Yeah, it's harder to work on, or maybe just different, but I guess the docs, info(searchable docs, posts, experience), and tooling are lacking.
What's the story for version control, debugging, testing, releasing? It'd be cool to have everything together for data locality and simplifying the stack, but it feels you'd lose a lot of useful knowledge about how to do stuff "properly".
Contributor here. Good points, we do need to develop some best practices around managing function versioning and lifecycle for pg_durable.
https://github.com/microsoft/duroxide - also OSS, the durable execution framework pg_durable is built on itself supports function versions. We can leverage that to get similar support in pg_durable.
+1 on "prefer my queue logic to be in code". The <shape> of my data doesn't change nearly as much as the actions I need to take on it; it doesn't make sense to me why I'd want to do a migration (which is an all or nothing op btw) every time I want to change how I behave with my data. This is also why I absolutely abhorred having to make postgres functions to do anything remotely non-trivial on Supabase.
That said, we did hand-build a simple job queue (just lock, poll, reserve on a column, poll and update reservation to mark job done) on top of postgres at my previous startup. Something like pgque would have made that much more polished.
You're not wrong, I've been a big postgres fanboy since version 7, and have tried to build stuff in PG to the greatest degree possible in experiments, and my experience is that at a minimum, the DX/observability isn't there. The multi-master scaling story isn't turnkey or bulletproof either, so I'm hesitant to do any fancy write-bound things that hasten the need to scale the database.
> As an ex-app engineer though, I kind of prefer my queue logic to be in code, in Git, but maybe with the right tooling, you can change my mind. :)
I mean, we used to keep our SQL code in git too for projects where we had DB triggers. I think some were even shoved in there via Django migrations just to let someone setup locally and have the triggers available in their local database.
If you have triggers I don't see why you wouldn't put them in a migration. That addresses one of the most problematic aspects of triggers (invisibility, no version tracking, etc) without reducing their usefulness.
With some cleverness you could even introduce some testing that way. Not perfect but better than nothing.
Durable execution was one of my most worth investing techniques 2024, and glad to see it's blooming in 2026. The idea behind it is pretty simple: persistent state machines, auto or semi-auto context capture, and a run engine, but it actually solves many common headaches like exactly once execution with retry, signal based workflow and so on.
If understanding correctly, Absurd (by the Pi LLM harness devs) minimizes the pure db approach as much as possible. I only just started getting into the topic myself, though.
Contributor here - at Microsoft we've built AI workflows on pg_durable and seen it substantially reduce code and increase reliability. Agree that the DSL ergonomics can be improved. Our pipelines use a higher level language and therefore simplified, but pg_durable is meant to solve a wider array of problems. We're happy to take suggestions for improvements.
Somebody else in the thread brought up the benefit of snapshotting a database at a point in time stores not only the state of execution but also the code, etc. That is a unique benefit I'd be interested in exploring over storing your orchestration outside of the database.
Not trying to dismiss the project - it looks like a lot of hard work has gone in and somebody has a use for it. I just come from an airflow style external orchestrator frame of mind that manages durability state in postgres but keeps the control flow out. Sorry if I came off as a bit snarky
Without reading any of the doco, it appears to be a job definition called invoice-approval-pipeline that runs every 5 seconds.
The steps are:
1. Get all the pending invoices
2. Set their state to "processing"
3. Call out to an external service/process to do the actual processing, wait for a response.
4. If the response is OK, do something
5. Wait 5 seconds and then start again.
Not sure I love the syntax and the way SQL is embedded between the $$
But it is in the database, can be updated and modified in the same way as all the other stored procedures/functions, allows job control, I assume other control structures for parallel steps etc.
"dollar quoting" is the PostgreSQL way to quote strings with quotes, avoiding double quoting or escape characters. I like to use the tagged version of it, like $sql$ SELECT ... $sql$ to describe what is inside.
ParadeDB is AGPL so not generally available on the hyperscalars. However, you can use https://github.com/timescale/pg_textsearch on Azure HorizonDB (and likely soon Flex). Disclosure: I'm the pg_textsearch maintainer and now at Azure.
I didn't quite follow your comment about vector support, are you asking for something beyond what pgvector + diskann provide (both available on Azure)?
