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PostgreSQL 9 High Availability Cookbook

You're reading from   PostgreSQL 9 High Availability Cookbook Over 100 recipes to design and implement a highly available server with the advanced features of PostgreSQL.

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Product type Paperback
Published in Jul 2014
Publisher Packt
ISBN-13 9781849516969
Length 398 pages
Edition 1st Edition
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Author (1):
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Shaun Thomas Shaun Thomas
Author Profile Icon Shaun Thomas
Shaun Thomas
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Table of Contents (12) Chapters Close

Preface 1. Hardware Planning FREE CHAPTER 2. Handling and Avoiding Downtime 3. Pooling Resources 4. Troubleshooting 5. Monitoring 6. Replication 7. Replication Management Tools 8. Advanced Stack 9. Cluster Control 10. Data Distribution Index

Making the most of memory

The primary focus when selecting memory for a highly available system is stability. It's no accident that most, if not all, server-class RAM is of the error-correcting variety. There are a few other things to consider, which may not appear obvious at first glance.

Due to the multi-core nature of our CPUs, the amount of addressable memory may depend on the core count. In addition, speed, latency, and parity are all considerations. We also must consider the number of channels reported by each CPU; failing to match this with an equal count of memory sticks will drastically reduce performance.

Let's make our server fast and stable by considering our memory options.

Getting ready

Some of the decisions we will make depend on the capabilities of the CPU. Make sure to read through the Picking a processor recipe before continuing. If we have a PostgreSQL database available, there's also a query that can prepare us for selecting the most advantageous count of memory modules. It's also a very good idea to complete the Sizing storage recipe to get a better idea for choosing an amount of memory.

How to do it...

We can collect some of the information we want from PostgreSQL if we have an install already. Follow these steps if there's an existing database install that we can use:

  1. Execute the following query to obtain the size of all databases in the instance:
    SELECT pg_size_pretty(sum(pg_database_size(oid))::BIGINT)
      FROM pg_database;
  2. Multiply the result by eight.

If we don't have an existing database, we should use a size estimate of the database install after three years. Refer to the Sizing storage recipe to obtain this estimate. Then, perform the following steps:

  1. Divide the current or estimated database storage size by ten to obtain the minimum amount of memory.
  2. Multiply our ideal CPU chip count by four to get the memory module count.
  3. Divide the minimum memory amount by the module count to get the minimum module size.
  4. Round up to the nearest available memory module size.

How it works...

The important part of this recipe is starting with a viable estimate of the database size. Since a lack of RAM won't cause the database to crash or operate improperly, we can use looser guidelines to obtain this number. Hence, three years down the road, an existing database install could be eight times larger than its current size.

Why do we then divide that number by ten? Our goal here is to maximize the benefit of the OS-level cache, which will consume a majority of our RAM. This estimate gives us a value that is ten times smaller than the space our database consumes. At this scale, data that is frequently fetched from disk is likely to be served from memory instead. The alternative is read latency due to insufficient memory for disk caching.

Most current CPUs are quad-channel, and thus operate best when the number of modules per processor is a multiple of four. Since we should have determined how many processor cores would be ideal for our system in the Picking a processor recipe, we automatically know the most efficient memory module count. Why do we multiply by four, regardless of how many memory channels the CPU has? Adding more memory modules is not wasted on chips with fewer channels, and provides a possible upgrade path.

Dividing the memory amount by the module count gives our minimum module size. RAM comes in many dimensions, and our calculation is not likely to match any of the available dimensions for purchase, so we need to round up. Why not round down? The operating system will utilize all available RAM to cache and buffer important data. Unless the greater amount is extremely expensive in comparison, any excess memory will not be wasted.

There's more...

We didn't focus on memory speed, timings, or latency here. Timing and latency can affect performance, but our primary focus is stability. We're always free to order faster or better memory as our budget allows.

Memory speed, on the other hand, is a more visible factor. Every memory speed works with a multiplier to match the highest compatible motherboard bus speed. This directly controls how quickly the CPU can utilize available RAM. Before buying memory, research the stated clock speed and try to match it with one of the faster settings compatible with both the CPU and motherboard.

For example, DDR3-1600 is twice as fast as DDR3-800 since it operates at 200 MHz, as opposed to 100 MHz. Database benchmarks would be vastly different between these two memory speeds, even with the same CPU. Fast memory means PostgreSQL can make more immediate use of cached data, and produce results more quickly.

You have been reading a chapter from
PostgreSQL 9 High Availability Cookbook
Published in: Jul 2014
Publisher: Packt
ISBN-13: 9781849516969
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