Difference between revisions of "Shared memory"

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This articles describes some intricacies of handling shared memory mappings, i.e. mappings that are shared between a few processes.
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Every process has one or more memory mappings, i.e. regions of virtual memory it allows to use.
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Some such mappings can be shared between a few processes, and they are called shared mappings.
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In other words, these are shared '''anonymous (not file-based) memory mappings'''.
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The article describes some intricacies of handling such mappings.  
  
 
== Checkpoint ==
 
== Checkpoint ==
  
Every process has one or more mmaped files. Some mappings (for example, ones of shared libraries)
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During the checkpointing, CRIU needs to figure out all the shared mappings in order to dump them as such.
are shared between a few processes. During the checkpointing, CRIU need to figure out
 
all the mappings that are shared in order to dump them as such.
 
  
It does so by performing <code>fstatat()</code> for each entry in <code>/proc/$PID/map_files/</code>,
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It does so by calling <code>fstatat()</code> on each entry found in the <code>/proc/$PID/map_files/</code>,
noting the ''device'' and ''inode'' fields of the structure returned by fstatat(). This information
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noting the ''device:inode'' pair of the structure returned by <code>fstatat()</code>. Now, if some processes
is collected and sorted. Now, if any few processes have a mapping with same ''device'' and ''inode'',
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have a mapping with the same ''device:inode'' pair, this mapping is marked as shared between these processes
this mapping is a shared one and should be dumped as such.
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and dumped as such.
  
It's important to note that the above mechanism works not just for the file-based mappings,
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Note that <code>fstatat()</code> works because the kernel actually creates a hidden
but also for the anonymous ones. For an anonymous mapping, kernel actually creates a hidden
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tmpfs file, not visible from any tmpfs mounts, but accessible via its
tmpfs file, and so <code>fstatat()</code> on the <code>/proc/$PID/map_files/</code> entry
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<code>/proc/$PID/map_files/</code> entry.
works the same way as for other files. The tmpfs file itself is not visible from any tmpfs
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mounts, but can be opened via its <code>map_files</code> entry.
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Dumping a mapping means two things:
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* writing an entry into process' mm.img file;
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* storing the actual mapping data (contents).
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For shared mappings, the contents is stored into a pair of image files: pagemap-shmem.img and pages.img.
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For details, see [[Memory dumps]].
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Note that different processes can map different parts of a shared memory segment.
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In this case, CRIU first collects mapping offsets and lengths from all the processes
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to determine the total segment size, then reads all the parts contents
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from the respective processes.
  
 
== Restore ==
 
== Restore ==
  
During the restore, CRIU already knows which mappings are shared, so they need to be restored as shared.
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During the restore, CRIU already knows which mappings are shared, so they need to be
To restore file mappings, no tricks are needed, they are opened and mmaped with with a MAP_SHARED flag set.
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restored as such. Here is how it is done.
 
 
Anonymous memory mappings, though, need some work to be restored as such. Here is how it is done.
 
  
 
Among all the processes sharing a mapping, the one with the lowest PID among the group
 
Among all the processes sharing a mapping, the one with the lowest PID among the group
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== Dumping present pages ==
 
== Dumping present pages ==
  
When dumping the contents of shared memory CRIU doesn't dump all the data. Instead, it determines which pages contain  
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When dumping the contents of shared memory, CRIU does not dump all of the data. Instead, it determines which pages contain  
it and dumps only them. This is done similarly to how regular [[memory dumping and restoring]] works, i.e. by analyzing
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it, and only dumps those pages. This is done similarly to how regular [[memory dumping and restoring]] works, i.e. by looking
the owners' pagemap entries for PRESENT or SWAPPED bits. But there's one feature of shmem dumps -- sometimes shmem
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for PRESENT or SWAPPED bits in owners' pagemap entries.
page can exist in the kernel, but not mapped to any process. In this case criu detects one by calling mincore() on
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the shmem segment, which reports back the page in-memory status. And the mincore bitmap is AND-ed with the per-process
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There is one particular feature of shared memory dumps worth mentioning. Sometimes, a shared memory page
ones.
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can exist in the kernel, but it is not mapped to any process. CRIU detects such pages by calling mincore()
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on the shmem segment, which reports back the page in-memory status. The mincore bitmap is when ANDed with
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the per-process ones.
  
