torch-mlir/e2e_testing/torchscript/elementwise.py

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# Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
# See https://llvm.org/LICENSE.txt for license information.
# SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
# Also available under a BSD-style license. See LICENSE.
Generalize support for elementwise ops. We plumb through e2e a fair number of interesting cases: - unary, binary, ternary elementwise ops - ops like `torch.aten.add.Tensor` that also take a scalar parameter - static size-1 broadcasting We allow the static size-1 broadcasting case, but emit a runtime error in the case of dynamic size-1 broadcasting. This seems like a sweet spot subset of things that can be lowered directly to linalg, while not being overly constraining to users. This is consistent with what IREE is doing for CHLO->Linalg lowering as well ([code](https://github.com/google/iree/blob/50bf7a87e465d2048c527bc27724edde40519b7e/iree/compiler/InputConversion/MHLO/BroadcastingToLinalgPatterns.cpp#L1)). To test the static size-1 case, we added support for the `torch.aten.unsqueeze` op and lowering for it through `linalg.tensor_expand_shape`. This involved a generalization of `MaximizeValueSemantics` able to handle it (the solution there also works for `torch.aten.flatten.using_ints` which we need for ResNet anyway) Also, a few minor additional changes: - Add `VerifyInvariantsBeforeBackendLowering` pass, which catches a large class of errors before we get to backend lowering (now that we are doing dialect conversion, the errors are way nicer if we just emit them up front rather than in the guts of a random pattern). - Minor change to RefBackend to allow `linalg.tensor_expand_shape`. Recommended review order: - e2e tests in elementwise.py - `ConvertElementwiseOp` in TorchToLinalg.cpp + elementwise.mlir test - `ConvertAtenUnsqueezeOp` in TorchToLinalg.cpp + unsqueeze.mlir test - RefineTypes.cpp + tests - MaximizeValueSemantics changes + test - VerifyInvariantsBeforeBackendLowering pass + test
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import torch
from torch_mlir_e2e_test.torchscript.framework import TestUtils
from torch_mlir_e2e_test.torchscript.registry import register_test_case
from torch_mlir_e2e_test.torchscript.annotations import annotate_args, export
Generalize support for elementwise ops. We plumb through e2e a fair number of interesting cases: - unary, binary, ternary elementwise ops - ops like `torch.aten.add.Tensor` that also take a scalar parameter - static size-1 broadcasting We allow the static size-1 broadcasting case, but emit a runtime error in the case of dynamic size-1 broadcasting. This seems like a sweet spot subset of things that can be lowered directly to linalg, while not being overly constraining to users. This is consistent with what IREE is doing for CHLO->Linalg lowering as well ([code](https://github.com/google/iree/blob/50bf7a87e465d2048c527bc27724edde40519b7e/iree/compiler/InputConversion/MHLO/BroadcastingToLinalgPatterns.cpp#L1)). To test the static size-1 case, we added support for the `torch.aten.unsqueeze` op and lowering for it through `linalg.tensor_expand_shape`. This involved a generalization of `MaximizeValueSemantics` able to handle it (the solution there also works for `torch.aten.flatten.using_ints` which we need for ResNet anyway) Also, a few minor additional changes: - Add `VerifyInvariantsBeforeBackendLowering` pass, which catches a large class of errors before we get to backend lowering (now that we are doing dialect conversion, the errors are way nicer if we just emit them up front rather than in the guts of a random pattern). - Minor change to RefBackend to allow `linalg.tensor_expand_shape`. Recommended review order: - e2e tests in elementwise.py - `ConvertElementwiseOp` in TorchToLinalg.cpp + elementwise.mlir test - `ConvertAtenUnsqueezeOp` in TorchToLinalg.cpp + unsqueeze.mlir test - RefineTypes.cpp + tests - MaximizeValueSemantics changes + test - VerifyInvariantsBeforeBackendLowering pass + test
2021-06-26 08:25:09 +08:00
# TODO: Support scalar !torch.int/!torch.float variants. Add support to
# ReduceOpVariants to implement them in terms of the tensor-only variants +
# torch.prim.NumToTensor.
# TODO: This is pretty verbose. Can we have a helper to reduce
# the boilerplate?
# ==============================================================================
class ElementwiseUnaryModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, a):
return torch.tanh(a)
@register_test_case(module_factory=lambda: ElementwiseUnaryModule())
def ElementwiseUnaryModule_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 4))
# ==============================================================================
class ElementwiseBinaryModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
([-1], torch.float32, True),
])
def forward(self, a, b):
return a * b
@register_test_case(module_factory=lambda: ElementwiseBinaryModule())
def ElementwiseBinaryModule_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 4), tu.rand(4))
# ==============================================================================
class ElementwiseTernaryModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1, -1], torch.float32, True),
([-1, -1], torch.float32, True),
([-1], torch.float32, True),
])
def forward(self, a, b, c):
return torch.lerp(a, b, c)
@register_test_case(module_factory=lambda: ElementwiseTernaryModule())
def ElementwiseTernaryModule_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 4, 5), tu.rand(4, 5), tu.rand(5))
