mirror of
https://github.com/enso-org/enso.git
synced 2024-12-24 02:23:28 +03:00
424 lines
19 KiB
Markdown
424 lines
19 KiB
Markdown
---
|
|
layout: developer-doc
|
|
title: Runtime Features
|
|
category: runtime
|
|
tags: [runtime, design]
|
|
order: 4
|
|
---
|
|
|
|
# Runtime Features
|
|
|
|
This document contains a detailed specification of Enso's runtime. It includes a
|
|
description of the technologies on which it is built, as well as the features
|
|
and functionality that it is required to support. In addition, the document aims
|
|
to explain why _this_ design, rather than one of the many alternatives available
|
|
to the team.
|
|
|
|
When we refer to the Enso 'runtime' in this document, we are referring to the
|
|
combination of the language communication protocol, typechecker, optimiser, and
|
|
interpreter. Though the interpreter itself has its own runtime, it is these
|
|
components that make up _Enso's_ runtime.
|
|
|
|
The runtime is built on top of [GraalVM](https://www.graalvm.org/), a universal
|
|
virtual machine on which you can run any language with an appropriate
|
|
interpreter. In basing Enso's runtime on GraalVM, we not only have access to a
|
|
comprehensive toolkit for building high-performance language interpreters, but
|
|
also to the ecosystems of all the other languages (e.g. C++, Python, R) that can
|
|
run on top of it. GraalVM also brings some additional important tooling, such as
|
|
the JVM ecosystem's performance monitoring, analysis, and debugging toolsets.
|
|
|
|
The runtime described below is a complex beast, so this document is broken up
|
|
into a number of sections. These aim to provide an architectural overview, and
|
|
then describe the design of each component in detail.
|
|
|
|
<!-- MarkdownTOC levels="1,2" autolink="true" -->
|
|
|
|
- [Architectural Overview](#architectural-overview)
|
|
- [The Broader Enso Ecosystem](#the-broader-enso-ecosystem)
|
|
- [The Runtime's Architecture](#the-runtimes-architecture)
|
|
- [Choosing GraalVM](#choosing-graalvm)
|
|
- [The Runtime Components](#the-runtime-components)
|
|
- [Language Server](#language-server)
|
|
- [Filesystem Driver](#filesystem-driver)
|
|
- [Typechecker](#typechecker)
|
|
- [Optimiser](#optimiser)
|
|
- [Interpreter and JIT](#interpreter-and-jit)
|
|
- [Cross-Cutting Concerns](#cross-cutting-concerns)
|
|
- [Caching](#caching)
|
|
- [Profiling and Debugging](#profiling-and-debugging)
|
|
- [Foreign Language Interoperability](#foreign-language-interoperability)
|
|
- [Lightweight Concurrency](#lightweight-concurrency)
|
|
- [The Initial Version of the Runtime](#the-initial-version-of-the-runtime)
|
|
- [Development Considerations](#development-considerations)
|
|
|
|
<!-- /MarkdownTOC -->
|
|
|
|
# Architectural Overview
|
|
|
|
The Enso runtime is just one of the many components of the Enso ecosystem. This
|
|
section provides an overview of how it fits into the broader ecosystem, with a
|
|
particular focus on how it enables workflows for Enso Studio, the Enso CLI, and
|
|
Language Server integration. In addition, this section also explores the
|
|
architecture of the runtime itself, breaking down the opaque 'runtime' label
|
|
into the
|
|
|
|
## The Broader Enso Ecosystem
|
|
|
|
While the runtime is arguably the core part of Enso, for the language would not
|
|
be able to exist without it, the language's success is just as dependent on the
|
|
surrounding ecosystem.
|
|
|
|
TBC...
|
|
|
|
It is worth providing a brief explanation of each of the components to aid in
|
|
understanding how the runtime fits into the ecosystem.
|
|
|
|
- **Enso Studio GUI:** This is the interface with which most of Enso's users
|
|
will interact. It handles the drawing of and interaction with the Enso graph
|
|
for users, as well as the searcher and other user-facing functionality. It
|
|
also provides a text editor.
