forked from OSchip/llvm-project
1370 lines
54 KiB
Markdown
1370 lines
54 KiB
Markdown
# Table-driven Operation Definition Specification (ODS)
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In addition to specializing the `mlir::Op` C++ template, MLIR also supports
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defining operations in a table-driven manner. This is achieved via
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[TableGen][TableGen], which is both a generic language and its tooling to
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maintain records of domain-specific information. Facts regarding an operation
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are specified concisely into a TableGen record, which will be expanded into an
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equivalent `mlir::Op` C++ template specialization at compiler build time.
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This manual explains in detail all the available mechanisms for defining
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operations in such a table-driven manner. It aims to be a specification instead
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of a tutorial. Please refer to [Quickstart tutorial to adding MLIR graph
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rewrite](Tutorials/QuickstartRewrites.md) for the latter.
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In addition to detailing each mechanism, this manual also tries to capture
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best practices. They are rendered as quoted bullet points.
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## Motivation
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MLIR allows pluggable dialects, and dialects contain, among others, a list of
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operations. This open and extensible ecosystem leads to the "stringly" type IR
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problem, e.g., repetitive string comparisons during optimization and analysis
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passes, unintuitive accessor methods (e.g., generic/error prone `getOperand(3)`
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vs self-documenting `getStride()`) with more generic return types, verbose and
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generic constructors without default arguments, verbose textual IR dump, and
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so on. Furthermore, operation verification is:
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1. best case: a central string-to-verification-function map,
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1. middle case: duplication of verification across the code base, or
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1. worst case: no verification functions.
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The fix is to support defining ops in a table-driven manner. Then for each
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dialect, we can have a central place that contains everything you need to know
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about each op, including its constraints, custom assembly form, etc. This
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description is also used to generate helper functions and classes to allow
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building, verification, parsing, printing, analysis, and many more.
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## Benefits
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Compared to the C++ template, this table-driven approach has several benefits
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including but not limited to:
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* **Single source of truth**: We strive to encode all facts regarding an
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operation into the record, so that readers don't need to jump among code
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snippets to fully understand an operation.
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* **Removing boilerplate**: We can automatically generate
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operand/attribute/result getter methods, operation build methods, operation
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verify methods, and many more utilities from the record. This greatly reduces
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the boilerplate needed for defining a new op.
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* **Facilitating auto-generation**: The usage of these operation information
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records are by no means limited to op definition itself. We can use them to
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drive the auto-generation of many other components, like computation graph
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serialization.
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## TableGen Syntax
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We use TableGen as the language for specifying operation information. TableGen
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itself just provides syntax for writing records; the syntax and constructs
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allowed in a TableGen file (typically with filename suffix `.td`) can be found
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[here][TableGenIntro]. The formal language specification can be found
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[here][TableGenRef]. _Roughly_ speaking,
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* TableGen `class` is similar to C++ class; it can be templated and
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subclassed.
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* TableGen `def` is similar to C++ object; it can be declared by specializing
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a TableGen `class` (e.g., `def MyDef : MyClass<...>;`) or completely
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independently (e.g., `def MyDef;`). It cannot be further templated or
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subclassed.
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* TableGen `dag` is a dedicated type for directed acyclic graph of elements. A
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`dag` has one operator and zero or more arguments. Its syntax is `(operator
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arg0, arg1, argN)`. The operator can be any TableGen `def`; an argument can
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be anything, including `dag` itself. We can have names attached to both the
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operator and the arguments like `(MyOp:$op_name MyArg:$arg_name)`.
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Please see the [language introduction][TableGenIntro] to learn about all the
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types and expressions supported by TableGen.
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## Operation Definition
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MLIR defines several common constructs to help operation definition and provide
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their semantics via a special [TableGen backend][TableGenBackend]:
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[`OpDefinitionsGen`][OpDefinitionsGen]. These constructs are defined in
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[`OpBase.td`][OpBase]. The main ones are
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* The `Op` class: It is the main construct for defining operations. All facts
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regarding the operation are specified when specializing this class, with the
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help of the following constructs.
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* The `Dialect` class: Operations belonging to one logical group are placed in
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the same dialect. The `Dialect` class contains dialect-level information.
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* The `OpTrait` class hierarchy: They are used to specify special properties
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and constraints of the operation, including whether the operation has side
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effect or whether its output has the same shape as the input.
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* The `ins`/`outs` marker: These are two special makers builtin to the
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`OpDefinitionsGen` backend. They lead the definitions of operands/attributes
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and results respectively.
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* The `TypeConstraint` class hierarchy: They are used to specify the
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constraints over operands or results. A notable subclass hierarchy is
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`Type`, which stands for constraints for common C++ types.
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* The `AttrConstraint` class hierarchy: They are used to specify the
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constraints over attributes. A notable subclass hierarchy is `Attr`, which
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stands for constraints for attributes whose values are of common types.
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An operation is defined by specializing the `Op` class with concrete contents
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for all the fields it requires. For example, `tf.AvgPool` is defined as
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```tablegen
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def TF_AvgPoolOp : TF_Op<"AvgPool", [NoSideEffect]> {
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let summary = "Performs average pooling on the input.";
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let description = [{
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Each entry in `output` is the mean of the corresponding size `ksize`
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window in `value`.
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}];
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let arguments = (ins
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TF_FpTensor:$value,
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Confined<I64ArrayAttr, [ArrayMinCount<4>]>:$ksize,
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Confined<I64ArrayAttr, [ArrayMinCount<4>]>:$strides,
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TF_AnyStrAttrOf<["SAME", "VALID"]>:$padding,
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DefaultValuedAttr<TF_ConvertDataFormatAttr, "NHWC">:$data_format
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);
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let results = (outs
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TF_FpTensor:$output
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);
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TF_DerivedOperandTypeAttr T = TF_DerivedOperandTypeAttr<0>;
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}
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```
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In the following we describe all the fields needed. Please see the definition
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of the `Op` class for the complete list of fields supported.
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### Operation name
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The operation name is a unique identifier of the operation within MLIR, e.g.,
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`tf.Add` for addition operation in the TensorFlow dialect. This is the
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equivalent of the mnemonic in assembly language. It is used for parsing and
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printing in the textual format. It is also used for pattern matching in graph
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rewrites.
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The full operation name is composed of the dialect name and the op name, with
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the former provided via the dialect and the latter provided as the second
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template parameter to the `Op` class.
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### Operation documentation
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This includes both a one-line `summary` and a longer human-readable
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`description`. They will be used to drive automatic generation of dialect
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documentation. They need to be provided in the operation's definition body:
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```tablegen
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let summary = "...";
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let description = [{
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...
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}];
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```
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`description` should be written in Markdown syntax.
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Placing the documentation at the beginning is recommended since
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it helps in understanding the operation.
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> * Place documentation at the beginning of the operation definition
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> * The summary should be short and concise. It should be a one-liner without
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> trailing punctuation. Put expanded explanation in description.
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### Operation arguments
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There are two kinds of arguments: operands and attributes. Operands are runtime
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values produced by other ops; while attributes are compile-time known constant
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values, including two categories:
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1. Natural attributes: these attributes affect the behavior of the operations
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(e.g., padding for convolution);
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1. Derived attributes: these attributes are not needed to define the operation
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but are instead derived from information of the operation. E.g., the output
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shape of type. This is mostly used for convenience interface generation or
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interaction with other frameworks/translation.
