented ones such as duckdb.
Seems to me, with my very limited experience of course, everything leads to same boring fundamental issue: Rarely the issue lays on infrastructure, and is mostly bad design decisions and poor domain knowledge. Realistic, how many times the bottleneck is indeed the type of database versus the quality of the code and the imlementation of the system design?
No, when things change fast and unpredictably, NoSQL is worse than when they are well-known and stable.
NoSQL gains you no speed at all in redesigning your system. Instead, you trade a few hard to do tasks in data migration into an unsurmountable mess of data inconsistency bugs that you'll never actually get into the end of.
> is mostly bad design decisions and poor domain knowledge
Yes, using NoSQL to avoid data migrations is a bad design decision. Usually created by poor general knowledge.
Makes sense. But in this case, why NoSQL exists? What problems does it resolves and when should it be considered? I'm being naive, but fast changing environment has been one of the main advantages that I was taught from devs when it comes to NoSQL vs SQL (nosql being the choice for flexible schemas). So it is more about BASE vs ACID?
NoSQL was created to deal with scales where ACID becomes a bottleneck. It also shown itself useful for dealing with data that don't actually have an schema.
If you have either of those problems, you will know it very clearly.
Also, ironically, Postgres became one of the most scalable NoSQL bases out there, and one of the most flexible to use unstructured data too.
I think part of it is the scale in terms of the past decade and a half... The hardware and vertical scale you could get in 2010 is dramatically different than today.
A lot of the bespoke no-sql data stores really started to come to the forefront around 2010 or so. At that time, having 8 cpu cores and 10k rpm SAS spinning drives was a high end server. Today, we have well over 100 cores, with TBs of RAM and PCIe Gen 4/5 NVME storage (u.x) that is thousands of times faster and has a total cost lower than the servers from 2010 or so that your average laptop can outclass today.
You can vertically scale a traditional RDBMS like PostgreSQL to an extreme degree... Not to mention utilizing features like JSONB where you can have denormalized tables within a structured world. This makes it even harder to really justify using NoSQL/NewSQL databases. The main bottlenecks are easier to overcome if you relax normalization where necessary.
There's also the consideration of specialized databases or alternative databases where data is echo'd to for the purposes of logging, metrics or reporting. Not to mention, certain layers of appropriate caching, which can still be less complex than some multi-database approaches.
What about the microservices/serverless functions world? This was another common topic over the years, that using SQL with this type of system was not optimal, I believe the issue being the connections to the SQL database and stuff.
I think a lot of the deference to microservices/serverless is for similar reasons... you can work around some of this if you use a connection proxy, which is pretty common for PostgreSQL...
That said, I've leaned into avoiding breaking up a lot of microservices unless/until you need them... I'm also not opposed to combining CQRS style workflows if/when you do need micro services. Usually if you need them, you're either breaking off certain compute/logic workflows first where the async/queued nature lends itself to your needs. My limited experience with a heavy micro-service application combined with GraphQL was somewhat painful in that the infrastructure and orchestration weren't appropriately backed by dedicated teams leading to excess complexity and job duties for a project that would have scaled just fine in a more monolithic approach.
YMMV depending on your specific needs, of course. You can also have microservices call natural services that have better connection sharing heuristics depending again on your infrastructure and needs... I've got worker pools that mostly operate of a queue, perform heavy compute loads then interact with the same API service(s) as everything else.
It's almost always a system design issue. Outside of a few specific use cases with big data, I struggle to imagine when I'd use NoSQL, especially in an application or data analytics scenario. At the end of the data, your data should be structured in a predictable manner, and it most likely relates to other data. So just use SQL.
You could also consider renting an Oracle DB. Yep! Consider some unintuitive facts:
ā¢ It can be cheaper to use Oracle than MongoDB. There are companies that have migrated away from Mongo to Oracle to save money. This idea violates some of HN's most sacred memes, but there you go. Cloud databases are things you always pay for, even if they're based on open source code.
ā¢ Oracle supports NoSQL features including the MongoDB protocol. You can use the Mongo GUI tools to view and edit your data. Starting with NoSQL is very easy as a consequence.
ā¢ But... it also has "JSON duality views". You start with a collection of JSON documents and the database not only works out your JSON schemas through data entropy analysis, but can also refactor your documents into relational tables behind the scenes whilst preserving the JSON/REST oriented view e.g. with optimistic locking using etags. Queries on JSON DVs become SQL queries that join tables behind the scenes so you get the benefits of both NoSQL and SQL worlds (i.e. updating a sub-object in one place updates it in all places cheaply).
ā¢ If your startup has viral growth you won't have db scaling issues because Oracle DBs scale horizontally, and have a bunch of other neat performance tricks like automatically adding indexes you forgot you needed, you can materialize views, there are high performance transactional message queues etc.
So you get a nice smooth scale-up and transition from ad hoc "stuff some json into the db and hope for the best" to well typed data with schemas and properly normalized forms that benefit from all the features of SQL.
Good points, but Postgres has all those, along with much better local testing story, easier and more reliable CDC, better UDFs (in Python, Go etc.), a huge ecosystem of extensions for eg. GIS data, no licencing issues ever, API compatability with DuckDB, Doris and other DBs, and (this is the big one) is not Oracle.
I generally limit Oracle to where you are in a position to have a dedicated team to the design, deployment and management of just database operations. I'm not really a fan of Oracle in general, but if you're in a position to spend upwards of $1m/yr or more for dedicated db staff, then it's probably worth considering.
Even then, PostgreSQL and even MS-SQL are often decent alternatives for most use cases.
That was true years ago but these days there's the autonomous database offering, where DB operations are almost all automated. You can rent them in the cloud and you just get the connection strings/wallet and go. Examples of stuff it automates: backups, scaling up/down, (as mentioned) adding indexes automatically, query plan A/B testing to catch bad replans, you can pin plans if you need to, rolling upgrades without downtime, automated application of security patches (if you want that), etc.
So yeah running a relational DB used to be quite high effort but it got a lot better over time.
At that point, you can say the same for PostgreSQL, which is more broadly supported across all major and minor cloud platforms with similar features and I'm assuming a lower cost and barrier of entry. This is without signing with Oracle, Inc... which tends to bring a lot of lock-in behaviors that come with those feature sets.
TBF, I haven't had to use Oracle in about a decade at this point... so I'm not sure how well it competes... My experiences with the corporate entity itself leave a lot to be desired, let alone just getting setup/started with local connectivity has always been what I considered extremely painful vs common alternatives. MS-SQL was always really nice to get setup, but more recently has had a lot of difficulties, in particular with docker/dev instances and more under arm (mac) than alternatives.
I'm a pretty big fan of PG, which is, again, very widely available and supported.
Autonomous DB can run on-premises or in any cloud, not just Oracle's cloud. So it's not quite the same.
I think PG doesn't have most of the features I named, I'm pretty sure it doesn't have integrated queues for example (SELECT FOR UPDATE SKIP LOCKED isn't an MQ system), but also, bear in mind the "postgres" cloud vendors sell is often not actually Postgres. They've forked it and are exploiting the weak trademark protection, so people can end up more locked in than they think. In the past one cloud even shipped a transaction isolation bug in something they were calling managed Postgres, that didn't exist upstream! So then you're stuck with both a single DB and a single cloud.
Local dev is the same as other DBs:
docker run -d --name <oracle-db> container-registry.oracle.com/database/free:latest
Works on Intel and ARM. I develop on an ARM Mac without issue. It starts up in a few seconds.
Cost isn't necessarily much lower. At one point I specced out a DB equivalent to what a managed Postgres would cost for OpenAI's reported workload:
> I knocked up an estimate using Azure's pricing calculator and the numbers they provide, assuming 5TB of data (under-estimate) and HA option. Even with a 1 year reservation @40% discount they'd be paying (list price) around $350k/month. For that amount you can rent a dedicated Oracle/ExaData cluster with 192 cores! That's got all kinds of fancy hardware optimizations like a dedicated intra-cluster replication network, RDMA between nodes, predicate pushdown etc. It's going to perform better, and have way more features that would relieve their operational headache.
There's plenty of middle ground between an unchanging SQL schema and the implicit schemas of "schemaless" databases. You can have completely fluid schemas with the full power of relational algebra (e.g. untyped datalog). You shouldn't be using NoSQL just because you want to easily change schemas.
I've never used DynamoDB in production, but it always struck me as the type of thing where you'd want to start with a typical relational database, and only transition the critical read/write paths when you get to massive scale and have a very good understanding of your data access patterns.
Same. DynamoDB is almost never a good default choice unless you've thought very carefully about your current and future use cases. That's not to say it's always bad! At previous startups we did some amazing things with Dynamo.
Here are two checks using joins, one with sqlite, one with the join builtin of ksh93:
check_empty_vhosts () {
# Check which vhost adapter doesn't have any VTD mapped
start_sqlite
tosql "SELECT l.vios_name,l.vadapter_name FROM vios_vadapter AS l
LEFT OUTER JOIN vios_wwn_disk_vadapter_vtd AS r
USING (vadapter_name,vios_name)
WHERE r.vadapter_name IS NULL AND
r.vios_name IS NULL AND
l.vadapter_name LIKE 'vhost%';"
endsql
getsql
stop_sqlite
}
check_empty_vhosts_sh () {
# same as above, but on the shell
join -v 1 -t , -1 1 -2 1 \
<(while IFS=, read vio host slot; do
if [[ $host == vhost* ]]; then
print ${vio}_$host,$slot
fi
done < $VIO_ADAPTER_SLOT | sort -t , -k 1)\
<(while IFS=, read vio vhost vtd disk; do
if [[ $vhost == vhost* ]]; then
print ${vio}_$vhost
fi
done < $VIO_VHOST_VTD_DISK | sort -t , -k 1)
}
Based on what's in the article, it wouldn't take much to move these files to SQLite or any other database in the future.
Edit: I just submitted a link to Joe Armstrong's Minimum Viable Programs article from 2014. If the response to my comment is about the enterprise and imaginary scaling problems, realize that those situations don't apply to some programming problems.
You can avoid the overhead of working with the database. If you want to work with json data and prefer the advantages of text files, this solution will be better when you're starting out. I'm not going to argue in favor of a particular solution because that depends on what you're doing. One could turn the question around and ask what's special about SQLite.
If your language supports it, what is the overhead of working with SQLite?
