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ReStructuredText
1153 lines
48 KiB
ReStructuredText
.. include:: ../global.rst.inc
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.. highlight:: none
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.. _data-structures:
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Data structures and file formats
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================================
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This page documents the internal data structures and storage
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mechanisms of Borg. It is partly based on `mailing list
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discussion about internals`_ and also on static code analysis.
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.. todo:: Clarify terms, perhaps create a glossary.
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ID (client?) vs. key (repository?),
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chunks (blob of data in repo?) vs. object (blob of data in repo, referred to from another object?),
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.. _repository:
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Repository
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----------
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.. Some parts of this description were taken from the Repository docstring
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Borg stores its data in a `Repository`, which is a file system based
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transactional key-value store. Thus the repository does not know about
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the concept of archives or items.
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Each repository has the following file structure:
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README
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simple text file telling that this is a Borg repository
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config
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repository configuration
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data/
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directory where the actual data is stored
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hints.%d
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hints for repository compaction
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index.%d
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repository index
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lock.roster and lock.exclusive/*
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used by the locking system to manage shared and exclusive locks
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Transactionality is achieved by using a log (aka journal) to record changes. The log is a series of numbered files
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called segments_. Each segment is a series of log entries. The segment number together with the offset of each
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entry relative to its segment start establishes an ordering of the log entries. This is the "definition" of
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time for the purposes of the log.
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.. _config-file:
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Config file
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~~~~~~~~~~~
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Each repository has a ``config`` file which which is a ``INI``-style file
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and looks like this::
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[repository]
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version = 1
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segments_per_dir = 1000
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max_segment_size = 524288000
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id = 57d6c1d52ce76a836b532b0e42e677dec6af9fca3673db511279358828a21ed6
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This is where the ``repository.id`` is stored. It is a unique
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identifier for repositories. It will not change if you move the
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repository around so you can make a local transfer then decide to move
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the repository to another (even remote) location at a later time.
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Keys
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~~~~
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Repository keys are byte-strings of fixed length (32 bytes), they
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don't have a particular meaning (except for the Manifest_).
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Normally the keys are computed like this::
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key = id = id_hash(unencrypted_data)
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The id_hash function depends on the :ref:`encryption mode <borg_init>`.
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As the id / key is used for deduplication, id_hash must be a cryptographically
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strong hash or MAC.
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Segments
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~~~~~~~~
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Objects referenced by a key are stored inline in files (`segments`) of approx.
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500 MB size in numbered subdirectories of ``repo/data``. The number of segments
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per directory is controlled by the value of ``segments_per_dir``. If you change
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this value in a non-empty repository, you may also need to relocate the segment
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files manually.
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A segment starts with a magic number (``BORG_SEG`` as an eight byte ASCII string),
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followed by a number of log entries. Each log entry consists of:
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* 32-bit size of the entry
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* CRC32 of the entire entry (for a PUT this includes the data)
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* entry tag: PUT, DELETE or COMMIT
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* PUT and DELETE follow this with the 32 byte key
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* PUT follow the key with the data
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Those files are strictly append-only and modified only once.
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Tag is either ``PUT``, ``DELETE``, or ``COMMIT``.
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When an object is written to the repository a ``PUT`` entry is written
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to the file containing the object id and data. If an object is deleted
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a ``DELETE`` entry is appended with the object id.
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A ``COMMIT`` tag is written when a repository transaction is
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committed. The segment number of the segment containing
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a commit is the **transaction ID**.
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When a repository is opened any ``PUT`` or ``DELETE`` operations not
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followed by a ``COMMIT`` tag are discarded since they are part of a
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partial/uncommitted transaction.
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The size of individual segments is limited to 4 GiB, since the offset of entries
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within segments is stored in a 32-bit unsigned integer in the repository index.
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Index, hints and integrity
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~~~~~~~~~~~~~~~~~~~~~~~~~~
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The **repository index** is stored in ``index.<TRANSACTION_ID>`` and is used to
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determine an object's location in the repository. It is a HashIndex_,
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a hash table using open addressing. It maps object keys_ to two
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unsigned 32-bit integers; the first integer gives the segment number,
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the second indicates the offset of the object's entry within the segment.
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The **hints file** is a msgpacked file named ``hints.<TRANSACTION_ID>``.
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It contains:
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* version
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* list of segments
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* compact
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The **integrity file** is a msgpacked file named ``integrity.<TRANSACTION_ID>``.
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It contains checksums of the index and hints files and is described in the
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:ref:`Checksumming data structures <integrity_repo>` section below.
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If the index or hints are corrupted, they are re-generated automatically.
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If they are outdated, segments are replayed from the index state to the currently
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committed transaction.
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Compaction
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~~~~~~~~~~
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For a given key only the last entry regarding the key, which is called current (all other entries are called
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superseded), is relevant: If there is no entry or the last entry is a DELETE then the key does not exist.
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Otherwise the last PUT defines the value of the key.
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By superseding a PUT (with either another PUT or a DELETE) the log entry becomes obsolete. A segment containing
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such obsolete entries is called sparse, while a segment containing no such entries is called compact.
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Since writing a ``DELETE`` tag does not actually delete any data and
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thus does not free disk space any log-based data store will need a
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compaction strategy (somewhat analogous to a garbage collector).
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Borg uses a simple forward compacting algorithm,
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which avoids modifying existing segments.
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Compaction runs when a commit is issued (unless the :ref:`append_only_mode` is active).
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One client transaction can manifest as multiple physical transactions,
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since compaction is transacted, too, and Borg does not distinguish between the two::
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Perspective| Time -->
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-----------+--------------
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Client | Begin transaction - Modify Data - Commit | <client waits for repository> (done)
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Repository | Begin transaction - Modify Data - Commit | Compact segments - Commit | (done)
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The compaction algorithm requires two inputs in addition to the segments themselves:
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(i) Which segments are sparse, to avoid scanning all segments (impractical).
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Further, Borg uses a conditional compaction strategy: Only those
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segments that exceed a threshold sparsity are compacted.
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To implement the threshold condition efficiently, the sparsity has
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to be stored as well. Therefore, Borg stores a mapping ``(segment
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id,) -> (number of sparse bytes,)``.
