Athena Query Queuing Time: What affects it? - amazon-web-services

I've started using Athena recently and it appears useful. However, one thing that bugs me is that Query Queuing times can sometimes be very long (around a minute). At other times, queries are executed almost immediately.
I have not been able to identify reasons why queries sometimes queue for so long, and not at other times. The only thing I noticed is that Table Creation and other DDL statements don't queue for long.
What are the factors that affect queuing time? Server load? Query length? Query complexity?
How can I reduce queuing time? There's no information on this available in the documents as far as I'm aware.

Around a minute it's not that long. We had a few weeks during which we had a random queuing time up to 10m. After a lot of back-and-forth with the support they finally tweaked something and queuing time was reduced to up to 1m, with average 10s.
The queuing is unrelated to your specific query or even "max concurrent queries" settings on your account, it's related to global region Athena load and many other hidden settings that AWS engineers can tweak.

Related

AWS OpenSearch (Elasticsearch): Reading search times in dashboard monitor, Search latency

I'm trying to understand what's causing spikes of slow searches on AWS Opensearch (ElasticSearch). Search times are typically 40-150 ms, but I see spikes of searches taking 5-15 seconds.
For now, I'm trying to understand how to read the monitors.
In the AWS dashboard, I'm looking at the Search latency monitor. It's described as "The average time that it takes a shard to complete a search operation." I see the spikes there. There are various drop-down options for Statistic. When I choose Maximum, the maximum shown during that bad spiking time is about 3000 ms. (Frankly, not sure how I can have an "average" of a "maximum".)
I also monitor the "took" value that is returned for every query search. Elasticsearch describes took as "Milliseconds it took Elasticsearch to execute the request." Here I'm seeing the 10+ second times. This also fits with what I'm actually measuring time wise, comparing times before and after I make the request.
So, why doesn't the dashboard monitor show the actual times? Is there a way for me to see it there?
I'm thinking of setting ES_SEARCH_TIMEOUT to a couple of seconds or so. No one is going to wait longer than that for a result, anyway. I think perhaps the slow searches build up, causing more slow searches. Better to have some early errors, hopefully preventing more slow queries. (Although not certain that this actually stops the query from continuing on the server.) (Considering options before I pay $600 a month more for the next larger instance size). But if AWS somehow sees 10 second searches as taking 3 seconds, then I'm not sure how to set it.

The execution time of parallel queries in Redshift increases drastically with the no of queries

I am new to Amazon Redshift. I have preloaded some data to a table and I am testing the query latency in Redshift. The fact that I have observed is that with parallel queries the execution time is going up highly as the no of queries fired parallely increases. The Redshift documentation points to the use of sort key and I have tried all that and the situation still remains the same. Kindly help me out in improving the parallel query execution time in Redshift.
It sounds like you are just issuing more queries and not changing the queue definitions, right?
Redshift uses a queuing system to manage the influx of queries called WLM (WorkLoad Manager). The WLM is configurable and limits the number of queries that are actually executed in parallel vs. held waiting in the queues. So the first question I'd want to look at is how much of the observed latency is due to "queue wait" time.
Now just increasing how many queries can execute in parallel is not going to fix the latency in many cases. Redshift can typically execute between 1 and 2 dozen queries at a time depending on the complexity of your queries. Allowing too many queries to execute at the same time can drastically reduce the total performance of the cluster. Most people have a mix of large and small queries and properly configuring the WLM can improve query latency by allowing simple and high priority queries to be executed quickly while big batch queries queue up.

How to efficiently aggregate data in billions of individual records in AWS?

