Operation Definition Specification (ODS)
In addition to specializing the mlir::Op
C++ template, MLIR also supports
defining operations and data types in a table-driven manner. This is achieved
via
TableGen, which is both a generic language and its tooling to
maintain records of domain-specific information. Facts regarding an operation
are specified concisely into a TableGen record, which will be expanded into an
equivalent mlir::Op
C++ template specialization at compiler build time.
This manual explains in detail all the available mechanisms for defining operations in such a table-driven manner. It aims to be a specification instead of a tutorial. Please refer to Quickstart tutorial to adding MLIR graph rewrite for the latter.
In addition to detailing each mechanism, this manual also tries to capture best practices. They are rendered as quoted bullet points.
Motivation ¶
MLIR allows pluggable dialects, and dialects contain, among others, a list of
operations. This open and extensible ecosystem leads to the “stringly” type IR
problem, e.g., repetitive string comparisons during optimization and analysis
passes, unintuitive accessor methods (e.g., generic/error prone getOperand(3)
vs self-documenting getStride()
) with more generic return types, verbose and
generic constructors without default arguments, verbose textual IR dumps, and so
on. Furthermore, operation verification is:
- best case: a central string-to-verification-function map,
- middle case: duplication of verification across the code base, or
- worst case: no verification functions.
The fix is to support defining ops in a table-driven manner. Then for each dialect, we can have a central place that contains everything you need to know about each op, including its constraints, custom assembly form, etc. This description is also used to generate helper functions and classes to allow building, verification, parsing, printing, analysis, and many more.
Benefits ¶
Compared to the C++ template, this table-driven approach has several benefits including but not limited to:
- Single source of truth: We strive to encode all facts regarding an operation into the record, so that readers don’t need to jump among code snippets to fully understand an operation.
- Removing boilerplate: We can automatically generate operand/attribute/result getter methods, operation build methods, operation verify methods, and many more utilities from the record. This greatly reduces the boilerplate needed for defining a new op.
- Facilitating auto-generation: The usage of these operation information records are by no means limited to op definition itself. We can use them to drive the auto-generation of many other components, like computation graph serialization.
TableGen Syntax ¶
We use TableGen as the language for specifying operation information. TableGen
itself just provides syntax for writing records; the syntax and constructs
allowed in a TableGen file (typically with the filename suffix .td
) can be found
here.
- TableGen
class
is similar to C++ class; it can be templated and subclassed. - TableGen
def
is similar to C++ object; it can be declared by specializing a TableGenclass
(e.g.,def MyDef : MyClass<...>;
) or completely independently (e.g.,def MyDef;
). It cannot be further templated or subclassed. - TableGen
dag
is a dedicated type for directed acyclic graph of elements. Adag
has one operator and zero or more arguments. Its syntax is(operator arg0, arg1, argN)
. The operator can be any TableGendef
; an argument can be anything, includingdag
itself. We can have names attached to both the operator and the arguments like(MyOp:$op_name MyArg:$arg_name)
.
Please see the language reference to learn about all the types and expressions supported by TableGen.
Operation Definition ¶
MLIR defines several common constructs to help operation definition and provide
their semantics via a special
TableGen backend:
OpDefinitionsGen
. These constructs are defined in
OpBase.td
. The main ones are:
- The
Op
class: It is the main construct for defining operations. All facts regarding the operation are specified when specializing this class, with the help of the following constructs. - The
Dialect
class: Operations belonging to one logical group are placed in the same dialect. TheDialect
class contains dialect-level information. - The
OpTrait
class hierarchy: They are used to specify special properties and constraints of the operation, including whether the operation has side effect or whether its output has the same shape as the input. - The
ins
/outs
marker: These are two special markers builtin to theOpDefinitionsGen
backend. They lead to the definitions of operands/attributes and results respectively. - The
TypeConstraint
class hierarchy: They are used to specify the constraints over operands or results. A notable subclass hierarchy isType
, which stands for constraints for common C++ types. - The
AttrConstraint
class hierarchy: They are used to specify the constraints over attributes. A notable subclass hierarchy isAttr
, which stands for constraints for attributes whose values are of common types. - The
Property
class hierarchy: They are used to specify non-attribute-backed properties that are inherent to operations. This will be expanded to aPropertyConstraint
class or something similar in the future.
An operation is defined by specializing the Op
class with concrete contents
for all the fields it requires. For example, tf.AvgPool
is defined as
def TF_AvgPoolOp : TF_Op<"AvgPool", [NoMemoryEffect]> {
let summary = "Performs average pooling on the input.";
let description = [{
Each entry in `output` is the mean of the corresponding size `ksize`
window in `value`.
}];
let arguments = (ins
TF_FpTensor:$value,
ConfinedAttr<I64ArrayAttr, [ArrayMinCount<4>]>:$ksize,
ConfinedAttr<I64ArrayAttr, [ArrayMinCount<4>]>:$strides,
TF_AnyStrAttrOf<["SAME", "VALID"]>:$padding,
DefaultValuedAttr<TF_ConvertDataFormatAttr, "NHWC">:$data_format
);
let results = (outs
TF_FpTensor:$output
);
TF_DerivedOperandTypeAttr T = TF_DerivedOperandTypeAttr<0>;
}
In the following we describe all the fields needed. Please see the definition of
the Op
class for the complete list of fields supported.
Operation name ¶
The operation name is a unique identifier for the operation within MLIR, e.g.,
tf.Add
for addition operation in the TensorFlow dialect. This is the
equivalent of the mnemonic in assembly language. It is used for parsing and
printing in the textual format. It is also used for pattern matching in graph
rewrites.
