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llvm/mlir/test/python/python_test_ops.td

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[mlir] Make attributes mutable in Python bindings Attributes represent additional data about an operation and are intended to be modifiable during the lifetime of the operation. In the dialect-specific Python bindings, attributes are exposed as properties on the operation class. Allow for assigning values to these properties. Also support creating new and deleting existing attributes through the generic "attributes" property of an operation. Any validity checking must be performed by the op verifier after the mutation, similarly to C++. Operations are not invalidated in the process: no dangling pointers can be created as all attributes are owned by the context and will remain live even if they are not used in any operation. Introduce a Python Test dialect by analogy with the Test dialect and to avoid polluting the latter with Python-specific constructs. Use this dialect to implement a test for the attribute access and mutation API. Reviewed By: stellaraccident, mehdi_amini Differential Revision: https://reviews.llvm.org/D91652
2020-11-17 18:28:16 +01:00
//===-- python_test_ops.td - Python test Op definitions ----*- tablegen -*-===//
//
// 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
//
//===----------------------------------------------------------------------===//
#ifndef PYTHON_TEST_OPS
#define PYTHON_TEST_OPS
[mlir] Split out AttrDef/TypeDef and pattern constructs from OpBase.td OpBase.td has formed into a huge monolith of all ODS constructs. This commits starts to rectify that by splitting out some constructs to their own .td files. Differential Revision: https://reviews.llvm.org/D118636
2022-01-27 21:58:31 -08:00
include "mlir/IR/AttrTypeBase.td"
[mlir] Make attributes mutable in Python bindings Attributes represent additional data about an operation and are intended to be modifiable during the lifetime of the operation. In the dialect-specific Python bindings, attributes are exposed as properties on the operation class. Allow for assigning values to these properties. Also support creating new and deleting existing attributes through the generic "attributes" property of an operation. Any validity checking must be performed by the op verifier after the mutation, similarly to C++. Operations are not invalidated in the process: no dangling pointers can be created as all attributes are owned by the context and will remain live even if they are not used in any operation. Introduce a Python Test dialect by analogy with the Test dialect and to avoid polluting the latter with Python-specific constructs. Use this dialect to implement a test for the attribute access and mutation API. Reviewed By: stellaraccident, mehdi_amini Differential Revision: https://reviews.llvm.org/D91652
2020-11-17 18:28:16 +01:00
include "mlir/IR/OpBase.td"
[mlir] support interfaces in Python bindings Introduce the initial support for operation interfaces in C API and Python bindings. Interfaces are a key component of MLIR's extensibility and should be available in bindings to make use of full potential of MLIR. This initial implementation exposes InferTypeOpInterface all the way to the Python bindings since it can be later used to simplify the operation construction methods by inferring their return types instead of requiring the user to do so. The general infrastructure for binding interfaces is defined and InferTypeOpInterface can be used as an example for binding other interfaces. Reviewed By: gysit Differential Revision: https://reviews.llvm.org/D111656
2021-10-14 17:18:28 +02:00
include "mlir/Interfaces/InferTypeOpInterface.td"
[mlir] Make attributes mutable in Python bindings Attributes represent additional data about an operation and are intended to be modifiable during the lifetime of the operation. In the dialect-specific Python bindings, attributes are exposed as properties on the operation class. Allow for assigning values to these properties. Also support creating new and deleting existing attributes through the generic "attributes" property of an operation. Any validity checking must be performed by the op verifier after the mutation, similarly to C++. Operations are not invalidated in the process: no dangling pointers can be created as all attributes are owned by the context and will remain live even if they are not used in any operation. Introduce a Python Test dialect by analogy with the Test dialect and to avoid polluting the latter with Python-specific constructs. Use this dialect to implement a test for the attribute access and mutation API. Reviewed By: stellaraccident, mehdi_amini Differential Revision: https://reviews.llvm.org/D91652