What's special about SQLite is that it already solves most of the things you need for data persistence without adding the same kind of overhead or trade offs as Postgres or other persistence layers, and that it saves you from solving those problems yourself in your json text files...
Like by all means don't use SQLite in every project. I have projects where I just use files on the disk too. But it's kinda inane to pretend it's some kind of burdensome tool that adds so much overhead it's not worth it.
Battle-tested, extremely performant, easier to use than a homegrown alternative?
By all means, hack around and make your own pseudo-database file system. Sounds like a fun weekend project. It doesn't sound easier or better or less costly than using SQLite in a production app though.
āVirding's First Rule of Programming: Any sufficiently complicated concurrent program in another language contains an ad hoc informally-specified bug-ridden slow implementation of half of Erlang.ā
I interpret YAGNI to mean that you shouldn't invest extra work and extra code complexity to create capabilities that you don't need.
In this case, I feel like using the filesystem directly is the opposite: doing much more difficult programming and creating more complex code, in order to do less.
It depends on how you weigh the cost of the additional dependency that lets you write simpler code, of course, but I think in this case adding a SQLite dependency is a lower long-term maintenance burden than writing code to make atomic file writes.
The original post isn't about simplicity, though. It's about performance. They claim they achieved better performance by using the filesystem directly, which could (if they really need the extra performance) justify the extra challenge and code complexity.
but it's so trivial to implement SQLite, in almost any app or language...there are sufficient ORMs to do the joins if you don't like working with SQL directly...the B-trees are built in and you don't need to reason about binary search, and your app doesn't have 300% test coverage with fuzzing like SQLite does
you should be squashing bugs related to your business logic, not core data storage. Local data storage on your one horizontally-scaling box is a solved problem using SQLite. Not to mention atomic backups?
Honestly, there is zero chance you will implement anything close to sqlite.
What is more likely, if you are making good decisions, is that you'll reach a point where the simple approach will fail to meet your needs. If you use the same attitude again and choose the simplest solution based on your _need_, you'll have concrete knowledge and constraints that you can redesign for.
Came here to also throw in a vote for it being so much easier to just use SQLite. You get so much for so very little. There might be a one-time up-front learning effort for tweaking settings, but that is a lot less effort than what you're going to spend on fiddling with stupid issues with data files all day, every day, for the rest of the life of your project.
Even then... I'd argue for at least LevelDB over raw jsonl files... and I say this as someone who would regularly do ETL and backups to jsonl file formats in prior jobs.
> and your app doesn't have 300% test coverage with fuzzing like SQLite does
Surely it does? Otherwise you cannot trust the interface point with SQLite and you're no further ahead. SQLite being flawless doesn't mean much if you screw things up before getting to it.
That's true but relying on a highly tested component like SQLite means that you can focus your tests on the interface and your business logic, i.e. you can test that you are persisting to the your datastore rather than testing that your datastore implementation is valid.
Your business logic tests will already, by osmosis, exercise the backing data store in every conceivable way to the fundamental extent that is possible with testing given finite time. If that's not the case, your business logic tests have cases that have been overlooked. Choosing SQLite does mean that it will also be tested for code paths that your application will never touch, but who cares about that? It makes no difference if code that is never executed is theoretically buggy.
Then your business logic contains unspecified behaviour. Maybe you have a business situation where power loss conditions being unspecified is perfectly acceptable, but if that is so it doesn't really matter what happens to your backing data store either.
Your article completely ignores operational considerations: backups, schema changes, replication/HA. As well as security, i.e. your application has full permissions to completely destroy your data file.
Regardless of whether most apps have enough requests per second to "need" a database for performance reasons, these are extremely important topics for any app used by a real business.
I love this article as it shows how fast computers really are.
There is one conclusion that I do not agree with. Near the end, the author lists cases where you will outgrow flat files. He then says that "None of these constraints apply to a lot of applications."
One of the constraints is "Multiple processes need to write at the same time." It turns out many early stage products need crons and message queues that execute on a separate worker. These multiple processes often need to write at the same time. You could finagle it so that the main server is the only one writing, but you'd introduce architectural complexity.
So while from the pure scale perspective I agree with the author, if you take a wider perspective, it's best to go with a database. And sqlite is a very sane choice.
If you need scale, cache the most often accessed data in memory and you have the best of both worlds.
SQLite has become my new go-to when starting any project that needs a DB. The performance is very fast, and if anything is ever successful enough to outgrow SQLite, it wouldn't be that hard to switch it out for Postgres. Not having to maintain/backup/manage a separate database server is cheaper and easier.
We built a PDF processing tool and faced this exact question early on.
For our use case ā merge, split, compress ā we went fully stateless. Files are processed in memory and never stored. No database needed at all.
The only time a database becomes necessary is when you need user accounts, history, or async jobs for large files. For simple tools, a database is often just added complexity.
The real question isn't "do you need a database" but "do you need state" ā and often the answer is no.
Writing your own storage is a great way to understand how databases work (if you do it efficiently, keeping indexes, correct data structures, etc.) and to come to the conclusion that if your intention wasn't just tinkering, you should've used a database from day 1.
Sharks vs. dinosaurs seems indeed an appropriate metaphor.
During Cretaceous, when dinosaurs were at their peak, sharks had already become very similar to the sharks of today, e.g. there were big sharks that differed very little from the white sharks and tiger sharks of today.
Then the dinosaurs have disappeared, together with the pterosaurs and the mosasaurs, and they have been replaced by other animals, but the sharks have continued to live until today with little changes, because they had already reached an optimized design that was hard to improve.
Besides the sharks, during Cretaceous there already existed along the dinosaurs other 2 groups of big predators that have changed little since then, crocodiles and big constrictor snakes similar to the pythons of today.
Therefore all 3 (sharks, crocodiles and big constrictor snakes) are examples of locally optimum designs that have been reached more than 70 million years ago, without needing after that any major upgrades.
Many eons ago I wrote a small sales web application in Perl. I couldn't install anything on the ISP's machine, so I used file-backed hashes: one for users, one for orders, another for something else.
As the years went by, I expected the client to move to something better, but he just stuck with it until he died after about 20 years, the family took over and had everything redone (it now runs Wordpress).
The last time I checked, it had hundreds of thousands of orders and still had good performance. The evolution of hardware made this hack keep its performance well past what I had expected it to endure. I'm pretty sure SQLite would be just fine nowadays.
> Binary search beats SQLite... For a pure ID lookup, you're paying for machinery you're not using.
You'll likely end up quite a chump if you follow this logic.
sqlite has pretty strong durability and consistency mechanism that their toy disk binary search doesn't have.
(And it is just a toy. It waves away the maintenance of the index, for god's sake, which is almost the entire issue with indexes!)
Typically, people need to change things over time as well, without losing all their data, so backwards compatibility and other aspects of flexibility that sqlite has are likely to matter too.
I think once you move beyond a single file read/written atomically, you might as well go straight to sqlite (or other db) rather than write your own really crappy db.
File systems are nice if you need to do manual or transparent script-based manipulations. Like 'oh hey, I just want to duplicate this entry and hand-modify it, and put these others in an archive.' Or use your OS's access control and network sharing easily with heterogeneous tools accessing the data from multiple machines. Or if you've got a lot of large blobs that aren't going to get modified in place.
What the world needs is a hybrid - database ACID/transaction semantics with the ability to cd/mv/cp file-like objects.
I dunno. Even in embedded systems every time I've started without a database I've eventually come to need something like a database, and in every case I've found myself building essentially an ad-hoc poorly managed database into the application including marshalling/unmarshalling, file management, notification, and so on because each new feature over the top of regular files was just that much easier to add versus switching to a database system.
However the driving motivation for adding a database is not necessarily managing data, but the fact that the database system creates a nice abstraction layer around storing data of relational or non-relational form in non-volatile memory and controlling access to it while other systems are updating it. And because it's a nice abstraction, there are a lot of existing libraries that can take advantage of it in your language of choice without requiring you to completely invent all of that stuff over the top of the filesystem. That has knock-on effects when you're trying to add new functionality or new interaction patterns to an existing system.
And in cases where two or more processes need to communicate using the same data, a database gives you some good abstractions and synchronization primitives that make sense, whereas regular files or IPC require you to invent a lot of that stuff. You could use messaging to communicate updates to data but now you have two copies of everything, and you have to somehow atomize the updates so that either copy is consistent for a point in time. Why not use a database?
Knowing what I know today I would start with some kind of database abstraction even if it's not necessarily designed for transactional data, and I would make sure it handled the numerous concerns I have around data sharing, consistency, atomicity, and notification because if I don't have those things I eventually have to invent them to solve the reliability problems I otherwise run in to without them.
I suggest every developer write a database from scratch at least once, and use it for something real. Or, even better, let somebody else use it for something real. Then you will know "why database".
My first time was with a Bukkit plugin as a kid. One of my updates broke existing flat json files. Someone asked me if it has MySQL support, I didn't know what that was, then realized oh this is nice.
There are also things besides databases that I'll DIY and then still wonder why so many people use a premade tool for it, like log4j
It's indeed an amazing design and implementation space to explore. If distributed it is nearly comprehensive in scope. (However, did lol @ your "every developer" - that's being super kind and generous or "developer" is doing heavy lifting here.)
I suggest every developer learn how to replicate, backup and restore the very database they are excited about, from scratch at least once. I propose this will teach them what takes to build a production ready system and gain some appreciation for other ways of managing state.
Please ā¦
Every few years the pendulum swings. First it was ārelational databases are too rigid, just use NoSQL.ā Then āNoSQL is a mess, just go back to Postgres.ā Now: ādo you even need a database at all, just use flat files.ā
Each wave is partially right. Butā¦ each wave is about to rediscover, the hard way, exactly why the previous generation made the choices they did.
SQLite is the answer to every painful lesson learned, every scar from long debug night the last time someone thought āa JSON file is basically a database.ā
Michael Stonebraker used to write long, scathing critiques of modern data storage/retrieval fads, and how they were forgetting important historical lessons.
They were terrific reads; his writing on object-oriented databases was the most fun technical reading I did in grad school. And I even learned a lot!
people wildly underestimate the os page cache and modern nvme drives tbh. disk io today is basically ram speeds from 10 years ago. seeing startups spin up managed postgres + redis clusters + prisma on day 1 just to collect waitlist emails is peak feature vomit.
a jsonl file and a single go binary will literally outlive most startup runways.
also, the irony of a database gui company writing a post about how you dont actually need a database is pretty based.
