Long story short, I'm rewriting a piece of a system and am looking for a way to store some hit counters in AWS SimpleDB.
For those of you not familiar with SimpleDB, the (main) problem with storing counters is that the cloud propagation delay is often over a second. Our application currently gets ~1,500 hits per second. Not all those hits will map to the same key, but a ballpark figure might be around 5-10 updates to a key every second. This means that if we were to use a traditional update mechanism (read, increment, store), we would end up inadvertently dropping a significant number of hits.
One potential solution is to keep the counters in memcache, and using a cron task to push the data. The big problem with this is that it isn't the "right" way to do it. Memcache shouldn't really be used for persistent storage... after all, it's a caching layer. In addition, then we'll end up with issues when we do the push, making sure we delete the correct elements, and hoping that there is no contention for them as we're deleting them (which is very likely).
Another potential solution is to keep a local SQL database and write the counters there, updating our SimpleDB out-of-band every so many requests or running a cron task to push the data. This solves the syncing problem, as we can include timestamps to easily set boundaries for the SimpleDB pushes. Of course, there are still other issues, and though this might work with a decent amount of hacking, it doesn't seem like the most elegant solution.
Has anyone encountered a similar issue in their experience, or have any novel approaches? Any advice or ideas would be appreciated, even if they're not completely flushed out. I've been thinking about this one for a while, and could use some new perspectives.
The existing SimpleDB API does not lend itself naturally to being a distributed counter. But it certainly can be done.
Working strictly within SimpleDB there are 2 ways to make it work. An easy method that requires something like a cron job to clean up. Or a much more complex technique that cleans as it goes.
The Easy Way
The easy way is to make a different item for each "hit". With a single attribute which is the key. Pump the domain(s) with counts quickly and easily. When you need to fetch the count (presumable much less often) you have to issue a query
SELECT count(*) FROM domain WHERE key='myKey'
Of course this will cause your domain(s) to grow unbounded and the queries will take longer and longer to execute over time. The solution is a summary record where you roll up all the counts collected so far for each key. It's just an item with attributes for the key {summary='myKey'} and a "Last-Updated" timestamp with granularity down to the millisecond. This also requires that you add the "timestamp" attribute to your "hit" items. The summary records don't need to be in the same domain. In fact, depending on your setup, they might best be kept in a separate domain. Either way you can use the key as the itemName and use GetAttributes instead of doing a SELECT.
Now getting the count is a two step process. You have to pull the summary record and also query for 'Timestamp' strictly greater than whatever the 'Last-Updated' time is in your summary record and add the two counts together.
SELECT count(*) FROM domain WHERE key='myKey' AND timestamp > '...'
You will also need a way to update your summary record periodically. You can do this on a schedule (every hour) or dynamically based on some other criteria (for example do it during regular processing whenever the query returns more than one page). Just make sure that when you update your summary record you base it on a time that is far enough in the past that you are past the eventual consistency window. 1 minute is more than safe.
This solution works in the face of concurrent updates because even if many summary records are written at the same time, they are all correct and whichever one wins will still be correct because the count and the 'Last-Updated' attribute will be consistent with each other.
This also works well across multiple domains even if you keep your summary records with the hit records, you can pull the summary records from all your domains simultaneously and then issue your queries to all domains in parallel. The reason to do this is if you need higher throughput for a key than what you can get from one domain.
This works well with caching. If your cache fails you have an authoritative backup.
The time will come where someone wants to go back and edit / remove / add a record that has an old 'Timestamp' value. You will have to update your summary record (for that domain) at that time or your counts will be off until you recompute that summary.
This will give you a count that is in sync with the data currently viewable within the consistency window. This won't give you a count that is accurate up to the millisecond.
The Hard Way
The other way way is to do the normal read - increment - store mechanism but also write a composite value that includes a version number along with your value. Where the version number you use is 1 greater than the version number of the value you are updating.
get(key) returns the attribute value="Ver015 Count089"
Here you retrieve a count of 89 that was stored as version 15. When you do an update you write a value like this:
put(key, value="Ver016 Count090")
The previous value is not removed and you end up with an audit trail of updates that are reminiscent of lamport clocks.
This requires you to do a few extra things.
the ability to identify and resolve conflicts whenever you do a GET
a simple version number isn't going to work you'll want to include a timestamp with resolution down to at least the millisecond and maybe a process ID as well.
in practice you'll want your value to include the current version number and the version number of the value your update is based on to more easily resolve conflicts.
you can't keep an infinite audit trail in one item so you'll need to issue delete's for older values as you go.
