# Torch-MLIR Lazy Tensor Core Backend ## Table of Contents - [Introduction](#introduction) - [Examples](#examples) - [Code Structure](#code-structure) - [Architecture](#architecture) - [Implementing a custom backend](#implementing-a-custom-backend) - [Future Expansion](#future-expansion) ## Introduction [Lazy Tensor Core](https://github.com/pytorch/pytorch/blob/master/torch/csrc/lazy/tutorial.md) is a tracing system in PyTorch which is supported as an entry point to Torch-MLIR. After registering an LTC backend, all operations performed on lazy tensors are recorded and handed off to the backend implementation. LTC support is provided through an abstract [`TorchMlirBackendImpl`](../python/torch_mlir/csrc/base_lazy_backend/backend_impl.h) class, which handles the conversion to MLIR. Implementations based on this abstract class will be able to specify their own compile and execution workflows. Additional details about how to implement a custom backend is available [below](#Implementing-a-custom-backend). ## Examples View examples [here](ltc_examples.md). ## Code Structure ### Autogen Build Tools ([`build_tools`](../build_tools)) - `autogen_ltc_backend.{py,yaml}` - The [autogen files](#autogen-files) are generated by this script based on the list of supported ops, which includes all ops from [`GeneratedTorchOps.td`](https://github.com/llvm/torch-mlir/blob/main/include/torch-mlir/Dialect/Torch/IR/GeneratedTorchOps.td), excluding those explicitly blacklisted in the YAML file ### Autogen Files ([`python/torch_mlir/csrc/base_lazy_backend/generated`](../python/torch_mlir/csrc/base_lazy_backend/generated)) Generated files are created in this directory, which is ignored by version control. - `LazyIr.h` - Definitions of `torch::lazy:TorchMlirNode` subclasses for each supported autogen op - `LazyNativeFunctions.{cpp,h}` - Native function definitions for each supported op (handles `at::Tensor -> at::Tensor` data flow and creation of `torch::lazy:TorchMlirNode`) - `LazyNonNativeIr.h` - Non-native `torch::lazy:TorchMlirNode` subclasses - `RegisterLazy.cpp` - Registers PyTorch kernels under the `lazy` dispatch key for all supported ops, which map to our native functions - `shape_inference.{cpp,h}` - Shape inference headers for supported ops and autogen'd placeholders for unimplemented functions ### Base Backend ([`python/torch_mlir/csrc/base_lazy_backend`](../python/torch_mlir/csrc/base_lazy_backend)) - `backend_impl.{cpp,h}` - Base LTC backend to setup Torch-MLIR lowering context - `dynamic_ir.{cpp,h}` - Manually implemented "dynamic" nodes - `ir_builder.h` - Torch-MLIR implementation of `torch::lazy::IrBuilder` - `mlir_lowering_context.h` - Handles conversion from `torch::lazy::Node` to MLIR via JIT and Torch-MLIR infrastructure - `mlir_native_functions.cpp` - Manually implemented native functions - `mlir_node.{cpp,h}` - Torch-MLIR implementation of `torch::lazy::Node` - `mlir_node_lowering.{cpp,h}` - Lower a `torch::lazy::Node` to JIT graph in preparation for MLIR generation - `shape_inference.cpp` - Implementation of select shape inference functions (most functions are [implemented upstream](https://github.com/pytorch/pytorch/blob/master/torch/csrc/lazy/core/shape_inference.cpp)) ### Reference Backend ([`python/torch_mlir/csrc/reference_lazy_backend`](../python/torch_mlir/csrc/reference_lazy_backend)) - `backend_impl.{cpp,h}` - Reference Torch-MLIR LTC backend implementation, which simply stores the MLIR as a string and executes computation on CPU - `reference_lazy_backend_pybind.cpp` - pybind for reference Torch-MLIR LTC backend ### Examples ([`examples`](../examples)) - `ltc_backend_bert.py` - Example HuggingFace BERT model traced by LTC to MLIR - `ltc_backend_mnist.py` - Example MNIST model traced by LTC to MLIR ## Architecture ### Tracing LTC graph The journey begins with a tensor in PyTorch on the `lazy` device, which may undergo a number of operations during its lifetime. ```python >>> lazy_backend._initialize() >>> x = torch.tensor(..., device='lazy') >>> y = torch.tanh(x) ... ``` The call to `torch.tanh` triggers a chain of events. PyTorch checks the dispatch table under the `lazy` key and finds the kernel for `tanh` previously registered in `RegisterLazy.cpp`. Next, `LazyNativeFunctions::tanh` from `LazyNativeFunctions.cpp` is called, which triggers the creation of a `Tanh` node, which is a subclass of `TorchMlirNode` and `torch::lazy::Node`, defined in `LazyIr.h`. These nodes are then tracked internally by LTC as the computation graph is traced out. ![Tracing Tensors](ltc_images/tracing_tensors.jpg) ### Syncing Tensors At some point, the tensors will be synced in order to execute the computation -- either explicitly via `mark_step`, or implicitly through some operation that requires the contents of the tensors (e.g. printing to console). ```python >>> torch._lazy.mark_step() ``` This triggers a call to `LazyGraphExecutor::SyncLiveTensorsGraph` somewhere in the guts of LTC, which collects all the `TorchMlirNode`s (technically `torch::lazy::Node`s at this point) from the current trace and creates an instance of `TorchMlirLoweringContext`. Here, the `TorchMlirNode`s are lowered to JIT via `mlir_node_lowering.cpp` and inserted into a `jit::Graph`. Next, `TorchMlirLoweringContext::Build` is executed and the final `jit::Graph` is sent to `torch_mlir::importJitFunctionAsFuncOp` to generate MLIR using the existing infrastructure from Torch-MLIR. At this point, a `TorchMlirComputation` is created containing the final `mlir::FuncOp`. ![Syncing Tensors](ltc_images/syncing_tensors.jpg) ### Final Compilation and Execution The `TorchMlirComputation` is sent to the vendor specific implementation of `TorchMlirBackendImpl::Compile` to be handed off to the vendor's compilation stack (if applicable). Finally, the compiled computation is sent to `TorchMlirBackendImpl::ExecuteComputation` to be executed on the vendor device, which produces some results to be send back to PyTorch. ![Vendor Execution](ltc_images/vendor_execution.jpg) ## Implementing a custom backend A reference implementation of a custom backend is available [here](../python/torch_mlir/csrc/reference_lazy_backend/). All the work involved with generating MLIR is handled in the base LTC backend, so vendors only need to worry about implementing `Compile`, `ExecuteComputation`, and some other minor methods to interface with the device. A pybind is needed to invoke C++ code to register the autogen PyTorch kernels and the custom backend itself. Most of the code in the reference implementation should be reusable, excluding some debug related function (e.g. `get_latest_computation`). ## Future Expansion There are a number of areas for future improvement: - Generate source information in `jit::Graph` so it can be embedded in the MLIR - Currently the reference backend implementation executes via the `jit::Graph` instead of the MLIR since we currently lack lowerings for many ops, which would make it difficult to run models such as HF BERT - In the future, we should change the implementation to lower the MLIR to linalg and execute on a reference backend - As new models get tested, we will inevitably run into errors related to unimplemented shape inference functions. This problem is simply solved by implementing the missing function, or adding a structured kernel to PyTorch.