//===- AffineOps.td - Affine operation definitions ---------*- tablegen -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// Defines MLIR affine operations.
//
//===----------------------------------------------------------------------===//
#ifndef AFFINE_OPS
#define AFFINE_OPS
include "mlir/Dialect/Arith/IR/ArithBase.td"
include "mlir/Dialect/Affine/IR/AffineMemoryOpInterfaces.td"
include "mlir/Interfaces/ControlFlowInterfaces.td"
include "mlir/Interfaces/InferTypeOpInterface.td"
include "mlir/Interfaces/LoopLikeInterface.td"
include "mlir/Interfaces/SideEffectInterfaces.td"
def Affine_Dialect : Dialect {
let name = "affine";
let cppNamespace = "::mlir::affine";
let hasConstantMaterializer = 1;
let dependentDialects = ["arith::ArithDialect", "ub::UBDialect"];
}
// Base class for Affine dialect ops.
class Affine_Op<string mnemonic, list<Trait> traits = []> :
Op<Affine_Dialect, mnemonic, traits>;
// Require regions to have affine.yield.
def ImplicitAffineTerminator
: SingleBlockImplicitTerminator<"AffineYieldOp">;
def AffineApplyOp : Affine_Op<"apply", [Pure]> {
let summary = "affine apply operation";
let description = [{
The `affine.apply` operation applies an [affine mapping](#affine-maps)
to a list of SSA values, yielding a single SSA value. The number of
dimension and symbol arguments to `affine.apply` must be equal to the
respective number of dimensional and symbolic inputs to the affine mapping;
the affine mapping has to be one-dimensional, and so the `affine.apply`
operation always returns one value. The input operands and result must all
have ‘index’ type.
Example:
```mlir
#map10 = affine_map<(d0, d1) -> (d0 floordiv 8 + d1 floordiv 128)>
...
%1 = affine.apply #map10 (%s, %t)
// Inline example.
%2 = affine.apply affine_map<(i)[s0] -> (i+s0)> (%42)[%n]
```
}];
let arguments = (ins AffineMapAttr:$map, Variadic<Index>:$mapOperands);
let results = (outs Index);
// TODO: The auto-generated builders should check to see if the return type
// has a constant builder. That way we wouldn't need to explicitly specify the
// result types here.
let builders = [
OpBuilder<(ins "ArrayRef<AffineExpr> ":$exprList,"ValueRange":$mapOperands),
[{
build($_builder, $_state, $_builder.getIndexType(),
AffineMap::inferFromExprList(exprList, $_builder.getContext())
.front(), mapOperands);
}]>
];
let extraClassDeclaration = [{
/// Returns the affine map to be applied by this operation.
AffineMap getAffineMap() { return getMap(); }
/// Returns the affine value map computed from this operation.
AffineValueMap getAffineValueMap();
/// Returns true if the result of this operation can be used as dimension id
/// in the region of the closest surrounding op with trait AffineScope.
bool isValidDim();
/// Returns true if the result of this operation can be used as dimension id
/// within 'region', i.e., for all its uses with `region`.
bool isValidDim(Region *region);
/// Returns true if the result of this operation is a symbol in the region
/// of the closest surrounding op that has the trait AffineScope.
bool isValidSymbol();
/// Returns true if the result of this operation is a symbol for all its
/// uses in `region`.
bool isValidSymbol(Region *region);
/// Returns all dimension operands.
ValueRange getDimOperands() {
return OperandRange{getOperands().begin(),
getOperands().begin() + getMap().getNumDims()};
}
/// Returns all symbol operands.
ValueRange getSymbolOperands() {
return OperandRange{getOperands().begin() + getMap().getNumDims(),
getOperands().end()};
}
}];
let hasCanonicalizer = 1;
let hasCustomAssemblyFormat = 1;
let hasFolder = 1;
let hasVerifier = 1;
}
def AffineForOp : Affine_Op<"for",
[AttrSizedOperandSegments, AutomaticAllocationScope,
ImplicitAffineTerminator, ConditionallySpeculatable,
RecursiveMemoryEffects, DeclareOpInterfaceMethods<LoopLikeOpInterface,
["getLoopInductionVars", "getLoopLowerBounds", "getLoopSteps",
"getLoopUpperBounds", "getYieldedValuesMutable",
"replaceWithAdditionalYields"]>,
DeclareOpInterfaceMethods<RegionBranchOpInterface,
["getEntrySuccessorOperands"]>]> {
let summary = "for operation";
let description = [{
Syntax:
```
operation ::= `affine.for` ssa-id `=` lower-bound `to` upper-bound
(`step` integer-literal)? `{` op* `}`
lower-bound ::= `max`? affine-map-attribute dim-and-symbol-use-list | shorthand-bound
upper-bound ::= `min`? affine-map-attribute dim-and-symbol-use-list | shorthand-bound
shorthand-bound ::= ssa-id | `-`? integer-literal
```
The `affine.for` operation represents an affine loop nest. It has one region
containing its body. This region must contain one block that terminates with
[`affine.yield`](#affineyield-mliraffineyieldop). *Note:* when
`affine.for` is printed in custom format, the terminator is omitted. The
block has one argument of [`index`](Builtin.md/#indextype) type that
represents the induction variable of the loop.
