Files
clang-p2996/mlir/lib/Dialect/Linalg/ComprehensiveBufferize/BufferizableOpInterface.cpp
Matthias Springer 698896cd6c [mlir][linalg][bufferize][NFC] Change allocationFn return type to FailureOr<Value>
In addition, all functions that call `allocationFn` now return FailureOr<Value>. This resolves a few TODOs in the code base.

Differential Revision: https://reviews.llvm.org/D116452
2022-01-07 06:33:19 +09:00

653 lines
26 KiB
C++

//===- BufferizableOpInterface.cpp - Comprehensive Bufferize --------------===//
//
// 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/ComprehensiveBufferize/BufferizableOpInterface.h"
#include "mlir/Dialect/Bufferization/IR/Bufferization.h"
#include "mlir/Dialect/MemRef/IR/MemRef.h"
#include "mlir/IR/AsmState.h"
#include "mlir/IR/BlockAndValueMapping.h"
#include "mlir/IR/BuiltinOps.h"
#include "mlir/IR/Operation.h"
#include "mlir/IR/TypeUtilities.h"
#include "mlir/IR/Value.h"
#include "llvm/Support/Debug.h"
namespace mlir {
namespace linalg {
namespace comprehensive_bufferize {
#include "mlir/Dialect/Linalg/ComprehensiveBufferize/BufferizableOpInterface.cpp.inc"
} // namespace comprehensive_bufferize
} // namespace linalg
} // namespace mlir
#define DEBUG_TYPE "bufferizable-op-interface"
#define DBGS() (llvm::dbgs() << '[' << DEBUG_TYPE << "] ")
#define LDBG(X) LLVM_DEBUG(DBGS() << (X))
using namespace mlir;
using namespace linalg::comprehensive_bufferize;
//===----------------------------------------------------------------------===//
// BufferizationOptions
//===----------------------------------------------------------------------===//
/// Default allocation function that is used by the comprehensive bufferization
/// pass. The default currently creates a ranked memref using `memref.alloc`.
static FailureOr<Value> defaultAllocationFn(OpBuilder &b, Location loc,
MemRefType type,
ArrayRef<Value> dynShape) {
Value allocated = b.create<memref::AllocOp>(
loc, type, dynShape, b.getI64IntegerAttr(kBufferAlignments));
return allocated;
}
/// Default deallocation function that is used by the comprehensive
/// bufferization pass. It expects to recieve back the value called from the
/// `defaultAllocationFn`.
static void defaultDeallocationFn(OpBuilder &b, Location loc,
Value allocatedBuffer) {
b.create<memref::DeallocOp>(loc, allocatedBuffer);
}
/// Default memory copy function that is used by the comprehensive bufferization
/// pass. Creates a `memref.copy` op.
static void defaultMemCpyFn(OpBuilder &b, Location loc, Value from, Value to) {
b.create<memref::CopyOp>(loc, from, to);
}
std::unique_ptr<AllocationCallbacks>
mlir::linalg::comprehensive_bufferize::defaultAllocationCallbacks() {
return std::make_unique<AllocationCallbacks>(
defaultAllocationFn, defaultDeallocationFn, defaultMemCpyFn);
}
// Default constructor for BufferizationOptions that sets all allocation
// callbacks to their default functions.
