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I am new to NoSQL world and thinking of replacing my MS Sql Server database to MongoDB. My application (written in .Net C#) interacts with IP Cameras and records meta data for each image coming from Camera, into MS SQL Database. On average, i am inserting about 86400 records per day for each camera and in current database schema I have created separate table for separate Camera images, e.g. Camera_1_Images, Camera_2_Images ... Camera_N_Images. Single image record consists of simple metadata info. like AutoId, FilePath, CreationDate. To add more details to this, my application initiates separate process (.exe) for each camera and each process inserts 1 record per second in relative table in database.
I need suggestions from (MongoDB) experts on following concerns:
to tell if MongoDB is good for holding such data, which eventually will be queried against time ranges (e.g. retrieve all images of a particular camera between a specified hour)? Any suggestions about Document Based schema design for my case?
What should be the specs of server (CPU, RAM, Disk)? any suggestion?
Should i consider Sharding/Replication for this scenario (while considering the performance in writing to synch replica sets)?
Are there any benefits of using multiple databases on same machine, so that one database will hold images of current day for all cameras, and the second one will be used to archive previous day images? I am thinking on this with respect to splitting reads and writes on separate databases. Because all read requests might be served by second database and writes to first one. Will it benefit or not? If yes then any idea to ensure that both databases are synced always.
Any other suggestions are welcomed please.
I am myself a starter on NoSQL databases. So I am answering this at the expense of potential down votes but it will be a great learning experience for me.
Before trying my best to answer your questions I should say that if MS
SQL Server is working well for you then stick with it. You have not
mentioned any valid reason WHY you want to use MongoDB except the fact
that you learnt about it as a document oriented db. Moreover I see
that you have almost the same set of meta-data you are capturing for
each camera i.e. your schema is dynamic.
to tell if MongoDB is good for holding such data, which eventually will be queried against time ranges (e.g. retrieve all images of a particular camera between a specified hour)? Any suggestions about Document Based schema design for my case?
MongoDB being a document oriented db, is good at querying within an aggregate (you call it document). Since you already are storing each camera's data in its own table, in MongoDB you will have a separate collection created for each camera. Here is how you perform date range queries.
What should be the specs of server (CPU, RAM, Disk)? any suggestion?
All NoSQL data bases are built to scale-out on commodity hardware. But by the way you have asked the question, you might be thinking of improving performance by scaling-up. You can start with a reasonable machine and as the load increases, you can keep adding more servers (scaling-out). You no need to plan and buy a high end server.
Should i consider Sharding/Replication for this scenario (while considering the performance in writing to synch replica sets)?
MongoDB locks the entire db for a single write (but yields for other operations) and is meant for systems which have more reads than writes. So this depends upon how your system is. There are multiple ways of sharding and should be domain specific. A generic answer is not possible. However some examples can be given like sharding by geography, by branches etc.
Also read A plain english introduction to CAP Theorem
Updated with answer to the comment on sharding
According to their documentation, You should consider deploying a sharded cluster, if:
your data set approaches or exceeds the storage capacity of a single node in your system.
the size of your system’s active working set will soon exceed the capacity of the maximum amount of RAM for your system.
your system has a large amount of write activity, a single MongoDB instance cannot write data fast enough to meet demand, and all other
approaches have not reduced contention.
So based upon the last point yes. The auto-sharding feature is built to scale writes. In that case, you have a write lock per shard, not per database. But mine is a theoretical answer. I suggest you take consultation from 10gen.com group.
to tell if MongoDB is good for holding such data, which eventually
will be queried against time ranges (e.g. retrieve all images of a
particular camera between a specified hour)?
This quiestion is too subjective for me to answer. From personal experience with numerous SQL solutions (ironically not MS SQL) I would say they are both equally as good, if done right.
Also:
What should be the specs of server (CPU, RAM, Disk)? any suggestion?
Depends on too many variables that only you know, however a small cluster of commodity hardware works quite well. I cannot really give a factual response to this question and it will come down to your testing.
As for a schema I would go for a document of the structure:
{
_id: {},
camera_name: "my awesome camera",
images: [
{
url: "http://I_like_S3_here.amazons3.com/my_image.png" ,
// All your other fields per image
}
]
}
This should be quite easy to mantain and update so long as you are not embedding much deeper since then it could become a bit of pain, however, that depends upon your queries.
Not only that but this should be good for sharding since you have all the data you need in one document, if you were to shard on _id you could probably get the perfect setup here.