The full operation name is composed of the dialect name and the op name, with
the former provided via the dialect and the latter provided as the second
template parameter to the Op
class.
Operation documentation ¶
This includes both a one-line summary
and a longer human-readable
description
. They will be used to drive automatic generation of dialect
documentation. They need to be provided in the operation’s definition body:
let summary = "...";
let description = [{
...
}];
description
should be written in Markdown syntax.
Placing the documentation at the beginning is recommended since it helps in understanding the operation.
- Place documentation at the beginning of the operation definition.
- The summary should be short and concise. It should be a one-liner starting with a capital letter and without trailing punctuation. Put expanded explanation in the description.
Operation arguments ¶
There are three kinds of arguments: operands, attributes, and properties. Operands are runtime values produced by other ops; while attributes and properties are compile-time known constant values, including two categories:
Natural attributes: these attributes affect the behavior of the operations (e.g., padding for convolution);
Derived attributes: these attributes are not needed to define the operation but are instead derived from information of the operation. E.g., the output shape of type. This is mostly used for convenience interface generation or interaction with other frameworks/translation.
All derived attributes should be materializable as an Attribute. That is, even though they are not materialized, it should be possible to store as an attribute.
Properties are similar to attributes, except that they are not stored within the MLIR context but are stored inline with the operation.
Operands, attributes, and properties are specified inside the dag
-typed
arguments
, led by ins
:
let arguments = (ins
<type-constraint>:$<operand-name>,
...
<attr-constraint>:$<attr-name>,
...
<property-constraint>:$<property-name>,
);
Here <type-constraint>
is a TableGen def
from the TypeConstraint
class
hierarchy. Similarly, <attr-constraint>
is a TableGen def
from the
AttrConstraint
class hierarchy and <property-constraint>
is a subclass
of Property
(though a PropertyConstraint
hierarchy is planned).
See
Constraints for more information.
There is no requirements on the relative order of operands and attributes; they
can mix freely. The relative order of operands themselves matters. From each
named argument a named getter will be generated that returns the argument with
the return type (in the case of attributes the return type will be constructed
from the storage type, while for operands it will be Value
). Each attribute’s
raw value (e.g., as stored) can also be accessed via generated <name>Attr
getters for use in transformation passes where the more user-friendly return
type is less suitable.
All the arguments should be named to:
- provide documentation,
- drive auto-generation of getter methods, and
- provide a handle to reference for other places like constraints.
Variadic operands ¶
To declare a variadic operand, wrap the TypeConstraint
for the operand with
Variadic<...>
.
Normally operations have no variadic operands or just one variadic operand. For
the latter case, it is easy to deduce which dynamic operands are for the static
variadic operand definition. However, if an operation has more than one variable
length operands (either optional or variadic), it would be impossible to
attribute dynamic operands to the corresponding static variadic operand
definitions without further information from the operation. Therefore, either
the SameVariadicOperandSize
or AttrSizedOperandSegments
trait is needed to
indicate that all variable length operands have the same number of dynamic
values.
VariadicOfVariadic operands ¶
To declare a variadic operand that has a variadic number of sub-ranges, wrap the
TypeConstraint
for the operand with VariadicOfVariadic<..., "<segment-attribute-name>">
.
The second field of the VariadicOfVariadic
is the name of an I32ElementsAttr
argument that contains the sizes of the variadic sub-ranges. This attribute will
be used when determining the size of sub-ranges, or when updating the size of
sub-ranges.
Optional operands ¶
To declare an optional operand, wrap the TypeConstraint
for the operand with
Optional<...>
.
Normally operations have no optional operands or just one optional operand. For
the latter case, it is easy to deduce which dynamic operands are for the static
operand definition. However, if an operation has more than one variable length
operands (either optional or variadic), it would be impossible to attribute
dynamic operands to the corresponding static variadic operand definitions
without further information from the operation. Therefore, either the
SameVariadicOperandSize
or AttrSizedOperandSegments
trait is needed to
indicate that all variable length operands have the same number of dynamic
values.
Optional attributes ¶
To declare an optional attribute, wrap the AttrConstraint
for the attribute
with OptionalAttr<...>
.
Attributes with default values ¶
To declare an attribute with a default value, wrap the AttrConstraint
for the
attribute with DefaultValuedAttr<..., "...">
.
The second parameter to DefaultValuedAttr
should be a string containing the
C++ default value. For example, a float default value should be specified as
like "0.5f"
, and an integer array default value should be specified as like
"{1, 2, 3}"
.
The generated operation printing function will not print default-valued attributes when the attribute value is equal to the default.
Confining attributes ¶
ConfinedAttr
is provided as a general mechanism to help modelling further
constraints on attributes beyond the ones brought by value types. You can use
ConfinedAttr
to compose complex constraints out of more primitive ones. For
example, a 32-bit integer attribute whose minimum value must be 10 can be
expressed as ConfinedAttr<I32Attr, [IntMinValue<10>]>
.
