We've written a Windows service, which fires off separate worker processes to perform various CPU-intensive tasks. The server and workers communicate via IPC named pipes.
At present, we create the workers via a simple
When we run up a number of workers on a fairly low-spec'd dual core server VM, Task Manager tells us that each worker uses approximately 2 - 3% CPU.
However (this is thing that's confusing us), when we perform the same test on a very powerful eight-core server, we still see each worker process using 2 - 3% CPU. Now, because there is more CPU 'power' available, I would expect to see each worker using a much smaller percentage of CPU.
This also means that on the low-powered server we hit 100% CPU after 30ish worker processes are created. But on the high-powered CPU, we hit the same limit after the same number of workers. We would expect to be able to run far more workers.
So, I have a couple of questions:
Are we misunderstanding the values that Task Manager is telling us? The CPU % value is the amount of CPU time consumed across all cores? If so, why is it the same on vastly different hardware?
Should we be doing something special / different to properly distribute our worker processes across multiple cores? At the moment, the processes have the default processor affinity (so they are able to run on any core).
Any help, advice, links, would be greatly appreciated.
Some extra info for people who have left comments:
I didn't mention it initially as I didn't necessarily want to add extra complexity to my question, but our worker processes are doing video transcoding of live video streams. As such, no worker ever 'completes' its task - it simply works for as long as a client is connected.
- A client connects to the server
- The server fires off a worker process which connects to a remote video stream
- When video is received from said video stream, the worker transcodes it and sends the transcoded video back to the client.
Not sure if this helps with any other suggestions? Thanks for all the comments so far.