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All derived attributes should be materializable as an Attribute. That is,
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even though they are not materialized, it should be possible to store as
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an attribute.
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Both operands and attributes are specified inside the `dag`-typed `arguments`,
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led by `ins`:
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```tablegen
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let arguments = (ins
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<type-constraint>:$<operand-name>,
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...
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<attr-constraint>:$<attr-name>,
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...
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);
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```
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Here `<type-constraint>` is a TableGen `def` from the `TypeConstraint` class
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hierarchy. Similarly, `<attr-constraint>` is a TableGen `def` from the
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`AttrConstraint` class hierarchy. See [Constraints](#constraints) for more
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information.
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There is no requirements on the relative order of operands and attributes; they
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can mix freely. The relative order of operands themselves matters. From each
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named argument a named getter will be generated that returns the argument with
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the return type (in the case of attributes the return type will be
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constructed from the storage type, while for operands it will be `Value`). Each
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attribute's raw value (e.g., as stored) can also be accessed via generated
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`<name>Attr` getters for use in transformation passes where the more user
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friendly return type is less suitable.
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All the arguments should be named to 1) provide documentation, 2) drive
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auto-generation of getter methods, 3) provide a handle to reference for other
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places like constraints.
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#### Variadic operands
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To declare a variadic operand, wrap the `TypeConstraint` for the operand with
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`Variadic<...>`.
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Normally operations have no variadic operands or just one variadic operand. For
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the latter case, it is easy to deduce which dynamic operands are for the static
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variadic operand definition. Though, if an operation has more than one variable
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length operands (either optional or variadic), it would be impossible to
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attribute dynamic operands to the corresponding static variadic operand
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definitions without further information from the operation. Therefore, either
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the `SameVariadicOperandSize` or `AttrSizedOperandSegments` trait is needed to
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indicate that all variable length operands have the same number of dynamic
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values.
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#### Optional operands
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To declare an optional operand, wrap the `TypeConstraint` for the operand with
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`Optional<...>`.
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Normally operations have no optional operands or just one optional operand. For
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the latter case, it is easy to deduce which dynamic operands are for the static
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operand definition. Though, if an operation has more than one variable length
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operands (either optional or variadic), it would be impossible to attribute
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dynamic operands to the corresponding static variadic operand definitions
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without further information from the operation. Therefore, either the
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`SameVariadicOperandSize` or `AttrSizedOperandSegments` trait is needed to
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indicate that all variable length operands have the same number of dynamic
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values.
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#### Optional attributes
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To declare an optional attribute, wrap the `AttrConstraint` for the attribute
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with `OptionalAttr<...>`.
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#### Attributes with default values
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To declare an attribute with a default value, wrap the `AttrConstraint` for the
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attribute with `DefaultValuedAttr<..., "...">`.
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The second parameter to `DefaultValuedAttr` should be a string containing the
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C++ default value. For example, a float default value should be specified as
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like `"0.5f"`, and an integer array default value should be specified as like
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`"{1, 2, 3}"`.
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#### Confining attributes
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`Confined` is provided as a general mechanism to help modelling further
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constraints on attributes beyond the ones brought by value types. You can use
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`Confined` to compose complex constraints out of more primitive ones. For
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example, a 32-bit integer attribute whose minimum value must be 10 can be
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expressed as `Confined<I32Attr, [IntMinValue<10>]>`.
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Right now, the following primitive constraints are supported:
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* `IntMinValue<N>`: Specifying an integer attribute to be greater than or
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equal to `N`
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* `IntMaxValue<N>`: Specifying an integer attribute to be less than or equal
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to `N`
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* `ArrayMinCount<N>`: Specifying an array attribute to have at least `N`
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elements
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* `IntArrayNthElemEq<I, N>`: Specifying an integer array attribute's `I`-th
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element to be equal to `N`
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* `IntArrayNthElemMinValue<I, N>`: Specifying an integer array attribute's
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`I`-th element to be greater than or equal to `N`
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TODO: Design and implement more primitive constraints
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### Operation regions
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The regions of an operation are specified inside of the `dag`-typed `regions`,
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led by `region`:
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```tablegen
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let regions = (region
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<region-constraint>:$<region-name>,
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...
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);
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```
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#### Variadic regions
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Similar to the `Variadic` class used for variadic operands and results,
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`VariadicRegion<...>` can be used for regions. Variadic regions can currently
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only be specified as the last region in the regions list.
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### Operation results
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Similar to operands, results are specified inside the `dag`-typed `results`, led
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by `outs`:
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```tablegen
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let results = (outs
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<type-constraint>:$<result-name>,
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...
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);
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```
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#### Variadic results
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Similar to variadic operands, `Variadic<...>` can also be used for results.
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And similarly, `SameVariadicResultSize` for multiple variadic results in the
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same operation.
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### Operation successors
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For terminator operations, the successors are specified inside of the
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`dag`-typed `successors`, led by `successor`:
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```tablegen
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let successors = (successor
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<successor-constraint>:$<successor-name>,
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...
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);
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```
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#### Variadic successors
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Similar to the `Variadic` class used for variadic operands and results,
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`VariadicSuccessor<...>` can be used for successors. Variadic successors can
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currently only be specified as the last successor in the successor list.
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### Operation traits and constraints
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Traits are operation properties that affect syntax or semantics. MLIR C++
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models various traits in the `mlir::OpTrait` namespace.
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Both operation traits, [interfaces](#operation-interfaces), and constraints
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involving multiple operands/attributes/results are provided as the second
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template parameter to the `Op` class. They should be deriving from the `OpTrait`
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class. See [Constraints](#constraints) for more information.
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### Operation interfaces
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[Operation interfaces](Interfaces.md#operation-interfaces) allow
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operations to expose method calls without the
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caller needing to know the exact operation type. Operation interfaces
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defined in C++ can be accessed in the ODS framework via the
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`OpInterfaceTrait` class. Aside from using pre-existing interfaces in
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the C++ API, the ODS framework also provides a simplified mechanism
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for defining such interfaces which removes much of the boilerplate
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necessary.
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Providing a definition of the `OpInterface` class will auto-generate the C++
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classes for the interface. An `OpInterface` includes a name, for the C++ class,
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a description, and a list of interface methods.
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```tablegen
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def MyInterface : OpInterface<"MyInterface"> {
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let description = ...;
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let methods = [...];
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}
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```
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There are two types of methods that can be used with an interface,
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`InterfaceMethod` and `StaticInterfaceMethod`. They are both comprised of the
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same core components, with the distinction that `StaticInterfaceMethod` models a
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static method on the derived operation.
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An `InterfaceMethod` is comprised of the following components:
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* Description
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- A string description of what this method does and its invariants.
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* ReturnType
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- A string corresponding to the C++ return type of the method.
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* MethodName
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- A string corresponding to the desired name of the method.
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* Arguments (Optional)
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- A dag of strings that correspond to a C++ type and variable name
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respectively.
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* MethodBody (Optional)
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- An optional explicit implementation of the interface method.
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- `ConcreteOp` is an implicitly defined typename that can be used to refer
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to the type of the derived operation currently being operated on.
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- In non-static methods, a variable 'ConcreteOp op' is defined and may be
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used to refer to an instance of the derived operation.
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* DefaultImplementation (Optional)
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- An optional explicit default implementation of the interface method.
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- This method is placed within the `Trait` class that is attached to the
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operation. As such, this method has the same characteristics as any
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other [`Trait`](Traits.md) method.