At a high / theoretical level I know exactly the type of architecture I want to build and how it would work, but I'm attempting to construct this as cheaply as possible using AWS services and my lack of familiarity with the offerings of AWS has me running in circles.
The Data
We run a video streaming platform. On busy nights we have about 100 simultaneous live streams going with upwards of 30,000 viewers. We expect this number to rise to 100,000 in the next few years. A live stream lasts, on average, 2 hours.
We send a heartbeat from our player every 10 seconds with information about the viewer -- how much data they've viewed, how much data they've buffered, what quality they're streaming, etc.
These heartbeats are sent directly to an AWS Kinesis endpoint.
Finally, we want to retain all past messages for at least 5 years (hopefully longer) so that we can look at historic analytics.
Some back of the envelope calculations suggest we will have 0.1 * 60 * 60 * 2 * 100000 * 365 * 5 = 131 billion heartbeat messages five years from now.
Our Old Pipeline
Our old system had a single Kinesis consumer. Aggregate data was stored in DynamoDB. Whenever a message arrived we would read the record from DynamoDB, update the record, then write the new record back. This read-update-write loop limited the speed at which we could process messages and made it so that each message coming in was dependent on the messages before it, so they could not be processed in parallel.
Part of the reason for this setup is that our message schema was not well designed from the outset. We send the timestamp at which the message was sent, but we do not send "amount of video watched since last heartbeat". As a result in order to compute the total viewer time we need to look up the last heartbeat message sent by this player, subtract the timestamps, and add that value. Similar issues exist with many other metrics.
Our New Pipeline
We've begun to run into scaling issues. During our peak hours analytics can be delayed by as much as four hours while waiting for a backlog of messages to be processed. If this backlog reaches 24 hours Kinesis will start deleting data. So we need to fix our pipeline to remove this dependency on past messages so we can process them in parallel.
The first part of this was updating the messages sent by our players. Our new specification includes only metrics that can be trivially sum'd with no subtraction. So we can just keep adding to the "time viewed" metric, for instance, without any regard to past messages.
The second part of this was ensuring that Kinesis never backs up. We dump the raw messages to S3 as quickly as they arrive with no processing (Kinesis Data Fire Hose) so that we can crunch analytics on them at our leisure.
Finally, we now want to actually extract information from these analytics as quickly as possible. This is where I've hit a snag.
The Questions We Want to Answer
As this is an analytics pipeline, our questions mostly revolve around filtering these messages and then aggregating fields for the remaining messages (possibly, in fact likely, with grouping). For instance:
How many Android users watched last night's stream in HD? (FILTER by stream and OS)
What's the average bandwidth usage among all users? (SUM and COUNT, with later division of the final aggregates which could be done on the dashboard side)
What percent of users last year were on any Apple device (iOS, tvOS, etc)? (COUNT, grouped by OS)
What's the average time spent buffering among Android users for streams in the past year? (a mix of all of the above)
Options
AWS Athena would allow us to query the data in S3 directly as if it were an ANSI SQL table. However reading up on Athena, unless the data is properly formatted it can be incredibly slow. Some benchmarks I've seen show that processing 1.1 billion rows of CSV data can take up to 2 minutes. I'm looking at processing 100x that much data
AWS EMR and AWS Redshift sound like they are built for this purpose, but are complicated to set up and have a high base cost to run (requiring an EC2 cluster to remain active at all times). AWS Redshift also requires data be loaded into it, which sounds like it might be a very slow process, delaying our access to analytics
AWS Glue sounds like it may be able to take the raw messages as they arrive in S3 and convert them to Parquet files for more rapid querying via Athena
We could run a job to regularly batch messages to reduce the total number that must be processed. While a stream is live we'll receive one message every 10 seconds, but we really only care about the totals for a given viewer. This means that when a 2-hour stream concludes we can combine the 720 messages we've received from that player into a single "summary" message about the viewer's experience during the whole stream. This would massively reduce the amount of data we need to process, but exactly how and when to trigger this process isn't clear to me
The Ideal Architecture
This is a Big Data problem. The generic solution to Big Data problems is "don't take your data to your query, take your query to your data". If these messages were spread across 100 small storage nodes then each node could filter, sum, and count the subset of data they hold and pass these aggregates back to a central node which sums the sums and sums the counts. If each node is only operating on 1/100th of the data set then this kind of processing could theoretically be incredibly fast.
My Confusion
While I have a theoretical understanding of the "ideal" architecture, it's not clear to me if AWS works this way or how to construct a system that will function well like this.
