mlir-hlo/lib/Dialect/mhlo/transforms/CMakeLists.txt

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CMake
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#
# Copyright 2020 The TensorFlow Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# https://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
#
include_directories(BEFORE
${CMAKE_CURRENT_BINARY_DIR}
${CMAKE_CURRENT_SOURCE_DIR})
set(LLVM_TARGET_DEFINITIONS lower_complex_patterns.td)
mlir_tablegen(generated_lower_complex.inc -gen-rewriters)
add_public_tablegen_target(MLIRMhloLowerComplexIncGen)
set(LLVM_TARGET_DEFINITIONS legalize_to_standard_patterns.td)
mlir_tablegen(generated_legalize_to_standard.inc -gen-rewriters)
add_public_tablegen_target(MLIRMhloLegalizeToStandardIncGen)
set(LLVM_TARGET_DEFINITIONS chlo_legalize_to_hlo_patterns.td)
mlir_tablegen(generated_chlo_legalize_to_hlo.inc -gen-rewriters)
add_public_tablegen_target(MLIRChloLegalizeToHloIncGen)
add_mlir_library(ChloPasses
chlo_legalize_to_hlo.cc
chlo_legalize_to_hlo_pass.cc
DEPENDS
MLIRhlo_opsIncGen
MLIRChloLegalizeToHloIncGen
LINK_COMPONENTS
Core
LINK_LIBS PUBLIC
ChloDialect
MLIRIR
MLIRPass
)
add_mlir_library(MhloPasses
broadcast_propagation.cc
legalize_gather_to_torch_index_select.cc
legalize_trigonometric_to_approximation.cc
lower_complex.cc
lower_complex_patterns.td
lower_general_dot.cc
materialize_broadcasts.cc
materialize_broadcasts_pass.cc
mhlo_fusion.cc
optimize_mhlo.cc
optimize_mhlo_pass.cc
rank_specialization.cc
sink_constants_to_control_flow.cc
test_infer_shaped_type_pass.cc
unfuse_batch_norm.cc
unfuse_batch_norm_pass.cc
DEPENDS
MLIRDiscRalPassIncGen
MLIRhlo_opsIncGen
MLIRMhloLowerComplexIncGen
MLIRMhloPassIncGen
LINK_COMPONENTS
Core
LINK_LIBS PUBLIC
MLIRIR
MLIRMhloUtils
MLIRPass
MLIRTransformUtils
)
add_mlir_library(MhloToLhloConversion
hlo_legalize_to_lhlo.cc
DEPENDS
MLIRhlo_opsIncGen
MLIRlhlo_opsIncGen
LINK_COMPONENTS
Core
LINK_LIBS PUBLIC
MhloDialect
LmhloDialect
MLIRIR
MLIRPass
MLIRMath
)
add_mlir_library(MhloToStandard
legalize_control_flow.cc
legalize_to_standard.cc
mhlo_control_flow_to_scf.cc
DEPENDS
MLIRhlo_opsIncGen
MLIRlhlo_opsIncGen
MLIRMhloLegalizeToStandardIncGen
LINK_COMPONENTS
Core
LINK_LIBS PUBLIC
MLIRIR
MLIRPass
MLIRTensor
)
add_mlir_library(MhloLhloToLinalg
legalize_to_linalg.cc
DEPENDS
MLIRhlo_opsIncGen
MLIRlhlo_opsIncGen
LINK_COMPONENTS
Core
LINK_LIBS PUBLIC
MhloDialect
MLIRComplex
MLIRIR
MLIRPass
)
add_mlir_library(LmhloPasses
fusion_utils.cc
legalize_tensor_load_op.cc
lhlo_fuse_linalg.cc
lhlo_fusion.cc
lhlo_legalize_to_affine.cc
lhlo_legalize_to_gpu.cc
lhlo_legalize_to_parallel_loops.cc
DEPENDS
MLIRlhlo_opsIncGen
LINK_COMPONENTS
Core
LINK_LIBS PUBLIC
LmhloDialect
MLIRIR
MLIRPass
)
PR #50191: [MLIR][DISC] Add RAL (Runtime abstraction layer) Dialect Imported from GitHub PR https://github.com/tensorflow/tensorflow/pull/50191 DISC is a e2e flow, including both compiler side and runtime side. For runtime side, we have different targeting environments (e.g. tensorflow, pytorch, or sometimes even a standalone binary). In order to simplify the design of the compiler side, we design a Runtime Abstraction Layer (RAL) to sperate the compiler side and runtime side. Thus the compiler side only need to target RAL itself and it is the responsibility of RAL to handle the differences between different targeting environments. One of the most important functions of RAL is to manage stateful resources. To this end, it provides a context object, and hides all stateful operations behind this context, thus the compiler side itself doesn't need to care about the resource initialization. For example, a kernel must be loaded before it can be launched on GPU. However, the loading operation should only be taken once during the whole lifetime of the context in order to achieve the best performance. Based on the initialization-free interfaces provided by RAL, compiler side can focus on its core optimization logic and lets the RAL to manage the resource status. The context mentioned above is passed as a parameter to the entry function and all RAL APIs should always use the context as their first argument. This CR also provides a pass to help to ensure this property. The pass rewrites the entry function to make sure their first argument is the context. For entry function, the pass also rewrites its inputs and outputs. To be concrete, all the original inputs and outputs of the entry function are received from and sent to RAL through a sequence of RAL API calls correspondingly. The motivation behind this is to hide the implementation details of I/Os. This design may also potentially enable partial execution of the compiled module when some of the inputs are ready. Copybara import of the project: -- c4f20a89aed71181e75bcc5265723b88bde23240 by Wenyi Zhao <reyizero@gmail.com>: [MLIR][DISC] Add RAL (Runtime abstraction layer) Dialect DISC is a e2e flow, including both compiler side and runtime side. For runtime side, we have different targeting environments (e.g. tensorflow, pytorch, or sometimes even a standalone binary). In order to simplify the design of the compiler side, we design a Runtime Abstraction Layer (RAL) to sperate the compiler side and runtime side. Thus the compiler side only need to target RAL itself and it is the responsibility of RAL to handle the differences between different targeting environments. One of the most important functions of RAL is to manage stateful resources. To this end, it provides a context object, and hides all stateful operations behind this context, thus the compiler side itself doesn't need to care about the resource initialization. For example, a kernel must be loaded before it can be launched on