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The 1.0.x series used a simpler non-conditional algorithm,
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which only required the list of sparse segments. Thus,
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it only stored a list, not the mapping described above.
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(ii) Each segment's reference count, which indicates how many live objects are in a segment.
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This is not strictly required to perform the algorithm. Rather, it is used to validate
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that a segment is unused before deleting it. If the algorithm is incorrect, or the reference
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count was not accounted correctly, then an assertion failure occurs.
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These two pieces of information are stored in the hints file (`hints.N`)
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next to the index (`index.N`).
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When loading a hints file, Borg checks the version contained in the file.
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The 1.0.x series writes version 1 of the format (with the segments list instead
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of the mapping, mentioned above). Since Borg 1.0.4, version 2 is read as well.
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The 1.1.x series writes version 2 of the format and reads either version.
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When reading a version 1 hints file, Borg 1.1.x will
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read all sparse segments to determine their sparsity.
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This process may take some time if a repository is kept in the append-only mode,
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which causes the number of sparse segments to grow. Repositories not in append-only
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mode have no sparse segments in 1.0.x, since compaction is unconditional.
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Compaction processes sparse segments from oldest to newest; sparse segments
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which don't contain enough deleted data to justify compaction are skipped. This
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avoids doing e.g. 500 MB of writing current data to a new segment when only
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a couple kB were deleted in a segment.
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Segments that are compacted are read in entirety. Current entries are written to
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a new segment, while superseded entries are omitted. After each segment an intermediary
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commit is written to the new segment. Then, the old segment is deleted
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(asserting that the reference count diminished to zero), freeing disk space.
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A simplified example (excluding conditional compaction and with simpler
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commit logic) showing the principal operation of compaction:
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.. figure:: compaction.png
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:figwidth: 100%
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:width: 100%
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(The actual algorithm is more complex to avoid various consistency issues, refer to
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the ``borg.repository`` module for more comments and documentation on these issues.)
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.. _internals_storage_quota:
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Storage quotas
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~~~~~~~~~~~~~~
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Quotas are implemented at the Repository level. The active quota of a repository
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is determined by the ``storage_quota`` `config` entry or a run-time override (via :ref:`borg_serve`).
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The currently used quota is stored in the hints file. Operations (PUT and DELETE) during
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a transaction modify the currently used quota:
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- A PUT adds the size of the *log entry* to the quota,
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i.e. the length of the data plus the 41 byte header.
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- A DELETE subtracts the size of the deleted log entry from the quota,
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which includes the header.
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Thus, PUT and DELETE are symmetric and cancel each other out precisely.
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The quota does not track on-disk size overheads (due to conditional compaction
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or append-only mode). In normal operation the inclusion of the log entry headers
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in the quota act as a faithful proxy for index and hints overheads.
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By tracking effective content size, the client can *always* recover from a full quota
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by deleting archives. This would not be possible if the quota tracked on-disk size,
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since journaling DELETEs requires extra disk space before space is freed.
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Tracking effective size on the other hand accounts DELETEs immediately as freeing quota.
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.. rubric:: Enforcing the quota
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The storage quota is meant as a robust mechanism for service providers, therefore
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:ref:`borg_serve` has to enforce it without loopholes (e.g. modified clients).
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The following sections refer to using quotas on remotely accessed repositories.
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For local access, consider *client* and *serve* the same.
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Accordingly, quotas cannot be enforced with local access,
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since the quota can be changed in the repository config.
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The quota is enforcible only if *all* :ref:`borg_serve` versions
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accessible to clients support quotas (see next section). Further, quota is
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per repository. Therefore, ensure clients can only access a defined set of repositories
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with their quotas set, using ``--restrict-to-repository``.
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If the client exceeds the storage quota the ``StorageQuotaExceeded`` exception is
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raised. Normally a client could ignore such an exception and just send a ``commit()``
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command anyway, circumventing the quota. However, when ``StorageQuotaExceeded`` is raised,
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it is stored in the ``transaction_doomed`` attribute of the repository.
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If the transaction is doomed, then commit will re-raise this exception, aborting the commit.
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The transaction_doomed indicator is reset on a rollback (which erases the quota-exceeding
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state).
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.. rubric:: Compatibility with older servers and enabling quota after-the-fact
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If no quota data is stored in the hints file, Borg assumes zero quota is used.
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Thus, if a repository with an enabled quota is written to with an older ``borg serve``
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version that does not understand quotas, then the quota usage will be erased.
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The client version is irrelevant to the storage quota and has no part in it.
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The form of error messages due to exceeding quota varies with client versions.
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A similar situation arises when upgrading from a Borg release that did not have quotas.
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Borg will start tracking quota use from the time of the upgrade, starting at zero.
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If the quota shall be enforced accurately in these cases, either
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- delete the ``index.N`` and ``hints.N`` files, forcing Borg to rebuild both,
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re-acquiring quota data in the process, or
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- edit the msgpacked ``hints.N`` file (not recommended and thus not
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documented further).
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The object graph
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----------------
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On top of the simple key-value store offered by the Repository_,
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Borg builds a much more sophisticated data structure that is essentially
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a completely encrypted object graph. Objects, such as archives_, are referenced
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by their chunk ID, which is cryptographically derived from their contents.
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More on how this helps security in :ref:`security_structural_auth`.
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.. figure:: object-graph.png
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:figwidth: 100%
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:width: 100%
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.. _manifest:
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The manifest
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~~~~~~~~~~~~
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The manifest is the root of the object hierarchy. It references
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all archives in a repository, and thus all data in it.
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Since no object references it, it cannot be stored under its ID key.
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Instead, the manifest has a fixed all-zero key.
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The manifest is rewritten each time an archive is created, deleted,
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or modified. It looks like this:
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.. code-block:: python
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{
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b'version': 1,
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b'timestamp': b'2017-05-05T12:42:23.042864',
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b'item_keys': [b'acl_access', b'acl_default', ...],
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b'config': {},
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b'archives': {
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b'2017-05-05-system-backup': {
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b'id': b'<32 byte binary object ID>',
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b'time': b'2017-05-05T12:42:22.942864',
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},
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},
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b'tam': ...,
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}
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The *version* field can be either 1 or 2. The versions differ in the
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way feature flags are handled, described below.