Never ever use Azure Cosmos DB. The entire point is to lock you in. This isn’t some paranoid shit either. We use azure a lot, and I have worked with many people designing systems on Azure. Always avoid cloud providers lock in services. That’s their bread and butter. They want you to use them. They want you using Azure Cosmos DB, Azure Event Hubs, Azure Apps, Azure DataLake, etc. Same with AWS. Don’t be naive. Use Azure VMs, Azure Postgres, Azure Redis. Those are fine. You’re just paying someone for the operational cost of a service, but you can migrate of. There is no migration from Cosmos or DataLake. They tell you you can abstract your code, but that never works. They know you will be locked in. That’s the entire business model. Also resist the temptation of the offers they’ll through at you to link those services with all their other crap. Don’t be naive.
I’m not sure why you’re getting downvoted because CosmosDB doesn’t even have a local install edition. Conversely the cloud hosted offering is slower than cold molasses and costs most of your body parts… per month.
You could. But then you’re also building from scratch HA failover, backups, replica management, monitoring, etc - cloud vendor managed RDBMS come with lots of niceties. All of which are possible to set yourself. But a hassle, and difficult to make bullet proof.
Hey! I'm a PM on the Azure PG team and work on AI features on Postgres. Wanted to address your points directly because we actually ship the capabilities you're asking about, we have made ALOT of progress in the last 3-6 months:
Hybrid search (BM25 + vector): Worth noting that ParadeDB's pg_search isn't an AWS-native feature either, you'd need to self-host it on EC2. On Azure PostgreSQL, we built pg_textsearch which provides the same BM25 ranking model (term frequency saturation, document-length normalization, IDF) natively. Fun fact, the main contributor of pg_textsearch is now on the Azure Postgres team :)
High-dimensional vectors: This is actually an area where we're ahead. pgvector with HNSW caps at 2,000 dimensions. We support pgvector for vector storage and search, and for high-dimensional / large-scale workloads we ship pg_diskann — Microsoft's graph-based vector index that supports up to 16,000 dimensions and also does advanced in-index filtering (your WHERE clauses get evaluated during graph traversal, so you don't lose recall on selective predicates).
These are available today on Azure PostgreSQL, specifically Azure HorizonDB (Preview). Happy to dig into specifics if you have a particular workload in mind.
This smells like stored procedures. You can’t unit test it. You can’t version it. Business logic in the database, (hidden brain problem), harder to isolate noisy workloads, no observability, scaling pressure lands solely in Postgres, lack of IO, especially API calls.
Good for local database only jobs though. Niche use cases.
> This smells like stored procedures. You can’t unit test it. You can’t version it
Say what? Stored procedures are awesome when used correctly.
Versioning is straightforward. You stick any sort of monotonically increasing id at the end of the name. Whenever you need a breaking change, you bump the id. You also leave the old version with the old id, retiring it only after it’s no longer used. You do need a real story for DB upgrades for this to work well. If your story is that someone on the team executes some random SQL migration as root, you’re gonna have a bad time.
You can unit test stored procedures in exactly the same way you could test any other SQL. You have to spin up a DB to do it. But if you can’t test your stored procedures, you’re admitting you have no way to test your SQL which is your real problem.
> Business logic in the database, (hidden brain problem)
Ok? How much you shove into your stored procedures is up to you. In my experience the real alternative to stored procedures is not zero business logic in the DB. It’s SQL code sprinkled throughout the codebase, where it’s harder to test, poorly versioned, and poorly encapsulated. And also often needlessly slow.
> harder to isolate noisy workloads
Dunno what this means
> no observability
Maybe some truth here. It is more work to inspect issues in SQL than most programming languages.
> scaling pressure lands solely in Postgres, lack of IO, especially API calls.
If stored procedures are causing IO problems and scaling issues then you are using them wrong.
Stored procedures often drastically reduce IO when used correctly and thereby improve scalability.
I was referring to network I/O. But disk I/O should be at least as good for a stored procedure and often better. It’s classic “bring the computation to the data”. Putting the computation into the DB means that use of disk caching (up to and including CPU caching) is maximized.