|
|
- **Project Manager:** This allows for management of one or more Enso projects,
|
|
and is primarily responsible for file-system-agnostic interaction with the
|
|
project structure, and spawning of the Enso runtime.
|
|
- **GUI Backend:** The GUI backend is instantiated for each project, and is
|
|
responsible for all of the user-facing logic that goes into interaction with
|
|
the Enso runtime.
|
|
- **Graph State Manager:** This component handles management of the state
|
|
required to draw the graph in the GUI.
|
|
- **Double Representation Manager:** This component handles the encoding and
|
|
decoding of the Enso program to and from the intermediate representation.
|
|
- **Undo/Redo Manager:** This component handles undo and redo for the graph, a
|
|
somewhat novel operation as it does not not always have a 1:1 correspondence
|
|
with textual editing.
|
|
- **CLI:** This provides a command-line (specifically a terminal) interface to
|
|
the Enso runtime. This allows both for the CLI invocation of Enso, as well as
|
|
an interactive REPL. This communicates with the runtime itself via the
|
|
language server protocol.
|
|
- **Enso Runtime:** This is what is described in this document, and is
|
|
responsible for the execution of Enso programs. It handles the typechecking,
|
|
optimisation, and interpretation of Enso code, as well as the provision of
|
|
interfaces to foreign languages.
|
|
|
|
## The Runtime's Architecture
|
|
|
|
In order to better appreciate how the components specified below interact, it is
|
|
important to have an understanding of the high-level architecture of the runtime
|
|
itself. The design in this document pertains _only_ to the 'Enso Runtime'
|
|
component of the diagram above, and hence makes no mention of the others.
|
|
|
|
In the diagram below, the direction of arrows is used to represent the 'flow' of
|
|
information between the various components.
|
|
|
|
TBC...
|
|
|
|
# Choosing GraalVM
|
|
|
|
Building the runtime on top of GraalVM was of course not the only choice that
|
|
could've been made, but it was overwhelmingly the most sensible option out of
|
|
those considered.
|
|
|
|
At the time the runtime was designed, there were three main options that were
|
|
being considered.
|
|
|
|
- **LLVM:** A battle-tested and comprehensive toolchain for the creation of
|
|
language compilers, [LLVM](https://llvm.org/) includes facilities for
|
|
compilation, optimisation, JIT, and linking.
|
|
- **GHC:** The [Glasgow Haskell Compiler](https://gitlab.haskell.org/ghc/) is a
|
|
sophisticated compiler and runtime for Haskell that provides a
|
|
language-agnostic set of internal representations that could be leveraged to
|
|
compile and/or interpret other functional languages.
|
|
- **JVM:** The [JVM](https://openjdk.java.net/) is a high-performance virtual
|
|
machine that includes sophisticated garbage collection, profiling tools, and a
|
|
JIT compiler.
|
|
- **GraalVM:** A universal virtual machine and language development toolkit,
|
|
[GraalVM](https://www.graalvm.org/) provides a framework for building language
|
|
interpreters, as well as a JIT compiler. Most importantly, it provides tools
|
|
for seamless interoperability between languages that can run on Graal, which
|
|
include Python and R.
|
|
|
|
The decision to build Enso's runtime using GraalVM was primarily motivated by
|
|
business concerns, but these concerns did not override the technical as well.
|
|
Addressing them one by one provides a comprehensive picture of why the decision
|
|
was made.
|
|
|
|
Overall, it is clear that GraalVM is an optimal choice for Enso at this stage of
|
|
the language's development. While the other potential targets do have their
|
|
upsides (e.g. the JVM's sophisticated garbage collection machinery), they all
|
|
had at least one 'fatal flaw' for Enso's use case.
|
|
|
|
### Speed of Development
|
|
|
|
A language runtime is a complex beast, so any solution that could remove some of
|
|
the implementation burden would be beneficial to Enso as a product.
|
|
|
|
Where LLVM provides comprehensive tools for compiling languages, it provides no
|
|
actual runtime. This would require significant implementation effort, requiring
|
|
the implementation of facilities for concurrency, as well as garbage collection,
|
|
neither of which are simple tasks.