2020-11-17 18:28:16 +01:00
def Python_Test_Dialect : Dialect {
let name = "python_test";
[mlir] support interfaces in Python bindings Introduce the initial support for operation interfaces in C API and Python bindings. Interfaces are a key component of MLIR's extensibility and should be available in bindings to make use of full potential of MLIR. This initial implementation exposes InferTypeOpInterface all the way to the Python bindings since it can be later used to simplify the operation construction methods by inferring their return types instead of requiring the user to do so. The general infrastructure for binding interfaces is defined and InferTypeOpInterface can be used as an example for binding other interfaces. Reviewed By: gysit Differential Revision: https://reviews.llvm.org/D111656
2021-10-14 17:18:28 +02:00
let cppNamespace = "python_test";
[mlir][ods] Simplify useDefaultType/AttributePrinterParser The current behaviour of `useDefaultTypePrinterParser` and `useDefaultAttributePrinterParser` is that they are set by default, but the dialect generator only generates the declarations for the parsing and printing hooks if it sees dialect types and attributes. Same goes for the definitions generated by the AttrOrTypeDef generator. This can lead to confusing and undesirable behaviour if the dialect generator doesn't see the definitions of the attributes and types, for example, if they are sensibly separated into different files: `Dialect.td`, `Ops.td`, `Attributes.td`, and `Types.td`. Now, these bits are unset by default. Setting them will always result in the dialect generator emitting the declarations for the parsing hooks. And if the AttrOrTypeDef generator sees it set, it will generate the default implementations. Reviewed By: rriddle, stellaraccident Differential Revision: https://reviews.llvm.org/D125809
2022-05-17 18:26:00 +00:00
let useDefaultTypePrinterParser = 1;
let useDefaultAttributePrinterParser = 1;
[mlir] Make attributes mutable in Python bindings Attributes represent additional data about an operation and are intended to be modifiable during the lifetime of the operation. In the dialect-specific Python bindings, attributes are exposed as properties on the operation class. Allow for assigning values to these properties. Also support creating new and deleting existing attributes through the generic "attributes" property of an operation. Any validity checking must be performed by the op verifier after the mutation, similarly to C++. Operations are not invalidated in the process: no dangling pointers can be created as all attributes are owned by the context and will remain live even if they are not used in any operation. Introduce a Python Test dialect by analogy with the Test dialect and to avoid polluting the latter with Python-specific constructs. Use this dialect to implement a test for the attribute access and mutation API. Reviewed By: stellaraccident, mehdi_amini Differential Revision: https://reviews.llvm.org/D91652
2020-11-17 18:28:16 +01:00
}
[mlir] Rework subclass construction in PybindAdaptors.h The constructor function was being defined without indicating its "__init__" name, which made it interpret it as a regular fuction rather than a constructor. When overload resolution failed, Pybind would attempt to print the arguments actually passed to the function, including "self", which is not initialized since the constructor couldn't be called. This would result in "__repr__" being called with "self" referencing an uninitialized MLIR C API object, which in turn would cause undefined behavior when attempting to print in C++. Even if the correct name is provided, the mechanism used by PybindAdaptors.h to bind constructors directly as "__init__" functions taking "self" is deprecated by Pybind. The new mechanism does not seem to have access to a fully-constructed "self" object (i.e., the constructor in C++ takes a `pybind11::detail::value_and_holder` that cannot be forwarded back to Python). Instead, redefine "__new__" to perform the required checks (there are no additional initialization needed for attributes and types as they are all wrappers around a C++ pointer). "__new__" can call its equivalent on a superclass without needing "self". Bump pybind11 dependency to 3.8.0, which is the first version that allows one to redefine "__new__". Reviewed By: stellaraccident Differential Revision: https://reviews.llvm.org/D117646
2022-01-19 12:21:42 +01:00
class TestType<string name, string typeMnemonic>
: TypeDef<Python_Test_Dialect, name> {
let mnemonic = typeMnemonic;
}
class TestAttr<string name, string attrMnemonic>
: AttrDef<Python_Test_Dialect, name> {
let mnemonic = attrMnemonic;
}