Pulling the data out of the DB to do computation in a higher layer cannot be more efficient in terms of any I/O unless your stored procedure is just poorly written. It might be a win if your DB is compute bound, though.
Microsoft has their own Durable Task framewor[1] for that kind of stuff, and it supports both running as a self-hosted standalone service like temporal, and running serverless on Azure Functions. It actually predated airflow, temporal, etc., IIRC.
This one seems to be more database-specific use case. The advantage is probably that you can track the exact state of the job in the database itself, rather than having to cross-reference the workflow log with the codebase and trace through it line by line to figure out what the state is. Plus I assume it's less overhead and latency, and operationally one less thing to spin up.
For one, Airflow (or anything external, for that matter) has no insight into DB load, so when devs slam 200 concurrent workers at the DB, other workloads may be impacted. In contrast, this could (I don’t think it does at this time) get near realtime feedback on performance without the RTT cost, and adjust itself accordingly.
it also feels strange to query for DB load before starting a job.. i'm not even sure how you would do it, how you would adjust a job given a load value, and what would you do if there's too much load.
A few things are not clear to me from reading through docs and examples:
df.wait_for_schedule()
How does this call work? Is it idempotent if I call it from an application? If I run it 2x with the same parameters, does it double tick? Am I invoking this manually from a query console to only do this one time? Am I running this as part of a migration script?
For this[0]:
-- Wait for human signal (5 minute timeout)
~> (df.wait_for_signal('approval', 300) |=> 'sig')
~> df.if(
$$SELECT NOT ($sig::jsonb->>'timed_out')::boolean
AND ($sig::jsonb->'data'->>'approved')::boolean$$,
Is the `timed_out` a fixed constant that is returned on timeout?
Also not immediately clear: how to handle errors/exceptions?
You are creating a durable function and starting its execution at the same time by calling df.start(<durable function definition>). This will you give you back an instance id which represents this durable function execution. You can use this to refer to this execution from this point onwards.
Within this durable function you are calling df.wait_for_signal(<signal_name>). This call is exactly once within this function instance. There are no duplicates possible. Your df.start() call might get duplicated if it times out and you re-run it, but in this case it would end up creating a different function instance.
Any 'unhandled' errors in executing SQL will fail the function instance. Its status would bubble up the exact error being raised.
Can anyone explain why I would want to use this over an orchestration tool that lives outside the DB? Read through the Readme and some of the examples, I still don't get it.
Snapshot PITR of your database means everything restores including the durable jobs at the PIT.
Don't need to synchronize the backups with anything else that is part of the same data store, good for ETL pipelines and other state machine type jobs.
If your ETL is mostly SQL anyway, then having the actual job being run on the same server helps as well.
Yes, but that doesn't have to imply that the compute part of the durable jobs framework also needs to be part of the database snapshot. You almost certainly want that defined in code anyway, if only to have a sane versioning story. So then by having it also be part of the snapshot, you've now got the problem that there are apparently two sources of truth for that bit of the code.
Contributor here. At Microsoft, our Postgres customers seem to split pretty evenly into 2 camps, those that want to do as much as they can in the database, and those that agree with your take - want to keep apps and compute outside the DB.
I bet this is correlated with how much they like/know Postgres already. When people don’t understand their database’s features, they want it to behave like something else they do understand (code). They’re leaving a lot of performance on the table by not leveraging everything their database can do.
Yup. Anymore, “we’ll handle that in code” reads to me as “I don’t understand my tools, and don’t want to learn.” Or hubris. The sheer number of times I’ve seen data integrity errors because someone didn’t think they needed a database-level constraint is too damn high.
The other one (also related) is normalization. They’ll have hundreds of millions of rows of duplicated, low-cardinality strings, because “joins are expensive,” while somehow missing the fact that the increased I/O from reduced page-packing also has a performance cost.
Yeah but the increased I/O is cheaper. It's easier to add another webserver as opposed to upgrading your db server.
And I don't think it's as simple as you make it. So where I work we use amongst other things Rails. There are places in our codebase where using joins just isn't feasable cause the database would use too much memory and let's just say N is large.
But since we use Rails we can have it query the tables apart and join the tables through the defined model. We literally save like 20 seconds in some cases because 1 HUGE query becomes 8 straightforward ones with maximum index usage.
