XS backup restore: Difference between revisions

From OLPC
Jump to navigation Jump to search
No edit summary
Line 1: Line 1:
= Goals =
= XO initiating a backup =


* Simple, efficient (minimise processing, traffic), quick dev turnaround, debuggable
In the following text, all timestamps are integers representing seconds
* Sane, fail-safe, atomic-ish
elapsed since the UNIX epoch.
* Independent of the actual storage strategy (DS-agnostic)
* And yet, it must work well with the current DS (as of April 2008), and avoid restricting the evolution of the DS
* Safe for XO and XS
* The server can refuse to backup due to traffic/load
* Simple version negotiation
* Supports full homedir restore
* Supports per-document restore (via journal and/or webbased)
** There is some interest in leveraging a webbased 'document restore' facility as 'async document share/publish' mechanism.


== Notes ==

* All timestamps are integers representing seconds elapsed since the UNIX epoch.
* There is a REST meta-protocol versioning scheme. Outside of that initialcheck, what this page describes is the version "1" of the backup/restore protocol.

= XO-initiated backup =


== XO side ==
== XO side ==


1. Issue a HTTP GET to XS with path
1. Issue a HTTP GET to XS with path
/backup/''<protocol version>''/last/''<this_XO_serial_number>''
/backup/''<protocol version>''/available/''<this_XO_serial_number>''
''<protocol version>'' is the integer representing the latest
''<protocol version>'' is the integer representing the latest
backup protocol version supported by this XO. In protocol version 1,
backup protocol version supported by this XO. In protocol version 1,
a successful reply consists of two comma-separated integers:
a successful reply consists of a single integer:
'''timestamp''' -- timestamp of latest backed up item for this user
'''timestamp''' -- timestamp of latest backed up item for this user
or 0 if there are no previous backups
or 0 if there are no previous backups
'''nonce''' -- a random 64-bit integer
If the sent protocol version is not supported by the school server,
If the sent protocol version is not supported by the school server,
Line 39: Line 51:
and use that protocol version.
and use that protocol version.
3. Let ''to_backup_all'' be the collection of '''all''' items currently in the
3. Write out all the metadata for all the documents available for
backup, in CanonicalJSON format. Save it as '''metadata.json'''
XO's datastore. If returned timestamp in step 1 is 0, let ''to_backup''
overwriting (atomically) any previously existing version.
be the same collection.
If not 0, let ''to_backup'' be the collection of all items whose
timestamp is greater '''or equal''' to the returned timestamp.
4. Write out a plaintext index of all items in ''to_backup'', where the
index format is defined by the backup protocol version selected in
step 2. For version 1, I propose a list of lines where the first
line is a single integer stating the backup protocol version, and
each following line is a JSON-encoded list describing a single
entry in to_backup (metadata and filename). This list may include
references to other files (e.g. thumbnails) as part of the metadata.
Move this index in the datastore directory to a file called
'''backup.idx''' overwriting an old such file if present.
5. Write out a plaintext index of all items in '''to_backup_all''' where
the index format is defined by the backup protocol version selected
in step 2. For version 1, I propose a list of lines where the first
line is a single integer stating the backup protocol version, and
each following line is just a UUID of each object in the list
(meaning currently on the XO).
Move this index in the datastore directory to a file called
'''backup-state.idx''' overwriting an old such file if present.
6. For every item in to_backup, also write a line to a text file
called '''backup-files.idx''' in the datastore directory, overwriting
the old file. Each output line contains only the full path to the
binary data for each object. For objects that have additional binary
files associated (such as thumbnails), output an additional line
per file. Finally, add a line to this file for ''backup-state.idx'',
so the state file gets picked up as part of the backup.
7. Run rsync, telling it to read the list of input files
4. Run rsync between the datastore and a remote directory called '''datastore-current/'''
from '''backup-files.idx''' and write to a directory called '''backup-new/'''
in the user's home directory on the school server.
in the user's home directory on the school server.

The remote datastore-current directory will have a complete set of files
so use the rsync facilities available to optimise the transfer and
delete stale files:

--times
--partial (to make retries faster)
--delete
Check the exit value from rsync. If non-zero, retry step 7 up to 3 times.
Check the exit value from rsync. If non-zero, retry up to 3 times.
If still non-zero, abort until next backup. Otherwise, proceed to step 8.
If still non-zero, abort until next backup.

