# Beaver đĻĢ
[![Package](https://img.shields.io/badge/-Package-important)](https://hex.pm/packages/beaver) [![Documentation](https://img.shields.io/badge/-Documentation-blueviolet)](https://hexdocs.pm/beaver)
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**Boost the almighty blue-silver dragon with some magical elixir!** đ§đ§ââī¸đ§ââī¸
## Motivation
In the de-facto way of using MLIR, we need to work with C/C++, TableGen, CMake and Python (in most of cases). Each language or tool here has some functionalities and convenience we want to leverage. There is nothing wrong choosing the most popular and upstream-supported solution, but having alternative ways to build MLIR-based projects is still valuable or at least worth trying.
Elixir could actually be a good fit as a MLIR front end. Elixir has SSA, pattern-matching, pipe-operator. We can use these language features to define MLIR patterns and pass pipeline in a natural and uniformed way. Elixir is strong-typed but not static-typed which makes it a great choice for quickly building prototypes to validate and explore new ideas.
To build a piece of IR in Beaver:
```elixir
Func.func some_func(function_type: Type.function([], [Type.i(32)])) do
region do
block _() do
v0 = Arith.constant(value: Attribute.integer(Type.i(32), 0)) >>> Type.i(32)
cond0 = Arith.constant(true) >>> Type.i(1)
CF.cond_br(cond0, Beaver.Env.block(bb1), {Beaver.Env.block(bb2), [v0]}) >>> []
end
block bb1() do
v1 = Arith.constant(value: Attribute.integer(Type.i(32), 0)) >>> Type.i(32)
_add = Arith.addi(v0, v0) >>> Type.i(32)
CF.br({Beaver.Env.block(bb2), [v1]}) >>> []
end
block bb2(arg >>> Type.i(32)) do
v2 = Arith.constant(value: Attribute.integer(Type.i(32), 0)) >>> Type.i(32)
add = Arith.addi(arg, v2) >>> Type.i(32)
Func.return(add) >>> []
end
end
end
```
And a small example to showcase what it is like to define and run a pass in Beaver (with some monad magic):
```elixir
alias Beaver.MLIR.Dialect.Func
defmodule ToyPass do
use Beaver.MLIR.Pass, on: "func.func"
defpat replace_add_op() do
a = value()
b = value()
res = type()
{op, _t} = TOSA.add(a, b) >>> {:op, [res]}
rewrite op do
{r, _} = TOSA.sub(a, b) >>> {:op, [res]}
replace(op, with: r)
end
end
def run(%MLIR.Operation{} = operation) do
with "func.func" <- Beaver.MLIR.Operation.name(operation),
attributes <- Beaver.Walker.attributes(operation),
2 <- Enum.count(attributes),
{:ok, _} <- MLIR.Pattern.apply_(operation, [replace_add_op(benefit: 2)]) do
:ok
end
end
end
~m"""
module {
func.func @tosa_add(%arg0: tensor<1x3xf32>, %arg1: tensor<2x1xf32>) -> tensor<2x3xf32> {
%0 = "tosa.add"(%arg0, %arg1) : (tensor<1x3xf32>, tensor<2x1xf32>) -> tensor<2x3xf32>
return %0 : tensor<2x3xf32>
}
}
""".(ctx)
|> MLIR.Pass.Composer.nested("func.func", [
ToyPass.create()
])
|> canonicalize
|> MLIR.Pass.Composer.run!()
```
## Goals
- Powered by Elixir's composable modularity and meta-programming features, provide a simple, intuitive, and extensible interface for MLIR.
- Edit-Build-Test-Debug Loop at seconds. Everything in Elixir and Zig are compiled in parallel.
- Compile Elixir to native/WASM/GPU with the help from MLIR.
- Revisit and reincarnate symbolic AI in the HW-accelerated world. Erlang/Elixir has [a Prolog root](https://www.erlang.org/blog/beam-compiler-history/#the-prolog-interpreter)!
- Introduce a new stack to machine learning.
