For many storage managers though the trade-off of efficiency is worth the gain in cost effective scalability. After all processing performance is relatively cheap today and power is a budget-able item that many can choose to live with. However, when scale out storage systems grow in size or as they try to appeal to small to mid-range data centers, suppliers need to address the challenges of poor resource utilization. The goal should be to increase the efficiency of each node in terms of processing resources, power and foot print.
There are ways to make scale out storage systems more resource, space and power efficient. First, if the scale out storage system is going to be focused on a nonperformance sensitive environments like most file sharing use cases then using a lower power processor might be a good alternative. For example we recently were briefed by a supplier that used Intel's ATOM processors. Using this processor increases the utilization per node while it decreases power utilization. Utilizing smart packaging will allow these cooler (from a temperature perspective) processors to run in tighter spaces which would lead to better floor space efficiency as well.
Another option is to, instead of making all the CPU resources of the physical server a node, subdivide that server into multiple nodes. For example we see increasing popularity to make each processor core a node as we discuss in a recent briefing report. That means for the same investment in server hardware you could end up with four or more nodes, all working much harder and being more efficient in their utilization. We also were recently briefed on another way to accomplish this which would to be able to run the clustered storage software as a virtual machine and allocate one virtual machine on each physical host to assemble your scale out storage. This would mean zero additional footprint.
A final option is to just make the expected workload of the node higher. Typically when you need more performance out of scale-out clustering the answer is to add more nodes so that more drives are available to respond to I/O requests. The individual nodes are not working harder, there are just more nodes to process the I/O. Mechanical storage inside a node will struggle with keeping that node's processor busy. There is too much latency. By comparison, zero latent technology like solid state drives can keep the node's processors very busy. The result is you have less nodes working harder, delivering the same or better I/O rates.
The other option is to provide better scaling within traditional non scale out (often called scale up) architectures. We will cover those options in an upcoming entry.
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George Crump is lead analyst of Storage Switzerland, an IT analyst firm focused on the storage and virtualization segments. Find Storage Switzerland's disclosure statement here.