S3 is a black box. It's not clear if Athena queries are run on individual nodes and aggregates are further reduced elsewhere, or if there's a system reading all of the data and aggregating it in a central location
Redshift requires the data by copied into a Redshift database. This doesn't sound fast, nor distributed
It's unclear to me how EMR works or if it will suit my purpose. Still researching
AWS Glue seems like it may need to be triggered by some event?
Parquet files seems to be like CSVs, where multiple records reside in a single file. Meanwhile I'm dumping one record per file. But perhaps there's a way to fix that? e.g. batching files every minute or every 5 minutes?
RDS or a similar service might be really good for this (indexing and whatnot) but would require a guaranteed schema (or necessitate migrating if our message schema changed) which is a concern. Migrating terabytes of data if we change our message schema sounds out of the question
Finally, along with wanting to get analytics results in as "real time" as possible (ideally we want to know within 1 minute when someone joins or leaves a stream), we want the dashboards to load quickly. Waiting 30 seconds to see the count of live viewers is horrendous. Dashboards should load in 2 seconds or less (ideally)
The plan is to use QuickSight to create dashboards (our old system had a hack-y Django app that read from our DynamoDB aggregates table, but I'd like to avoid creating more code for people to maintain)
I expect you are going to get a lot of different answers and opinions from the broad set of experts you have pinged with this. There is likely no single best answer to this as there are a lot of variables. Let me give you my best advice based on my experience in the field.
Kinesis to S3 is a good start and not moving data more than needed is the right philosophy.
You didn't mention Kinesis Data Analytics and this could be a solution for SOME of your needs. It is best for questions about what is happening in the data feed right now. The longer timeframe questions are better suited for the tools you mention. If you aren't too interested in what is happening in the past 10 minutes (or so) it could be good to omit.
S3 organization will be key to performing any analytic directly on the data there. You mention parquet formatting which is good but partitioning is far more powerful. Organizing the S3 data into "days" or "hours" of data and setting up the partitioning based on this can greatly speed up any query that is limited in the amount of time that is needed (don't read what you don't need).
Important safety note on S3 - S3 is an object store and as such there is overhead for each object you reference. Having many small objects (10,000+) treated as a single set of data is going to be slow no matter what solution you go with. You need to fix this before you go forward with any solution. You see it takes upwards of .5 sec to look up an object in S3 but if the file is small the transfer time is next to nothing. Now multiply .5 sec times all the objects you have and see how long it will take to read them. This is not a function of the downstream tool you choose but of the S3 organization you have. S3 objects as part of a Big Data solution should be at least 100M in size to not suffer greatly from the object lookup time. The choice of parquet or CSV files is mute without addressing object size and partitioning first.
Athena is good for occasional queries especially if the date ranges are limited. Is this the query pattern you expect? As you say "move the compute to the data" but if you use Athena to do large cross-sectional analytics where a large percentage of the data needs to be used, you are just moving the data to Athena every time you execute this query. Don't stop thinking about data movement at the point it is stored - think about the data movements to do the analytics also.
So a big question is how much data is needed and how often to support your analytics workloads and BI functions? This is the end result you are looking for. If a high percentage of the data is needed frequently then a warehouse solution like Redshift with the data loaded to disk is the right answer. The data load time to Redshift is quite fast as it parallel loads the data from S3 (you see S3 is a cluster and Redshift is a cluster and parallel loads can be done). If loading all your data into Redshift is what you need then the load time is not your main concern - the cost is. Big powerful tool with a price tag to match. The new RA3 instance type bends this curve down significantly for large data size clusters so could be a possibility.
Another tool you haven't mentioned is Redshift Spectrum. This brings several powerful technologies together that could be important to you. First is the power of Redshift with the ability to choose smaller cluster sizes that normally would be used for your data size. S3 filtering and aggregation technology allows Spectrum to perform actions on the data in S3 (yes initial compute actions of the query are performed inside of S3 potentially greatly reducing the data moved to Redshift). If your query patterns support this data reduction in S3 then the data movement will be small and the Redshift cluster can be small (cheap) too. This can be a powerful compromise point for IoT solutions like yours since complex data models and joining are not needed.
You bring up Glue and conversion to parquet. These can be good to do but as I mentioned before partitioning of the data in S3 is usually far more powerful. The value of parquet will increase as the width of your data increases. Parquet is a columnar format so it is advantaged if only a subset of "columns" are needed. The downside is the conversion time/cost and the loss of easy human readability (which can be huge during debug).