# ==============================================================================
# Addition is an interesting special case of a binary op, because under the hood
# it carries a third scalar "alpha" parameter, which needs special handling.
class ElementwiseAddModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1], torch.float32, True),
([], torch.float32, True),
])
def forward(self, a, b):
return a + b
@register_test_case(module_factory=lambda: ElementwiseAddModule())
def ElementwiseAddModule_basic(module, tu: TestUtils):
module.forward(tu.rand(4), tu.rand())
# ==============================================================================
class ElementwiseUnsqueezeBroadcastModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1], torch.float32, True),
([], torch.float32, True),
])
def forward(self, a, b):
return a * b.unsqueeze(0)
@register_test_case(
module_factory=lambda: ElementwiseUnsqueezeBroadcastModule())
def ElementwiseUnsqueezeBroadcastModule_basic(module, tu: TestUtils):
module.forward(tu.rand(4), tu.rand())
# ==============================================================================
class ElementwiseUnsqueezeNegDimsModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, a):
# As mentioned in `unsqueeze` docstring,
# valid dim values are [-input.dim()-1, input.dim()+1).
# This tests the lower bound
return torch.unsqueeze(a, -3)
@register_test_case(
module_factory=lambda: ElementwiseUnsqueezeNegDimsModule())
def ElementwiseUnsqueezeNegDimsModule_basic(module, tu: TestUtils):
module.forward(tu.rand(4, 3))
# ==============================================================================
class ElementwiseFlattenBroadcastModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1], torch.float32, True),
([], torch.float32, True),
])
def forward(self, a, b):
return a * b.flatten(-1, -1)
@register_test_case(module_factory=lambda: ElementwiseFlattenBroadcastModule())
def ElementwiseFlattenBroadcastModule_basic(module, tu: TestUtils):
module.forward(tu.rand(6), tu.rand())
# ==============================================================================
Generalize support for elementwise ops. We plumb through e2e a fair number of interesting cases: - unary, binary, ternary elementwise ops - ops like `torch.aten.add.Tensor` that also take a scalar parameter - static size-1 broadcasting We allow the static size-1 broadcasting case, but emit a runtime error in the case of dynamic size-1 broadcasting. This seems like a sweet spot subset of things that can be lowered directly to linalg, while not being overly constraining to users. This is consistent with what IREE is doing for CHLO->Linalg lowering as well ([code](https://github.com/google/iree/blob/50bf7a87e465d2048c527bc27724edde40519b7e/iree/compiler/InputConversion/MHLO/BroadcastingToLinalgPatterns.cpp#L1)). To test the static size-1 case, we added support for the `torch.aten.unsqueeze` op and lowering for it through `linalg.tensor_expand_shape`. This involved a generalization of `MaximizeValueSemantics` able to handle it (the solution there also works for `torch.aten.flatten.using_ints` which we need for ResNet anyway) Also, a few minor additional changes: - Add `VerifyInvariantsBeforeBackendLowering` pass, which catches a large class of errors before we get to backend lowering (now that we are doing dialect conversion, the errors are way nicer if we just emit them up front rather than in the guts of a random pattern). - Minor change to RefBackend to allow `linalg.tensor_expand_shape`. Recommended review order: - e2e tests in elementwise.py - `ConvertElementwiseOp` in TorchToLinalg.cpp + elementwise.mlir test - `ConvertAtenUnsqueezeOp` in TorchToLinalg.cpp + unsqueeze.mlir test - RefineTypes.cpp + tests - MaximizeValueSemantics changes + test - VerifyInvariantsBeforeBackendLowering pass + test
2021-06-26 08:25:09 +08:00
class ElementwiseReluModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, x):
return torch.relu(x)
@register_test_case(module_factory=lambda: ElementwiseReluModule())
def ElementwiseReluModule_basic(module, tu: TestUtils):
module.forward(tu.rand(4, 2) - 0.5)
# ==============================================================================
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class ElementwiseLeakyReluModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, x):
return torch.ops.aten.leaky_relu(x, negative_slope=0.1)
@register_test_case(module_factory=lambda: ElementwiseLeakyReluModule())
def ElementwiseLeakyReluModule_basic(module, tu: TestUtils):
module.forward(tu.rand(4, 2) - 0.5)
# ==============================================================================
class ElementwiseGeluModule(torch.nn.Module):
def __init__(self):
super().__init__()
self.gelu = torch.nn.GELU()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, x):
return self.gelu(x)
@register_test_case(module_factory=lambda: ElementwiseGeluModule())
def ElementwiseGeluModule_basic(module, tu: TestUtils):
module.forward(2*tu.rand(5, 3) - 0.5)
# ==============================================================================
class ElementwiseSigmoidModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, x):
return torch.sigmoid(x)
@register_test_case(module_factory=lambda: ElementwiseSigmoidModule())
def ElementwiseSigmoidModule_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 5))
# ==============================================================================
class ElementwiseMinimumModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
([-1, -1], torch.float32, True),
])
def forward(self, x, y):
return torch.minimum(x, y)
@register_test_case(module_factory=lambda: ElementwiseMinimumModule())
def ElementwiseMinimumModule_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 5), tu.rand(3, 5))
module.forward(tu.nans(3, 5), tu.rand(3, 5))
# ==============================================================================
class ElementwiseMaximumModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
([-1, -1], torch.float32, True),
])
def forward(self, x, y):
return torch.maximum(x, y)
@register_test_case(module_factory=lambda: ElementwiseMaximumModule())
def ElementwiseMaximumModule_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 5), tu.rand(3, 5))
module.forward(tu.nans(3, 5), tu.rand(3, 5))
# ==============================================================================
class ElementwiseClampModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, x):