Right now, the following primitive constraints are supported:
IntMinValue<N>
: Specifying an integer attribute to be greater than or equal toN
IntMaxValue<N>
: Specifying an integer attribute to be less than or equal toN
IntNEQValue<N>
: Specifying an integer attribute to be not equal toN
IntPositive
: Specifying an integer attribute whose value is positiveIntNonNegative
: Specifying an integer attribute whose value is non-negativeArrayMinCount<N>
: Specifying an array attribute to have at leastN
elementsArrayMaxCount<N>
: Specifying an array attribute to have at mostN
elementsArrayCount<N>
: Specifying an array attribute to have exactlyN
elementsDenseArrayCount<N>
: Specifying a dense array attribute to have exactlyN
elementsDenseArrayStrictlyPositive<arrayType>
: Specifying a dense array attribute of typearrayType
to have all positive elementsDenseArrayStrictlyNonNegative<arrayType>
: Specifying a dense array attribute of typearrayType
to have all non-negative elementsDenseArraySorted<arrayType>
: Specifying a dense array attribute of typearrayType
to have elements in non-decreasing orderDenseArrayStrictlySorted<arrayType>
: Specifying a dense array attribute of typearrayType
to have elements in increasing orderIntArrayNthElemEq<I, N>
: Specifying an integer array attribute’sI
-th element to be equal toN
IntArrayNthElemMinValue<I, N>
: Specifying an integer array attribute’sI
-th element to be greater than or equal toN
IntArrayNthElemMaxValue<I, N>
: Specifying an integer array attribute’sI
-th element to be less than or equal toN
IntArrayNthElemInRange<I, M, N>
: Specifying an integer array attribute’sI
-th element to be greater than or equal toM
and less than or equal toN
IsNullAttr
: Specifying an optional attribute which must be empty
TODO: Design and implement more primitive constraints
Optional and default-valued properties ¶
To declare a property with a default value, use DefaultValuedProperty<..., "...">
.
If the property’s storage data type is different from its interface type,
for example, in the case of array properties (which are stored as SmallVector
s
but use ArrayRef
as an interface type), add the storage-type equivalent
of the default value as the third argument.
To declare an optional property, use OptionalProperty<...>
.
This wraps the underlying property in an std::optional
and gives it a
default value of std::nullopt
.
Combining constraints ¶
AllAttrOf
is provided to allow combination of multiple constraints which
must all hold.
For example:
def OpAllAttrConstraint1 : TEST_Op<"all_attr_constraint_of1"> {
let arguments = (ins I64ArrayAttr:$attr);
let results = (outs I32);
}
def OpAllAttrConstraint2 : TEST_Op<"all_attr_constraint_of2"> {
let arguments = (ins I64ArrayAttr:$attr);
let results = (outs I32);
}
def Constraint0 : AttrConstraint<
CPred<"::llvm::cast<::mlir::IntegerAttr>(::llvm::cast<ArrayAttr>($_self)[0]).getInt() == 0">,
"[0] == 0">;
def Constraint1 : AttrConstraint<
CPred<"::llvm::cast<::mlir::IntegerAttr>(::llvm::cast<ArrayAttr>($_self)[1]).getInt() == 1">,
"[1] == 1">;
def : Pat<(OpAllAttrConstraint1
AllAttrOf<[Constraint0, Constraint1]>:$attr),
(OpAllAttrConstraint2 $attr)>;
Operation regions ¶
The regions of an operation are specified inside of the dag
-typed regions
,
led by region
:
let regions = (region
<region-constraint>:$<region-name>,
...
);
Variadic regions ¶
Similar to the Variadic
class used for variadic operands and results,
VariadicRegion<...>
can be used for regions. Variadic regions can currently
only be specified as the last region in the regions list.
Operation results ¶
Similar to operands, results are specified inside the dag
-typed results
, led
by outs
:
let results = (outs
<type-constraint>:$<result-name>,
...
);
Variadic results ¶
Similar to variadic operands, Variadic<...>
can also be used for results. And
similarly, SameVariadicResultSize
for multiple variadic results in the same
operation.
Operation successors ¶
For terminator operations, the successors are specified inside of the
dag
-typed successors
, led by successor
:
let successors = (successor
<successor-constraint>:$<successor-name>,
...
);
Variadic successors ¶
Similar to the Variadic
class used for variadic operands and results,
VariadicSuccessor<...>
can be used for successors. Variadic successors can
currently only be specified as the last successor in the successor list.
Operation traits and constraints ¶
Traits are operation properties that affect syntax or semantics. MLIR C++ models
various traits in the mlir::OpTrait
namespace.
Both operation traits,
interfaces,
and constraints involving multiple operands/attributes/results are provided as
the third template parameter to the Op
class. They should be deriving from
the OpTrait
class. See
Constraints for more information.
Builder methods ¶
For each operation, there are a few builders automatically generated based on the arguments and returns types. For example, given the following op definition:
def MyOp : ... {
let arguments = (ins
I32:$i32_operand,
F32:$f32_operand,
...,
I32Attr:$i32_attr,
F32Attr:$f32_attr,
...
I32Property:$i32_prop,
...
);
let results = (outs
I32:$i32_result,
F32:$f32_result,
...
);
}
The following builders are generated:
// All result-types/operands/attributes have one aggregate parameter.
static void build(OpBuilder &odsBuilder, OperationState &odsState,
TypeRange 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, ...,
int32_t i32_prop);
// 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, ...,
int32_t i32_prop, ...);
// Each operand/attribute has a separate parameter but result type is aggregate.
static void build(OpBuilder &odsBuilder, OperationState &odsState,
TypeRange resultTypes,
Value i32_operand, Value f32_operand, ...,
IntegerAttr i32_attr, FloatAttr f32_attr, ...,
int32_t i32_prop, ...);
// All operands/attributes have aggregate parameters.
// Generated if return type can be inferred.
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, the 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.
ODS will generate a builder that doesn’t require the return type specified if
- Op implements InferTypeOpInterface interface;
- All return types are either buildable types or are the same as a given
operand (e.g.,
AllTypesMatch
constraint between operand and result);
And there may potentially exist other builders depending on the specific op; please refer to the generated C++ file for the complete list.