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The *timestamp* field is used to avoid logical replay attacks where
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the server just resets the repository to a previous state.
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*item_keys* is a list containing all Item_ keys that may be encountered in
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the repository. It is used by *borg check*, which verifies that all keys
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in all items are a subset of these keys. Thus, an older version of *borg check*
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supporting this mechanism can correctly detect keys introduced in later versions.
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The *tam* key is part of the :ref:`tertiary authentication mechanism <tam_description>`
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(formerly known as "tertiary authentication for metadata") and authenticates
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the manifest, since an ID check is not possible.
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*config* is a general-purpose location for additional metadata. All versions
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of Borg preserve its contents (it may have been a better place for *item_keys*,
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which is not preserved by unaware Borg versions, releases predating 1.0.4).
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Feature flags
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+++++++++++++
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Feature flags are used to add features to data structures without causing
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corruption if older versions are used to access or modify them. The main issues
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to consider for a feature flag oriented design are flag granularity,
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flag storage, and cache_ invalidation.
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Feature flags are divided in approximately three categories, detailed below.
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Due to the nature of ID-based deduplication, write (i.e. creating archives) and
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read access are not symmetric; it is possible to create archives referencing
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chunks that are not readable with the current feature set. The third
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category are operations that require accurate reference counts, for example
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archive deletion and check.
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As the manifest is always updated and always read, it is the ideal place to store
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feature flags, comparable to the super-block of a file system. The only problem
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is to recover from a lost manifest, i.e. how is it possible to detect which feature
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flags are enabled, if there is no manifest to tell. This issue is left open at this time,
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but is not expected to be a major hurdle; it doesn't have to be handled efficiently, it just
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needs to be handled.
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Lastly, cache_ invalidation is handled by noting which feature
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flags were and which were not understood while manipulating a cache.
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This allows to detect whether the cache needs to be invalidated,
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i.e. rebuilt from scratch. See `Cache feature flags`_ below.
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The *config* key stores the feature flags enabled on a repository:
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.. code-block:: python
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config = {
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b'feature_flags': {
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b'read': {
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b'mandatory': [b'some_feature'],
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},
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b'check': {
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b'mandatory': [b'other_feature'],
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}
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b'write': ...,
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b'delete': ...
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},
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}
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The top-level distinction for feature flags is the operation the client intends
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to perform,
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| the *read* operation includes extraction and listing of archives,
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| the *write* operation includes creating new archives,
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| the *delete* (archives) operation,
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| the *check* operation requires full understanding of everything in the repository.
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These are weakly set-ordered; *check* will include everything required for *delete*,
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*delete* will likely include *write* and *read*. However, *read* may require more
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features than *write* (due to ID-based deduplication, *write* does not necessarily
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require reading/understanding repository contents).
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Each operation can contain several sets of feature flags. Only one set,
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the *mandatory* set is currently defined.
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Upon reading the manifest, the Borg client has already determined which operation
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should be performed. If feature flags are found in the manifest, the set
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of feature flags supported by the client is compared to the mandatory set
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found in the manifest. If any unsupported flags are found (i.e. the mandatory set is
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not a subset of the features supported by the Borg client used), the operation
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is aborted with a *MandatoryFeatureUnsupported* error:
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Unsupported repository feature(s) {'some_feature'}. A newer version of borg is required to access this repository.
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Older Borg releases do not have this concept and do not perform feature flags checks.
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These can be locked out with manifest version 2. Thus, the only difference between
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manifest versions 1 and 2 is that the latter is only accepted by Borg releases
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implementing feature flags.
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Therefore, as soon as any mandatory feature flag is enabled in a repository,
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the manifest version must be switched to version 2 in order to lock out all
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Borg releases unaware of feature flags.
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.. _Cache feature flags:
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.. rubric:: Cache feature flags
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`The cache`_ does not have its separate set of feature flags. Instead, Borg stores
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which flags were used to create or modify a cache.
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All mandatory manifest features from all operations are gathered in one set.
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Then, two sets of features are computed;
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- those features that are supported by the client and mandated by the manifest
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are added to the *mandatory_features* set,
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- the *ignored_features* set comprised of those features mandated by the manifest,
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but not supported by the client.
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Because the client previously checked compliance with the mandatory set of features
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required for the particular operation it is executing, the *mandatory_features* set
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will contain all necessary features required for using the cache safely.
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Conversely, the *ignored_features* set contains only those features which were not
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relevant to operating the cache. Otherwise, the client would not pass the feature
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set test against the manifest.
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When opening a cache and the *mandatory_features* set is not a subset of the features
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supported by the client, the cache is wiped out and rebuilt,
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since a client not supporting a mandatory feature that the cache was built with
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would be unable to update it correctly.
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The assumption behind this behaviour is that any of the unsupported features could have
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been reflected in the cache and there is no way for the client to discern whether
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that is the case.
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Meanwhile, it may not be practical for every feature to have clients using it track
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whether the feature had an impact on the cache.
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Therefore, the cache is wiped.
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When opening a cache and the intersection of *ignored_features* and the features
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supported by the client contains any elements, i.e. the client possesses features
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that the previous client did not have and those new features are enabled in the repository,
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the cache is wiped out and rebuilt.
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While the former condition likely requires no tweaks, the latter condition is formulated
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in an especially conservative way to play it safe. It seems likely that specific features
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might be exempted from the latter condition.
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.. rubric:: Defined feature flags
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Currently no feature flags are defined.
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From currently planned features, some examples follow,
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these may/may not be implemented and purely serve as examples.
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- A mandatory *read* feature could be using a different encryption scheme (e.g. session keys).