- Higher-level: Elixir
- Representation: MLIR
- Lower-level: Zig
## Why is it called Beaver?
Beaver is an umbrella species increase biodiversity. We hope this project could enable other compilers and applications in the way a beaver pond becomes the habitat of many other creatures. Many Elixir projects also use animal names as their package names and it is often about raising awareness of endangered species. To read more about why beavers are important to our planet, check out [this National Geographic article](https://www.nationalgeographic.com/animals/article/beavers-climate-change-conservation-news).
## Quick introduction
Beaver is essentially LLVM/MLIR on Erlang/Elixir. It is kind of interesting to see a crossover of two well established communities and four sub-communities. Here are some brief information about each of them.
### For Erlang/Elixir forks
- Explain this MLIR thing to me in one sentence
MLIR could be regarded as the XML for compilers and an MLIR dialect acts like HTTP standard which gives the generic format real-world semantics and functionalities.
- Check out [the home page](https://mlir.llvm.org/) of MLIR.
### For LLVM/MLIR forks
- What's so good about this programming language Elixir?
- It gets compiled to Erlang and runs on BEAM (Erlang's VM). So it has all the fault-tolerance and concurrency features of Erlang.
- As a Lisp, Elixir has all the good stuff of a Lisp-y language including hygienic macro, protocol-based polymorphism.
- Elixir has a powerful [module system](https://elixir-lang.org/getting-started/module-attributes.html) to persist compile-time data and this allows library users to easily adjust runtime behavior.
- Minimum, very few keywords. Most of the language is built with itself.
<!-- TODO: some rephrase -->
- Check out [the official guide](https://elixir-lang.org/getting-started/introduction.html) of Elixir.
## Getting started
- Tutorial: [Your first compiler with Beaver!](https://hexdocs.pm/beaver/your-first-beaver-compiler.html)
<!-- TODO: single .exs example -->
### Installation
The package can be installed
by adding `beaver` to your list of dependencies in `mix.exs`:
```elixir
def deps do
[
{:beaver, "~> 0.3.6"}
]
end
```
Add this to your `.formatter.exs` will have the formatter properly transform the macros introduced by `beaver`
```elixir
import_deps: [:beaver],
```
## Erlang apps related to the Beaver
LLVM/MLIR is a giant project, and built around that Beaver have thousands of functions. To properly ship LLVM/MLIR and streamline the development process, we need to carefully break the functionalities at different level into different Erlang apps under the same umbrella.
- `:beaver`: Elixir and C/C++ hybrid.
- Top level app ships the high level functionalities including IR generation and pattern definition.
- MLIR CAPI wrappers built by parsing LLVM/MLIR CAPI C headers and some middle level helper functions to hide the C pointer related operations. This app will add the loaded MLIR C library and managed MLIR context to Erlang supervisor tree. Rust is also used in this app, but mainly for LLVM/MLIR CMake integration.
- All the Ops defined in stock MLIR dialects, built by querying the registry. This app will ship MLIR Ops with Erlang idiomatic practices like behavior compliance.
- `:kinda`: Elixir and Zig hybrid, generating NIFs from MLIR C headers. Repo: https://github.com/beaver-lodge/kinda
- `:manx`: Pure Elixir, compiler backend for [Nx](https://github.com/elixir-nx/nx/tree/main/nx#readme).
### Notes on consuming and development
- Only `:beaver` and `:kinda` are designed to be used as stand-alone app being directly consumed by other apps.
- `:manx` could only work with Nx.
- Although `:kinda` is built for Beaver, any Erlang/Elixir app with interest bundling some C API could take advantage of it as well.
- The namespace `Beaver.MLIR` is for standard features are generally expected in any MLIR tools.
- The namespace `Beaver` is for concepts and practice only exists in Beaver, which are mostly in a DSL provided as a set of macros (including `mlir/0`, `block/1`, `defpat/2`, etc). The implementations are usually under `Beaver.DSL` namespace.
- In Beaver, there is no strict requirements on the consistency between the Erlang app name and Elixir module name. Two modules with same namespace prefix could locate in different Erlang apps (this happens a lot to the `Beaver.MLIR` namespace). Of course redefinition of Elixir modules with an identical name should be avoided.
## How it works?
To implement a MLIR toolkit, we at least need these group of APIs:
- IR API, to create and update Ops and blocks in the IR
- Pass API, to create and run passes
- Pattern API, in which you declare the transformation of a specific structure of Ops
We implement the IR API and Pass API with the help of the [MLIR C API](https://mlir.llvm.org/docs/CAPI/). There are both lower level APIs generated from the C headers and higher level APIs that are more idiomatic in Elixir.
