Nicolas Vasilache 7741de9435 [mlir][Linalg] NFC - Cleanup Linalg Pass locations and namespacing
Summary:
This diff moves the conversion pass declaration closer to its definition
and makes the namespacing of passes consistent with the rest of the
infrastructure (i.e. `mlir::linalg::createXXXPass` -> `mlir::createXXXPass`).

Reviewers: ftynse, jpienaar, mehdi_amini

Subscribers: rriddle, burmako, shauheen, antiagainst, arpith-jacob, mgester, lucyrfox, aartbik, liufengdb, llvm-commits

Tags: #llvm

Differential Revision: https://reviews.llvm.org/D72766
2020-01-15 11:06:28 -05:00

369 lines
15 KiB
C++

//===- Fusion.cpp - Implementation of linalg Fusion -----------------------===//
//
// Part of the MLIR 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
//
//===----------------------------------------------------------------------===//
//
// This file implements the linalg dialect Fusion pass.
//
//===----------------------------------------------------------------------===//
#include "mlir/Analysis/Dominance.h"
#include "mlir/Dialect/Linalg/Analysis/DependenceAnalysis.h"
#include "mlir/Dialect/Linalg/IR/LinalgOps.h"
#include "mlir/Dialect/Linalg/IR/LinalgTypes.h"
#include "mlir/Dialect/Linalg/Passes.h"
#include "mlir/Dialect/Linalg/Utils/Intrinsics.h"
#include "mlir/Dialect/Linalg/Utils/Utils.h"
#include "mlir/EDSC/Helpers.h"
#include "mlir/IR/AffineExpr.h"
#include "mlir/IR/AffineMap.h"
#include "mlir/IR/OpImplementation.h"
#include "mlir/Pass/Pass.h"
#include "mlir/Support/LLVM.h"
#include "mlir/Support/STLExtras.h"
#include "mlir/Transforms/FoldUtils.h"
#include "llvm/ADT/SetVector.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/Debug.h"
#define DEBUG_TYPE "linalg-fusion"
using namespace mlir;
using namespace mlir::edsc;
using namespace mlir::edsc::intrinsics;
using namespace mlir::linalg;
using namespace mlir::linalg::intrinsics;
using llvm::dbgs;
/// Implements a simple high-level fusion pass of linalg library operations.
///
/// In each block, linalg ops are processed in reverse textual order.
/// Given a linalg op `O`, fusion occurs by:
/// 1. inspecting the linalg ops that write into the views read by `O`. This
/// uses the SSA value of the views and a simple subview/slice analysis to
/// determine producer-consumer dependences;
/// 2. greedily fuse the linalg ops that produce subview
/// 3. inspect the fused ops and determine whether they have other remaining
/// LinalgOp uses. If not, then erase the original producing linalg op.
///
/// More advanced use cases, analyses as well as profitability heuristics are
/// left for future work.
static llvm::cl::OptionCategory clOptionsCategory(DEBUG_TYPE " options");
static llvm::cl::list<unsigned> clTileSizes(
"linalg-fusion-tile-sizes",
llvm::cl::desc(
"Tile sizes by which to tile linalg operations during linalg fusion"),
llvm::cl::ZeroOrMore, llvm::cl::MiscFlags::CommaSeparated,
llvm::cl::cat(clOptionsCategory));
// Return a cloned version of `op` that operates on `loopRanges`, assumed to be
// a subset of the original loop ranges of `op`.
// This is achieved by applying the `loopToOperandRangesMaps` permutation maps
// to the `loopRanges` in order to obtain view ranges.
static LinalgOp cloneWithLoopRanges(OpBuilder &b, Location loc, LinalgOp op,
ArrayRef<SubViewOp::Range> loopRanges) {
assert(op.hasBufferSemantics() && "expected linalg op with buffer semantics");
auto maps = loopToOperandRangesMaps(op);
SmallVector<Value, 8> clonedViews;
clonedViews.reserve(op.getNumInputsAndOutputs());
// Iterate over the inputs and outputs in order.
// Extract the subranges from the linearized ranges.
