I need a way to copy pages from one virtual address range to another without actually copying the data. The ranges are massive and latency is important. mremap can do this, but the problem is it also deletes the old mapping. Since I need to do this in a multithreaded environment I need the old mapping to be simultaneously usable, I will free it later when I'm certain no other threads can be using it. Is this possible, however hacky, without modifying the kernel? The solution only need work with recent Linux kernels.

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    Out of curiosity, why bother with remap if the memory is still being accessed at the old address? – user4815162342 Sep 19 '13 at 20:44
  • Is there another mechanism to map the same pages to a new, larger mapping at a different address? That would answer the question. – Eloff Sep 19 '13 at 20:49
  • I don't know the answer to your question (AFAIK it's impossible), but I'm curious as to why you need that. After all, if you only need to enlarge the mapping, that should be possible without relocating it, as long as you keep adjacent mapping well-spaced, which should not be a problem unless you're running a 32-bit kernel. – user4815162342 Sep 19 '13 at 20:52
  • Difficult and unreliable with potentially hundreds of thousands of large mappings on x64. I'd rather modify the kernel. These mappings are actually mapped shm_open names. I think it might be possible to extend the mapping with ftruncate and then map the new larger region in an overlapping new mmap in the same process. Is that possible? – Eloff Sep 19 '13 at 21:03
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    Are you mapping an actual file, or an anonymous region? I think if it's a file, then you can use mmap the same file again and get a different set of addresses. – Mats Petersson Sep 19 '13 at 21:56
up vote 9 down vote accepted

It is possible, although there are architecture-specific cache consistency issues you may need to consider. Some architectures simply do not allow the same page to be accessed from multiple virtual addresses simultaneously without losing coherency. So, some architectures will manage this fine, others do not.

Edited to add: AMD64 Architecture Programmer's Manual vol. 2, System Programming, section 7.8.7 Changing Memory Type, states:

A physical page should not have differing cacheability types assigned to it through different virtual mappings; they should be either all of a cacheable type (WB, WT, WP) or all of a non-cacheable type (UC, WC, CD). Otherwise, this may result in a loss of cache coherency, leading to stale data and unpredictable behavior.

Thus, on AMD64, it should be safe to mmap() the same file or shared memory region again, as long as the same prot and flags are used; it should cause the kernel to use the same cacheable type to each of the mappings.


The first step is to always use a file backing for the memory maps. Use mmap(NULL, length, PROT_READ | PROT_WRITE, MAP_SHARED | MAP_NORESERVE, fd, 0) so that the mappings do not reserve swap. (If you forget this, you'll run into swap limits much sooner than you hit actual real life limits for many workloads.) The extra overhead caused by having a file backing is absolutely neglible.

Edited to add: User strcmp pointed out that current kernels do not apply address space randomization to the addresses. Fortunately, this is easy to fix, by simply supplying randomly generated addresses to mmap() instead of NULL. On x86-64, the user address space is 47-bit, and the address should be page aligned; you could use e.g. Xorshift* to generate the addresses, then mask out the unwanted bits: & 0x00007FFFFE00000 would give 2097152-byte-aligned 47-bit addresses, for example.

Because the backing is to a file, you can create a second mapping to the same file, after enlarging the backing file using ftruncate(). Only after a suitable grace period -- when you know no thread is using the mapping anymore (perhaps use an atomic counter to keep track of that?) --, you unmap the original mapping.

In practice, when a mapping needs to be enlarged, you first enlarge the backing file, then try mremap(mapping, oldsize, newsize, 0) to see if the mapping can be grown, without moving the mapping. Only if the in-place remapping fails, do you need to switch to the new mapping.

Edited to add: You definitely do want to use mremap() instead of just using mmap() and MAP_FIXED to create a larger mapping, because mmap() unmaps (atomically) any existing mappings, including those belonging to other files or shared memory regions. With mremap(), you get an error if the enlarged mapping would overlap with existing mappings; with mmap() and MAP_FIXED, any existing mappings that the new mapping overlaps are ignored (unmapped).

Unfortunately, I must admit I haven't verified if the kernel detects collisions between existing mappings, or if it just assumes the programmer knows about such collisions -- after all, the programmer must know the address and length of every mapping, and therefore should know if the mapping would collide with anther existing one. Edited to add: The 3.8 series kernels do, returning MAP_FAILED with errno==ENOMEM if the enlarged mapping would collide with existing maps. I expect all Linux kernels to behave the same way, but have no proof, aside from testing on 3.8.0-30-generic on x86_64.

Also note that in Linux, POSIX shared memory is implemented using a special filesystem, typically a tmpfs mounted at /dev/shm (or /run/shm with /dev/shm being a symlink). The shm_open() et. al are implemented by the C library. Instead of having a large POSIX shared memory capability, I'd personally use a specially mounted tmpfs for use in a custom application. If not for anything else, the security controls (users and groups able to create new "files" in there) are much easier and clearer to manage.


If the mapping is, and has to be, anonymous, you can still use mremap(mapping, oldsize, newsize, 0) to try and resize it; it just may fail.