The Pattern API is implemented with the help from the [PDL dialect](https://mlir.llvm.org/docs/Dialects/PDLOps/). We are using the lower level IR APIs to compile your Elixir code to PDL. Another way to look at this is that Elixir/Erlang pattern matching is serving as a frontend alternative to [PDLL](https://mlir.llvm.org/docs/PDLL/).
## Design principles
### Transformation over builder
It is very common to use builder pattern to construct IR, especially in an OO programming language like C++/Python.
One problem this approach has is that the compiler code looks very different from the code it is generating.
Because Erlang/Elixir is SSA by its nature, in Beaver a MLIR Op's creation is very declarative and its container will transform it with the correct contextual information. By doing this, we could:
- Keep compiler code's structure as close as possible to the generated code, with less noise and more readability.
- Allow dialects of different targets and semantic to introduce different DSL. For instance, CPU, SIMD, GPU could all have their specialized transformation tailored for their own unique concepts.
One example:
```elixir
module do
v2 = Arith.constant(1) >>> ~t<i32>
end
# module/1 is a macro, it will transformed the SSA `v2= Arith.constant..` to:
v2 =
%Beaver.SSA{}
|> Beaver.SSA.put_arguments(value: ~a{1})
|> Beaver.SSA.put_block(Beaver.Env.block())
|> Beaver.SSA.put_ctx(Beaver.Env.context())
|> Beaver.SSA.put_results(~t<i32>)
|> Arith.constant()
```
Also, using the declarative way to construct IR, proper dominance and operand reference is formed naturally.
<!-- TODO: use real code here -->
```elixir
SomeDialect.some_op do
region do
block entry() do
x = Arith.constant(1) >>> ~t<i32>
y = Arith.constant(1) >>> ~t<i32>
end
end
region do
block entry() do
z = Arith.addi(x, y) >>> ~t<i32>
end
end
end
# will be transformed to:
SomeDialect.some_op(
regions: fn -> do
region = Beaver.Env.region() # first region created
block = Beaver.Env.block()
x = Arith.constant(...)
y = Arith.constant(...)
region = Beaver.Env.region() # second region created
block = Beaver.Env.block()
z = Arith.addi([x, y, ...]) # x and y dominate z
end
)
```
### Beaver DSL as higher level AST for MLIR
There should be a 1:1 mapping between Beaver SSA DSL to MLIR SSA. It is possible to do a roundtrip parsing MLIR text format and dump it to Beaver DSL which is Elixir AST essentially. This makes it possible to easily debug a piece of IR in a more programmable and readable way.
In Beaver, working with MLIR should be in one format, no matter it is generating, transforming, debugging.
### High level API in Erlang/Elixir idiom
When possible, lower level C APIs should be wrapped as Elixir struct with support to common Elixir protocols.
For instance the iteration over one MLIR operation's operands, results, successors, attributes, regions should be implemented in Elixir's Enumerable protocol.
This enable the possibility to use the rich collection of functions in Elixir standard libraries and Hex packages.
## Is Beaver a compiler or binding to LLVM/MLIR?
Elixir is a programming language built for all purposes. There are multiple sub-ecosystems in the general Erlang/Elixir ecosystem.
Each sub-ecosystem appears distinct/unrelated to each other, but they actually complement each other in the real world production.
To name a few:
- [Phoenix Framework](https://phoenixframework.org/) for web application and realtime message
- [Nerves Project](https://www.nerves-project.org/) for embedded device and IoT
- [Nx](https://github.com/elixir-nx/nx) for tensor and numerical
Each of these sub-ecosystems starts with a seed project/library. Beaver should evolve to become a sub-ecosystem for compilers built with Elixir and MLIR.
## MLIR context management
When calling higher-level APIs, it is ideal not to have MLIR context passing around everywhere.
If no MLIR context provided, an attribute and type getter should return an anonymous function with MLIR context as argument.
In Erlang, all values are copied, so it is very safe to pass around these anonymous functions.