GPU. However, the loading operation should only be taken once during the whole lifetime of the context in order to achieve the best performance. Based on the initialization-free interfaces provided by RAL, compiler side can focus on its core optimization logic and lets the RAL to manage the resource status. The context mentioned above is passed as a parameter to the entry function and all RAL APIs should always use the context as their first argument. This CR also provides a pass to help to ensure this property. The pass rewrites the entry function to make sure their first argument is the context. For entry function, the pass also rewrites its inputs and outputs. To be concrete, all the original inputs and outputs of the entry function are received from and sent to RAL through a sequence of RAL API calls correspondingly. The motivation behind this is to hide the implementation details of I/Os. This design may also potentially enable partial execution of the compiled module when some of the inputs are ready. -- 1991d4f80ab6087943956e1c0fec4940a22ab08d by Wenyi Zhao <reyizero@gmail.com>: fix PiperOrigin-RevId: 379317586
2021-06-15 02:26:41 +08:00
add_mlir_library(DiscRalPasses
ral_inject_execution_context.cc
DEPENDS
MLIRdisc_ral_opsIncGen
MLIRDiscRalPassIncGen
LINK_COMPONENTS
Core
LINK_LIBS PUBLIC
DiscRalDialect
MLIRIR
MLIRPass
)
add_library(AllMhloPasses INTERFACE)
target_link_libraries(AllMhloPasses INTERFACE
ChloPasses
PR #50191: [MLIR][DISC] Add RAL (Runtime abstraction layer) Dialect Imported from GitHub PR https://github.com/tensorflow/tensorflow/pull/50191 DISC is a e2e flow, including both compiler side and runtime side. For runtime side, we have different targeting environments (e.g. tensorflow, pytorch, or sometimes even a standalone binary). In order to simplify the design of the compiler side, we design a Runtime Abstraction Layer (RAL) to sperate the compiler side and runtime side. Thus the compiler side only need to target RAL itself and it is the responsibility of RAL to handle the differences between different targeting environments. One of the most important functions of RAL is to manage stateful resources. To this end, it provides a context object, and hides all stateful operations behind this context, thus the compiler side itself doesn't need to care about the resource initialization. For example, a kernel must be loaded before it can be launched on GPU. However, the loading operation should only be taken once during the whole lifetime of the context in order to achieve the best performance. Based on the initialization-free interfaces provided by RAL, compiler side can focus on its core optimization logic and lets the RAL to manage the resource status. The context mentioned above is passed as a parameter to the entry function and all RAL APIs should always use the context as their first argument. This CR also provides a pass to help to ensure this property. The pass rewrites the entry function to make sure their first argument is the context. For entry function, the pass also rewrites its inputs and outputs. To be concrete, all the original inputs and outputs of the entry function are received from and sent to RAL through a sequence of RAL API calls correspondingly. The motivation behind this is to hide the implementation details of I/Os. This design may also potentially enable partial execution of the compiled module when some of the inputs are ready. Copybara import of the project: -- c4f20a89aed71181e75bcc5265723b88bde23240 by Wenyi Zhao <reyizero@gmail.com>: [MLIR][DISC] Add RAL (Runtime abstraction layer) Dialect DISC is a e2e flow, including both compiler side and runtime side. For runtime side, we have different targeting environments (e.g. tensorflow, pytorch, or sometimes even a standalone binary). In order to simplify the design of the compiler side, we design a Runtime Abstraction Layer (RAL) to sperate the compiler side and runtime side. Thus the compiler side only need to target RAL itself and it is the responsibility of RAL to handle the differences between different targeting environments. One of the most important functions of RAL is to manage stateful resources. To this end, it provides a context object, and hides all stateful operations behind this context, thus the compiler side itself doesn't need to care about the resource initialization. For example, a kernel must be loaded before it can be launched on GPU. However, the loading operation should only be taken once during the whole lifetime of the context in order to achieve the best performance. Based on the initialization-free interfaces provided by RAL, compiler side can focus on its core optimization logic and lets the RAL to manage the resource status. The context mentioned above is passed as a parameter to the entry function and all RAL APIs should always use the context as their first argument. This CR also provides a pass to help to ensure this property. The pass rewrites the entry function to make sure their first argument is the context. For entry function, the pass also rewrites its inputs and outputs. To be concrete, all the original inputs and outputs of the entry function are received from and sent to RAL through a sequence of RAL API calls correspondingly. The motivation behind this is to hide the implementation details of I/Os. This design may also potentially enable partial execution of the compiled module when some of the inputs are ready. -- 1991d4f80ab6087943956e1c0fec4940a22ab08d by Wenyi Zhao <reyizero@gmail.com>: fix PiperOrigin-RevId: 379317586
2021-06-15 02:26:41 +08:00
DiscRalPasses
MhloPasses
MhloToLhloConversion
MhloToStandard
MhloLhloToLinalg
LmhloPasses
)