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Once files are added (or removed or moved), need to send those changes to
all the other git clones, at both the git level and the key/value level.
## bugs
* Running the assistant in a fresh clone of a repository, it sometimes
skips downloading a file, while successfully downloading all the rest.
There does not seem to be an error message. This will sometimes reproduce
(in a fresh clone each time) several times in a row, but then stops happening,
which has prevented me from debugging it.
This could possibly have been caused by the bug fixed in 750c4ac6c282d14d19f79e0711f858367da145e4.
* The transfer code doesn't always manage to transfer file contents.
Besides reconnection events, there are two places where transfers get queued:
1. When the committer commits a file, it queues uploads.
2. When the watcher sees a broken symlink be created, it queues downloads.
Consider a doubly-linked chain of three repositories, A B and C.
(C and A do not directly communicate.)
* File is added to A.
* A uploads its content to B.
* At the same time, A git syncs to B.
* Once B gets the git sync, it git syncs to C.
* When C's watcher sees the file appear, it tries to download it. But if
B had not finished receiving the file from A, C doesn't know B has it,
and cannot download it from anywhere.
Possible solution: After B receives content, it could queue uploads of it
to all remotes that it doesn't know have it yet, which would include C.
In practice, this has the problem that when C receives the content,
it will queue uploads of it, which can send back to B (or to some other repo
that already has the content) and loop, until the git-annex branches catch
up and break the cycle.
Possible solution: C could record a deferred download. (Similar to a failed
download, but with an unknown source.) When C next receives a git-annex
branch push, it could try to queue deferred downloads. **done**
Note that this solution won't cover use cases the other does. For example,
connect a USB drive A; B syncs files from it, and then should pass them to C.
If the files are not new, C won't immediatly request them from B.
## TODO
* Test MountWatcher on LXDE.
* git-annex needs a simple speed control knob, which can be plumbed
through to, at least, rsync. A good job for an hour in an
airport somewhere.
* Find a way to probe available outgoing bandwidth, to throttle so
we don't bufferbloat the network to death.
* Investigate the XMPP approach like dvcs-autosync does, or other ways of
signaling a change out of band.
* Add a hook, so when there's a change to sync, a program can be run
and do its own signaling.
* --debug will show often unnecessary work being done. Optimise.
* This assumes the network is connected. It's often not, so the
[[cloud]] needs to be used to bridge between LANs.
* Configurablity, including only enabling git syncing but not data transfer;
only uploading new files but not downloading, and only downloading
files in some directories and not others. See for use cases:
[[forum/Wishlist:_options_for_syncing_meta-data_and_data]]
* speed up git syncing by using the cached ssh connection for it too
Will need to use `GIT_SSH`, which needs to point to a command to run,
not a shell command line. Beware that the network connection may have
bounced and the cached ssh connection not be usable.
* Map the network of git repos, and use that map to calculate
optimal transfers to keep the data in sync. Currently a naive flood fill
is done instead.
* Find a more efficient way for the TransferScanner to find the transfers
that need to be done to sync with a remote. Currently it walks the git
working copy and checks each file. That probably needs to be done once,
but further calls to the TransferScanner could eg, look at the delta
between the last scan and the current one in the git-annex branch.
* Ensure that when a remote receives content, and updates its location log,
it syncs that update back out. Currently, it does not, unless the master
branch also changed. Prerequisite for:
* After git sync, identify new content that we don't have that is now available
on remotes, and transfer. (Needed when we have a uni-directional connection
to a remote, so it won't be uploading content to us.) Note: Does not
need to use the TransferScanner, if we get and check a list of the changed
files.
* [[use multiple transfer slots|todo/Slow_transfer_for_a_lot_of_small_files.]]
* The TransferQueue's list of deferred downloads could theoretically
grow without bounds in memory. Limit it to a given number of entries,
and fall back to some other method -- either storing deferred downloads
on disk, or perhaps scheduling a TransferScanner run to get back into sync.
## data syncing
There are two parts to data syncing. First, map the network and second,
decide what to sync when.
Mapping the network can reuse code in `git annex map`. Once the map is
built, we want to find paths through the network that reach all nodes
eventually, with the least cost. This is a minimum spanning tree problem,
except with a directed graph, so really a Arborescence problem.
With the map, we can determine which nodes to push new content to. Then we
need to control those data transfers, sending to the cheapest nodes first,
and with appropriate rate limiting and control facilities.
This probably will need lots of refinements to get working well.
### first pass: flood syncing
Before mapping the network, the best we can do is flood all files out to every
reachable remote. This is worth doing first, since it's the simplest way to
get the basic functionality of the assistant to work. And we'll need this
anyway.
## TransferScanner
The TransferScanner thread needs to find keys that need to be Uploaded
to a remote, or Downloaded from it.
How to find the keys to transfer? I'd like to avoid potentially
expensive traversals of the whole git working copy if I can.
(Currently, the TransferScanner does do the naive and possibly expensive
scan of the git working copy.)
One way would be to do a git diff between the (unmerged) git-annex branches
of the git repo, and its remote. Parse that for lines that add a key to
either, and queue transfers. That should work fairly efficiently when the
remote is a git repository. Indeed, git-annex already does such a diff
when it's doing a union merge of data into the git-annex branch. It
might even be possible to have the union merge and scan use the same
git diff data.