8. Issue a GET request to the XS, with path
5. Store the epoch of the end time of step 4.

/backup/''<protocol version>''/new/''<XO_serial_number>''.
'''Note''': This backup scheme is not atomic. Users of the backed-up data must be prepared for slightly inconsistent state between metadata and files - a large window exists between steps 3 and 5. Solutions to this could come from the FS (a ZFS-like implementation) or from a higher-level later (a git-based DS for example).
For protocol version 1, include a '''Backup-Auth''' header, whose contents
is the hex-digest output of SHA-1(''<nonce>''+''<XO_UUID>''), where
''<nonce>'' is the value received in step 1, and XO_UUID is this XO's UUID.


== XS side ==
== XS side ==

=== request for '''last''' ===


On the school server, when getting a request for
On the school server, when getting a request for
'''/backup/''<protocol version>''/last/''<SN>''''':
'''/backup/''<protocol version>''/available/''<SN>''''':
1. Check if we support the protocol version. If not, return 404 and a list
1. Check if we support the protocol version. If not, return 404 and a list
of supported versions. Otherwise, proceed.
of supported versions. Otherwise, proceed.
==== protocol version 1 ====

2. Check if we know this machine (can find it in our registration DB on
2. Check if we know this machine (can find it in our registration DB on
the XS). If not, return 403. We will not offer it backup service.
the XS). If not, return 403. We will not offer it backup service.
Line 111: Line 92:
it.
it.
4. Return timestamp in the body of a 200 OK
(I deliberately don't specify where the school server stores the timestamp,
as it might use mysql/sqlite/plain files for this, and the XO doesn't
and must not care.)
4. If backups for this machine don't exist yet, let nonce be
0. Otherwise, find the file '''nonce''' in the backup hierarchy for
this XO, e.g. /backups/''<SN>''/nonce and load its contents into the
variable '''nonce'''.
5. Return comma-separated timestamp and nonce in the body of a 200 OK
response.
response.




Line 202: Line 176:




= XO initiates a restore =
= XO-initiated full restore =


== XO side ==
== XO side ==
1. Issue a HTTP GET to the XS with path
1. Issue a HTTP GET to the XS with path
/backup/''<protocol version>''/restore/''<this_XO_serial_number>''
/backup/''<protocol version>''/restore/''<this_XO_serial_number>''
==== protocol version 1 ====
The response is 0 or a single absolute path on the XS, pointing to
The response is 0 or a single absolute path on the XS, pointing to
Line 270: Line 242:


== XS side ==
== XS side ==

=== request for '''restore''' ===


On the school server, when getting a request for
On the school server, when getting a request for
Line 279: Line 249:
of supported versions. Otherwise, proceed.
of supported versions. Otherwise, proceed.
==== protocol v1 ====

2. Check if backups for this machine exist. If not, return 200 OK whose
2. Check if backups for this machine exist. If not, return 200 OK whose
only body contents is '''0'''. Otherwise, proceed.
only body contents is '''0'''. Otherwise, proceed.

Revision as of 01:54, 25 April 2008

Goals

  • Simple, efficient (minimise processing, traffic), quick dev turnaround, debuggable
  • Sane, fail-safe, atomic-ish
  • Independent of the actual storage strategy (DS-agnostic)
  • And yet, it must work well with the current DS (as of April 2008), and avoid restricting the evolution of the DS
  • Safe for XO and XS
  • The server can refuse to backup due to traffic/load
  • Simple version negotiation
  • Supports full homedir restore
  • Supports per-document restore (via journal and/or webbased)
    • There is some interest in leveraging a webbased 'document restore' facility as 'async document share/publish' mechanism.

Notes

  • All timestamps are integers representing seconds elapsed since the UNIX epoch.
  • There is a REST meta-protocol versioning scheme. Outside of that initialcheck, what this page describes is the version "1" of the backup/restore protocol.

XO-initiated backup

XO side

1. Issue a HTTP GET to XS with path 
  /backup/<protocol version>/available/<this_XO_serial_number>
  
  <protocol version> is the integer representing the latest
  backup protocol version supported by this XO. In protocol version 1,
  a successful reply consists of a single integer:
  
      timestamp -- timestamp of latest backed up item for this user                                    
                   or 0 if there are no previous backups

  If the sent protocol version is not supported by the school server,
  it will return a 404 not found error, whose only body contents is 
  a comma-separated list of integers representing the backup protocol
  versions supported by this school server.

  If this school server refuses to provide backup service for this XO,
  it will return a 403 forbidden error.

  If the school server is too busy to deal with the XO's backup request,
  it will return a 503 service unavailable error. The XO will sleep 5
  minutes and retry.


2. If the request in step 1 succeeded, go to step 3. Otherwise, 
  if none of the backup system versions on the XO (multiple may be
  present) are in the 'versions' variable listed in the 404 error, abort
  until next scheduled backup time (we cannot back up to this XS). If
  a version was returned that also exists locally, go back to step 1
  and use that protocol version.