Should i consider Sharding/Replication for this scenario (while considering the performance in writing to synch replica sets)?
Possibly, many people assume they need to shard when in reality they just need to be more intelligent in how they design the database. MongoDB is very free form so there are a lot of ways to do it wrong, but that being said, there are also a lot of ways of dong it right. I personally would keep sharding in mind. Replication can be very useful too.
Are there any benefits of using multiple databases on same machine, so that one database will hold images of current day for all cameras, and the second one will be used to archive previous day images?
Even though MongoDBs write lock is on DB level (currently) I would say: No. The right document structure and the right sharding/replication (if needed) should be able to handle this in a single document based collection(s) under a single DB. Not only that but you can direct writes and reads within a cluster to certain servers so as to create a concurrency situation between certain machines in your cluster. I would promote the correct usage of MongoDBs concurrency features over DB separation.
Edit
After reading the question again I omitted from my solution that you are inserting 80k+ images for each camera a day. As such instead of the embedded option I would actually make a row per image in a collection called images and then a camera collection and query the two like you would in SQL.
Sharding the images collection should be just as easy on camera_id.
Also make sure you take you working set into consideration with your server.
to tell if MongoDB is good for holding such data, which eventually
will be queried against time ranges (e.g. retrieve all images of a
particular camera between a specified hour)? Any suggestions about
Document Based schema design for my case?
MongoDB can do this. For better performance, you can set an index on your time field.
What should be the specs of server (CPU, RAM, Disk)? any suggestion?
I think RAM and Disk would be important.
If you don't want to do sharding to scale out, you should consider a larger size of disk so you can store all your data in it.
Your hot data should can fit into your RAM. If not, then you should consider a larger RAM because the performance of MongoDB mainly depends on RAM.
Should i consider Sharding/Replication for this scenario (while
considering the performance in writing to synch replica sets)?
I don't know many cameras do you have, even 1000 inserts/second with total 1000 cameras should still be easy to MongoDB. If you are concerning insert performance, I don't think you need to do sharding(Except the data size are too big that you have to separate them into several machines).
Another problem is the read frequency of your application. It it is very high, then you can consider sharding or replication here.
And you can use (timestamp + camera_id) as your sharding key if your query only on one camera in a time range.
Are there any benefits of using multiple databases on same machine, so
that one database will hold images of current day for all cameras, and
the second one will be used to archive previous day images?
You can separate the table into two collections(archive and current). And set index only on archive if you only query date on archive. Without the overhead of index creation, the current collection should benefit with insert.
And you can write a daily program to dump the current data into archive.
Related
I have an APP that will be demanding in terms of pulling data. Each time a user logs in, data is pulled, each time a new page is visited data is pulled, etc.
Let's suppose that these queries will never involve joins.
Can I assume then that the queries will scale?
No, it does not follow that using MongoDB and not using joins means "your queries will scale." That's a myth told by MongoDB marketing, not real software engineering.
It depends what your query is doing. Every query has a cost, no matter what brand of datastore you use. Every data access needs to use resources on the server, and that resource usage adds up. Do you queries scan thousands or millions of documents in the MongoDB datastore? Do they need to do map-reduce? How many documents are in the query response? Is it pulling data that is cached, or will it cost I/O overhead to pull that data? How many requests per second do you need to serve? Can MongoDB support the rate of queries you need to do? Are you configuring a MongoDB replica set or a sharded cluster? How many shards do you queries need to visit to get their result? How powerful are the servers hosting each node?
These are some examples of the types of questions you need to understand and analyze for your queries and your MongoDB cluster (the list is not complete).
You don't need to give me the answers to these questions. I'm just using them to illustrate why it's a naive question to ask "will it scale?"
It's like asking "I'm need to drive my car to my brother's house, will I have to refill my fuel tank?" That's not enough information to answer the question. How far away is your brother's house? What type of vehicle do you have? What is its fuel efficiency? Is your vehicle laden with a lot of heavy cargo? How many times do you need to make the trip? How fast are you driving? How rough are the roads on the route?
There are probably many things to consider depending on your needs but i think the main difference comes from the document data model (that MongoDB is made to support and scale on)
Document => more related data in 1 place
fewer joins (expensive especially if data are in different machines)
fewer transactions (single document updates are atomic)
simpler smaller schema, more tailored to your application
data model, similar to the way programmers save their data on
objects(maps)/arrays
If you have many applications or too many different ways to access the same data, maybe you end up normalizing more your data to a more general data representation => losing some of the above benefits or duplicating some of your data to serve the different needs.