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- `ConcreteOp` is an implicitly defined typename that can be used to refer
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to the type of the derived operation currently being operated on.
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ODS also allows generating the declarations for the `InterfaceMethod` of the op
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if one specifies the interface with `DeclareOpInterfaceMethods` (see example
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below).
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Examples:
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```tablegen
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def MyInterface : OpInterface<"MyInterface"> {
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let description = [{
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My interface is very interesting. ...
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}];
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let methods = [
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// A simple non-static method with no inputs.
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InterfaceMethod<"'foo' is a non-static method with no inputs.",
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"unsigned", "foo"
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>,
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// A new non-static method accepting an input argument.
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InterfaceMethod<"/*insert doc here*/",
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"Value ", "bar", (ins "unsigned":$i)
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>,
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// Query a static property of the derived operation.
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StaticInterfaceMethod<"'fooStatic' is a static method with no inputs.",
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"unsigned", "fooStatic"
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>,
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// Provide the definition of a static interface method.
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// Note: `ConcreteOp` corresponds to the derived operation typename.
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StaticInterfaceMethod<"/*insert doc here*/",
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"Operation *", "create", (ins "OpBuilder &":$builder, "Location":$loc), [{
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return builder.create<ConcreteOp>(loc);
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}]>,
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// Provide a definition of the non-static method.
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// Note: `op` corresponds to the derived operation variable.
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InterfaceMethod<"/*insert doc here*/",
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"unsigned", "getNumInputsAndOutputs", (ins), [{
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return op.getNumInputs() + op.getNumOutputs();
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}]>,
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// Provide only a default definition of the method.
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// Note: `ConcreteOp` corresponds to the derived operation typename.
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InterfaceMethod<"/*insert doc here*/",
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"unsigned", "getNumWithDefault", (ins), /*methodBody=*/[{}], [{
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ConcreteOp op = cast<ConcreteOp>(getOperation());
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return op.getNumInputs() + op.getNumOutputs();
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}]>,
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];
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}
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// Interfaces can optionally be wrapped inside DeclareOpInterfaceMethods. This
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// would result in autogenerating declarations for members `foo`, `bar` and
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// `fooStatic`. Methods with bodies are not declared inside the op
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// declaration but instead handled by the op interface trait directly.
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def OpWithInferTypeInterfaceOp : Op<...
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[DeclareOpInterfaceMethods<MyInterface>]> { ... }
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// Methods that have a default implementation do not have declarations
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// generated. If an operation wishes to override the default behavior, it can
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// explicitly specify the method that it wishes to override. This will force
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// the generation of a declaration for those methods.
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def OpWithOverrideInferTypeInterfaceOp : Op<...
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[DeclareOpInterfaceMethods<MyInterface, ["getNumWithDefault"]>]> { ... }
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```
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A verification method can also be specified on the `OpInterface` by setting
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`verify`. Setting `verify` results in the generated trait having a `verifyTrait`
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method that is applied to all operations implementing the trait.
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### Builder methods
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For each operation, there are a few builders automatically generated based on
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the arguments and returns types. For example, given the following op definition:
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```tablegen
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def MyOp : ... {
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let arguments = (ins
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I32:$i32_operand,
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F32:$f32_operand,
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...,
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I32Attr:$i32_attr,
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F32Attr:$f32_attr,
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...
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);
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let results = (outs
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I32:$i32_result,
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F32:$f32_result,
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...
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);
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}
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```
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|
|
The following builders are generated:
|
|
|
|
```c++
|
|
// All result-types/operands/attributes have one aggregate parameter.
|
|
static void build(OpBuilder &odsBuilder, OperationState &odsState,
|
|
ArrayRef<Type> resultTypes,
|
|
ValueRange operands,
|
|
ArrayRef<NamedAttribute> attributes);
|
|
|
|
// Each result-type/operand/attribute has a separate parameter. The parameters
|
|
// for attributes are of mlir::Attribute types.
|
|
static void build(OpBuilder &odsBuilder, OperationState &odsState,
|
|
Type i32_result, Type f32_result, ...,
|
|
Value i32_operand, Value f32_operand, ...,
|
|
IntegerAttr i32_attr, FloatAttr f32_attr, ...);
|
|
|
|
// Each result-type/operand/attribute has a separate parameter. The parameters
|
|
// for attributes are raw values unwrapped with mlir::Attribute instances.
|
|
// (Note that this builder will not always be generated. See the following
|
|
// explanation for more details.)
|
|
static void build(OpBuilder &odsBuilder, OperationState &odsState,
|
|
Type i32_result, Type f32_result, ...,
|
|
Value i32_operand, Value f32_operand, ...,
|
|
APInt i32_attr, StringRef f32_attr, ...);
|
|
|
|
// Each operand/attribute has a separate parameter but result type is aggregate.
|
|
static void build(OpBuilder &odsBuilder, OperationState &odsState,
|
|
ArrayRef<Type> resultTypes,
|
|
Value i32_operand, Value f32_operand, ...,
|
|
IntegerAttr i32_attr, FloatAttr f32_attr, ...);
|
|
|
|
// All operands/attributes have aggregate parameters.
|
|
// Generated if InferTypeOpInterface interface is specified.
|
|
static void build(OpBuilder &odsBuilder, OperationState &odsState,
|
|
ValueRange operands,
|
|
ArrayRef<NamedAttribute> attributes);
|
|
|
|
// (And manually specified builders depending on the specific op.)
|
|
```
|
|
|
|
The first form provides basic uniformity so that we can create ops using the
|
|
same form regardless of the exact op. This is particularly useful for
|
|
implementing declarative pattern rewrites.
|
|
|
|
The second and third forms are good for use in manually written code given that
|
|
they provide better guarantee via signatures.
|
|
|
|
The third form will be generated if any of the op's attribute has different
|
|
`Attr.returnType` from `Attr.storageType` and we know how to build an attribute
|
|
from an unwrapped value (i.e., `Attr.constBuilderCall` is defined.)
|
|
Additionally, for the third form, if an attribute appearing later in the
|
|
`arguments` list has a default value, the default value will be supplied in the
|
|
declaration. This works for `BoolAttr`, `StrAttr`, `EnumAttr` for now and the
|
|
list can grow in the future. So if possible, default valued attribute should be
|
|
placed at the end of the `arguments` list to leverage this feature. (This
|
|
behavior is essentially due to C++ function parameter default value placement
|
|
restrictions.) Otherwise, the builder of the third form will still be generated
|
|
but default values for the attributes not at the end of the `arguments` list
|
|
will not be supplied in the builder's signature.
|
|
|
|
And there may potentially exist other builders depending on the specific op;
|
|
please refer to the
|
|
[generated C++ file](#run-mlir-tblgen-to-see-the-generated-content) for the
|
|
complete list.
|
|
|
|
#### Custom builder methods
|
|
|
|
However, if the above cases cannot satisfy all needs, you can define additional
|
|
convenience build methods with `OpBuilder`.
|
|
|
|
`OpBuilder` is a class that takes the parameter list and the optional `build()`
|
|
method body. They are separated because we need to generate op declaration and
|
|
definition into separate files. The parameter list should _include_ `Builder
|
|
*builder, OperationState &state`. If the `body` is not provided, _only_ the
|
|
builder declaration will be generated; this provides a way to define complicated
|
|
builders entirely in C++ files.