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This may not be mandatory for the *write* operation - reading data is not strictly required for
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creating an archive.
|
|
- Any additions to the way chunks are referenced (e.g. to support larger archives) would
|
|
become a mandatory *delete* and *check* feature; *delete* implies knowing correct
|
|
reference counts, so all object references need to be understood. *check* must
|
|
discover the entire object graph as well, otherwise the "orphan chunks check"
|
|
could delete data still in use.
|
|
|
|
.. _archive:
|
|
|
|
Archives
|
|
~~~~~~~~
|
|
|
|
Each archive is an object referenced by the manifest. The archive object
|
|
itself does not store any of the data contained in the archive it describes.
|
|
|
|
Instead, it contains a list of chunks which form a msgpacked stream of items_.
|
|
The archive object itself further contains some metadata:
|
|
|
|
* *version*
|
|
* *name*, which might differ from the name set in the manifest.
|
|
When :ref:`borg_check` rebuilds the manifest (e.g. if it was corrupted) and finds
|
|
more than one archive object with the same name, it adds a counter to the name
|
|
in the manifest, but leaves the *name* field of the archives as it was.
|
|
* *items*, a list of chunk IDs containing item metadata (size: count * ~34B)
|
|
* *cmdline*, the command line which was used to create the archive
|
|
* *hostname*
|
|
* *username*
|
|
* *time* and *time_end* are the start and end timestamps, respectively
|
|
* *comment*, a user-specified archive comment
|
|
* *chunker_params* are the :ref:`chunker-params <chunker-params>` used for creating the archive.
|
|
This is used by :ref:`borg_recreate` to determine whether a given archive needs rechunking.
|
|
* Some other pieces of information related to recreate.
|
|
|
|
.. _archive_limitation:
|
|
|
|
.. rubric:: Note about archive limitations
|
|
|
|
The archive is currently stored as a single object in the repository
|
|
and thus limited in size to MAX_OBJECT_SIZE (20MiB).
|
|
|
|
As one chunk list entry is ~40B, that means we can reference ~500.000 item
|
|
metadata stream chunks per archive.
|
|
|
|
Each item metadata stream chunk is ~128kiB (see hardcoded ITEMS_CHUNKER_PARAMS).
|
|
|
|
So that means the whole item metadata stream is limited to ~64GiB chunks.
|
|
If compression is used, the amount of storable metadata is bigger - by the
|
|
compression factor.
|
|
|
|
If the medium size of an item entry is 100B (small size file, no ACLs/xattrs),
|
|
that means a limit of ~640 million files/directories per archive.
|
|
|
|
If the medium size of an item entry is 2kB (~100MB size files or more
|
|
ACLs/xattrs), the limit will be ~32 million files/directories per archive.
|
|
|
|
If one tries to create an archive object bigger than MAX_OBJECT_SIZE, a fatal
|
|
IntegrityError will be raised.
|
|
|
|
A workaround is to create multiple archives with less items each, see
|
|
also :issue:`1452`.
|
|
|
|
.. _item:
|
|
|
|
Items
|
|
~~~~~
|
|
|
|
Each item represents a file, directory or other file system item and is stored as a
|
|
dictionary created by the ``Item`` class that contains:
|
|
|
|
* path
|
|
* list of data chunks (size: count * ~40B)
|
|
* user
|
|
* group
|
|
* uid
|
|
* gid
|
|
* mode (item type + permissions)
|
|
* source (for symlinks, and for hardlinks within one archive)
|
|
* rdev (for device files)
|
|
* mtime, atime, ctime in nanoseconds
|
|
* xattrs
|
|
* acl (various OS-dependent fields)
|
|
* bsdflags
|
|
|
|
All items are serialized using msgpack and the resulting byte stream
|
|
is fed into the same chunker algorithm as used for regular file data
|
|
and turned into deduplicated chunks. The reference to these chunks is then added
|
|
to the archive metadata. To achieve a finer granularity on this metadata
|
|
stream, we use different chunker params for this chunker, which result in
|
|
smaller chunks.
|
|
|
|
A chunk is stored as an object as well, of course.
|
|
|
|
.. _chunks:
|
|
.. _chunker_details:
|
|
|
|
Chunks
|
|
~~~~~~
|
|
|
|
The Borg chunker uses a rolling hash computed by the Buzhash_ algorithm.
|
|
It triggers (chunks) when the last HASH_MASK_BITS bits of the hash are zero,
|
|
producing chunks of 2^HASH_MASK_BITS Bytes on average.
|
|
|
|
Buzhash is **only** used for cutting the chunks at places defined by the
|
|
content, the buzhash value is **not** used as the deduplication criteria (we
|
|
use a cryptographically strong hash/MAC over the chunk contents for this, the
|
|
id_hash).
|
|
|
|
``borg create --chunker-params CHUNK_MIN_EXP,CHUNK_MAX_EXP,HASH_MASK_BITS,HASH_WINDOW_SIZE``
|
|
can be used to tune the chunker parameters, the default is:
|
|
|
|
- CHUNK_MIN_EXP = 19 (minimum chunk size = 2^19 B = 512 kiB)
|
|
- CHUNK_MAX_EXP = 23 (maximum chunk size = 2^23 B = 8 MiB)
|
|
- HASH_MASK_BITS = 21 (statistical medium chunk size ~= 2^21 B = 2 MiB)
|
|
- HASH_WINDOW_SIZE = 4095 [B] (`0xFFF`)
|
|
|
|
The buzhash table is altered by XORing it with a seed randomly generated once
|
|
for the archive, and stored encrypted in the keyfile. This is to prevent chunk
|
|
size based fingerprinting attacks on your encrypted repo contents (to guess
|
|
what files you have based on a specific set of chunk sizes).
|
|
|
|
For some more general usage hints see also ``--chunker-params``.
|
|
|
|
.. _cache:
|
|
|
|
The cache
|
|
---------
|
|
|
|
The **files cache** is stored in ``cache/files`` and is used at backup time to
|
|
quickly determine whether a given file is unchanged and we have all its chunks.
|
|
|
|
In memory, the files cache is a key -> value mapping (a Python *dict*) and contains:
|
|
|
|
* key: id_hash of the encoded, absolute file path
|
|
* value:
|
|
|
|
- file inode number
|
|
- file size
|
|
- file mtime_ns
|
|
- age (0 [newest], 1, 2, 3, ..., BORG_FILES_CACHE_TTL - 1)
|
|
- list of chunk ids representing the file's contents
|
|
|
|
To determine whether a file has not changed, cached values are looked up via
|
|
the key in the mapping and compared to the current file attribute values.