Custom builder methods ¶
However, if the above cases cannot satisfy all needs, you can define additional
convenience build methods in the builders
field as follows.
def MyOp : Op<"my_op", []> {
let arguments = (ins F32Attr:$attr);
let builders = [
OpBuilder<(ins "float":$val)>
];
}
The builders
field is a list of custom builders that are added to the Op
class. In this example, we provide a convenience builder that takes a floating
point value instead of an attribute. The ins
prefix is common to many function
declarations in ODS, which use a TableGen
dag
. What
follows is a comma-separated list of types (quoted string) and names prefixed
with the $
sign. This will generate the declaration of a builder method that
looks like:
class MyOp : /*...*/ {
/*...*/
static void build(::mlir::OpBuilder &builder, ::mlir::OperationState &state,
float val);
};
Note that the method has two additional leading arguments. These arguments are
useful to construct the operation. In particular, the method must populate
state
with attributes, operands, regions and result types of the operation to
be constructed. builder
can be used to construct any IR objects that belong to
the Op, such as types or nested operations. Since the type and name are
generated as is in the C++ code, they should be valid C++ constructs for a type
(in the namespace of the Op) and an identifier (e.g., class
is not a valid
identifier).
Implementations of the builder can be provided directly in ODS, using TableGen code block as follows.
def MyOp : Op<"my_op", []> {
let arguments = (ins F32Attr:$attr);
let builders = [
OpBuilder<(ins "float":$val), [{
$_state.addAttribute("attr", $_builder.getF32FloatAttr(val));
}]>
];
}
The equivalents of builder
and state
arguments are available as $_builder
and $_state
special variables. The named arguments listed in the ins
part
are available directly, e.g. val
. The body of the builder will be generated by
substituting special variables and should otherwise be valid C++. While there is
no limitation on the code size, we encourage one to define only short builders
inline in ODS and put definitions of longer builders in C++ files.
Finally, if some arguments need a default value, they can be defined using
CArg
to wrap the type and this value as follows.
def MyOp : Op<"my_op", []> {
let arguments = (ins F32Attr:$attr);
let builders = [
OpBuilder<(ins CArg<"float", "0.5f">:$val), [{
$_state.addAttribute("attr", $_builder.getF32FloatAttr(val));
}]>
];
}
The generated code will use default value in the declaration, but not in the definition, as required by C++.
/// Header file.
class MyOp : /*...*/ {
/*...*/
static void build(::mlir::OpBuilder &builder, ::mlir::OperationState &state,
float val = 0.5f);
};
/// Source file.
MyOp::build(::mlir::OpBuilder &builder, ::mlir::OperationState &state,
float val) {
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 specified on various entities of the op. To perform additional verification, you can use
let hasVerifier = 1;
let hasRegionVerifier = 1;
This will generate LogicalResult verify()
/LogicalResult verifyRegions()
method declarations on the op class that can be defined with any additional
verification constraints. For verificaiton which needs to access the nested
operations, you should use hasRegionVerifier
to ensure that it won’t access
any ill-formed operation. Except that, The other verifications can be
implemented with hasVerifier
. Check the next section for the execution order
of these verification methods.
Verification Ordering ¶
The verification of an operation involves several steps,
- StructuralOpTrait will be verified first, they can be run independently.
verifyInvariants
which is constructed by ODS, it verifies the type, attributes, .etc.- Other Traits/Interfaces that have marked their verifier as
verifyTrait
orverifyWithRegions=0
. - Custom verifier which is defined in the op and has been marked
hasVerifier=1
If an operation has regions, then it may have the second phase,
- Traits/Interfaces that have marked their verifier as
verifyRegionTrait
orverifyWithRegions=1
. This implies the verifier needs to access the operations in its regions. - Custom verifier which is defined in the op and has been marked
hasRegionVerifier=1
Note that the second phase will be run after the operations in the region are verified. Verifiers further down the order can rely on certain invariants being verified by a previous verifier and do not need to re-verify them.
Emitting diagnostics in custom verifiers ¶
Custom verifiers should avoid printing operations using custom operation
printers, because they require the printed operation (and sometimes its parent
operation) to be verified first. In particular, when emitting diagnostics,
custom verifiers should use the Error
severity level, which prints operations
in generic form by default, and avoid using lower severity levels (Note
,
Remark
, Warning
).
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:
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.
- Any inherent attributes that are not used elsewhere in the format are
printed as part of the attribute dictionary unless a
prop-dict
is present. - Discardable attributes are always part of the
attr-dict
.
attr-dict-with-keyword
- Represents the attribute dictionary of the operation, but prefixes the
dictionary with an
attributes
keyword.
- Represents the attribute dictionary of the operation, but prefixes the
dictionary with an
prop-dict
- Represents the properties of the operation converted to a dictionary.
- Any property or inherent attribute that are not used elsewhere in the format are parsed and printed as part of this dictionary.
- If present, the
attr-dict
will not contain any inherent attributes.
custom < UserDirective > ( Params )
- Represents a custom directive implemented by the user in C++.
- See the Custom Directives section below for more details.
functional-type ( inputs , outputs )
- Formats the
inputs
andoutputs
arguments as a function type. - The constraints on
inputs
andoutputs
are the same as theinput
of thetype
directive.
- Formats the
oilist ( `keyword` elements | `otherKeyword` elements ...)
- Represents an optional order-independent list of clauses. Each clause has a keyword and corresponding assembly format.
- Each clause can appear 0 or 1 time (in any order).
- Only literals, types and variables can be used within an oilist element.
- All the variables must be optional or variadic.
operands
- Represents all of the operands of an operation.
ref ( input )
- Represents a reference to a variable or directive, that must have
already been resolved, that may be used as a parameter to a
custom
directive. - Used to pass previously parsed entities to custom directives.
- The input may be any directive or variable, aside from
functional-type
andcustom
.