The irony isnāt lost on us, trust me. We spent a while debating whether to even publish this one.
But yeah, the page cache point is real and massively underappreciated. Modern infrastructure discourse skips past it almost entirely. A warm NVMe-backed file with the OS doing the caching is genuinely fast enough for most early-stage products.
Definitely appreciate the post and the discussion that has come from it... While I'm still included to just reach for SQLite as a near starting point, it's often worth considering depending on your needs.
In practice, I almost always separate the auth chain from the service chain(s) in that if auth gets kicked over under a DDoS, at least already authenticated users stand a chance of still being able to use the apps. I've also designed auth system essentially abstracted to key/value storage with adapters for differing databases (including SQLite) for deployments...
Would be interested to see how LevelDB might perform for your testing case, in that it seems to be a decent option for how your example is using data.
props for actually publishing it tbh. transparent engineering takes are so rare now, usually its just seo fluff.
weve basically been brainwashed to think we need kubernetes and 3 different databases just to serve a few thousand users. gotta burn those startup cloud credits somehow i guess.
mad respect for the honesty though, actually makes me want to check out db pro when i finally outgrow my flat files.
I'm feel like I could write another post: Do you even need serverless/Cloud because we've also been brainwashed into thinking we need to spend hundreds/thousands a month on AWS when a tiny VPS will do.
You are both right, with the exception that it requires knowledge and taste to accomplish, both of which are in short supply in the industry.
Why setup a go binary and a json file? Just use google forms and move on, or pay someone for a dead simple form system so you can capture and commmunicate with customers.
People want to do the things that make them feel good - writing code to fit in just the right size, spending money to make themselves look cool, getting "the right setup for the future so we can scale to all the users in the world!" - most people don't consider the business case.
What they "need" is an interesting one because it requires a forecast of what the actual work to be done in the future is, and usually the head of any department pretends they do that when in reality they mostly manage a shared delusion about how great everything is going to go until reality hits.
I have worked for companies getting billions of hits a month and ones that I had to get the founder to admit there's maybe 10k users on earth for the product, and neither of them was good at planning based on "what they need".
Serverless is cheap as hell as low volumes. Your tiny VPS can't scale to zero. If you're doing sustained traffic your tiny VPS might win though. The real value in Cloud is turning capex spend into opex spend. You don't have to wait weeks or months to requisition equipment.
> weve basically been brainwashed to think we need kubernetes and 3 different databases just to serve a few thousand users. gotta burn those startup cloud credits somehow i guess.
I don't think it makes any sense to presume everyone around you is brainwashed and you are the only soul cursed with reasoning powers. Might it be possible that "we" are actually able to analyse tradeoffs and understand the value of, say, have complete control over deployments with out of the box support for things like deployment history, observability, rollback control, and infrastructure as code?
Or is it brainwashing?
Let's put your claim to the test. If you believe only brainwashed people could see value in things like SQLite or Kubernetes, what do you believe are reasonable choices for production environments?
Except that eventually you'll find you lose a write when things go down because the page cache is write behind. So you start issuing fsync calls. Then one day you'll find yourself with a WAL and buffer pool wondering why you didn't just start with sqlite instead.
Don't know if it counts, but my London cinema listings website just uses static json files that I upload every weekend. All of the searching and stuff is done client side. Although I do use sqlite to create the files locally.
Total hosting costs are Ā£0 ($0) other than the domain name.
A few months back I decided to write an embedded db for my firm's internal JS framework. Learned a lot about how/why databases work the way they do. I use stuff like reading memory cached markdown files for static sites, but there are certain things that a database gives you (chief of which for me was query ergonomicsāI loved MongoDB's query language but grew too frustrated with the actual runtime) that you'll miss once you move past a trivial data set.
I think a better way to ask this question is "does this application and its constraints necessitate a database? And if so, which database is the correct tool for this context?"
For me, I just wish MongoDB had scaling options closer to how Elatic/Cassandra and other horizontally scalable databases work, in that the data is sharded in a circle with redundancy metrics... as opposed to Mongo, which afaik is still limited to either sharding or replication (or layers of them). FWIW, I wish that RethinkDB had seen more attention and success and for that matter might be more included to use CockroachDB over Mongo, where I can get some of the scaling features while still being able to have some level of structured data.
Separate from performance, I feel like databases are a sub-specialty that has its own cognitive load.
I can use databases just fine, but will never be able to make wise decisions about table layouts, ORMs, migrations, backups, scaling.
I don't understand the culture of "oh we need to use this tool because that's what professionals use" when the team doesn't have the knowledge or discipline to do it right and the scale doesn't justify the complexity.
I'm so old I remember working on databases that were designed to use RAW, not files. I'm betting some databases still do, but probably only for mainframe systems nowadays.
> OracleĀ® Database Platform Guide 10g Release 2 (10.2) for Microsoft Windows Itanium (64-Bit)
Well, I guess that at least confirms Oracle on Itanium (!?) still supported RAW 5 years ago.
I'm guessing everyone's on ASM by now though, if they're still upgrading. I ran into a company not long ago with a huge oracle cluster that still employed physical database admins and logical database admins as separate roles...I would bet they're still paying millions for an out of date version of Oracle and using RAW.
I'm a big fan of using S3 as a database. A lot of apps can get a lot of mileage just doing that for a good chunk of their data; that which just needs lookup by a single field (usually ID, but doesn't have to be).
I worked in an org where a lot of records were denormalized to be used in a search database... since I went through that level of work anyway, I also fed the exports into S3 records for a "just in case" backup. That backup path became really useful in practice, since there was a need for eventually a "pending" version of records, separate from the "published" version.
In practice, the records themselves took no less than 30 joins for a flat view of the record data that was needed for a single view of what could/should have been one somewhat denormalied record in practice. In the early 2010's that meant the main database was often kicked over under load, and it took a lot of effort to add in appropriate caching and the search db, that wound up handling most of the load on a smaller server.
I'd argue for using LevelDB or similar if I just wanted to store arbitrary data based on a single indexable value like TFA. That said, I'd probably just default to SQLite myself since the access, backup, restore patterns are relatively well known and that you can port/grow your access via service layers that include Turso or Cloudflare D1, etc.
Embedded KV stores like LevelDB are great for what they are, but Iāve often found that Iāll need to add an index to search the data in a different way.
And then another index. And at some point you want to ensure uniqueness or some other constraint.
And then youāre rewriting a half-complete and buggy SQLite. So Iāve come around to defaulting to SQLite/PostgresQL unless I have a compelling need otherwise. Theyāre usually the right long-term choice for my needs.
Absolutely... I was just bringing it up, as it seems to have in the box support for a lot of what TFA is discussing. I'm generally more inclined to just use SQLite most of the time anyway.
That it's now in the box (node:sqlite) for Deno/TS makes it that much more of an easy button option.
I feel like someone who works for a DB company ought to mention at least some of the pitfalls in file-based backing stores (data loss due to crashes, file truncation, fsync weirdness, etc)
Not to nitpick, but it would be interesting to see profiling info of the benchmarks
Different languages and stdlib methods can often spend time doing unexpected things that makes what looks like apples-to-apples comparisons not quite equivalent
In many cases not. E.g. for caching with python, diskcache is a good choice.
For small amounts of data, a JSON file does the job (you pointed to JSONL as an option).
But for larger collections, that should be searchable/processable, postgres is a good choice.
Memory of course, as you wrote, also seems reasonable in many cases.
SRE here. My "Huh, neat" side of my brain is very interested. The SRE side of my brain is screaming "GOD NO, PLEASE NO"
Overhead in any project is understanding it and onboarding new people to it. Keeping on "mainline" path is key to lower friction here. All 3 languages have well supported ORM that supports SQLite.
Sorry, this I think is a dangerous attitude: for me it is not about onboarding. Every newcomer reading `Huh, neat` is poised to repeat the mistakes of us and our ancestors.
I'm mostly with you here... it's amazing how many devs don't have a certain amount of baseline knowledge to understand file-io, let alone thin abstractions for custom data and indexing like tfa. Then again, most devs also don't understand the impacts of database normalization under load either.
Then proceeds to (poorly) implement database on files.
Sure, Hash Map that take ~400mb in memory going to offer you fast lookups. Some workloads will never reach this size can be done as argument, but what are you losing by using SQLite?
What happens when services shutdowns mid write? Corruption that later results in (poorly) implemented WAL being added?
SQLite also showed something important - it was consistent in all benchmarks regardless of dataset size.
I need a filesystem that does some database things. We got teased with that with WinFS and Beos's BFS, but it seems the football always gets yanked away, and the mainstream of filesystems always reverts back to the APIs established in the 1980s.
Transactions are one thing I want the most, and that's not going to happen on S3. Sure, I can reinvent them by hand, but the point is I want that baked in.
Yeah, closest thing there is MS-SQL FILESTREAM, but even that has flaws and severe limitations... you can do similar transaction implemenations for binary data storage in any given RDBMS, or do similarly via behavior to read/write to filestream along with a transactional row lock that corresponds to the underlying data. But that gets its' own complexities.
Honestly, I have been thinking about the same topic for some time, and I do realize that direct files could be faster.
In my (hypothetical, 'cause I never actually sat down and wrote that) case, I wanted the personal transactions in a month, and I realized I could just keep one single file per month, and read the whole thing at once (also 'cause the application would display the whole month at once).
Filesystems can be considered a key-value (or key-document) database. The funny thing about the example used in the link is that one could simply create a structure like `user/[id]/info.json` and directly access the user ID instead of running some file to find them -- again, just 'cause the examples used, search by name would be a pain, and one point where databases would handle things better.
I avoided DBs like the plague early in my career, in favor of serialized formats on disk. I still think there's a lot of merit to that, but at this point in my career I see a lot more use case for sqlite and the relational features it comes with. At the least, I've spent a lot less time chasing down data corruption bugs since changing philosophy.
Now that said, if there's value to the "database" being human readable/editable, json is still well worth a consideration. Dealing with even sqlite is a pain in the ass when you just need to tweak or read something, especially if you're not the dev.
Pain in the ass was way too strong, I retract that. Mainly I meant relative. For example `nvim <filename>.json` and then /search for what I want, versus tracking down the sqlite file, opening, examining the schema, figuring out where the most likely place is that I care about, writing a SQL statement to query, etc.