# TODO: It would be great to return all of these, so they get checked
# individually, but RefBackend doesn't support multiple returns.
# Instead, multiply them together, which has some chance of propagating
# all the values.
float_min = torch.clamp(x, min=-2.0)
int_min = torch.clamp(x, min=-3)
float_max = torch.clamp(x, max=2.0)
int_max = torch.clamp(x, max=3)
both = torch.clamp(x, min=-5, max=5)
return float_min * int_min * float_max * int_max * both
@register_test_case(module_factory=lambda: ElementwiseClampModule())
def ElementwiseClampModule_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 5, low=-10, high=10))
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# ==============================================================================
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class RsubModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, x):
return torch.rsub(x, 3.0, alpha=1.0)
@register_test_case(module_factory=lambda: RsubModule())
def RsubModule_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 4))
class RsubModule_noalpha(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, x):
return torch.rsub(x, 2.0)
@register_test_case(module_factory=lambda: RsubModule_noalpha())
def RsubModule_noalpha_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 4))
# ==============================================================================
class ElementwiseMulScalarModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, x):
return torch.mul(x, 100.0)
@register_test_case(module_factory=lambda: ElementwiseMulScalarModule())
def ElementwiseMulScalarModule_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 4))
# ==============================================================================
class ElementwiseLogModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, a):
return torch.log(a)
@register_test_case(module_factory=lambda: ElementwiseLogModule())
def ElementwiseLogModule_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 4))
class ElementwiseSqrtModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, a):
return torch.sqrt(a)
@register_test_case(module_factory=lambda: ElementwiseSqrtModule())
def ElementwiseSqrtModule_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 4))
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class ElementwiseFloorModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, a):
return torch.floor(a)
@register_test_case(module_factory=lambda: ElementwiseFloorModule())
def ElementwiseFloorModule_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 4))
class ElementwisePowModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, a):
return torch.pow(a, 2.0)
@register_test_case(module_factory=lambda: ElementwisePowModule())
def ElementwisePowModule_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 4))
# ==============================================================================
class ElementwiseToDtypeF32ToI64Module(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True)
])
def forward(self, x):
return x.to(torch.int64)
@register_test_case(module_factory=lambda: ElementwiseToDtypeF32ToI64Module())
def ElementwiseToDtypeF32ToI64Module_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 5))
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class ElementwiseLog2Module(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, a):
return torch.log2(a)
@register_test_case(module_factory=lambda: ElementwiseLog2Module())
def ElementwiseLog2Module_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 4))
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class ElementwiseRsqrtModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, a):
return torch.rsqrt(a)
@register_test_case(module_factory=lambda: ElementwiseRsqrtModule())
def ElementwiseRsqrtModule_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 4))
# ==============================================================================
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class ElementwiseAbsModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1, -1], torch.float32, True),
])
def forward(self, a):
return torch.abs(a)
@register_test_case(module_factory=lambda: ElementwiseAbsModule())
def ElementwiseAbsModule_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 4, 5, low=-1.0, high=1.0))
# ==============================================================================
class ElementwiseReciprocalModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1], torch.float32, True),
])
def forward(self, a):
return torch.reciprocal(a)
@register_test_case(module_factory=lambda: ElementwiseReciprocalModule())
def ElementwiseReciprocalModule_basic(module, tu: TestUtils):
module.forward(tu.rand(4))
# ==============================================================================
class ElementwiseDivScalarModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.float32, True),
])
def forward(self, x):
return torch.div(x, 10.0)
@register_test_case(module_factory=lambda: ElementwiseDivScalarModule())
def ElementwiseDivScalarModule_basic(module, tu: TestUtils):
module.forward(tu.rand(3, 4))
# ==============================================================================
class ElementwiseAndIntegerModule(torch.nn.Module):
def __init__(self):
super().__init__()
@export
@annotate_args([
None,
([-1, -1], torch.int32, True),
([-1, -1], torch.int64, True),
])
def forward(self, x, y):
return torch.bitwise_and(x, y)
@register_test_case(module_factory=lambda: ElementwiseAndIntegerModule())
def ElementwiseAndIntegerModule_basic(module, tu: TestUtils):
module.forward(torch.randint(-10, 10, (3, 4)).to(torch.int32),
torch.randint(-10, 10, (3, 4)))