- Represents a reference to a variable or directive, that must have
already been resolved, that may be used as a parameter to a
regions
- Represents all of the regions 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, theoperands
directive, or theresults
directive.
qualified ( type_or_attribute )
- Wraps a
type
directive or an attribute parameter. - Used to force printing the type or attribute prefixed with its dialect
and mnemonic. For example the
vector.multi_reduction
operation has akind
attribute ; by default the declarative assembly will print:vector.multi_reduction <minf>, ...
but usingqualified($kind)
in the declarative assembly format will print it instead as:vector.multi_reduction #vector.kind<minf>, ...
.
- Wraps a
Literals ¶
A literal is either a keyword or punctuation surrounded by ``.
The following are the set of valid punctuation:
:
, ,
, =
, <
, >
, (
, )
, {
, }
, [
, ]
, ->
, ?
, +
, *
The following are valid whitespace punctuation:
\n
,
The \n
literal emits a newline an indents to the start of the operation. An
example is shown below:
let assemblyFormat = [{
`{` `\n` ` ` ` ` `this_is_on_a_newline` `\n` `}` attr-dict
}];
%results = my.operation {
this_is_on_a_newline
}
An empty literal `` may be used to remove a space that is inserted implicitly
after certain literal elements, such as )
/]
/etc. For example, “]
” may
result in an output of ]
it is not the last element in the format. “]
``”
would trim the trailing space in this situation.
Variables ¶
A variable is an entity that has been registered on the operation itself, i.e.
an argument(attribute or operand), region, 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.
Custom Directives ¶
The declarative assembly format specification allows for handling a large majority of the common cases when formatting an operation. For the operations that require or desire specifying parts of the operation in a form not supported by the declarative syntax, custom directives may be specified. A custom directive essentially allows for users to use C++ for printing and parsing subsections of an otherwise declaratively specified format. Looking at the specification of a custom directive above:
custom-directive ::= `custom` `<` UserDirective `>` `(` Params `)`
A custom directive has two main parts: The UserDirective
and the Params
. A
custom directive is transformed into a call to a print*
and a parse*
method
when generating the C++ code for the format. The UserDirective
is an
identifier used as a suffix to these two calls, i.e., custom<MyDirective>(...)
would result in calls to parseMyDirective
and printMyDirective
within the
parser and printer respectively. Params
may be any combination of variables
(i.e. Attribute, Operand, Successor, etc.), type directives, attr-dict
, and
strings of C++ code. The type directives must refer to a variable, but that
variable need not also be a parameter to the custom directive.
The arguments to the parse<UserDirective>
method are firstly a reference to
the OpAsmParser
(OpAsmParser &
), and secondly a set of output parameters
corresponding to the parameters specified in the format. The mapping of
declarative parameter to parse
method argument is detailed below:
- Attribute Variables
- Single:
<Attribute-Storage-Type>(e.g. Attribute) &
- Optional:
<Attribute-Storage-Type>(e.g. Attribute) &
- Single:
- Operand Variables
- Single:
OpAsmParser::UnresolvedOperand &
- Optional:
Optional<OpAsmParser::UnresolvedOperand> &
- Variadic:
SmallVectorImpl<OpAsmParser::UnresolvedOperand> &
- VariadicOfVariadic:
SmallVectorImpl<SmallVector<OpAsmParser::UnresolvedOperand>> &
- Single:
- Ref Directives
- A reference directive is passed to the parser using the same mapping as
the input operand. For example, a single region would be passed as a
Region &
.
- A reference directive is passed to the parser using the same mapping as
the input operand. For example, a single region would be passed as a
- Region Variables
- Single:
Region &
- Variadic:
SmallVectorImpl<std::unique_ptr<Region>> &
- Single:
- Successor Variables
- Single:
Block *&
- Variadic:
SmallVectorImpl<Block *> &
- Single:
- Type Directives
- Single:
Type &
- Optional:
Type &
- Variadic:
SmallVectorImpl<Type> &
- VariadicOfVariadic:
SmallVectorImpl<SmallVector<Type>> &
- Single:
attr-dict
Directive:NamedAttrList &
When a variable is optional, the value should only be specified if the variable
is present. Otherwise, the value should remain None
or null.
The arguments to the print<UserDirective>
method is firstly a reference to the
OpAsmPrinter
(OpAsmPrinter &
), second the op (e.g. FooOp op
which can be
Operation *op
alternatively), and finally a set of output parameters
corresponding to the parameters specified in the format. The mapping of
declarative parameter to print
method argument is detailed below:
- Attribute Variables
- Single:
<Attribute-Storage-Type>(e.g. Attribute)
- Optional:
<Attribute-Storage-Type>(e.g. Attribute)
- Single:
- Operand Variables
- Single:
Value
- Optional:
Value
- Variadic:
OperandRange
- VariadicOfVariadic:
OperandRangeRange
- Single:
- Ref Directives
- A reference directive is passed to the printer using the same mapping as
the input operand. For example, a single region would be passed as a
Region &
.
- A reference directive is passed to the printer using the same mapping as
the input operand. For example, a single region would be passed as a
- Region Variables
- Single:
Region &
- Variadic:
MutableArrayRef<Region>
- Single:
- Successor Variables
- Single:
Block *
- Variadic:
SuccessorRange
- Single:
- Type Directives
- Single:
Type
- Optional:
Type
- Variadic:
TypeRange
- VariadicOfVariadic:
TypeRangeRange
- Single:
attr-dict
Directive:DictionaryAttr
When a variable is optional, the provided value may be null. When a variable is
referenced in a custom directive parameter using ref
, it is passed in by
value. Referenced variables to print<UserDirective>
are passed as the same as
bound variables, but referenced variables to parse<UserDirective>
are passed
like to the printer.