The `affine.for` operation executes its body a number of times iterating
from a lower bound to an upper bound by a stride. The stride, represented by
`step`, is a positive constant integer which defaults to "1" if not present.
The lower and upper bounds specify a half-open range: the range includes the
lower bound but does not include the upper bound.
The lower and upper bounds of a `affine.for` operation are represented as an
application of an affine mapping to a list of SSA values passed to the map.
The [same restrictions](#restrictions-on-dimensions-and-symbols) hold for
these SSA values as for all bindings of SSA values to dimensions and
symbols.
The affine mappings for the bounds may return multiple results, in which
case the `max`/`min` keywords are required (for the lower/upper bound
respectively), and the bound is the maximum/minimum of the returned values.
There is no semantic ambiguity, but MLIR syntax requires the use of these
keywords to make things more obvious to human readers.
Many upper and lower bounds are simple, so MLIR accepts two custom form
syntaxes: the form that accepts a single 'ssa-id' (e.g. `%N`) is shorthand
for applying that SSA value to a function that maps a single symbol to
itself, e.g., `()[s]->(s)()[%N]`. The integer literal form (e.g. `-42`) is
shorthand for a nullary mapping function that returns the constant value
(e.g. `()->(-42)()`).
Example showing reverse iteration of the inner loop:
```mlir
#map57 = affine_map<(d0)[s0] -> (s0 - d0 - 1)>
func.func @simple_example(%A: memref<?x?xf32>, %B: memref<?x?xf32>) {
%N = dim %A, 0 : memref<?x?xf32>
affine.for %i = 0 to %N step 1 {
affine.for %j = 0 to %N { // implicitly steps by 1
%0 = affine.apply #map57(%j)[%N]
%tmp = call @F1(%A, %i, %0) : (memref<?x?xf32>, index, index)->(f32)
call @F2(%tmp, %B, %i, %0) : (f32, memref<?x?xf32>, index, index)->()
}
}
return
}
```
`affine.for` can also operate on loop-carried variables (`iter_args`) and
return the final values after loop termination. The initial values of the
variables are passed as additional SSA operands to the `affine.for`
following the operands for the loop's lower and upper bounds. The
operation's region has equivalent arguments for each variable representing
the value of the variable at the current iteration.
The region must terminate with an `affine.yield` that passes all the current
iteration variables to the next iteration, or to the `affine.for`'s results
if at the last iteration. For `affine.for`'s that execute zero iterations, the
initial values of the loop-carried variables (corresponding to the SSA
operands) will be the op's results.
For example, to sum-reduce a memref:
```mlir
func.func @reduce(%buffer: memref<1024xf32>) -> (f32) {
// Initial sum set to 0.
%sum_0 = arith.constant 0.0 : f32
// iter_args binds initial values to the loop's region arguments.
%sum = affine.for %i = 0 to 10 step 2
iter_args(%sum_iter = %sum_0) -> (f32) {
%t = affine.load %buffer[%i] : memref<1024xf32>
%sum_next = arith.addf %sum_iter, %t : f32
// Yield current iteration sum to next iteration %sum_iter or to %sum
// if final iteration.
affine.yield %sum_next : f32
}
return %sum : f32
}
```
```mlir
%res:2 = affine.for %i = 0 to 128 iter_args(%arg0 = %init0, %arg1 = %init1)
-> (index, index) {
%y0 = arith.addi %arg0, %c1 : index
%y1 = arith.addi %arg1, %c2 : index
affine.yield %y0, %y1 : index, index
}
```
If the `affine.for` defines any values, a yield terminator must be
explicitly present. The number and types of the "affine.for" results must
match the initial values in the `iter_args` binding and the yield operands.
}];
let arguments = (ins Variadic<Index>:$lowerBoundOperands,
Variadic<Index>:$upperBoundOperands,
Variadic<AnyType>:$inits,
AffineMapAttr:$lowerBoundMap,
AffineMapAttr:$upperBoundMap,
IndexAttr:$step);
let results = (outs Variadic<AnyType>:$results);
let regions = (region SizedRegion<1>:$region);
let skipDefaultBuilders = 1;
let builders = [
OpBuilder<(ins "int64_t":$lowerBound, "int64_t":$upperBound,
CArg<"int64_t", "1">:$step, CArg<"ValueRange", "std::nullopt">:$iterArgs,
CArg<"function_ref<void(OpBuilder &, Location, Value, ValueRange)>",
"nullptr">:$bodyBuilder)>,
OpBuilder<(ins "ValueRange":$lbOperands, "AffineMap":$lbMap,
"ValueRange":$ubOperands, "AffineMap":$ubMap, CArg<"int64_t", "1">:$step,
CArg<"ValueRange", "std::nullopt">:$iterArgs,
CArg<"function_ref<void(OpBuilder &, Location, Value, ValueRange)>",
"nullptr">:$bodyBuilder)>
];
let extraClassDeclaration = [{
/// Defining the function type we use for building the body of affine.for.
using BodyBuilderFn =
function_ref<void(OpBuilder &, Location, Value, ValueRange)>;
BlockArgument getInductionVar() { return getBody()->getArgument(0); }
Block::BlockArgListType getRegionIterArgs() {
return getBody()->getArguments().drop_front();
}
/// Returns operands for the lower and upper bound maps with the operands
/// for the lower bound map in front of those for the upper bound map.
operand_range getControlOperands();
/// Returns information about the lower bound as a single object.
