234 lines
10 KiB
Markdown
234 lines
10 KiB
Markdown
# MLIR-HLO: A Standalone "HLO" MLIR-based Compiler
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The code here exists in two places:
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* https://github.com/tensorflow/tensorflow/tree/master/tensorflow/compiler/mlir/hlo;
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this is the canonical location and where contributions should be made using
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GitHub pull-requests.
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* https://github.com/tensorflow/mlir-hlo; this is a standalone repository with
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a view to the same code to allow other projects to use this without
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depending on the entire TF monorepo.
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This implements a self-contained compiler for a linear algebra set of operations
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inspired by XLA
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[HLO IR](https://www.tensorflow.org/xla/architecture#how_does_xla_work) using
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MLIR components. It is designed to provide an end-to-end flow independent of
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TensorFlow and XLA, but usable inside of these projects.
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Coding practice and conventions in this repository follow the
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[MLIR Developer Guide](https://mlir.llvm.org/getting_started/DeveloperGuide/) in
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this repo as part of the intent to act as an incubator for technology to
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upstream.
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## QuickStart: building and testing
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These instructions work on Linux, you may have to adjust for your plaform.
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To build the code in this repository, you need a clone of the LLVM/MLIR git
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repository:
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$ git clone https://github.com/llvm/llvm-project.git
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You need to make sure you have the right commit checked out in the LLVM
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repository (you need to do this every time you pull from this repo):
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$ (cd llvm-project && git checkout $(cat build_tools/llvm_version.txt))
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We provide a script to configure and build LLVM/MLIR:
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$ build_tools/build_mlir.sh ${PWD}/llvm-project/ ${PWD}/llvm-build
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Again this is something to do every time you pull from this repository and the
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LLVM revision changes.
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Finally you can build and test this repository:
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$ mkdir build && cd build
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$ cmake .. -GNinja \
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-DLLVM_ENABLE_LLD=ON \
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-DCMAKE_BUILD_TYPE=Release \
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-DLLVM_ENABLE_ASSERTIONS=On \
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-DMLIR_DIR=${PWD}/../llvm-build/lib/cmake/mlir
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$ ninja check-mlir-hlo
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## Overview
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MLIR-HLO aims to provide an end-to-end compiler for CPU and GPU, as well as
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building reusable blocks for other accelerators. This is heavily inspired by the
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success of XLA.
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[XLA](https://www.tensorflow.org/xla/) (Accelerated Linear Algebra) is a
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domain-specific compiler framework and execution environment for linear algebra,
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which powers code-generation for ML frameworks like TensorFlow, JAX, and others.
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A cornerstone of XLA is the HLO (High Level Optimizer) IR, which offers a
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carefully fixed selected list of operations, mostly orthogonal to each other. It
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provides an efficient optimizer for computations expressed with this set of
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operations and generate codes for hardware platforms like CPU, GPU, and TPUs.
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Its goal is to provide a uniform interface to compile and execute these
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optimized HLO programs independently of the targeted device. It is not a
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front-end ML system like TensorFlow or JAX, rather it is a backend framework
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that optimizes HLO and lowers to machine code.
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The HLO set of operations is closed and has well defined semantics. HLO
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operations operate on immutable Tensors with static shapes (actually bounded
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shapes to be exact) and explicit broadcasts.
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[MLIR](https://mlir.llvm.org/) is a compiler infrastructure which intends to
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come with "battery included", as such it intends to provide all the blocks
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required to assemble graph optimization and codegen pipelines. The longer term
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roadmap for MLIR is to provide a
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[Tensor Compute Primitive](https://llvm.discourse.group/c/mlir/MLIR-TCP-WG/36)
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(TCP) dialect, which should hopefully be general enough to model what HLO
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represents today (see
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[slides](https://drive.google.com/open?id=1iljcpTQ5NPaMfGpoPDFml1XkYxjK_6A4) and
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[recording](https://drive.google.com/open?id=1jSPa8TwPKUt0WuLquGc8OgSUVYJHMvWZ)
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for a technical discussion on this topic).
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The work on MLIR-HLO can be seen as a stepping stone towards building TCP, while
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integrating intermediate components into XLA itself by relying on the
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well-proven HLO IR and introducing more pieces from upstream MLIR
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([Linalg](https://mlir.llvm.org/docs/Dialects/Linalg/),
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[Vector](https://mlir.llvm.org/docs/Dialects/Vector/),
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[GPU](https://mlir.llvm.org/docs/Dialects/GPU/) dialect, ...).
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[This document](https://www.tensorflow.org/mlir/xla_gpu_codegen) provides more
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information on the current migration of the XLA GPU codegen.
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## MLIR Dialects for XLA-style compilation
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This repository defines three dialects to support a HLO-like compilation
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pipeline using MLIR:
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* `chlo`: the "client" HLO dialect, intended to be closer to the frontend
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(including implicit broadcast semantics).
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* `mhlo`: "meta"-HLO dialect ; similar to `xla_hlo`, but with extensions for
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dynamic shape support.