|
|
|
|
If the file's size, mtime_ns and inode number is still the same, it is
|
|
considered to not have changed. In that case, we check that all file content
|
|
chunks are (still) present in the repository (we check that via the chunks
|
|
cache).
|
|
|
|
If everything is matching and all chunks are present, the file is not read /
|
|
chunked / hashed again (but still a file metadata item is written to the
|
|
archive, made from fresh file metadata read from the filesystem). This is
|
|
what makes borg so fast when processing unchanged files.
|
|
|
|
If there is a mismatch or a chunk is missing, the file is read / chunked /
|
|
hashed. Chunks already present in repo won't be transferred to repo again.
|
|
|
|
The inode number is stored and compared to make sure we distinguish between
|
|
different files, as a single path may not be unique across different
|
|
archives in different setups.
|
|
|
|
Not all filesystems have stable inode numbers. If that is the case, borg can
|
|
be told to ignore the inode number in the check via --ignore-inode.
|
|
|
|
The age value is used for cache management. If a file is "seen" in a backup
|
|
run, its age is reset to 0, otherwise its age is incremented by one.
|
|
If a file was not seen in BORG_FILES_CACHE_TTL backups, its cache entry is
|
|
removed. See also: :ref:`always_chunking` and :ref:`a_status_oddity`
|
|
|
|
The files cache is a python dictionary, storing python objects, which
|
|
generates a lot of overhead.
|
|
|
|
Borg can also work without using the files cache (saves memory if you have a
|
|
lot of files or not much RAM free), then all files are assumed to have changed.
|
|
This is usually much slower than with files cache.
|
|
|
|
The on-disk format of the files cache is a stream of msgpacked tuples (key, value).
|
|
Loading the files cache involves reading the file, one msgpack object at a time,
|
|
unpacking it, and msgpacking the value (in an effort to save memory).
|
|
|
|
The **chunks cache** is stored in ``cache/chunks`` and is used to determine
|
|
whether we already have a specific chunk, to count references to it and also
|
|
for statistics.
|
|
|
|
The chunks cache is a key -> value mapping and contains:
|
|
|
|
* key:
|
|
|
|
- chunk id_hash
|
|
* value:
|
|
|
|
- reference count
|
|
- size
|
|
- encrypted/compressed size
|
|
|
|
The chunks cache is a HashIndex_. Due to some restrictions of HashIndex,
|
|
the reference count of each given chunk is limited to a constant, MAX_VALUE
|
|
(introduced below in HashIndex_), approximately 2**32.
|
|
If a reference count hits MAX_VALUE, decrementing it yields MAX_VALUE again,
|
|
i.e. the reference count is pinned to MAX_VALUE.
|
|
|
|
.. _cache-memory-usage:
|
|
|
|
Indexes / Caches memory usage
|
|
-----------------------------
|
|
|
|
Here is the estimated memory usage of Borg - it's complicated::
|
|
|
|
chunk_count ~= total_file_size / 2 ^ HASH_MASK_BITS
|
|
|
|
repo_index_usage = chunk_count * 40
|
|
|
|
chunks_cache_usage = chunk_count * 44
|
|
|
|
files_cache_usage = total_file_count * 240 + chunk_count * 80
|
|
|
|
mem_usage ~= repo_index_usage + chunks_cache_usage + files_cache_usage
|
|
= chunk_count * 164 + total_file_count * 240
|
|
|
|
Due to the hashtables, the best/usual/worst cases for memory allocation can
|
|
be estimated like that::
|
|
|
|
mem_allocation = mem_usage / load_factor # l_f = 0.25 .. 0.75
|
|
|
|
mem_allocation_peak = mem_allocation * (1 + growth_factor) # g_f = 1.1 .. 2
|
|
|
|
All units are Bytes.
|
|
|
|
It is assuming every chunk is referenced exactly once (if you have a lot of
|
|
duplicate chunks, you will have less chunks than estimated above).
|
|
|
|
It is also assuming that typical chunk size is 2^HASH_MASK_BITS (if you have
|
|
a lot of files smaller than this statistical medium chunk size, you will have
|
|
more chunks than estimated above, because 1 file is at least 1 chunk).
|
|
|
|
If a remote repository is used the repo index will be allocated on the remote side.
|
|
|
|
The chunks cache, files cache and the repo index are all implemented as hash
|
|
tables. A hash table must have a significant amount of unused entries to be
|
|
fast - the so-called load factor gives the used/unused elements ratio.
|
|
|
|
When a hash table gets full (load factor getting too high), it needs to be
|
|
grown (allocate new, bigger hash table, copy all elements over to it, free old
|
|
hash table) - this will lead to short-time peaks in memory usage each time this
|
|
happens. Usually does not happen for all hashtables at the same time, though.
|
|
For small hash tables, we start with a growth factor of 2, which comes down to
|
|
~1.1x for big hash tables.
|
|
|
|
E.g. backing up a total count of 1 Mi (IEC binary prefix i.e. 2^20) files with a total size of 1TiB.
|
|
|
|
a) with ``create --chunker-params 10,23,16,4095`` (custom, like borg < 1.0 or attic):
|
|
|
|
mem_usage = 2.8GiB
|
|
|
|
b) with ``create --chunker-params 19,23,21,4095`` (default):
|
|
|
|
mem_usage = 0.31GiB
|
|
|
|
.. note:: There is also the ``--files-cache=disabled`` option to disable the files cache.
|
|
You'll save some memory, but it will need to read / chunk all the files as
|
|
it can not skip unmodified files then.
|
|
|
|
HashIndex
|
|
---------
|
|
|
|
The chunks cache and the repository index are stored as hash tables, with
|
|
only one slot per bucket, spreading hash collisions to the following
|
|
buckets. As a consequence the hash is just a start position for a linear
|
|
search. If a key is looked up that is not in the table, then the hash table
|
|
is searched from the start position (the hash) until the first empty
|
|
bucket is reached.
|
|
|
|
This particular mode of operation is open addressing with linear probing.
|
|
|
|
When the hash table is filled to 75%, its size is grown. When it's
|
|
emptied to 25%, its size is shrinked. Operations on it have a variable
|
|
complexity between constant and linear with low factor, and memory overhead
|
|
varies between 33% and 300%.
