Difference between revisions of "CR tools"

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# There is no way to use cgroups freezer facility yet.
 
# There is no way to use cgroups freezer facility yet.
 
# No network or IPC checkpoint/restore supported.
 
# No network or IPC checkpoint/restore supported.
 
=== Agenda ===
 
 
# Basic design (checkpoint == proc + SEIZE, restore == syscalls + execve)
 
# What's required from kernel
 
  
 
== Basic design ==
 
== Basic design ==

Revision as of 09:12, 15 October 2011

What CRtools is

CRtools is an utility to checkpoint/restore process tree. Unlike checkpoint/restore implemented completely in kernel space, it tries to achieve the same target mostly in user space. Since this tools and overall concept are still under heavy development stage there are some known limitations applied

  1. Only pure x86-64 environment is supported, no IA32 emulation allowed.
  2. There is no way to use cgroups freezer facility yet.
  3. No network or IPC checkpoint/restore supported.

Basic design

Checkpoint

The checkpoint procedure relies heavily on /proc file system (it's a general place where crtools takes all the information it needs). Which includes

  • Files descriptors information (via /proc/$pid/fd and /proc/$pid/fdinfo).
  • Pipes parameters.
  • Memory maps (via /proc/$pid/maps).

The process dumper (lets call it simply the dumper further) does the following steps during checkpoint stage

  1. A $pid of a process group leader is obtained from the command line.
  2. By using this $pid the dumper walks though /proc/$pid/status and gathers children $pids recursively. At the end we will have a process tree.
  3. Then it takes every $pid from a process tree, sends SIGSTOP to every process found, and performs the following steps on each $pid.
    • Collects VMA areas by parsing /proc/$pid/maps.
    • Seizes a task via relatively new ptrace interface. Seizing a task means to put it into a special state when the task have no idea if it's being operated by ptrace.
    • Core parameters of a task (such as registers and friends) are being dumped via ptrace interface and parsing /proc/$pid/stat entry.
    • The dumper injects a parasite code into a task via ptrace interface. This allows us to dump pages of a task right from within the task's address space.
      • An injection procedure is pretty simple - the dumper scans executable VMA areas of a task (which were collected previously) and tests if there a place for syscall call, then (by ptrace as well) it substitutes an original code with syscall instructions and creates a new VMA area inside process address space.
      • Finally parasite code get copied into the new VMA and the former code which was modified during parasite bootstrap procedure get restored.
    • Then (by using a parasite code) the dumper flushes contents of a task's pages to the file. And pulls out parasite code block completely, since we don't need it anymore.
    • Once parasite removed a task get unseized via ptrace call but it remains stopped still.
    • The dumper writes out files and pipes parameter and data.
  4. The procedure continues for every $pid.

Restore

The restore procedure (aka restorer) proceed in the following steps

  1. A process tree has been read from a file.
  2. Every process started with saved (i.e. original) $pid via clone() call with new CLONE_CHILD_USEPID flag.
  3. Files and pipes are restored (by restored it's meant - they are opened and positioned).
  4. A new file generated. The file has an Elf format but with modified executable and program header types (telling the kernel that this particular file is not a regular Elf'oid but rather the kernel is to handle it in a slightly different way).
  5. Finally execve with new Elf file as an argument is executed, which initiate the kernel's stage of restore procedure.

Kernel requirements

Since checkpoint and restore processes requires some some help from the Linux kernel the following patches are needed

FIXME