So I've been trying hard to figure out if NoSQL is really bringing that much value outside of auto-sharding and handling UNSTRUCTURED data.
Assuming I can fit my STRUCTURED data on a single machine OR have an effective 'auto-sharding' feature for SQL, what advantages do any NoSQL options offer? I've determined the following:
Document-based (MongoDB, Couchbase, etc) - Outside of it's 'auto-sharding' capabilities, I'm having a hard time understanding where the benefit is. Linked objects are quite similar to SQL joins, while Embedded objects significantly bloat doc size and causes a challenge regarding to replication (a comment could belong to both a post AND a user, and therefore the data would be redundant). Also, loss of ACID and transactions are a big disadvantage.
Key-value based (Redis, Memcached, etc) - Serves a different use case, ideal for caching but not complex queries
Columnar (Cassandra, HBase, etc ) - Seems that the big advantage here is more how the data is stored on disk, and mostly useful for aggregations rather than general use
Graph (Neo4j, OrientDB, etc) - The most intriguing, the use of both edges and nodes makes for an interesting value-proposition, but mostly useful for highly complex relational data rather than general use.
I can see the advantages of Key-value, Columnar and Graph DBs for specific use cases (Caching, social network relationship mapping, aggregations), but can't see any reason to use something like MongoDB for STRUCTURED data outside of it's 'auto-sharding' capabilities.
If SQL has a similar 'auto-sharding' ability, would SQL be a no-brainer for structured data? Seems to me it would be, but I would like the communities opinion...
NOTE: This is in regards to a typical CRUD application like a Social Network, E-Commerce site, CMS etc.
If you're starting off on a single server, then many advantages of NoSQL go out the window. The biggest advantages to the most popular NoSQL are high availability with less down time. Eventual consistency requirements can lead to performance improvements as well. It really depends on your needs.
Document-based - If your data fits well into a handful of small buckets of data, then a document oriented database. For example, on a classifieds site we have Users, Accounts and Listings as the core data. The bulk of search and display operations are against the Listings alone. With the legacy database we have to do nearly 40 join operations to get the data for a single listing. With NoSQL it's a single query. With NoSQL we can also create indexes against nested data, again with results queried without Joins. In this case, we're actually mirroring data from SQL to MongoDB for purposes of search and display (there are other reasons), with a longer-term migration strategy being worked on now. ElasticSearch, RethinkDB and others are great databases as well. RethinkDB actually takes a very conservative approach to the data, and ElasticSearch's out of the box indexing is second to none.
Key-value store - Caching is an excellent use case here, when you are running a medium to high volume website where data is mostly read, a good caching strategy alone can get you 4-5 times the users handled by a single server. Key-value stores (RocksDB, LevelDB, Redis, etc) are also very good options for Graph data, as individual mapping can be held with subject-predicate-target values which can be very fast for graphing options over the top.
Columnar - Cassandra in particular can be used to distribute significant amounts of load for even single-value lookups. Cassandra's scaling is very linear to the number of servers in use. Great for heavy read and write scenarios. I find this less valuable for live searches, but very good when you have a VERY high load and need to distribute. It takes a lot more planning, and may well not fit your needs. You can tweak settings to suite your CAP needs, and even handle distribution to multiple data centers in the box. NOTE: Most applications do emphatically NOT need this level of use. ElasticSearch may be a better fit in most scenarios you would consider HBase/Hadoop or Cassandra for.
Graph - I'm not as familiar with graph databases, so can't comment here (beyond using a key-value store as underlying option).
Given that you then comment on MongoDB specifically vs SQL ... even if both auto-shard. PostgreSQL in particular has made a lot of strides in terms of getting unstrictured data usable (JSON/JSONB types) not to mention the power you can get from something like PLV8, it's probably the most suited to handling the types of loads you might throw at a document store with the advantages of NoSQL. Where it happens to fall down is that replication, sharding and failover are bolted on solutions not really in the box.
For small to medium loads sharding really isn't the best approach. Most scenarios are mostly read so having a replica-set where you have additional read nodes is usually better when you have 3-5 servers. MongoDB is great in this scenario, the master node is automagically elected, and failover is pretty fast. The only weirdness I've seen is when Azure went down in late 2014, and only one of the servers came up first, the other two were almost 40 minutes later. With replication any given read request can be handled in whole by a single server. Your data structures become simpler, and your chances of data loss are reduced.
