//===------ IslNodeBuilder.cpp - Translate an isl AST into a LLVM-IR AST---===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file contains the IslNodeBuilder, a class to translate an isl AST into // a LLVM-IR AST. // //===----------------------------------------------------------------------===// #include "polly/CodeGen/IslNodeBuilder.h" #include "polly/CodeGen/BlockGenerators.h" #include "polly/CodeGen/CodeGeneration.h" #include "polly/CodeGen/IslAst.h" #include "polly/CodeGen/IslExprBuilder.h" #include "polly/CodeGen/LoopGenerators.h" #include "polly/CodeGen/Utils.h" #include "polly/Config/config.h" #include "polly/DependenceInfo.h" #include "polly/LinkAllPasses.h" #include "polly/ScopInfo.h" #include "polly/Support/GICHelper.h" #include "polly/Support/SCEVValidator.h" #include "polly/Support/ScopHelper.h" #include "llvm/ADT/PostOrderIterator.h" #include "llvm/ADT/SmallPtrSet.h" #include "llvm/Analysis/LoopInfo.h" #include "llvm/Analysis/PostDominators.h" #include "llvm/IR/DataLayout.h" #include "llvm/IR/Module.h" #include "llvm/IR/Verifier.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/Debug.h" #include "llvm/Transforms/Utils/BasicBlockUtils.h" #include "isl/aff.h" #include "isl/ast.h" #include "isl/ast_build.h" #include "isl/list.h" #include "isl/map.h" #include "isl/set.h" #include "isl/union_map.h" #include "isl/union_set.h" using namespace polly; using namespace llvm; // The maximal number of dimensions we allow during invariant load construction. // More complex access ranges will result in very high compile time and are also // unlikely to result in good code. This value is very high and should only // trigger for corner cases (e.g., the "dct_luma" function in h264, SPEC2006). static int const MaxDimensionsInAccessRange = 9; __isl_give isl_ast_expr * IslNodeBuilder::getUpperBound(__isl_keep isl_ast_node *For, ICmpInst::Predicate &Predicate) { isl_id *UBID, *IteratorID; isl_ast_expr *Cond, *Iterator, *UB, *Arg0; isl_ast_op_type Type; Cond = isl_ast_node_for_get_cond(For); Iterator = isl_ast_node_for_get_iterator(For); isl_ast_expr_get_type(Cond); assert(isl_ast_expr_get_type(Cond) == isl_ast_expr_op && "conditional expression is not an atomic upper bound"); Type = isl_ast_expr_get_op_type(Cond); switch (Type) { case isl_ast_op_le: Predicate = ICmpInst::ICMP_SLE; break; case isl_ast_op_lt: Predicate = ICmpInst::ICMP_SLT; break; default: llvm_unreachable("Unexpected comparision type in loop conditon"); } Arg0 = isl_ast_expr_get_op_arg(Cond, 0); assert(isl_ast_expr_get_type(Arg0) == isl_ast_expr_id && "conditional expression is not an atomic upper bound"); UBID = isl_ast_expr_get_id(Arg0); assert(isl_ast_expr_get_type(Iterator) == isl_ast_expr_id && "Could not get the iterator"); IteratorID = isl_ast_expr_get_id(Iterator); assert(UBID == IteratorID && "conditional expression is not an atomic upper bound"); UB = isl_ast_expr_get_op_arg(Cond, 1); isl_ast_expr_free(Cond); isl_ast_expr_free(Iterator); isl_ast_expr_free(Arg0); isl_id_free(IteratorID); isl_id_free(UBID); return UB; } /// @brief Return true if a return value of Predicate is true for the value /// represented by passed isl_ast_expr_int. static bool checkIslAstExprInt(__isl_take isl_ast_expr *Expr, isl_bool (*Predicate)(__isl_keep isl_val *)) { if (isl_ast_expr_get_type(Expr) != isl_ast_expr_int) { isl_ast_expr_free(Expr); return false; } auto ExprVal = isl_ast_expr_get_val(Expr); isl_ast_expr_free(Expr); if (Predicate(ExprVal) != true) { isl_val_free(ExprVal); return false; } isl_val_free(ExprVal); return true; } int IslNodeBuilder::getNumberOfIterations(__isl_keep isl_ast_node *For) { assert(isl_ast_node_get_type(For) == isl_ast_node_for); auto Body = isl_ast_node_for_get_body(For); // First, check if we can actually handle this code switch (isl_ast_node_get_type(Body)) { case isl_ast_node_user: break; case isl_ast_node_block: { isl_ast_node_list *List = isl_ast_node_block_get_children(Body); for (int i = 0; i < isl_ast_node_list_n_ast_node(List); ++i) { isl_ast_node *Node = isl_ast_node_list_get_ast_node(List, i); int Type = isl_ast_node_get_type(Node); isl_ast_node_free(Node); if (Type != isl_ast_node_user) { isl_ast_node_list_free(List); isl_ast_node_free(Body); return -1; } } isl_ast_node_list_free(List); break; } default: isl_ast_node_free(Body); return -1; } isl_ast_node_free(Body); auto Init = isl_ast_node_for_get_init(For); if (!checkIslAstExprInt(Init, isl_val_is_zero)) return -1; auto Inc = isl_ast_node_for_get_inc(For); if (!checkIslAstExprInt(Inc, isl_val_is_one)) return -1; CmpInst::Predicate Predicate; auto UB = getUpperBound(For, Predicate); if (isl_ast_expr_get_type(UB) != isl_ast_expr_int) { isl_ast_expr_free(UB); return -1; } auto UpVal = isl_ast_expr_get_val(UB); isl_ast_expr_free(UB); int NumberIterations = isl_val_get_num_si(UpVal); isl_val_free(UpVal); if (NumberIterations < 0) return -1; if (Predicate == CmpInst::ICMP_SLT) return NumberIterations; else return NumberIterations + 1; } struct SubtreeReferences { LoopInfo &LI; ScalarEvolution &SE; Scop &S; ValueMapT &GlobalMap; SetVector &Values; SetVector &SCEVs; BlockGenerator &BlockGen; }; /// @brief Extract the values and SCEVs needed to generate code for a block. static int findReferencesInBlock(struct SubtreeReferences &References, const ScopStmt *Stmt, const BasicBlock *BB) { for (const Instruction &Inst : *BB) for (Value *SrcVal : Inst.operands()) { auto *Scope = References.LI.getLoopFor(BB); if (canSynthesize(SrcVal, References.S, &References.LI, &References.SE, Scope)) { References.SCEVs.insert(References.SE.getSCEVAtScope(SrcVal, Scope)); continue; } else if (Value *NewVal = References.GlobalMap.lookup(SrcVal)) References.Values.insert(NewVal); } return 0; } /// Extract the out-of-scop values and SCEVs referenced from a ScopStmt. /// /// This includes the SCEVUnknowns referenced by the SCEVs used in the /// statement and the base pointers of the memory accesses. For scalar /// statements we force the generation of alloca memory locations and list /// these locations in the set of out-of-scop values as well. /// /// @param Stmt The statement for which to extract the information. /// @param UserPtr A void pointer that can be casted to a SubtreeReferences /// structure. static isl_stat addReferencesFromStmt(const ScopStmt *Stmt, void *UserPtr) { auto &References = *static_cast(UserPtr); if (Stmt->isBlockStmt()) findReferencesInBlock(References, Stmt, Stmt->getBasicBlock()); else { assert(Stmt->isRegionStmt() && "Stmt was neither block nor region statement"); for (const BasicBlock *BB : Stmt->getRegion()->blocks()) findReferencesInBlock(References, Stmt, BB); } for (auto &Access : *Stmt) { if (Access->isArrayKind()) { auto *BasePtr = Access->getScopArrayInfo()->getBasePtr(); if (Instruction *OpInst = dyn_cast(BasePtr)) if (Stmt->getParent()->contains(OpInst)) continue; References.Values.insert(BasePtr); continue; } References.Values.insert(References.BlockGen.getOrCreateAlloca(*Access)); } return isl_stat_ok; } /// Extract the out-of-scop values and SCEVs referenced from a set describing /// a ScopStmt. /// /// This includes the SCEVUnknowns referenced by the SCEVs used in the /// statement and the base pointers of the memory accesses. For scalar /// statements we force the generation of alloca memory locations and list /// these locations in the set of out-of-scop values as well. /// /// @param Set A set which references the ScopStmt we are interested in. /// @param UserPtr A void pointer that can be casted to a SubtreeReferences /// structure. static isl_stat addReferencesFromStmtSet(isl_set *Set, void *UserPtr) { isl_id *Id = isl_set_get_tuple_id(Set); auto *Stmt = static_cast(isl_id_get_user(Id)); isl_id_free(Id); isl_set_free(Set); return addReferencesFromStmt(Stmt, UserPtr); } /// Extract the out-of-scop values and SCEVs referenced from a union set /// referencing multiple ScopStmts. /// /// This includes the SCEVUnknowns referenced by the SCEVs used in the /// statement and the base pointers of the memory accesses. For scalar /// statements