EMR is another choice you mention but I generally advise clients against going with EMR unless they need the flexibility it brings to the analytics and they have the skills to use it well. Without these EMR tends to be an unneeded costs sink.
If this is really going to be a Big Data solution then RDS (and Aurora) not good choices. They are designed for transactional workloads, not analytics. The data size and analytics will not fit well or be cost effective.
Another tool in the space is S3 Select. Not likely what you are looking for but something to remember exists and can be a tool in the toolbox.
Hybrid solutions are common in this space if there are variable needs based on some factor. A common one "is time of day" - no one is running extensive reports at 3am so the needed performance is much less. Another is user group - some groups need simple analytics while others need much more power. Another factor is timeliness of data - does everyone need "up to the second" information or is daily information sufficient? Trying to have one tool that does everything for everybody, all the time is often a path to an expensive, oversized solution.
Since Redshift Spectrum and Athena can point at the same S3 data (well organized since both will benefit) both tools can coexist on the same data. Also, Redshift is ideal for sifting through huge mounds of data, it is ideal for producing summary tables and then writing them (in partitioned parquet) to S3 for tools like Athena to use. All these cloud services can be run on schedules and this includes Redshift and EMR (Athena is query on demand) so they don't need to run all the time. Redshift with Spectrum can run a few hours a day to perform deep analytics and summarize data for writing to S3. Your data scientist can also use Redshift for their hardcore work while Athena supports dashboards using the daily summary data and Kinesis Data Analytics as source.
Lastly you bring up a 2 sec requirement for dashboards. This is definitely possible with Quicksight backed up by Redshift or Athena but won't be met for arbitrarily complex / data intensive queries. To meet this you will need the engine to have enough horsepower to produce the data in question. Redshift with local data storage is likely the fastest (Redshift Spectrum with some data pruning done in S3 wins in some cases) and Athena is the weakest / slowest. But the power doesn't matter if the work is small - see your query workload will be a huge deciding factor. The fastest will be to load the needed data into Quicksight storage (SPICE) but this is another localized / summarized version of the data so timeliness is again a factor (how often is this updated).
Based on designing similar systems and a bunch of guesses as to what you need I'd recommend that you:
Fix your object size (Kineses can be configured to do this)
Partition your data by day
Set up a small Redshift cluster (4 X dc2.large) and use Spectrum source address the data
Connect Quicksight to Redshift
Measure the performance (and cost) and compare to requirements (there will likely be gaps)
Adjust to solution (summary tables to S3, Athena, SPICE etc.) to meet goals
The alternative is to hire someone who has set up such systems before and have them review the requirements in detail and make a less "guess-based" recommendation.
I would look into Druid. Not an AWS offering, but easily runs on AWS, with good integration with S3 and Kinesis.
Capable of reading from Kinesis, at high speeds, and make the data available for querying right away. Can also flatten and transform the data as it reads it.
Capable of doing rollups/aggregation/compaction during ingestion (and further reduce data in an async manner). From what you wrote, it seems to me that it could easily reduce the number of rows in the DB by a very large factor.
Capable of fast queries, using standard SQL.
Smart partitioning of the data to scan only the relevant dates.
The down-side is that you will need to keep a cluster up and running for ingestion and for querying. It is pretty scalable, so you can start small.
On the up-side - you're not using 10 different technologies (Athena/Glue/EMR/etc.)
You might want to consider contacting Imply, which can ease the deployment.
A usual approach a lot of companies take is they do heavy weight lifting in athena or bigquery (or some other distributed sql environment) -> aggregate intermediate results into multiple indexed+partitioned postgres/mysql/redshift/clickhouse tables and then connect their APIs to read on those tables. Of course, this works fine except the fact that with an increased amount of intermediate-aggregated data, table indices grow and problems like cumulative sum or sorting become less and less efficient.
With your problem in hand, I think you can get a lot of help with AWS Lambda. AWS Lambda provides a very feasible serverless approach towards solving large granular data problems (if used correctly). For instance, assume that your pipelines partitions incoming stream by YYYYMMMDDHHMM and stores it into some S3 path which has a Lambda listening to it (as a trigger function) then your data ingest + aggregation becomes pretty much simultaneous processes. As soon as a minute is up, a new instance of the same Lambda function will be taking care of data landing into partition YYYYMMMDDHHMM+1. So, this way, you can run thousands of simultaneous processes with a good bunch of Lambda functions doing the same thing in parallel. Of course, this is a rough picture, but I think it can greatly help.