SmallVector<Value, 8> ios(op.getInputsAndOutputBuffers());
for (auto en : llvm::enumerate(ios)) {
unsigned idx = en.index();
auto map = maps[idx];
LLVM_DEBUG(dbgs() << "map: " << map << "\n");
Value view = en.value();
SmallVector<SubViewOp::Range, 4> viewRanges(map.getNumResults());
for (auto en2 : llvm::enumerate(map.getResults())) {
unsigned d = en2.index();
// loopToOperandRangesMaps are permutations-only.
unsigned loopPos = en2.value().cast<AffineDimExpr>().getPosition();
viewRanges[d] = loopRanges[loopPos];
LLVM_DEBUG(dbgs() << "\ni,j: " << en.index() << ", " << en2.index()
<< "\t"
<< "loopPos: " << loopPos << "\t" << viewRanges[d]);
}
// Construct a new subview for the tile.
unsigned rank = viewRanges.size();
SmallVector<Value, 4> offsets, sizes, strides;
offsets.reserve(rank);
sizes.reserve(rank);
strides.reserve(rank);
for (auto r : viewRanges) {
offsets.push_back(r.offset);
sizes.push_back(r.size);
strides.push_back(r.stride);
}
clonedViews.push_back(
b.create<SubViewOp>(loc, view, offsets, sizes, strides));
}
auto operands = getAssumedNonViewOperands(op);
clonedViews.append(operands.begin(), operands.end());
return op.clone(b, loc, clonedViews);
}
struct ViewDimension {
Value view;
unsigned dimension;
};
// Given an `op`, returns the first (`view`, `dimension`) pair that identifies
// the loop range at `loopDepth`. The semantics of the loopToOperandRangesMaps
// guarantees at least one such dimension is found. If multiple candidates exist
// they must agree by construction (i.e. have the same size) and we just return
// the first one.
static ViewDimension getViewDefiningLoopRange(LinalgOp op, unsigned loopDepth) {
assert(op.hasBufferSemantics() && "expected linalg op with buffer semantics");
auto maps = loopToOperandRangesMaps(op);
// Iterate over the inputs and outputs in order.
// Extract the subranges from the linearized ranges.
SmallVector<Value, 8> ios(op.getInputsAndOutputBuffers());
for (auto en : llvm::enumerate(ios)) {
unsigned idx = en.index();
auto map = maps[idx];
LLVM_DEBUG(dbgs() << "getViewDefiningLoopRange I/O idx: " << idx << "\n");
LLVM_DEBUG(dbgs() << "getViewDefiningLoopRange map: " << map << "\n");
Value view = en.value();
SmallVector<Value, 8> viewRanges(map.getNumResults(), nullptr);
for (auto en2 : llvm::enumerate(map.getResults())) {
if (loopDepth == en2.value().cast<AffineDimExpr>().getPosition()) {
LLVM_DEBUG(dbgs() << "getViewDefiningLoopRange loopDepth: " << loopDepth
<< "\n");
LLVM_DEBUG(dbgs() << "getViewDefiningLoopRange view: " << view << "\n");
return ViewDimension{view, static_cast<unsigned>(en2.index())};
}
}
}
llvm_unreachable("Expect to be able to extract a view defining loop range");
}
static LinalgOp fuse(Value producedView, LinalgOp producer, LinalgOp consumer,
unsigned consumerIdx, unsigned producerIdx,
OperationFolder *folder) {
assert(producer.hasBufferSemantics() &&
"expected linalg op with buffer semantics");
assert(consumer.hasBufferSemantics() &&
"expected linalg op with buffer semantics");
auto subView = dyn_cast_or_null<SubViewOp>(
consumer.getInput(consumerIdx).getDefiningOp());
auto slice =
dyn_cast_or_null<SliceOp>(consumer.getInput(consumerIdx).getDefiningOp());
assert(subView || slice);
(void)subView;
(void)slice;
// loopToOperandRangesMaps are permutations-only by construction:
// we can always identify a data dimension with a (at least one) loop
// dimension.