|
|
|
|
GHC, on the other hand, provides a comprehensive runtime system that includes
|
|
both a garbage collector and sophisticated concurrency system. However, while it
|
|
does provide language-agnostic intermediate representations, these are tied to
|
|
Haskell from a development perspective. Unlike LLVM, GraalVM, or even the JVM,
|
|
if GHC Haskell requires a change to these representations, that change will be
|
|
made.
|
|
|
|
With many languages already targeting the JVM it also seemed like an attractive
|
|
option. The stable bytecode target would be useful, but other languages have
|
|
proven the challenges of generating sensible bytecode to provide good language
|
|
performance.
|
|
|
|
GraalVM manages to provide excellent performance with a sensible, high-level
|
|
interface, thereby enabling rapid development of a performant runtime without
|
|
the need to implement complex components such as a GC and concurrency.
|
|
|
|
### Language Interoperability Support
|
|
|
|
With Enso aiming to be the be-all and end-all for the data-science world, the
|
|
ability to seamlessly interoperate with other programming languages is key. This
|
|
means that a user should be able to paste in some Python or R code and have it
|
|
work properly.
|
|
|
|
From a simple perspective, there were no other options in this category. While
|
|
the JVM would allow for interoperability with other JVM languages such as Scala,
|
|
Kotlin, and Java itself, the two 'most important' languages for interoperation
|
|
had no support. LLVM's story is similar, allowing users to use LLVM IR as a
|
|
common interoperation format, but this is far less practical than the JVM. With
|
|
GHC, any interoperation would have to be developed from-scratch and by hand,
|
|
essentially ruling it out in this category.
|
|
|
|
With GraalVM supporting not only our primary interoperability targets, but also
|
|
the whole JVM ecosystem and any language that targets LLVM, it is an absolute
|
|
dream for ensuring that Enso can seamlessly communicate with a whole host of
|
|
other programming languages.
|
|
|
|
### Implementation Performance
|
|
|
|
Data science often involves the manipulation of very large amounts of data, and
|
|
ensuring that an interactive environment like Enso doesn't slow down as it does
|
|
so requires a high level of performance.
|
|
|
|
GraalVM's partially-evaluated-interpreter based approach allows the developers
|
|
to write a 'naive interpreter' and automatically have the platform provide
|
|
better performance. This is a stark contrast to all of the other listed options,
|
|
each of which would require significant complexity around generating the right
|
|
intermediate representation structures, as well as significant work on front-end
|
|
language optimisations.
|
|
|
|
In essence, GraalVM provides for the best performance with the smallest amount
|
|
of effort, while still providing comprehensive facilities to improve performance
|
|
further in the future.
|
|
|
|
### Maintenance Burden
|
|
|
|
Just as important as getting a working runtime is the ability for the developers
|
|
to improve and evolve it. This encompasses many factors, but Enso is primarily
|
|
concerned with being able to evolve without having to account for undue changes
|
|
to the runtime.
|
|
|
|
LLVM provides a relatively stable IR target, so the maintenance burden wouldn't
|
|
have been too onerous. Similarly for the JVM, where the bytecode format has been
|
|
stable for many years. Though both projects add new instructions, they very
|
|
rarely remove them, meaning that Enso's potential code generator would be able
|
|
to work as the underlying platform evolves.
|
|
|
|
As mentioned before, however, the intermediate representations in GHC that Enso
|
|
would have used as a target are very much changeable. This is due to their
|
|
primary existence being to support GHC's version of Haskell, which means that
|
|
they change often. Furthermore, their generation would require copying of many
|
|
of the idiosyncrasies of GHC's lowering mechanisms, and in all likelihood place
|
|
a significant burden on Enso's developers.
|
|
|
|
GraalVM, on the other hand, provides a stable interface to writing an
|
|
interpreter that is far higher level than any of the other options. This API is
|
|
very unlikely to change, but even if it does the high-level nature means that
|
|
the maintenance burden of coping with those changes is significantly reduced.
|
|
Furthermore, GraalVM comes with the truffle toolkit for building interpreters,
|
|
and as a result provides many of the facilities required by Enso for free or at
|
|
least for little effort.