|
|
|
|
For example, for the following op:
|
|
|
|
```tablegen
|
|
def MyOp : Op<"my_op", []> {
|
|
let arguments = (ins F32Attr:$attr);
|
|
|
|
let results = (outs);
|
|
}
|
|
```
|
|
|
|
If we want to define a builder with a default value for the only attribute, we
|
|
can add into `MyOp`:
|
|
|
|
```tablegen
|
|
def MyOp : ... {
|
|
...
|
|
|
|
let builders = [
|
|
OpBuilder<"OpBuilder &builder, OperationState &state, float val = 0.5f", [{
|
|
state.addAttribute("attr", builder.getF32FloatAttr(val));
|
|
}]>
|
|
];
|
|
}
|
|
```
|
|
|
|
The generated builder will look like:
|
|
|
|
```c++
|
|
static void build(OpBuilder &builder, OperationState &state, float val = 0.5f) {
|
|
state.addAttribute("attr", builder.getF32FloatAttr(val));
|
|
}
|
|
```
|
|
|
|
### Custom parser and printer methods
|
|
|
|
Functions to parse and print the operation's custom assembly form.
|
|
|
|
### Custom verifier code
|
|
|
|
Verification code will be automatically generated for
|
|
[constraints](#constraints) specified on various entities of the op. To
|
|
perform _additional_ verification, you can use
|
|
|
|
```tablegen
|
|
let verifier = [{
|
|
...
|
|
}];
|
|
```
|
|
|
|
Code placed in `verifier` will be called after the auto-generated verification
|
|
code.
|
|
|
|
### Declarative Assembly Format
|
|
|
|
The custom assembly form of the operation may be specified in a declarative
|
|
string that matches the operations operands, attributes, etc. With the ability
|
|
to express additional information that needs to be parsed to build the
|
|
operation:
|
|
|
|
```tablegen
|
|
def CallOp : Std_Op<"call", ...> {
|
|
let arguments = (ins FlatSymbolRefAttr:$callee, Variadic<AnyType>:$args);
|
|
let results = (outs Variadic<AnyType>);
|
|
|
|
let assemblyFormat = [{
|
|
$callee `(` $args `)` attr-dict `:` functional-type($args, results)
|
|
}];
|
|
}
|
|
```
|
|
|
|
The format is comprised of three components:
|
|
|
|
#### Directives
|
|
|
|
A directive is a type of builtin function, with an optional set of arguments.
|
|
The available directives are as follows:
|
|
|
|
* `attr-dict`
|
|
|
|
- Represents the attribute dictionary of the operation.
|
|
|
|
* `attr-dict-with-keyword`
|
|
|
|
- Represents the attribute dictionary of the operation, but prefixes the
|
|
dictionary with an `attributes` keyword.
|
|
|
|
* `functional-type` ( inputs , results )
|
|
|
|
- Formats the `inputs` and `results` arguments as a
|
|
[function type](LangRef.md#function-type).
|
|
- The constraints on `inputs` and `results` are the same as the `input` of
|
|
the `type` directive.
|
|
|
|
* `operands`
|
|
|
|
- Represents all of the operands of an operation.
|
|
|
|
* `results`
|
|
|
|
- Represents all of the results of an operation.
|
|
|
|
* `successors`
|
|
|
|
- Represents all of the successors of an operation.
|
|
|
|
* `type` ( input )
|
|
|
|
- Represents the type of the given input.
|
|
- `input` must be either an operand or result [variable](#variables), the
|
|
`operands` directive, or the `results` directive.
|
|
|
|
#### Literals
|
|
|
|
A literal is either a keyword or punctuation surrounded by \`\`.
|
|
|
|
The following are the set of valid punctuation:
|
|
`:`, `,`, `=`, `<`, `>`, `(`, `)`, `[`, `]`, `->`
|
|
|
|
#### Variables
|
|
|
|
A variable is an entity that has been registered on the operation itself, i.e.
|
|
an argument(attribute or operand), result, successor, etc. In the `CallOp`
|
|
example above, the variables would be `$callee` and `$args`.
|
|
|
|
Attribute variables are printed with their respective value type, unless that
|
|
value type is buildable. In those cases, the type of the attribute is elided.
|
|
|
|
#### Optional Groups
|
|
|
|
In certain situations operations may have "optional" information, e.g.
|
|
attributes or an empty set of variadic operands. In these situations a section
|
|
of the assembly format can be marked as `optional` based on the presence of this
|
|
information. An optional group is defined by wrapping a set of elements within
|
|
`()` followed by a `?` and has the following requirements:
|
|
|
|
* The first element of the group must either be a literal or an operand.
|
|
- This is because the first element must be optionally parsable.
|
|
* Exactly one argument variable within the group must be marked as the anchor
|
|
of the group.
|
|
- The anchor is the element whose presence controls whether the group
|
|
should be printed/parsed.
|
|
- An element is marked as the anchor by adding a trailing `^`.
|
|
- The first element is *not* required to be the anchor of the group.
|
|
* Literals, variables, and type directives are the only valid elements within
|
|
the group.
|
|
- Any attribute variable may be used, but only optional attributes can be
|
|
marked as the anchor.
|
|
- Only variadic or optional operand arguments can be used.
|
|
- The operands to a type directive must be defined within the optional
|
|
group.
|
|
|
|
An example of an operation with an optional group is `std.return`, which has a
|
|
variadic number of operands.
|
|
|
|
```
|
|
def ReturnOp : ... {
|
|
let arguments = (ins Variadic<AnyType>:$operands);
|
|
|
|
// We only print the operands and types if there are a non-zero number
|
|
// of operands.
|
|
let assemblyFormat = "attr-dict ($operands^ `:` type($operands))?";
|
|
}
|
|
```
|
|
|
|
#### Requirements
|
|
|
|
The format specification has a certain set of requirements that must be adhered
|
|
to:
|
|
|
|
1. The output and operation name are never shown as they are fixed and cannot be
|
|
altered.
|
|
1. All operands within the operation must appear within the format, either
|
|
individually or with the `operands` directive.
|
|
1. All operand and result types must appear within the format using the various
|
|
`type` directives, either individually or with the `operands` or `results`
|
|
directives.
|
|
1. The `attr-dict` directive must always be present.
|
|
1. Must not contain overlapping information; e.g. multiple instances of
|
|
'attr-dict', types, operands, etc.
|
|
- Note that `attr-dict` does not overlap with individual attributes. These
|
|
attributes will simply be elided when printing the attribute dictionary.
|
|
|
|
##### Type Inference
|
|
|
|
One requirement of the format is that the types of operands and results must
|
|
always be present. In certain instances, the type of a variable may be deduced
|
|
via type constraints or other information available. In these cases, the type of
|
|
that variable may be elided from the format.
|
|
|
|
* Buildable Types
|
|
|
|
Some type constraints may only have one representation, allowing for them to
|
|
be directly buildable; for example the `I32` or `Index` types. Types in `ODS`
|
|
may mark themselves as buildable by setting the `builderCall` field or
|
|
inheriting from the `BuildableType` class.
|
|
|
|
* Trait Equality Constraints
|
|
|
|
There are many operations that have known type equality constraints registered
|
|
as traits on the operation; for example the true, false, and result values of a
|
|
`select` operation often have the same type. The assembly format may inspect
|
|
these equal constraints to discern the types of missing variables. The currently
|
|
supported traits are: `AllTypesMatch`, `SameTypeOperands`, and
|
|
`SameOperandsAndResultType`.