A custom directive can take a string of C++ code as a parameter. The code is
pasted verbatim in the calls to the custom parser and printers, with the
substitutions $_builder
and $_ctxt
. String literals can be used to
parameterize custom directives.
Optional Groups ¶
In certain situations operations may have “optional” information, e.g.
attributes or an empty set of variadic operands. In these situations a section
of the assembly format can be marked as optional
based on the presence of this
information. An optional group is defined as follows:
optional-group: `(` then-elements `)` (`:` `(` else-elements `)`)? `?`
The elements of an optional group have the following requirements:
- The first element of
then-elements
must either be a attribute, literal, operand, property, or region.- This is because the first element must be optionally parsable.
- If a property is used, it must have an
optionalParser
defined and have a default value.
- Exactly one argument variable or type directive within either
then-elements
orelse-elements
must be marked as the anchor of the group.- The anchor is the element whose presence controls which elements should be printed/parsed.
- An element is marked as the anchor by adding a trailing
^
. - The first element is not required to be the anchor of the group.
- When a non-variadic region anchors a group, the detector for printing the group is if the region is empty.
- Literals, variables, custom directives, and type directives are the only
valid elements within the group.
- Any attribute variable may be used, but only optional or default-valued attributes can be marked as the anchor. A default-valued anchor is considered present if it holds a value other than the default.
- Only variadic or optional results and operand arguments and can be used.
- All region variables can be used. When a non-variable length region is used, if the group is not present the region is empty.
An example of an operation with an optional group is func.return
, which has a
variadic number of operands.
def ReturnOp : ... {
let arguments = (ins Variadic<AnyType>:$operands);
// We only print the operands and types if there are a non-zero number
// of operands.
let assemblyFormat = "attr-dict ($operands^ `:` type($operands))?";
}
Unit Attributes ¶
In MLIR, the
unit
Attribute is special in that it
only has one possible value, i.e. it derives meaning from its existence. When a
unit attribute is used to anchor an optional group and is not the first element
of the group, the presence of the unit attribute can be directly correlated with
the presence of the optional group itself. As such, in these situations the unit
attribute will not be printed or present in the output and will be automatically
inferred when parsing by the presence of the optional group itself.
For example, the following operation:
def FooOp : ... {
let arguments = (ins UnitAttr:$is_read_only);
let assemblyFormat = "attr-dict (`is_read_only` $is_read_only^)?";
}
would be formatted as such:
// When the unit attribute is present:
foo.op is_read_only
// When the unit attribute is not present:
foo.op
The same logic applies to a UnitProperty
.
Optional “else” Group ¶
Optional groups also have support for an “else” group of elements. These are
elements that are parsed/printed if the anchor
element of the optional group
is not present. Unlike the main element group, the “else” group has no
restriction on the first element and none of the elements may act as the
anchor
for the optional. An example is shown below:
def FooOp : ... {
let arguments = (ins UnitAttr:$foo);
let assemblyFormat = "attr-dict (`foo_is_present` $foo^):(`foo_is_absent`)?";
}
would be formatted as such:
// When the `foo` attribute is present:
foo.op foo_is_present
// When the `foo` attribute is not present:
foo.op foo_is_absent
Requirements ¶
The format specification has a certain set of requirements that must be adhered to:
- The output and operation name are never shown as they are fixed and cannot be altered.
- All operands within the operation must appear within the format, either
individually or with the
operands
directive. - All regions within the operation must appear within the format, either
individually or with the
regions
directive. - All successors within the operation must appear within the format, either
individually or with the
successors
directive. - All operand and result types must appear within the format using the various
type
directives, either individually or with theoperands
orresults
directives. - Unless all non-attribute properties appear in the format, the
prop-dict
directive must be present. - The
attr-dict
directive must always be present. - 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.
- Note that
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
, TypesMatchWith
, SameTypeOperands
, and
SameOperandsAndResultType
.
- InferTypeOpInterface
Operations that implement InferTypeOpInterface
can omit their result types in
their assembly format since the result types can be inferred from the operands.
hasCanonicalizer
¶
This boolean field indicate whether canonicalization patterns have been defined
for this operation. If it is 1
, then ::getCanonicalizationPatterns()
should
be defined.
hasCanonicalizeMethod
¶
When this boolean field is set to true
, it indicates that the op implements a
canonicalize
method for simple “matchAndRewrite” style canonicalization
patterns. If hasCanonicalizer
is 0, then an implementation of
::getCanonicalizationPatterns()
is implemented to call this function.
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.
Extra definitions ¶
When defining base op classes in TableGen that are inherited many times by
different ops, users may want to provide common definitions of utility and
interface functions. However, many of these definitions may not be desirable or
possible in extraClassDeclaration
, which append them to the op’s C++ class
declaration. In these cases, users can add an extraClassDefinition
to define
code that is added to the generated source file inside the op’s C++ namespace.
The substitution $cppClass
is replaced by the op’s C++ class name.
Generated C++ code ¶
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 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. 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 Adaptor
as well as an alias
Adaptor
inside the op class.
Operand adaptors can be used in function templates that also process operations:
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(Adaptor<AddOp>(newOperands));
/*...*/
}
Sharded Operation Definitions ¶
Large dialects with many operations may struggle with C++ compile time of
generated op definitions, due to large compilation units. mlir-tblgen
provides the ability to shard op definitions by splitting them up evenly
by passing -op-shard-count
to -gen-op-defs
and -gen-op-decls
. The tool
will generate a single include file for the definitions broken up by
GET_OP_DEFS_${N}
where ${N}
is the shard number. A shard can be compiled in
a single compilation unit by adding a file like this to your dialect library:
#include "mlir/IR/Operation.h"
// Add any other required includes.