BufferizationOptions::BufferizationOptions()
: allocationFns(defaultAllocationCallbacks()) {}
BufferizableOpInterface mlir::linalg::comprehensive_bufferize::
BufferizationOptions::dynCastBufferizableOp(Operation *op) const {
if (isOpAllowed(op))
return dyn_cast<BufferizableOpInterface>(op);
return nullptr;
}
BufferizableOpInterface mlir::linalg::comprehensive_bufferize::
BufferizationOptions::dynCastBufferizableOp(Value value) const {
if (auto bufferizableOp = value.getDefiningOp<BufferizableOpInterface>())
if (isOpAllowed(bufferizableOp.getOperation()))
return bufferizableOp;
return nullptr;
}
//===----------------------------------------------------------------------===//
// BufferizationAliasInfo
//===----------------------------------------------------------------------===//
BufferizationAliasInfo::BufferizationAliasInfo(Operation *rootOp) {
rootOp->walk([&](Operation *op) {
for (Value v : op->getResults())
if (v.getType().isa<TensorType>())
createAliasInfoEntry(v);
for (Region &r : op->getRegions())
for (Block &b : r.getBlocks())
for (auto bbArg : b.getArguments())
if (bbArg.getType().isa<TensorType>())
createAliasInfoEntry(bbArg);
});
}
/// Add a new entry for `v` in the `aliasInfo` and `equivalentInfo`. In the
/// beginning the alias and equivalence sets only contain `v` itself.
void BufferizationAliasInfo::createAliasInfoEntry(Value v) {
aliasInfo.insert(v);
equivalentInfo.insert(v);
}
/// Insert an info entry for `newValue` and merge its alias set with that of
/// `alias`.
void BufferizationAliasInfo::insertNewBufferAlias(Value newValue, Value alias) {
createAliasInfoEntry(newValue);
aliasInfo.unionSets(newValue, alias);
}
/// Insert an info entry for `newValue` and merge its alias set with that of
/// `alias`. Additionally, merge their equivalence classes.
void BufferizationAliasInfo::insertNewBufferEquivalence(Value newValue,
Value alias) {
insertNewBufferAlias(newValue, alias);
equivalentInfo.unionSets(newValue, alias);
}
/// Return `true` if a value was marked as in-place bufferized.
bool BufferizationAliasInfo::isInPlace(OpResult opResult) const {
return inplaceBufferized.contains(opResult);
}
/// Set the inPlace bufferization spec to true.
void BufferizationAliasInfo::bufferizeInPlace(OpResult result,
OpOperand &operand) {
LLVM_DEBUG(llvm::dbgs() << "bufferizeInPlace: ");
LLVM_DEBUG(result.print(llvm::dbgs()));
markInPlace(result);
aliasInfo.unionSets(result, operand.get());
}
/// Set the inPlace bufferization spec to false.
void BufferizationAliasInfo::bufferizeOutOfPlace(OpResult result) {
LLVM_DEBUG(llvm::dbgs() << "bufferizeOutOfPlace: ");
LLVM_DEBUG(result.print(llvm::dbgs()));
if (inplaceBufferized.contains(result))
inplaceBufferized.erase(result);
}
/// Apply `fun` to all the members of the equivalence class of `v`.
void BufferizationAliasInfo::applyOnEquivalenceClass(
Value v, function_ref<void(Value)> fun) const {
auto leaderIt = equivalentInfo.findLeader(v);
for (auto mit = leaderIt, meit = equivalentInfo.member_end(); mit != meit;
++mit) {
fun(*mit);
}
}
/// Apply `fun` to all aliases of `v`.
void BufferizationAliasInfo::applyOnAliases(
Value v, function_ref<void(Value)> fun) const {
auto leaderIt = aliasInfo.findLeader(v);
for (auto mit = leaderIt, meit = aliasInfo.member_end(); mit != meit; ++mit) {
fun(*mit);
}
}
BufferizationAliasInfo::EquivalenceClassRangeType
BufferizationAliasInfo::getAliases(Value v) const {
DenseSet<Value> res;
auto it = aliasInfo.findValue(aliasInfo.getLeaderValue(v));
for (auto mit = aliasInfo.member_begin(it), meit = aliasInfo.member_end();
mit != meit; ++mit) {
res.insert(static_cast<Value>(*mit));
}
return BufferizationAliasInfo::EquivalenceClassRangeType(
aliasInfo.member_begin(it), aliasInfo.member_end());
}
//===----------------------------------------------------------------------===//
// Helper functions for BufferizableOpInterface
//===----------------------------------------------------------------------===//
static void setInsertionPointAfter(OpBuilder &b, Value value) {
if (auto bbArg = value.dyn_cast<BlockArgument>()) {
b.setInsertionPointToStart(bbArg.getOwner());
} else {
b.setInsertionPointAfter(value.getDefiningOp());
}
}
/// Determine which OpOperand* will alias with `result` if the op is bufferized
/// in place. Return an empty vector if the op is not bufferizable.