What you get with this technique is like a tree of divergent updates. you'll have one value and then all of a sudden multiple updates will occur and you will have a bunch of updates based off the same old value none of which know about each other.
When I say resolve conflicts at GET time I mean that if you read an item and the value looks like this:
11 --- 12
/
10 --- 11
\
11
You have to to be able to figure that the real value is 14. Which you can do if you include for each new value the version of the value(s) you are updating.
It shouldn't be rocket science
If all you want is a simple counter: this is way over-kill. It shouldn't be rocket science to make a simple counter. Which is why SimpleDB may not be the best choice for making simple counters.
That isn't the only way but most of those things will need to be done if you implement an SimpleDB solution in lieu of actually having a lock.
Don't get me wrong, I actually like this method precisely because there is no lock and the bound on the number of processes that can use this counter simultaneously is around 100. (because of the limit on the number of attributes in an item) And you can get beyond 100 with some changes.
Note
But if all these implementation details were hidden from you and you just had to call increment(key), it wouldn't be complex at all. With SimpleDB the client library is the key to making the complex things simple. But currently there are no publicly available libraries that implement this functionality (to my knowledge).
To anyone revisiting this issue, Amazon just added support for Conditional Puts, which makes implementing a counter much easier.
Now, to implement a counter - simply call GetAttributes, increment the count, and then call PutAttributes, with the Expected Value set correctly. If Amazon responds with an error ConditionalCheckFailed, then retry the whole operation.
Note that you can only have one expected value per PutAttributes call. So, if you want to have multiple counters in a single row, then use a version attribute.
pseudo-code:
begin
attributes = SimpleDB.GetAttributes
initial_version = attributes[:version]
attributes[:counter1] += 3
attributes[:counter2] += 7
attributes[:version] += 1
SimpleDB.PutAttributes(attributes, :expected => {:version => initial_version})
rescue ConditionalCheckFailed
retry
end
I see you've accepted an answer already, but this might count as a novel approach.
If you're building a web app then you can use Google's Analytics product to track page impressions (if the page to domain-item mapping fits) and then to use the Analytics API to periodically push that data up into the items themselves.
I haven't thought this through in detail so there may be holes. I'd actually be quite interested in your feedback on this approach given your experience in the area.
Thanks
Scott
For anyone interested in how I ended up dealing with this... (slightly Java-specific)
I ended up using an EhCache on each servlet instance. I used the UUID as a key, and a Java AtomicInteger as the value. Periodically a thread iterates through the cache and pushes rows to a simpledb temp stats domain, as well as writing a row with the key to an invalidation domain (which fails silently if the key already exists). The thread also decrements the counter with the previous value, ensuring that we don't miss any hits while it was updating. A separate thread pings the simpledb invalidation domain, and rolls up the stats in the temporary domains (there are multiple rows to each key, since we're using ec2 instances), pushing it to the actual stats domain.
I've done a little load testing, and it seems to scale well. Locally I was able to handle about 500 hits/second before the load tester broke (not the servlets - hah), so if anything I think running on ec2 should only improve performance.
Answer to feynmansbastard:
If you want to store huge amount of events i suggest you to use distributed commit log systems such as kafka or aws kinesis. They allow to consume stream of events cheap and simple (kinesis's pricing is 25$ per month for 1K events per seconds) – you just need to implement consumer (using any language), which bulk reads all events from previous checkpoint, aggregates counters in memory then flushes data into permanent storage (dynamodb or mysql) and commit checkpoint.
Events can be logged simply using nginx log and transfered to kafka/kinesis using fluentd. This is very cheap, performant and simple solution.
Also had similiar needs/challenges.
I looked at using google analytics and count.ly. the latter seemed too expensive to be worth it (plus they have a somewhat confusion definition of sessions). GA i would have loved to use, but I spent two days using their libraries and some 3rd party ones (gadotnet and one other from maybe codeproject). unfortunately I could only ever see counters post in GA realtime section, never in the normal dashboards even when the api reported success. we were probably doing something wrong but we exceeded our time budget for ga.
We already had an existing simpledb counter that updated using conditional updates as mentioned by previous commentor. This works well, but suffers when there is contention and conccurency where counts are missed (for example, our most updated counter lost several million counts over a period of 3 months, versus a backup system).
