POSIX environments provide at least two ways of accessing files. There's the standard system calls open(), read(), write(), and friends, but there's also the option of using mmap() to map the file into virtual memory.

When is it preferable to use one over the other? What're their individual advantages that merit including two interfaces?


6 Answers 6


mmap is great if you have multiple processes accessing data in a read only fashion from the same file, which is common in the kind of server systems I write. mmap allows all those processes to share the same physical memory pages, saving a lot of memory.

mmap also allows the operating system to optimize paging operations. For example, consider two programs; program A which reads in a 1MB file into a buffer created with malloc, and program B which mmaps the 1MB file into memory. If the operating system has to swap part of A's memory out, it must write the contents of the buffer to swap before it can reuse the memory. In B's case any unmodified mmap'd pages can be reused immediately because the OS knows how to restore them from the existing file they were mmap'd from. (The OS can detect which pages are unmodified by initially marking writable mmap'd pages as read only and catching seg faults, similar to Copy on Write strategy).

mmap is also useful for inter process communication. You can mmap a file as read / write in the processes that need to communicate and then use synchronization primitives in the mmap'd region (this is what the MAP_HASSEMAPHORE flag is for).

One place mmap can be awkward is if you need to work with very large files on a 32 bit machine. This is because mmap has to find a contiguous block of addresses in your process's address space that is large enough to fit the entire range of the file being mapped. This can become a problem if your address space becomes fragmented, where you might have 2 GB of address space free, but no individual range of it can fit a 1 GB file mapping. In this case you may have to map the file in smaller chunks than you would like to make it fit.

Another potential awkwardness with mmap as a replacement for read / write is that you have to start your mapping on offsets of the page size. If you just want to get some data at offset X you will need to fixup that offset so it's compatible with mmap.

And finally, read / write are the only way you can work with some types of files. mmap can't be used on things like pipes and ttys.

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    Can you use mmap() on files that are growing? Or is the size fixed at the point when you allocate the mmap() memory/file? Commented Nov 3, 2008 at 23:44
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    When you make the mmap call you have to specify a size. So if you want to do something like a tail operation it's not very suitable. Commented Nov 4, 2008 at 2:13
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    Afaik MAP_HASSEMAPHORE is specific to BSD. Commented May 24, 2010 at 8:13
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    @JonathanLeffler Certainly you can use mmap() on files that are growing, but you have to call mmap() again with the new size when the file reaches the limit of the space you initially allocated. LevelDB's PosixMmapFile give you a good example. But it stopped using mmap from 1.15. You can get the old version from Github
    – baotiao
    Commented Mar 4, 2015 at 9:16
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    mmap could also be useful in case a file needs to be processed in multiple passes : the cost of allocating virtual memory pages is only paid once.
    – Jib
    Commented Dec 7, 2016 at 13:26

One area where I found mmap() to not be an advantage was when reading small files (under 16K). The overhead of page faulting to read the whole file was very high compared with just doing a single read() system call. This is because the kernel can sometimes satisify a read entirely in your time slice, meaning your code doesn't switch away. With a page fault, it seemed more likely that another program would be scheduled, making the file operation have a higher latency.

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    +1 I can confirm that. For small files it's faster to malloc a piece of memory and making 1 read into it. This allows to have the same code that handles memory maps handle malloc'ed . Commented May 24, 2010 at 8:18
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    This said, your justification for it is not right. The scheduler has nothing at all to do with the difference. The difference comes from the write accesses to the page tables, which is a global structure of the kernel holding what processes hold which memory page and its access rights. This operation can be very costly (it can invalided cache lines, it can through away TLB, the table is global so has to be protected against concurrent access, etc.). You need a certain size of map so that the overhead of read accesses is higher than the overhead of virtual memory manipulation. Commented May 24, 2010 at 8:36
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    @PatrickSchlüter Okay, I understand that there is overhead at the start of mmap() which involves modifying the page table. Say we map 16K of a file to memory. For a page size of 4K, mmap has to update 4 entries in the page table. But using read to copy into a buffer of 16K also involves updating 4 page table entries, not to mention it needs to copy the 16K into the user addr space. So could you elaborate on the differences of operations on the page table, and how it's more expensive for mmap?
    – flow2k
    Commented Aug 24, 2018 at 7:44
  • mmap reloads some pages, so reading smaller files won't necessarily page fault
    – FloweyTF
    Commented Sep 26, 2021 at 15:53

mmap has the advantage when you have random access on big files. Another advantage is that you access it with memory operations (memcpy, pointer arithmetic), without bothering with the buffering. Normal I/O can sometimes be quite difficult when using buffers when you have structures bigger than your buffer. The code to handle that is often difficult to get right, mmap is generally easier. This said, there are certain traps when working with mmap. As people have already mentioned, mmap is quite costly to set up, so it is worth using only for a given size (varying from machine to machine).

For pure sequential accesses to the file, it is also not always the better solution, though an appropriate call to madvise can mitigate the problem.

You have to be careful with alignment restrictions of your architecture(SPARC, itanium), with read/write IO the buffers are often properly aligned and do not trap when dereferencing a casted pointer.

You also have to be careful that you do not access outside of the map. It can easily happen if you use string functions on your map, and your file does not contain a \0 at the end. It will work most of the time when your file size is not a multiple of the page size as the last page is filled with 0 (the mapped area is always in the size of a multiple of your page size).