SmallVector<OpOperand *>
mlir::linalg::comprehensive_bufferize::BufferizationState::getAliasingOpOperand(
OpResult result) const {
if (Operation *op = result.getDefiningOp())
if (auto bufferizableOp = dyn_cast<BufferizableOpInterface>(op))
return bufferizableOp.getAliasingOpOperand(result, *this);
return {};
}
/// Determine which OpResult will alias with `opOperand` if the op is bufferized
/// in place. Return an empty OpResult if the op is not bufferizable.
OpResult
mlir::linalg::comprehensive_bufferize::BufferizationState::getAliasingOpResult(
OpOperand &opOperand) const {
if (auto bufferizableOp =
dyn_cast<BufferizableOpInterface>(opOperand.getOwner()))
return bufferizableOp.getAliasingOpResult(opOperand, *this);
return OpResult();
}
/// Return true if `opOperand` bufferizes to a memory read. Return `true` if the
/// op is not bufferizable.
bool mlir::linalg::comprehensive_bufferize::BufferizationState::
bufferizesToMemoryRead(OpOperand &opOperand) const {
if (auto bufferizableOp =
dyn_cast<BufferizableOpInterface>(opOperand.getOwner()))
return bufferizableOp.bufferizesToMemoryRead(opOperand, *this);
// Unknown op that returns a tensor. The inplace analysis does not support it.
// Conservatively return true.
return true;
}
/// Return true if `opOperand` bufferizes to a memory write. Return
/// `true` if the op is not bufferizable.
bool mlir::linalg::comprehensive_bufferize::BufferizationState::
bufferizesToMemoryWrite(OpOperand &opOperand) const {
if (auto bufferizableOp =
dyn_cast<BufferizableOpInterface>(opOperand.getOwner()))
return bufferizableOp.bufferizesToMemoryWrite(opOperand, *this);
// Unknown op that returns a tensor. The inplace analysis does not support it.
// Conservatively return true.
return true;
}
/// Return true if `opOperand` does neither read nor write but bufferizes to an
/// alias. Return false if the op is not bufferizable.
bool mlir::linalg::comprehensive_bufferize::BufferizationState::
bufferizesToAliasOnly(OpOperand &opOperand) const {
if (auto bufferizableOp =
dyn_cast<BufferizableOpInterface>(opOperand.getOwner()))
return bufferizableOp.bufferizesToAliasOnly(opOperand, *this);
// Unknown op that returns a tensor. The inplace analysis does not support it.
// Conservatively return false.
return false;
}
/// Return true if the given value is read by an op that bufferizes to a memory
/// read. Also takes into account ops that create an alias but do not read by
/// themselves (e.g., ExtractSliceOp).
bool mlir::linalg::comprehensive_bufferize::BufferizationState::isValueRead(
Value value) const {
SmallVector<OpOperand *> workingSet;
for (OpOperand &use : value.getUses())
workingSet.push_back(&use);
while (!workingSet.empty()) {
OpOperand *uMaybeReading = workingSet.pop_back_val();
// Skip over all ops that neither read nor write (but create an alias).
if (bufferizesToAliasOnly(*uMaybeReading))
for (OpOperand &use : getAliasingOpResult(*uMaybeReading).getUses())
workingSet.push_back(&use);
if (bufferizesToMemoryRead(*uMaybeReading))
return true;
}
return false;
}
// Starting from `value`, follow the use-def chain in reverse, always selecting
// the aliasing OpOperands. Find and return Values for which `condition`
// evaluates to true. OpOperands of such matching Values are not traversed any
// further.
