llvm-project/mlir/lib/Dialect/Linalg/IR/LinalgInterfaces.cpp
MaheshRavishankar 9afc065743 Split InferShapedTypeOpInterface to create ReifyRankedShapedTypeInterface.
The `reifyReturnTypeShapesPerResultDim` method supports shape
inference for rsults that are ranked types. These are used lower in
the codegeneration stack than its counter part `reifyReturnTypeShapes`
which also supports unranked types, and is more suited for use higher
up the compilation stack. To have separation of concerns, this method
is split into its own interface.
See discussion : https://llvm.discourse.group/t/better-layering-for-infershapedtypeopinterface/3823

Differential Revision: https://reviews.llvm.org/D106133
2021-07-19 14:44:52 -07:00

536 lines
22 KiB
C++

//===- LinalgInterfaces.cpp - Linalg interfaces implementation ------------===//
//
// 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
//
//===----------------------------------------------------------------------===//
#include "mlir/Dialect/Linalg/IR/LinalgInterfaces.h"
#include "mlir/Dialect/Affine/IR/AffineOps.h"
#include "mlir/Dialect/MemRef/IR/MemRef.h"
#include "mlir/IR/AffineExprVisitor.h"
#include "mlir/IR/AffineMap.h"
#include "mlir/IR/TypeUtilities.h"
#include "llvm/ADT/SmallSet.h"
using namespace mlir;
using namespace mlir::linalg;
/// Include the definitions of the copy operation interface.
#include "mlir/Dialect/Linalg/IR/LinalgInterfaces.cpp.inc"
//===----------------------------------------------------------------------===//
// ContractionOpInterface implementation
//===----------------------------------------------------------------------===//
/// Return true if the use-def chain from `v` to `from` consists of 0 or more
/// unary single-operand operations.
// TODO: relax to multi-operands with constants, which are technically unary ops
// as needed (e.g. add5).
static bool isChainOfUnaryOpsFrom(Value v, Value from) {
while (true) {
if (v == from)
return true;
Operation *op = v.getDefiningOp();
if (!op || op->getNumOperands() != 1)
return false;
v = op->getOperand(0);
};
}
/// Return the unique instance of OpType in `block` if it is indeed unique.
/// Return null if none or more than 1 instances exist.
template <typename OpType>
static OpType getSingleOpOfType(Block &block) {
OpType res = nullptr;
block.walk([&](OpType op) {
if (res) {
res = nullptr;
return WalkResult::interrupt();
}
res = op;
return WalkResult::advance();
});
return res;
}
/// Detect whether res is any permutation of `u5(u1(c) + u2(u3(a) * u4(b)))`
/// on the field (AddOpType, MulOpType), where u1, u2, u3, u4 and u5 represent
/// unary operations that may change the type.
template <typename AddOpType, typename MulOpType>
static bool isAddMul(Block &block) {
if (block.getNumArguments() != 3)
return false;
Operation *yieldOp = block.getTerminator();
if (yieldOp->getNumOperands() != 1)
return false;
AddOpType addOp = getSingleOpOfType<AddOpType>(block);
MulOpType mulOp = getSingleOpOfType<MulOpType>(block);
if (!addOp || !mulOp)
return false;
Value argA = block.getArgument(0), argB = block.getArgument(1);
Value a = mulOp->getOperand(0), b = mulOp->getOperand(1);
Value mul = mulOp->getResult(0);
Value argC = block.getArgument(2);
Value c1 = addOp->getOperand(0), c2 = addOp->getOperand(1);
Value add = addOp->getResult(0);
Value res = yieldOp->getOperand(0);
// Result traces back to add.
auto un = isChainOfUnaryOpsFrom;
bool success = un(res, add);
// One of the operands of add traces back to argC, the other to the mul.
success |= (un(c1, argC) && un(c2, mul)) || ((un(c1, mul)) && un(c2, argC));
// One of the operands of mul traces back to argA, the other to argB.
