//===- VPlanUtils.cpp - VPlan-related utilities ---------------------------===// // // 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 "VPlanUtils.h" #include "VPlanCFG.h" #include "VPlanPatternMatch.h" #include "llvm/ADT/TypeSwitch.h" #include "llvm/Analysis/ScalarEvolutionExpressions.h" using namespace llvm; using namespace llvm::VPlanPatternMatch; bool vputils::onlyFirstLaneUsed(const VPValue *Def) { return all_of(Def->users(), [Def](const VPUser *U) { return U->onlyFirstLaneUsed(Def); }); } bool vputils::onlyFirstPartUsed(const VPValue *Def) { return all_of(Def->users(), [Def](const VPUser *U) { return U->onlyFirstPartUsed(Def); }); } bool vputils::onlyScalarValuesUsed(const VPValue *Def) { return all_of(Def->users(), [Def](const VPUser *U) { return U->usesScalars(Def); }); } VPValue *vputils::getOrCreateVPValueForSCEVExpr(VPlan &Plan, const SCEV *Expr) { if (auto *Expanded = Plan.getSCEVExpansion(Expr)) return Expanded; VPValue *Expanded = nullptr; if (auto *E = dyn_cast(Expr)) Expanded = Plan.getOrAddLiveIn(E->getValue()); else { auto *U = dyn_cast(Expr); // Skip SCEV expansion if Expr is a SCEVUnknown wrapping a non-instruction // value. Otherwise the value may be defined in a loop and using it directly // will break LCSSA form. The SCEV expansion takes care of preserving LCSSA // form. if (U && !isa(U->getValue())) { Expanded = Plan.getOrAddLiveIn(U->getValue()); } else { Expanded = new VPExpandSCEVRecipe(Expr); Plan.getEntry()->appendRecipe(Expanded->getDefiningRecipe()); } } Plan.addSCEVExpansion(Expr, Expanded); return Expanded; } bool vputils::isHeaderMask(const VPValue *V, VPlan &Plan) { if (isa(V)) return true; auto IsWideCanonicalIV = [](VPValue *A) { return isa(A) || (isa(A) && cast(A)->isCanonical()); }; VPValue *A, *B; if (match(V, m_ActiveLaneMask(m_VPValue(A), m_VPValue(B), m_One()))) return B == Plan.getTripCount() && (match(A, m_ScalarIVSteps(m_Specific(Plan.getCanonicalIV()), m_One(), m_Specific(&Plan.getVF()))) || IsWideCanonicalIV(A)); return match(V, m_Binary(m_VPValue(A), m_VPValue(B))) && IsWideCanonicalIV(A) && B == Plan.getOrCreateBackedgeTakenCount(); } const SCEV *vputils::getSCEVExprForVPValue(VPValue *V, ScalarEvolution &SE) { if (V->isLiveIn()) { if (Value *LiveIn = V->getLiveInIRValue()) return SE.getSCEV(LiveIn); return SE.getCouldNotCompute(); } // TODO: Support constructing SCEVs for more recipes as needed. return TypeSwitch(V->getDefiningRecipe()) .Case( [](const VPExpandSCEVRecipe *R) { return R->getSCEV(); }) .Default([&SE](const VPRecipeBase *) { return SE.getCouldNotCompute(); }); } bool vputils::isUniformAcrossVFsAndUFs(VPValue *V) { // Live-ins are uniform. if (V->isLiveIn()) return true; VPRecipeBase *R = V->getDefiningRecipe(); if (R && V->isDefinedOutsideLoopRegions()) { if (match(V->getDefiningRecipe(), m_VPInstruction())) return false; return all_of(R->operands(), isUniformAcrossVFsAndUFs); } auto *CanonicalIV = R->getParent()->getPlan()->getCanonicalIV(); // Canonical IV chain is uniform. if (V == CanonicalIV || V == CanonicalIV->getBackedgeValue()) return true; return TypeSwitch(R) .Case([](const auto *R) { return true; }) .Case([](const auto *R) { // Loads and stores that are uniform across VF lanes are handled by // VPReplicateRecipe.IsUniform. They are also uniform across UF parts if // all their operands are invariant. // TODO: Further relax the restrictions. return R->isSingleScalar() && (isa(R->getUnderlyingValue())) && all_of(R->operands(), isUniformAcrossVFsAndUFs); }) .Case([](const auto *VPI) { return VPI->isScalarCast() && isUniformAcrossVFsAndUFs(VPI->getOperand(0)); }) .Case([](const auto *R) { // A cast is uniform according to its operand. return isUniformAcrossVFsAndUFs(R->getOperand(0)); }) .Default([](const