// Utilities shared by generated op definitions: custom directive parsers,
// printers, etc.
#include "OpUtils.h"
#define GET_OP_DEFS_0
#include "MyDialectOps.cpp.inc"
Note: this requires restructing shared utility functions within the dialect
library so they can be shared by multiple compilation units. I.e. instead of
defining static
methods in the same source file, you should declare them in a
shared header and define them in their own source file.
The op registration hooks are also sharded, because the template instantiation can take a very long time to compile. Operations should be registered in your dialect like:
void MyDialect::initialize() {
registerMyDialectOperations(this);
}
CMake and Bazel functions are included to make sharding dialects easier.
Assuming you have organized your operation utility functions into their own
header, define a file that looks like the one above, but without the #define
:
// MyDialectOps.cpp
#include "mlir/IR/Operation.h"
#include "OpUtils.h"
#include "MyDialectOps.cpp.inc"
In CMake, remove the manual mlir_tablegen
invocations and replace them with:
set(LLVM_TARGET_DEFINITIONS MyDialectOps.td)
add_sharded_ops(MyDialectOps 8) # shard the op definitions by 8
add_mlir_library(MyDialect
MyDialect.cpp
MyDialectOpDefs.cpp
${SHARDED_SRCS}
DEPENDS
MLIRTestOpsShardGen
)
This will automatically duplicate the MyDialectOps.cpp
source file and add the
#define
up the number of shards indicated.
It is recommended that any out-of-line op member functions (like verifiers) be
defined in a separate source file. In this example, it is called
MyDialectOpDefs.cpp
.
In Bazel, remove the -gen-op-defs
and -gen-op-decls
invocations, and add
gentbl_sharded_ops(
name = "MyDialectOpSrcs",
hdr_out = "MyDialectOps.h.inc",
shard_count = 8,
sharder = "//mlir:mlir-src-sharder",
src_file = "MyDialectOps.cpp",
src_out = "MyDialectOps.cpp.inc",
tblgen = "//mlir:mlir-tblgen",
td_file = "MyDialectOps.td",
deps = [":MyDialectOpsTdFiles"],
)
cc_library(
name = "MyDialect",
srcs = glob(["MyDialect/*.cpp"]) + [":MyDialectOpSrcs"]
)
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
as 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 and 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.
Multi-entity constraints are modeled as PredOpTrait
(a subclass of OpTrait
)
in
OpBase.td
.A bunch of constraint primitives are provided to help
specification. See
OpBase.td
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.
Traits are modeled as NativeOpTrait
(a subclass of OpTrait
) in
OpBase.td
. 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:
CPred
: the primitive leaf predicate.- 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
:
$_builder
will be replaced by amlir::Builder
instance so that you can access common build methods.$_op
will be replaced by the current operation so that you can access information of the current operation.$_self
will be replaced with the entity this predicate is attached to. E.g.,BoolAttr
is an attribute constraint that wraps aCPred<"$_self.isa<BoolAttr>()">
. Then forBoolAttr:$attr
,$_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., forF32
inF32:$operand
, its$_self
will be expanded asoperand(...).getType()
.
TODO: Reconsider the leading symbol for special placeholders. Eventually we want
to allow referencing operand/result $-name
s; such $-name
s 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 $_self
as the special placeholder to be
replaced by the current attribute attr
at expansion time.
For more complicated predicates, you can wrap it in a single CPred
, or you can
use predicate combiners to combine them. For example, to write the constraint
that an attribute attr
is a 32-bit or 64-bit integer, you can write it as
And<[
CPred<"$_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
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
bool HasSomeProperty(Attribute attr) { ... }
and then define the op as:
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 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 helper getters) as well as a method
to convert between the internal storage and the helper method.
Attribute decorators ¶
There are a few important attribute adapters/decorators/modifiers that can be applied to ODS attributes to specify common additional properties like optionality, default values, etc.:
DefaultValuedAttr
: specifies the default value for an attribute.OptionalAttr
: specifies an attribute as optional.ConfinedAttr
: adapts an attribute with further constraints.AllAttrOf
: adapts an attribute with multiple constraints.
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: IntEnumAttr
, and BitEnumAttr
.
