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...and remove LargeObject
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IWYU needs to be explicitly instructed how to handle included .tpp
files in order to not falsely suggest their removal. Conversely,
it also needs to know not to suggest including .tpp files instead
of the corresponding .hpp files.
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- add more noexcept requirements and enforce existing
- fixing inconsistencies related to function arguments
- remove redundant static keywords
- silencing excessive lint reporting in test cases
While there, make more getters const ref.
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...and move it to the common stage.
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...to create ArtifactDigests.
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...with ArtifactDigestFactory::HashFileAs
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...with ArtifactDigest.
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...with ArtifactDigest
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...with ArtifactDigest.
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...with ArtifactDigest.
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...with ArtifactDigest.
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...with ArtifactDigest.
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... while keeping our .clang-format file.
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During multithreaded splicing, the main process can be forked (inheriting open file descriptors). In this case, the executable file saved using hardlinking becomes inaccessible. To prevent this, executables must be stored as copies made in a child process.
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...in LocalApi and BazelApi.
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...in LocalApi and BazelApi.
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and trees.
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For splicing of large objects from external sources additional checks are performed:
* The digest of the spliced result must be equal to the expected digest;
* The parts of a spliced tree must be in the storage.
Tested:
* Regular splicing of large objects;
* If the result is unexpected, splicing fails;
* If some parts of a tree are missing, splicing fails.
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* Uplink parts of the large entry before entry itself;
* Uplink large entries in LargeObjectCAS::GetEntryPath to not split things two times;
* Promote spliced tree during uplinking of a large tree entry to properly promote parts of the tree;
* Uplink large entries in LocalUplink{Blob, Tree} to support proper uplinking in Action Cache and Target Cache;
Tested:
* Uplink large blobs and trees;
* Uplink a large object that depends on other large objects.
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Implicitly reconstruct objects during regular uplinking of Blobs/Trees.
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Main culprits:
- std::size_t, std::nullptr_t, and NULL require <cstddef>
- std::move and std::forward require <utility>
- unordered maps and sets require respective includes
- std::for_each and std::all_of require <algorithm>
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Some of the more specific issues addressed:
- missing log_level target/include
- header-only libs wrongly marking deps as private
- missing/misplaced gsl includes
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...as early as possible. This ensures that callers always receive
only the tree entries for the supported object types.
For the symlinks non-upwardness check we pass a lambda capturing
the real backend of the tree entries, such that the symlinks can
be read.
Updates git_tree tests accordingly.
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As those functions indicate success, it is up to the caller to
decide if the error was fatal or not. Reporting an error nevertheless
might result in error messages on successful operaitons, which is
confusing for the user.
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The improved GC implementation uses refactored storage
classes instead of directly accessing "unknown" file paths.
The required storage class refactoring is quite substantial
and outlined in the following paragraphs.
The module `buildtool/file_system` was extended by:
- `ObjectCAS`: a plain CAS implementation for
reading/writing blobs and computing digests for a given
`ObjectType`. Depending on that type, files written to the
file system may have different properties (e.g., the x-bit
set) or the digest may be computed differently (e.g., tree
digests in non-compatible mode).
A new module `buildtool/storage` was introduced containing:
- `LocalCAS`: provides a common interface for the "logical
CAS", which internally combines three `ObjectCAS`s, one
for each `ObjectType` (file, executable, tree).
- `LocalAC`: implements the action cache, which needs the
`LocalCAS` for storing cache values.
- `TargetCache`: implements the high-level target cache,
which also needs the `LocalCAS` for storing cache values.
- `LocalStorage`: combines the storage classes `LocalCAS`,
`LocalAC`, and `TargetCache`. Those are initialized with
settings from `StorageConfig`, such as the build root base
path or number of generations for the garbage collector.
`LocalStorage` is templated with a Boolean parameter
`kDoGlobalUplink`, which indicates that, on every
read/write access, the garbage collector should be used
for uplinking across all generations (global).
- `GarbageCollector`: responsible for garbage collection and
the global uplinking across all generations. To do so, it
employs instances of `LocalStorage` with `kDoGlobalUplink`
set to false, in order to avoid endless recursion. The
actual (local) uplinking within two single generations is
performed by the corresponding storage class (e.g.,
`TargetCache` implements uplinking of target cache entries
between two target cache generations etc.). Thereby, the
actual knowledge how data should be uplinked is
implemented by the instance that is responsible for
creating the data in the first place.
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