 
== See also ==
 
== See also ==
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[[Category:Memory]]
 
[[Category:Memory]]
 
[[Category:Under the hood]]
 
[[Category:Under the hood]]
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[[Category:Editor help needed]]

Latest revision as of 08:02, 10 January 2018

Every process has one or more memory mappings, i.e. regions of virtual memory it allows to use. Some such mappings can be shared between a few processes, and they are called shared mappings. In other words, these are shared anonymous (not file-based) memory mappings. The article describes some intricacies of handling such mappings.

Checkpoint[edit]

During the checkpointing, CRIU needs to figure out all the shared mappings in order to dump them as such.

It does so by calling fstatat() on each entry found in the /proc/$PID/map_files/, noting the device:inode pair of the structure returned by fstatat(). Now, if some processes have a mapping with the same device:inode pair, this mapping is marked as shared between these processes and dumped as such.

Note that fstatat() works because the kernel actually creates a hidden tmpfs file, not visible from any tmpfs mounts, but accessible via its /proc/$PID/map_files/ entry.

Dumping a mapping means two things:

  • writing an entry into process' mm.img file;
  • storing the actual mapping data (contents).

For shared mappings, the contents is stored into a pair of image files: pagemap-shmem.img and pages.img. For details, see Memory dumps.

Note that different processes can map different parts of a shared memory segment. In this case, CRIU first collects mapping offsets and lengths from all the processes to determine the total segment size, then reads all the parts contents from the respective processes.

Restore[edit]

During the restore, CRIU already knows which mappings are shared, so they need to be restored as such. Here is how it is done.

Among all the processes sharing a mapping, the one with the lowest PID among the group (see postulates) is assigned to be a mapping creator. The creator task is to obtain a mapping file descriptor, restore the mapping data, and signal all the other process that it's ready. During this process, all the other processes are waiting.

First, the creator need to obtain a file descriptor for the mapping. To achieve it, two different approaches are used, depending on the availability.

In case memfd_create() syscall is available (Linux kernel v3.17+), it is used to obtain a file descriptor. Next, ftruncate() is called to set the proper size of mapping.

If memfd_create() is not available, the alternative approach is used. First, mmap() is called to create a mapping. Next, a file in /proc/self/map_files/ is opened to get a file descriptor for the mapping. The limitation of this method is, due to security concerns, /proc/$PID/map_files/ is not available for processes that live inside a user namespace, so it is impossible to use it if there are any user namespaces in the dump.

Once the creator have the file descriptor, it mmap()s it and restores its content from the dump (using memcpy()). The creator then unmaps the the mapping (note the file descriptor is still available). Next, it calls futex(FUTEX_WAKE) to signal all the waiting processes that the mapping file descriptor is ready.

All the other processes that need this mapping wait on futex(FUTEX_WAIT). Once the wait is over, they open the creator's /proc/$CREATOR_PID/fd/$FD file to get the mapping file descriptor.

Finally, all the processes (including the creator itself) call mmap() to create a needed mapping (note that mmap() arguments such as length, offset and flags may differ for different processes), and close() the mapping file descriptor as it is no longer needed.

Changes tracking[edit]

For iterative migration it's very useful to track changes in memory. Until CRIU v2.5, changes were tracked for anonymous memory only, but now it is also shared memory can be tracked as well. To achieve it, CRIU scans all the shmem segment owners' pagemap (as it does for anonymous memory) and then ANDs the collected soft-dirty bits.

The changes tracking caused developers to implement memory images deduplication for shmem segments as well.

Dumping present pages[edit]

When dumping the contents of shared memory, CRIU does not dump all of the data. Instead, it determines which pages contain it, and only dumps those pages. This is done similarly to how regular memory dumping and restoring works, i.e. by looking for PRESENT or SWAPPED bits in owners' pagemap entries.

There is one particular feature of shared memory dumps worth mentioning. Sometimes, a shared memory page can exist in the kernel, but it is not mapped to any process. CRIU detects such pages by calling mincore() on the shmem segment, which reports back the page in-memory status. The mincore bitmap is when ANDed with the per-process ones.

See also[edit]