Again in my own example above, for a mediums sized classifieds site, the vast majority of data belongs to a single collection... it is searched against, and displayed from that collection. With this use case a document store works much better than structured/normalized data. The way the objects are stored are much closer to their representation in the application. There's less of a cognitive disconnect and it simply works.
The fact is that SQL JOIN operations kill performance, especially when aggregating data across those joins. For a single query for a single user it's fine, even with a dozen of them. When you get to dozens of joins with thousands of simultaneous users, it starts to fall apart. At this point you have several choices...
Caching - caching is always a great approach, and the less often your data changes, the better the approach. This can be anything from a set of memcache/redis instances to using something like MongoDB, RethinkDB or ElasticSearch to hold composite records. The challenge here comes down to updating or invalidating your cached data.
Migrating - migrating your data to a data store that better represents your needs can be a good idea as well. If you need to handle massive writes, or very massive read scenarios no SQL database can keep up. You could NEVER handle the likes of Facebook or Twitter on SQL.
Something in between - As you need to scale it depends on what you are doing and where your pain points are as to what will be the best solution for a given situation. Many developers and administrators fear having data broken up into multiple places, but this is often the best answer. Does your analytical data really need to be in the same place as your core operational data? For that matter do your logins need to be tightly coupled? Are you doing a lot of correlated queries? It really depends.
Personal Opinions Ahead
For me, I like the safety net that SQL provides. Having it as the central store for core data it's my first choice. I tend to treat RDBMS's as dumb storage, I don't like being tied to a given platform. I feel that many people try to over-normalize their data. Often I will add an XML or JSON field to a table so additional pieces of data can be stored without bloating the scheme, specifically if it's unlikely to ever be queried... I'll then have properties in my objects in the application code that store in those fields. A good example may be a payment... if you are currently using one system, or multiple systems (one for CC along with Paypal, Google, Amazon etc) then the details of the transaction really don't affect your records, why create 5+ tables to store this detailed data. You can even use JSON for primary storage and have computed columns derived and persisted from that JSON for broader query capability and indexing where needed. Databases like postgresql and mysql (iirc) offer direct indexing against JSON data as well.
When data is a natural fit for a document store, I say go for it... if the vast majority of your queries are for something that fits better to a single record or collection, denormalize away. Having this as a mirror to your primary data is great.
For write-heavy data you want multiple systems in play... It depends heavily on your needs here... Do you need fast hot-query performance? Go with ElasticSearch. Do you need absolute massive horizontal scale, HBase or Cassandra.
The key take away here is not to be afraid to mix it up... there really isn't a one size fits all. As an aside, I feel that if PostgreSQL comes up with a good in the box (for the open-source version) solution for even just replication and automated fail-over they're in a much better position than most at that point.
I didn't really get into, but feel I should mention that there are a number of SaaS solutions and other providers that offer hybrid SQL systems. You can develop against MySQL/MariaDB locally and deploy to a system with SQL on top of a distributed storage cluster. I still feel that HBase or ElasticSearch are better for logging and analitical data, but the SQL on top solutions are also compelling.
More: http://www.mongodb.com/nosql-explained
Schema-less storage (or schema-free). Ability to modify the storage (basically add new fields to records) without having to modify the storage 'declared' schema. RDBMSs require the explicit declaration of said 'fields' and require explicit modifications to the schema before a new 'field' is saved. A schema-free storage engine allows for fast application changes, just modify the app code to save the extra fields, or rename the fields, or drop fields and be done.
Traditional RDBMS folk consider the schema-free a disadvantage because they argue that on the long run one needs to query the storage and handling the heterogeneous records (some have some fields, some have other fields) makes it difficult to handle. But for a start-up the schema-free is overwhelmingly alluring, as fast iteration and time-to-market is all that matter (and often rightly so).
You asked us to assume that either the data can fit on a single machine, OR your database has an effective auto-sharding feature.
Going with the assumption that your SQL data has an auto-sharding feature, that means you're talking about running a cluster. Any time you're running a cluster of machines you have to worry about fault-tolerance.
For example, let's say you're using the simplest approach of sharding your data by application function, and are storing all of your user account data on server A and your product catalog on server B.
Is it acceptable to your business if server A goes down and none of your users can login?
Is it acceptable to your business if server B goes down and no one can buy things?
If not, you need to worry about setting up data replication and high-availability failover. Doable, but not pleasant or easy for SQL databases. Other types of sharding strategies (key, lookup service, etc) have the same challenges.
