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I am not a database expert and have no formal computer science background, so bear with me. I want to know the kinds of real world negative things that can happen if you use MongoDB, which is not ACID compliant. This applies to any ACID noncompliant database.

I understand that MongoDB can perform Atomic Operations, but that they don't "support traditional locking and complex transactions", mostly for performance reasons. I also understand the importance of database transactions, and the example of when your database is for a bank, and you're updating several records that all need to be in sync, you want the transaction to revert back to the initial state if there's a power outage so credit equals purchase, etc.

But when I get into conversations about MongoDB, those of us that don't know the technical details of how databases are actually implemented start throwing around statements like:

MongoDB is way faster than MySQL and Postgres, but there's a tiny chance, like 1 in a million, that it "won't save correctly".

That "won't save correctly" part is referring to this understanding: If there's a power outage right at the instant you're writing to MongoDB, there's a chance for a particular record (say you're tracking pageviews in documents with 10 attributes each), that one of the documents only saved 5 of the attributes… which means over time your pageview counters are going to be "slightly" off. You'll never know by how much, you know they'll be 99.999% correct, but not 100%. This is because, unless you specifically made this a mongodb atomic operation, the operation is not guaranteed to have been atomic.

So my question is, what is the correct interpretation of when and why MongoDB may not "save correctly"? What parts of ACID does it not satisfy, and under what circumstances, and how do you know when that 0.001% of your data is off? Can't this be fixed somehow? If not, this seems to mean that you shouldn't store things like your users table in MongoDB, because a record might not save. But then again, that 1/1,000,000 user might just need to "try signing up again", no?

I am just looking for maybe a list of when/why negative things happen with an ACID noncompliant database like MongoDB, and ideally if there's a standard workaround (like run a background job to cleanup data, or only use SQL for this, etc.).

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6 Answers 6

up vote 57 down vote accepted

One thing you lose with MongoDB is multi-collection (table) transactions. Atomic modifiers in MongoDB can only work against a single document.

If you need to remove an item from inventory and add it to someone's order at the same time - you cant. Unless those two things - inventory and orders - exist in the same document (which they probably do not).

I encountered this very issue in an application I am working on and two possible solutions exist:

1) Structure your documents as best you can and use atomic modifiers as best you can and for he remaining bit, use a background process to cleanup records that may be out of sync. For example, I remove items from inventory and add them to a reservedInventory array of the same document using atomic modifiers.

This lets me always know that items are NOT available in the inventory (because they are reserved by a customer). When the customer check's out, I then remove the items from the reservedInventory. Its not a standard transaction and since the customer could abandon the cart, I need some background process to go through and find abandoned carts and move the reserved inventory back into the available inventory pool.

This is obviously less than ideal, but its the only part of a large application where mongodb does not fit the need perfectly. Plus, it works flawlessly thus far. This may not be possible for many scenarios, but because of the document structure I am using, it fits well.

2) Use a transactional database in conjunction with MongoDB. It is common to use MySQL to provide transactions for the things that absolutely need them while letting MongoDB (or any other NoSQL) do what it does best.

If my solution from #1 does not work in the long run, I will investigate further into combining MongoDB with MySQL but for now #1 suits my needs well.

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"Atomic modifiers in MongoDB can only work against a single collection" => I think you meant "against a single document". –  assylias Apr 5 '13 at 9:27
Excellent information, generally an excellent answer with the exception of suggesting to use MySQL. –  Doug Molineux Oct 23 '14 at 20:52

It's actually not correct that MongoDB is not ACID-compliant. On the contrary, MongoDB is ACID-compilant at the document level.

Any update to a single document is

  • Atomic: it either fully completes or it does not
  • Consistent: no reader will see a "partially applied" update
  • Isolated: again, no reader will see a "dirty" read
  • Durable: (with the appropriate write concern)

What MongoDB doesn't have is transactions -- that is, multiple-document updates that can be rolled back and are ACID-compliant.

Note that you can build transactions on top of the ACID-compliant updates to a single document, by using two-phase commit.

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Was the clearest answer for me –  babonk Apr 8 '14 at 7:00
Note that the transactions of two-phase commits are not ACID-compliant. For some reason I inferred the opposite until I followed the link. –  Justin C Jul 27 '14 at 19:01
There's some question about the durability of distributed MongoDB at the document level, regardless of the write concern configuration. The open-source tool Jepsen found that data can be lost in the face of a network partition even with the MAJORITY write concern. See the write-up here: aphyr.com/posts/284-call-me-maybe-mongodb –  jrullmann Sep 3 '14 at 13:57

A good explanation is contained in "Starbucks Does Not Use Two Phase Commit".

It's not about NoSQL databases, but it does illustrate the point that sometimes you can afford to lose a transaction or have your database in an inconsistent state temporarily.

I wouldn't consider it to be something that needs to be "fixed". The fix is to use an ACID-compliant relational database. You choose a NoSQL alternative when its behavior meets your application requirements.

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nice real world example –  gbn Aug 22 '11 at 16:06
Like any analogy it has its limitations. In software, it is easy to create new Array[Cashiers] and have them process synchronous transactions each, while real world cost of that would be ridiculously expensive. –  HRJ Dec 7 '12 at 11:01

I think other people gave good answers already. However i would like to add that there are ACID NOSQL DBs (like http://ravendb.net/ ). So it is not only decision NOSQL - no ACID vs Relational with ACID....

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thanks @subGate. anyone out there who can share their experience with ravenDB and if it indeed satisfies the requirement? –  Nir Pengas Oct 22 '13 at 3:30

"won't save correctly" could mean:

  1. By default MongoDB does not save your changes to the drive immediately. So there is a possibility that you tell a user "update is successful", power outage happens and the update is lost. MongoDB provides options to control level of update "durability". It can wait for the other replica(s) to receive this update (in memory), wait for the write to happen to the local journal file, etc.

  2. There is no easy "atomic" updates to multiple collections and even multiple documents in the same collection. It's not a problem in most cases because it can be circumvented with Two Phase Commit, or restructuring your schema so updates are made to a single document. See this question: Document Databases: Redundant data, references, etc. (MongoDB specifically)

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The only reason atomic modifies work against a single-collection is because the mongodb developers recently exchanged a database lock with a collection wide write-lock. Deciding that the increased concurrency here was worth the trade-off. At it's core, mongodb is a memory-mapped file: they've delegated the buffer-pool management to the machine's vm subsystem. Because it's always in memory, they're able to get away with very course grained locks: you'll be performing in-memory only operations while holding it, which will be extremely fast. This differs significantly from a traditional database system which is sometimes forced to perform I/O while holding a pagelock or a rowlock.

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could you please explain why this increases concurrency? Sorry if I am missing the obvious here. –  batbrat Mar 14 '14 at 15:05
@batbrat: Consider two clients who attempt to simultaneously write to different collections in the same database. With a database lock, one of the clients will have to wait for the other to finish before its write can occur. With a collection lock both clients can write at the same time. That's what is meant by increased concurrency. Of course, if both clients attempt to write to the same collection then one will have to wait. –  jrullmann Sep 3 '14 at 14:02

protected by Brad Larson Apr 9 '14 at 17:42

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