Even with hundreds of thousands of mappings, the 64-bit address space is vast, and the failure case rare. So, although you must handle the failure case too, it does not necessarily have to be fast. Edited to modify: On x86-64, the address space is 47-bit, and mappings must start at a page boundary (12 bits for normal pages, 21 bits for 2M hugepages, and 30 bits for 1G hugepages), so there is only 35, 26, or 17 bits available in the address space for the mappings. So, the collisions are more frequent, even if random addresses are suggested. (For 2M mappings, 1024 maps had an occasional collision, but at 65536 maps, the probability of a collision (resize failure) was about 2.3%.)

Edited to add: User strcmp pointed out in a comment that by default Linux mmap() will return consecutive addresses, in which case growing the mapping will always fail unless it's the last one, or a map was unmapped just there.

The approach I know works in Linux is complicated and very architecture-specific. You can remap the original mapping read-only, create a new anonymous map, and copy the old contents there. You need a SIGSEGV handler (SIGSEGV signal being raised for the particular thread that tries to write to the now read-only mapping, this being one of the few recoverable SIGSEGV situations in Linux even if POSIX disagrees) that examines the instruction that caused the problem, simulates it (modifying the contents of the new mapping instead), and then skips the problematic instruction. After a grace period, when there are no more threads accessing the old, now read-only mapping, you can tear down the mapping.

All of the nastiness is in the SIGSEGV handler, of course. Not only must it be able to decode all machine instructions and simulate them (or at least those that write to memory), but it must also busy-wait if the new mapping has not been completely copied yet. It is complicated, absolutely unportable, and very architecture-specific.. but possible.

  • I'm having trouble googling x64 virtual address aliasing and whether it will work or not, do you know? The problem is I've got up to 1000 processes, each of which use ridiculous amounts of virtual address space, on a box with 256GB of ram and only a piddling 512GB of disk, half of which is earmarked for other things. So file backed is not possible, but afaik the shm_open handles work like nameable, shareable mappings. Since they're nameable you can try to map the same one in the same process (about to test what the kernel does with that.) – Eloff Sep 19 '13 at 23:25
  • Failing that I much prefer changing mremap in the kernel (adding an extra flag to keep the old mapping.) I'd imagine that's relatively easy and may even get accepted upstream, but then my imagination doesn't always intersect with reality. – Eloff Sep 19 '13 at 23:25
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    mremap is not needed at all, the shm_open fd can be mapped, extended with ftruncate, and then mapped again in a new overlapping mapping. You get two seperate virtual addresses and writing to one and reading from the other works just fine. Please update your answer to make this clear for anyone who finds this answer later, and I will accept it. – Eloff Sep 19 '13 at 23:53
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    @Eloff, wrt. no mremap(): mmap() with MAP_FIXED flag will happily overwrite ALL existing maps, even those belonging to other files (or shared memory regions, which are basically the same thing in Linux). So, if you use mmap(addr,newsize,PROT_READ|PROT_WRITE,MAP_SHARED|MAP_NORESERVE|MAP_FIXED,fd,0) to "grow" the region, you won't get an error if the new region would overlap with another mapping; it will just succeed. On the other hand, with mremap(), you get an error if the enlarged mapping collides with another mapping. So, you do need to use mremap(). – Nominal Animal Sep 20 '13 at 0:49
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    @strcat: Instead of just downvoting because of your "feelings", perhaps you should instead consider offering your own answer? Frankly, I see downvoting an answer if you are incapable of pointing out the issues as either useless or petty. Have I pissed you off somehow? The only reason I care is that I care about the quality of my answers -- I never vote on other answers myself --, and am always ready to admit to my error, and try to fix it. I kinda liked having only two downvotes among my 200 answers thus far. Yours is the third, and the first that I cannot understand at all. – Nominal Animal Feb 5 '15 at 17:26

Yes, you can do this.

mremap(old_address, old_size, new_size, flags) deletes the old mapping only of the size "old_size". So if you pass 0 as "old_size", it will not unmap anything at all.

Caution: this works as expected only with shared mappings, so such mremap() should be used on a region previously mapped with MAP_SHARED. This is actually all of that, i.e. you don't even need a file-backed mapping, you can successfully use "MAP_SHARED | MAP_ANONYMOUS" combination for mmap() flags. Some very old OSes may not support "MAP_SHARED | MAP_ANONYMOUS", but on linux you are safe.

If you try that on a MAP_PRIVATE region, the result would be roughly similar to memcpy(), i.e. no memory alias will be created. But it will still use the CoW machinery. It is not clear from your initial question whether do you need an alias, or the CoW copy is fine too.

UPDATE: for this to work, you also need to specify the MREMAP_MAYMOVE flag obviously.

  • “if you pass 0 as "old_size", it will not unmap anything at all” — that's technically correct, but it also means that no virtual address will be remapped to begin with, thus making the call to mremap useless and leaving OP's problem unsolved. Pages are indeed moved from [old_address, old_address + min(old_size, new_size)] to [new_address, new_address + min(old_size, new_size)]. – Arkanosis Jul 22 '16 at 10:29
  • Please check your facts. What you say is simply wrong and any small test-case can confirm this. – stsp Jul 23 '16 at 12:53
  • It is also a bit unclear what dos the OP really want: does he need a memory alias, or does he need a CoW copy of the original region? – stsp Jul 23 '16 at 13:01

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