Very quick answer: memory is being freed,
rss is not a very accurate tool for telling where the memory is being consumed,
rss gives a measure of the memory the process has used, not the memory the process is using (keep reading to see a demo), you can use the package memory-profiler in order to check line by line, the memory use of your function.
So, how to force Django models to be released from memory? You can't tell have such problem just using
I can, however, propose a solution for you to optimize your code. And write a demo on why
process.memory_info().rss is not a very accurate tool to measure memory being used in some block of code.
Proposed solution: as demonstrated later in this same post, applying
del to the list is not going to be the solution, optimization using
iterator will help (be aware
chunk_size option for
iterator was added in Django 2.0), that's for sure, but the real enemy here is that nasty list.
Said that, you can use a list of just fields you need to perform your analysis (I'm assuming your analysis can't be tackled one building at the time) in order to reduce the amount of data stored in that list.
Try getting just the attributes you need on the go and select targeted buildings using the Django's ORM.
for zip in zips.iterator(): # Using chunk_size here if you're working with Django >= 2.0 might help.
important_buildings = Building.objects.filter(
# Some conditions here ...
# You could even use annotations with conditional expressions
# as Case and When.
# Also Q and F expressions.
# It is very uncommon the use case you cannot address
# with Django's ORM.
# Ultimately you could use raw SQL. Anything to avoid having
# a list with the whole object.
# And then just load into the list the data you need
# to perform your analysis.
# Analysis according size.
data = important_buildings.values_list('size', flat=True)
# Analysis according height.
data = important_buildings.values_list('height', flat=True)
# Perhaps you need more than one attribute ...
# Analysis according to height and size.
data = important_buildings.values_list('height', 'size')
# Etc ...
It's very important to note that if you use a solution like this, you'll be only hitting database when populating
data variable. And of course, you will only have in memory the minimum required for accomplishing your analysis.
Thinking in advance.
When you hit issues like this you should start thinking about parallelism, clusterization, big data, etc ... Read also about ElasticSearch it has very good analysis capabilities.
process.memory_info().rss Won't tell you about memory being freed.
I was really intrigued by your question and the fact you describe here:
It seems like the important_buildings list is hogging up memory, even after going out of scope.
Indeed, it seems but is not. Look the following example:
from psutil import Process
a = 
for i in range(10000):
print(process.memory_info().rss) # Prints 29728768
print(process.memory_info().rss) # Prints 30023680
So even if
a memory is freed, the last number is bigger. That's because
memory_info.rss() is the total memory the process has used, not the memory is using at the moment, as stated here in the docs: memory_info.
The following image is a plot (memory/time) for the same code as before but with
I use the script
mprof that comes in memory-profiler for this graph generation.
You can see the memory is completely freed, is not what you see when you profile using
If I replace important_buildings.append(building) with _ = building use less memory
That's always will be that way, a list of objects will always use more memory than a single object.
And on the other hand, you also can see the memory used don't grow linearly as you would expect. Why?
From this excellent site we can read:
The append method is “amortized” O(1). In most cases, the memory required to append a new value has already been allocated, which is strictly O(1). Once the C array underlying the list has been exhausted, it must be expanded in order to accommodate further appends. This periodic expansion process is linear relative to the size of the new array, which seems to contradict our claim that appending is O(1).
However, the expansion rate is cleverly chosen to be three times the previous size of the array; when we spread the expansion cost over each additional append afforded by this extra space, the cost per append is O(1) on an amortized basis.
It is fast but has a memory cost.
The real problem is not the Django models not being released from memory. The problem is the algorithm/solution you've implemented, it uses too much memory. And of course, the list is the villain.
A golden rule for Django optimization: Replace the use of a list for querisets wherever you can.