3. Write out all the metadata for all the documents available for
  backup, in CanonicalJSON format. Save it as metadata.json
  overwriting (atomically) any previously existing version.

4. Run rsync between the datastore and a remote directory called datastore-current/
  in the user's home directory on the school server.
  The remote datastore-current directory will have a complete set of files
  so use the rsync facilities available to optimise the transfer and 
  delete stale files:
   --times
   --partial (to make retries faster)
   --delete
 
  Check the exit value from rsync. If non-zero, retry up to 3 times.
  If still non-zero, abort until next backup.
5. Store the epoch of the end time of step 4.

Note: This backup scheme is not atomic. Users of the backed-up data must be prepared for slightly inconsistent state between metadata and files - a large window exists between steps 3 and 5. Solutions to this could come from the FS (a ZFS-like implementation) or from a higher-level later (a git-based DS for example).

XS side

On the school server, when getting a request for /backup/<protocol version>/available/<SN>:

1. Check if we support the protocol version. If not, return 404 and a list
  of supported versions. Otherwise, proceed.

2. Check if we know this machine (can find it in our registration DB on
  the XS). If not, return 403. We will not offer it backup service.
  Check if we're too busy to process another concurrent backup (e.g.
  based on transfer rate or number of rsync processes), if so, return
  503.
  
3. Check if backups for this machine exist. In protocol version 1, if
  backups don't exist, let timestamp be 0. Otherwise, find the
  timestamp of the last backed-up object for this machine and return
  it.

4. Return timestamp in the body of a 200 OK
  response.



request for new

On the school server, when getting a request for /backup/<protocol version>/new/<SN>:

1. Check if we support the protocol version. If not, return 404 and a list
  of supported versions. Otherwise, proceed.

protocol version 1

2. If no 'Backup-Auth' header is present, return 403, otherwise
  proceed.
  
3. Load the contents of the nonce file from the backup hierarchy for
  this XO (e.g. /backups/<SN>/nonce) in the nonce variable. If there
  is no nonce file, use '0' for the nonce variable.

4. Find the XO's UUID in the local database, load into XO_UUID
  variable. Verify that the contents of the Backup-Auth header
  match exactly the contents of SHA1(<nonce>+<XO_UUID>). If not,
  return 403, otherwise return empty (no body) 200 OK request to the
  client and proceed to next step.

  (Note: the nonce circus is required to keep a malicious actor
  from inhibiting all backups on his network by watching for /last
  GETs, then issuing /new gets 5 seconds later for the same XO. As
  the backup won't have completed, getting an updater running on the
  server would invalidate the backup, as will be seen in the following
  steps.)
   
5. Spawn an updater process in the background that does this:

  5.1. Issue a call to a setuid helper command that makes the
       'backup-new' folder in the XO's home directory (on the server)
       writable by the updater UID.
  
  5.2. Check if a file exists in the XO's home directory, within the
       dir backup-new, called backup.idx.processing. If the file
       does not exist, go to step 5.3.
       
       If its timestamp is NOT older than 10 minutes, exit the
       updater.  (We don't allow users to force us to do index
       updates for backups more frequently than once in 10 minutes.)
        
       If the timestamp is older than 10 minutes:

       * Check if a file called backup.idx.processing.pid exists
         AND is owned by us. If so, read its contents -- it contains
         a PID of the updater that tried to deal with the new backup
         -- and issue a SIGKILL to that PID.

       * Go to step 5.4.
      
  5.3. Move backup.idx to backup.idx.processing and write our own
       PID to backup.idx.processing.pid. If the move
       fails (because backup.idx doesn't exist), go to last step.
       Check if 'backup-state.idx' exists.  If not, go to last step.

  5.4. Read backup.idx.processing by line. The first line is a
       single backup protocol integer. If this updater doesn't
       support this version, the client sent a backup even though we
       told it not to. Go to last step.

       For every following line, check that the object filename it
       references exists in the backup-new folder. If it exists,
       move this file to the server's real backup hierarchy,
       e.g. /backups/<SN>/ and add a record to the server's backup DB
       backend (whatever it is) for this object.  If the file doesn't
       exist, move to next line.

  5.5. Move backup-state.idx to server backup hierarchy, e.g.
       /backup/<SN>/backup-state.idx. Generate a 64-bit nonce
       and write it out to /backup/<SN>/nonce.