Remove OpTrait, AttrTrait and TypeTrait - Remove the `{Op,Attr,Type}Trait` TableGen classes and replace with `Trait` - Rename `OpTraitList` to `TraitList` and use it in a few places The bulk of this change is a mechanical s/OpTrait/Trait/ throughout the codebase. Reviewed By: rriddle, jpienaar, herhut Differential Revision: https://reviews.llvm.org/D118543
2022-01-29 14:30:57 -08:00
class TestOp<string mnemonic, list<Trait> traits = []>
[mlir] Make attributes mutable in Python bindings Attributes represent additional data about an operation and are intended to be modifiable during the lifetime of the operation. In the dialect-specific Python bindings, attributes are exposed as properties on the operation class. Allow for assigning values to these properties. Also support creating new and deleting existing attributes through the generic "attributes" property of an operation. Any validity checking must be performed by the op verifier after the mutation, similarly to C++. Operations are not invalidated in the process: no dangling pointers can be created as all attributes are owned by the context and will remain live even if they are not used in any operation. Introduce a Python Test dialect by analogy with the Test dialect and to avoid polluting the latter with Python-specific constructs. Use this dialect to implement a test for the attribute access and mutation API. Reviewed By: stellaraccident, mehdi_amini Differential Revision: https://reviews.llvm.org/D91652
2020-11-17 18:28:16 +01:00
: Op<Python_Test_Dialect, mnemonic, traits>;
[mlir] Rework subclass construction in PybindAdaptors.h The constructor function was being defined without indicating its "__init__" name, which made it interpret it as a regular fuction rather than a constructor. When overload resolution failed, Pybind would attempt to print the arguments actually passed to the function, including "self", which is not initialized since the constructor couldn't be called. This would result in "__repr__" being called with "self" referencing an uninitialized MLIR C API object, which in turn would cause undefined behavior when attempting to print in C++. Even if the correct name is provided, the mechanism used by PybindAdaptors.h to bind constructors directly as "__init__" functions taking "self" is deprecated by Pybind. The new mechanism does not seem to have access to a fully-constructed "self" object (i.e., the constructor in C++ takes a `pybind11::detail::value_and_holder` that cannot be forwarded back to Python). Instead, redefine "__new__" to perform the required checks (there are no additional initialization needed for attributes and types as they are all wrappers around a C++ pointer). "__new__" can call its equivalent on a superclass without needing "self". Bump pybind11 dependency to 3.8.0, which is the first version that allows one to redefine "__new__". Reviewed By: stellaraccident Differential Revision: https://reviews.llvm.org/D117646
2022-01-19 12:21:42 +01:00
//===----------------------------------------------------------------------===//
// Type definitions.
//===----------------------------------------------------------------------===//
def TestType : TestType<"TestType", "test_type">;
//===----------------------------------------------------------------------===//
// Attribute definitions.
//===----------------------------------------------------------------------===//
def TestAttr : TestAttr<"TestAttr", "test_attr">;
//===----------------------------------------------------------------------===//
// Operation definitions.
//===----------------------------------------------------------------------===//
[mlir] Make attributes mutable in Python bindings Attributes represent additional data about an operation and are intended to be modifiable during the lifetime of the operation. In the dialect-specific Python bindings, attributes are exposed as properties on the operation class. Allow for assigning values to these properties. Also support creating new and deleting existing attributes through the generic "attributes" property of an operation. Any validity checking must be performed by the op verifier after the mutation, similarly to C++. Operations are not invalidated in the process: no dangling pointers can be created as all attributes are owned by the context and will remain live even if they are not used in any operation. Introduce a Python Test dialect by analogy with the Test dialect and to avoid polluting the latter with Python-specific constructs. Use this dialect to implement a test for the attribute access and mutation API. Reviewed By: stellaraccident, mehdi_amini Differential Revision: https://reviews.llvm.org/D91652
2020-11-17 18:28:16 +01:00
def AttributedOp : TestOp<"attributed_op"> {
let arguments = (ins I32Attr:$mandatory_i32,
OptionalAttr<I32Attr>:$optional_i32,