|
|
|
|
If an element is deleted, and the slot behind the deleted element is not empty,
|
|
then the element will leave a tombstone, a bucket marked as deleted. Tombstones
|
|
are only removed by insertions using the tombstone's bucket, or by resizing
|
|
the table. They present the same load to the hash table as a real entry,
|
|
but do not count towards the regular load factor.
|
|
|
|
Thus, if the number of empty slots becomes too low (recall that linear probing
|
|
for an element not in the index stops at the first empty slot), the hash table
|
|
is rebuilt. The maximum *effective* load factor, i.e. including tombstones, is 93%.
|
|
|
|
Data in a HashIndex is always stored in little-endian format, which increases
|
|
efficiency for almost everyone, since basically no one uses big-endian processors
|
|
any more.
|
|
|
|
HashIndex does not use a hashing function, because all keys (save manifest) are
|
|
outputs of a cryptographic hash or MAC and thus already have excellent distribution.
|
|
Thus, HashIndex simply uses the first 32 bits of the key as its "hash".
|
|
|
|
The format is easy to read and write, because the buckets array has the same layout
|
|
in memory and on disk. Only the header formats differ. The on-disk header is
|
|
``struct HashHeader``:
|
|
|
|
- First, the HashIndex magic, the eight byte ASCII string "BORG_IDX".
|
|
- Second, the signed 32-bit number of entries (i.e. buckets which are not deleted and not empty).
|
|
- Third, the signed 32-bit number of buckets, i.e. the length of the buckets array
|
|
contained in the file, and the modulus for index calculation.
|
|
- Fourth, the signed 8-bit length of keys.
|
|
- Fifth, the signed 8-bit length of values. This has to be at least four bytes.
|
|
|
|
All fields are packed.
|
|
|
|
The HashIndex is *not* a general purpose data structure.
|
|
The value size must be at least 4 bytes, and these first bytes are used for in-band
|
|
signalling in the data structure itself.
|
|
|
|
The constant MAX_VALUE (defined as 2**32-1025 = 4294966271) defines the valid range for
|
|
these 4 bytes when interpreted as an uint32_t from 0 to MAX_VALUE (inclusive).
|
|
The following reserved values beyond MAX_VALUE are currently in use (byte order is LE):
|
|
|
|
- 0xffffffff marks empty buckets in the hash table
|
|
- 0xfffffffe marks deleted buckets in the hash table
|
|
|
|
HashIndex is implemented in C and wrapped with Cython in a class-based interface.
|
|
The Cython wrapper checks every passed value against these reserved values and
|
|
raises an AssertionError if they are used.
|
|
|
|
Encryption
|
|
----------
|
|
|
|
.. seealso:: The :ref:`borgcrypto` section for an in-depth review.
|
|
|
|
AES_-256 is used in CTR mode (so no need for padding). A 64 bit initialization
|
|
vector is used, a MAC is computed on the encrypted chunk
|
|
and both are stored in the chunk. Encryption and MAC use two different keys.
|
|
Each chunk consists of ``TYPE(1)`` + ``MAC(32)`` + ``NONCE(8)`` + ``CIPHERTEXT``:
|
|
|
|
.. figure:: encryption.png
|
|
:figwidth: 100%
|
|
:width: 100%
|
|
|
|
In AES-CTR mode you can think of the IV as the start value for the counter.
|
|
The counter itself is incremented by one after each 16 byte block.
|
|
The IV/counter is not required to be random but it must NEVER be reused.
|
|
So to accomplish this Borg initializes the encryption counter to be
|
|
higher than any previously used counter value before encrypting new data.
|
|
|
|
To reduce payload size, only 8 bytes of the 16 bytes nonce is saved in the
|
|
payload, the first 8 bytes are always zeros. This does not affect security but
|
|
limits the maximum repository capacity to only 295 exabytes (2**64 * 16 bytes).
|
|
|
|
Encryption keys (and other secrets) are kept either in a key file on the client
|
|
('keyfile' mode) or in the repository config on the server ('repokey' mode).
|
|
In both cases, the secrets are generated from random and then encrypted by a
|
|
key derived from your passphrase (this happens on the client before the key
|
|
is stored into the keyfile or as repokey).
|
|
|
|
The passphrase is passed through the ``BORG_PASSPHRASE`` environment variable
|
|
or prompted for interactive usage.
|
|
|
|
.. _key_files:
|
|
|
|
Key files
|
|
---------
|
|
|
|
.. seealso:: The :ref:`key_encryption` section for an in-depth review of the key encryption.
|
|
|
|
When initialized with the ``init -e keyfile`` command, Borg
|
|
needs an associated file in ``$HOME/.config/borg/keys`` to read and write
|
|
the repository. The format is based on msgpack_, base64 encoding and
|
|
PBKDF2_ SHA256 hashing, which is then encoded again in a msgpack_.
|
|
|
|
The same data structure is also used in the "repokey" modes, which store
|
|
it in the repository in the configuration file.
|
|
|
|
The internal data structure is as follows:
|
|
|
|
version
|
|
currently always an integer, 1
|
|
|
|
repository_id
|
|
the ``id`` field in the ``config`` ``INI`` file of the repository.
|
|
|
|
enc_key
|
|
the key used to encrypt data with AES (256 bits)
|
|
|
|
enc_hmac_key
|
|
the key used to HMAC the encrypted data (256 bits)
|
|
|
|
id_key
|
|
the key used to HMAC the plaintext chunk data to compute the chunk's id
|
|
|
|
chunk_seed
|
|
the seed for the buzhash chunking table (signed 32 bit integer)
|
|
|
|
These fields are packed using msgpack_. The utf-8 encoded passphrase
|
|
is processed with PBKDF2_ (SHA256_, 100000 iterations, random 256 bit salt)
|
|
to derive a 256 bit key encryption key (KEK).
|
|
|
|
A `HMAC-SHA256`_ checksum of the packed fields is generated with the KEK,
|
|
then the KEK is also used to encrypt the same packed fields using AES-CTR.
