9
The basic idea is that for a directory in a tree (committed or otherwise), we
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will have a single scalar value. If these values are the same, the contents of
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the subtree under that directory are necessarily the same.
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This is intended to help with these use cases, by allowing them to quickly skip
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over directories with no relevant changes, and to detect when a directory has
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* diff/status (both local trees and historical trees)
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Use-case oriented APIs
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----------------------
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Most of this will be hidden behind the Tree interface. This should cover
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``log -v``, ``diff``, ``status``, ``merge`` (and implicit merge during
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tree.iter_changes(other_tree)
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tree.get_file_lines(file_id) # and get_file, get_file_text
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Commit is similar to ``iter_changes``, but different because it needs to
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compare to all the trees. Commit currently needs to compare the working
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tree to all the parent trees, which is needed to update the last_modified
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field and would be unnecessary if we removed that field (for both files
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and directories) and did not store per-file graphs.
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This would potentially speed up commit after merge.
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Verbose commit also displays the merged files, which does
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require looking at all parents of files that aren't identical
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to the left-hand parent.
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Log is interested in two operations: finding the revisions that touched
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anything inside a directory, and getting the differences between
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consecutive revisions (possibly filtered to a directory)::
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find_touching_revisions(branch, file_id) # should be on Branch?
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Log shows the revisions that merged a change. At the moment that is not
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included in the per-file graph, and it would also not be visible if the
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directories were hashed.
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* Is this a good idea at all?
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If changing a file changes all its parent directories up to the root it
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will cause more churn on commit. (We currently update the all-in-one
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inventory, but only have to update one line of it.)
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Every time a child changes, we'll get a new node in the per-directory
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graph. This is generally useful: it allows bzr log to do the default
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mode easily, which is to show all changes under that directory. The
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less common operation, ``log --no-recursive`` is still possible by
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looking only at when the directory itself was renamed, added or removed.
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(That is what the directory graph describes in bzr 0.18 and it is rarely
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* Should these be hashes or revision ids or something else?
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Pros of using hashes: hashes are easy to generate by a foreign branch
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plugin (e.g. bzr-svn). They don't need to get recursive last-changed
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from the foreign branch, or to walk back through history. They just
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need the relevant directory state, which any system we support can
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Hashes converge: if you modify and then modify back, you get the same
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hash. This is a pro because you can detect that there were ultimately
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no significant changes. And also a con: you cannot use these hashes to form a graph
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because they get cycles.
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* Are the values unique across the whole tree, or only when comparing
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different versions of the same object?
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If we use last-changed revisions, then they will be very not unique
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across the whole tree. To look up the contents, you must pass a
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composite key like ``(file_id, last_changed)``.
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If we use hashes they will be same only when the two contain the same
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contents. Since we say that file ids must be unique, this
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means they will match if and only if they are empty. We might relax
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that in future when we introduce path tokens.
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* Is it reasonable to assume hashes won't collide?
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The odds of SHA-1 hashes colliding "accidentally" are vanishingly small.
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It is possible that a `preimage attack`_ against SHA-1 may be discovered
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in the future. Since we're not proposing in this document to make
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revision-ids be SHA-1, if SHA-1 was obsoleted then we could rewrite the
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contents of revisions but would not need to rename revisions. So the
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impact of such a migration should just be a format upgrade, and a
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recommendation (but not requirement) to re-sign revisions.
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.. _`preimage attack`: http://tools.ietf.org/html/rfc4270
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* If we use hashes, should it be the hash of the
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representation stored for a directory?
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In other words, should we pun the representation of the directory with
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the form used for validation.
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If there's some data stored that's not in the hash it's problematic.
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The hash in no longer (effectively) uniquely identifies the
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It is desirable that we have a hash that covers all data, to guard
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against bugs, transmission errors, or users trying to hand-hack files.
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Since we need one hash of everything in the tree, perhaps we should also
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use it for the fingerprint.
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Testaments explicitly separate the form used for hashing/signing from
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the form used for storage. This allows us to change the storage form
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without breaking existing GPG signatures. The downside is that we need
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to do work O(tree) to make a testament, and this slows down signing,
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verifying and generating bundles. It also means that there is some
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stored data which is not protected by the signature: this data is less
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important, but corruption of it would still cause problems.
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We have encountered some specific problems with disagreement between
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inventories as to the last-change of files, which is currently unsigned.
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These problems can be introduced by ghosts.
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If we hash the representation, there is still a way to support old
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signatures, assuming that we never discard irreplaceable information.
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The signature should say what format it applies to (similar to
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testaments), and we could transform in memory the tree back to that
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* Is hashing substantially slower than other possible approaches?
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We already hash all the plain files. Except in unusual cases, the
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directory metadata will be substantially smaller: perhaps 200:1 as a
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When building a bzr tree, we spend on the order of 100ms hashing all the
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source lines to validate them (about 13MB of source).
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* Can you calculate one from a directory in the working tree? Without a basis?
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This seems possible with either hashes or revision ids.
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Using last_changed means that calculating the fingerprint from a working
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tree necessarily requires reading the inventory for the basis
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revision, so that we know when unchanged files were last changed. With
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hashes we could calculate them using the working tree information alone.