|
|
|
|
### `hasCanonicalizer`
|
|
|
|
This boolean field indicate whether canonicalization patterns have been defined
|
|
for this operation. If it is `1`, then `::getCanonicalizationPatterns()` should
|
|
be defined.
|
|
|
|
### `hasFolder`
|
|
|
|
This boolean field indicate whether general folding rules have been defined
|
|
for this operation. If it is `1`, then `::fold()` should be defined.
|
|
|
|
### Extra declarations
|
|
|
|
One of the goals of table-driven op definition is to auto-generate as much logic
|
|
and methods needed for each op as possible. With that said, there will always be
|
|
long-tail cases that won't be covered. For such cases, you can use
|
|
`extraClassDeclaration`. Code in `extraClassDeclaration` will be copied
|
|
literally to the generated C++ op class.
|
|
|
|
Note that `extraClassDeclaration` is a mechanism intended for long-tail cases
|
|
by power users; for not-yet-implemented widely-applicable cases, improving the
|
|
infrastructure is preferable.
|
|
|
|
### Generated C++ code
|
|
|
|
[OpDefinitionsGen][OpDefinitionsGen] processes the op definition spec file and
|
|
generates two files containing the corresponding C++ code: one for declarations,
|
|
the other for definitions. The former is generated via the `-gen-op-decls`
|
|
command-line option, while the latter is via the `-gen-op-defs` option.
|
|
|
|
The definition file contains all the op method definitions, which can be
|
|
included and enabled by defining `GET_OP_CLASSES`. For each operation,
|
|
OpDefinitionsGen generates an operation class and an
|
|
[operand adaptor](#operand-adaptors) class. Besides, it also contains a
|
|
comma-separated list of all defined ops, which can be included and enabled by
|
|
defining `GET_OP_LIST`.
|
|
|
|
#### Class name and namespaces
|
|
|
|
For each operation, its generated C++ class name is the symbol `def`ed with
|
|
TableGen with dialect prefix removed. The first `_` serves as the delimiter.
|
|
For example, for `def TF_AddOp`, the C++ class name would be `AddOp`.
|
|
We remove the `TF` prefix because it is for scoping ops; other dialects
|
|
may as well define their own `AddOp`s.
|
|
|
|
The namespaces of the generated C++ class will come from the dialect's
|
|
`cppNamespace` field. For example, if a dialect's `cppNamespace` is `A::B`,
|
|
then an op of that dialect will be placed in
|
|
`namespace A { namespace B { ... } }`. If a dialect does not specify a
|
|
`cppNamespace`, we then use the dialect's name as the namespace.
|
|
|
|
This means the qualified name of the generated C++ class does not necessarily
|
|
match exactly with the operation name as explained in
|
|
[Operation name](#operation-name). This is to allow flexible naming to satisfy
|
|
coding style requirements.
|
|
|
|
#### Operand adaptors
|
|
|
|
For each operation, we automatically generate an _operand adaptor_. This class
|
|
solves the problem of accessing operands provided as a list of `Value`s without
|
|
using "magic" constants. The operand adaptor takes a reference to an array of
|
|
`Value` and provides methods with the same names as those in the operation class
|
|
to access them. For example, for a binary arithmetic operation, it may provide
|
|
`.lhs()` to access the first operand and `.rhs()` to access the second operand.
|
|
|
|
The operand adaptor class lives in the same namespace as the operation class,
|
|
and has the name of the operation followed by `OperandAdaptor`. A template
|
|
declaration `OperandAdaptor<>` is provided to look up the operand adaptor for
|
|
the given operation.
|
|
|
|
Operand adaptors can be used in function templates that also process operations:
|
|
|
|
```c++
|
|
template <typename BinaryOpTy>
|
|
std::pair<Value, Value> zip(BinaryOpTy &&op) {
|
|
return std::make_pair(op.lhs(), op.rhs());;
|
|
}
|
|
|
|
void process(AddOp op, ArrayRef<Value> newOperands) {
|
|
zip(op);
|
|
zip(OperandAdaptor<AddOp>(newOperands));
|
|
/*...*/
|
|
}
|
|
```
|
|
|
|
## Constraints
|
|
|
|
Constraint is a core concept in table-driven operation definition: operation
|
|
verification and graph operation matching are all based on satisfying
|
|
constraints. So both the operation definition and rewrite rules specification
|
|
significantly involve writing constraints. We have the `Constraint` class in
|
|
[`OpBase.td`][OpBase] has the common base class for all constraints.
|
|
|
|
An operation's constraint can cover different range; it may
|
|
|
|
* Only concern a single attribute (e.g. being a 32-bit integer greater than 5),
|
|
* Multiple operands and results (e.g., the 1st result's shape must be the same
|
|
as the 1st operand), or
|
|
* Intrinsic to the operation itself (e.g., having no side effect).
|
|
|
|
We call them as single-entity constraint, multi-entity constraint, and traits,
|
|
respectively.
|
|
|
|
### Single-entity constraint
|
|
|
|
Constraints scoped to a single operand, attribute, or result are specified at
|
|
the entity's declaration place as described in
|
|
[Operation arguments](#operation-arguments) and
|
|
[Operation results](#operation-results).
|
|
|
|
To help modelling constraints of common types, a set of `TypeConstraint`s are
|
|
created; they are the `Type` subclass hierarchy. It includes `F32` for the
|
|
constraints of being a float, `TensorOf<[F32]>` for the constraints of being
|
|
a float tensor, and so on.
|
|
|
|
Similarly, a set of `AttrConstraint`s are created for helping modelling
|
|
constraints of common attribute kinds. They are the `Attr` subclass hierarchy.
|
|
It includes `F32Attr` for the constraints of being a float attribute,
|
|
`F32ArrayAttr` for the constraints of being a float array attribute, and so on.
|
|
|
|
### Multi-entity constraint
|
|
|
|
Constraints involving more than one operand/attribute/result are quite common
|
|
on operations, like the element type and shape relation between operands and
|
|
results. These constraints should be specified as the `Op` class template
|
|
parameter as described in
|
|
[Operation traits and constraints](#operation-traits-and-constraints).
|
|
|
|
Multi-entity constraints are modeled as `PredOpTrait` (a subclass of `OpTrait`)
|
|
in [`OpBase.td`][OpBase].A bunch of constraint primitives are provided to help
|
|
specification. See [`OpBase.td`][OpBase] for the complete list.
|
|
|
|
### Trait
|
|
|
|
Traits are intrinsic properties of the operation like having side effect or not,
|
|
commutative or not, whether is a terminator, etc. These constraints should be
|
|
specified as the `Op` class template parameter as described in
|
|
[Operation traits and constraints](#operation-traits-and-constraints).
|
|
|
|
Traits are modeled as `NativeOpTrait` (a subclass of `OpTrait`) in
|
|
[`OpBase.td`][OpBase]. They are backed and will be translated into the
|
|
corresponding C++ `mlir::OpTrait` classes.
|
|
|
|
### How to specify new constraint
|
|
|
|
To write a constraint, you need to provide its predicates and give it a
|
|
descriptive name. Predicates, modeled with the `Pred` class, are the workhorse
|
|
for composing constraints. The predicate for a constraint is typically built up
|
|
in a nested manner, using the two categories of predicates:
|
|
|
|
1. `CPred`: the primitive leaf predicate.