success |= (un(a, argA) && un(b, argB)) || ((un(a, argB)) && un(b, argA));
return success;
}
enum MatchContractionResult {
Success = 0,
NotLinalgOp,
WrongNumOperands,
NoReduction,
NotProjectedPermutations,
NotAddMul
};
static MatchContractionResult isContractionInterfaceImpl(Operation *op) {
auto linalgOp = dyn_cast<linalg::LinalgOp>(op);
if (!linalgOp)
return MatchContractionResult::NotLinalgOp;
if (linalgOp.getNumInputs() != 2 || linalgOp.getNumOutputs() != 1)
return MatchContractionResult::WrongNumOperands;
auto mapRange = linalgOp.indexing_maps().getAsValueRange<AffineMapAttr>();
if (linalgOp.getNumReductionLoops() == 0)
return MatchContractionResult::NoReduction;
if (llvm::any_of(mapRange,
[](AffineMap m) { return !m.isProjectedPermutation(); }))
return MatchContractionResult::NotProjectedPermutations;
// TODO: more fields than add/mul.
if (!isAddMul<AddFOp, MulFOp>(linalgOp->getRegion(0).front()) &&
!isAddMul<AddIOp, MulIOp>(linalgOp->getRegion(0).front()))
return MatchContractionResult::NotAddMul;
return MatchContractionResult::Success;
}
bool mlir::linalg::isaContractionOpInterface(LinalgOp linalgOp) {
if (!linalgOp)
return false;
Operation *op = linalgOp.getOperation();
return isa<ContractionOpInterface>(op) ||
(isContractionInterfaceImpl(op) == MatchContractionResult::Success);
}
/// Verify that a LinalgOp `op` is a contraction.
/// A Linalg contraction is defined in general terms:
/// 1. Has 2 input and 1 output shapes.
/// 2. Has at least one reduction dimension.
/// 3. Has only projected permutation indexing maps.
/// 4. its body computes `u5(u1(c) + u2(u3(a) * u4(b)))` on some field
/// (AddOpType, MulOpType), where u1, u2, u3, u4 and u5 represent scalar unary
/// operations that may change the type (e.g. for mixed-precision).
/// As a consequence, when vectorization of such an op occurs, the only special
/// behavior is that the (unique) MulOpType is vectorized into a
/// `vector.contract`. All other ops are handled in a generic fashion.
/// In the future, we may wish to allow more input arguments and elementwise and
/// constant operations that do not involve the reduction dimension(s).
LogicalResult mlir::linalg::detail::verifyContractionInterface(Operation *op) {
auto res = isContractionInterfaceImpl(op);
if (res == MatchContractionResult::NotLinalgOp)
return op->emitError("expected a LinalgOp");
if (res == MatchContractionResult::WrongNumOperands)
return op->emitError("expected op with 2 inputs and 1 outputs");
if (res == MatchContractionResult::NoReduction)
return op->emitError("expected at least a reduction loop");
if (res == MatchContractionResult::NotProjectedPermutations)
return op->emitError("expected all indexings to be projected permutations");
if (res == MatchContractionResult::NotAddMul)
return op->emitError("(add, mul) operations not found");
return success();
}
//===----------------------------------------------------------------------===//
// StructuredOpInterface implementation
//===----------------------------------------------------------------------===//
OpOperandVector::operator SmallVector<Value>() {
SmallVector<Value> result;
result.reserve(this->size());
llvm::transform(*this, std::back_inserter(result),
[](OpOperand *opOperand) { return opOperand->get(); });
return result;
}
/// Fully compose map with operands and canonicalize the result.
