mlir/lib/Analysis/DataFlow/LivenessAnalysis.cpp

   1 //===- LivenessAnalysis.cpp - Liveness analysis ---------------------------===//
   2 //
   3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
   4 // See https://llvm.org/LICENSE.txt for license information.
   5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
   6 //
   7 //===----------------------------------------------------------------------===//
   8
   9 #include "mlir/IR/SymbolTable.h"
  10 #include <cassert>
  11 #include <mlir/Analysis/DataFlow/LivenessAnalysis.h>
  12
  13 #include <mlir/Analysis/DataFlow/ConstantPropagationAnalysis.h>
  14 #include <mlir/Analysis/DataFlow/DeadCodeAnalysis.h>
  15 #include <mlir/Analysis/DataFlow/SparseAnalysis.h>
  16 #include <mlir/Analysis/DataFlowFramework.h>
  17 #include <mlir/IR/Operation.h>
  18 #include <mlir/IR/Value.h>
  19 #include <mlir/Interfaces/CallInterfaces.h>
  20 #include <mlir/Interfaces/SideEffectInterfaces.h>
  21 #include <mlir/Support/LLVM.h>
  22
  23 using namespace mlir;
  24 using namespace mlir::dataflow;
  25
  26 //===----------------------------------------------------------------------===//
  27 // Liveness
  28 //===----------------------------------------------------------------------===//
  29
  30 void Liveness::print(raw_ostream &os) const {
  31   os << (isLive ? "live" : "not live");
  32 }
  33
  34 ChangeResult Liveness::markLive() {
  35   bool wasLive = isLive;
  36   isLive = true;
  37   return wasLive ? ChangeResult::NoChange : ChangeResult::Change;
  38 }
  39
  40 ChangeResult Liveness::meet(const AbstractSparseLattice &other) {
  41   const auto *otherLiveness = reinterpret_cast<const Liveness *>(&other);
  42   return otherLiveness->isLive ? markLive() : ChangeResult::NoChange;
  43 }
  44
  45 //===----------------------------------------------------------------------===//
  46 // LivenessAnalysis
  47 //===----------------------------------------------------------------------===//
  48
  49 /// For every value, liveness analysis determines whether or not it is "live".
  50 ///
  51 /// A value is considered "live" iff it:
  52 ///   (1) has memory effects OR
  53 ///   (2) is returned by a public function OR
  54 ///   (3) is used to compute a value of type (1) or (2).
  55 /// It is also to be noted that a value could be of multiple types (1/2/3) at
  56 /// the same time.
  57 ///
  58 /// A value "has memory effects" iff it:
  59 ///   (1.a) is an operand of an op with memory effects OR
  60 ///   (1.b) is a non-forwarded branch operand and its branch op could take the
  61 ///   control to a block that has an op with memory effects OR
  62 ///   (1.c) is a non-forwarded call operand.
  63 ///
  64 /// A value `A` is said to be "used to compute" value `B` iff `B` cannot be
  65 /// computed in the absence of `A`. Thus, in this implementation, we say that
  66 /// value `A` is used to compute value `B` iff:
  67 ///   (3.a) `B` is a result of an op with operand `A` OR
  68 ///   (3.b) `A` is used to compute some value `C` and `C` is used to compute
  69 ///   `B`.
  70
  71 LogicalResult
  72 LivenessAnalysis::visitOperation(Operation *op, ArrayRef<Liveness *> operands,
  73                                  ArrayRef<const Liveness *> results) {
  74   // This marks values of type (1.a) liveness as "live".
  75   if (!isMemoryEffectFree(op)) {
  76     for (auto *operand : operands)
  77       propagateIfChanged(operand, operand->markLive());
  78   }
  79
  80   // This marks values of type (3) liveness as "live".
  81   bool foundLiveResult = false;
  82   for (const Liveness *r : results) {
  83     if (r->isLive && !foundLiveResult) {
  84       // It is assumed that each operand is used to compute each result of an
  85       // op. Thus, if at least one result is live, each operand is live.
  86       for (Liveness *operand : operands)
  87         meet(operand, *r);
  88       foundLiveResult = true;
  89     }
  90     addDependency(const_cast<Liveness *>(r), getProgramPointAfter(op));
  91   }
  92   return success();
  93 }
  94
  95 void LivenessAnalysis::visitBranchOperand(OpOperand &operand) {
  96   // We know (at the moment) and assume (for the future) that `operand` is a
  97   // non-forwarded branch operand of a `RegionBranchOpInterface`,
  98   // `BranchOpInterface`, `RegionBranchTerminatorOpInterface` or return-like op.
  99   Operation *op = operand.getOwner();
 100   assert((isa<RegionBranchOpInterface>(op) || isa<BranchOpInterface>(op) ||
 101           isa<RegionBranchTerminatorOpInterface>(op)) &&
 102          "expected the op to be `RegionBranchOpInterface`, "
 103          "`BranchOpInterface` or `RegionBranchTerminatorOpInterface`");
 104
 105   // The lattices of the non-forwarded branch operands don't get updated like
 106   // the forwarded branch operands or the non-branch operands. Thus they need
 107   // to be handled separately. This is where we handle them.