|
|
2. Compound predicate: a predicate composed from child predicates using
|
|
predicate combiners (conjunction: `And`, disjunction: `Or`, negation: `Neg`,
|
|
substitution: `SubstLeaves`, concatenation: `Concat`).
|
|
|
|
`CPred` is the basis for composing more complex predicates. It is the "atom"
|
|
predicate from the perspective of TableGen and the "interface" between
|
|
TableGen and C++. What is inside is already C++ code, which will be treated
|
|
as opaque strings with special placeholders to be substituted.
|
|
|
|
You can put any C++ code that returns a boolean value inside a `CPred`,
|
|
including evaluating expressions, calling functions, calling class methods,
|
|
and so on.
|
|
|
|
To help interaction with the C++ environment, there are a few special
|
|
placeholders provided to refer to entities in the context where this predicate
|
|
is used. They serve as "hooks" to the enclosing environment. This includes
|
|
`$_builder`, `$_op`, and `$_self`:
|
|
|
|
* `$_builder` will be replaced by a `mlir::Builder` instance so that you can
|
|
access common build methods.
|
|
* `$_op` will be replaced by the current operation so that you can access
|
|
information of the current operation.
|
|
* `$_self` will be replaced with the entity this predicate is attached to.
|
|
E.g., `BoolAttr` is an attribute constraint that wraps a
|
|
`CPred<"$_self.isa<BoolAttr>()">`. Then for `F32:$attr`,`$_self` will be
|
|
replaced by `$attr`. For type constraints, it's a little bit special since
|
|
we want the constraints on each type definition reads naturally and we want
|
|
to attach type constraints directly to an operand/result, `$_self` will be
|
|
replaced by the operand/result's type. E.g., for `F32` in `F32:$operand`, its
|
|
`$_self` will be expanded as `getOperand(...).getType()`.
|
|
|
|
TODO(b/130663252): Reconsider the leading symbol for special placeholders.
|
|
Eventually we want to allow referencing operand/result $-names; such $-names
|
|
can start with underscore.
|
|
|
|
For example, to write an attribute `attr` is an `IntegerAttr`, in C++ you can
|
|
just call `attr.isa<IntegerAttr>()`. The code can be wrapped in a `CPred` as
|
|
`$_self.isa<IntegerAttr>()`, with `$_self` as the special placeholder to be
|
|
replaced by the current attribute `attr` at expansion time.
|
|
|
|
For more complicated predicates, you can wrap it in a single `CPred`, or you
|
|
can use predicate combiners to combine them. For example, to write the
|
|
constraint that an attribute `attr` is a 32-bit or 64-bit integer, you can
|
|
write it as
|
|
|
|
```tablegen
|
|
And<[
|
|
CPred<"$_self.isa<IntegerAttr>()">,
|
|
Or<[
|
|
CPred<"$_self.cast<IntegerAttr>().getType().isInteger(32)">,
|
|
CPred<"$_self.cast<IntegerAttr>().getType().isInteger(64)">
|
|
]>
|
|
]>
|
|
```
|
|
|
|
(Note that the above is just to show with a familiar example how you can use
|
|
`CPred` and predicate combiners to write complicated predicates. For integer
|
|
attributes specifically, [`OpBase.td`][OpBase] already defines `I32Attr` and
|
|
`I64Attr`. So you can actually reuse them to write it as `Or<[I32Attr.predicate,
|
|
I64Attr.predicate]>`.)
|
|
|
|
TODO: Build up a library of reusable primitive constraints
|
|
|
|
If the predicate is very complex to write with `CPred` together with predicate
|
|
combiners, you can also write it as a normal C++ function and use the `CPred`
|
|
as a way to "invoke" the function. For example, to verify an attribute `attr`
|
|
has some property, you can write a C++ function like
|
|
|
|
```cpp
|
|
bool HasSomeProperty(Attribute attr) { ... }
|
|
```
|
|
|
|
and then define the op as:
|
|
|
|
```tablegen
|
|
def HasSomeProperty : AttrConstraint<CPred<"HasSomeProperty($_self)">,
|
|
"has some property">;
|
|
|
|
def MyOp : Op<...> {
|
|
let arguments = (ins
|
|
...
|
|
HasSomeProperty:$attr
|
|
);
|
|
}
|
|
```
|
|
|
|
As to whether we should define the predicate using a single `CPred` wrapping
|
|
the whole expression, multiple `CPred`s with predicate combiners, or a single
|
|
`CPred` "invoking" a function, there are no clear-cut criteria. Defining using
|
|
`CPred` and predicate combiners is preferable since it exposes more information
|
|
(instead hiding all the logic behind a C++ function) into the op definition spec
|
|
so that it can potentially drive more auto-generation cases. But it will
|
|
require a nice library of common predicates as the building blocks to avoid the
|
|
duplication, which is being worked on right now.
|
|
|
|
## Attribute Definition
|
|
|
|
An attribute is a compile-time known constant of an operation.
|
|
|
|
ODS provides attribute wrappers over C++ attribute classes. There are a few
|
|
common C++ [attribute classes][AttrClasses] defined in MLIR's core IR library
|
|
and one is free to define dialect-specific attribute classes. ODS allows one
|
|
to use these attributes in TableGen to define operations, potentially with
|
|
more fine-grained constraints. For example, `StrAttr` directly maps to
|
|
`StringAttr`; `F32Attr`/`F64Attr` requires the `FloatAttr` to additionally
|
|
be of a certain bitwidth.
|
|
|
|
ODS attributes are defined as having a storage type (corresponding to a backing
|
|
`mlir::Attribute` that _stores_ the attribute), a return type (corresponding to
|
|
the C++ _return_ type of the generated of the helper getters) as well as method
|
|
to convert between the internal storage and the helper method.
|
|
|
|
### Attribute decorators
|
|
|
|
There are a few important attribute adapters/decorators/modifers that can be
|
|
applied to ODS attributes to specify common additional properties like
|
|
optionality, default values, etc.:
|
|
|
|
* `DefaultValuedAttr`: specifies the
|
|
[default value](#attributes-with-default-values) for an attribute.
|
|
* `OptionalAttr`: specifies an attribute as [optional](#optional-attributes).
|
|
* `Confined`: adapts an attribute with
|
|
[further constraints](#confining-attributes).
|
|
|
|
### Enum attributes
|
|
|
|
Some attributes can only take values from a predefined enum, e.g., the
|
|
comparison kind of a comparison op. To define such attributes, ODS provides
|
|
several mechanisms: `StrEnumAttr`, `IntEnumAttr`, and `BitEnumAttr`.
|
|
|
|
* `StrEnumAttr`: each enum case is a string, the attribute is stored as a
|
|
[`StringAttr`][StringAttr] in the op.
|
|
* `IntEnumAttr`: each enum case is an integer, the attribute is stored as a
|
|
[`IntegerAttr`][IntegerAttr] in the op.
|
|
* `BitEnumAttr`: each enum case is a bit, the attribute is stored as a
|
|
[`IntegerAttr`][IntegerAttr] in the op.
|
|
|
|
All these `*EnumAttr` attributes require fully specifying all of the allowed
|
|
cases via their corresponding `*EnumAttrCase`. With this, ODS is able to
|
|
generate additional verification to only accept allowed cases. To facilitate the
|
|
interaction between `*EnumAttr`s and their C++ consumers, the
|
|
[`EnumsGen`][EnumsGen] TableGen backend can generate a few common utilities: a
|
|
C++ enum class, `llvm::DenseMapInfo` for the enum class, conversion functions
|
|
from/to strings. This is controlled via the `-gen-enum-decls` and
|
|
`-gen-enum-defs` command-line options of `mlir-tblgen`.