/// Return the `createOrFold`'ed AffineApply op.
static Value createFoldedComposedAffineApply(OpBuilder &b, Location loc,
AffineMap map,
ValueRange operandsRef) {
SmallVector<Value, 4> operands(operandsRef.begin(), operandsRef.end());
fullyComposeAffineMapAndOperands(&map, &operands);
canonicalizeMapAndOperands(&map, &operands);
return b.createOrFold<AffineApplyOp>(loc, map, operands);
}
SmallVector<Value, 4> mlir::linalg::applyMapToValues(OpBuilder &b, Location loc,
AffineMap map,
ValueRange values) {
SmallVector<Value, 4> res;
res.reserve(map.getNumResults());
unsigned numDims = map.getNumDims(), numSym = map.getNumSymbols();
// For each `expr` in `map`, applies the `expr` to the values extracted from
// ranges. If the resulting application can be folded into a Value, the
// folding occurs eagerly.
for (auto expr : map.getResults()) {
AffineMap map = AffineMap::get(numDims, numSym, expr);
res.push_back(createFoldedComposedAffineApply(b, loc, map, values));
}
return res;
}
/// Helper function that creates a memref::DimOp or tensor::DimOp depending on
/// the type of `source`.
static Value createOrFoldDimOp(OpBuilder &b, Location loc, Value source,
int64_t dim) {
if (source.getType().isa<UnrankedMemRefType, MemRefType>())
return b.createOrFold<memref::DimOp>(loc, source, dim);
if (source.getType().isa<UnrankedTensorType, RankedTensorType>())
return b.createOrFold<tensor::DimOp>(loc, source, dim);
llvm_unreachable("Expected MemRefType or TensorType");
}
SmallVector<Value, 4> LinalgOp::createFlatListOfOperandDims(OpBuilder &b,
Location loc) {
SmallVector<Value, 4> res;
for (OpOperand *opOperand : getInputAndOutputOperands()) {
for (int64_t i = 0, e = getRank(opOperand); i < e; ++i)
res.push_back(createOrFoldDimOp(b, loc, opOperand->get(), i));
}
return res;
}
SmallVector<int64_t, 4> LinalgOp::createFlatListOfOperandStaticDims() {
SmallVector<int64_t, 4> res;
assert(!hasDynamicShape() && "expected operands to have static shapes");
for (OpOperand *opOperand : getInputAndOutputOperands())
llvm::append_range(res, getShape(opOperand));
return res;
}
SmallVector<Range, 4> LinalgOp::createLoopRanges(OpBuilder &b, Location loc) {
AffineMap map = getLoopsToShapesMap();
unsigned numDims = map.getNumDims(), numRes = map.getNumResults();
auto viewSizes = createFlatListOfOperandDims(b, loc);
SmallVector<Range, 4> res(numDims);
Value zeroVal = b.create<ConstantIndexOp>(loc, 0);
Value oneVal = b.create<ConstantIndexOp>(loc, 1);
for (unsigned idx = 0; idx < numRes; ++idx) {
auto result = map.getResult(idx);
if (auto d = result.dyn_cast<AffineDimExpr>()) {
if (res[d.getPosition()].offset)
continue;
res[d.getPosition()] = Range{zeroVal, viewSizes[idx], oneVal};
}
}
return res;
}
SmallVector<int64_t, 4> LinalgOp::computeStaticLoopSizes() {
AffineMap map = getLoopsToShapesMap();
unsigned numDims = map.getNumDims(), numRes = map.getNumResults();
SmallVector<int64_t, 4> allShapeSizes = createFlatListOfOperandStaticDims();
SmallVector<int64_t, 4> res(numDims, 0);
for (unsigned idx = 0; idx < numRes; ++idx) {
auto result = map.getResult(idx);
if (auto d = result.dyn_cast<AffineDimExpr>())
res[d.getPosition()] = allShapeSizes[idx];
}
return res;
}
/// Visitor to check if any of the given set of positions from AffineDimExprs
/// are used within an AffineExpr.