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It's true that we will often then compare that information to the basis
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tree (e.g. for simple ``bzr diff``), but we may only have to compare at
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the top level, and sometimes we're comparing to a
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different tree. This also touches on whether we should store
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``last_modified`` for files, rather than directories.
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For revision ids we need to assign a value to use for uncommitted
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changes, but see below about the problems of this.
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In some ways it would be elegant to say (hypothetical)::
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wt.get_root().get_last_modified() == branch.get_last_revision()
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to know that nothing was changed; but this may not be much better than
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wt.get_root().get_hash() ==
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branch.get_basis().get_root().get_hash()
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* Can you use this to compare (directories from) two working trees?
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If you can generate it from a working tree, you should be able to use it
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This does rule out for example using ``last_modified=None`` or
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``='current:'`` to mean "changed in the working tree." Even if this is
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not supported there seems some risk that we would get the same
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fingerprint for trees that are actually different.
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hypothetical revision id to the tree for uncommitted files. In that
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case there is some risk that the not-yet-committed id would become
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visible or committed.
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* Can we use an "approximate basis"?
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When using radix trees, you may need context beyond the specific
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directory being compared.
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* Can you get the fingerprint of parents directories with only selected file ids
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taken from the working tree?
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With hashes, we'd want to carry through the unselected files and
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directories from the values they had in the parent revision.
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* Are unbalanced trees a significant problem? Trees can be unbalanced by having
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many directories (deep or wide), or many files per directory.
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For small trees like bzr, 744 of 874 are in the bzrlib subtree. In
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general, larger trees are more balanced, because humans, editors and
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other tools have trouble managing very unbalanced trees. But there are
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exceptions: Aaron has one tree with 20,000 generated but versioned
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entries in one directory.
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* Should we use a radix tree approach where fingerprints are calculated on a synthetic
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tree that is by definition balanced, even when the actual tree is unbalanced?
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* What are the specific advantages of using recursive-last-modified rather than
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It may be a smaller step change.
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It's a bidirectional link: given a directory text identifier ``(file_id,
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last_changed)`` you can look up the revision that last changed it.
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From the preceding, even without the per-file graph you can skip through
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the history of this file: go to the last-changed revision, look at all
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its parents and repeat.
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* Is it a smaller change to use recursive-last-modified on directories?
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1. We can just put it into the current inventory format without changing
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By contrast to use a hash we'd have to either split up the inventory
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as stored, or change the sort order for the inventory, or synthesize
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per-directory inventories in memory for hashing.
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However, XML is somewhat redundant and slow to parse/generate; and
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reading the whole thing before comparing some sections is only a
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partial win. It may be a smaller change but we'd be preserving
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things we want to change.
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1. At present we rarely hash storage representations, only file texts.
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This is not a large technical change, but it is a conceptual change.
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This has some consequences for how we can upgrade it in future: all
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the changed directories need to be rewritten up to the revision level.
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1. If we address directories by hash we need hash-addressed
274
1. If we address directories by hash then for consistency we'd probably
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(not necessarily) want to address file texts by hash.
277
1. The per-file graph can't be indexed by hash because they can converge, so we
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need to either rework or dispose of the per-file graph.
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* Any possibilities for avoiding hashes recurring?
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1. Hash along with an identification of the parents (as in hg). Then you
284
can't convert a tree without all its basis trees, and there is still
285
convergence when the same merge is done by two people, and you can't
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create it directly from the working tree.
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1. Include last-modified revision id in the hash.
290
1. Index by ``(revision, hash)`` or vice versa.
292
1. Store a per-file graph and allow it to have repeated keys. The graph
293
would tell you about all the parent texts ever seen; you would need
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to use revision graph information to resolve ambiguities.
297
* What are the specific disadvantages of using recursive-last-modified rather than
300
To calculate the last-changed revision, given the last-changed
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information of the contained files, you need to look at the revision
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graph. They're not enough because you need to know the relations
303
between the mentioned revisions. In a merge it's possible the correct
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directory last-modified will not be the same as that of any of the files
305
within it. This can also happen when a file is removed (deleted or
306
renamed) from a directory.
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* Should we split up storage of the inventories?
311
This is not quite the same but connected.
314
* How does this relate to per-file/per-directory hashes?
316
If the version of a file or directory is identified by a hash, we can't
317
use that to point into a per-file graph. We can have a graph indexed by
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``(file_id, hash, revision_id)``. The last-modified could be stored as
321
The graph would no longer be core data; it could be always present but
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might be rebuilt. Treating it as non-core data may make some changes
323
like shallow branches easier?
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* How do you ask a tree for a given text?
330
revision_tree.get_file_lines(file_id)
332
so the choice of storage is hidden behind the revision tree: it could be
333
accessed by ``(file_id, last_changed)`` or by hash or otherwise.
335
At the moment the Repository exports a friend api to RevisionTree,
336
currently usually talking in VersionedFiles.
338
We probably wouldn't want Repository to expose a ``get_text_for_sha1()``
339
interface because that would be very difficult to support on old
340
repositories or on foreign branches.
358
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