IntEnumAttr
: each enum case is an integer, the attribute is stored as aIntegerAttr
in the op.BitEnumAttr
: each enum case is a either the empty case, a single bit, or a group of single bits, and the attribute is stored as aIntegerAttr
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
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
:
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
:
namespace Outer {
namespace Inner {
// An example int enum
enum class MyIntEnum : uint32_t {
Case15 = 15,
Case20 = 20,
};
std::optional<MyIntEnum> symbolizeMyIntEnum(uint32_t);
llvm::StringRef ConvertToString(MyIntEnum);
std::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
:
namespace Outer {
namespace Inner {
llvm::StringRef ConvertToString(MyIntEnum val) {
switch (val) {
case MyIntEnum::Case15: return "Case15";
case MyIntEnum::Case20: return "Case20";
}
return "";
}
std::optional<MyIntEnum> ConvertToEnum(llvm::StringRef str) {
return llvm::StringSwitch<std::optional<MyIntEnum>>(str)
.Case("Case15", MyIntEnum::Case15)
.Case("Case20", MyIntEnum::Case20)
.Default(std::nullopt);
}
std::optional<MyIntEnum> symbolizeMyIntEnum(uint32_t value) {
switch (value) {
case 15: return MyIntEnum::Case15;
case 20: return MyIntEnum::Case20;
default: return std::nullopt;
}
}
} // namespace Inner
} // namespace Outer
Similarly for the following BitEnumAttr
definition:
def None: I32BitEnumAttrCaseNone<"None">;
def Bit0: I32BitEnumAttrCaseBit<"Bit0", 0, "tagged">;
def Bit1: I32BitEnumAttrCaseBit<"Bit1", 1>;
def Bit2: I32BitEnumAttrCaseBit<"Bit2", 2>;
def Bit3: I32BitEnumAttrCaseBit<"Bit3", 3>;
def MyBitEnum: BitEnumAttr<"MyBitEnum", "An example bit enum",
[None, Bit0, Bit1, Bit2, Bit3]>;
We can have:
// An example bit enum
enum class MyBitEnum : uint32_t {
None = 0,
Bit0 = 1,
Bit1 = 2,
Bit2 = 4,
Bit3 = 8,
};
std::optional<MyBitEnum> symbolizeMyBitEnum(uint32_t);
std::string stringifyMyBitEnum(MyBitEnum);
std::optional<MyBitEnum> symbolizeMyBitEnum(llvm::StringRef);
inline constexpr MyBitEnum operator|(MyBitEnum a, MyBitEnum b) {
return static_cast<MyBitEnum>(static_cast<uint32_t>(a) | static_cast<uint32_t>(b));
}
inline constexpr MyBitEnum operator&(MyBitEnum a, MyBitEnum b) {
return static_cast<MyBitEnum>(static_cast<uint32_t>(a) & static_cast<uint32_t>(b));
}
inline constexpr MyBitEnum operator^(MyBitEnum a, MyBitEnum b) {
return static_cast<MyBitEnum>(static_cast<uint32_t>(a) ^ static_cast<uint32_t>(b));
}
inline constexpr MyBitEnum operator~(MyBitEnum bits) {
// Ensure only bits that can be present in the enum are set
return static_cast<MyBitEnum>(~static_cast<uint32_t>(bits) & static_cast<uint32_t>(15u));
}
inline constexpr bool bitEnumContainsAll(MyBitEnum bits, MyBitEnum bit) {
return (bits & bit) == bit;
}
inline constexpr bool bitEnumContainsAny(MyBitEnum bits, MyBitEnum bit) {
return (static_cast<uint32_t>(bits) & static_cast<uint32_t>(bit)) != 0;
}
inline constexpr MyBitEnum bitEnumClear(MyBitEnum bits, MyBitEnum bit) {
return bits & ~bit;
}
inline std::string stringifyEnum(MyBitEnum enumValue) {
return stringifyMyBitEnum(enumValue);
}
template <typename EnumType>
::std::optional<EnumType> symbolizeEnum(::llvm::StringRef);
template <>
inline ::std::optional<MyBitEnum> symbolizeEnum<MyBitEnum>(::llvm::StringRef str) {
return symbolizeMyBitEnum(str);
}
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;
}
};
std::string stringifyMyBitEnum(MyBitEnum symbol) {
auto val = static_cast<uint32_t>(symbol);
assert(15u == (15u | val) && "invalid bits set in bit enum");
// Special case for all bits unset.
if (val == 0) return "None";
llvm::SmallVector<llvm::StringRef, 2> strs;
if (1u == (1u & val)) { strs.push_back("tagged"); }
if (2u == (2u & val)) { strs.push_back("Bit1"); }
if (4u == (4u & val)) { strs.push_back("Bit2"); }
if (8u == (8u & val)) { strs.push_back("Bit3"); }
return llvm::join(strs, "|");
}
std::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<std::optional<uint32_t>>(symbol)
.Case("tagged", 1)
.Case("Bit1", 2)
.Case("Bit2", 4)
.Case("Bit3", 8)
.Default(std::nullopt);
if (bit) { val |= *bit; } else { return std::nullopt; }
}
return static_cast<MyBitEnum>(val);
}
std::optional<MyBitEnum> symbolizeMyBitEnum(uint32_t value) {
// Special case for all bits unset.
if (value == 0) return MyBitEnum::None;
if (value & ~static_cast<uint32_t>(15u)) return std::nullopt;
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.
To see the generated code, invoke mlir-tblgen
with a specific generator by
providing include paths via -I
. For example,
# 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 ¶
Reporting deprecation in TableGen ¶
Classes/defs can be marked as deprecated by using the Deprecate
helper class,
e.g.,
def OpTraitA : NativeOpTrait<"OpTraitA">, Deprecated<"use `bar` instead">;
would result in marking OpTraitA
as deprecated and mlir-tblgen can emit a
warning (default) or error (depending on -on-deprecated
flag) to make
deprecated state known.
Reporting deprecation in C++ ¶
TableGen generated C++ entities, such as classes, functions or methods, can be
marked as deprecated using the CppDeprecated
mixin:
def MyOp : Op<MyDialect, "my.op">, CppDeprecated<"use 'your.op' instead">;
This differs to the deprecation mechanic for TableGen, in that no warning is emitted by mlir-tblgen. Rather, a warning with the given reason is emitted by the C++ compiler on use of the given entity.
To allow more convenient syntax, helper classes exist for TableGen classes which are commonly used as anonymous definitions. These currently include:
DeprecatedOpBuilder
: Can be used in place ofOpBuilder
with the same arguments except taking the reason as first argument, e.g.DeprecatedOpBuilder<"use 'build' with foo instead", (ins "int":$bar)>
Note: Support for the CppDeprecated
mechanism has to be implemented by
every code generator separately.
Requirements and existing mechanisms analysis ¶
The op description should be 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 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.
- 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 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.
- Parser-level remappings (e.g.,
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.