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I have a python script which read a file line by line and look if each line matches a regular expression.

I would like to improve the performance of that script by using memory map the file before I search. I have looked into mmap example: http://docs.python.org/2/library/mmap.html

My question is how can I mmap a file when it is too big (15GB) for the memory of my machine (4GB)

I read the file like this:

fi = open(log_file, 'r', buffering=10*1024*1024)

for line in fi: 
    //do somemthong

fi.close()

Since I set the buffer to 10MB, in terms of performance, is it the same as I mmap 10MB of file?

Thank you.

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2  
make sure the IO is performance bottleneck and not the regex search or some other operation in your program. –  J.F. Sebastian Jan 12 '13 at 2:19
    
@J.F.Sebastian: +1. Doing a Python loop with an re.search (and an implicit find('\n') equivalent) once per 80 characters, vs. once per 10MB, may be enough CPU work to dwarf the IO costs and make the rest of the question irrelevant. I updated my answer to take that into account. –  abarnert Jan 12 '13 at 2:38

1 Answer 1

up vote 13 down vote accepted

First, the memory of your machine is irrelevant. It's the size of your process's address space that's relevant. With a 32-bit Python, this will be somewhere under 4GB. With a 64-bit Python, it will be more than enough.

The reason for this is that mmap isn't about mapping a file into physical memory, but into virtual memory. An mmapped file becomes just like a special swap file for your program. Thinking about this can get a bit complicated, but the Wikipedia links above should help.

So, the first answer is "use a 64-bit Python". But obviously that may not be applicable in your case.

The obvious alternative is to map in the first 1GB, search that, unmap it, map in the next 1GB, etc. The way you do this is by specifying the length and offset parameters to the mmap method. For example:

m = mmap.mmap(f.fileno(), length=1024*1024*1024, offset=1536*1024*1024)

However, the regex you're searching for could be found half-way in the first 1GB, and half in the second. So, you need to use windowing—map in the first 1GB, search, unmap, then map in a partially-overlapping 1GB, etc.

The question is, how much overlap do you need? If you know the maximum possible size of a match, you don't need anything more than that. And if you don't know… well, then there is no way to actually solve the problem without breaking up your regex—if that isn't obvious, imagine how you could possibly find a 2GB match in a single 1GB window.

Answering your followup question:

Since I set the buffer to 10MB, in terms of performance, is it the same as I mmap 10MB of file?

As with any performance question, if it really matters, you need to test it, and if it doesn't, don't worry about it.

If you want me to guess: I think mmap may be faster here, but only because (as J.F. Sebastian implied) looping and calling re.match 128K times as often may cause your code to be CPU-bound instead of IO-bound. But you could optimize that away without mmap, just by using read. So, would mmap be faster than read? Given the sizes involved, I'd expect the performance of mmap to be much faster on old Unix platforms, about the same on modern Unix platforms, and a bit slower on Windows. (You can still get large performance benefits out of mmap over read or read+lseek if you're using madvise, but that's not relevant here.) But really, that's just a guess.

The most compelling reason to use mmap is usually that it's simpler than read-based code, not that it's faster. When you have to use windowing even with mmap, and when you don't need to do any seeking with read, this is less compelling, but still, if you try writing the code both ways, I'd expect your mmap code would end up a bit more readable. (Especially if you tried to optimize out the buffer copies from the obvious read solution.)

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1  
Good answer, but IMHO could have been even better if you'd explained why it is address space rather than amount of physical memory in the machine that matters. –  martineau Jan 12 '13 at 2:53
    
@martineau: Good idea. I tried, but… it's tricky to explain this stuff, especially if you don't know how much the audience already knows. If the last paragraph is an unreadable mess, I wouldn't be too surprised. Any suggestions for improvement? –  abarnert Jan 12 '13 at 20:16
    
What you added seems a little too detailed. I guess it could be summed up into it's address space that matters more because that's how much memory your computer can access without using some trickery, and this already has to hold your operating system, running programs, and non-memory-mapped data. If you memory-map a file, the whole thing will need to fit into what's free within that space. On a 32-bit system there's just no way to fit a 15 GB file into the < 4 GB address space available, so directly memory-mapping the while file is simply impossible. –  martineau Jan 12 '13 at 21:02
    
@martineau: Um… what you just summed up is wrong. I'm not sure whether you're talking about physical memory, or about master page table space, but neither of those is relevant here. The address space is how much memory each process can access, not the computer as a whole. Other running programs and their data are irrelevant. And so are 32- vs. 64-bit systems—if you run a 32-bit process on a 64-bit system, it still only has a 4GB address space. –  abarnert Jan 12 '13 at 21:27
    
My example was about the 4 GB virtual address space available to processes running under a 32-bit OS. I consider things like the page table part of the OS. I may have said "computer" instead of the more-correct term "process". The illustrations in the linked article show what I was trying to describe -- namely that everything, including memory-mapped files, would have to fit within 4 GB in such a scenario. –  martineau Jan 13 '13 at 1:02

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