I am trying to figure out a situation where PHP is not consuming a lot of memory but instead causes a very high
Take this munin memory report for example:
As soon as I kick off our Laravel queue (10 ~ 30 workers), committed memory goes through the roof. We have 2G mem + 2G swap on this vps instance and so far there are about 600M unused memory (that's about 30% free).
If I understand
Committed_AS correctly, it's meant to be a 99.9% guarantee no
out of memory issue given current workload, and it seems to suggest we need to triple our vps memory just to be safe.
I tried to reduce the number of queues from 30 to around 10, but as you can see the green line is quite high.
As for the setup: Laravel 4.1 with PHP 5.5 opcache enabled. The upstart script we use spawn instance like following:
instance $N exec start-stop-daemon --start --make-pidfile --pidfile /var/run/laravel_queue.$N.pid --chuid $USER --chdir $HOME --exec /usr/bin/php artisan queue:listen -- --queue=$N --timeout=60 --delay=120 --sleep=30 --memory=32 --tries=3 >> /var/log/laravel_queue.$N.log 2>&1
I have seen a lot of cases when high swap use imply insufficient memory, but our swap usage is low, so I am not sure what troubleshooting step is appropriate here.
PS: we don't have this problem prior to Laravel 4.1 and our vps upgrade, here is an image to prove that.
Maybe I should rephrase my question as: how are Committed_AS calculated exactly and how does PHP factor into it?
I had a theory on this problem: since laravel queue worker actually use PHP
sleep() when waiting for new job from queue (in my case
beanstalkd), it would suggest the high
Committed_AS estimation is due to the relatively low workload and relatively high memory consumption.
This make sense as I see
avg. memory usage / avg. workload. As PHP
sleep() properly, little to no CPU are used; yet whatever memory it consumes is still reserved. Which result in server thinking: hey, you use so much memory (on average) even when load is minimal (on average), you should be better prepared for higher load (but in this case, higher load doesn't result in higher memory footprint)
If anyone would like to test this theory, I will be happy to award the bounty to them.