But that approach has several problems:
1. The list of keys it would generate wouldn't have associated git
filenames, so the UI couldn't show the user what files were being
transferred.
2. Worse, without filenames, any later features to exclude
files/directories from being transferred wouldn't work.
3. Looking at a git diff of the git-annex branches would find keys
that were added to either side while the two repos were disconnected.
But if the two repos' keys were not fully in sync before they
disconnected (which is quite possible; transfers could be incomplete),
the diff would not show those older out of sync keys.
The remote could also be a special remote. In this case, I have to either
traverse the git working copy, or perhaps traverse the whole git-annex
branch (which would have the same problems with filesnames not being
available).
If a traversal is done, should check all remotes, not just
one. Probably worth handling the case where a remote is connected
while in the middle of such a scan, so part of the scan needs to be
redone to check it.
## done
1. Can use `git annex sync`, which already handles bidirectional syncing.
When a change is committed, launch the part of `git annex sync` that pushes
out changes. **done**; changes are pushed out to all remotes in parallel
1. Watch `.git/refs/remotes/` for changes (which would be pushed in from
another node via `git annex sync`), and run the part of `git annex sync`
that merges in received changes, and follow it by the part that pushes out
changes (sending them to any other remotes).
[The watching can be done with the existing inotify code! This avoids needing
any special mechanism to notify a remote that it's been synced to.]
**done**
1. Periodically retry pushes that failed. **done** (every half an hour)
1. Also, detect if a push failed due to not being up-to-date, pull,
and repush. **done**
2. Use a git merge driver that adds both conflicting files,
so conflicts never break a sync. **done**
* on-disk transfers in progress information files (read/write/enumerate)
**done**
* locking for the files, so redundant transfer races can be detected,
and failed transfers noticed **done**
* transfer info for git-annex-shell **done**
* update files as transfers proceed. See [[progressbars]]
(updating for downloads is easy; for uploads is hard)
* add Transfer queue TChan **done**
* add TransferInfo Map to DaemonStatus for tracking transfers in progress.
**done**
* Poll transfer in progress info files for changes (use inotify again!
wow! hammer, meet nail..), and update the TransferInfo Map **done**
* enqueue Transfers (Uploads) as new files are added to the annex by
Watcher. **done**
* enqueue Tranferrs (Downloads) as new dangling symlinks are noticed by
Watcher. **done**
(Note: Needs git-annex branch to be merged before the tree is merged,
so it knows where to download from. Checked and this is the case.)
* Write basic Transfer handling thread. Multiple such threads need to be
able to be run at once. Each will need its own independant copy of the
Annex state monad. **done**
* Write transfer control thread, which decides when to launch transfers.
**done**
* Transfer watching has a race on kqueue systems, which makes finished
fast transfers not be noticed by the TransferWatcher. Which in turn
prevents the transfer slot being freed and any further transfers
from happening. So, this approach is too fragile to rely on for
maintaining the TransferSlots. Instead, need [[todo/assistant_threaded_runtime]],
which would allow running something for sure when a transfer thread
finishes. **done**
* Test MountWatcher on KDE, and add whatever dbus events KDE emits when
drives are mounted. **done**
* It would be nice if, when a USB drive is connected,
syncing starts automatically. Use dbus on Linux? **done**
* Optimisations in 5c3e14649ee7c404f86a1b82b648d896762cbbc2 temporarily
broke content syncing in some situations, which need to be added back.
**done**
Now syncing a disconnected remote only starts a transfer scan if the
remote's git-annex branch has diverged, which indicates it probably has
new files. But that leaves open the cases where the local repo has
new files; and where the two repos git branches are in sync, but the
content transfers are lagging behind; and where the transfer scan has
never been run.
Need to track locally whether we're believed to be in sync with a remote.
This includes:
* All local content has been transferred to it successfully.
* The remote has been scanned once for data to transfer from it, and all
transfers initiated by that scan succeeded.
Note the complication that, if it's initiated a transfer, our queued
transfer will be thrown out as unnecessary. But if its transfer then
fails, that needs to be noticed.
If we're going to track failed transfers, we could just set a flag,
and use that flag later to initiate a new transfer scan. We need a flag
in any case, to ensure that a transfer scan is run for each new remote.
The flag could be `.git/annex/transfer/scanned/uuid`.
But, if failed transfers are tracked, we could also record them, in
order to retry them later, without the scan. I'm thinking about a
directory like `.git/annex/transfer/failed/{upload,download}/uuid/`,
which failed transfer log files could be moved to.
* A remote may lose content it had before, so when requeuing
a failed download, check the location log to see if the remote still has
the content, and if not, queue a download from elsewhere. (And, a remote
may get content we were uploading from elsewhere, so check the location
log when queuing a failed Upload too.) **done**
* Fix MountWatcher to notice umounts and remounts of drives. **done**
* Run transfer scan on startup. **done**
* Often several remotes will be queued for full TransferScanner scans,
and the scan does the same thing for each .. so it would be better to
combine them into one scan in such a case. **done**
* The syncing code currently doesn't run for special remotes. While
transfering the git info about special remotes could be a complication,
if we assume that's synced between existing git remotes, it should be
possible for them to do file transfers to/from special remotes.
**done**
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