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I am running some large array processing code (on a Pentium running Linux). The sizes of the arrays are large enough for the processes to swap. So far it is working, probably because i try to keep my read and writes contiguous. However, I will soon need to handle larger arrays. In this scenario, would switching over to anonymous mmapped blocks help ?

If so would you please explain why.

In my shallow understanding, mmap implements a memory mapped file mounted from a tmpfs partition which under memory pressure would fall back to the swapping mechanism. What I would like to understand is how does mmap do it better than the standard malloc (for the sake or argument I am assuming that it is indeed better, I do not know if it is so).

Note: Please do not suggest getting a 64 bit and more RAM. That, unfortunately, is not an option.

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try benchmarking... –  Mitch Wheat Nov 24 '11 at 23:33
I suggest switching to... ah nevermind. Just wait for the cat to bark. Also, profile, profile, profile. I don't anticipate there would be any difference, but depending on your usage patterns, there might be. –  sehe Nov 24 '11 at 23:34
@Mitch Wheat The mmaped interface is unimplemented. Before implementing it I want to know if there is a realistic chance of it doing better and why –  san Nov 24 '11 at 23:34

2 Answers 2

up vote 8 down vote accepted

The memory that backs your malloc() allocations is handled by the kernel in much the same way as the memory that backs private anonymous mappings created with mmap(). In fact, for large allocations malloc() will create an anonymous mapping with mmap() to back it anyway, so you are unlikely to see much difference by explicitly using mmap() yourself.

At the end of the day, if your working set exceeds the physical memory size then you will need to use swap, and whether you use anonymous mappings created with mmap() or malloc() is not going to change that. The best thing you can do is to try and refactor your algorithm so that it has good locality of reference, which will reduce the extent to which swap hurts you.

You can also try to give the kernel some hints about your usage of the memory with the madvise() system call.

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Thanks, and am I correct to assume that kernel's swapping mechanism is better than mapping a disk based file. –  san Nov 25 '11 at 0:16
@san: The mechanisms used by the kernel to write out dirty pages to a file-backed mapping or a swap-backed mapping are actually very closely related. The advantage of using a file-backed mapping is that you can place the file on a device that you know is faster than swap. –  caf Nov 25 '11 at 0:41
It is considered good SO etiquette to leave a comment explaining why when you downvote an answer. –  caf Nov 25 '11 at 4:25

The key difference here is that with malloc(3)-ed input buffers you ask the kernel to copy the data from file-mapped pages that are already in memory, while with mmap(2) you just use those pages. The first approach doubles the amount of physical memory required to back up both your and in-kernel buffers, while the second approach shares that physical memory and only increases number of virtual mappings for the useland process.

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This is for memory-mapped files. The OP is specifically talking about anonymous mmaps, i.e. no backing file. There is no zero-copy path involved –  sehe Nov 24 '11 at 23:52
Thanks. Is this the case when malloc internally uses a memory mapped file, or is it always the case for malloc ? I am not trained in CS so these may be very basic questions. And with anonymous mmap there is no on disk filemapping right ? Just that s region of RAM is given a file interface and that file interface is used for the file mapping. –  san Nov 24 '11 at 23:53
Yes, I missed the 'anonymous' qualifier. See @caf's answer for that case. My answer applies for memory-mapping portions of the file. –  Nikolai N Fetissov Nov 25 '11 at 3:35

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