SqliteBrowser will let you open up your tables in an Excel-type view. You can also edit directly from the GUI. Still not as frictionless as a plain text file, and I'm not sure how good the search functionality is, but it lets you skip having to write any SQL.
> Well, you still need to track down the <filename> part and knowing what you want to search, so you need to examine the schema anyway.
Yes agreed, but it's usually a lot easier to find the filename part, especially if the application follows XDG. Sqlite databases are usually buried somewhere because they aren't expected to be looked at.
In order to ask this question it's important to understand the lifecycle of the data in question. If it is constantly being updated and requires "liveness" (updates are reflected in queries immediately), the simple answer is: yes, you need a database.
But if you have data that is static or effectively static (data that is updated occasionally or batched), then serving via custom file handling can have its place.
If the records are fixed width and sorted on the key value, then it becomes trivial to do a binary search on the mmapped file. It's about as lightweight as could be asked for.
I should have been clear with the assumption baked into that statement: the data in question is in a single file, with fixed size fields and sorted by primary keys. That precludes "looser" datasets, but I believe my point stands for the given context.
I've used foreign keys and unique indexes to enforce validity on even the smallest, most disposable toy applications I've ever written. These benchmarks are really interesting, but the idea that performance is the only consideration is kind of silly.
I worked one place that shoehorned SQL Server into a system to hold a small amount of static data that could easily have been a config file or even (eek) hard-coded.
The SQLite "faster than filesystem" page is specifically about reading small blobs where the overhead of individual filesystem calls (open/read/close per blob) exceeds SQLite reading from a single already-open file. Once you're talking about reading one big JSON file sequentially, that overhead disappears and you're just doing a single read - which is basically the best case for the filesystem and the worst case for SQLite (which still has to parse its B-tree, check schemas, etc).
"Do not cite the deep magic to me witch, I was there when it was written"
If you want to do this for fun or for learning? Absolutely! I did my CS Masters thesis on SQL JOINS and tried building my own new JOIN indexing system (tl;dr: mine wasn't better). Learning is fun! Just don't recommend people build production systems like this.
Is this article trolling? It feels like trolling. I struggle to take an article seriously that conflates databases with database management systems.
A JSON file is a database. A CSV is a database. XML (shudder) is a database. PostgreSQL data files, I guess, are a database (and indexes and transaction logs).
They never actually posit a scenario in which rolling your own DBMS makes sense (the only pro is "hand rolled binary search is faster than SQLite"), and their "When you might need" a DBMS misses all the scenarios, the addition of which would cause the conclusion to round to "just start with SQLite".
It should basically be "if you have an entirely read-only system on a single server/container/whatever" then use JSON files. I won't even argue with that.
Nobody - and I mean nobody - is running a production system processing hundreds of thousands of requests per second off of a single JSON file. I mean, if req/sec is the only consideration, at that point just cache everything to flat HTML files! Node and Typescript and code at all is unnecessary complexity.
PostgreSQL (MySQL, et al) is a DBMS (DataBase Management System). It might sound pedantic but the "MS" part is the thing you're building in code:
concurrency, access controls, backups, transactions: recovery, rollback, committing, etc., ability to do aggregations, joins, indexing, arbitrary queries, etc. etc.
These are not just "nice to have" in the vast, vast majority of projects.
"The cases where you'll outgrow flat files:"
Please add "you just want to get shit done and never have to build your own database management system". Which should be just about everybody.
If your app is meaningfully successful - and I mean more than just like a vibe-coded prototype - it will break. It will break in both spectacular ways that wake you up at 2AM and it will break in subtle ways that you won't know about until you realize something terrible has happened and you lost your data.
It feels like we're throwing away 50 years of collective knowledge, skills, and experience because it "is faster" (and in the same breath note that nobody is gonna hit these req/sec.)
I know, it's really, really hard to type `yarn add sqlite3` and then `SELECT * FROM foo WHERE bar='baz'`. You're right, it's so much easier writing your own binary search and indexing logic and reordering files and query language.
Not to mention now you need a AGENTS.md that says "We use our own home-grown database nonsense if you want to query the JSON file in a different way just generate more code." - NOT using standard components that LLMs know backwards-and-forwards? Gonna have a bad time. Enjoy burning your token budget on useless, counter-productive code.
I agree. Databases are useless. You don't even need to load it into the memory. Reading it from the disk when there is a need to read something must be ok. I don't believe the case that there are billions of records so the database must be something optimized for handling it. That amount of records most likely is something like access logs etc, I think they should not be stored at all, for such case.
Even it's postgres, it is still a file on disk. If there is need something like like partitioning the data, it is much more easier to write the code that partitions the data.
If there is a need to adding something with textinputs, checkboxes etc, database with their admin tools may be a good thing. If the data is something that imported exported etc, database may be a good thing too. But still I don't believe such cases, in my ten something years of software development career, something like that never happened.
I worked as a software engineer for 30 years before being forced to use a database, and that was for a web site. I've been coding actively, daily, since the 70's. Forever we just wrote proprietary files to disk, and that was the norm, for decades. Many a new developer can't even imagine writing their own proprietary file formats, the idea literally scares them. The engineers produced today are a shadow of what they used to be.
Hmm... Sure, if you do not need a database then do not use a database.
Don't use a sports-car to haul furniture or a garbage truck as an ambulance.
For the use case and scale mentioned in the article it's obvious not to use a database.
Am I missing something? I guess many people are the using the tools they are familiar with and rarely question whether they are really applicable. Is that the message?
I think a more interesting question is whether you will need a single source of truth. If you don't you can scale on many small data sets without a database.
I will say this before I shut up with my rant: If you start with a design that scales you will have an easier to scale when it is time without re-engineering your stack. Whether you think you will need to scale depends on your projected growth and the nature of your problem (do you need a single source of truth, etc.)
You need databases if you need any kind of atomicity. Doing atomic writes is extremely fragile if you are just on top of the filesystem.
This is also why many databases have persistence issues and can easily corrupt on-disk data on crash. Rocksdb on windows is a very simple example a couple years back. It was regularly having corruption issues when doing development with it.
Honestly, at this point, if I had a design that required making atomic changes to files, I'd redo the design to use SQLite. The other way around sounds crazy to me.
"Why use spray paint when you can achieve the same effect by ejecting paint from your mouth in a uniform high-velocity mist?" If you happen to have developed that particular weird skill, by all means use it, but if you haven't, don't start now.
That probably sounds soft and lazy. I should learn to use my operating system's filesystem APIs safely. It would make me a better person. But honestly, I think that's a very niche skill these days, and you should consider if you really need it now and if you'll ever benefit from it in the future.
Also, even if you do it right, the people who inherit your code probably won't develop the same skills. They'll tell their boss it's impossibly dangerous to make any changes, and they'll replace it with a database.
Nice, so we are already covering the A of ACID. And don't get me started about what OLAP databases like DuckDB can do for out of core workloads.
For the simple case, it isn't necessarily that fragile. Write the entire database to a temp file, then after flushing, move the temp file to overwrite the old file. All Unix filesystems will ensure the move operation is atomic. Lots of "we dump a bunch of JSON to the disk" use cases could be much more stable if they just did this.
Doesn't scale at all, though - all of the data that needs to be self-consistent needs to be part of the same file, so unnecessary writes go through the roof if you're only doing small updates on a giant file. Still gotta handle locking if there is risk of a stray process messing it up. And doing this only handles part of ACID.
I mean, if your atomic unit is a single file and you can tolerate simple consistency models, flat files are perfectly fine. There are many use cases that fit here comfortably where a whole database would be overkill
At some point, don't you just end up making a low-quality, poorly-tested reinvention of SQLite by doing this and adding features?
Sometimes yes, I've seen it. It even tends to happen on NoSQL databases as well. Three times I've seen apps start on top of Dynamo DB, and then end up re-implementing relational databases at the application level anyway. Starting with postgres would have been the right answer for all three of those. Initial dev went faster, but tech debt and complexity quickly started soaking up all those gains and left a hard-to-maintain mess.
This always confuses me because we have decades of SQL and all its issues as well. Hundreds of experienced devs talking about all the issues in SQL and the quirks of queries when your data is not trivial.
One would think that for a startup of sorts, where things changes fast and are unpredictable, NoSQL is the correct answer. And when things are stable and the shape of entities are known, going for SQL becomes a natural path.
There is also cases for having both, and there is cases for graph-oriented databases or even columnar-oriented ones such as duckdb.
Seems to me, with my very limited experience of course, everything leads to same boring fundamental issue: Rarely the issue lays on infrastructure, and is mostly bad design decisions and poor domain knowledge. Realistic, how many times the bottleneck is indeed the type of database versus the quality of the code and the imlementation of the system design?
No, when things change fast and unpredictably, NoSQL is worse than when they are well-known and stable.
NoSQL gains you no speed at all in redesigning your system. Instead, you trade a few hard to do tasks in data migration into an unsurmountable mess of data inconsistency bugs that you'll never actually get into the end of.
> is mostly bad design decisions and poor domain knowledge
Yes, using NoSQL to avoid data migrations is a bad design decision. Usually created by poor general knowledge.
If the argument for NoSQL is, āwe donāt know what our schema is going to beā, stop.
Stop and go ask more questions until you have a better understanding of the problem.
Makes sense. But in this case, why NoSQL exists? What problems does it resolves and when should it be considered? I'm being naive, but fast changing environment has been one of the main advantages that I was taught from devs when it comes to NoSQL vs SQL (nosql being the choice for flexible schemas). So it is more about BASE vs ACID?
NoSQL was created to deal with scales where ACID becomes a bottleneck. It also shown itself useful for dealing with data that don't actually have an schema.
If you have either of those problems, you will know it very clearly.
Also, ironically, Postgres became one of the most scalable NoSQL bases out there, and one of the most flexible to use unstructured data too.
I think part of it is the scale in terms of the past decade and a half... The hardware and vertical scale you could get in 2010 is dramatically different than today.
A lot of the bespoke no-sql data stores really started to come to the forefront around 2010 or so. At that time, having 8 cpu cores and 10k rpm SAS spinning drives was a high end server. Today, we have well over 100 cores, with TBs of RAM and PCIe Gen 4/5 NVME storage (u.x) that is thousands of times faster and has a total cost lower than the servers from 2010 or so that your average laptop can outclass today.
