2021-07-15 15:14:32 +03:00
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---
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layout: developer-doc
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title: IR Caching in the Enso Compiler
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category: runtime
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tags: [runtime, caching]
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order: 10
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---
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# IR Caching in the Enso Compiler
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One of the largest pain points for users of Enso at the moment is the fact that
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it has to precompile the entire standard library on every project load. This is,
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in essence, due to the fact that the current parser is abysmally slow, and
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incredibly demanding. The obvious solution to improve this is to take the parser
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out of the equation in its entirety, by serialising the parser's output.
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To that end, we want to serialise the Enso IR to a format that can later be read
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back in, bypassing the parser entirely. Furthermore, we can move the boundary at
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which this serialisation takes place to the end of the compiler pipeline,
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thereby bypassing doing most of the compilation work, and further improving
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startup performance.
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<!-- MarkdownTOC levels="2,3" autolink="true" -->
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- [Serialising the IR](#serialising-the-ir)
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- [Breaking Links](#breaking-links)
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- [Storing the IR](#storing-the-ir)
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- [Metadata Format](#metadata-format)
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- [Portability Guarantees](#portability-guarantees)
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- [Loading the IR](#loading-the-ir)
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- [Integrity Checking](#integrity-checking)
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- [Error Handling](#error-handling)
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- [Testing the Serialisation](#testing-the-serialisation)
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- [Future Directions](#future-directions)
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2021-07-15 15:14:32 +03:00
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<!-- /MarkdownTOC -->
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## Serialising the IR
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As the serialised IR doesn't need to be read by anything other than Enso, we
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need not use a representation that is portable between platforms. As a result,
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we have picked the `Serializable` infrastructure that is _already present_ on
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the JVM. It has the following benefits:
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- It is able to serialise arbitrary object graphs while maintaining object
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identity and tracking references. This cannot be disabled for `Serializable`,
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but that is fine as we want it.
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- It is built into the JVM and is hence guaranteed to be portable between
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instances of the same JVM.
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- It copes fine with highly-nested scala types, like our IR.
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In order to maximise the benefits of this process, we want to serialise the IR
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as _late_ in the compiler pipeline as possible. This means serialising it just
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before the code generation step that generates Truffle nodes (before the
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`RuntimeStubsGenerator` and `IrToTruffle` run).
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This serialisation should take place in an _offloaded thread_ so that it doesn't
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block the compiler from continuing.
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### Breaking Links
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Doing this naïvely, however, means that we can inadvertently end up serialising
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the entire module graph. This is due to the `BindingsMap`, which contains a
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reference to the associated `runtime.Module`, from which there is a reference to
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the `ModuleScope`. The `ModuleScope` may then reference other `runtime.Module`s
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which all contain `IR.Module`s. Therefore, done in a silly fashion, we end up
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serialising the entire reachable module graph. This is not what we want.
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While the ideal way of solving this problem would be to customise the
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serialisation and deserialisation process for the `BindingsMap`, the JVM's
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`Serializable` does not provide the ability to customise it enough to solve this
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problem. Instead, we solve it using a preprocessing step:
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- We can modify `BindingsMap` and its child types to be able to contain an
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unlinked module pointer
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`case class ModulePointer(qualifiedName: List[String])` in place of a
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`Module`.
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- As the `MetadataStorage` type that holds the `BindingsMap` is mutable it can
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be updated in place without having to reassemble the entire IR graph.
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- Hence, we can traverse all the nodes in the `ir.preorder` that have metadata
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consisting of either the `BindingsMap` or `ResolvedName` types (provided by
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the following passes: `BindingAnalysis`, `MethodDefinitions`,
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`UppercaseNames`, `VectorLiterals`, `Patterns`), and perform a replacement.
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Having done this, we have broken any links that the IR may hold between modules,
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and can serialise each module individually.
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This serialisation must take place _after_ codegen has happened as it modifies
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the IR in place. The compiler can handle giving it to the offloaded
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serialisation thread. It _may_ be necessary to `duplicate` the IR before handing
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it to this thread, but this should be checked during development.
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## Storing the IR
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The serialized IR needs to be stored in a location that is tied to the library
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that it serializes. Despite this, we _also_ want to be able to ship cached IR
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with libraries. This leads to a two pronged solution where we check two
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locations for the cache.
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1. **With the Library:** As libraries can have a hidden `.enso` directory, we
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can use a path within that for caching. This should be
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`$package/.enso/cache/ir/enso-$version/`, and can be accessed by extending
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the `pkg` library to be aware of the cache directories.
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2. **Globally:** As some library locations may not be writeable, we need to have
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a global out-of-line cache that is used if the first one is not writeable.
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This is located under `$ENSO_DATA` (whose location can be obtained from the
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`RuntimeDistributionManager`), and is located under the path
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`$ENSO_DATA/cache/ir/$hash/enso-$version/`, where `$hash` is the `SHA3-224`
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hash of the tuple `(namespace, library_name, version)`, where
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`version = SemVer | "local"`. This hash is computed by concatenating the
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string representations of these fields.