And because we have this capability in Rails we would never use something like this, cause that would neccesate us holding two mental models and have a clear "what do we run where" directive which honestly is a PTA.
> literally save like 20 seconds in some cases because 1 HUGE query becomes 8 straightforward ones with maximum index usage.
I don’t understand how splitting a query up would have any relationship to index utilization; the planner should trivially pick up on it?
Also are you sure you’re not solving a different problem[0]? Doing joins manually being faster doesn’t smell right, except in the case of data duplication increasing total resultset size substantially
Like the cost of increased network load from not filtering through the join should outweigh anything else in the equation
Understanding and deciding to rely upon are not the same. Complexity is one of the biggest challenges in real world software systems. Keeping a subsystem’s responsibilities simple can do a lot for a system’s reliability. Most teams have extremely mature systems for managing complexity in their code - tests, CICD etc. Sure you CAN build all those things for your database too, but it’s more work. Most teams I’ve worked on choose to minimize database migrations because it’s a lot of work to make that part of the system as robust against mistakes as code is. Choosing to ignore a feature in your database is often a very rational pragmatic choice aimed at keeping complexity under control.
You can have well-integrated applicative workflows (eg: progress report on a permalink in your front end app), app-restart-proof resumable workflows, and it avoids adding an extra piece of infrastructure.
We use Postgres for that on https://transport.data.gouv.fr (Elixir app which does a fair bit of processing), and it helps.
Not familiar yet with pg_durable though, but I have used or implemented similar solutions and can relate.
Long-running jobs on Postgres are not new at all. See pg_cron for one example. At the end of the day, these workloads would be running anyway against the database, whether triggered by an external component. HTTP queries from the database have also become more popular to avoid round-trips and failure points from additional components in data or AI pipelines. But yes, whether to bring the compute to the data or vice-versa is a design choice that has a lot of contention.
Feels like perhaps yet another https://en.wikipedia.org/wiki/Inner-platform_effect that would be unnecessary if popular programming languages/virtual machines already supported determinism, metered and controllable stepwise execution and runtime state suspension, (de)serialization and resumption?
Committer here. I would love to hear more about this scenario.
Is the proposal to be able to export pg_dump formatted data on some schedule or trigger, entirely hosted in PostgreSQL and with timeouts? There are already extension that can export to blob/file storage and can be combined with pg_durable or pg_cron, so I assume the challenge is pg_dump compatible data export from SQL running in the database?
These approaches always suffer from the same issues such as synchronous single threaded code that would be trivial to parallelise in a “proper” programming language such as C#.
Looks pretty good but I wonder why they didn’t build it on pgmq? If you’re on elixir I maintain a DAG package around this (based on and compatible with pgflow.dev which is TS/Deno).
I would argue that for all but the largest tech companies you only need a single data system which is Postgres. Message brokers, analytical databases all can be built on Postgres. Unfortunately, Postgres as it's built now lacks any semblence of extensibility which makes this impossible in practice.
I would propose a rewrite of Postgres in another language like Rust, introducing a pluggable application layer on top. While ambitious in scope I think it would be helpful and even necessary.
There are 100+ popular extensions around Postgres. They have dependencies on the internal data structures of Postgres. If someone spends the time to rewrite Postgres on Rust and it doesn't support these extensions off the bat, then its DOA.
What I'm saying is that Postgres was built for a long gone age. We need a extensible database written in Rust which can serve as a foundation for any data system. We don't need a relic of the 1980s serving our most critical workloads.
Why does it matter it's from the 80s? You're suggesting people back then were incapable of making good decisions, and people now will make better ones?
This is a great initiative. Postgres was written in the 1980s and we can't afford to have our most utilized workloads running on a software written before most of us even existed. LLMs make it possible to rewrite Postgres and we should take that chance.
This is a pretty poor take. Sure the software that we call "PostgreSQL" started to be developed in the 80's... but they didn't stop there. PostgreSQL has been in continuous development, including improvements, changes, and additions, and by some very smart people at that. It's not static and as long as I've been a professional user of the database, decades, it has continually evolved and in some cases even led the way. If we were to survey the software, wouldn't you at least be interested to know how much of code base actually dates back to those long ago decades and how much is more modern before making such statement?