struct HasAffineDimExprVisitor
: public AffineExprVisitor<HasAffineDimExprVisitor, bool> {
HasAffineDimExprVisitor(llvm::SmallSet<unsigned, 4> &positions)
: positions(positions) {}
bool visitAffineBinaryOpExpr(AffineBinaryOpExpr binaryOpExpr) {
return visit(binaryOpExpr.getLHS()) || visit(binaryOpExpr.getRHS());
}
bool visitDimExpr(AffineDimExpr dimExpr) {
return positions.count(dimExpr.getPosition());
}
bool visitConstantExpr(AffineConstantExpr constExpr) { return false; }
bool visitSymbolExpr(AffineSymbolExpr symbolExpr) { return false; }
private:
llvm::SmallSet<unsigned, 4> positions;
};
LogicalResult
LinalgOp::reifyResultShapes(OpBuilder &b,
ReifiedRankedShapedTypeDims &reifiedReturnShapes) {
// An example that helps understand the logic below.
// Consider the following expression O(i+j, j) += A(i,k) * B(k, j)
// We want to express the shape of dim 0 of O in terms of shape of the inputs.
// This is achieved as follows.
// loopsToShapesMap = (d0, d1, d2) -> (d0, d2, d2, d1, d0 + d1, d1)
// subMapOfResultShapes = (d0, d1, d2) -> (d0 + d1, d1)
// shapesToLoopsMap = (d0, d2, d2, d3, d4, d5) -> (d0, d3, d2)
// resultShapesFromInputShapes = subMapOfResultDim.compose(shapesToLoopMap)
// = (d0, d1, d2, d3, d4, d5) -> (d0 + d1, d1)
AffineMap loopsToShapesMap = getLoopsToShapesMap();
// Find the position in the above map that represents the shape of the
// result:dim being inferred.
auto resultShapesSubMapPos = getResultsPositionInLoopsToShapeMap();
/// From loopsToShapesMap extract the submap that represents the shape of the
/// (resultIdx, dim) needed.
SmallVector<unsigned, 4> resultPosRange =
llvm::to_vector<4>(llvm::seq<unsigned>(resultShapesSubMapPos.first,
resultShapesSubMapPos.second));
AffineMap loopToResultsShapeMap = loopsToShapesMap.getSubMap(resultPosRange);
AffineMap resultShapesFromInputShapesMap =
loopToResultsShapeMap.compose(getShapesToLoopsMap());
// Check that the result dim map does not contain the positions corresponding
// to the outputs.
llvm::SmallSet<unsigned, 4> outputDims;
llvm::for_each(resultPosRange,
[&outputDims](unsigned dim) { outputDims.insert(dim); });
HasAffineDimExprVisitor checkDimExpr(outputDims);
Location loc = getOperation()->getLoc();
auto allResultDimValues =
applyMapToValues(b, loc, resultShapesFromInputShapesMap,
createFlatListOfOperandDims(b, loc));
int64_t pos = 0;
ArrayRef<AffineExpr> shapeExprs = resultShapesFromInputShapesMap.getResults();
for (OpOperand *opOperand : getOutputOperands()) {
SmallVector<Value> shapes;
for (int64_t dim : llvm::seq<int64_t>(0, getRank(opOperand))) {
if (checkDimExpr.visit(shapeExprs[pos]))
shapes.push_back(createOrFoldDimOp(b, loc, opOperand->get(), dim));
else
shapes.push_back(allResultDimValues[pos]);
pos++;
}
reifiedReturnShapes.emplace_back(std::move(shapes));
}
return success();
}
LogicalResult mlir::linalg::detail::verifyStructuredOpInterface(Operation *op) {
LinalgOp linalgOp = cast<LinalgOp>(op);
// Expect at least one output operand.
// This means an op that constructs a tensor out of indices cannot be a
// LinalgOp at the moment. For now this will have to be a special op until we
// have output shape operands that are not tensors.
int64_t numInputs = linalgOp.getNumInputs();
int64_t numOutputs = linalgOp.getNumOutputs();
if (numOutputs == 0)
return op->emitOpError("expected at least one output operand");
if (failed(OpTrait::impl::verifyNOperands(op, numInputs + numOutputs)))
return failure();
// Verify the number of results matches the number of output tensors.