You can vertically scale a traditional RDBMS like PostgreSQL to an extreme degree... Not to mention utilizing features like JSONB where you can have denormalized tables within a structured world. This makes it even harder to really justify using NoSQL/NewSQL databases. The main bottlenecks are easier to overcome if you relax normalization where necessary.
There's also the consideration of specialized databases or alternative databases where data is echo'd to for the purposes of logging, metrics or reporting. Not to mention, certain layers of appropriate caching, which can still be less complex than some multi-database approaches.
What about the microservices/serverless functions world? This was another common topic over the years, that using SQL with this type of system was not optimal, I believe the issue being the connections to the SQL database and stuff.
I think a lot of the deference to microservices/serverless is for similar reasons... you can work around some of this if you use a connection proxy, which is pretty common for PostgreSQL...
That said, I've leaned into avoiding breaking up a lot of microservices unless/until you need them... I'm also not opposed to combining CQRS style workflows if/when you do need micro services. Usually if you need them, you're either breaking off certain compute/logic workflows first where the async/queued nature lends itself to your needs. My limited experience with a heavy micro-service application combined with GraphQL was somewhat painful in that the infrastructure and orchestration weren't appropriately backed by dedicated teams leading to excess complexity and job duties for a project that would have scaled just fine in a more monolithic approach.
YMMV depending on your specific needs, of course. You can also have microservices call natural services that have better connection sharing heuristics depending again on your infrastructure and needs... I've got worker pools that mostly operate of a queue, perform heavy compute loads then interact with the same API service(s) as everything else.
It's almost always a system design issue. Outside of a few specific use cases with big data, I struggle to imagine when I'd use NoSQL, especially in an application or data analytics scenario. At the end of the data, your data should be structured in a predictable manner, and it most likely relates to other data. So just use SQL.
System design issues are a product of culture, capabilities, and prototyping speed of the dev team
Disclaimer: I work part time on the DB team.
You could also consider renting an Oracle DB. Yep! Consider some unintuitive facts:
ā¢ It can be cheaper to use Oracle than MongoDB. There are companies that have migrated away from Mongo to Oracle to save money. This idea violates some of HN's most sacred memes, but there you go. Cloud databases are things you always pay for, even if they're based on open source code.
ā¢ Oracle supports NoSQL features including the MongoDB protocol. You can use the Mongo GUI tools to view and edit your data. Starting with NoSQL is very easy as a consequence.
ā¢ But... it also has "JSON duality views". You start with a collection of JSON documents and the database not only works out your JSON schemas through data entropy analysis, but can also refactor your documents into relational tables behind the scenes whilst preserving the JSON/REST oriented view e.g. with optimistic locking using etags. Queries on JSON DVs become SQL queries that join tables behind the scenes so you get the benefits of both NoSQL and SQL worlds (i.e. updating a sub-object in one place updates it in all places cheaply).
ā¢ If your startup has viral growth you won't have db scaling issues because Oracle DBs scale horizontally, and have a bunch of other neat performance tricks like automatically adding indexes you forgot you needed, you can materialize views, there are high performance transactional message queues etc.
So you get a nice smooth scale-up and transition from ad hoc "stuff some json into the db and hope for the best" to well typed data with schemas and properly normalized forms that benefit from all the features of SQL.
Good points, but Postgres has all those, along with much better local testing story, easier and more reliable CDC, better UDFs (in Python, Go etc.), a huge ecosystem of extensions for eg. GIS data, no licencing issues ever, API compatability with DuckDB, Doris and other DBs, and (this is the big one) is not Oracle.
I generally limit Oracle to where you are in a position to have a dedicated team to the design, deployment and management of just database operations. I'm not really a fan of Oracle in general, but if you're in a position to spend upwards of $1m/yr or more for dedicated db staff, then it's probably worth considering.
Even then, PostgreSQL and even MS-SQL are often decent alternatives for most use cases.
That was true years ago but these days there's the autonomous database offering, where DB operations are almost all automated. You can rent them in the cloud and you just get the connection strings/wallet and go. Examples of stuff it automates: backups, scaling up/down, (as mentioned) adding indexes automatically, query plan A/B testing to catch bad replans, you can pin plans if you need to, rolling upgrades without downtime, automated application of security patches (if you want that), etc.
So yeah running a relational DB used to be quite high effort but it got a lot better over time.
At that point, you can say the same for PostgreSQL, which is more broadly supported across all major and minor cloud platforms with similar features and I'm assuming a lower cost and barrier of entry. This is without signing with Oracle, Inc... which tends to bring a lot of lock-in behaviors that come with those feature sets.
TBF, I haven't had to use Oracle in about a decade at this point... so I'm not sure how well it competes... My experiences with the corporate entity itself leave a lot to be desired, let alone just getting setup/started with local connectivity has always been what I considered extremely painful vs common alternatives. MS-SQL was always really nice to get setup, but more recently has had a lot of difficulties, in particular with docker/dev instances and more under arm (mac) than alternatives.
I'm a pretty big fan of PG, which is, again, very widely available and supported.
Autonomous DB can run on-premises or in any cloud, not just Oracle's cloud. So it's not quite the same.
I think PG doesn't have most of the features I named, I'm pretty sure it doesn't have integrated queues for example (SELECT FOR UPDATE SKIP LOCKED isn't an MQ system), but also, bear in mind the "postgres" cloud vendors sell is often not actually Postgres. They've forked it and are exploiting the weak trademark protection, so people can end up more locked in than they think. In the past one cloud even shipped a transaction isolation bug in something they were calling managed Postgres, that didn't exist upstream! So then you're stuck with both a single DB and a single cloud.
Local dev is the same as other DBs:
See https://container-registry.oracle.comWorks on Intel and ARM. I develop on an ARM Mac without issue. It starts up in a few seconds.
Cost isn't necessarily much lower. At one point I specced out a DB equivalent to what a managed Postgres would cost for OpenAI's reported workload:
> I knocked up an estimate using Azure's pricing calculator and the numbers they provide, assuming 5TB of data (under-estimate) and HA option. Even with a 1 year reservation @40% discount they'd be paying (list price) around $350k/month. For that amount you can rent a dedicated Oracle/ExaData cluster with 192 cores! That's got all kinds of fancy hardware optimizations like a dedicated intra-cluster replication network, RDMA between nodes, predicate pushdown etc. It's going to perform better, and have way more features that would relieve their operational headache.
In the spirit of helpfulness (not pedantry) FYI "knocked up" means "impregnated". Maybe "put together"?
Ah, this must be a British vs American English thing, thanks for the info.
Yes I meant it in this sense: "If you knock something up, you make it or build it very quickly, using whatever materials are available."
https://www.collinsdictionary.com/dictionary/english/knock-u...
And, again... most of my issues are with Oracle, Inc. So technical advantages are less of a consideration.
If you have an option, never ever use Oracle!
Never!
I wanted to hate you for suggesting Oracle, but you defend it well! I had no idea
There's plenty of middle ground between an unchanging SQL schema and the implicit schemas of "schemaless" databases. You can have completely fluid schemas with the full power of relational algebra (e.g. untyped datalog). You shouldn't be using NoSQL just because you want to easily change schemas.
I've never used DynamoDB in production, but it always struck me as the type of thing where you'd want to start with a typical relational database, and only transition the critical read/write paths when you get to massive scale and have a very good understanding of your data access patterns.
Same. DynamoDB is almost never a good default choice unless you've thought very carefully about your current and future use cases. That's not to say it's always bad! At previous startups we did some amazing things with Dynamo.
As soon as you need to do a JOIN, you're either rewriting a database or replatforming on Sqlite.
Here are two checks using joins, one with sqlite, one with the join builtin of ksh93:
a) Just heard today: JOINs are bad for performance b) How many columns can (an Excel) table have: no need for JOINs
Based on what's in the article, it wouldn't take much to move these files to SQLite or any other database in the future.
Edit: I just submitted a link to Joe Armstrong's Minimum Viable Programs article from 2014. If the response to my comment is about the enterprise and imaginary scaling problems, realize that those situations don't apply to some programming problems.
> Based on what's in the article, it wouldn't take much to move these files to SQLite or any other database in the future.
Why waste time screwing around with ad-hoc file reads, then?
I mean, what exactly are you buying by rolling your own?
You can avoid the overhead of working with the database. If you want to work with json data and prefer the advantages of text files, this solution will be better when you're starting out. I'm not going to argue in favor of a particular solution because that depends on what you're doing. One could turn the question around and ask what's special about SQLite.
If your language supports it, what is the overhead of working with SQLite?
What's special about SQLite is that it already solves most of the things you need for data persistence without adding the same kind of overhead or trade offs as Postgres or other persistence layers, and that it saves you from solving those problems yourself in your json text files...
Like by all means don't use SQLite in every project. I have projects where I just use files on the disk too. But it's kinda inane to pretend it's some kind of burdensome tool that adds so much overhead it's not worth it.
> what's special about SQLite
Battle-tested, extremely performant, easier to use than a homegrown alternative?
By all means, hack around and make your own pseudo-database file system. Sounds like a fun weekend project. It doesn't sound easier or better or less costly than using SQLite in a production app though.
So you trade the overhead of SQL with the overhead of JSON?
> You can avoid the overhead of working with the database.
What overhead?
SQLite is literally more performant than fread/fwrite.
That's exactly what I was going to say. This seems more like a neat "look Ma, no database!" hobby project than an actual production recommendation.
Probably more like a low-quality, poorly-tested reinvention of BerkeleyDB.
im sure, but honestly, i would love to have a db engine that just writes/reads csv or json. does it exist?
DuckDB can do exactly this, once you get the API working in your system, it becomes something simple like
Writing generally involves reading to an in-memory database, making whatever changes you want, then something likeI wrote a CSV DB engine once! I can't remember why. For fun?
Reminds me of the infamous Robert Virding quote:
āVirding's First Rule of Programming: Any sufficiently complicated concurrent program in another language contains an ad hoc informally-specified bug-ridden slow implementation of half of Erlang.ā
In case you weren't aware, that in itself is riffing on Greenspun's tenth rule:
https://en.wikipedia.org/wiki/Greenspun%27s_tenth_rule
āYou Arenāt Gonna Need Itā - one of the most important software principles.
Wait until you actually need it.
I interpret YAGNI to mean that you shouldn't invest extra work and extra code complexity to create capabilities that you don't need.