|
|
|
|
For example, given the following `EnumAttr`:
|
|
|
|
```tablegen
|
|
def Case15: I32EnumAttrCase<"Case15", 15>;
|
|
def Case20: I32EnumAttrCase<"Case20", 20>;
|
|
|
|
def MyIntEnum: I32EnumAttr<"MyIntEnum", "An example int enum",
|
|
[Case15, Case20]> {
|
|
let cppNamespace = "Outer::Inner";
|
|
let stringToSymbolFnName = "ConvertToEnum";
|
|
let symbolToStringFnName = "ConvertToString";
|
|
}
|
|
```
|
|
|
|
The following will be generated via `mlir-tblgen -gen-enum-decls`:
|
|
|
|
```c++
|
|
namespace Outer {
|
|
namespace Inner {
|
|
// An example int enum
|
|
enum class MyIntEnum : uint32_t {
|
|
Case15 = 15,
|
|
Case20 = 20,
|
|
};
|
|
|
|
llvm::Optional<MyIntEnum> symbolizeMyIntEnum(uint32_t);
|
|
llvm::StringRef ConvertToString(MyIntEnum);
|
|
llvm::Optional<MyIntEnum> ConvertToEnum(llvm::StringRef);
|
|
inline constexpr unsigned getMaxEnumValForMyIntEnum() {
|
|
return 20;
|
|
}
|
|
|
|
} // namespace Inner
|
|
} // namespace Outer
|
|
|
|
namespace llvm {
|
|
template<> struct DenseMapInfo<Outer::Inner::MyIntEnum> {
|
|
using StorageInfo = llvm::DenseMapInfo<uint32_t>;
|
|
|
|
static inline Outer::Inner::MyIntEnum getEmptyKey() {
|
|
return static_cast<Outer::Inner::MyIntEnum>(StorageInfo::getEmptyKey());
|
|
}
|
|
|
|
static inline Outer::Inner::MyIntEnum getTombstoneKey() {
|
|
return static_cast<Outer::Inner::MyIntEnum>(StorageInfo::getTombstoneKey());
|
|
}
|
|
|
|
static unsigned getHashValue(const Outer::Inner::MyIntEnum &val) {
|
|
return StorageInfo::getHashValue(static_cast<uint32_t>(val));
|
|
}
|
|
|
|
static bool isEqual(const Outer::Inner::MyIntEnum &lhs, const Outer::Inner::MyIntEnum &rhs) {
|
|
return lhs == rhs;
|
|
}
|
|
};
|
|
}
|
|
```
|
|
|
|
The following will be generated via `mlir-tblgen -gen-enum-defs`:
|
|
|
|
```c++
|
|
namespace Outer {
|
|
namespace Inner {
|
|
llvm::StringRef ConvertToString(MyIntEnum val) {
|
|
switch (val) {
|
|
case MyIntEnum::Case15: return "Case15";
|
|
case MyIntEnum::Case20: return "Case20";
|
|
}
|
|
return "";
|
|
}
|
|
|
|
llvm::Optional<MyIntEnum> ConvertToEnum(llvm::StringRef str) {
|
|
return llvm::StringSwitch<llvm::Optional<MyIntEnum>>(str)
|
|
.Case("Case15", MyIntEnum::Case15)
|
|
.Case("Case20", MyIntEnum::Case20)
|
|
.Default(llvm::None);
|
|
}
|
|
llvm::Optional<MyIntEnum> symbolizeMyIntEnum(uint32_t value) {
|
|
switch (value) {
|
|
case 15: return MyIntEnum::Case15;
|
|
case 20: return MyIntEnum::Case20;
|
|
default: return llvm::None;
|
|
}
|
|
}
|
|
|
|
} // namespace Inner
|
|
} // namespace Outer
|
|
```
|
|
|
|
Similarly for the following `BitEnumAttr` definition:
|
|
|
|
```tablegen
|
|
def None: BitEnumAttrCase<"None", 0x0000>;
|
|
def Bit1: BitEnumAttrCase<"Bit1", 0x0001>;
|
|
def Bit2: BitEnumAttrCase<"Bit2", 0x0002>;
|
|
def Bit3: BitEnumAttrCase<"Bit3", 0x0004>;
|
|
|
|
def MyBitEnum: BitEnumAttr<"MyBitEnum", "An example bit enum",
|
|
[None, Bit1, Bit2, Bit3]>;
|
|
```
|
|
|
|
We can have:
|
|
|
|
```c++
|
|
// An example bit enum
|
|
enum class MyBitEnum : uint32_t {
|
|
None = 0,
|
|
Bit1 = 1,
|
|
Bit2 = 2,
|
|
Bit3 = 4,
|
|
};
|
|
|
|
llvm::Optional<MyBitEnum> symbolizeMyBitEnum(uint32_t);
|
|
std::string stringifyMyBitEnum(MyBitEnum);
|
|
llvm::Optional<MyBitEnum> symbolizeMyBitEnum(llvm::StringRef);
|
|
inline MyBitEnum operator|(MyBitEnum lhs, MyBitEnum rhs) {
|
|
return static_cast<MyBitEnum>(static_cast<uint32_t>(lhs) | static_cast<uint32_t>(rhs));
|
|
}
|
|
inline MyBitEnum operator&(MyBitEnum lhs, MyBitEnum rhs) {
|
|
return static_cast<MyBitEnum>(static_cast<uint32_t>(lhs) & static_cast<uint32_t>(rhs));
|
|
}
|
|
inline bool bitEnumContains(MyBitEnum bits, MyBitEnum bit) {
|
|
return (static_cast<uint32_t>(bits) & static_cast<uint32_t>(bit)) != 0;
|
|
}
|
|
|
|
namespace llvm {
|
|
template<> struct DenseMapInfo<::MyBitEnum> {
|
|
using StorageInfo = llvm::DenseMapInfo<uint32_t>;
|
|
|
|
static inline ::MyBitEnum getEmptyKey() {
|
|
return static_cast<::MyBitEnum>(StorageInfo::getEmptyKey());
|
|
}
|
|
|
|
static inline ::MyBitEnum getTombstoneKey() {
|
|
return static_cast<::MyBitEnum>(StorageInfo::getTombstoneKey());
|
|
}
|
|
|
|
static unsigned getHashValue(const ::MyBitEnum &val) {
|
|
return StorageInfo::getHashValue(static_cast<uint32_t>(val));
|
|
}
|
|
|
|
static bool isEqual(const ::MyBitEnum &lhs, const ::MyBitEnum &rhs) {
|
|
return lhs == rhs;
|
|
}
|
|
};
|
|
```
|
|
|
|
```c++
|
|
std::string stringifyMyBitEnum(MyBitEnum symbol) {
|
|
auto val = static_cast<uint32_t>(symbol);
|
|
// Special case for all bits unset.
|
|
if (val == 0) return "None";
|
|
|
|
llvm::SmallVector<llvm::StringRef, 2> strs;
|
|
if (1u & val) { strs.push_back("Bit1"); val &= ~1u; }
|
|
if (2u & val) { strs.push_back("Bit2"); val &= ~2u; }
|
|
if (4u & val) { strs.push_back("Bit3"); val &= ~4u; }
|
|
|
|
if (val) return "";
|
|
return llvm::join(strs, "|");
|
|
}
|
|
|
|
llvm::Optional<MyBitEnum> symbolizeMyBitEnum(llvm::StringRef str) {
|
|
// Special case for all bits unset.