AffineBound getLowerBound();
/// Returns information about the upper bound as a single object.
AffineBound getUpperBound();
/// Returns loop step.
int64_t getStepAsInt() { return getStep().getSExtValue(); }
/// Set lower bound. The new bound must have the same number of operands as
/// the current bound map. Otherwise, 'replaceForLowerBound' should be used.
void setLowerBound(ValueRange operands, AffineMap map);
/// Set upper bound. The new bound must not have more operands than the
/// current bound map. Otherwise, 'replaceForUpperBound' should be used.
void setUpperBound(ValueRange operands, AffineMap map);
/// Set loop step.
void setStep(int64_t step) {
assert(step > 0 && "step has to be a positive integer constant");
setStep(APInt(/*numBits=*/64, step, /*isSigned=*/true));
}
/// Returns number of region arguments for loop-carried values.
unsigned getNumRegionIterArgs() {
return getBody()->getNumArguments() - 1;
}
/// Number of operands controlling the loop: lb and ub.
unsigned getNumControlOperands() {
return getOperation()->getNumOperands() - getNumIterOperands();
}
/// Get the number of loop-carried values.
unsigned getNumIterOperands();
/// Returns true if the lower bound is constant.
bool hasConstantLowerBound();
/// Returns true if the upper bound is constant.
bool hasConstantUpperBound();
/// Returns true if both bounds are constant.
bool hasConstantBounds() {
return hasConstantLowerBound() && hasConstantUpperBound();
}
/// Returns the value of the constant lower bound.
/// Fails assertion if the bound is non-constant.
int64_t getConstantLowerBound();
/// Returns the value of the constant upper bound. The upper bound is
/// exclusive. Fails assertion if the bound is non-constant.
int64_t getConstantUpperBound();
/// Sets the lower bound to the given constant value.
void setConstantLowerBound(int64_t value);
/// Sets the upper bound to the given constant value.
void setConstantUpperBound(int64_t value);
/// Returns true if both the lower and upper bound have the same operand
/// lists (same operands in the same order).
bool matchingBoundOperandList();
/// Interface method for ConditionallySpeculatable.
Speculation::Speculatability getSpeculatability();
}];
let hasCanonicalizer = 1;
let hasCustomAssemblyFormat = 1;
let hasFolder = 1;
let hasRegionVerifier = 1;
}
def AffineIfOp : Affine_Op<"if",
[ImplicitAffineTerminator, RecursivelySpeculatable,
RecursiveMemoryEffects, NoRegionArguments,
DeclareOpInterfaceMethods<RegionBranchOpInterface>
]> {
let summary = "if-then-else operation";
let description = [{
Syntax:
```
operation ::= `affine.if` if-op-cond `{` op* `}` (`else` `{` op* `}`)?
if-op-cond ::= integer-set-attr dim-and-symbol-use-list
```
The `affine.if` operation restricts execution to a subset of the loop
iteration space defined by an integer set (a conjunction of affine
constraints). A single `affine.if` may end with an optional `else` clause.
The condition of the `affine.if` is represented by an
[integer set](#integer-sets) (a conjunction of affine constraints),
and the SSA values bound to the dimensions and symbols in the integer set.
The [same restrictions](#restrictions-on-dimensions-and-symbols) hold for
these SSA values as for all bindings of SSA values to dimensions and
symbols.
The `affine.if` operation contains two regions for the "then" and "else"
clauses. `affine.if` may return results that are defined in its regions.
The values defined are determined by which execution path is taken. Each
region of the `affine.if` must contain a single block with no arguments,
and be terminated by `affine.yield`. If `affine.if` defines no values,
the `affine.yield` can be left out, and will be inserted implicitly.
Otherwise, it must be explicit. If no values are defined, the else block
may be empty (i.e. contain no blocks).
Example:
```mlir
#set = affine_set<(d0, d1)[s0]: (d0 - 10 >= 0, s0 - d0 - 9 >= 0,
d1 - 10 >= 0, s0 - d1 - 9 >= 0)>
func.func @reduced_domain_example(%A, %X, %N) : (memref<10xi32>, i32, i32) {
affine.for %i = 0 to %N {
affine.for %j = 0 to %N {
%0 = affine.apply #map42(%j)
%tmp = call @S1(%X, %i, %0)
affine.if #set(%i, %j)[%N] {
%1 = affine.apply #map43(%i, %j)
call @S2(%tmp, %A, %i, %1)
}
}
}
return
}
```
Example with an explicit yield (initialization with edge padding):
```mlir
#interior = affine_set<(i, j) : (i - 1 >= 0, j - 1 >= 0, 10 - i >= 0, 10 - j >= 0)> (%i, %j)
func.func @pad_edges(%I : memref<10x10xf32>) -> (memref<12x12xf32) {
%O = alloc memref<12x12xf32>
affine.parallel (%i, %j) = (0, 0) to (12, 12) {
%1 = affine.if #interior (%i, %j) {
%2 = load %I[%i - 1, %j - 1] : memref<10x10xf32>
affine.yield %2
} else {
%2 = arith.constant 0.0 : f32
affine.yield %2 : f32
}
affine.store %1, %O[%i, %j] : memref<12x12xf32>
}
return %O
}
```
}];
let arguments = (ins Variadic<AnyType>);
let results = (outs Variadic<AnyType>:$results);
let regions = (region SizedRegion<1>:$thenRegion, AnyRegion:$elseRegion);
let skipDefaultBuilders = 1;
let builders = [
OpBuilder<(ins "IntegerSet":$set, "ValueRange":$args,
"bool":$withElseRegion)>,
OpBuilder<(ins "TypeRange":$resultTypes, "IntegerSet":$set,
"ValueRange":$args, "bool":$withElseRegion)>,
];
let extraClassDeclaration = [{
static StringRef getConditionAttrStrName() { return "condition"; }
IntegerSet getIntegerSet();
void setIntegerSet(IntegerSet newSet);
/// Sets the integer set with its operands.