|
|
|
|
# The Runtime Components
|
|
|
|
Like any sensible large software project, Enso's runtime is modular and broken
|
|
down into components. These are described in detail below.
|
|
|
|
## Language Server
|
|
|
|
The language server component is responsible for controlling the runtime itself.
|
|
It communicates with other portions of the ecosystem (such as the REPL and the
|
|
Enso Studio backend) via a protocol. While this protocol is based on the
|
|
[Language Server Protocol](https://microsoft.github.io/language-server-protocol/specification),
|
|
it has been extended significantly to better support Enso's use-cases.
|
|
|
|
<!-- TODO
|
|
- A description of the protocol format.
|
|
- A description of bidirectional protocol operation. This means that Enso's
|
|
runtime is not purely a server, but can also push data to the client.
|
|
- A description of how the protocol design admits extensibility.
|
|
- An informal description of each of the protocol messages, for example \
|
|
(`expandOptionalArgs`, which expands all defaulted arguments in a call with
|
|
the defaults as the values). Needs to account for on-demand opt, metadata
|
|
handling.
|
|
- A description of how a Enso process should manage source files in server mode,
|
|
including a description of changesets (dual payload, text diff or AST diff).
|
|
-->
|
|
|
|
## Filesystem Driver
|
|
|
|
This component of the runtime deals with access from the runtime to external
|
|
devices. This includes the Enso code files on disk, but is also responsible for
|
|
watching filesystem resources (such as databases, files, and sockets) that are
|
|
used by Enso programs.
|
|
|
|
<!-- TODO
|
|
- A diagram of the interactive file-system watching.
|
|
- A description of how this layer words.
|
|
- A design for the strategy for reloading based on source-data changes.
|
|
-->
|
|
|
|
## Typechecker
|
|
|
|
The typechecker is the portion of the runtime that handles the type-inference
|
|
and type-checking of Enso code. This is a sophisticated piece of machinery, with
|
|
the primary theory under which it operates being described in the specification
|
|
of [the type system](../types/README.md).
|
|
|
|
<!-- TODO
|
|
- A description of the typechecker's architecture as graph transformations.
|
|
- An analysis of how the typechecking process interacts with the interpreter.
|
|
- An analysis of how we can associate type information with nodes in the Enso
|
|
graph. A description of what information can be erased.
|
|
- An analysis of how the typechecker will support for runtime metaprogramming
|
|
and the manipulation of types.
|
|
-->
|
|
|
|
## Optimiser
|
|
|
|
With much of Enso's performance relying on the JIT optimiser built into Graal,
|
|
the native language optimiser instead relies on handling more front-end specific
|
|
optimisations.
|
|
|
|
<!-- TODO
|
|
- A diagram of the optimisation process.
|
|
- A description of its architecture.
|
|
- A description of the optimisations that it needs to perform to generate a
|
|
sensible input to GraalVM.
|
|
- A description of additional transformations it needs to perform (e.g. for
|
|
the handling of strictness).
|
|
- A design for hierarchical description of optimisation passes.
|
|
- A design for parallel local optimisation.
|
|
-->
|
|
|
|
## Interpreter and JIT
|
|
|
|
The interpreter component is responsible for the actual execution of Enso code.
|
|
It is built on top of the Truffle framework provided by GraalVM, and is JIT
|
|
compiled by GraalVM.
|
|
|
|
<!-- TODO
|
|
- A design for encoding the execution model for Lazy and Strict computations.
|
|
- A design for encoding the evaluation of monadic contexts (how `=` works).
|
|
- A design for the compilation strategy (what is resolved when).
|
|
- A design for how we work with wired-in functionality (e.g. the stdlib).
|
|
- An analysis of techniques that can be used to minimise interpreter startup
|
|
time.
|
|
- A description of support for library precompilation.
|
|
- An analysis of how the interpreter is involved in the typechecking process.
|
|
-->
|
|
|
|
# Cross-Cutting Concerns
|
|
|
|
The runtime also has to deal with a number of concerns that don't fit directly
|
|
into the above components, but are nevertheless important parts of the design.