llvm::SetVector<Value> mlir::linalg::comprehensive_bufferize::
BufferizationState::findValueInReverseUseDefChain(
Value value, llvm::function_ref<bool(Value)> condition) const {
llvm::SetVector<Value> result, workingSet;
workingSet.insert(value);
while (!workingSet.empty()) {
Value value = workingSet.pop_back_val();
if (condition(value) || value.isa<BlockArgument>()) {
result.insert(value);
continue;
}
OpResult opResult = value.cast<OpResult>();
SmallVector<OpOperand *> opOperands = getAliasingOpOperand(opResult);
if (opOperands.empty() || !options.isOpAllowed(value.getDefiningOp())) {
result.insert(value);
continue;
}
for (OpOperand *o : opOperands)
workingSet.insert(o->get());
}
return result;
}
// Find the Value of the last preceding write of a given Value.
Value mlir::linalg::comprehensive_bufferize::BufferizationState::
findLastPrecedingWrite(Value value) const {
SetVector<Value> result =
findValueInReverseUseDefChain(value, [&](Value value) {
Operation *op = value.getDefiningOp();
if (!op)
return true;
auto bufferizableOp = options.dynCastBufferizableOp(op);
if (!bufferizableOp)
return true;
return bufferizableOp.isMemoryWrite(value.cast<OpResult>(), *this);
});
// To simplify the analysis, `scf.if` ops are considered memory writes. There
// are currently no other ops where one OpResult may alias with multiple
// OpOperands. Therefore, this function should return exactly one result at
// the moment.
assert(result.size() == 1 && "expected exactly one result");
return result.front();
}
mlir::linalg::comprehensive_bufferize::BufferizationState::BufferizationState(
Operation *op, const BufferizationOptions &options)
: aliasInfo(op), options(options) {
// Set up alias sets for OpResults that must bufferize in-place. This should
// be done before making any other bufferization decisions.
op->walk([&](BufferizableOpInterface bufferizableOp) {
if (!options.isOpAllowed(bufferizableOp))
return WalkResult::skip();
for (OpResult opResult : bufferizableOp->getOpResults()) {
if (opResult.getType().isa<TensorType>())
if (bufferizableOp.mustBufferizeInPlace(opResult, *this)) {
SmallVector<OpOperand *> operands =
bufferizableOp.getAliasingOpOperand(opResult, *this);
assert(!operands.empty() &&
"expected that OpResult has aliasing OpOperand");
for (OpOperand *operand : operands)
aliasInfo.unionAliasSets(operand->get(), opResult);
aliasInfo.markInPlace(opResult);
}
}
return WalkResult::advance();
});
}
/// Return the result buffer (memref) for a given OpResult (tensor). Allocate
/// a new buffer and copy over data from the existing buffer if out-of-place
/// bufferization is necessary.
FailureOr<Value>
mlir::linalg::comprehensive_bufferize::BufferizationState::getResultBuffer(
RewriterBase &rewriter, OpResult result) const {
OpBuilder::InsertionGuard guard(rewriter);
Operation *op = result.getOwner();
SmallVector<OpOperand *> aliasingOperands = getAliasingOpOperand(result);
assert(!aliasingOperands.empty() && "could not get aliasing OpOperand");
OpOperand *opOperand = aliasingOperands.front();
Value operand = opOperand->get();
Value operandBuffer = lookupBuffer(rewriter, operand);
// Make sure that all OpOperands are the same buffer. If this is not the case,
// we would have to materialize a memref value.