void setConditional(IntegerSet set, ValueRange operands);
/// Returns true if an else block exists.
bool hasElse() { return !getElseRegion().empty(); }
Block *getThenBlock() {
assert(!getThenRegion().empty() && "Unexpected empty 'then' region.");
return &getThenRegion().front();
}
Block *getElseBlock() {
assert(hasElse() && "Empty 'else' region.");
return &getElseRegion().front();
}
OpBuilder getThenBodyBuilder() {
assert(!getThenRegion().empty() && "Unexpected empty 'then' region.");
Block &body = getThenRegion().front();
return OpBuilder(&body, std::prev(body.end()));
}
OpBuilder getElseBodyBuilder() {
assert(hasElse() && "No 'else' block");
Block &body = getElseRegion().front();
return OpBuilder(&body, std::prev(body.end()));
}
}];
let hasCanonicalizer = 1;
let hasCustomAssemblyFormat = 1;
let hasFolder = 1;
let hasVerifier = 1;
}
class AffineLoadOpBase<string mnemonic, list<Trait> traits = []> :
Affine_Op<mnemonic, !listconcat(traits,
[DeclareOpInterfaceMethods<AffineReadOpInterface>,
DeclareOpInterfaceMethods<AffineMapAccessInterface>,
MemRefsNormalizable])> {
let arguments = (ins Arg<AnyMemRef, "the reference to load from",
[MemRead]>:$memref,
Variadic<Index>:$indices,
AffineMapAttr:$map);
code extraClassDeclarationBase = [{
/// Returns the operand index of the memref.
unsigned getMemRefOperandIndex() { return 0; }
void setMemRef(Value value) { setOperand(getMemRefOperandIndex(), value); }
/// Returns the affine map used to index the memref for this operation.
AffineMapAttr getAffineMapAttr() {
return getProperties().map;
}
static StringRef getMapAttrStrName() { return "map"; }
}];
}
def AffineLoadOp : AffineLoadOpBase<"load"> {
let summary = "affine load operation";
let description = [{
Syntax:
```
operation ::= ssa-id `=` `affine.load` ssa-use `[` multi-dim-affine-map-of-ssa-ids `]` `:` memref-type
```
The `affine.load` op reads an element from a memref, where the index
for each memref dimension is an affine expression of loop induction
variables and symbols. The output of `affine.load` is a new value with the
same type as the elements of the memref. An affine expression of loop IVs
and symbols must be specified for each dimension of the memref. The keyword
`symbol` can be used to indicate SSA identifiers which are symbolic.
Example 1:
```mlir
%1 = affine.load %0[%i0 + 3, %i1 + 7] : memref<100x100xf32>
```
Example 2: Uses `symbol` keyword for symbols `%n` and `%m`.
```mlir
%1 = affine.load %0[%i0 + symbol(%n), %i1 + symbol(%m)] : memref<100x100xf32>
```
}];
let results = (outs AnyType:$result);
let builders = [
/// Builds an affine load op with the specified map and operands.
OpBuilder<(ins "AffineMap":$map, "ValueRange":$operands)>,
/// Builds an affine load op with an identity map and operands.
OpBuilder<(ins "Value":$memref, CArg<"ValueRange", "{}">:$indices)>,
/// Builds an affine load op with the specified map and its operands.
OpBuilder<(ins "Value":$memref, "AffineMap":$map,
"ValueRange":$mapOperands)>
];
let extraClassDeclaration = extraClassDeclarationBase;
let hasCanonicalizer = 1;
let hasCustomAssemblyFormat = 1;
let hasFolder = 1;
let hasVerifier = 1;
}
class AffineMinMaxOpBase<string mnemonic, list<Trait> traits = []> :
Op<Affine_Dialect, mnemonic, traits> {
let arguments = (ins AffineMapAttr:$map, Variadic<Index>:$operands);
let results = (outs Index);
let extraClassDeclaration = [{
static StringRef getMapAttrStrName() { return "map"; }
AffineMap getAffineMap() { return getMap(); }
ValueRange getMapOperands() { return getOperands(); }
ValueRange getDimOperands() {
return OperandRange{getOperands().begin(),
getOperands().begin() + getMap().getNumDims()};
}
ValueRange getSymbolOperands() {
return OperandRange{getOperands().begin() + getMap().getNumDims(),
getOperands().end()};
}
}];
let hasCustomAssemblyFormat = 1;
let hasFolder = 1;
let hasCanonicalizer = 1;
let hasVerifier = 1;
}
def AffineMinOp : AffineMinMaxOpBase<"min", [Pure]> {
let summary = "min operation";
let description = [{
Syntax:
```
operation ::= ssa-id `=` `affine.min` affine-map-attribute dim-and-symbol-use-list
```
The `affine.min` operation applies an [affine mapping](#affine-expressions)
to a list of SSA values, and returns the minimum value of all result
expressions. The number of dimension and symbol arguments to `affine.min`
must be equal to the respective number of dimensional and symbolic inputs to
the affine mapping; the `affine.min` operation always returns one value. The
input operands and result must all have 'index' type.
