MLIR allows for a truly open operation ecosystem, as any dialect may define operations that suit a specific level of abstraction. Traits are a mechanism in which to abstract implementation details and properties that are common across many different operations. Traits may be used to specify special properties and constraints of the operation, including whether the operation has side effects or whether its output has the same type as the input. Some examples of traits are Commutative, SingleResult, Terminator, etc. See the more comprehensive list below for more examples of what is possible.
Traits may be defined in C++ by inheriting from the OpTrait::TraitBase<ConcreteType, TraitType> class. This base class takes as template parameters:
Curiously Recurring Template Pattern.A derived trait class is expected to take a single template that corresponds to the ConcreteType. An example trait definition is shown below:
template <typename ConcreteType> class MyTrait : public OpTrait::TraitBase<ConcreteType, MyTrait> { };
Derived traits may also provide a verifyTrait hook, that is called when verifying the concrete operation. The trait verifiers will currently always be invoked before the main Op::verify.
template <typename ConcreteType> class MyTrait : public OpTrait::TraitBase<ConcreteType, MyTrait> { public: /// Override the 'verifyTrait' hook to add additional verification on the /// concrete operation. static LogicalResult verifyTrait(Operation *op) { // ... } };
Note: It is generally good practice to define the implementation of the verifyTrait hook out-of-line as a free function when possible to avoid instantiating the implementation for every concrete operation type.
The above demonstrates the definition of a simple self-contained trait. It is also often useful to provide some static parameters to the trait to control its behavior. Given that the definition of the trait class is rigid, i.e. we must have a single template argument for the concrete operation, the templates for the parameters will need to be split out. An example is shown below:
template <int Parameter> class MyParametricTrait { public: template <typename ConcreteType> class Impl : public OpTrait::TraitBase<ConcreteType, Impl> { // Inside of 'Impl' we have full access to the template parameters // specified above. }; };
Traits may be used when defining a derived operation type, by simply adding the name of the trait class to the Op class after the concrete operation type:
/// Here we define 'MyOp' along with the 'MyTrait' and `MyParametric trait /// classes we defined previously. class MyOp : public Op<MyOp, MyTrait, MyParametricTrait<10>::Impl> {};
To use a trait in the ODS framework, we need to provide a definition of the trait class. This can be done using the NativeOpTrait and ParamNativeOpTrait classes. ParamNativeOpTrait provides a mechanism in which to specify arguments to a parametric trait class with an internal Impl.
// The argument is the c++ trait class name. def MyTrait : NativeOpTrait<"MyTrait">; // The first argument is the parent c++ class name. The second argument is a // string containing the parameter list. class MyParametricTrait<int prop> : NativeOpTrait<"MyParametricTrait", !cast<string>(!head(parameters))>;
These can then be used in the traits list of an op definition:
def OpWithInferTypeInterfaceOp : Op<...[MyTrait, MyParametricTrait<10>]> { ... }
See the documentation on operation definitions for more details.
Traits may be used to provide additional methods, static fields, or other information directly on the concrete operation. Traits internally become Base classes of the concrete operation, so all of these are directly accessible. To expose this information opaquely to transformations and analyses, interfaces may be used.
To query if a specific operation contains a specific trait, the hasTrait<> method may be used. This takes as a template parameter the trait class, which is the same as the one passed when attaching the trait to an operation.
Operation *op = ..; if (op->hasTrait<MyTrait>() || op->hasTrait<MyParametricTrait<10>::Impl>()) ...;
MLIR provides a suite of traits that provide various functionalities that are common across many different operations. Below is a list of some key traits that may be used directly by any dialect. The format of the header for each trait section goes as follows:
HeaderC++ class -- ODS class(if applicable))OpTrait::BroadcastableTwoOperandsOneResult -- BroadcastableThis trait provides the API for operations that are known to have broadcast-compatible operand and result types. Specifically, starting from the most varying dimension, each dimension pair of the two operands' types should either be the same or one of them is one. Also, the result type should have the corresponding dimension equal to the larger one, if known. Shapes are checked partially if ranks or dimensions are not known. For example, an op with tensor<?x2xf32> and tensor<2xf32> as operand types and tensor<3x2xf32> as the result type is broadcast-compatible.
Ths trait assumes the op has two operands and one result, and it asserts if the pre-condition is not satisfied.
OpTrait::IsCommutative -- CommutativeThis trait adds the property that the operation is commutative, i.e. X op Y == Y op X
OpTrait::FunctionLikeThis trait provides APIs for operations that behave like functions. In particular:
Symbol trait;This trait does NOT provide type support for the functions, meaning that concrete Ops must handle the type of the declared or defined function. getTypeAttrName() is a convenience function that returns the name of the attribute that can be used to store the function type, but the trait makes no assumption based on it.
OpTrait::HasParent<typename ParentOpType> -- HasParent<string op>This trait provides APIs and verifiers for operations that can only be nested within regions that are attached to operations of ParentOpType.
OpTrait::IsIsolatedFromAbove -- IsolatedFromAboveThis trait signals that the regions of an operations are known to be isolated from above. This trait asserts that the regions of an operation will not capture, or reference, SSA values defined above the region scope. This means that the following is invalid if foo.region_op is defined as IsolatedFromAbove:
%result = constant 10 : i32 foo.region_op { foo.yield %result : i32 }
This trait is an important structural property of the IR, and enables operations to have passes scheduled under them.
OpTrait::HasNoSideEffect -- NoSideEffectThis trait signifies that the operation is pure and has no visible side effects.
OpTrait::SingleBlockImplicitTerminator<typename TerminatorOpType> : SingleBlockImplicitTerminator<string op>This trait provides APIs and verifiers for operations with regions that have a single block that must terminate with TerminatorOpType.
OpTrait::Symbol -- SymbolThis trait is used for operations that define a Symbol.
TODO(riverriddle) Link to the proper document detailing the design of symbols.
OpTrait::SymbolTable -- SymbolTableThis trait is used for operations that define a SymbolTable.
TODO(riverriddle) Link to the proper document detailing the design of symbols.
OpTrait::IsTerminator -- TerminatorThis trait provides verification and functionality for operations that are known to be terminators.