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* `lmhlo`: "late"-"meta"-HLO, it is the IR after buffer allocation is
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performed. In XLA the buffer allocation is a side-datastructure which keeps
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track of these informations, while this separate dialect materializes it in
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the IR.
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We describe these in more details below.
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### HLO Client Dialect: `chlo`.
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* It was originaly designed to map the
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[XLA client APIs](https://www.tensorflow.org/xla/operation_semantics) (e.g.,
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ops supports implicit broadcast and roughly modeled on XlaBuilder API)
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modulo support for dynamic shapes and additional ops required to support
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dynamic client side HLOs.
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* Ops can be from either the XlaBuilder or XLA helper functions can be
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converted into ops (e.g., given ambiguity in what constitutes these ops,
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there is some freedom to decide), the goal of this dialect is to correspond
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close to client level and enable a thin layer between client use and op
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construction (making it cheap to construct and optimizations on the dialect
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close to optimizations on the client ops).
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Entry:
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* The vast majority of old "client" interactions are via the XlaBuilder APIs.
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These APIs are used by TF2XLA kernels, JAX, PyTorch bridge and directly. The
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legalization path (described below) can also reuse the XlaBuilder's APIs to
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construct XLA Client HLO ops directly (this uses MlirXlaBuilder which is a
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subclass of XlaBuilder).
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* The other entry point is during legalization from TensorFlow ops in the TF
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Graph Compiler and other tools (e.g., SavedModel lowering and TFCompile).
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Exit:
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* MHLO
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* May be exported to xla::HloInstructionProto by invoking the XlaBuilder APIs
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(with regular XlaBuilder)
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The `chlo` dialect started originally as mapping to the XLA client Builder APIs.
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It enables it to both be constructed and converted back to existing XLA
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interfaces using the XlaBuilder API. Due to the way that translation into and
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out of the dialect works, there is no expectation that this dialect roundtrips
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to XLA (e.g., it is only intended to be translated to MLIR and then legalized to
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another dialect or translated to HloInstructionProto).
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The export approach of reusing the XlaBuilders enables reusing a lot of logic
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that was already implemented in terms of computing shapes, inserting broadcasts
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etc.
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An important topic here is that XLA Client HLO ops are not a well defined set.
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And in particular what some would consider helper functions, others would
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consider ops. It should be easy to move between these and so define a new op
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along with the helper function or autogenerate the helper functions from the
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descriptions of the ops. For the former, a simple approach would be to simply
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consider the context in which the op is being constructed and if an MLIR one,
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construct a op in the client dialect instead of further calls into XlaBuilder.
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The latter could be implemented by adding the op and a legalization of the op to
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other known ops, from which a helper function can get generated that could be
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used as regular.
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Status: Exists but need to be cleaned up.
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### Meta HLO Dialect `mhlo`
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* Dialect is closer to current HLO server ops (e.g., no implicit broadcast)
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* MHLO dialect where we can deviate from the requirements of the client or
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server dialect, in particular:
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* Control flow ops with implicit capture to enable simpler optimizations
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(e.g., generic LICM, unroll & jam, etc.)
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* Multiple results ops (e.g., no tuples)
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* More ops (for example, unique op or assert op), and ops that don't need
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to be added to either client or server dialect.
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* Op set not constrained by implementation (e.g., hlo.add operating on say
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i79 or !mydialect.weird_type is allowed even though no XLA backend
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supports it). Verification on types happening at the boundaries.
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* It does not need to preserve some deprecated XLA constructs (e.g.
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stateful RNG HLO).
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* More dynamic shape support ops without need for updating all
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users/backends.
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* This dialect enables evolving HLO independently from XLA in order to
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experiment with features we'd like to upstream in MLIR TCP. In particular it
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intends to be user-extensible through
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[interfaces](https://mlir.llvm.org/docs/Interfaces/).
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* It should have no TensorFlow, or proto, or other Google internal
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dependencies.
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* It need not be a complete superset of ops compared to XLA HLO dialect.
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Entry:
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* Legalization from `chlo` dialect or conversion from XLA HLO.
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* Directly emitted from TF Graph Compiler;
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* Builder call (e.g., EDSL);
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Exit:
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* LMHLO, Linalg IREE, directly used in codegen.
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* XLA HLO.
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The MHLO dialect has no direct export format, it is only meant as an
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intermediate optimization dialect/format. It is also where we can experiment
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cheaply with new ops. This format will be where the representation would differ
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from existing end points.
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Status: Exists but need to be cleaned up and evolved, in particular with respect
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to supporting dynamic shapes.
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### LMHLO
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LMHLO corresponds to late `mhlo` and operates on buffer domain (e.g., memref)
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with side-effecting operations. The lowering from `mhlo` dialect proceeds by way
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of scheduling, memory and buffer allocation. The current mapping is directly on
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XLA Client HLOs but without implicit broadcast and with operation on memrefs.
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This dialect will instead be rebased on `mhlo` dialect but operating on buffers
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still.
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Entry:
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* Post buffer assignment on `mhlo` dialect, or from XLA after buffer
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assignment.
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Exit:
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* Codegen (LLVM IR in the common cases at the moment)
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## End-to-End pipeline
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TODO
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