// TODO: Should be looking for checking for "equivalent buffers" instead of
// operator== here, but equivalent buffers for scf.if yield values are not
// set up yet.
if (aliasingOperands.size() > 1 &&
!llvm::all_of(aliasingOperands, [&](OpOperand *o) {
return lookupBuffer(rewriter, o->get()) == operandBuffer;
}))
return FailureOr<Value>(op->emitError("result buffer is ambiguous"));
// If bufferizing out-of-place, allocate a new buffer.
if (!aliasInfo.isInPlace(result)) {
// Ops with multiple aliasing operands can currently not bufferize
// out-of-place.
assert(
aliasingOperands.size() == 1 &&
"ops with multiple aliasing OpOperands cannot bufferize out-of-place");
Location loc = op->getLoc();
// Move insertion point right after `operandBuffer`. That is where the
// allocation should be inserted (in the absence of allocation hoisting).
setInsertionPointAfter(rewriter, operandBuffer);
// Allocate the result buffer.
FailureOr<Value> resultBuffer =
createAlloc(rewriter, loc, operandBuffer, options.createDeallocs);
if (failed(resultBuffer))
return failure();
bool skipCopy = false;
// Do not copy if the last preceding write of `operand` is an op that does
// not write (skipping ops that merely create aliases). E.g., InitTensorOp.
// Note: If `findLastPrecedingWrite` reaches the end of the reverse SSA
// use-def chain, it returns that value, regardless of whether it is a
// memory write or not.
Value lastWrite = findLastPrecedingWrite(operand);
if (auto bufferizableOp = options.dynCastBufferizableOp(lastWrite))
if (!bufferizableOp.isMemoryWrite(lastWrite.cast<OpResult>(), *this))
skipCopy = true;
// Do not copy if the copied data is never read.
if (!isValueRead(result))
skipCopy = true;
// Do not copy if this op does not read the data, but writes it.
if (bufferizesToMemoryWrite(*opOperand) &&
!bufferizesToMemoryRead(*opOperand))
skipCopy = true;
if (!skipCopy) {
// The copy happens right before the op that is bufferized.
rewriter.setInsertionPoint(op);
createMemCpy(rewriter, loc, operandBuffer, *resultBuffer);
}
return resultBuffer;
}
// Bufferizing in-place. No need to allocate a new buffer.
return operandBuffer;
}
void mlir::linalg::comprehensive_bufferize::replaceOpWithBufferizedValues(
RewriterBase &rewriter, Operation *op, ValueRange values) {
OpBuilder::InsertionGuard g(rewriter);
// Replace all OpResults with the given values.
for (OpResult opResult : op->getOpResults()) {
// Skip OpResult if it has no uses.
if (opResult.getUses().empty())
continue;
Value replacement = values[opResult.getResultNumber()];
if (opResult.getType().isa<TensorType>()) {
// The OpResult is a tensor. Such values are replaced with memrefs during
// bufferization.
assert((replacement.getType().isa<MemRefType>() ||
replacement.getType().isa<UnrankedMemRefType>()) &&
"tensor op result should be replaced with a memref value");
// The existing uses of the OpResult still expect a tensor. Insert a
// ToTensorOp. Throughout bufferization, this ToTensorOp will gradually
// loose all of its users and eventually DCE away.
setInsertionPointAfter(rewriter, replacement);
replacement = rewriter.create<bufferization::ToTensorOp>(
replacement.getLoc(), replacement);
}
opResult.replaceAllUsesWith(replacement);
}
rewriter.eraseOp(op);
}
//===----------------------------------------------------------------------===//
// Bufferization-specific scoped alloc/dealloc insertion support.