UnitAttr:$unit);
}
[MLIR][python bindings] Add more basic AttrBuilder for _ops_gen.py files Add more attribute builders, such as "F32Attr", "F64Attr" and "F64ArrayAttr", which are useful to create operations by python bindings. For example, tosa.clamp in _tosa_ops_gen.py need 'F32Attr'. Reviewed By: ftynse Differential Revision: https://reviews.llvm.org/D150757
2023-05-22 18:35:33 +02:00
def AttributesOp : TestOp<"attributes_op"> {
let arguments = (ins BoolAttr:$x_bool,
I16Attr: $x_i16,
I32Attr: $x_i32,
I64Attr: $x_i64,
SI16Attr: $x_si16,
SI32Attr: $x_si32,
F32Attr: $x_f32,
F64Attr: $x_f64,
StrAttr: $x_str,
I32ArrayAttr: $x_i32_array,
I64ArrayAttr: $x_i64_array,
F32ArrayAttr: $x_f32_array,
F64ArrayAttr: $x_f64_array,
DenseI64ArrayAttr: $x_i64_dense);
}
[MLIR] [Python ODS] Use @builtins.property for cases where 'property' is already defined In cases where an operation has an argument or result named 'property', the ODS-generated python fails on import because the `@property` resolves to the `property` operation argument instead of the builtin `@property` decorator. We should always use the fully qualified decorator name. Reviewed By: mikeurbach Differential Revision: https://reviews.llvm.org/D106106
2021-07-15 19:03:48 -07:00
def PropertyOp : TestOp<"property_op"> {
let arguments = (ins I32Attr:$property,
I32:$idx);
}
[mlir] support interfaces in Python bindings Introduce the initial support for operation interfaces in C API and Python bindings. Interfaces are a key component of MLIR's extensibility and should be available in bindings to make use of full potential of MLIR. This initial implementation exposes InferTypeOpInterface all the way to the Python bindings since it can be later used to simplify the operation construction methods by inferring their return types instead of requiring the user to do so. The general infrastructure for binding interfaces is defined and InferTypeOpInterface can be used as an example for binding other interfaces. Reviewed By: gysit Differential Revision: https://reviews.llvm.org/D111656
2021-10-14 17:18:28 +02:00
def DummyOp : TestOp<"dummy_op"> {
}
def InferResultsOp : TestOp<"infer_results_op", [InferTypeOpInterface]> {
let arguments = (ins);
let results = (outs AnyInteger:$single, AnyInteger:$doubled);
let extraClassDeclaration = [{
static ::mlir::LogicalResult inferReturnTypes(
mlir/tblgen: use std::optional in generation This is part of an effort to migrate from llvm::Optional to std::optional. This patch changes the way mlir-tblgen generates .inc files, and modifies tests and documentation appropriately. It is a "no compromises" patch, and doesn't leave the user with an unpleasant mix of llvm::Optional and std::optional. A non-trivial change has been made to ControlFlowInterfaces to split one constructor into two, relating to a build failure on Windows. See also: https://discourse.llvm.org/t/deprecating-llvm-optional-x-hasvalue-getvalue-getvalueor/63716 Signed-off-by: Ramkumar Ramachandra <r@artagnon.com> Differential Revision: https://reviews.llvm.org/D138934
2022-12-14 11:39:19 +01:00
::mlir::MLIRContext *context, ::std::optional<::mlir::Location> location,
[mlir] support interfaces in Python bindings Introduce the initial support for operation interfaces in C API and Python bindings. Interfaces are a key component of MLIR's extensibility and should be available in bindings to make use of full potential of MLIR. This initial implementation exposes InferTypeOpInterface all the way to the Python bindings since it can be later used to simplify the operation construction methods by inferring their return types instead of requiring the user to do so. The general infrastructure for binding interfaces is defined and InferTypeOpInterface can be used as an example for binding other interfaces. Reviewed By: gysit Differential Revision: https://reviews.llvm.org/D111656
2021-10-14 17:18:28 +02:00
::mlir::ValueRange operands, ::mlir::DictionaryAttr attributes,
Introduce MLIR Op Properties This new features enabled to dedicate custom storage inline within operations. This storage can be used as an alternative to attributes to store data that is specific to an operation. Attribute can also be stored inside the properties storage if desired, but any kind of data can be present as well. This offers a way to store and mutate data without uniquing in the Context like Attribute. See the OpPropertiesTest.cpp for an example where a struct with a std::vector<> is attached to an operation and mutated in-place: struct TestProperties { int a = -1; float b = -1.; std::vector<int64_t> array = {-33}; }; More complex scheme (including reference-counting) are also possible. The only constraint to enable storing a C++ object as "properties" on an operation is to implement three