Example:
```mlir
%0 = affine.min affine_map<(d0)[s0] -> (1000, d0 + 512, s0)> (%arg0)[%arg1]
```
}];
}
def AffineMaxOp : AffineMinMaxOpBase<"max", [Pure]> {
let summary = "max operation";
let description = [{
The `affine.max` operation computes the maximum value result from a multi-result
affine map.
Example:
```mlir
%0 = affine.max (d0) -> (1000, d0 + 512) (%i0) : index
```
}];
}
def AffineParallelOp : Affine_Op<"parallel",
[AutomaticAllocationScope, ImplicitAffineTerminator, RecursivelySpeculatable,
RecursiveMemoryEffects, DeclareOpInterfaceMethods<LoopLikeOpInterface>,
MemRefsNormalizable]> {
let summary = "multi-index parallel band operation";
let description = [{
The `affine.parallel` operation represents a hyper-rectangular affine
parallel band, defining zero or more SSA values for its induction variables.
It has one region capturing the parallel band body. The induction variables
are represented as arguments of this region. These SSA values always have
type index, which is the size of the machine word. The strides, represented
by steps, are positive constant integers which defaults to "1" if not
present. The lower and upper bounds specify a half-open range: the range
includes the lower bound but does not include the upper bound. The body
region must contain exactly one block that terminates with `affine.yield`.
The lower and upper bounds of a parallel operation are represented as an
application of an affine mapping to a list of SSA values passed to the map.
The same restrictions hold for these SSA values as for all bindings of SSA
values to dimensions and symbols. The list of expressions in each map is
interpreted according to the respective bounds group attribute. If a single
expression belongs to the group, then the result of this expression is taken
as a lower(upper) bound of the corresponding loop induction variable. If
multiple expressions belong to the group, then the lower(upper) bound is the
max(min) of these values obtained from these expressions. The loop band has
as many loops as elements in the group bounds attributes.
Each value yielded by `affine.yield` will be accumulated/reduced via one of
the reduction methods defined in the AtomicRMWKind enum. The order of
reduction is unspecified, and lowering may produce any valid ordering.
Loops with a 0 trip count will produce as a result the identity value
associated with each reduction (i.e. 0.0 for addf, 1.0 for mulf). Assign
reductions for loops with a trip count != 1 produces undefined results.
Note: Calling `AffineParallelOp::build` will create the required region and
block, and insert the required terminator if it is trivial (i.e. no values
are yielded). Parsing will also create the required region, block, and
terminator, even when they are missing from the textual representation.
Example (3x3 valid convolution):
```mlir
func.func @conv_2d(%D : memref<100x100xf32>, %K : memref<3x3xf32>) -> (memref<98x98xf32>) {
%O = memref.alloc() : memref<98x98xf32>
affine.parallel (%x, %y) = (0, 0) to (98, 98) {
%0 = affine.parallel (%kx, %ky) = (0, 0) to (2, 2) reduce ("addf") -> f32 {
%1 = affine.load %D[%x + %kx, %y + %ky] : memref<100x100xf32>
%2 = affine.load %K[%kx, %ky] : memref<3x3xf32>
%3 = arith.mulf %1, %2 : f32
affine.yield %3 : f32
}
affine.store %0, %O[%x, %y] : memref<98x98xf32>
}
return %O : memref<98x98xf32>
}
```
Example (tiling by potentially imperfectly dividing sizes):
```mlir
affine.parallel (%ii, %jj) = (0, 0) to (%N, %M) step (32, 32) {
affine.parallel (%i, %j) = (%ii, %jj)
to (min(%ii + 32, %N), min(%jj + 32, %M)) {
call @f(%i, %j) : (index, index) -> ()
}
}
```
}];
let arguments = (ins
TypedArrayAttrBase<AtomicRMWKindAttr, "Reduction ops">:$reductions,
AffineMapAttr:$lowerBoundsMap,
I32ElementsAttr:$lowerBoundsGroups,
AffineMapAttr:$upperBoundsMap,
I32ElementsAttr:$upperBoundsGroups,
I64SmallVectorArrayAttr:$steps,
Variadic<Index>:$mapOperands);
let results = (outs Variadic<AnyType>:$results);
let regions = (region SizedRegion<1>:$region);
let builders = [
OpBuilder<(ins "TypeRange":$resultTypes,
"ArrayRef<arith::AtomicRMWKind>":$reductions, "ArrayRef<int64_t>":$ranges)>,
OpBuilder<(ins "TypeRange":$resultTypes,
"ArrayRef<arith::AtomicRMWKind>":$reductions, "ArrayRef<AffineMap>":$lbMaps,
"ValueRange":$lbArgs, "ArrayRef<AffineMap>":$ubMaps, "ValueRange":$ubArgs,
"ArrayRef<int64_t>":$steps)>
];
let extraClassDeclaration = [{
/// Get the number of dimensions.