if (op->getNumResults() != linalgOp.getOutputTensorOperands().size())
return op->emitOpError("expected the number of results (")
<< op->getNumResults()
<< ") to be equal to the number of output tensors ("
<< linalgOp.getOutputTensorOperands().size() << ")";
// Before checking indexing maps, we need to make sure the attributes
// referenced by it are valid.
if (linalgOp.hasDynamicIndexingMaps())
if (failed(linalgOp.verifyIndexingMapRequiredAttributes()))
return failure();
// All input/output operands must be indexed.
if (static_cast<int64_t>(linalgOp.indexing_maps().size()) !=
linalgOp.getNumInputsAndOutputs())
return op->emitOpError("expected the number of indexing_map (")
<< linalgOp.indexing_maps().size()
<< ") to be equal to the number of input/output operands ("
<< linalgOp.getNumInputsAndOutputs() << ")";
for (OpOperand *opOperand : linalgOp.getInputAndOutputOperands()) {
AffineMap indexingMap = linalgOp.getTiedIndexingMap(opOperand);
// Symbols disallowed.
if (indexingMap.getNumSymbols() != 0)
return op->emitOpError("unexpected symbols in indexing_map #")
<< opOperand->getOperandNumber();
// Domain must be consistent.
unsigned numLoops = linalgOp.getNumLoops();
if (indexingMap.getNumDims() != numLoops)
return op->emitOpError("expected indexing_map #")
<< opOperand->getOperandNumber() << " to have " << numLoops
<< " dim(s) to match the number of loops";
int64_t rank = linalgOp.getRank(opOperand);
if (indexingMap.getNumResults() != rank)
return op->emitOpError("expected operand rank (")
<< rank << ") to match the result rank of indexing_map #"
<< opOperand->getOperandNumber() << " ("
<< indexingMap.getNumResults() << ")";
}
SmallVector<AffineExpr> redDims;
linalgOp.getReductionDims(redDims);
// Simplifying assumption: either full tensor or full buffer mode.
// This allows simpler verification of output operands vs result types
// without premature tracking of which operand is what in mixed-mode.
// TODO: relax when mixed-mode needs to pass verification.
if (!linalgOp.getOutputBufferOperands().empty() &&
!linalgOp.getOutputTensorOperands().empty())
return op->emitOpError(
"expected output operands to all have tensor type or "
"all have buffer type");
for (OpOperand *opOperand : linalgOp.getOutputTensorOperands()) {
OpResult result = linalgOp.getTiedOpResult(opOperand);
if (result.getType() != opOperand->get().getType())
return op->emitOpError("expected type of operand #")
<< opOperand->getOperandNumber() << " ("
<< opOperand->get().getType() << ")"
<< " to match type of corresponding result (" << result.getType()
<< ")";
}
// Output tensor indexing map may not depend on reduction indices.
for (OpOperand *opOperand : linalgOp.getOutputOperands()) {
AffineMap indexingMap = linalgOp.getTiedIndexingMap(opOperand);
for (auto expr : indexingMap.getResults()) {
for (auto dim : redDims) {
unsigned pos = dim.cast<AffineDimExpr>().getPosition();
if (expr.isFunctionOfDim(pos)) {
std::string exprStr;
{
llvm::raw_string_ostream os(exprStr);
os << expr;
}
return op->emitOpError(
"unexpected output tensor expression in indexing map #")
<< (opOperand->getOperandNumber() - linalgOp.getNumInputs())
<< " a.k.a '" << exprStr
<< "' is function of reduction iterator 'd" << pos << "'";
}
}
}
}
// Named ops that are defined manually have a region builder but no region at
// this time. Assume the region is well-formed by specification.
// TODO: use linalg-ods-gen for all ops when we have enough expressive power.
if (linalgOp->getNumRegions() == 0) {
assert(!linalgOp.getRegionBuilder() && "regionBuilder but no region");
return success();
}
auto &region = linalgOp->getRegion(0);
if (linalgOp->getNumRegions() > 1 || !llvm::hasSingleElement(region))
return op->emitOpError("expected 1 region with 1 block");
if (!linalgOp.getShapesToLoopsMap())
return op->emitOpError("expected the shape-to-loops map to be non-null");
// Simplifying assumption: bbargs match 1-1 with shape operands elemental
// types.
