Data layout information allows the compiler to answer questions related to how a value of a particular type is stored in memory. For example, the size of a value or its address alignment requirements. It enables, among others, the generation of various linear memory addressing schemes for containers of abstract types and deeper reasoning about vectors.
The data layout subsystem is designed to scale to MLIR's open type and operation system. At the top level, it consists of:
Built-in types are handled specially to decrease the overall query cost. Similarly, built-in ModuleOp
supports data layouts without going through the interface.
Following MLIR's nested structure, data layout properties are scoped to regions belonging to either operations that implement the DataLayoutOpInterface
or ModuleOp
operations. Such scoping operations partially control the data layout properties and may have attributes that affect them, typically organized in a data layout specification.
Types may have a different data layout in different scopes, including scopes that are nested in other scopes such as modules contained in other modules. At the same time, within the given scope excluding any nested scope, a given type has fixed data layout properties. Types are also expected to have a default, “natural” data layout in case they are used outside of any operation that provides data layout scope for them. This ensures that data layout queries always have a valid result.
The information necessary to compute layout properties can be combined from nested scopes. For example, an outer scope can define layout properties for a subset of types while inner scopes define them for a disjoint subset, or scopes can progressively relax alignment requirements on a type. This mechanism is supported by the notion of data layout compatibility: the layout defined in a nested scope is expected to be compatible with that of the outer scope. MLIR does not prescribe what compatibility means for particular ops and types but provides hooks for them to provide target- and type-specific checks. For example, one may want to only allow relaxation of alignment constraints (i.e., smaller alignment) in nested modules or, alternatively, one may require nested modules to fully redefine all constraints of the outer scope.
Data layout compatibility is also relevant during IR transformation. Any transformation that affects the data layout scoping operation is expected to maintain data layout compatibility. It is under responsibility of the transformation to ensure it is indeed the case.
Data layout property queries can be performed on the special object -- DataLayout
-- which can be created for the given scoping operation. These objects allow one to interface with the data layout infrastructure and query properties of given types in the scope of the object. The signature of DataLayout
class is as follows.
class DataLayout { public: explicit DataLayout(DataLayoutOpInterface scope); unsigned getTypeSize(Type type) const; unsigned getTypeSizeInBits(Type type) const; unsigned getTypeABIAlignment(Type type) const; unsigned getTypePreferredAlignment(Type type) const; };
The user can construct the DataLayout
object for the scope of interest. Since the data layout properties are fixed in the scope, they will be computed only once upon first request and cached for further use. Therefore, DataLayout(op.getParentOfType<DataLayoutOpInterface>()).getTypeSize(type)
is considered an anti-pattern since it discards the cache after use. Because of caching, a DataLayout
object returns valid results as long as the data layout properties of enclosing scopes remain the same, that is, as long as none of the ancestor operations are modified in a way that affects data layout. After such a modification, the user is expected to create a fresh DataLayout
object. To aid with this, DataLayout
asserts that the scope remains identical if MLIR is compiled with assertions enabled.
Extensibility of the data layout modeling is provided through a set of MLIR Interfaces.
Data layout specification is an attribute that is conceptually a collection of key-value pairs called data layout specification entries. Data layout specification attributes implement the DataLayoutSpecInterface
, described below. Each entry is itself an attribute that implements the DataLayoutEntryInterface
. Entries have a key, either a Type
or a StringAttr
, and a value. Keys are used to associate entries with specific types or dialects: when handling a data layout properties request, a type or a dialect can only see the specification entries relevant to them and must go through the supplied DataLayout
object for any recursive query. This supports and enforces better composability because types cannot (and should not) understand layout details of other types. Entry values are arbitrary attributes, specific to the type.
For example, a data layout specification may be an actual list of pairs with simple custom syntax resembling the following:
#my_dialect.layout_spec< #my_dialect.layout_entry<!my_dialect.type, size=42>, #my_dialect.layout_entry<"my_dialect.endianness", "little">, #my_dialect.layout_entry<!my_dialect.vector, prefer_large_alignment>>
The exact details of the specification and entry attributes, as well as their syntax, are up to implementations.
We use the notion of type class throughout the data layout subsystem. It corresponds to the C++ class of the given type, e.g., IntegerType
for built-in integers. MLIR does not have a mechanism to represent type classes in the IR. Instead, data layout entries contain specific instances of a type class, for example, IntegerType{signedness=signless, bitwidth=8}
(or i8
in the IR) or IntegerType{signedness=unsigned, bitwidth=32}
(or ui32
in the IR). When handling a data layout property query, a type class will be supplied with all entries with keys belonging to this type class. For example, IntegerType
will see the entries for i8
, si16
and ui32
, but will not see those for f32
or memref<?xi32>
(neither will MemRefType
see the entry for i32
). This allows for type-specific “interpolation” behavior where a type class can compute data layout properties of any specific type instance given properties of other instances. Using integers as an example again, their alignment could be computed by taking that of the closest from above integer type with power-of-two bitwidth.