unsigned getNumDims();
/// Get ranges as constants, may fail in dynamic case.
std::optional<SmallVector<int64_t, 8>> getConstantRanges();
Block *getBody();
OpBuilder getBodyBuilder();
MutableArrayRef<BlockArgument> getIVs() {
return getBody()->getArguments();
}
/// Returns elements of the loop lower bound.
AffineMap getLowerBoundMap(unsigned pos);
operand_range getLowerBoundsOperands();
AffineValueMap getLowerBoundsValueMap();
/// Sets elements of the loop lower bound.
void setLowerBounds(ValueRange operands, AffineMap map);
/// Returns elements of the loop upper bound.
AffineMap getUpperBoundMap(unsigned pos);
operand_range getUpperBoundsOperands();
AffineValueMap getUpperBoundsValueMap();
/// Sets elements fo the loop upper bound.
void setUpperBounds(ValueRange operands, AffineMap map);
void setSteps(ArrayRef<int64_t> newSteps);
/// Returns attribute names to use in op construction. Not expected to be
/// used directly.
static StringRef getReductionsAttrStrName() { return "reductions"; }
static StringRef getLowerBoundsMapAttrStrName() { return "lowerBoundsMap"; }
static StringRef getLowerBoundsGroupsAttrStrName() {
return "lowerBoundsGroups";
}
static StringRef getUpperBoundsMapAttrStrName() { return "upperBoundsMap"; }
static StringRef getUpperBoundsGroupsAttrStrName() {
return "upperBoundsGroups";
}
static StringRef getStepsAttrStrName() { return "steps"; }
/// Returns `true` if the loop bounds have min/max expressions.
bool hasMinMaxBounds() {
return getLowerBoundsMap().getNumResults() != getNumDims() ||
getUpperBoundsMap().getNumResults() != getNumDims();
}
}];
let hasCustomAssemblyFormat = 1;
let hasFolder = 1;
let hasVerifier = 1;
}
def AffinePrefetchOp : Affine_Op<"prefetch",
[DeclareOpInterfaceMethods<AffineMapAccessInterface>,
MemRefsNormalizable]> {
let summary = "affine prefetch operation";
let description = [{
The `affine.prefetch` op prefetches data from a memref location described
with an affine subscript similar to affine.load, and has three attributes:
a read/write specifier, a locality hint, and a cache type specifier as shown
below:
```mlir
affine.prefetch %0[%i, %j + 5], read, locality<3>, data : memref<400x400xi32>
```
The read/write specifier is either 'read' or 'write', the locality hint
specifier ranges from locality<0> (no locality) to locality<3> (extremely
local keep in cache). The cache type specifier is either 'data' or 'instr'
and specifies whether the prefetch is performed on data cache or on
instruction cache.
}];
let arguments = (ins AnyMemRef:$memref, Variadic<Index>:$indices,
BoolAttr:$isWrite,
ConfinedAttr<I32Attr, [IntMinValue<0>,
IntMaxValue<3>]>:$localityHint,
BoolAttr:$isDataCache,
AffineMapAttr:$map);
let builders = [
OpBuilder<(ins "Value":$memref, "AffineMap":$map,
"ArrayRef<Value>":$mapOperands, "bool":$isWrite, "unsigned":$localityHint,
"bool":$isDataCache),
[{
assert(map.getNumInputs() == mapOperands.size()
&& "inconsistent index info");
auto localityHintAttr = $_builder.getI32IntegerAttr(localityHint);
auto isWriteAttr = $_builder.getBoolAttr(isWrite);
auto isDataCacheAttr = $_builder.getBoolAttr(isDataCache);
$_state.addOperands(memref);
$_state.addOperands(mapOperands);
Properties &prop = $_state.getOrAddProperties<Properties>();
prop.map = AffineMapAttr::get(map);
prop.localityHint = localityHintAttr;
prop.isWrite = isWriteAttr;
prop.isDataCache = isDataCacheAttr;
}]>];
let extraClassDeclaration = [{
MemRefType getMemRefType() {
return ::llvm::cast<MemRefType>(getMemref().getType());
}
/// Returns the affine map used to index the memref for this operation.
AffineMap getAffineMap() { return getAffineMapAttr().getValue(); }
AffineMapAttr getAffineMapAttr() {
return getProperties().map;
}
/// Implements the AffineMapAccessInterface.
/// Returns the AffineMapAttr associated with 'memref'.
