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