AffineMap producerMap =
loopToOperandRangesMaps(producer)[producer.getNumInputs() + producerIdx];
LLVM_DEBUG(dbgs() << "Producer Idx: " << producerIdx
<< ", producer map: " << producerMap << "\n");
unsigned nPar = producer.getNumParallelLoops();
unsigned nRed = producer.getNumReductionLoops();
unsigned nWin = producer.getNumWindowLoops();
SmallVector<SubViewOp::Range, 8> loopRanges(nPar + nRed + nWin);
// Iterate over dimensions identified by the producer map for `producerIdx`.
// This defines a subset of the loop ranges that we need to complete later.
for (auto en : llvm::enumerate(producerMap.getResults())) {
unsigned posInProducerLoop = en.value().cast<AffineDimExpr>().getPosition();
loopRanges[posInProducerLoop] = subView.getRanges()[en.index()];
}
OpBuilder b(consumer.getOperation());
auto loc = consumer.getLoc();
// Iterate over all dimensions. For the dimensions not identified by the
// producer map for `producerIdx`, we need to explicitly compute the view that
// defines the loop ranges using the `producer`.
for (unsigned i = 0, nLoops = loopRanges.size(); i < nLoops; ++i) {
if (loopRanges[i].offset)
LLVM_DEBUG(llvm::dbgs()
<< "existing LoopRange: " << loopRanges[i] << "\n");
else {
auto viewDim = getViewDefiningLoopRange(producer, i);
loopRanges[i] = SubViewOp::Range{constant_index(folder, 0),
dim(viewDim.view, viewDim.dimension),
constant_index(folder, 1)};
LLVM_DEBUG(llvm::dbgs() << "new LoopRange: " << loopRanges[i] << "\n");
}
}
return cloneWithLoopRanges(b, loc, producer, loopRanges);
}
// Encode structural fusion safety preconditions.
// Some of these will be lifted in the future with better analysis.
static bool isStructurallyFusableProducer(LinalgOp producer, Value consumedView,
LinalgOp consumer) {
assert(producer.hasBufferSemantics() &&
"expected linalg op with buffer semantics");
assert(consumer.hasBufferSemantics() &&
"expected linalg op with buffer semantics");
if (producer.getNumOutputs() != 1) {
LLVM_DEBUG(dbgs() << "\nNot structurally fusable (multi-output)");
return false;
}
// Only fuse when the producer block dominates.
DominanceInfo dom(producer.getOperation());
if (!dom.dominates(producer.getOperation()->getBlock(),
consumer.getOperation()->getBlock())) {
LLVM_DEBUG(
dbgs()
<< "\nNot structurally fusable (producer block does not dominate)");
return false;
}
return true;
}
bool mlir::linalg::isProducerLastWriteOfView(const LinalgDependenceGraph &graph,
LinalgOp consumer,
Value consumedView,
LinalgOp producer) {
assert(producer.hasBufferSemantics() &&
"expected linalg op with buffer semantics");
assert(consumer.hasBufferSemantics() &&
"expected linalg op with buffer semantics");
// Make some simple structural checks that alleviate the need for more
// complex analyses.
if (!isStructurallyFusableProducer(producer, consumedView, consumer)) {
LLVM_DEBUG(dbgs() << "\n***Not static last write due to structure:\t"
<< *producer.getOperation());
return false;
}
// Check for any interleaved write to consumedView.
if (!graph.findCoveringWrites(producer, consumer, consumedView).empty()) {
LLVM_DEBUG(dbgs() << "\n***Not fusable due to interleaved write:\t"
<< *producer.getOperation());
return false;
}
return true;
}
bool mlir::linalg::isFusableInto(const LinalgDependenceGraph &graph,
LinalgOp consumer, Value consumedView,
LinalgOp producer) {
assert(producer.hasBufferSemantics() &&
"expected linalg op with buffer semantics");
assert(consumer.hasBufferSemantics() &&
"expected linalg op with buffer semantics");
if (!isProducerLastWriteOfView(graph, consumer, consumedView, producer))
return false;
// Check for any fusion-preventing dependence to any view read/written that
// would violate dependences.
if (!graph.findCoveringDependences(producer, consumer).empty()) {
LLVM_DEBUG(dbgs() << "\n***Not fusable due to an interleaved dependence:\t"
<< *producer.getOperation());
return false;
}
return true;
}
// Only consider RAW atm.