functions: - convert from the candidate object to an Attribute - convert from the Attribute to the candidate object - hash the object Optional the parsing and printing can also be customized with 2 extra functions. A new options is introduced to ODS to allow dialects to specify: let usePropertiesForAttributes = 1; When set to true, the inherent attributes for all the ops in this dialect will be using properties instead of being stored alongside discardable attributes. The TestDialect showcases this feature. Another change is that we introduce new APIs on the Operation class to access separately the inherent attributes from the discardable ones. We envision deprecating and removing the `getAttr()`, `getAttrsDictionary()`, and other similar method which don't make the distinction explicit, leading to an entirely separate namespace for discardable attributes. Recommit d572cd1b067f after fixing python bindings build. Differential Revision: https://reviews.llvm.org/D141742
2023-02-26 10:46:01 -05:00
::mlir::OpaqueProperties,
[mlir] support interfaces in Python bindings Introduce the initial support for operation interfaces in C API and Python bindings. Interfaces are a key component of MLIR's extensibility and should be available in bindings to make use of full potential of MLIR. This initial implementation exposes InferTypeOpInterface all the way to the Python bindings since it can be later used to simplify the operation construction methods by inferring their return types instead of requiring the user to do so. The general infrastructure for binding interfaces is defined and InferTypeOpInterface can be used as an example for binding other interfaces. Reviewed By: gysit Differential Revision: https://reviews.llvm.org/D111656
2021-10-14 17:18:28 +02:00
::mlir::RegionRange regions,
::llvm::SmallVectorImpl<::mlir::Type> &inferredReturnTypes) {
::mlir::Builder b(context);
inferredReturnTypes.push_back(b.getI32Type());
inferredReturnTypes.push_back(b.getI64Type());
return ::mlir::success();
}
}];
}
[MLIR][python bindings] Fix inferReturnTypes + AttrSizedOperandSegments for optional operands Right now `inferTypeOpInterface.inferReturnTypes` fails because there's a cast in there to `py::sequence` which throws a `TypeError` when it tries to cast the `None`s. Note `None`s are inserted into `operands` for omitted operands passed to the generated builder: ``` operands.append(_get_op_result_or_value(start) if start is not None else None) operands.append(_get_op_result_or_value(stop) if stop is not None else None) operands.append(_get_op_result_or_value(step) if step is not None else None) ``` Note also that skipping appending to the list operands doesn't work either because [[ https://github.com/llvm/llvm-project/blob/27c37327da67020f938aabf0f6405f57d688441e/mlir/lib/Bindings/Python/IRCore.cpp#L1585 | build generic ]] checks against the number of operand segments expected. Currently the only way around is to handroll through `ir.Operation.create`. Reviewed By: rkayaith Differential Revision: https://reviews.llvm.org/D151409
2023-05-26 14:39:03 -05:00
def I32OrF32 : TypeConstraint<Or<[I32.predicate, F32.predicate]>,
"i32 or f32">;
def InferResultsVariadicInputsOp : TestOp<"infer_results_variadic_inputs_op",
[InferTypeOpInterface, AttrSizedOperandSegments]> {
let arguments = (ins Optional<I64>:$single, Optional<I64>:$doubled);
let results = (outs I32OrF32:$res);
let extraClassDeclaration = [{
static ::mlir::LogicalResult inferReturnTypes(
::mlir::MLIRContext *context, ::std::optional<::mlir::Location> location,
::mlir::ValueRange operands, ::mlir::DictionaryAttr attributes,
::mlir::OpaqueProperties,
::mlir::RegionRange regions,
::llvm::SmallVectorImpl<::mlir::Type> &inferredReturnTypes) {
::mlir::Builder b(context);
if (operands.size() == 1)
inferredReturnTypes.push_back(b.getI32Type());
else if (operands.size() == 2)
inferredReturnTypes.push_back(b.getF32Type());
return ::mlir::success();
}
}];
}
[mlir][python] Infer result types in generated constructors whenever possible In several cases, operation result types can be unambiguously inferred from operands and attributes at operation construction time. Stop requiring the user to provide these types as arguments in the ODS-generated constructors in Python bindings. In particular, handle the SameOperandAndResultTypes and FirstAttrDerivedResultType traits as well as InferTypeOpInterface using the recently added interface support. This is a significant usability improvement for IR construction, similar to what C++ ODS provides. Depends On D111656 Reviewed By: gysit Differential Revision: https://reviews.llvm.org/D111811
2021-10-14 17:19:06 +02:00
// If all result types are buildable, the InferTypeOpInterface is implied and is
// autogenerated by C++ ODS.