We implemented a newer solution which is somewhat similiar to the answer for this question, except much simpler.
We just sharded/partitioned the counters. When you create a counter you specify the # of shards which is a function of how many simulatenous updates you expect. this creates a number of sub counters, each which has the shard count started with it as an attribute :
COUNTER (w/5shards) creates :
shard0 { numshards = 5 } (informational only)
shard1 { count = 0, numshards = 5, timestamp = 0 }
shard2 { count = 0, numshards = 5, timestamp = 0 }
shard3 { count = 0, numshards = 5, timestamp = 0 }
shard4 { count = 0, numshards = 5, timestamp = 0 }
shard5 { count = 0, numshards = 5, timestamp = 0 }
Sharded Writes
Knowing the shard count, just randomly pick a shard and try to write to it conditionally. If it fails because of contention, choose another shard and retry.
If you don't know the shard count, get it from the root shard which is present regardless of how many shards exist. Because it supports multiple writes per counter, it lessens the contention issue to whatever your needs are.
Sharded Reads
if you know the shard count, read every shard and sum them.
If you don't know the shard count, get it from the root shard and then read all and sum.
Because of slow update propogation, you can still miss counts in reading but they should get picked up later. This is sufficient for our needs, although if you wanted more control over this you could ensure that- when reading- the last timestamp was as you expect and retry.
Related
The problem: very frequent "403 Request throttled due to too many requests" errors during data indexing which should be a memory usage issue.
The infrastructure:
Elasticsearch version: 7.8
t3.small.elasticsearch instance (2 vCPU, 2 GB memory)
Default settings
Single domain, 1 node, 1 shard per index, no replicas
There's 3 indices with searchable data. 2 of them have roughly 1 million documents (500-600 MB) each and one with 25k (~20 MB). Indexing is not very simple (has history tracking) so I've been testing refresh with true, wait_for values or calling it separately when needed. The process is using search and bulk queries (been trying sizes of 500, 1000). There should be a limit of 10MB from AWS side so these are safely below that. I've also tested adding 0,5/1 second delays between requests, but none of this fiddling really has any noticeable benefit.
The project is currently in development so there is basically no traffic besides the indexing process itself. The smallest index generally needs an update once every 24 hours, larger ones once a week. Upscaling the infrastructure is not something we want to do just because indexing is so brittle. Even only updating the 25k data index twice in a row tends to fail with the above mentioned error. Any ideas how to reasonably solve this issue?
Update 2020-11-10
Did some digging in past logs and found that we used to have 429 circuit_breaking_exception-s (instead of the current 403) with a reason among the lines of [parent] Data too large, data for [<http_request>] would be [1017018726/969.9mb], which is larger than the limit of [1011774259/964.9mb], real usage: [1016820856/969.7mb], new bytes reserved: [197870/193.2kb], usages [request=0/0b, fielddata=0/0b, in_flight_requests=197870/193.2kb, accounting=4309694/4.1mb]. Used cluster stats API to track memory usage during indexing, but didn't find anything that I could identify as a direct cause for the issue.
Ended up creating a solution based on the information that I could find. After some searching and reading it seemed like just trying again when running into errors is a valid approach with Elasticsearch. For example:
Make sure to watch for TOO_MANY_REQUESTS (429) response codes
(EsRejectedExecutionException with the Java client), which is the way
that Elasticsearch tells you that it cannot keep up with the current
indexing rate. When it happens, you should pause indexing a bit before
trying again, ideally with randomized exponential backoff.
The same guide has also useful information about refreshes:
The operation that consists of making changes visible to search -
called a refresh - is costly, and calling it often while there is
ongoing indexing activity can hurt indexing speed.
By default, Elasticsearch periodically refreshes indices every second,
but only on indices that have received one search request or more in
the last 30 seconds.
In my use case indexing is a single linear process that does not occur frequently so this is what I did:
Disabled automatic refreshes (index.refresh_interval set to -1)
Using refresh API and refresh parameter (with true value) when and where needed
When running into a "403 Request throttled due to too many requests" error the program will keep trying every 15 seconds until it succeeds or the time limit (currently 60 seconds) is hit. Will adjust the numbers/functionality if needed, but results have been good so far.
This way the indexing is still fast, but will slow down when needed to provide better stability.
If I scan or query in DynamoDB it is possible to set the Limit property. The DynamoDB documentation says the following:
The maximum number of items to evaluate (not necessarily the number of
matching items).