// TODO: once ranked shape types are plugged in, we may want to drop the
// corresponding bbargs, that can never be read from. This will be subject to
// consistency discussions (i.e. what to do with output tensors whose bbarg is
// not used).
Block &block = linalgOp->getRegion(0).front();
if (linalgOp.getNumInputsAndOutputs() != block.getNumArguments())
return op->emitOpError("expected as many non-induction variable region "
"arguments as the number of input/output operands");
for (OpOperand *opOperand : linalgOp.getInputAndOutputOperands()) {
Type elementType = getElementTypeOrSelf(opOperand->get());
Type argType = block.getArgument(opOperand->getOperandNumber()).getType();
if (elementType != argType)
return op->emitOpError("expected type of bb argument #")
<< opOperand->getOperandNumber() << " (" << argType << ")"
<< " to match element or self type of the corresponding operand ("
<< elementType << ")";
}
// Check if given shapes match to inferred shapes.
Optional<SmallVector<int64_t, 4>> endLoopRangeValues =
linalgOp.getStaticLoopRanges();
if (!endLoopRangeValues)
return op->emitOpError("unable to find loop range for operation");
SmallVector<int64_t, 4> startLoopRangeValues((*endLoopRangeValues).size(), 0);
// Verify only static cases since we can't get exact dimension sizes and loop
// ranges for dynamic cases in this stage.
if (llvm::none_of(*endLoopRangeValues, ShapedType::isDynamic)) {
for (int64_t &range : *endLoopRangeValues)
range -= 1;
for (OpOperand *opOperand : linalgOp.getInputAndOutputOperands()) {
AffineMap indexingMap = linalgOp.getTiedIndexingMap(opOperand);
SmallVector<int64_t, 4> startIndices =
indexingMap.compose(startLoopRangeValues);
SmallVector<int64_t, 4> endIndices =
indexingMap.compose(*endLoopRangeValues);
ArrayRef<int64_t> shape = linalgOp.getShape(opOperand);
for (auto dim : llvm::seq<int64_t>(0, shape.size())) {
// Ignore dynamic dimension or the case that the dimension size is 0
if (ShapedType::isDynamic(shape[dim]) || shape[dim] == 0)
continue;
// The first index or last index should be the maximum or the minimum in
// the inferred index ranges since the range is increasing or
// decreasing. The size of dimensions of input/output operands and the
// maximum value + 1 in the inferred range should be the same. But, for
// now we check if the inferred ranges are in boundary of input/output
// operands' size or not in case that Affine Expressions are complicated
// such as d0 * 3
// + d1 since it is not easy to handle the issues.
// Found the case that this solution can't check, for example, (d0, d1)
// -> (d1 - d0)
int64_t inferredDimSize =
std::max(startIndices[dim], endIndices[dim]) + 1;
if (std::min(startIndices[dim], endIndices[dim]) < 0) {
std::string mapStr;
{
llvm::raw_string_ostream os(mapStr);
os << indexingMap;
}
return op->emitOpError(
"unexpected result less than 0 at expression #")
<< dim << " in " << mapStr;
}
if (indexingMap.getResult(dim).dyn_cast<AffineDimExpr>()) {
if (inferredDimSize != shape[dim]) {
return op->emitOpError("inferred input/output operand #")
<< opOperand->getOperandNumber()
<< " has shape's dimension #" << dim << " to be "
<< inferredDimSize << ", but found " << shape[dim];
}
} else {
if (inferredDimSize > shape[dim]) {
return op->emitOpError("inferred input/output operand #")
<< opOperand->getOperandNumber()
<< " has shape's dimension #" << dim
<< " to be greater than or equal to " << inferredDimSize
<< ", but found " << shape[dim];
}
}
}
}
}
return success();
}