In this case, I feel like using the filesystem directly is the opposite: doing much more difficult programming and creating more complex code, in order to do less.
It depends on how you weigh the cost of the additional dependency that lets you write simpler code, of course, but I think in this case adding a SQLite dependency is a lower long-term maintenance burden than writing code to make atomic file writes.
The original post isn't about simplicity, though. It's about performance. They claim they achieved better performance by using the filesystem directly, which could (if they really need the extra performance) justify the extra challenge and code complexity.
Is this what we do with education in general?
100%.
Premature optimisation I believe that's called.
I've seen it play out many times in engineering over the years.
Only if you get there and need it.
but it's so trivial to implement SQLite, in almost any app or language...there are sufficient ORMs to do the joins if you don't like working with SQL directly...the B-trees are built in and you don't need to reason about binary search, and your app doesn't have 300% test coverage with fuzzing like SQLite does
you should be squashing bugs related to your business logic, not core data storage. Local data storage on your one horizontally-scaling box is a solved problem using SQLite. Not to mention atomic backups?
Honestly, there is zero chance you will implement anything close to sqlite.
What is more likely, if you are making good decisions, is that you'll reach a point where the simple approach will fail to meet your needs. If you use the same attitude again and choose the simplest solution based on your _need_, you'll have concrete knowledge and constraints that you can redesign for.
Sqlite is also the only major database to receive DO-178B certification, which allows Sqlite to legally operate in avionic environments and roles.
Came here to also throw in a vote for it being so much easier to just use SQLite. You get so much for so very little. There might be a one-time up-front learning effort for tweaking settings, but that is a lot less effort than what you're going to spend on fiddling with stupid issues with data files all day, every day, for the rest of the life of your project.
Even then... I'd argue for at least LevelDB over raw jsonl files... and I say this as someone who would regularly do ETL and backups to jsonl file formats in prior jobs.
> and your app doesn't have 300% test coverage with fuzzing like SQLite does
Surely it does? Otherwise you cannot trust the interface point with SQLite and you're no further ahead. SQLite being flawless doesn't mean much if you screw things up before getting to it.
That's true but relying on a highly tested component like SQLite means that you can focus your tests on the interface and your business logic, i.e. you can test that you are persisting to the your datastore rather than testing that your datastore implementation is valid.
Your business logic tests will already, by osmosis, exercise the backing data store in every conceivable way to the fundamental extent that is possible with testing given finite time. If that's not the case, your business logic tests have cases that have been overlooked. Choosing SQLite does mean that it will also be tested for code paths that your application will never touch, but who cares about that? It makes no difference if code that is never executed is theoretically buggy.
Business logic tests will rarely test what happens to your data if a machine loses power.
Then your business logic contains unspecified behaviour. Maybe you have a business situation where power loss conditions being unspecified is perfectly acceptable, but if that is so it doesn't really matter what happens to your backing data store either.
Exactly. And most apps don't get there and therefore don't need it.
Your article completely ignores operational considerations: backups, schema changes, replication/HA. As well as security, i.e. your application has full permissions to completely destroy your data file.
Regardless of whether most apps have enough requests per second to "need" a database for performance reasons, these are extremely important topics for any app used by a real business.
I love this article as it shows how fast computers really are.
There is one conclusion that I do not agree with. Near the end, the author lists cases where you will outgrow flat files. He then says that "None of these constraints apply to a lot of applications."
One of the constraints is "Multiple processes need to write at the same time." It turns out many early stage products need crons and message queues that execute on a separate worker. These multiple processes often need to write at the same time. You could finagle it so that the main server is the only one writing, but you'd introduce architectural complexity.
So while from the pure scale perspective I agree with the author, if you take a wider perspective, it's best to go with a database. And sqlite is a very sane choice.
If you need scale, cache the most often accessed data in memory and you have the best of both worlds.
My winning combo is sqlite + in-memory cache.
SQLite has become my new go-to when starting any project that needs a DB. The performance is very fast, and if anything is ever successful enough to outgrow SQLite, it wouldn't be that hard to switch it out for Postgres. Not having to maintain/backup/manage a separate database server is cheaper and easier.
Backups are super-simple as well.
I'm also a convert.
Seeing the Rust 1M benches were an amazing reminder as to how fast stuff really is.
The reality is that things will be blazing fast in any language if you save things by PK in HashMaps.
We built a PDF processing tool and faced this exact question early on.
For our use case ā merge, split, compress ā we went fully stateless. Files are processed in memory and never stored. No database needed at all.
The only time a database becomes necessary is when you need user accounts, history, or async jobs for large files. For simple tools, a database is often just added complexity.
The real question isn't "do you need a database" but "do you need state" ā and often the answer is no.
> The real question isn't "do you need a database" but "do you need state" ā and often the answer is no.
This is a solid takeaway and applies to a lot of domains. Great observation
Very interesting, I'd never heard of JSONL before: https://jsonlines.org/
Also notable mention for JSON5 which supports comments!: https://json5.org/
Writing your own storage is a great way to understand how databases work (if you do it efficiently, keeping indexes, correct data structures, etc.) and to come to the conclusion that if your intention wasn't just tinkering, you should've used a database from day 1.
Relational Databases Arenāt Dinosaurs, Theyāre Sharks. https://www.simplethread.com/relational-databases-arent-dino...
The very small bonus you get on small apps is hardly worth the time you spend redeveloping the wheel.
Sharks vs. dinosaurs seems indeed an appropriate metaphor.
During Cretaceous, when dinosaurs were at their peak, sharks had already become very similar to the sharks of today, e.g. there were big sharks that differed very little from the white sharks and tiger sharks of today.
Then the dinosaurs have disappeared, together with the pterosaurs and the mosasaurs, and they have been replaced by other animals, but the sharks have continued to live until today with little changes, because they had already reached an optimized design that was hard to improve.
Besides the sharks, during Cretaceous there already existed along the dinosaurs other 2 groups of big predators that have changed little since then, crocodiles and big constrictor snakes similar to the pythons of today.
Therefore all 3 (sharks, crocodiles and big constrictor snakes) are examples of locally optimum designs that have been reached more than 70 million years ago, without needing after that any major upgrades.
Many eons ago I wrote a small sales web application in Perl. I couldn't install anything on the ISP's machine, so I used file-backed hashes: one for users, one for orders, another for something else.
As the years went by, I expected the client to move to something better, but he just stuck with it until he died after about 20 years, the family took over and had everything redone (it now runs Wordpress).
The last time I checked, it had hundreds of thousands of orders and still had good performance. The evolution of hardware made this hack keep its performance well past what I had expected it to endure. I'm pretty sure SQLite would be just fine nowadays.
What type of product or service were they selling?
A calendar for cutting your hair according to the phases of the moon.
Sounds like a tough business. The profit margins must have been razor thin.
Jokes aside, the guy made an impressive amount of money with this.
I should have charged him a percentage. Even if I had charged 0.5%, I would have made more money.
Retail customers or B2B? What was stopping you from starting a similar business, but different product category?
> Binary search beats SQLite... For a pure ID lookup, you're paying for machinery you're not using.
You'll likely end up quite a chump if you follow this logic.
sqlite has pretty strong durability and consistency mechanism that their toy disk binary search doesn't have.
(And it is just a toy. It waves away the maintenance of the index, for god's sake, which is almost the entire issue with indexes!)
Typically, people need to change things over time as well, without losing all their data, so backwards compatibility and other aspects of flexibility that sqlite has are likely to matter too.
I think once you move beyond a single file read/written atomically, you might as well go straight to sqlite (or other db) rather than write your own really crappy db.
File systems are nice if you need to do manual or transparent script-based manipulations. Like 'oh hey, I just want to duplicate this entry and hand-modify it, and put these others in an archive.' Or use your OS's access control and network sharing easily with heterogeneous tools accessing the data from multiple machines. Or if you've got a lot of large blobs that aren't going to get modified in place.
What the world needs is a hybrid - database ACID/transaction semantics with the ability to cd/mv/cp file-like objects.
I dunno. Even in embedded systems every time I've started without a database I've eventually come to need something like a database, and in every case I've found myself building essentially an ad-hoc poorly managed database into the application including marshalling/unmarshalling, file management, notification, and so on because each new feature over the top of regular files was just that much easier to add versus switching to a database system.
However the driving motivation for adding a database is not necessarily managing data, but the fact that the database system creates a nice abstraction layer around storing data of relational or non-relational form in non-volatile memory and controlling access to it while other systems are updating it. And because it's a nice abstraction, there are a lot of existing libraries that can take advantage of it in your language of choice without requiring you to completely invent all of that stuff over the top of the filesystem. That has knock-on effects when you're trying to add new functionality or new interaction patterns to an existing system.
And in cases where two or more processes need to communicate using the same data, a database gives you some good abstractions and synchronization primitives that make sense, whereas regular files or IPC require you to invent a lot of that stuff. You could use messaging to communicate updates to data but now you have two copies of everything, and you have to somehow atomize the updates so that either copy is consistent for a point in time. Why not use a database?
Knowing what I know today I would start with some kind of database abstraction even if it's not necessarily designed for transactional data, and I would make sure it handled the numerous concerns I have around data sharing, consistency, atomicity, and notification because if I don't have those things I eventually have to invent them to solve the reliability problems I otherwise run in to without them.
I suggest every developer write a database from scratch at least once, and use it for something real. Or, even better, let somebody else use it for something real. Then you will know "why database".
My first time was with a Bukkit plugin as a kid. One of my updates broke existing flat json files. Someone asked me if it has MySQL support, I didn't know what that was, then realized oh this is nice.
There are also things besides databases that I'll DIY and then still wonder why so many people use a premade tool for it, like log4j
It's indeed an amazing design and implementation space to explore. If distributed it is nearly comprehensive in scope. (However, did lol @ your "every developer" - that's being super kind and generous or "developer" is doing heavy lifting here.)
Hm, sometimes opening a book could do wonders? But these were the old times...
I'll do one better.
I suggest every developer learn how to replicate, backup and restore the very database they are excited about, from scratch at least once. I propose this will teach them what takes to build a production ready system and gain some appreciation for other ways of managing state.
The real question - do you really need to hack around with in-memory maps and files when you could just use a database?