  5.6. Delete everything in backup-new and exit the updater.


XO-initiated full restore

XO side

1. Issue a HTTP GET to the XS with path
  /backup/<protocol version>/restore/<this_XO_serial_number>

  The response is 0 or a single absolute path on the XS, pointing to
  the location of this XO's backup files in the backup hierarchy. If
  the response is 0, abort and report to user; there are no backups
  to restore. Otherwise store the path variable for future use.

  If the request returns a 500, abort and report to user that they
  must pick out restore files individually from the web interface.

  If the request returns a 503, wait 1 minute, then retry step 1,
  otherwise proceed.

2. Let variable index_path be the concatenation of the path variable
  from step 1 and the string restore.idx. Rsync the file whose path
  is index_path from the XS to the XO.  This file is a set of lines
  formatted like the contents of a backup.idx file -- produced
  exactly like in step 4 of the XO-side backup.  In other words, the
  first line repeats the protocol version, and every next line
  describes a single DS object. If the rsync fails, retry 3 times;
  if still failing, abort restore and report to user.

3. For every item in this list, parse out any paths to files,
  and write each one (e.g. one for the binary object, one for the
  thumbnail) to a local file called restore-files.idx, one per line.

  Note that the paths contained in 'restore.idx' that we
  received in step 2 are absolute paths on the schoolserver,
  e.g. /backups/<SN>/<filename>, and those paths MUST be preserved
  when writing to restore-files.idx.

4. Run a rsync on the XO, going from the schoolserver to the XO, and
  pass it restore-files.idx as the list of files to rsync.

5. Check the rsync exit value. If non-zero, retry 3 times. If still
  non-zero, abort and report failure to the user.

6. Go back through the list received in step 2 line by line.  For
  every file path in the current line (there might be several for
  e.g. binary object, thumbnail, etc), strip everything except the
  filename -- remove the directory components. Verify that the files
  exist locally on the XO.

  If they don't exist, rsync didn't get all the files back, but there
  should have been some (because we didn't get 0 for timestamp in
  step 1) AND rsync thinks it succeeded (because of step 5). Abort
  restore and report to user that something is wrong.

  If the files exist, issue a request to the DS to create the object
  based on the metadata in the line, and pass in stripped file paths
  for the contents/thumbnail.

  (Note: if the DS does not support setting creation timestamps or
  thumbnails through the present API, another function might have to
  be added specifically for the restore system to use, where such
  functions are allowed.)

7. If the last line in the list returned in step 1 is processed and
  stored in the DS, we have succeeded with the restore. Inform
  user. Eat some ice cream. Do the macarena.

XS side

On the school server, when getting a request for /backup/<protocol version>/restore/<SN>:

1. Check if we support the protocol version. If not, return 404 and a list
  of supported versions. Otherwise, proceed.

2. Check if backups for this machine exist. If not, return 200 OK whose
  only body contents is 0. Otherwise, proceed.

3. Check if a file called restore.idx exists in the backup hierarchy
  for the XO. If so, return absolute path to this XO's files in the
  server backup hierarchy (e.g. /backups/<SN>/) as sole body of a 200
  OK response. If it doesn't exist, proceed.
   
4. Check if a file called restore-state.idx in the backup hierarchy
  for the XO exists. If not, return error 500. For some reason we don't
  have a state file for this machine; this shouldn't happen, but it means
  the user has to pick out objects to restore individually from the
  web interface.
   
5. Return 503 service unavailable, and in the background, spawn
  a restore process that does the following:

    5.1. Check if a file called restore-state.idx.processing in the
         backup hierarchy for this XO exists. If not, proceed to next
         step. If it exists, and its timestamp is older than 10
         minutes, we tried to prepare a restore list for this machine
         already and somehow failed (e.g. database timeouts,
         etc). Check if restore-state.idx.processing.pid exists and
         is owned by us; if so, load its contents and send SIGKILL
         to the PID, then move to step 5.3. If the timestamp is
         younger than 10 minutes, exit.
     
    5.2. Move restore-state.idx in the XO's backup hierarchy to
         restore-state.processing.idx

    5.3. Write our own PID to restore-state.processing.idx.pid.

    5.4. To a temporary file, write a line containing the backup
         protocol version.

    5.5. For each line in restore-state.processing.idx
         (representing a UUID), query all the relevant metadata from
         the XS store and write it, one JSON dictionary-encoded line
         per object, to the temporary file. Paths of any referenced
         files (binary objects, thumbnails) must be absolute paths on
         the XS. If any queries fail, retry with a timeout, and if
         failure continues, exit the updater.

    5.6. When finished, move temporary file to restore.idx in the
         backup hierarchy for this XO. Unlink
         restore-state.processing.idx.