Appendix B: History and Architecture

Nextcloud provides desktop sync clients to synchronize the contents of local directories from computers, tablets, and handheld devices to the Nextcloud server.

Synchronization is accomplished using csync, a bidirectional file synchronizing tool that provides both a command line client as well as a library. A special module for csync was written to synchronize with the Nextcloud built-in WebDAV server.

The Nextcloud Client software is written in C++ using the Qt Framework. As a result, the Nextcloud Client runs on Linux, Windows, and MacOS.

The Synchronization Process

The process of synchronization keeps files in two separate repositories the same. When synchronized:

  • If a file is added to one repository it is copied to the other synchronized repository.
  • When a file is changed in one repository, the change is propagated to any other synchronized repository.
  • If a file is deleted in one repository, it is deleted in any other.

It is important to note that the Nextcloud synchronization process does not use a typical client/server system where the server is always master. This is a major difference between the Nextcloud synchronization process and other systems like a file backup, where only changes to files or folders and the addition of new files are propagated, but these files and folders are never deleted unless explicitly deleted in the backup.

During synchronization, the Nextcloud Client checks both repositories for changes frequently. This process is referred to as a sync run. In between sync runs, the local repository is monitored by a file system monitoring process that starts a sync run immediately if something was edited, added, or removed.

Synchronization by Time versus ETag

Until the release of the client version 1.1, the Nextcloud synchronization process employed a single file property – the file modification time – to decide which file was newer and needed to be synchronized to the other repository.

The modification timestamp is part of the files metadata. It is available on every relevant filesystem and is the typical indicator for a file change. Modification timestamps do not require special action to create, and have a general meaning. One design goal of csync is to not require a special server component. This design goal is why csync was chosen as the backend component.

To compare the modification times of two files from different systems, csync must operate on the same base. Before client version 1.1.0, csync required both device repositories to run on the exact same time. This requirement was achieved through the use of enterprise standard NTP time synchronization on all machines.

Because this timing strategy is rather fragile without the use of NTP, the Nextcloud server provides a unique number that changes whenever the file changes. Although this number is a unique value, it is not a hash of the file. Instead, it is a randomly chosen number, that is transmitted in the Etag field. Because the file number changes if the file changes, its use is guaranteed to determine if one of the files has changed and, thereby, launching a synchronization process.

Before the 1.3.0 release of the Desktop Client, the synchronization process might create false conflict files if time deviates. Original and changed files conflict only in their timestamp, but not in their content. This behavior was changed to employ a binary check if files differ.

Like files, directories also hold a unique ID that changes whenever one of the contained files or directories is modified. Because this is a recursive process, it significantly reduces the effort required for a synchronization cycle, because the client only analyzes directories with a modified ID.

Comparison and Conflict Cases

As mentioned above, during a sync run the client must first detect if one of the two repositories have changed files. On the local repository, the client traverses the file tree and compares the modification time of each file with an expected value stored in its database. If the value is not the same, the client determines that the file has been modified in the local repository.

Note

On the local side, the modification time is a good attribute to use for detecting changes, because the value does not depend on time shifts and such.

For the remote (that is, Nextcloud server) repository, the client compares the ETag of each file with its expected value. Again, the expected ETag value is queried from the client database. If the ETag is the same, the file has not changed and no synchronization occurs.

In the event a file has changed on both the local and the remote repository since the last sync run, it can not easily be decided which version of the file is the one that should be used. However, changes to any side will not be lost. Instead, a conflict case is created. The client resolves this conflict by renaming the local file, appending a conflict label and timestamp, and saving the remote file under the original file name.

Example: Assume there is a conflict in message.txt because its contents have changed both locally and remotely since the last sync run. The local file with the local changes will be renamed to message_conflict-20160101-153110.txt and the remote file will be downloaded and saved as message.txt.

Conflict files are always created on the client and never on the server.

Ignored Files

The Nextcloud Client supports the ability to exclude or ignore certain files from the synchronization process. Some system wide file patterns that are used to exclude or ignore files are included with the client by default and the Nextcloud Client provides the ability to add custom patterns.

By default, the Nextcloud Client ignores the following files:

  • Files matched by one of the patterns defined in the Ignored Files Editor.
  • Files starting with ._sync_*.db*, .sync_*.db*, .csync_journal.db*, .owncloudsync.log*, as these files are reserved for journalling.
  • Files with a name longer than 254 characters.
  • The file Desktop.ini in the root of a synced folder.
  • Files matching the pattern *_conflict-* unless conflict file uploading is enabled.
  • Windows only: Files containing characters that do not work on typical Windows filesystems (`\, /, :, ?, *, ", >, <, |`).
  • Windows only: Files with a trailing space or dot.
  • Windows only: Filenames that are reserved on Windows.

If a pattern selected using a checkbox in the ignoredFilesEditor-label (or if a line in the exclude file starts with the character ] directly followed by the file pattern), files matching the pattern are considered fleeting meta data.

These files are ignored and removed by the client if found in the synchronized folder. This is suitable for meta files created by some applications that have no sustainable meaning.

If a pattern ends with the forward slash (/) character, only directories are matched. The pattern is only applied for directory components of filenames selected using the checkbox.

To match filenames against the exclude patterns, the UNIX standard C library function fnmatch is used. This process checks the filename against the specified pattern using standard shell wildcard pattern matching. For more information, please refer to The opengroup website.

The path that is checked is the relative path under the sync root directory.

Pattern and File Match Examples:

Pattern File Matches
~$* ~$foo, ~$example.doc
fl?p flip, flap
moo/ map/moo/, moo/

The Sync Journal

The client stores the ETag number in a per-directory database, called the journal. This database is a hidden file contained in the directory to be synchronized.

If the journal database is removed, the Nextcloud Client CSync backend rebuilds the database by comparing the files and their modification times. This process ensures that both server and client are synchronized using the appropriate NTP time before restarting the client following a database removal.

Custom WebDAV Properties

In the communication between client and server a couple of custom WebDAV properties were introduced. They are either needed for sync functionality or help have a positive effect on synchronization performance.

This chapter describes additional XML elements which the server returns in response to a successful PROPFIND request on a file or directory. The elements are returned in the namespace oc.

Server Side Permissions

The XML element <oc:permissions> represents the permission- and sharing state of the item. It is a list of characters, and each of the chars has a meaning as outlined in the table below:

Code Resource Description
S File or Folder is shared
R File or Folder can share (includes re-share)
M File or Folder is mounted (like on Dropbox, Samba, etc.)
W File can write file
C Folder can create file in folder
K Folder can create folder (mkdir)
D File or Folder can delete file or folder
N File or Folder can rename file or folder
V File or Folder can move file or folder

Example:

<oc:permissions>RDNVCK</oc:permissions>

File- or Directory Size

The XML element <oc:size> represents the file- or directory size in bytes. For directories, the size of the whole file tree underneath the directory is accumulated.

Example:

<oc:size>2429176697</oc:size>

FileID

The XML element <oc:id> represents the so called file ID. It is a non volatile string id that stays constant as long as the file exists. It is not changed if the file changes or is renamed or moved.

Example:

<oc:id>00000020oc5cfy6qqizm</oc:id>