NamedAttribute getAffineMapAttrForMemRef(Value mref) {
assert(mref == getMemref() &&
"Expected mref argument to match memref operand");
return {StringAttr::get(getContext(), getMapAttrStrName()),
getAffineMapAttr()};
}
/// Get affine map operands.
operand_range getMapOperands() {
return {operand_begin() + 1, operand_end()};
}
static StringRef getMapAttrStrName() { return "map"; }
static StringRef getLocalityHintAttrStrName() { return "localityHint"; }
static StringRef getIsWriteAttrStrName() { return "isWrite"; }
static StringRef getIsDataCacheAttrStrName() { return "isDataCache"; }
}];
let hasCanonicalizer = 1;
let hasCustomAssemblyFormat = 1;
let hasFolder = 1;
let hasVerifier = 1;
}
class AffineStoreOpBase<string mnemonic, list<Trait> traits = []> :
Affine_Op<mnemonic, !listconcat(traits,
[DeclareOpInterfaceMethods<AffineWriteOpInterface>,
DeclareOpInterfaceMethods<AffineMapAccessInterface>,
MemRefsNormalizable])> {
code extraClassDeclarationBase = [{
/// Returns the operand index of the value to be stored.
unsigned getStoredValOperandIndex() { return 0; }
/// Returns the operand index of the memref.
unsigned getMemRefOperandIndex() { return 1; }
void setMemRef(Value value) { setOperand(getMemRefOperandIndex(), value); }
/// Returns the affine map used to index the memref for this operation.
AffineMapAttr getAffineMapAttr() {
return getProperties().map;
}
static StringRef getMapAttrStrName() { return "map"; }
}];
}
def AffineStoreOp : AffineStoreOpBase<"store"> {
let summary = "affine store operation";
let description = [{
Syntax:
```
operation ::= `affine.store` ssa-use, ssa-use `[` multi-dim-affine-map-of-ssa-ids `]` `:` memref-type
```
The `affine.store` op writes an element to a memref, where the index
for each memref dimension is an affine expression of loop induction
variables and symbols. The `affine.store` op stores a new value which is the
same type as the elements of the memref. An affine expression of loop IVs
and symbols must be specified for each dimension of the memref. The keyword
`symbol` can be used to indicate SSA identifiers which are symbolic.
Example 1:
```mlir
affine.store %v0, %0[%i0 + 3, %i1 + 7] : memref<100x100xf32>
```
Example 2: Uses `symbol` keyword for symbols `%n` and `%m`.
```mlir
affine.store %v0, %0[%i0 + symbol(%n), %i1 + symbol(%m)] : memref<100x100xf32>
```
}];
let arguments = (ins AnyType:$value,
Arg<AnyMemRef, "the reference to store to",
[MemWrite]>:$memref,
Variadic<Index>:$indices,
AffineMapAttr:$map);
let skipDefaultBuilders = 1;
let builders = [
OpBuilder<(ins "Value":$valueToStore, "Value":$memref,
"ValueRange":$indices)>,
OpBuilder<(ins "Value":$valueToStore, "Value":$memref, "AffineMap":$map,
"ValueRange":$mapOperands)>
];
let extraClassDeclaration = extraClassDeclarationBase;
let hasCanonicalizer = 1;
let hasCustomAssemblyFormat = 1;
let hasFolder = 1;
let hasVerifier = 1;
}
def AffineYieldOp : Affine_Op<"yield", [Pure, Terminator, ReturnLike,
MemRefsNormalizable]> {
let summary = "Yield values to parent operation";
let description = [{
The `affine.yield` yields zero or more SSA values from an affine op region and
terminates the region. The semantics of how the values yielded are used
is defined by the parent operation.
If `affine.yield` has any operands, the operands must match the parent
operation's results.
If the parent operation defines no values, then the `affine.yield` may be
left out in the custom syntax and the builders will insert one implicitly.
Otherwise, it has to be present in the syntax to indicate which values are
yielded.
}];
let arguments = (ins Variadic<AnyType>:$operands);
let builders = [
OpBuilder<(ins), [{ build($_builder, $_state, std::nullopt); }]>
];
let assemblyFormat = "attr-dict ($operands^ `:` type($operands))?";
let hasVerifier = 1;
}
def AffineVectorLoadOp : AffineLoadOpBase<"vector_load"> {
let summary = "affine vector load operation";
let description = [{
The `affine.vector_load` is the vector counterpart of
[affine.load](#affineload-mliraffineloadop). It reads a slice from a
[MemRef](Builtin.md/#memreftype), supplied as its first operand,
into a [vector](Builtin.md/#vectortype) of the same base elemental type.
The index for each memref dimension is an affine expression of loop induction
variables and symbols. These indices determine the start position of the read
within the memref. The shape of the return vector type determines the shape of
the slice read from the memref. This slice is contiguous along the respective
dimensions of the shape. Strided vector loads will be supported in the future.
An affine expression of loop IVs and symbols must be specified for each
dimension of the memref. The keyword `symbol` can be used to indicate SSA
identifiers which are symbolic.
Example 1: 8-wide f32 vector load.
```mlir
%1 = affine.vector_load %0[%i0 + 3, %i1 + 7] : memref<100x100xf32>, vector<8xf32>
```
Example 2: 4-wide f32 vector load. Uses `symbol` keyword for symbols `%n` and `%m`.
```mlir
%1 = affine.vector_load %0[%i0 + symbol(%n), %i1 + symbol(%m)] : memref<100x100xf32>, vector<4xf32>
```
Example 3: 2-dim f32 vector load.