//===----------------------------------------------------------------------===//
/// Move the insertion point of the given builder to the beginning of a
/// surrounding block as much as possible, while not crossing any allocation
/// hoisting barriers.
static void moveInsertionPointToAllocationHoistingBarrier(OpBuilder &b) {
Operation *op = b.getInsertionBlock()->getParentOp();
while (op) {
if (auto bufferizableOp = dyn_cast<BufferizableOpInterface>(op))
if (bufferizableOp.isAllocationHoistingBarrier())
break;
op = op->getParentOp();
}
if (!op) {
// No allocation hoisting barrier found. Hoist to FuncOp.
op = b.getInsertionBlock()->getParentOp();
if (!isa<FuncOp>(op))
op = op->getParentOfType<FuncOp>();
assert(op && "could not find enclosing FuncOp");
}
// TODO: Handle cases where allocation hoisting barrier has more than one
// region or block.
assert(op->getNumRegions() == 1 &&
"allocation hoisting barriers with >1 regions not supported");
assert(op->getRegion(0).getBlocks().size() == 1 &&
"allocation hoisting barriers with >1 blocks not supported");
b.setInsertionPointToStart(&(op->getRegion(0).front()));
}
/// Compute the type of the `memref` to use for allocating the buffer for
/// `shapedValue`. Also returns (by reference in `dynShape`), the value for the
/// dynamic dimensions in the returned `memref` type. The function may also set
/// the insertion point to an earlier location, where the allocation should
/// happen ("allocation hoisting").
static MemRefType getAllocationTypeAndShape(OpBuilder &b, Location loc,
Value shapedValue,
SmallVectorImpl<Value> &dynShape) {
MemRefType allocMemRefType =
getContiguousMemRefType(shapedValue.getType().cast<ShapedType>());
// Compute the dynamic part of the shape.
bool reifiedShapes = false;
if (auto rankedOp = dyn_cast_or_null<ReifyRankedShapedTypeOpInterface>(
shapedValue.getDefiningOp())) {
ReifiedRankedShapedTypeDims resultDims;
if (succeeded(rankedOp.reifyResultShapes(b, resultDims))) {
reifiedShapes = true;
OpResult resultValue = shapedValue.dyn_cast<OpResult>();
auto &shape = resultDims[resultValue.getResultNumber()];
for (const auto &dim : enumerate(allocMemRefType.getShape()))
if (ShapedType::isDynamic(dim.value()))
dynShape.push_back(shape[dim.index()]);
}
}
if (!reifiedShapes) {
for (const auto &dim : enumerate(allocMemRefType.getShape()))
if (ShapedType::isDynamic(dim.value())) {
assert((shapedValue.getType().isa<UnrankedMemRefType>() ||
shapedValue.getType().isa<MemRefType>()) &&
"expected MemRef type");
dynShape.push_back(
b.create<memref::DimOp>(loc, shapedValue, dim.index()));
}
}
// If the buffer is statically shaped, try to hoist it to the first enclosing
// parallel region.
// TODO: also hoist in the dynamic case. For now this relies on subsequent
// calls to LICM and buffer hoisting which will most likely not succeed.
// TODO: when packing, allocate a static bounding box which will enable more
// hoisting.
if (dynShape.empty())
moveInsertionPointToAllocationHoistingBarrier(b);
return allocMemRefType;
}
/// Create an AllocOp/DeallocOp pair, where the AllocOp is after
/// `shapedValue.getDefiningOp` (or at the top of the block in case of a
/// bbArg) and the DeallocOp is at the end of the block.
FailureOr<Value>
mlir::linalg::comprehensive_bufferize::BufferizationState::createAlloc(
OpBuilder &b, Location loc, Value shapedValue, bool deallocMemref) const {
// Take a guard before anything else.
OpBuilder::InsertionGuard g(b);
// 1. Create memory allocation.
assert(shapedValue.getType().isa<ShapedType>());
MemRefType memRefType = shapedValue.getType().dyn_cast<MemRefType>();
SmallVector<Value> dynShape;
// Note: getAllocationTypeAndShape also sets the insertion point.