VPRecipeBase *) { // A value is considered non-uniform // unless proven otherwise. return false; }); } VPBasicBlock *vputils::getFirstLoopHeader(VPlan &Plan, VPDominatorTree &VPDT) { auto DepthFirst = vp_depth_first_shallow(Plan.getEntry()); auto I = find_if(DepthFirst, [&VPDT](VPBlockBase *VPB) { return VPBlockUtils::isHeader(VPB, VPDT); }); return I == DepthFirst.end() ? nullptr : cast(*I); } unsigned vputils::getVFScaleFactor(VPRecipeBase *R) { if (!R) return 1; if (auto *RR = dyn_cast(R)) return RR->getVFScaleFactor(); if (auto *RR = dyn_cast(R)) return RR->getVFScaleFactor(); assert( (!isa(R) || cast(R)->getOpcode() != VPInstruction::ReductionStartVector) && "getting scaling factor of reduction-start-vector not implemented yet"); return 1; } std::optional vputils::getRecipesForUncountableExit(VPlan &Plan, SmallVectorImpl &Recipes, SmallVectorImpl &GEPs) { // Given a VPlan like the following (just including the recipes contributing // to loop control exiting here, not the actual work), we're looking to match // the recipes contributing to the uncountable exit condition comparison // (here, vp<%4>) back to either live-ins or the address nodes for the load // used as part of the uncountable exit comparison so that we can copy them // to a preheader and rotate the address in the loop to the next vector // iteration. // // Currently, the address of the load is restricted to a GEP with 2 operands // and a live-in base address. This constraint may be relaxed later. // // VPlan ' for UF>=1' { // Live-in vp<%0> = VF // Live-in ir<64> = original trip-count // // entry: // Successor(s): preheader, vector.ph // // vector.ph: // Successor(s): vector loop // // vector loop: { // vector.body: // EMIT vp<%2> = CANONICAL-INDUCTION ir<0> // vp<%3> = SCALAR-STEPS vp<%2>, ir<1>, vp<%0> // CLONE ir<%ee.addr> = getelementptr ir<0>, vp<%3> // WIDEN ir<%ee.load> = load ir<%ee.addr> // WIDEN vp<%4> = icmp eq ir<%ee.load>, ir<0> // EMIT vp<%5> = any-of vp<%4> // EMIT vp<%6> = add vp<%2>, vp<%0> // EMIT vp<%7> = icmp eq vp<%6>, ir<64> // EMIT vp<%8> = or vp<%5>, vp<%7> // EMIT branch-on-cond vp<%8> // No successors // } // Successor(s): middle.block // // middle.block: // Successor(s): preheader // // preheader: // No successors // } // Find the uncountable loop exit condition. auto *Region = Plan.getVectorLoopRegion(); VPValue *UncountableCondition = nullptr; if (!match(Region->getExitingBasicBlock()->getTerminator(), m_BranchOnCond(m_OneUse(m_c_BinaryOr( m_AnyOf(m_VPValue(UncountableCondition)), m_VPValue()))))) return std::nullopt; SmallVector Worklist; Worklist.push_back(UncountableCondition); while (!Worklist.empty()) { VPValue *V = Worklist.pop_back_val(); // Any value defined outside the loop does not need to be copied. if (V->isDefinedOutsideLoopRegions()) continue; // FIXME: Remove the single user restriction; it's here because we're // starting with the simplest set of loops we can, and multiple // users means needing to add PHI nodes in the transform. if (V->getNumUsers() > 1) return std::nullopt; VPValue *Op1, *Op2; // Walk back through recipes until we find at least one load from memory. if (match(V, m_ICmp(m_VPValue(Op1), m_VPValue(Op2)))) { Worklist.push_back(Op1); Worklist.push_back(Op2); Recipes.push_back(V->getDefiningRecipe()); } else if (auto *Load = dyn_cast(V)) { // Reject masked loads for the time being; they make the exit condition // more complex. if (Load->isMasked()) return std::nullopt; VPValue *GEP = Load->getAddr(); if (!match(GEP, m_GetElementPtr(m_LiveIn(), m_VPValue()))) return std::nullopt; Recipes.push_back(Load); Recipes.push_back(GEP->getDefiningRecipe()); GEPs.push_back(GEP->getDefiningRecipe()); } else return std::nullopt; } return UncountableCondition; }