Optional<FusionInfo> mlir::linalg::fuseProducerOf(
OpBuilder &b, LinalgOp consumer, unsigned consumerIdx,
const LinalgDependenceGraph &graph, OperationFolder *folder) {
assert(consumer.hasBufferSemantics() &&
"expected linalg op with buffer semantics");
LLVM_DEBUG(dbgs() << "\nStart examining consumer: "
<< *consumer.getOperation());
for (auto dependence : graph.getDependencesInto(
consumer, LinalgDependenceGraph::DependenceType::RAW)) {
LLVM_DEBUG(dbgs() << "\n***Consider producer:\t"
<< *dependence.dependentOpView.op << "\n");
auto producer = cast<LinalgOp>(dependence.dependentOpView.op);
// Check that the dependence is indeed on the input `consumerIdx` view.
auto consumedView = dependence.indexingView;
if (consumer.getInput(consumerIdx) != consumedView)
continue;
// Consumer consumes this view, `isStructurallyFusableProducer` also checks
// whether it is a strict subview of the producer view.
auto producedView = dependence.dependentOpView.view;
auto producerIdx = producer.getIndexOfOutputBuffer(producedView).getValue();
// `consumerIdx` and `producerIdx` exist by construction.
LLVM_DEBUG(dbgs() << "\nRAW producer: " << *producer.getOperation()
<< " view: " << producedView
<< " output index: " << producerIdx);
// Must be a subview or a slice to guarantee there are loops we can fuse
// into.
auto subView = dyn_cast_or_null<SubViewOp>(consumedView.getDefiningOp());
auto slice = dyn_cast_or_null<SliceOp>(consumedView.getDefiningOp());
if (!subView && !slice) {
LLVM_DEBUG(dbgs() << "\nNot fusable (not a subview or slice)");
continue;
}
// Simple fusability checks.
if (!isFusableInto(graph, consumer, consumedView, producer))
continue;
// Fuse `producer` just before `consumer`.
OpBuilder::InsertionGuard g(b);
b.setInsertionPoint(consumer.getOperation());
ScopedContext scope(b, consumer.getLoc());
LLVM_DEBUG(dbgs() << "Fuse into consumer: " << *consumer << "\n");
auto fusedProducer = fuse(producedView, producer, consumer, consumerIdx,
producerIdx, folder);
return FusionInfo{producer, fusedProducer};
}
return llvm::None;
}
static void fuseLinalgOpsGreedily(FuncOp f) {
LLVM_DEBUG(f.print(dbgs() << "\nBefore linalg-fusion: \n"));
OpBuilder b(f);
OperationFolder folder(f.getContext());
DenseSet<Operation *> eraseSet;
// Save original Linalg ops, we only want to make a pass over those.
SmallVector<Operation *, 8> linalgOps;
f.walk([&](LinalgOp op) {
if (op.hasBufferSemantics())
linalgOps.push_back(op);
});
Aliases aliases;
LinalgDependenceGraph G(aliases, linalgOps);
for (auto *op : llvm::reverse(linalgOps)) {
for (unsigned consumerIdx = 0, e = LinalgOp(op).getNumInputs();
consumerIdx < e; ++consumerIdx) {
if (auto fusionInfo = fuseProducerOf(b, op, consumerIdx, G, &folder))
eraseSet.insert(fusionInfo->originalProducer.getOperation());
}
}
// The `fuseProducerOf` function performs structural checks and in particular
// that no covering read or write exist between the consumer and the producer.
// As a consequence, the only fusions that may occur preserve subsequent
// dependences and are guaranteed by construction to produce the whole view.
// We may thus erase the producer once it is fused.
for (auto *e : eraseSet)
e->erase();
LLVM_DEBUG(f.print(dbgs() << "\nAfter linalg-fusion: \n"));
}
namespace {
struct LinalgFusionPass : public FunctionPass<LinalgFusionPass> {
void runOnFunction() override { fuseLinalgOpsGreedily(getFunction()); }
};
} // namespace
std::unique_ptr<OpPassBase<FuncOp>> mlir::createLinalgFusionPass() {
return std::make_unique<LinalgFusionPass>();
}
static PassRegistration<LinalgFusionPass>
pass("linalg-fusion", "Fuse operations in the linalg dialect");