|
|
|
|
## Caching
|
|
|
|
The runtime cache for Enso is a key part of how it delivers exceptional
|
|
performance when working on big data sets. The key recognition, as seen in many
|
|
data processing tools, is that changing code or data often doesn't require the
|
|
interpreter to recompute the entire program. Instead, it can only recompute the
|
|
portions that are required of it, while using cached results for the rest.
|
|
|
|
<!-- TODO
|
|
- Describe the architecture of the cache.
|
|
- Describe the dependency-tracking, keying, and cache eviction strategies with a
|
|
focus on granularity, performance, and type information (e.g. strictness).
|
|
- Describe the LRU mechanism that can be used to constrain cache size to under a
|
|
certain amount of RAM.
|
|
- A description of how the cache is made IO aware and operates in relation to
|
|
the filesystem layer (see Skip for more ideas).
|
|
- An examination of how cache state can be persisted to disk to enable fast
|
|
reloading of analysis projects.
|
|
-->
|
|
|
|
## Profiling and Debugging
|
|
|
|
Similarly important to the Enso user experience is the ability to visually debug
|
|
and profile programs. This component deals with the retrieval, storage, and
|
|
manipulation of profiling data, as well as the ability to debug programs in Enso
|
|
using standard and non-standard debugging paradigms.
|
|
|
|
<!-- TODO
|
|
- An analysis of how breakpoints can be set in the Truffle interpreter.
|
|
- A design for a framework / API for introspection of the interpreter state.
|
|
- An analysis of how the JVM tools can be used to collect Enso-side profiling
|
|
information.
|
|
- A design for this profiling data collection and a discussion of how to expose
|
|
it to users.
|
|
-->
|
|
|
|
## Foreign Language Interoperability
|
|
|
|
This component deals with using the GraalVM language interoperability features
|
|
to provide a seamless interface to foreign code from inside Enso.
|
|
|
|
<!-- TODO
|
|
- A design for standard, unsafe, C-level FFI using JNI.
|
|
- A design for what types can be exposed across the C-FFI boundary.
|
|
- A design for how to expose foreign languages to Enso in a safe fashion.
|
|
- An analysis of how Enso can minimise the conversions that take place when
|
|
going between languages.
|
|
-->
|
|
|
|
## Lightweight Concurrency
|
|
|
|
Though not strictly a component, this section deals with how Enso can provide
|
|
its users with lightweight concurrency primitives in the form of green threads.
|
|
|
|
<!-- TODO
|
|
- Examine how the JVM's basic concurrency primitives can be used in Enso.
|
|
- A design for how these can be used for automatic parallelism.
|
|
- An examination of how Project Loom could be employed to provide users with
|
|
lightweight concurrency in Enso, thereby avoiding async/await 'colouring' of
|
|
functions.
|
|
-->
|
|
|
|
# The Initial Version of the Runtime
|
|
|
|
In order to have a working version of the new runtime as quickly as possible, it
|
|
was decided to design and build an initial, stripped-down version of the final
|
|
design. This design focused on development of a minimal working subset of the
|
|
runtime that would allow Enso to run.
|
|
|
|
<!-- TODO
|
|
- Describe a design for a dynamic-only runtime
|
|
- Describe hardcoded support for IO, State, Exception (!) monads
|
|
-->
|
|
|
|
# Development Considerations
|
|
|
|
As part of developing the new Enso runtime, the following things need to be
|
|
accounted for. This is to ensure that the eventual quality of the software is
|
|
high, and that we also provide a product that is actually useful to our users.
|
|
|
|
- **Benchmarking:** A comprehensive micro and macro benchmark suite that tests
|
|
all the components of the runtime. This should be accompanied by a regression
|
|
suite to catch performance regressions.
|
|
- **Execution Tests:** A test suite that checks that executing Enso programs
|
|
results in the correct outputs.
|
|
- **Typechecker Tests:** A test suite that ensures that changes made to the
|
|
typechecker do not result in acceptance of ill-typed programs, or rejection of
|
|
well-typed programs.
|
|
- **Caching Tests:** A test suite that ensures that data is evicted from the
|
|
cache when it should be, and retained when it should be.
|