It would be a mistake to take what PostgreSQL actually offers: an excellent database that has be continuously developed and updated over many years (i.e. "maturity"), for some arbitrary idea and evidently baseless idea that somehow "new" must be better.
If new is better, say why; and do so with more actually true statements than it's not extensible. Want it in rust? Well, OK, sure you can give hand-wavy reasons about security and such for why that might be beneficial; but if you want to be convincing you need to be much more specific about the problem in PostgreSQL and the specific way in which your recommendation actually and convincingly moves the needle. If you can't do that, you're simply giving us an emotional outpouring rather than a rational one.
It’s always been possible to rewrite it; LLMs just made it possible for people who don’t understand it to do so. I personally don’t see that as a benefit, but you do you.
As to the age statement, why on earth does that matter? HAProxy launched in 2001, and despite it being 25 years old, you’ll struggle to find anything faster or more stable in its field. Then there’s, you know, Linux - 1991. I suppose you want to see it rewritten?
As an ex-app engineer though, I kind of prefer my queue logic to be in code, in Git, but maybe with the right tooling, you can change my mind. :)
[0]: https://www.dbos.dev/
[1]: https://github.com/NikolayS/pgque
What's the story for version control, debugging, testing, releasing? It'd be cool to have everything together for data locality and simplifying the stack, but it feels you'd lose a lot of useful knowledge about how to do stuff "properly".
https://github.com/microsoft/duroxide - also OSS, the durable execution framework pg_durable is built on itself supports function versions. We can leverage that to get similar support in pg_durable.
why is Azure/durabletask disabled? ':)
That said, we did hand-build a simple job queue (just lock, poll, reserve on a column, poll and update reservation to mark job done) on top of postgres at my previous startup. Something like pgque would have made that much more polished.
I mean, we used to keep our SQL code in git too for projects where we had DB triggers. I think some were even shoved in there via Django migrations just to let someone setup locally and have the triggers available in their local database.
With some cleverness you could even introduce some testing that way. Not perfect but better than nothing.
i have always had maintenance packages for this type of stuff. if i could deploy them alongside the database itself that could be kind of cool.
but yeah i agree with you that i do prefer having this in the code layer.
https://github.com/earendil-works/absurd
but I might not know all the details, I'm genuinely curious
How is this project at all comparable to something like Temporal? Am I misunderstanding the limitation implied by this particular recommendation?
It's an interesting technical achievement I guess, but it's very bizarre to try and read this
Not trying to dismiss the project - it looks like a lot of hard work has gone in and somebody has a use for it. I just come from an airflow style external orchestrator frame of mind that manages durability state in postgres but keeps the control flow out. Sorry if I came off as a bit snarky
The steps are:
1. Get all the pending invoices
2. Set their state to "processing"
3. Call out to an external service/process to do the actual processing, wait for a response.
4. If the response is OK, do something
5. Wait 5 seconds and then start again.
Not sure I love the syntax and the way SQL is embedded between the $$
But it is in the database, can be updated and modified in the same way as all the other stored procedures/functions, allows job control, I assume other control structures for parallel steps etc.
Gonna go read the doco now.
For example, you cant use this: https://www.paradedb.com/blog/hybrid-search-in-postgresql-th...
Also for example, you dont get ultra-wide high dimensionality vectors.
It is nice they are open sourcing pg_durable, but how about adopting table stakes I'd get with AWS?
I didn't quite follow your comment about vector support, are you asking for something beyond what pgvector + diskann provide (both available on Azure)?
Hybrid search (BM25 + vector): Worth noting that ParadeDB's pg_search isn't an AWS-native feature either, you'd need to self-host it on EC2. On Azure PostgreSQL, we built pg_textsearch which provides the same BM25 ranking model (term frequency saturation, document-length normalization, IDF) natively. Fun fact, the main contributor of pg_textsearch is now on the Azure Postgres team :)
Docs: https://learn.microsoft.com/en-us/azure/horizondb/ai/full-te...