```mlir
%1 = affine.vector_load %0[%i0, %i1] : memref<100x100xf32>, vector<2x8xf32>
```
TODOs:
* Add support for strided vector loads.
* Consider adding a permutation map to permute the slice that is read from memory
(see [vector.transfer_read](../Vector/#vectortransfer_read-mlirvectortransferreadop)).
}];
let results = (outs AnyVector:$result);
let builders = [
/// Builds an affine vector load op with the specified map and operands.
OpBuilder<(ins "VectorType":$resultType, "AffineMap":$map,
"ValueRange":$operands)>,
/// Builds an affine vector load op with an identity map and operands.
OpBuilder<(ins "VectorType":$resultType, "Value":$memref,
CArg<"ValueRange", "{}">:$indices)>,
/// Builds an affine vector load op with the specified map and its operands.
OpBuilder<(ins "VectorType":$resultType, "Value":$memref,
"AffineMap":$map, "ValueRange":$mapOperands)>
];
let extraClassDeclaration = extraClassDeclarationBase # [{
VectorType getVectorType() {
return ::llvm::cast<VectorType>(getResult().getType());
}
}];
let hasCanonicalizer = 1;
let hasCustomAssemblyFormat = 1;
let hasVerifier = 1;
}
def AffineVectorStoreOp : AffineStoreOpBase<"vector_store"> {
let summary = "affine vector store operation";
let description = [{
The `affine.vector_store` is the vector counterpart of
[affine.store](#affinestore-mliraffinestoreop). It writes a
[vector](Builtin.md/#vectortype), supplied as its first operand,
into a slice within a [MemRef](Builtin.md/#memreftype) of the same base
elemental type, supplied as its second operand.
The index for each memref dimension is an affine expression of loop
induction variables and symbols. These indices determine the start position
of the write within the memref. The shape of th input vector determines the
shape of the slice written to the memref. This slice is contiguous along the
respective dimensions of the shape. Strided vector stores will be supported
in the future.
An affine expression of loop IVs and symbols must be specified for each
dimension of the memref. The keyword `symbol` can be used to indicate SSA
identifiers which are symbolic.
Example 1: 8-wide f32 vector store.
```mlir
affine.vector_store %v0, %0[%i0 + 3, %i1 + 7] : memref<100x100xf32>, vector<8xf32>
```
Example 2: 4-wide f32 vector store. Uses `symbol` keyword for symbols `%n` and `%m`.
```mlir
affine.vector_store %v0, %0[%i0 + symbol(%n), %i1 + symbol(%m)] : memref<100x100xf32>, vector<4xf32>
```
Example 3: 2-dim f32 vector store.
```mlir
affine.vector_store %v0, %0[%i0, %i1] : memref<100x100xf32>, vector<2x8xf32>
```
TODOs:
* Add support for strided vector stores.
* Consider adding a permutation map to permute the slice that is written to memory
(see [vector.transfer_write](../Vector/#vectortransfer_write-mlirvectortransferwriteop)).
}];
let arguments = (ins AnyVector:$value,
Arg<AnyMemRef, "the reference to store to",
[MemWrite]>:$memref,
Variadic<Index>:$indices,
AffineMapAttr:$map);
let skipDefaultBuilders = 1;
let builders = [
OpBuilder<(ins "Value":$valueToStore, "Value":$memref,
"ValueRange":$indices)>,
OpBuilder<(ins "Value":$valueToStore, "Value":$memref, "AffineMap":$map,
"ValueRange":$mapOperands)>
];
let extraClassDeclaration = extraClassDeclarationBase # [{
VectorType getVectorType() {
return ::llvm::cast<VectorType>(getValue().getType());
}
}];
let hasCanonicalizer = 1;
let hasCustomAssemblyFormat = 1;
let hasVerifier = 1;
}
//===----------------------------------------------------------------------===//
// AffineDelinearizeIndexOp
//===----------------------------------------------------------------------===//
def AffineDelinearizeIndexOp : Affine_Op<"delinearize_index",
[Pure, DeclareOpInterfaceMethods<InferTypeOpInterface>]> {
let summary = "delinearize an index";
let description = [{
The `affine.delinearize_index` operation takes a single index value and
calculates the multi-index according to the given basis.
Example:
```
%indices:3 = affine.delinearize_index %linear_index into (%c16, %c224, %c224) : index, index, index
```
In the above example, `%indices:3` conceptually holds the following:
```
#map0 = affine_map<()[s0] -> (s0 floordiv 50176)>
#map1 = affine_map<()[s0] -> ((s0 mod 50176) floordiv 224)>
#map2 = affine_map<()[s0] -> (s0 mod 224)>
%indices_0 = affine.apply #map0()[%linear_index]
%indices_1 = affine.apply #map1()[%linear_index]
%indices_2 = affine.apply #map2()[%linear_index]
```
}];
let arguments = (ins Index:$linear_index, Variadic<Index>:$basis);
let results = (outs Variadic<Index>:$multi_index);
let assemblyFormat = [{
$linear_index `into` ` ` `(` $basis `)` attr-dict `:` type($multi_index)
}];
let builders = [
OpBuilder<(ins "Value":$linear_index, "ArrayRef<OpFoldResult>":$basis)>
];
let hasVerifier = 1;
}
#endif // AFFINE_OPS
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