|
|
|
|
The result is stored in a another msgpack_ formatted as follows:
|
|
|
|
version
|
|
currently always an integer, 1
|
|
|
|
salt
|
|
random 256 bits salt used to process the passphrase
|
|
|
|
iterations
|
|
number of iterations used to process the passphrase (currently 100000)
|
|
|
|
algorithm
|
|
the hashing algorithm used to process the passphrase and do the HMAC
|
|
checksum (currently the string ``sha256``)
|
|
|
|
hash
|
|
HMAC-SHA256 of the *plaintext* of the packed fields.
|
|
|
|
data
|
|
The encrypted, packed fields.
|
|
|
|
The resulting msgpack_ is then encoded using base64 and written to the
|
|
key file, wrapped using the standard ``textwrap`` module with a header.
|
|
The header is a single line with a MAGIC string, a space and a hexadecimal
|
|
representation of the repository id.
|
|
|
|
Compression
|
|
-----------
|
|
|
|
Borg supports the following compression methods:
|
|
|
|
- none (no compression, pass through data 1:1)
|
|
- lz4 (low compression, but super fast)
|
|
- zlib (level 0-9, level 0 is no compression [but still adding zlib overhead],
|
|
level 1 is low, level 9 is high compression)
|
|
- lzma (level 0-9, level 0 is low, level 9 is high compression).
|
|
|
|
Speed: none > lz4 > zlib > lzma
|
|
Compression: lzma > zlib > lz4 > none
|
|
|
|
Be careful, higher zlib and especially lzma compression levels might take a
|
|
lot of resources (CPU and memory).
|
|
|
|
The overall speed of course also depends on the speed of your target storage.
|
|
If that is slow, using a higher compression level might yield better overall
|
|
performance. You need to experiment a bit. Maybe just watch your CPU load, if
|
|
that is relatively low, increase compression until 1 core is 70-100% loaded.
|
|
|
|
Even if your target storage is rather fast, you might see interesting effects:
|
|
while doing no compression at all (none) is a operation that takes no time, it
|
|
likely will need to store more data to the storage compared to using lz4.
|
|
The time needed to transfer and store the additional data might be much more
|
|
than if you had used lz4 (which is super fast, but still might compress your
|
|
data about 2:1). This is assuming your data is compressible (if you backup
|
|
already compressed data, trying to compress them at backup time is usually
|
|
pointless).
|
|
|
|
Compression is applied after deduplication, thus using different compression
|
|
methods in one repo does not influence deduplication.
|
|
|
|
See ``borg create --help`` about how to specify the compression level and its default.
|
|
|
|
Lock files
|
|
----------
|
|
|
|
Borg uses locks to get (exclusive or shared) access to the cache and
|
|
the repository.
|
|
|
|
The locking system is based on creating a directory `lock.exclusive` (for
|
|
exclusive locks). Inside the lock directory, there is a file indicating
|
|
hostname, process id and thread id of the lock holder.
|
|
|
|
There is also a json file `lock.roster` that keeps a directory of all shared
|
|
and exclusive lockers.
|
|
|
|
If the process can create the `lock.exclusive` directory for a resource, it has
|
|
the lock for it. If creation fails (because the directory has already been
|
|
created by some other process), lock acquisition fails.
|
|
|
|
The cache lock is usually in `~/.cache/borg/REPOID/lock.*`.
|
|
The repository lock is in `repository/lock.*`.
|
|
|
|
In case you run into troubles with the locks, you can use the ``borg break-lock``
|
|
command after you first have made sure that no Borg process is
|
|
running on any machine that accesses this resource. Be very careful, the cache
|
|
or repository might get damaged if multiple processes use it at the same time.
|
|
|
|
Checksumming data structures
|
|
----------------------------
|
|
|
|
As detailed in the previous sections, Borg generates and stores various files
|
|
containing important meta data, such as the repository index, repository hints,
|
|
chunks caches and files cache.
|
|
|
|
Data corruption in these files can damage the archive data in a repository,
|
|
e.g. due to wrong reference counts in the chunks cache. Only some parts of Borg
|
|
were designed to handle corrupted data structures, so a corrupted files cache
|
|
may cause crashes or write incorrect archives.
|
|
|
|
Therefore, Borg calculates checksums when writing these files and tests checksums
|
|
when reading them. Checksums are generally 64-bit XXH64 hashes.
|
|
The canonical xxHash representation is used, i.e. big-endian.
|
|
Checksums are stored as hexadecimal ASCII strings.
|
|
|
|
For compatibility, checksums are not required and absent checksums do not trigger errors.
|
|
The mechanisms have been designed to avoid false-positives when various Borg
|
|
versions are used alternately on the same repositories.
|
|
|
|
Checksums are a data safety mechanism. They are not a security mechanism.
|
|
|
|
.. rubric:: Choice of algorithm
|
|
|
|
XXH64 has been chosen for its high speed on all platforms, which avoids performance
|
|
degradation in CPU-limited parts (e.g. cache synchronization).
|
|
Unlike CRC32, it neither requires hardware support (crc32c or CLMUL)
|
|
nor vectorized code nor large, cache-unfriendly lookup tables to achieve good performance.
|
|
This simplifies deployment of it considerably (cf. src/borg/algorithms/crc32...).
|
|
|
|
Further, XXH64 is a non-linear hash function and thus has a "more or less" good
|
|
chance to detect larger burst errors, unlike linear CRCs where the probability
|
|
of detection decreases with error size.
|
|
|
|
The 64-bit checksum length is considered sufficient for the file sizes typically
|
|
checksummed (individual files up to a few GB, usually less).
|
|
xxHash was expressly designed for data blocks of these sizes.
|
|
|
|
Lower layer — file_integrity
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
To accommodate the different transaction models used for the cache and repository,
|
|
there is a lower layer (borg.crypto.file_integrity.IntegrityCheckedFile)
|
|
wrapping a file-like object, performing streaming calculation and comparison of checksums.
|
|
Checksum errors are signalled by raising an exception (borg.crypto.file_integrity.FileIntegrityError)
|
|
at the earliest possible moment.
|
|
|
|
.. rubric:: Calculating checksums
|
|
|
|
Before feeding the checksum algorithm any data, the file name (i.e. without any path)
|
|
is mixed into the checksum, since the name encodes the context of the data for Borg.