[include “Interfaces/DataLayoutAttrInterface.md”]
Operations that define a scope for data layout queries, and that can be used to create a DataLayout
object, are expected to implement the DataLayoutOpInterface
. Such ops must provide at least a way of obtaining the data layout specification. The specification need not be necessarily attached to the operation as an attribute and may be constructed on-the-fly; it is only fetched once per DataLayout
object and cached. Such ops may also provide custom handlers for data layout queries that provide results without forwarding the queries down to specific types or post-processing the results returned by types in target- or scope-specific ways. These custom handlers make it possible for scoping operations to (re)define data layout properties for types without having to modify the types themselves, e.g., when types are defined in another dialect.
[include “Interfaces/DataLayoutOpInterface.md”]
Type classes that intend to handle data layout queries themselves are expected to implement the DataLayoutTypeInterface
. This interface provides overridable hooks for each data layout query. Each of these hooks is supplied with the type instance, a DataLayout
object suitable for recursive queries, and a list of data layout queries relevant for the type class. It is expected to provide a valid result even if the list of entries is empty. These hooks do not have access to the operation in the scope of which the query is handled and should use the supplied entries instead.
[include “Interfaces/DataLayoutTypeInterface.md”]
For data layout entries that are not related to a particular type class, the key of the entry is an Identifier that belongs to some dialect. In this case, the dialect is expected to implement the DataLayoutDialectInterface
. This dialect provides hooks for verifying the validity of the entry value attributes and for and the compatibility of nested entries.
Two versions of hooks are provided for sizes: in bits and in bytes. The version in bytes has a default implementation that derives the size in bytes by rounding up the result of division of the size in bits by 8. Types exclusively targeting architectures with different assumptions can override this. Operations can redefine this for all types, providing scoped versions for cases of byte sizes other than eight without having to modify types, including built-in types.
The overall flow of a data layout property query is as follows.
DataLayout
at the given scope. The constructor fetches the data layout specification and combines it with those of enclosing scopes (layouts are expected to be compatible).DataLayout::query(Type ty)
.DataLayout
has a cached response, this response is returned immediately.DataLayout
to the closest layout scoping operation. If it implements DataLayoutOpInterface
, then the query is forwarded toDataLayoutOpInterface::query(ty, *this, relevantEntries)
where the relevant entries are computed as described above. If it does not implement DataLayoutOpInterface
, it must be a ModuleOp
, and the query is forwarded to DataLayoutTypeInterface::query(dataLayout, relevantEntries)
after casting ty
to the type interface.query
hook is reimplemented by the op interface, the query is handled further down to DataLayoutTypeInterface::query(dataLayout, relevantEntries)
after casting ty
to the type interface. If the type does not implement the interface, an unrecoverable fatal error is produced.DataLayout.
The default implementation of the data layout interfaces directly handles queries for a subset of built-in types.
Built-in ModuleOp
allows at most one attribute that implements DataLayoutSpecInterface
. It does not implement the entire interface for efficiency and layering reasons. Instead, DataLayout
can be constructed for ModuleOp
and handles modules transparently alongside other operations that implement the interface.
The following describes the default properties of built-in types.
The size of built-in integers and floats in bytes is computed as ceildiv(bitwidth, 8)
. The ABI alignment of integer types with bitwidth below 64 and of the float types is the closest from above power-of-two number of bytes. The ABI alignment of integer types with bitwidth 64 and above is 4 bytes (32 bits).
The size of built-in vectors is computed by first rounding their number of elements in the innermost dimension to the closest power-of-two from above, then getting the total number of elements, and finally multiplying it with the element size. For example, vector<3xi32>
and vector<4xi32>
have the same size. So do vector<2x3xf32>
and vector<2x4xf32>
, but vector<3x4xf32>
and vector<4x4xf32>
have different sizes. The ABI and preferred alignment of vector types is computed by taking the innermost dimension of the vector, rounding it up to the closest power-of-two, taking a product of that with element size in bytes, and rounding the result up again to the closest power-of-two.
Note: these values are selected for consistency with the default data layout in LLVM, which MLIR assumed until the introduction of proper data layout modeling, and with the modeling of n-D vectors. They may change in the future.
index
typeIndex type is an integer type used for target-specific size information in, e.g., memref
operations. Its data layout is parameterized by a single integer data layout entry that specifies its bitwidth. For example,
module attributes { dlti.dl_spec = #dlti.dl_spec< #dlti.dl_entry<index, 32> >} {}
specifies that index
has 32 bits. All other layout properties of index
match those of the integer type with the same bitwidth defined above.
In absence of the corresponding entry, index
is assumed to be a 64-bit integer.
complex
typeBy default complex type is treated like a 2 element structure of its given element type. This is to say that each of its elements are aligned to their preferred alignment, the entire complex type is also aligned to this preference, and the complex type size includes the possible padding between elements to enforce alignment.
The default data layout assumes 8-bit bytes.
The DLTI dialect provides the attributes implementing DataLayoutSpecInterface
and DataLayoutEntryInterface
, as well as a dialect attribute that can be used to attach the specification to a given operation. The verifier of this attribute triggers those of the specification and checks the compatibility of nested specifications.