When creating an operation, these functions will be called with the MLIR context in an operation state.
With this approach we achieve both succinctness and modularity, not having a global MLIR context.
Usually a function accepting a MLIR context to create an operation or type is called a "creator" in Beaver.
## Development
1. Install Elixir, https://elixir-lang.org/install.html
2. Install Zig, https://ziglang.org/learn/getting-started/#installing-zig
3. Install LLVM/MLIR
- Option 1: Install with pip
```bash
python3 -m pip install -r dev-requirements.txt
export LLVM_CONFIG_PATH=$(python3 -c 'import mlir;print(mlir.__path__[0])')/bin/llvm-config
```
- Option 2: Build from source https://mlir.llvm.org/getting_started/
Recommended install commands:
```bash
cmake -B build -S llvm -G Ninja -DLLVM_ENABLE_PROJECTS=mlir \
-DLLVM_TARGETS_TO_BUILD="host" \
-DCMAKE_C_COMPILER_LAUNCHER=ccache -DCMAKE_CXX_COMPILER_LAUNCHER=ccache \
-DLLVM_ENABLE_ASSERTIONS=ON \
-DLLVM_ENABLE_OCAMLDOC=OFF \
-DLLVM_ENABLE_BINDINGS=OFF \
-DCMAKE_BUILD_TYPE=RelWithDebInfo \
-DCMAKE_INSTALL_PREFIX=${HOME}/llvm-install
cmake --build build -t install
export LLVM_CONFIG_PATH=$HOME/llvm-install/bin/llvm-config
```
(Optional) To use Vulkan:
- Install Vulkan SDK (global installation is required), reference: https://vulkan.lunarg.com/sdk/home
- Setting environment variable by adding commands these to your bash/zsh profile:
```
# you might need to change the version here
cd $HOME/VulkanSDK/1.3.216.0/
source setup-env.sh
cd -
```
- Use `vulkaninfo` and `vkvia` to verify Vulkan is working
- Add `-DMLIR_ENABLE_VULKAN_RUNNER=ON` in LLVM CMake config command
4. Run tests
- Clone the repo
- Make sure LLVM environment variable is set properly, otherwise it might fail to build
```bash
echo $LLVM_CONFIG_PATH
```
- Build and run Elixir tests
```bash
mix deps.get
BEAVER_BUILD_CMAKE=1 mix test
# run tests with filters
mix test --exclude vulkan # use this to skip vulkan tests
mix test --only smoke
mix test --only nx
```
5. debug
- setting environment variable to control Erlang scheduler number, `ERL_AFLAGS="+S 10:5"`
- run mix test under LLDB, `scripts/lldb-mix-test`
6. Livebook
- Please use Elixir 1.14 and install Livebook from source on GitHub:
```bash
mix escript.install github livebook-dev/livebook
```
- To use Beaver in [Livebook](https://livebook.dev/), run this in the source directory:
```bash
livebook server --name livebook@127.0.0.1 --home .
```
- In the setup cell, replace the content with:
```elixir
beaver_app_root = Path.join(__DIR__, "..")
Mix.install(
[
{:beaver, path: beaver_app_root, env: :test}
],
config_path: Path.join(beaver_app_root, "config/config.exs"),
lockfile: Path.join(beaver_app_root, "mix.lock")
)
```
## Release a new version
### Update Elixir source
- Bump versions in [`README.md`](README.md) and [`mix.exs`](/mix.exs)
### Linux
- Run CI, which generates the new GitHub release uploaded to https://github.com/beaver-lodge/beaver-prebuilt/releases.
- Update release url in [`mix.exs`](/mix.exs)
### Mac
- Run macOS build with:
```bash
rm -rf _build/prod
bash scripts/build-for-publish.sh
```
- Upload the `beaver-nif-[xxx].tar.gz` file to release
### Generate `checksum.exs`
```
rm checksum.exs
mix clean
mix
mix elixir_make.checksum --all --ignore-unavailable --print
```
Check the version in the output is correct.
### Publish to Hex
```
BEAVER_BUILD_CMAKE=1 mix hex.publish
```
## (Optional) Format CMake files
```bash
python3 -m pip install cmake-format
cmake-format -i native/**/CMakeLists.txt native/**/*.cmake
```