Is there a better way for me to architect this batch processing pipeline?

So I have a large dataset (1.5 Billion) I need to perform a I/O bound transform task on (same task for each point) and place the result into a store that allows fuzzy searching on the transforms fields.
What I currently have is a Step-Function Batch Job Pipeline feeding into RDS. It works like so
Lamba splits input data into X number of even partitions
An Array Batch job is created with X array elements matching the X paritions
Batch jobs (1 vCPU, 2048 Gb ram) run on number of EC2 spot instances, transform the data and place it into RDS.
This current solution (with X=1600 workers) runs in about 20-40 minutes, mainly based on the time it takes to spin up spot instance jobs. The actual jobs themselves average about 15 minutes in run time. As for total cost, with spot savings the workers cost ~40 bucks but the real kicker is the RDS postgres DB. To be able to handle 1600 concurrent writes you need at least a r5.xlarge which is 500 a month!
Therein lies my problem. It seems I could run the actual workers quicker and for cheaper ( due to second based pricing) by having say 10,000 workers but then I would need a RDS system that could handle 10,000 concurrent DB connections somehow.
I've looked high and low and can't find a good solution to this scaling wall I am hitting. Below I'll detail some things I've tried and why they haven't worked for me or don't seem like a good fit.
RDS proxies - I tried creating 2 proxies set to 50% connection pool and giving "Even" numbered jobs one proxy and odd numbered jobs the other but that didn't help
DynamoDb - This seems off the bat to solve my problem hugely concurrent, can definitely handle the write load but it doesn't allow fuzzy searching like select * where field LIKE Y which is a key part of my workflow with the batch job results
(Theory) - have the jobs write their results to S3 then trigger a lambda on new bucket entries to insert those into the DB. (This might be a terrible idea I'm not sure)
Anyways, what I'm after is improving the cost of running this batch pipeline (mainly the DB), improving the time to run (to save on Spot costs) or both! I am open to any feedback or suggestion!
Let me know if there's some key piece of info you need I missed.

Expected Cassandra MapReduce Performance

Having a very specific access pattern for my data, I wonder about the expected mapreduce performance of Cassandra. These are my requirements:
There will be 10 Million Documents (e.g. JSON, a couple of KB each)
in my database There will be occasional updates of the documents
Users want to create results from the whole dataset that require
processing of each document
Users will want to do this in a
semi-interactive fashion, trying out effects of changes they make to
the processing of each document. Waiting for the result a couple of
minutes is ok.
Users would like to be able to spend money (scaling up
or out) to increase interactive speed if there is a desire to
increase processing speed.
There will not be large user numbers,
processing needs to be done a couple of times per hour, maybe.
Durability is not a primary concern, as the data is replicated from a
source system anyway.
This sounds like a good Job for Cassandra and MapReduce but given that MapReduce is not intended to be used semi-interactively but rather as a background job, I wonder what performance possibilities I can expect using Cassandra.
My other options are plain MySQL with documents stored as CLOBS or partitioned Redis.
Can anyone provide clues on how to estimate the speed possibilities?