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In each location, the IR is stored with the following assumptions:
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- The IR file is located in a directory modelled after its module path, followed
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by a file named after the module itself with the extension `.ir` (e.g. the IR
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for `Standard.Base.Data.Vector` is stored in `Standard/Base/Data/Vector.ir`).
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- The [metadata](#metadata-format) file is located in a directory modelled after
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its module path, followed by a file named after the module itself with the
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extension `.meta` (e.g. the metadata for `Standard.Base.Data.Vector.enso` is
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stored in `Standard/Base/Data/Vector.meta`). This is right next to the
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corresponding `.ir` file.
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Storage of the IR only takes place iff the intended location for that IR is
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_empty_.
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### Metadata Format
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The metadata is used for integrity checking of the cached IR to prevent loading
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corrupted or out of date data from the cache. Due to the fact that engines can
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only load IR created by their versions, and cached IR is located in a directory
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named after the engine version, this format need not be forward compatible.
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It is a JSON file as follows:
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```typescript
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{
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sourceHash: String; // The hash of the corresponding source file.
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blobHash: String; // The hash of the blob.
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compilationStage: String; // The compilation stage of the IR.
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}
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```
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All hashes are encoded in SHA3-224 format, as is used by other components in the
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Engine. The engine version is encoded in the cache path, and hence does not need
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to be explicitly specified in the metadata.
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### Portability Guarantees
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As part of this design we provide only the following portability guarantees:
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- The serialised IR must be able to be deserialised by _the same version of
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Enso_ that wrote the original blob.
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## Loading the IR
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Loading the IR is a multi-stage process that involves performing integrity
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checking on the loaded cache. It works as follows.
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1. **Find the Cache:** Look in the global cache directory under `$ENSO_DATA`. If
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there is no cached IR here that is valid for the current configuration, check
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the ibrary's `.enso/cache` folder. This should be hooked into in
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`Compiler::parseModule`.
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2. **Check Integrity:** Check the module's [metadata](#metadata-format) for
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validity according to the [integrity rules](#integrity-checking).
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3. **Load:** If the cache passes the integrity check, load the `.ir` file. If
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deserialisation fails in any way, immediately fall back to parsing the source
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file.
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4. **Re-Link:** If loading completed successfully, re-link the `BindingsMap`
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metadata to the proper modules in question.
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The main subtlety here is handling the dependencies between modules. We need to
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ensure that, when loading multiple cached libraries, we properly handle them
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one-by-one. Doing this is as simple as hooking into `Compiler::parseModule` and
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setting `AFTER_STATIC_PASSES` as the compilation state after loading the module.
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This will tie into the current `ImportsResolver` and `ExportsResolver` which are
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run in an un-gated fashion in `Compiler::run`.
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In order to prevent the execution of malicious code when deserialising we should
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employ a deserialisation filter as built into the JDK.
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### Integrity Checking
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For a cache to be usable, the following properties need to be satisfied:
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1. The `sourceHash` must match the hash of the corresponding source file.
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2. The `blobHash` must match the hash of the corresponding `.ir` file.
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If any of these fail, the cache file should be deleted where possible, or
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ignored if it is in a read-only location.
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### Error Handling
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It is important, as part of this, that we fail under all circumstances into a
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working state. This means that:
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- If serialisation fails, we report a low-priority error message and continue.
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- If deserialisation fails, we fall back to loading and parsing the original
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source file.
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At no point should this mechanism be exposed to the user in any visible way,
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other than the fact that they may be seeing the actual files on disk.
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## Testing the Serialisation
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There are two main elements that need to be tested as part of this feature.
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- Firstly, we need to test the serialisation and deserialisation process,
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including the rewrite of `BindingsMap` to work properly.
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- We also need to test the discovery of cache locations on the filesystem and
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cache eviction strategies. The best way to do this is to set `$ENSO_DATA` to a
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temporary directory and then directly interact with the filesystem. Caching
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should be disabled for existing tests. This will require adding additional
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runtime options for debugging, but also constructing the `DistributionManager`
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on context creation (removing `RuntimeDistributionManager`).
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2021-09-18 15:48:13 +03:00
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## Future Directions
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Due to the less than ideal platform situation we're in, we're limited to using
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Java's `Serializable`. It is not as performant as other options.
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- [FST](https://github.com/RuedigerMoeller/fast-serialization) is around 10x
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faster than the JVM's serialization, and is a drop-in replacement.
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- However, the version that supports Java 11 utilises reflection that trips
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warnings that will be disallowed with Java 17 (the next LTS version for
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GraalVM).
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- The version that fixes this relies on the foreign memory API which is
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available in Java 17. I recommend that once we're on Java 17 builds the
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serialization is updated to work using FST.
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