So the problem with this is if you set filters and such it won't return all the items.
My goal that I'm trying to figure out how to achieve is to have a filter in a scan or query, but have it return x number of items. No matter what. I'm ok with having to use LastEvaluatedKey and make multiple requests, but I would like to try to make it as seamless and easy as possible (so not doing that would be best.
The only way I have thought to do this is to set the Limit property to say 1 or something. Then just keep scanning or querying using the LastEvaluatedKey until I reach that x number of items I'm looking for. Problem is, this seems VERY wasteful and inefficient. I mean if you have a table of millions of records you might have to make thousands and thousands of requests. It doesn't seem like it scales very well. Of course I'm sure it's no different than what DynamoDB would be doing behind the scenes.
But is there a way to do this more efficiently where I can reduce the number of requests I have to make? Or is that the only way to achieve this?
How would you achieve this goal?
A single Query operation will read up to the maximum number of items set (if using the Limit parameter) or a maximum of 1 MB of data and then apply any filtering to the results using FilterExpression.
You're 100% right that Limit is applied before FilterExpression. Meaning Dynamo might return some number or documents less than the Limit while other documents that satisfy the FilterExpression still exist in the table but aren't returned.
Its sounds like it would be unacceptable for your api to behave in the same manner. That is going to mean that in some cases, a single request to your service will result in multiple requests to Dynamo. Also, keep in mind that there is no way to predict what the LastEvaluatedKey will be which would be required to parallelize these requests. So in the case that your service makes multiple requests to Dynamo, they will be serial. To me, this is a rather heavy tradeoff but, if it is a requirement that you satisfy the Limit whenever possible, you have options.
First, Dynamo will automatically page at 1 MB. That means you could simply send your query to Dynamo without a Limit and implement the Limit on your end. You may still need to make multiple requests to ensure that your've satisfied the Limit but this approach will result in the fewest number of requests to Dynamo. The trade off here is the total data being read and transferred. Chances are your Limit will not happen to line up perfectly with the 1 MB limit which means the excess data being read, filtered, and transferred is wasted.
You already mentioned the other extreme of sending a Limit of 1 and pointed out that will result in the maximum number of requests to Dynamo
Another approach along these lines is to create some sort of probabilistic function that takes the Limit given to your service by the client and computes a new Limit for Dynamo. For example, your FilterExpression filters out about half of the documents in the table. That means you can multiply the client Limit by 2 and that would be a reasonable Limit to send to Dynamo. Of the approaches we've talked about so far, this one has the highest potential for efficiency however, it also has the highest potential for complexity. For example, you might find that using a simple linear function is not good enough and instead you need to use machine learning to find a multi-variate non-linear function to calculate the new Limit. This approach also heavily depends on the uniformity of your data in Dynamo as well as your access patterns. Again, you might need machine learning to optimize for those variables.
In any of the cases where you are implementing the Limit on your end, if you plan on sending back the LastEvaluatedKey to the client for subsequent calls to your service, you will also need to take care to keep track of the LastEvaluatedKey that you evaluated. You will no longer be able to rely on the LastEvaluatedKey returned from Dynamo.
The final approach would be to reorganize/regroup your data either with a GSI, a separate table that you keep in sync using Dynamo Streams or a different schema altogether with the goal of not requiring a FilterExpression.
We are implementing support for tracking of Mailgun events in our application. We reviewed the proposed event polling algorithm but find ourselves not quite comfortable with it. First, we would prefer not to discard the data that we have already fetched and then retry from scratch after a pause. It is not very efficient and leaves a door open for a long loop of retries, as it is not clear when the loop is supposed to end. Second, the "threshold age" seems to be the key to determine "trustworthiness", but its value is not defined, only a very large "half an hour" is suggested.
It is our understanding that the events become "trustworthy" after some threshold delay, let us call it D_max, when the events are guaranteed to reside in the event storage. If so, we can implement this algorithm in a different way, so that we do not fetch the data that we know are not "trustworthy" and make use of all data which have been fetched.
We would be fetching data periodically, and on each iteration we would:
Make a request to the events API specifying an ascending time range from T_1 to T_2 = now() - D_max. For the first iteration, T_1 can be set to some time in the past, "e.g., half an hour ago". For the subsequent iterations, T_1 is set to the value of T_2 from the previous iteration.
Fetch all pages one by one while the next page URL is returned.
Use all fetched events, as they are all "trustworthy".