MemRefType allocMemRefType =
getAllocationTypeAndShape(b, loc, shapedValue, dynShape);
FailureOr<Value> allocated = createAlloc(b, loc, allocMemRefType, dynShape);
if (failed(allocated))
return failure();
Value casted = allocated.getValue();
if (memRefType && memRefType != allocMemRefType) {
casted = b.create<memref::CastOp>(loc, memRefType, allocated.getValue());
}
if (deallocMemref) {
// 2. Create memory deallocation.
b.setInsertionPoint(allocated.getValue().getParentBlock()->getTerminator());
createDealloc(b, loc, allocated.getValue());
}
return casted;
}
/// Create a memref allocation.
FailureOr<Value>
mlir::linalg::comprehensive_bufferize::BufferizationState::createAlloc(
OpBuilder &b, Location loc, MemRefType type,
ArrayRef<Value> dynShape) const {
return options.allocationFns->allocationFn(b, loc, type, dynShape);
}
/// Create a memref deallocation.
void mlir::linalg::comprehensive_bufferize::BufferizationState::createDealloc(
OpBuilder &b, Location loc, Value allocatedBuffer) const {
return options.allocationFns->deallocationFn(b, loc, allocatedBuffer);
}
/// Create a memory copy between two memref buffers.
void mlir::linalg::comprehensive_bufferize::BufferizationState::createMemCpy(
OpBuilder &b, Location loc, Value from, Value to) const {
return options.allocationFns->memCpyFn(b, loc, from, to);
}
//===----------------------------------------------------------------------===//
// Bufferization-specific BlockAndValueMapping support with debugging.
//===----------------------------------------------------------------------===//
bool mlir::linalg::comprehensive_bufferize::isFunctionArgument(Value value) {
auto bbArg = value.dyn_cast<BlockArgument>();
if (!bbArg)
return false;
return isa<FuncOp>(bbArg.getOwner()->getParentOp());
}
Value mlir::linalg::comprehensive_bufferize::BufferizationState::lookupBuffer(
RewriterBase &rewriter, Value tensor) const {
assert(tensor.getType().isa<TensorType>() && "unexpected non-tensor type");
// Replace "%t = to_tensor %m" with %m.
if (auto toTensorOp = tensor.getDefiningOp<bufferization::ToTensorOp>())
return toTensorOp.memref();
// Insert to_memref op.
OpBuilder::InsertionGuard g(rewriter);
setInsertionPointAfter(rewriter, tensor);
Type memrefType;
if (auto rankedTensorType = tensor.getType().dyn_cast<RankedTensorType>()) {
memrefType = getDynamicMemRefType(rankedTensorType);
} else {
memrefType = getUnrankedMemRefType(
tensor.getType().cast<TensorType>().getElementType());
}
return rewriter.create<bufferization::ToMemrefOp>(tensor.getLoc(), memrefType,
tensor);
}
bool mlir::linalg::comprehensive_bufferize::BufferizationState::isInPlace(
OpResult opResult) const {
return aliasInfo.isInPlace(opResult);
}
MemRefType mlir::linalg::comprehensive_bufferize::getContiguousMemRefType(
ShapedType shapedType, MemRefLayoutAttrInterface layout,
Attribute memorySpace) {
return MemRefType::get(shapedType.getShape(), shapedType.getElementType(),
layout, memorySpace);
}
UnrankedMemRefType mlir::linalg::comprehensive_bufferize::getUnrankedMemRefType(
Type elementType, Attribute memorySpace) {
return UnrankedMemRefType::get(elementType, memorySpace);
}
MemRefType mlir::linalg::comprehensive_bufferize::getDynamicMemRefType(
RankedTensorType tensorType, unsigned addressSpace) {
// TODO: address space decisions to connect with the actual alloc.
int64_t dynamicOffset = ShapedType::kDynamicStrideOrOffset;
SmallVector<int64_t> dynamicStrides(tensorType.getRank(),
ShapedType::kDynamicStrideOrOffset);
AffineMap stridedLayout = makeStridedLinearLayoutMap(
dynamicStrides, dynamicOffset, tensorType.getContext());
return MemRefType::get(tensorType.getShape(), tensorType.getElementType(),
stridedLayout, addressSpace);
}