|
|
if (str == "None") return MyBitEnum::None;
|
|
|
|
llvm::SmallVector<llvm::StringRef, 2> symbols;
|
|
str.split(symbols, "|");
|
|
|
|
uint32_t val = 0;
|
|
for (auto symbol : symbols) {
|
|
auto bit = llvm::StringSwitch<llvm::Optional<uint32_t>>(symbol)
|
|
.Case("Bit1", 1)
|
|
.Case("Bit2", 2)
|
|
.Case("Bit3", 4)
|
|
.Default(llvm::None);
|
|
if (bit) { val |= *bit; } else { return llvm::None; }
|
|
}
|
|
return static_cast<MyBitEnum>(val);
|
|
}
|
|
|
|
llvm::Optional<MyBitEnum> symbolizeMyBitEnum(uint32_t value) {
|
|
// Special case for all bits unset.
|
|
if (value == 0) return MyBitEnum::None;
|
|
|
|
if (value & ~(1u | 2u | 4u)) return llvm::None;
|
|
return static_cast<MyBitEnum>(value);
|
|
}
|
|
```
|
|
|
|
## Debugging Tips
|
|
|
|
### Run `mlir-tblgen` to see the generated content
|
|
|
|
TableGen syntax sometimes can be obscure; reading the generated content can be
|
|
a very helpful way to understand and debug issues. To build `mlir-tblgen`, run
|
|
`cmake --build . --target mlir-tblgen` in your build directory and find the
|
|
`mlir-tblgen` binary in the `bin/` subdirectory. All the supported generators
|
|
can be found via `mlir-tblgen --help`. For example, `--gen-op-decls` and
|
|
`--gen-op-defs` as explained in [Generated C++ code](#generated-c++-code).
|
|
|
|
To see the generated code, invoke `mlir-tblgen` with a specific generator by
|
|
providing include paths via `-I`. For example,
|
|
|
|
```sh
|
|
# To see op C++ class declaration
|
|
mlir-tblgen --gen-op-decls -I /path/to/mlir/include /path/to/input/td/file
|
|
# To see op C++ class definition
|
|
mlir-tblgen --gen-op-defs -I /path/to/mlir/include /path/to/input/td/file
|
|
# To see op documentation
|
|
mlir-tblgen --gen-dialect-doc -I /path/to/mlir/include /path/to/input/td/file
|
|
|
|
# To see op interface C++ class declaration
|
|
mlir-tblgen --gen-op-interface-decls -I /path/to/mlir/include /path/to/input/td/file
|
|
# To see op interface C++ class definition
|
|
mlir-tblgen --gen-op-interface-defs -I /path/to/mlir/include /path/to/input/td/file
|
|
# To see op interface documentation
|
|
mlir-tblgen --gen-op-interface-doc -I /path/to/mlir/include /path/to/input/td/file
|
|
```
|
|
|
|
## Appendix
|
|
|
|
### Requirements and existing mechanisms analysis
|
|
|
|
The op description should as declarative as possible to allow a wide range of
|
|
tools to work with them and query methods generated from them. In particular
|
|
this means specifying traits, constraints and shape inference information in
|
|
a way that is easily analyzable (e.g., avoid opaque calls to C++ functions where
|
|
possible).
|
|
|
|
We considered the approaches of several contemporary systems and focused on
|
|
requirements that were desirable:
|
|
|
|
* Ops registered using a registry separate from C++ code.
|
|
* Unknown ops are allowed in MLIR, so ops need not be registered. The
|
|
ability of the compiler to optimize those ops or graphs containing those
|
|
ops is constrained but correct.
|
|
* The current proposal does not include a runtime op description, but it
|
|
does not preclude such description, it can be added later.
|
|
* The op registry is essential for generating C++ classes that make
|
|
manipulating ops, verifying correct construction etc. in C++ easier by
|
|
providing a typed representation and accessors.
|
|
* The op registry will be defined in
|
|
[TableGen](https://llvm.org/docs/TableGen/index.html) and be used to
|
|
generate C++ classes and utility functions
|
|
(builder/verifier/parser/printer).
|
|
* TableGen is a modelling specification language used by LLVM's backends
|
|
and fits in well with trait-based modelling. This is an implementation
|
|
decision and there are alternative ways of doing this. But the
|
|
specification language is good for the requirements of modelling the
|
|
traits (as seen from usage in LLVM processor backend modelling) and easy
|
|
to extend, so a practical choice. If another good option comes up, we
|
|
will consider it.
|
|
* MLIR allows both defined and undefined ops.
|
|
* Defined ops should have fixed semantics and could have a corresponding
|
|
reference implementation defined using, for example, EDSC.
|
|
* Dialects are under full control of the dialect owner and normally live
|
|
with the framework of the dialect.
|
|
* The op's traits (e.g., commutative) are modelled along with the op in the
|
|
registry.
|
|
* The op's operand/return type constraints are modelled along with the op in
|
|
the registry (see [Shape inference](ShapeInference.md) discussion below),
|
|
this allows (e.g.) optimized concise syntax in textual dumps.
|
|
* Behavior of the op is documented along with the op with a summary and a
|
|
description. The description is written in markdown and extracted for
|
|
inclusion in the generated LangRef section of the dialect.
|
|
* The generic assembly form of printing and parsing is available as normal,
|
|
but a custom parser and printer can either be specified or automatically
|
|
generated from an optional string representation showing the mapping of the
|
|
"assembly" string to operands/type.
|
|
* Parser-level remappings (e.g., `eq` to enum) will be supported as part
|
|
of the parser generation.
|
|
* Matching patterns are specified separately from the op description.
|
|
* Contrasted with LLVM there is no "base" set of ops that every backend
|
|
needs to be aware of. Instead there are many different dialects and the
|
|
transformations/legalizations between these dialects form a graph of
|
|
transformations.
|
|
* Reference implementation may be provided along with the op definition.
|
|
|
|
* The reference implementation may be in terms of either standard ops or
|
|
other reference implementations.
|
|
|
|
TODO: document expectation if the dependent op's definition changes.
|
|
|
|
[TableGen]: https://llvm.org/docs/TableGen/index.html
|
|
[TableGenIntro]: https://llvm.org/docs/TableGen/LangIntro.html
|
|
[TableGenRef]: https://llvm.org/docs/TableGen/LangRef.html
|
|
[TableGenBackend]: https://llvm.org/docs/TableGen/BackEnds.html#introduction
|
|
[OpBase]: https://github.com/llvm/llvm-project/blob/master/mlir/include/mlir/IR/OpBase.td
|
|
[OpDefinitionsGen]: https://github.com/llvm/llvm-project/blob/master/mlir/tools/mlir-tblgen/OpDefinitionsGen.cpp
|
|
[EnumsGen]: https://github.com/llvm/llvm-project/blob/master/mlir/tools/mlir-tblgen/EnumsGen.cpp
|
|
[StringAttr]: LangRef.md#string-attribute
|
|
[IntegerAttr]: LangRef.md#integer-attribute
|
|
[AttrClasses]: https://github.com/llvm/llvm-project/blob/master/mlir/include/mlir/IR/Attributes.h
|