My questions are:
Q1: Are there any problems with this approach?
Q2: What is the minimum realistic value of D_max? Obviously, we can use "half an hour" for it, but we would like to be more agile in tracking events, so it would be great to know what is the minimum value we can set it to and still reliably fetch all events.
Thanks!
1: I see no problems with this solution (in fact I'm doing something very similar). I'm also storing ID's of the events to validate I'm not inserting duplicate entries.
2: I've been working through this similar process. Right now I am testing with D_max at 10 minutes.
Additionally, While going through a testing process I'm running an additional task nightly that goes back over the entire day to validate a few things:
Am I missing existing metrics?
Diagnose if there is a problem with the assumptions I've made about D_max.
My current approach:
I have one domain class - Application
Each application in my system is stored in "applications" bucket under APPLICATION_KEY key
Apart from application metadata stored in this bucket, each application has its own bucket called "time_metrics/APPLICATION_KEY" where I store time series in a way:
KEY - timestamp / VALUE - some attributes
My concern is efficiency of queries made over specific time window for given application. Currently to get time series from some specific time window and eventually make some reductions I have to make map/reduce over whole "time_metric/APPLICATION_KEY" bucket, which what I have found is not the recommended use case for Riak Map/Reduce.
My question: what would be the best db structure for this kind of a system and how efficiently query it.
Adding onto #macintux's answer.
Basho has had a few customers that have used riak for time series metrics.
Boundary has a nice tech talk about how they use Riak with their network monitoring software. They rollup data into different chunks of time (1m, 5m, 15m) for analysis.
They also have a series of blog posts about lessons learned while implementing this system.
Kivra also has a good slide deck about how they use timeseries data with riak.
You could roll up your data into some sort of arbitrary time length, then read the range you need by issuing regular K/V gets, and then reconstruct the larger picture / reduce in your application.
If you have spare computing power and you know in advance what keys you need, you certainly can use Riak's MapReduce, but often retrieving the keys and running your processing on the client will be as fast (and won't strain your cluster).
Some general ideas:
Roll up your data into larger blocks
If you're concerned about losing data if your client crashes while buffering it, you can always store the data as it arrives
Similar idea: store the data as it arrives, then retrieve it and roll it up at certain intervals
You can automatically expire data once you're confident it is being reliably stored in larger blocks, using either the Bitcask or Memory backends
Memory backend is quite useful (RAM permitting) for any data that only needs to be stored for a limited period of time
Related: don't be afraid to store multiple copies of your data to make reading/reporting easier later
Multiple chunks of time (5- and 15-minute blocks, for example)
Multiple report formats
Having said all that, if you're doing straight key/value requests (it's ideal to always be able to compute the keys you need, rather than doing indexing or searching), Riak can support very heavy traffic loads, so I wouldn't recommend spending too much time creating alternative storage mechanisms unless you know you're going to face latency problems.
I'm currently developing a strategy for an incremental update of our user data. We assume 100_000_000 records in our database of which approximately 1_000_000 records are updated per workflow.
The idea is to update records in a MapReduce job. Is it useful to use an indexed storage (eg. Cassandra) to be able to access current records randomly? Or is it preferable to retrieve data from HDFS and join new information to existing records.
The record size is O(200 Bytes). The user data has a fixed length but should be extendable. The log events have a similar but not equal structure. The number of user records is likely to grow. Near real-time updates are desirable, ie. a 3 hour time gap is not acceptable, few minutes is OK.
Have you made any experiences with either of these strategies and data of this size?
Is the pig JOIN fast enough? Is it a bottleneck always to read all records? Is Cassandra able to hold this amount of data efficiently? Which solution is scalable? What about the complexity of the system?
You need to define your requirements first. Your record volumes are not a problem, but you don't give a record length. Are they fixed length, fixed field number, likely to change format over time? Are we talking 100 byte records or 100,000 byte records? You need an index on a field/column if you wish to query by that field/column, unless you do all your work using map/reduce. Will the number of user records stay at 100mill (1 server will probably suffice) or will it grow 100% per year ( probably multiple servers adding new ones over time).
How you access records for updating depends on whether you need to update them in real-time or whether you can run a batch job. Will updates be every minute, or hour, or month?
I would strongly suggest you do some experimenting. Have you done any testing already? This will give you a context for your questions and this will lead to more objective questions and answers. It is unlikely that you can 'whiteboard' a solution based on your question.