Many NoSQL databases will automatically handle replication and failovers. Some will do it out of the box, with very little configuration. That's a huge benefit from an operational point of view.
Full disclosure: I'm an engineer at FoundationDB, a NoSQL database that automatically handles sharding, replication, and fail-over with very little configuration. It also has a SQL layer so you you don't have to give up structured data.
The task is to filter and analyze a huge amount of logfiles (around 8TB) from a finished research project. The idea is to fill a database with the data to be able to run different analysis tasks later.
The values are stored comma separated. In principle the values are tuples of up to 5 values:
id, timestamp, type, v1, v2, v3, v4, v5
In a first try using MySQL I used one table with one log entry per row. So there is no direct relation between the log values. The downside here is slow querying of subsets.
Because there is no relation I looked into alternatives like NoSQL databases, and column based tables like hbase or cassandra seemed to be a perfect fit for this kind of data. But these systems are made for huge distributed systems, which we not have. In our case the analysis will run on a single machine or perhaps some VMs.
Which kind of database would fit this task? Is it worth to setup a single machine instance with hadoop+hbase... or is this all a bit over-sized?
What database would you choose to do high-performance logfile analysis?
EDIT: Maybe out of my question it is not clear that we cannot spend money for cloud services or new hardware. The Question is if there are benefits in using noSQL approaches instead of mySQL (especially for this data). If there are none, or if they are so small that the effort of setting up a noSQL system is not worth the benefit we can use our ESXi infrastructure and MySQL.
EDIT2: I'm still having the Problem here. I did further experiments with MySQL and just inserted a quarter of all available data. The insert is now running for over 2 days and is not yet finished. Currently there are 2,147,483,647 rows in my single table db. With indeces this takes 211,2 GiB of disk space. And this is just a quarter of all logging data...
A query of the form
SELECT * FROM `table` WHERE `timestamp`>=1342105200000 AND `timestamp`<=1342126800000 AND `logid`=123456 AND `unit`="UNIT40";
takes 761 seconds to complete, in this case returning one row.
There is a combined index on timestamp, logid, unit.
So I think this is not the way to go, because later in analysis I will have to get all entries in a time range and compare the datapoints.
I read bout MongoDB and Redis, but the problem with them is, that they are in Memory databases.
In the later analyzing process there will a very small amount of concurrent database access. In fact the analyzing will be run from one single machine.
I do not need redundancy. I would be able to regenerate the database in case of a failure.
When the database is once completely written, there would also be no need to update or add further row.
What do you think about alternatives like Redis, MongoDB and so on. When I get this right, i would need RAM in the dimension of my data...
Is this task even somehow possible with a single node system or with maybe two nodes?
well i personally would prefer the faster solution, as you said you need a high-perfomance analysis. the problem is, if you have to setup a whole new system to do so and the performance-improvement would be minor in relation to the additional effort you'd need, then stay with SQL.
in our company, we have a quite small Database containing not even half a GB of Data on the VM. the problem now is, as soon as you use a VM, you will have major performance issues, when opening the Database on VM you can go for a coffee in the meantime ;)
But if the time until the Database is loaded to cache is not so important it doesn't matter. It all depends on how much faster you think the new System will be, and how much effort you will have to put in it, but as i said i'd prefer the faster solution if you have to go for "high-performance analysis"
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I have developed a website which provides very generic data storage. Currently it works just fine but I am thinking about optimizing the speed.
INSERT/SELECT ratio is hard to predict and changes for different cases but usually SELECT is more often. INSERTs are fast enough. SELECTs are what worries me. There are a lot of LEFT JOINs. E.g. each object can have a image which is stored in separate table (as it can span across multiple objects) and stores additional information about the image as well.
Up to 8 joins are made every select and it can take up to 1 seconds to process - mean value is around 0.3s. There can be multiple of such selects for every request. It has already been optimized multiple times on SQL side and there is not much that can be done there.
Other than buying more powerful machine for DB, what can be done (if anything)?
Django is not a speed demon here as well but we still got some optimizations left there. Switch to PyPy if we must. On DB side I had a few ideas but there they seem to be uncommon - couldn't find any real case scenario.
Use different storage for this part that's faster. We need transactions and we need consistency checks so it may not be preferable.
Searchable cache? Does it make any sense here? E.g. maintain a flat copy of all tables combined in NoSQL or something. Inserts would be more expensive - it needs to update multiple records in NoSQL if some common table changes. Tough to maintain as well.