 108
 109   // This marks values of type (1.b) liveness as "live". A non-forwarded
 110   // branch operand will be live if a block where its op could take the control
 111   // has an op with memory effects.
 112   // Populating such blocks in `blocks`.
 113   SmallVector<Block *, 4> blocks;
 114   if (isa<RegionBranchOpInterface>(op)) {
 115     // When the op is a `RegionBranchOpInterface`, like an `scf.for` or an
 116     // `scf.index_switch` op, its branch operand controls the flow into this
 117     // op's regions.
 118     for (Region &region : op->getRegions()) {
 119       for (Block &block : region)
 120         blocks.push_back(&block);
 121     }
 122   } else if (isa<BranchOpInterface>(op)) {
 123     // When the op is a `BranchOpInterface`, like a `cf.cond_br` or a
 124     // `cf.switch` op, its branch operand controls the flow into this op's
 125     // successors.
 126     blocks = op->getSuccessors();
 127   } else {
 128     // When the op is a `RegionBranchTerminatorOpInterface`, like an
 129     // `scf.condition` op or return-like, like an `scf.yield` op, its branch
 130     // operand controls the flow into this op's parent's (which is a
 131     // `RegionBranchOpInterface`'s) regions.
 132     Operation *parentOp = op->getParentOp();
 133     assert(isa<RegionBranchOpInterface>(parentOp) &&
 134            "expected parent op to implement `RegionBranchOpInterface`");
 135     for (Region &region : parentOp->getRegions()) {
 136       for (Block &block : region)
 137         blocks.push_back(&block);
 138     }
 139   }
 140   bool foundMemoryEffectingOp = false;
 141   for (Block *block : blocks) {
 142     if (foundMemoryEffectingOp)
 143       break;
 144     for (Operation &nestedOp : *block) {
 145       if (!isMemoryEffectFree(&nestedOp)) {
 146         Liveness *operandLiveness = getLatticeElement(operand.get());
 147         propagateIfChanged(operandLiveness, operandLiveness->markLive());
 148         foundMemoryEffectingOp = true;
 149         break;
 150       }
 151     }
 152   }
 153
 154   // Now that we have checked for memory-effecting ops in the blocks of concern,
 155   // we will simply visit the op with this non-forwarded operand to potentially
 156   // mark it "live" due to type (1.a/3) liveness.
 157   SmallVector<Liveness *, 4> operandLiveness;
 158   operandLiveness.push_back(getLatticeElement(operand.get()));
 159   SmallVector<const Liveness *, 4> resultsLiveness;
 160   for (const Value result : op->getResults())
 161     resultsLiveness.push_back(getLatticeElement(result));
 162   (void)visitOperation(op, operandLiveness, resultsLiveness);
 163
 164   // We also visit the parent op with the parent's results and this operand if
 165   // `op` is a `RegionBranchTerminatorOpInterface` because its non-forwarded
 166   // operand depends on not only its memory effects/results but also on those of
 167   // its parent's.
 168   if (!isa<RegionBranchTerminatorOpInterface>(op))
 169     return;
 170   Operation *parentOp = op->getParentOp();
 171   SmallVector<const Liveness *, 4> parentResultsLiveness;
 172   for (const Value parentResult : parentOp->getResults())
 173     parentResultsLiveness.push_back(getLatticeElement(parentResult));
 174   (void)visitOperation(parentOp, operandLiveness, parentResultsLiveness);
 175 }
 176
 177 void LivenessAnalysis::visitCallOperand(OpOperand &operand) {
 178   // We know (at the moment) and assume (for the future) that `operand` is a
 179   // non-forwarded call operand of an op implementing `CallOpInterface`.
 180   assert(isa<CallOpInterface>(operand.getOwner()) &&
 181          "expected the op to implement `CallOpInterface`");
 182
 183   // The lattices of the non-forwarded call operands don't get updated like the
 184   // forwarded call operands or the non-call operands. Thus they need to be
 185   // handled separately. This is where we handle them.
 186
 187   // This marks values of type (1.c) liveness as "live". A non-forwarded
 188   // call operand is live.
 189   Liveness *operandLiveness = getLatticeElement(operand.get());
 190   propagateIfChanged(operandLiveness, operandLiveness->markLive());
 191 }
 192
 193 void LivenessAnalysis::setToExitState(Liveness *lattice) {
 194   // This marks values of type (2) liveness as "live".
 195   (void)lattice->markLive();
 196 }
 197
 198 //===----------------------------------------------------------------------===//
 199 // RunLivenessAnalysis
 200 //===----------------------------------------------------------------------===//
 201
 202 RunLivenessAnalysis::RunLivenessAnalysis(Operation *op) {
 203   SymbolTableCollection symbolTable;
 204
 205   solver.load<DeadCodeAnalysis>();
 206   solver.load<SparseConstantPropagation>();
 207   solver.load<LivenessAnalysis>(symbolTable);
 208   (void)solver.initializeAndRun(op);
 209 }
 210
 211 const Liveness *RunLivenessAnalysis::getLiveness(Value val) {
 212   return solver.lookupState<Liveness>(val);
 213 }