Please ā¦ Every few years the pendulum swings. First it was ārelational databases are too rigid, just use NoSQL.ā Then āNoSQL is a mess, just go back to Postgres.ā Now: ādo you even need a database at all, just use flat files.ā Each wave is partially right. Butā¦ each wave is about to rediscover, the hard way, exactly why the previous generation made the choices they did. SQLite is the answer to every painful lesson learned, every scar from long debug night the last time someone thought āa JSON file is basically a database.ā
Michael Stonebraker used to write long, scathing critiques of modern data storage/retrieval fads, and how they were forgetting important historical lessons.
They were terrific reads; his writing on object-oriented databases was the most fun technical reading I did in grad school. And I even learned a lot!
Yes, but you are probably a bit too polite. And I'm not sure how to do justice to SQLite, Postgres and my new favourite toy DuckDB.
people wildly underestimate the os page cache and modern nvme drives tbh. disk io today is basically ram speeds from 10 years ago. seeing startups spin up managed postgres + redis clusters + prisma on day 1 just to collect waitlist emails is peak feature vomit.
a jsonl file and a single go binary will literally outlive most startup runways.
also, the irony of a database gui company writing a post about how you dont actually need a database is pretty based.
The irony isnāt lost on us, trust me. We spent a while debating whether to even publish this one.
But yeah, the page cache point is real and massively underappreciated. Modern infrastructure discourse skips past it almost entirely. A warm NVMe-backed file with the OS doing the caching is genuinely fast enough for most early-stage products.
Definitely appreciate the post and the discussion that has come from it... While I'm still included to just reach for SQLite as a near starting point, it's often worth considering depending on your needs.
In practice, I almost always separate the auth chain from the service chain(s) in that if auth gets kicked over under a DDoS, at least already authenticated users stand a chance of still being able to use the apps. I've also designed auth system essentially abstracted to key/value storage with adapters for differing databases (including SQLite) for deployments...
Would be interested to see how LevelDB might perform for your testing case, in that it seems to be a decent option for how your example is using data.
props for actually publishing it tbh. transparent engineering takes are so rare now, usually its just seo fluff.
weve basically been brainwashed to think we need kubernetes and 3 different databases just to serve a few thousand users. gotta burn those startup cloud credits somehow i guess.
mad respect for the honesty though, actually makes me want to check out db pro when i finally outgrow my flat files.
I'm feel like I could write another post: Do you even need serverless/Cloud because we've also been brainwashed into thinking we need to spend hundreds/thousands a month on AWS when a tiny VPS will do.
Similar sentiment.
You are both right, with the exception that it requires knowledge and taste to accomplish, both of which are in short supply in the industry.
Why setup a go binary and a json file? Just use google forms and move on, or pay someone for a dead simple form system so you can capture and commmunicate with customers.
People want to do the things that make them feel good - writing code to fit in just the right size, spending money to make themselves look cool, getting "the right setup for the future so we can scale to all the users in the world!" - most people don't consider the business case.
What they "need" is an interesting one because it requires a forecast of what the actual work to be done in the future is, and usually the head of any department pretends they do that when in reality they mostly manage a shared delusion about how great everything is going to go until reality hits.
I have worked for companies getting billions of hits a month and ones that I had to get the founder to admit there's maybe 10k users on earth for the product, and neither of them was good at planning based on "what they need".
Serverless is cheap as hell as low volumes. Your tiny VPS can't scale to zero. If you're doing sustained traffic your tiny VPS might win though. The real value in Cloud is turning capex spend into opex spend. You don't have to wait weeks or months to requisition equipment.
> weve basically been brainwashed to think we need kubernetes and 3 different databases just to serve a few thousand users. gotta burn those startup cloud credits somehow i guess.
I don't think it makes any sense to presume everyone around you is brainwashed and you are the only soul cursed with reasoning powers. Might it be possible that "we" are actually able to analyse tradeoffs and understand the value of, say, have complete control over deployments with out of the box support for things like deployment history, observability, rollback control, and infrastructure as code?
Or is it brainwashing?
Let's put your claim to the test. If you believe only brainwashed people could see value in things like SQLite or Kubernetes, what do you believe are reasonable choices for production environments?
Except that eventually you'll find you lose a write when things go down because the page cache is write behind. So you start issuing fsync calls. Then one day you'll find yourself with a WAL and buffer pool wondering why you didn't just start with sqlite instead.
> seeing startups spin up managed postgres + redis clusters + prisma on day 1 just to collect waitlist emails is peak feature vomit.
I'm pretty sure most startups just use a quick and easy CRM that makes this process easy, and that tool will certainly use a database.
Don't know if it counts, but my London cinema listings website just uses static json files that I upload every weekend. All of the searching and stuff is done client side. Although I do use sqlite to create the files locally.
Total hosting costs are Ā£0 ($0) other than the domain name.
A few months back I decided to write an embedded db for my firm's internal JS framework. Learned a lot about how/why databases work the way they do. I use stuff like reading memory cached markdown files for static sites, but there are certain things that a database gives you (chief of which for me was query ergonomicsāI loved MongoDB's query language but grew too frustrated with the actual runtime) that you'll miss once you move past a trivial data set.
I think a better way to ask this question is "does this application and its constraints necessitate a database? And if so, which database is the correct tool for this context?"
For me, I just wish MongoDB had scaling options closer to how Elatic/Cassandra and other horizontally scalable databases work, in that the data is sharded in a circle with redundancy metrics... as opposed to Mongo, which afaik is still limited to either sharding or replication (or layers of them). FWIW, I wish that RethinkDB had seen more attention and success and for that matter might be more included to use CockroachDB over Mongo, where I can get some of the scaling features while still being able to have some level of structured data.
Separate from performance, I feel like databases are a sub-specialty that has its own cognitive load.
I can use databases just fine, but will never be able to make wise decisions about table layouts, ORMs, migrations, backups, scaling.
I don't understand the culture of "oh we need to use this tool because that's what professionals use" when the team doesn't have the knowledge or discipline to do it right and the scale doesn't justify the complexity.
Hm, I somewhat understand your point of `making wise decisions`. But doesn't that concern all kinds of software development? For me, it does.
I'm so old I remember working on databases that were designed to use RAW, not files. I'm betting some databases still do, but probably only for mainframe systems nowadays.
https://docs.oracle.com/cd/B16276_01/doc/win.102/b14305/arch...
> OracleĀ® Database Platform Guide 10g Release 2 (10.2) for Microsoft Windows Itanium (64-Bit)
Well, I guess that at least confirms Oracle on Itanium (!?) still supported RAW 5 years ago.
I'm guessing everyone's on ASM by now though, if they're still upgrading. I ran into a company not long ago with a huge oracle cluster that still employed physical database admins and logical database admins as separate roles...I would bet they're still paying millions for an out of date version of Oracle and using RAW.
I'm a big fan of using S3 as a database. A lot of apps can get a lot of mileage just doing that for a good chunk of their data; that which just needs lookup by a single field (usually ID, but doesn't have to be).
I worked in an org where a lot of records were denormalized to be used in a search database... since I went through that level of work anyway, I also fed the exports into S3 records for a "just in case" backup. That backup path became really useful in practice, since there was a need for eventually a "pending" version of records, separate from the "published" version.
In practice, the records themselves took no less than 30 joins for a flat view of the record data that was needed for a single view of what could/should have been one somewhat denormalied record in practice. In the early 2010's that meant the main database was often kicked over under load, and it took a lot of effort to add in appropriate caching and the search db, that wound up handling most of the load on a smaller server.
I'd argue for using LevelDB or similar if I just wanted to store arbitrary data based on a single indexable value like TFA. That said, I'd probably just default to SQLite myself since the access, backup, restore patterns are relatively well known and that you can port/grow your access via service layers that include Turso or Cloudflare D1, etc.
Embedded KV stores like LevelDB are great for what they are, but Iāve often found that Iāll need to add an index to search the data in a different way.
And then another index. And at some point you want to ensure uniqueness or some other constraint.
And then youāre rewriting a half-complete and buggy SQLite. So Iāve come around to defaulting to SQLite/PostgresQL unless I have a compelling need otherwise. Theyāre usually the right long-term choice for my needs.
Absolutely... I was just bringing it up, as it seems to have in the box support for a lot of what TFA is discussing. I'm generally more inclined to just use SQLite most of the time anyway.
That it's now in the box (node:sqlite) for Deno/TS makes it that much more of an easy button option.
I feel like someone who works for a DB company ought to mention at least some of the pitfalls in file-based backing stores (data loss due to crashes, file truncation, fsync weirdness, etc)
Pretty sure the origin should be `dbunpro.app`, no? I'd think the consensus should be: do you even need the file system?
My recent project - a replacement for CodeMaster's RaceNet, runs on flat files! https://dirtforever.net/
Just have to use locks to be careful with writes.
I figured I'd migrate it to a database after maybe 10k users or so.
And crashes you can exclude? Good luck!
The security level is the same actually as the codemasters servers.
Neat, what happened to the original system? Last I checked multiplayer was working in DR2.
EA is shutting down Clubs. That is the primary motivation here.
Sadly no solution for non-rooted consoles.
The "database" in this article is a read-only KV store. Still the benchmarks are interesting.
If you think files are easier than a database, check out https://danluu.com/file-consistency/
Not to nitpick, but it would be interesting to see profiling info of the benchmarks
Different languages and stdlib methods can often spend time doing unexpected things that makes what looks like apples-to-apples comparisons not quite equivalent
In many cases not. E.g. for caching with python, diskcache is a good choice. For small amounts of data, a JSON file does the job (you pointed to JSONL as an option). But for larger collections, that should be searchable/processable, postgres is a good choice.
Memory of course, as you wrote, also seems reasonable in many cases.
> Every database you have ever used reads and writes to the filesystem, exactly like your code does when it calls open().
Nope. There are non-persistent in-memory databases too.
In fact, a database can be a plethora of things and the stuff they were building is just a subset of a subset (persistent, local relational database)
SRE here. My "Huh, neat" side of my brain is very interested. The SRE side of my brain is screaming "GOD NO, PLEASE NO"
Overhead in any project is understanding it and onboarding new people to it. Keeping on "mainline" path is key to lower friction here. All 3 languages have well supported ORM that supports SQLite.
Sorry, this I think is a dangerous attitude: for me it is not about onboarding. Every newcomer reading `Huh, neat` is poised to repeat the mistakes of us and our ancestors.
I'm mostly with you here... it's amazing how many devs don't have a certain amount of baseline knowledge to understand file-io, let alone thin abstractions for custom data and indexing like tfa. Then again, most devs also don't understand the impacts of database normalization under load either.