High-dimensional vectors: This is actually an area where we're ahead. pgvector with HNSW caps at 2,000 dimensions. We support pgvector for vector storage and search, and for high-dimensional / large-scale workloads we ship pg_diskann — Microsoft's graph-based vector index that supports up to 16,000 dimensions and also does advanced in-index filtering (your WHERE clauses get evaluated during graph traversal, so you don't lose recall on selective predicates).
pgvector: https://learn.microsoft.com/en-us/azure/horizondb/ai/vector-...
DiskANN high-dimension support: https://learn.microsoft.com/en-us/azure/horizondb/ai/vector-...
These are available today on Azure PostgreSQL, specifically Azure HorizonDB (Preview). Happy to dig into specifics if you have a particular workload in mind.
Maybe you meant to word this differently and I’m nitpicking, but didn’t TJ Green build this while he was still at Tiger Data?
Good for local database only jobs though. Niche use cases.
Say what? Stored procedures are awesome when used correctly.
Versioning is straightforward. You stick any sort of monotonically increasing id at the end of the name. Whenever you need a breaking change, you bump the id. You also leave the old version with the old id, retiring it only after it’s no longer used. You do need a real story for DB upgrades for this to work well. If your story is that someone on the team executes some random SQL migration as root, you’re gonna have a bad time.
You can unit test stored procedures in exactly the same way you could test any other SQL. You have to spin up a DB to do it. But if you can’t test your stored procedures, you’re admitting you have no way to test your SQL which is your real problem.
> Business logic in the database, (hidden brain problem)
Ok? How much you shove into your stored procedures is up to you. In my experience the real alternative to stored procedures is not zero business logic in the DB. It’s SQL code sprinkled throughout the codebase, where it’s harder to test, poorly versioned, and poorly encapsulated. And also often needlessly slow.
> harder to isolate noisy workloads
Dunno what this means
> no observability
Maybe some truth here. It is more work to inspect issues in SQL than most programming languages.
> scaling pressure lands solely in Postgres, lack of IO, especially API calls.
If stored procedures are causing IO problems and scaling issues then you are using them wrong.
Stored procedures often drastically reduce IO when used correctly and thereby improve scalability.
Pulling the data out of the DB to do computation in a higher layer cannot be more efficient in terms of any I/O unless your stored procedure is just poorly written. It might be a win if your DB is compute bound, though.
You can certainly unit test them, good databases have telemetry and metrics.
Version control is no different from using containers instead of VMs.
Any database change goes through CI/CD pipelines and regular devs cannot edit code directly on the DB.
In fact the biggest issue with databases is like debugging, some devs rather not learn how to use them properly.
In one they never go beyond printf, in the other, they only know what an ORM looks like, and the command line applications for basic SELECTs.
Why would I want to store my control flow in the database and not in code? It feels strange.
Not trying to dismiss the project, I'm just not getting it yet I think.
This one seems to be more database-specific use case. The advantage is probably that you can track the exact state of the job in the database itself, rather than having to cross-reference the workflow log with the codebase and trace through it line by line to figure out what the state is. Plus I assume it's less overhead and latency, and operationally one less thing to spin up.
[1] https://learn.microsoft.com/en-us/azure/durable-task/common/...
Indeed Durable tasks is an exceptional project and was a unique innovation at the time.
pg_durable brings the same reliability and durablity semantics to long running operations within the database.
We have tons of interesting scenarios on the roadmap. Stay tuned! :)
ai.backfill() ignores that row-level state entirely and reprocesses everything from scratch. https://learn.microsoft.com/en-us/azure/horizondb/ai/ai-pipe...
pg_durable answers "did this workflow instance finish, and if it crashed, where do I resume?", completed/running/pending/failed per node + checkpoint replay. https://github.com/microsoft/pg_durable/blob/main/USER_GUIDE...
If you want this problem addressed better, please add an issue to the open-source repo, we would love to dig in. https://github.com/microsoft/pg_durable/issues
For this[0]:
Is the `timed_out` a fixed constant that is returned on timeout?Also not immediately clear: how to handle errors/exceptions?
[0] https://github.com/microsoft/pg_durable/blob/main/examples/i...
Within this durable function you are calling df.wait_for_signal(<signal_name>). This call is exactly once within this function instance. There are no duplicates possible. Your df.start() call might get duplicated if it times out and you re-run it, but in this case it would end up creating a different function instance.