In addition to other nice answers, a quote from Linux system programming written by Google's expert Robert Love:

Advantages of mmap( )

Manipulating files via mmap( ) has a handful of advantages over the standard read( ) and write( ) system calls. Among them are:

  • Reading from and writing to a memory-mapped file avoids the extraneous copy that occurs when using the read( ) or write( ) system calls, where the data must be copied to and from a user-space buffer.

  • Aside from any potential page faults, reading from and writing to a memory-mapped file does not incur any system call or context switch overhead. It is as simple as accessing memory.

  • When multiple processes map the same object into memory, the data is shared among all the processes. Read-only and shared writable mappings are shared in their entirety; private writable mappings have their not-yet-COW (copy-on-write) pages shared.

  • Seeking around the mapping involves trivial pointer manipulations. There is no need for the lseek( ) system call.

For these reasons, mmap( ) is a smart choice for many applications.

Disadvantages of mmap( )

There are a few points to keep in mind when using mmap( ):

  • Memory mappings are always an integer number of pages in size. Thus, the difference between the size of the backing file and an integer number of pages is "wasted" as slack space. For small files, a significant percentage of the mapping may be wasted. For example, with 4 KB pages, a 7 byte mapping wastes 4,089 bytes.

  • The memory mappings must fit into the process' address space. With a 32-bit address space, a very large number of various-sized mappings can result in fragmentation of the address space, making it hard to find large free contiguous regions. This problem, of course, is much less apparent with a 64-bit address space.

  • There is overhead in creating and maintaining the memory mappings and associated data structures inside the kernel. This overhead is generally obviated by the elimination of the double copy mentioned in the previous section, particularly for larger and frequently accessed files.

For these reasons, the benefits of mmap( ) are most greatly realized when the mapped file is large (and thus any wasted space is a small percentage of the total mapping), or when the total size of the mapped file is evenly divisible by the page size (and thus there is no wasted space).

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    "For small files, a significant percentage of the mapping may be wasted.". No space is wasted in mmap case. The kernel will map the file in a page for the file cache in ALL cases. If your app uses mmap or not. With the mmap, at least you can avoid a local buffer to copy your data into. mmap, in reality gives just access to the file cache. Commented Oct 21, 2020 at 13:58
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    The mapping overhead is also present with file I/O as the kernel does map the file into its file cache in any case. The mmap overhead consists only in giving access rights to the mapped page to the requesting process. The page buildup and disk read are done in all cases. Commented Oct 21, 2020 at 14:02

Memory mapping has a potential for a huge speed advantage compared to traditional IO. It lets the operating system read the data from the source file as the pages in the memory mapped file are touched. This works by creating faulting pages, which the OS detects and then the OS loads the corresponding data from the file automatically.

This works the same way as the paging mechanism and is usually optimized for high speed I/O by reading data on system page boundaries and sizes (usually 4K) - a size for which most file system caches are optimized to.

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    Note that mmap() is not always faster than read(). For sequential reads, mmap() will give you no measurable advantage - this is based on empirical and theoretical evidence. If you don't believe me, write your own test.
    – Tim Cooper
    Commented Dec 9, 2008 at 4:40
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    I can give numbers coming from our project, a kind of text index for a phrase database. The index is several Gigabyte big and the keys are held in a ternary tree. The index is still growing in parallel to read access, access outside the mapped parts are made via pread. On Solaris 9 Sparc (V890) the pread access are between 2 and 3 times slower than the memcpy from the mmap. But you're right that sequential access are not necessarly faster. Commented May 24, 2010 at 8:25
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    Just a little nitpick. It doesn't work like the paging mechanism, it is the paging mechanism. Mapping a file is assigning a memory area to a file instead of the anonymous swap file. Commented May 24, 2010 at 8:59

An advantage that isn't listed yet is the ability of mmap() to keep a read-only mapping as clean pages. If one allocates a buffer in the process's address space, then uses read() to fill the buffer from a file, the memory pages corresponding to that buffer are now dirty since they have been written to.

Dirty pages can not be dropped from RAM by the kernel. If there is swap space, then they can be paged out to swap. But this is costly and on some systems, such as small embedded devices with only flash memory, there is no swap at all. In that case, the buffer will be stuck in RAM until the process exits, or perhaps gives it back withmadvise().

Non written to mmap() pages are clean. If the kernel needs RAM, it can simply drop them and use the RAM the pages were in. If the process that had the mapping accesses it again, it cause a page fault the kernel re-loads the pages from the file they came from originally. The same way they were populated in the first place.

This doesn't require more than one process using the mapped file to be an advantage.

  • Can't the kernel drop a 'dirty' mmap'd page by writing its contents out to the underlying file first? Commented Feb 6, 2020 at 2:06
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    When using read(), the pages that data is eventually put into have no relationship to the file they may have come from. So they can't be written out, except to swap space. If a file is mmap()ed, and the mapping is writable (as opposed to read only), and written to, then it depends on whether the mapping was MAP_SHARED or MAP_PRIVATE. A shared mapping can/must be written to the file, but a private can not be.
    – TrentP
    Commented Feb 6, 2020 at 21:30
  • This is the same advantage described by the second paragraph of the accepted answer
    – Nemo
    Commented Jul 2, 2021 at 17:26

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