> Do you even need a database?
Then proceeds to (poorly) implement database on files.
Sure, Hash Map that take ~400mb in memory going to offer you fast lookups. Some workloads will never reach this size can be done as argument, but what are you losing by using SQLite?
What happens when services shutdowns mid write? Corruption that later results in (poorly) implemented WAL being added?
SQLite also showed something important - it was consistent in all benchmarks regardless of dataset size.
I need a filesystem that does some database things. We got teased with that with WinFS and Beos's BFS, but it seems the football always gets yanked away, and the mainstream of filesystems always reverts back to the APIs established in the 1980s.
FWIW, you can do some things like this on top of S3 Metadata.
Transactions are one thing I want the most, and that's not going to happen on S3. Sure, I can reinvent them by hand, but the point is I want that baked in.
Yeah, closest thing there is MS-SQL FILESTREAM, but even that has flaws and severe limitations... you can do similar transaction implemenations for binary data storage in any given RDBMS, or do similarly via behavior to read/write to filestream along with a transactional row lock that corresponds to the underlying data. But that gets its' own complexities.
If the cloud is just someone elseās hard disks (etc) then RDBMS is just someone elseās btree
>So the question is not whether to use files. You're always using files. The question is whether to use a database's files or your own.
It's the opposite. A file system is a database. And databases can recursively store their data within another database.
This is a great incredibly well written piece. Nice work showing under the hood build up of how a db works. It makes you think.
About what?
everyone thinks this is a great idea until they learn about file descriptor limits the hard way
Honestly, I have been thinking about the same topic for some time, and I do realize that direct files could be faster.
In my (hypothetical, 'cause I never actually sat down and wrote that) case, I wanted the personal transactions in a month, and I realized I could just keep one single file per month, and read the whole thing at once (also 'cause the application would display the whole month at once).
Filesystems can be considered a key-value (or key-document) database. The funny thing about the example used in the link is that one could simply create a structure like `user/[id]/info.json` and directly access the user ID instead of running some file to find them -- again, just 'cause the examples used, search by name would be a pain, and one point where databases would handle things better.
I have found that SQLite can be faster than using text or binary files, confirming their claims here: https://sqlite.org/fasterthanfs.html
I avoided DBs like the plague early in my career, in favor of serialized formats on disk. I still think there's a lot of merit to that, but at this point in my career I see a lot more use case for sqlite and the relational features it comes with. At the least, I've spent a lot less time chasing down data corruption bugs since changing philosophy.
Now that said, if there's value to the "database" being human readable/editable, json is still well worth a consideration. Dealing with even sqlite is a pain in the ass when you just need to tweak or read something, especially if you're not the dev.
> Dealing with even sqlite is a pain in the ass when you just need to tweak or read something, especially if you're not the dev.
How? With SQL is super easy to search, compare, and update data. That's what itās built for.
Pain in the ass was way too strong, I retract that. Mainly I meant relative. For example `nvim <filename>.json` and then /search for what I want, versus tracking down the sqlite file, opening, examining the schema, figuring out where the most likely place is that I care about, writing a SQL statement to query, etc.
There is Antares SQL which is an Electron-based GUI for opening databases. It has support for all the major databases except MongoDB.
SqliteBrowser will let you open up your tables in an Excel-type view. You can also edit directly from the GUI. Still not as frictionless as a plain text file, and I'm not sure how good the search functionality is, but it lets you skip having to write any SQL.
Well, you still need to track down the <filename> part and knowing what you want to search, so you need to examine the schema anyway.
However, if your all application state can be represented in a single json file of less than a dozen MB, yes, a database can be overkill.
> Well, you still need to track down the <filename> part and knowing what you want to search, so you need to examine the schema anyway.
Yes agreed, but it's usually a lot easier to find the filename part, especially if the application follows XDG. Sqlite databases are usually buried somewhere because they aren't expected to be looked at.
In order to ask this question it's important to understand the lifecycle of the data in question. If it is constantly being updated and requires "liveness" (updates are reflected in queries immediately), the simple answer is: yes, you need a database.
But if you have data that is static or effectively static (data that is updated occasionally or batched), then serving via custom file handling can have its place.
If the records are fixed width and sorted on the key value, then it becomes trivial to do a binary search on the mmapped file. It's about as lightweight as could be asked for.
But then you'll get two files to join?
I should have been clear with the assumption baked into that statement: the data in question is in a single file, with fixed size fields and sorted by primary keys. That precludes "looser" datasets, but I believe my point stands for the given context.
Sounds like a good way to waste the only scarce resource: time.
I've just built myself a useful tool which now really would benefit from a database and I'm deeply regretting not doing that from the get-go.
So my opinion has thoroughly shifted to "start with a database, and if you _really_ don't need one it'll be obvious.
But you probably do.
I've used foreign keys and unique indexes to enforce validity on even the smallest, most disposable toy applications I've ever written. These benchmarks are really interesting, but the idea that performance is the only consideration is kind of silly.
I tried doing this with csv files (and for an online solution, Google Sheets)
I ended up just buying a VPS, putting openclaw on it, and letting it Postgres my app.
I feel like this article is outdated since the invention of OpenClaw/Claude Opus level AI Agents. The difficulty is no longer programming.
Isn't this the same case the NoSQL movement made.
I worked one place that shoehorned SQL Server into a system to hold a small amount of static data that could easily have been a config file or even (eek) hard-coded.
I think so, yea.
Surprised to see this beating SQLite after previously reading https://sqlite.org/fasterthanfs.html
The SQLite "faster than filesystem" page is specifically about reading small blobs where the overhead of individual filesystem calls (open/read/close per blob) exceeds SQLite reading from a single already-open file. Once you're talking about reading one big JSON file sequentially, that overhead disappears and you're just doing a single read - which is basically the best case for the filesystem and the worst case for SQLite (which still has to parse its B-tree, check schemas, etc).
"Do not cite the deep magic to me witch, I was there when it was written"
If you want to do this for fun or for learning? Absolutely! I did my CS Masters thesis on SQL JOINS and tried building my own new JOIN indexing system (tl;dr: mine wasn't better). Learning is fun! Just don't recommend people build production systems like this.
Is this article trolling? It feels like trolling. I struggle to take an article seriously that conflates databases with database management systems.
A JSON file is a database. A CSV is a database. XML (shudder) is a database. PostgreSQL data files, I guess, are a database (and indexes and transaction logs).
They never actually posit a scenario in which rolling your own DBMS makes sense (the only pro is "hand rolled binary search is faster than SQLite"), and their "When you might need" a DBMS misses all the scenarios, the addition of which would cause the conclusion to round to "just start with SQLite".
It should basically be "if you have an entirely read-only system on a single server/container/whatever" then use JSON files. I won't even argue with that.
Nobody - and I mean nobody - is running a production system processing hundreds of thousands of requests per second off of a single JSON file. I mean, if req/sec is the only consideration, at that point just cache everything to flat HTML files! Node and Typescript and code at all is unnecessary complexity.
PostgreSQL (MySQL, et al) is a DBMS (DataBase Management System). It might sound pedantic but the "MS" part is the thing you're building in code:
concurrency, access controls, backups, transactions: recovery, rollback, committing, etc., ability to do aggregations, joins, indexing, arbitrary queries, etc. etc.
These are not just "nice to have" in the vast, vast majority of projects.
"The cases where you'll outgrow flat files:"
Please add "you just want to get shit done and never have to build your own database management system". Which should be just about everybody.
If your app is meaningfully successful - and I mean more than just like a vibe-coded prototype - it will break. It will break in both spectacular ways that wake you up at 2AM and it will break in subtle ways that you won't know about until you realize something terrible has happened and you lost your data.
Didn't we just have this discussion like yesterday (https://ultrathink.art/blog/sqlite-in-production-lessons)?
It feels like we're throwing away 50 years of collective knowledge, skills, and experience because it "is faster" (and in the same breath note that nobody is gonna hit these req/sec.)
I know, it's really, really hard to type `yarn add sqlite3` and then `SELECT * FROM foo WHERE bar='baz'`. You're right, it's so much easier writing your own binary search and indexing logic and reordering files and query language.
Not to mention now you need a AGENTS.md that says "We use our own home-grown database nonsense if you want to query the JSON file in a different way just generate more code." - NOT using standard components that LLMs know backwards-and-forwards? Gonna have a bad time. Enjoy burning your token budget on useless, counter-productive code.
This is madness.
I agree. Databases are useless. You don't even need to load it into the memory. Reading it from the disk when there is a need to read something must be ok. I don't believe the case that there are billions of records so the database must be something optimized for handling it. That amount of records most likely is something like access logs etc, I think they should not be stored at all, for such case.
Even it's postgres, it is still a file on disk. If there is need something like like partitioning the data, it is much more easier to write the code that partitions the data.
If there is a need to adding something with textinputs, checkboxes etc, database with their admin tools may be a good thing. If the data is something that imported exported etc, database may be a good thing too. But still I don't believe such cases, in my ten something years of software development career, something like that never happened.
Poeās law in action?
Not sure if sarcasticā¦
I worked as a software engineer for 30 years before being forced to use a database, and that was for a web site. I've been coding actively, daily, since the 70's. Forever we just wrote proprietary files to disk, and that was the norm, for decades. Many a new developer can't even imagine writing their own proprietary file formats, the idea literally scares them. The engineers produced today are a shadow of what they used to be.
Yeah, it scares me because I'm experienced enough to know all the difficulties involved in keeping durable data consistent, correct, and performant
> we just wrote proprietary files to disk
That alone is a terrible thing. Open formats are so much more user friendly
>The engineers produced today are a shadow of what they used to be.
ā¦and it wonāt get better anytime soon.
Hmm... Sure, if you do not need a database then do not use a database.
Don't use a sports-car to haul furniture or a garbage truck as an ambulance. For the use case and scale mentioned in the article it's obvious not to use a database.
Am I missing something? I guess many people are the using the tools they are familiar with and rarely question whether they are really applicable. Is that the message?
I think a more interesting question is whether you will need a single source of truth. If you don't you can scale on many small data sets without a database.
I will say this before I shut up with my rant: If you start with a design that scales you will have an easier to scale when it is time without re-engineering your stack. Whether you think you will need to scale depends on your projected growth and the nature of your problem (do you need a single source of truth, etc.)
Edits: Spelling