Any 'unhandled' errors in executing SQL will fail the function instance. Its status would bubble up the exact error being raised.
Don't need to synchronize the backups with anything else that is part of the same data store, good for ETL pipelines and other state machine type jobs.
If your ETL is mostly SQL anyway, then having the actual job being run on the same server helps as well.
The other one (also related) is normalization. They’ll have hundreds of millions of rows of duplicated, low-cardinality strings, because “joins are expensive,” while somehow missing the fact that the increased I/O from reduced page-packing also has a performance cost.
And I don't think it's as simple as you make it. So where I work we use amongst other things Rails. There are places in our codebase where using joins just isn't feasable cause the database would use too much memory and let's just say N is large.
But since we use Rails we can have it query the tables apart and join the tables through the defined model. We literally save like 20 seconds in some cases because 1 HUGE query becomes 8 straightforward ones with maximum index usage.
And because we have this capability in Rails we would never use something like this, cause that would neccesate us holding two mental models and have a clear "what do we run where" directive which honestly is a PTA.
I don’t understand how splitting a query up would have any relationship to index utilization; the planner should trivially pick up on it?
Also are you sure you’re not solving a different problem[0]? Doing joins manually being faster doesn’t smell right, except in the case of data duplication increasing total resultset size substantially
Like the cost of increased network load from not filtering through the join should outweigh anything else in the equation
https://learn.microsoft.com/en-us/ef/core/querying/single-sp...
Also if all the "state" is in one database, then you have better chance of getting consistent backups.
We use Postgres for that on https://transport.data.gouv.fr (Elixir app which does a fair bit of processing), and it helps.
Not familiar yet with pg_durable though, but I have used or implemented similar solutions and can relate.
For better or worse, they “understand” and have seen a lot of message queuing code and read lots of message queue support discussions.
One would be able to trigger maintenance jobs via simple lambda functions whose duration is capped.
Is the proposal to be able to export pg_dump formatted data on some schedule or trigger, entirely hosted in PostgreSQL and with timeouts? There are already extension that can export to blob/file storage and can be combined with pg_durable or pg_cron, so I assume the challenge is pg_dump compatible data export from SQL running in the database?
What has Microsoft done to work around this?
https://github.com/agoodway/pgflow
The provider is an extensibility point. We just shipped the simplest version of it. Happy to take contribs if someone sends a pgmq based provider!
I would propose a rewrite of Postgres in another language like Rust, introducing a pluggable application layer on top. While ambitious in scope I think it would be helpful and even necessary.
PostGIS. pgvector. TimescaleDB. Citus. pg_cron. pgmq. Apache AGE. ParadeDB. hstore. plv8. postgres_fdw. pg_partman. pg_stat_statements...
The extension API is the thing making your thesis possible. Rewriting it away would mean deleting the exact feature you're asking for.
I won't be running that, though.
pgrust.
This is a pretty poor take. Sure the software that we call "PostgreSQL" started to be developed in the 80's... but they didn't stop there. PostgreSQL has been in continuous development, including improvements, changes, and additions, and by some very smart people at that. It's not static and as long as I've been a professional user of the database, decades, it has continually evolved and in some cases even led the way. If we were to survey the software, wouldn't you at least be interested to know how much of code base actually dates back to those long ago decades and how much is more modern before making such statement?
It would be a mistake to take what PostgreSQL actually offers: an excellent database that has be continuously developed and updated over many years (i.e. "maturity"), for some arbitrary idea and evidently baseless idea that somehow "new" must be better.
If new is better, say why; and do so with more actually true statements than it's not extensible. Want it in rust? Well, OK, sure you can give hand-wavy reasons about security and such for why that might be beneficial; but if you want to be convincing you need to be much more specific about the problem in PostgreSQL and the specific way in which your recommendation actually and convincingly moves the needle. If you can't do that, you're simply giving us an emotional outpouring rather than a rational one.
As to the age statement, why on earth does that matter? HAProxy launched in 2001, and despite it being 25 years old, you’ll struggle to find anything faster or more stable in its field. Then there’s, you know, Linux - 1991. I suppose you want to see it rewritten?