def InferResultsImpliedOp : TestOp<"infer_results_implied_op"> {
let results = (outs I32:$integer, F64:$flt, Index:$index);
}
[MLIR] Add InferShapedTypeOpInterface bindings Add C and python bindings for InferShapedTypeOpInterface and ShapedTypeComponents. This allows users to invoke InferShapedTypeOpInterface for ops that implement it. Reviewed By: ftynse Differential Revision: https://reviews.llvm.org/D149494
2023-05-11 14:29:16 -05:00
def InferShapedTypeComponentsOp : TestOp<"infer_shaped_type_components_op",
[DeclareOpInterfaceMethods<InferShapedTypeOpInterface,
["inferReturnTypeComponents"]>]> {
let arguments = (ins AnyTensor:$operand);
let results = (outs AnyTensor:$result);
let extraClassDefinition = [{
::mlir::LogicalResult $cppClass::inferReturnTypeComponents(
::mlir::MLIRContext *context, ::std::optional<::mlir::Location> location,
::mlir::ValueShapeRange operands, ::mlir::DictionaryAttr attributes,
::mlir::OpaqueProperties properties, ::mlir::RegionRange regions,
::llvm::SmallVectorImpl<
::mlir::ShapedTypeComponents>& inferredShapedTypeComponents) {
$cppClass::Adaptor adaptor(operands, attributes, properties, regions);
auto operandType =
[mlir] Update cast/isa method calls to function calls This updates the rest (at implementation) of MLIR's use of cast/isa method calls where function calls are possible and automatic refactoring is not. These changes occured in .td files or in macros. Context: - https://mlir.llvm.org/deprecation/ at "Use the free function variants for dyn_cast/cast/isa/…" - Original discussion at https://discourse.llvm.org/t/preferred-casting-style-going-forward/68443
2023-05-25 16:35:45 +02:00
::llvm::cast<::mlir::ShapedType>(adaptor.getOperand().getType());
[MLIR] Add InferShapedTypeOpInterface bindings Add C and python bindings for InferShapedTypeOpInterface and ShapedTypeComponents. This allows users to invoke InferShapedTypeOpInterface for ops that implement it. Reviewed By: ftynse Differential Revision: https://reviews.llvm.org/D149494
2023-05-11 14:29:16 -05:00
if (operandType.hasRank()) {
inferredShapedTypeComponents.emplace_back(operandType.getShape(),
operandType.getElementType());
} else {
inferredShapedTypeComponents.emplace_back(operandType.getElementType());
}
return ::mlir::success();
}
}];
}
[mlir][python] Infer result types in generated constructors whenever possible In several cases, operation result types can be unambiguously inferred from operands and attributes at operation construction time. Stop requiring the user to provide these types as arguments in the ODS-generated constructors in Python bindings. In particular, handle the SameOperandAndResultTypes and FirstAttrDerivedResultType traits as well as InferTypeOpInterface using the recently added interface support. This is a significant usability improvement for IR construction, similar to what C++ ODS provides. Depends On D111656 Reviewed By: gysit Differential Revision: https://reviews.llvm.org/D111811
2021-10-14 17:19:06 +02:00
def SameOperandAndResultTypeOp : TestOp<"same_operand_and_result_type_op",
[SameOperandsAndResultType]> {
let arguments = (ins Variadic<AnyType>);
let results = (outs AnyType:$one, AnyType:$two);
}
def FirstAttrDeriveTypeAttrOp : TestOp<"first_attr_derive_type_attr_op",
[FirstAttrDerivedResultType]> {
let arguments = (ins AnyType:$input, TypeAttr:$type);
let results = (outs AnyType:$one, AnyType:$two);
}
def FirstAttrDeriveAttrOp : TestOp<"first_attr_derive_attr_op",
[FirstAttrDerivedResultType]> {
let arguments = (ins AnyAttr:$iattr);
let results = (outs AnyType:$one, AnyType:$two, AnyType:$three);
}
[mlir][Python] Fix generation of accessors for Optional Previously, in case there was only one `Optional` operand/result within the list, we would always return `None` from the accessor, e.g., for a single optional result we would generate: ``` return self.operation.results[0] if len(self.operation.results) > 1 else None ``` But what we really want is to return `None` only if the length of `results` is smaller than the total number of element groups (i.e., the optional operand/result is in fact missing). This commit also renames a few local variables in the generator to make the distinction between `isVariadic()` and `isVariableLength()` a bit more clear. Reviewed By: ftynse Differential Revision: https://reviews.llvm.org/D113855
2021-11-18 09:41:57 +01:00
def OptionalOperandOp : TestOp<"optional_operand_op"> {
let arguments = (ins Optional<AnyType>:$input);
let results = (outs I32:$result);
}
[mlir] Make attributes mutable in Python bindings Attributes represent additional data about an operation and are intended to be modifiable during the lifetime of the operation. In the dialect-specific Python bindings, attributes are exposed as properties on the operation class. Allow for assigning values to these properties. Also support creating new and deleting existing attributes through the generic "attributes" property of an operation. Any validity checking must be performed by the op verifier after the mutation, similarly to C++. Operations are not invalidated in the process: no dangling pointers can be created as all attributes are owned by the context and will remain live even if they are not used in any operation. Introduce a Python Test dialect by analogy with the Test dialect and to avoid polluting the latter with Python-specific constructs. Use this dialect to implement a test for the attribute access and mutation API. Reviewed By: stellaraccident, mehdi_amini Differential Revision: https://reviews.llvm.org/D91652
2020-11-17 18:28:16 +01:00
#endif // PYTHON_TEST_OPS
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