|
|
|
|
The various indices used by Borg have separate header and main data parts.
|
|
IntegrityCheckedFile allows to checksum them independently, which avoids
|
|
even reading the data when the header is corrupted. When a part is signalled,
|
|
the length of the part name is mixed into the checksum state first (encoded
|
|
as an ASCII string via `%10d` printf format), then the name of the part
|
|
is mixed in as an UTF-8 string. Lastly, the current position (length)
|
|
in the file is mixed in as well.
|
|
|
|
The checksum state is not reset at part boundaries.
|
|
|
|
A final checksum is always calculated in the same way as the parts described above,
|
|
after seeking to the end of the file. The final checksum cannot prevent code
|
|
from processing corrupted data during reading, however, it prevents use of the
|
|
corrupted data.
|
|
|
|
.. rubric:: Serializing checksums
|
|
|
|
All checksums are compiled into a simple JSON structure called *integrity data*:
|
|
|
|
.. code-block:: json
|
|
|
|
{
|
|
"algorithm": "XXH64",
|
|
"digests": {
|
|
"HashHeader": "eab6802590ba39e3",
|
|
"final": "e2a7f132fc2e8b24"
|
|
}
|
|
}
|
|
|
|
The *algorithm* key notes the used algorithm. When reading, integrity data containing
|
|
an unknown algorithm is not inspected further.
|
|
|
|
The *digests* key contains a mapping of part names to their digests.
|
|
|
|
Integrity data is generally stored by the upper layers, introduced below. An exception
|
|
is the DetachedIntegrityCheckedFile, which automatically writes and reads it from
|
|
a ".integrity" file next to the data file.
|
|
It is used for archive chunks indexes in chunks.archive.d.
|
|
|
|
Upper layer
|
|
~~~~~~~~~~~
|
|
|
|
Storage of integrity data depends on the component using it, since they have
|
|
different transaction mechanisms, and integrity data needs to be
|
|
transacted with the data it is supposed to protect.
|
|
|
|
.. rubric:: Main cache files: chunks and files cache
|
|
|
|
The integrity data of the ``chunks`` and ``files`` caches is stored in the
|
|
cache ``config``, since all three are transacted together.
|
|
|
|
The ``[integrity]`` section is used:
|
|
|
|
.. code-block:: ini
|
|
|
|
[cache]
|
|
version = 1
|
|
repository = 3c4...e59
|
|
manifest = 10e...21c
|
|
timestamp = 2017-06-01T21:31:39.699514
|
|
key_type = 2
|
|
previous_location = /path/to/repo
|
|
|
|
[integrity]
|
|
manifest = 10e...21c
|
|
chunks = {"algorithm": "XXH64", "digests": {"HashHeader": "eab...39e3", "final": "e2a...b24"}}
|
|
|
|
The manifest ID is duplicated in the integrity section due to the way all Borg
|
|
versions handle the config file. Instead of creating a "new" config file from
|
|
an internal representation containing only the data understood by Borg,
|
|
the config file is read in entirety (using the Python ConfigParser) and modified.
|
|
This preserves all sections and values not understood by the Borg version
|
|
modifying it.
|
|
|
|
Thus, if an older versions uses a cache with integrity data, it would preserve
|
|
the integrity section and its contents. If a integrity-aware Borg version
|
|
would read this cache, it would incorrectly report checksum errors, since
|
|
the older version did not update the checksums.
|
|
|
|
However, by duplicating the manifest ID in the integrity section, it is
|
|
easy to tell whether the checksums concern the current state of the cache.
|
|
|
|
Integrity errors are fatal in these files, terminating the program,
|
|
and are not automatically corrected at this time.
|
|
|
|
.. rubric:: chunks.archive.d
|
|
|
|
Indices in chunks.archive.d are not transacted and use DetachedIntegrityCheckedFile,
|
|
which writes the integrity data to a separate ".integrity" file.
|
|
|
|
Integrity errors result in deleting the affected index and rebuilding it.
|
|
This logs a warning and increases the exit code to WARNING (1).
|
|
|
|
.. _integrity_repo:
|
|
|
|
.. rubric:: Repository index and hints
|
|
|
|
The repository associates index and hints files with a transaction by including the
|
|
transaction ID in the file names. Integrity data is stored in a third file
|
|
("integrity.<TRANSACTION_ID>"). Like the hints file, it is msgpacked:
|
|
|
|
.. code-block:: python
|
|
|
|
{
|
|
b'version': 2,
|
|
b'hints': b'{"algorithm": "XXH64", "digests": {"final": "411208db2aa13f1a"}}',
|
|
b'index': b'{"algorithm": "XXH64", "digests": {"HashHeader": "846b7315f91b8e48", "final": "cb3e26cadc173e40"}}'
|
|
}
|
|
|
|
The *version* key started at 2, the same version used for the hints. Since Borg has
|
|
many versioned file formats, this keeps the number of different versions in use
|
|
a bit lower.
|
|
|
|
The other keys map an auxiliary file, like *index* or *hints* to their integrity data.
|
|
Note that the JSON is stored as-is, and not as part of the msgpack structure.
|
|
|
|
Integrity errors result in deleting the affected file(s) (index/hints) and rebuilding the index,
|
|
which is the same action taken when corruption is noticed in other ways (e.g. HashIndex can
|
|
detect most corrupted headers, but not data corruption). A warning is logged as well.
|
|
The exit code is not influenced, since remote repositories cannot perform that action.
|
|
Raising the exit code would be possible for local repositories, but is not implemented.
|
|
|
|
Unlike the cache design this mechanism can have false positives whenever an older version
|
|
*rewrites* the auxiliary files for a transaction created by a newer version,
|
|
since that might result in a different index (due to hash-table resizing) or hints file
|
|
(hash ordering, or the older version 1 format), while not invalidating the integrity file.
|
|
|
|
For example, using 1.1 on a repository, noticing corruption or similar issues and then running
|
|
``borg-1.0 check --repair``, which rewrites the index and hints, results in this situation.
|
|
Borg 1.1 would erroneously report checksum errors in the hints and/or index files and trigger
|
|
an automatic rebuild of these files.
|