Is there anything that would make sense or is it just the fastest that can get and just get more RAM, increase cache size in rdbms, get SSD and leave it. Focus on optimizing other parts like pooling database connections as they are expensive as well.
Technologies used: PostgreSQL 9.1 and Django (python).
To summarize. Question is: after optimizing all SQL part - indexes, clustering etc. What can be done to optimize further when static timeout cache for results is not an option (different request arguments, different results anyway).
---EDIT 30-08-2012---
We are already using checking slow queries on a daily basis. This IS our bottleneck. We only order and filter on indexes. Also, sorry for not being clear about this - we don't store actual images in db. Just file paths.
JOINs and ORDER BY are killing our performance here. E.g. one complex query that spits out 20 000 results takes 1800ms (EXPLAIN ANALYZE used). And this assumes that we are not using any kind of filtering based on JOINed tables.
If we skip all the JOINS we are down to 110ms. That's insane... That's why we are thinking of some kind of searchable cache or flat copy NoSQL.
Without ordering we got 60ms which is great but what's with the JOIN performance in PostgreSQL?
Is there some different DB that can do better for us? Preferably free one.
First, although I think that there are times and places to store image files in the database, in general you are going to have extra I/O and memory associated with this sort of operation. If I was looking at optimizing this I would put every image with a path and be able to bulk save these to the fs. This way they are still in your db for backup purposes but you can just pull the relative path out and generate links, thus saving you a bunch of sql queries and reducing overhead. Over a web-based backend you aren't going to be able to get transactions working really well between generating the HTML and retrieving the image anyway since these come in under different HTTP requests.
As for speed, I can't tell if you are looking at total http request time or db time. But the first thing you need to do is break everything apart and look for where most of your time is being spent. This may surprise you. The next thing is to get query plans of those queries which are slow queries:
http://heatware.net/databases/how-to-find-log-slow-queries-postgresql/
Then from there, start using explain analyze to find out what is the problem.
Also in deciding to upgrade hardware you want to have a good idea of where you are currently facing limits. More RAM helps generally (and it is helpful if your db can fit comfortably in RAM), but beyond that it makes no sense to put faster storage in a cpu-bound server or switch to a server with faster cpu's in an I/O bound server. top is your friend there. Similarly depending on the concurrency issues, it might (or might not!) make sense to use a hot standby for your select statements.
But without a lot more information I can't tell you what the best way to go about further optimizing your db is. PostgreSQL is capable of running really fast under the right conditions and scaling very well.
I inhereted a high volume OLTP DB which I have free reign to improve as much as I find reasonably possible. The improvements already were very helpful but I want to take it to the next level. The data access patterns I found made it a good candidate IMO to cache the data on other servers and I would love to hear anyone's experience or recommendations with this type of setup.
We have a DB that gets about 3GB of data added to a table every day and reporting on it used to be very slow. The data does not change once it's put in, and no data gets inserted that is over a week old. Rows inputted within the last 3 days tend to see thousands of inserts between tens of millions of rows.
I was thinking of having data over 2 weeks old get pushed out to MongoDB. I could then have the 2 week sliding window data that is not pushed out to Mongo be, be cached by some kind of caching software so those get queried and displayed instead of the data being read out of the DB the whole time. I figure this way we still get full A.C.I.D compliance by having the DB engine validate all the data, have high read performance as it is not hitting the DB, then Mongo can take it when it is no longer a 'transaction'.
Anyone have any recommended solutions? I was looking at MemCached, but not quite sure if that's a good or even plausible solution. Thanks!
Another thing you could consider is using the new In-Memory OLTP feature in SQL Server 2014. That feature improves efficiency and scaling for OLTP workloads. You will potentially be able to get a lot more out of your existing server, without the need to consider specific caching mechanisms.
I don't have specific experience with SQL Server, but what you are describing does seem like a valid use case for MongoDB.
Note that while MongoDB can't directly handle transactions, it is capable of handling certain operations in an atomic fashion (see findAndModify, for instance). Additionally, with journaling enabled, you shouldn't have any reason to worry about durability. MongoDB is a reliable data store and will not lose or corrupt your data.
MongoDB itself can also act as a performant cache if you run a second deployment with journaling disabled. In this instance, writes will take place in memory and only be persisted to the disk every 60 seconds (unless otherwise configured). This will provide comparable performance to memcache which is solely in-memory while allowing you to keep your stack a bit simpler.
Hope this helps!