we force the generation of alloca memory locations and list /// these locations in the set of out-of-scop values as well. /// /// @param USet A union set referencing the ScopStmts we are interested /// in. /// @param References The SubtreeReferences data structure through which /// results are returned and further information is /// provided. static void addReferencesFromStmtUnionSet(isl_union_set *USet, struct SubtreeReferences &References) { isl_union_set_foreach_set(USet, addReferencesFromStmtSet, &References); isl_union_set_free(USet); } __isl_give isl_union_map * IslNodeBuilder::getScheduleForAstNode(__isl_keep isl_ast_node *For) { return IslAstInfo::getSchedule(For); } void IslNodeBuilder::getReferencesInSubtree(__isl_keep isl_ast_node *For, SetVector &Values, SetVector &Loops) { SetVector SCEVs; struct SubtreeReferences References = { LI, SE, S, ValueMap, Values, SCEVs, getBlockGenerator()}; for (const auto &I : IDToValue) Values.insert(I.second); for (const auto &I : OutsideLoopIterations) Values.insert(cast(I.second)->getValue()); isl_union_set *Schedule = isl_union_map_domain(getScheduleForAstNode(For)); addReferencesFromStmtUnionSet(Schedule, References); for (const SCEV *Expr : SCEVs) { findValues(Expr, SE, Values); findLoops(Expr, Loops); } Values.remove_if([](const Value *V) { return isa(V); }); /// Remove loops that contain the scop or that are part of the scop, as they /// are considered local. This leaves only loops that are before the scop, but /// do not contain the scop itself. Loops.remove_if([this](const Loop *L) { return S.contains(L) || L->contains(S.getEntry()); }); } void IslNodeBuilder::updateValues(ValueMapT &NewValues) { SmallPtrSet Inserted; for (const auto &I : IDToValue) { IDToValue[I.first] = NewValues[I.second]; Inserted.insert(I.second); } for (const auto &I : NewValues) { if (Inserted.count(I.first)) continue; ValueMap[I.first] = I.second; } } void IslNodeBuilder::createUserVector(__isl_take isl_ast_node *User, std::vector &IVS, __isl_take isl_id *IteratorID, __isl_take isl_union_map *Schedule) { isl_ast_expr *Expr = isl_ast_node_user_get_expr(User); isl_ast_expr *StmtExpr = isl_ast_expr_get_op_arg(Expr, 0); isl_id *Id = isl_ast_expr_get_id(StmtExpr); isl_ast_expr_free(StmtExpr); ScopStmt *Stmt = (ScopStmt *)isl_id_get_user(Id); std::vector VLTS(IVS.size()); isl_union_set *Domain = isl_union_set_from_set(Stmt->getDomain()); Schedule = isl_union_map_intersect_domain(Schedule, Domain); isl_map *S = isl_map_from_union_map(Schedule); auto *NewAccesses = createNewAccesses(Stmt, User); createSubstitutionsVector(Expr, Stmt, VLTS, IVS, IteratorID); VectorBlockGenerator::generate(BlockGen, *Stmt, VLTS, S, NewAccesses); isl_id_to_ast_expr_free(NewAccesses); isl_map_free(S); isl_id_free(Id); isl_ast_node_free(User); } void IslNodeBuilder::createMark(__isl_take isl_ast_node *Node) { auto *Id = isl_ast_node_mark_get_id(Node); auto Child = isl_ast_node_mark_get_node(Node); isl_ast_node_free(Node); // If a child node of a 'SIMD mark' is a loop that has a single iteration, // it will be optimized away and we should skip it. if (!strcmp(isl_id_get_name(Id), "SIMD") && isl_ast_node_get_type(Child) == isl_ast_node_for) { bool Vector = PollyVectorizerChoice == VECTORIZER_POLLY; int VectorWidth = getNumberOfIterations(Child); if (Vector && 1 < VectorWidth && VectorWidth <= 16) createForVector(Child, VectorWidth); else createForSequential(Child, true); isl_id_free(Id); return; } create(Child); isl_id_free(Id); } void IslNodeBuilder::createForVector(__isl_take isl_ast_node *For, int VectorWidth) { isl_ast_node *Body = isl_ast_node_for_get_body(For); isl_ast_expr *Init = isl_ast_node_for_get_init(For); isl_ast_expr *Inc = isl_ast_node_for_get_inc(For); isl_ast_expr *Iterator = isl_ast_node_for_get_iterator(For); isl_id *IteratorID = isl_ast_expr_get_id(Iterator); Value *ValueLB = ExprBuilder.create(Init); Value *ValueInc = ExprBuilder.create(Inc); CmpInst::Predicate Predicate; auto *UB = getUpperBound(For, Predicate); auto *ValueUB = ExprBuilder.create(UB); ExprBuilder.unifyTypes(ValueLB, ValueUB, ValueInc); std::vector IVS(VectorWidth); IVS[0] = ValueLB; for (int i = 1; i < VectorWidth; i++) IVS[i] = Builder.CreateAdd(IVS[i - 1], ValueInc, "p_vector_iv"); isl_union_map *Schedule = getScheduleForAstNode(For); assert(Schedule && "For statement annotation does not contain its schedule"); IDToValue[IteratorID] = ValueLB; switch (isl_ast_node_get_type(Body)) { case isl_ast_node_user: createUserVector(Body, IVS, isl_id_copy(IteratorID), isl_union_map_copy(Schedule)); break; case isl_ast_node_block: { isl_ast_node_list *List = isl_ast_node_block_get_children(Body); for (int i = 0; i < isl_ast_node_list_n_ast_node(List); ++i) createUserVector(isl_ast_node_list_get_ast_node(List, i), IVS, isl_id_copy(IteratorID), isl_union_map_copy(Schedule)); isl_ast_node_free(Body); isl_ast_node_list_free(List); break; } default: isl_ast_node_dump(Body); llvm_unreachable("Unhandled isl_ast_node in vectorizer"); } IDToValue.erase(IDToValue.find(IteratorID)); isl_id_free(IteratorID); isl_union_map_free(Schedule); isl_ast_node_free(For); isl_ast_expr_free(Iterator); } void IslNodeBuilder::createForSequential(__isl_take isl_ast_node *For, bool KnownParallel) { isl_ast_node *Body; isl_ast_expr *Init, *Inc, *Iterator, *UB; isl_id *IteratorID; Value *ValueLB, *ValueUB, *ValueInc; BasicBlock *ExitBlock; Value *IV; CmpInst::Predicate Predicate; bool Parallel; Parallel = KnownParallel || (IslAstInfo::isParallel(For) && !IslAstInfo::isReductionParallel(For)); Body = isl_ast_node_for_get_body(For); // isl_ast_node_for_is_degenerate(For) // // TODO: For degenerated loops we could generate a plain assignment. // However, for now we just reuse the logic for normal loops, which will // create a loop with a single iteration. Init = isl_ast_node_for_get_init(For); Inc = isl_ast_node_for_get_inc(For); Iterator = isl_ast_node_for_get_iterator(For); IteratorID = isl_ast_expr_get_id(Iterator); UB = getUpperBound(For, Predicate); ValueLB = ExprBuilder.create(Init); ValueUB = ExprBuilder.create(UB); ValueInc = ExprBuilder.create(Inc); ExprBuilder.unifyTypes(ValueLB, ValueUB, ValueInc); // If we can show that LB UB holds at least once, we can // omit the GuardBB in front of the loop. bool UseGuardBB = !SE.isKnownPredicate(Predicate, SE.getSCEV(ValueLB), SE.getSCEV(ValueUB)); IV = createLoop(ValueLB, ValueUB, ValueInc, Builder, P, LI, DT, ExitBlock, Predicate, &Annotator, Parallel, UseGuardBB); IDToValue[IteratorID] = IV; create(Body); Annotator.popLoop(Parallel); IDToValue.erase(IDToValue.find(IteratorID)); Builder.SetInsertPoint(&ExitBlock->front()); isl_ast_node_free(For); isl_ast_expr_free(Iterator); isl_id_free(IteratorID); } /// @brief Remove the BBs contained in a (sub)function from the dominator tree. /// /// This function removes the basic blocks that are part of a subfunction from /// the dominator tree. Specifically, when generating code it may happen that at /// some point the code generation continues in a new sub-function (e.g., when /// generating OpenMP code). The basic blocks that are created in this /// sub-function are then still part of the dominator tree of the original /// function, such that the dominator tree reaches over function boundaries. /// This is not only incorrect, but also causes crashes. This function now /// removes from the dominator tree all basic blocks that are dominated (and /// consequently reachable) from the entry block of this (sub)function. /// /// FIXME: A LLVM (function or region) pass should not touch anything outside of /// the function/region it runs on. Hence, the pure need for this function shows /// that we do not comply to this rule. At the moment, this does not cause any /// issues, but we should be aware that such issues may appear. Unfortunately /// the current LLVM pass infrastructure does not allow to make Polly a module /// or call-graph pass to solve this issue, as such a pass would not have access /// to the per-function analyses passes needed by Polly. A future pass manager /// infrastructure is supposed to enable such kind of access possibly allowing /// us to create a cleaner solution here. /// /// FIXME: Instead of adding the dominance information and then dropping it /// later on, we should try to just not add it in the first place. This requires /// some careful testing to make sure this does not break in interaction with /// the SCEVBuilder and SplitBlock which may rely on the dominator tree or /// which may try to update it. /// /// @param F The function which contains the BBs to removed. /// @param DT The dominator tree from which to remove the BBs. static void removeSubFuncFromDomTree(Function *F, DominatorTree &DT) { DomTreeNode *N = DT.getNode(&F->getEntryBlock()); std::vector Nodes; // We can only remove an element from the dominator tree, if all its children // have been removed. To ensure this we obtain the list of nodes to remove // using a post-order tree traversal. for (po_iterator I = po_begin(N), E = po_end(N); I != E; ++I) Nodes.push_back(I->getBlock()); for (BasicBlock *BB : Nodes) DT.eraseNode(BB); } void IslNodeBuilder::createForParallel(__isl_take isl_ast_node *For) { isl_ast_node *Body; isl_ast_expr *Init, *Inc, *Iterator, *UB; isl_id *IteratorID; Value *ValueLB, *ValueUB, *ValueInc; Value *IV; CmpInst::Predicate Predicate; // The preamble of parallel code interacts different than normal code with // e.g., scalar initialization. Therefore, we ensure the parallel code is // separated from the last basic block. BasicBlock *ParBB = SplitBlock(Builder.GetInsertBlock(), &*Builder.GetInsertPoint(), &DT, &LI); ParBB->setName("polly.parallel.for"); Builder.SetInsertPoint(&ParBB->front()); Body = isl_ast_node_for_get_body(For); Init = isl_ast_node_for_get_init(For); Inc = isl_ast_node_for_get_inc(For); Iterator = isl_ast_node_for_get_iterator(For); IteratorID = isl_ast_expr_get_id(Iterator); UB = getUpperBound(For, Predicate); ValueLB = ExprBuilder.create(Init); ValueUB = ExprBuilder.create(UB); ValueInc = ExprBuilder.create(Inc); // OpenMP always uses SLE. In case the isl generated AST uses a SLT // expression, we need to adjust the loop blound by one. if (Predicate == CmpInst::ICMP_SLT) ValueUB = Builder.CreateAdd( ValueUB, Builder.CreateSExt(Builder.getTrue(), ValueUB->getType())); ExprBuilder.unifyTypes(ValueLB, ValueUB, ValueInc); BasicBlock::iterator LoopBody; SetVector SubtreeValues; SetVector Loops; getReferencesInSubtree(For, SubtreeValues, Loops); // Create for all loops we depend on values that contain the current loop // iteration. These values are necessary to generate code for SCEVs that // depend on such loops. As a result we need to pass them to the subfunction. for (const Loop *L : Loops) { const SCEV *OuterLIV = SE.getAddRecExpr(SE.getUnknown(Builder.getInt64(0)), SE.getUnknown(Builder.getInt64(1)), L, SCEV::FlagAnyWrap); Value *V = generateSCEV(OuterLIV); OutsideLoopIterations[L] = SE.getUnknown(V); SubtreeValues.insert(V); } ValueMapT NewValues; ParallelLoopGenerator ParallelLoopGen(Builder, P, LI, DT, DL); IV = ParallelLoopGen.createParallelLoop(ValueLB, ValueUB, ValueInc, SubtreeValues, NewValues, &LoopBody); BasicBlock::iterator AfterLoop = Builder.GetInsertPoint(); Builder.SetInsertPoint(&*LoopBody); // Remember the parallel subfunction ParallelSubfunctions.push_back(LoopBody->getFunction()); // Save the current values. auto ValueMapCopy = ValueMap; IslExprBuilder::IDToValueTy IDToValueCopy = IDToValue; updateValues(NewValues); IDToValue[IteratorID] = IV; ValueMapT NewValuesReverse; for (auto P : NewValues) NewValuesReverse[P.second] = P.first; Annotator.addAlternativeAliasBases(NewValuesReverse); create(Body); Annotator.resetAlternativeAliasBases(); // Restore the original values. ValueMap = ValueMapCopy; IDToValue = IDToValueCopy; Builder.SetInsertPoint(&*AfterLoop); removeSubFuncFromDomTree((*LoopBody).getParent()->getParent(), DT); for (const Loop *L : Loops) OutsideLoopIterations.erase(L); isl_ast_node_free(For); isl_ast_expr_free(Iterator); isl_id_free(IteratorID); } void IslNodeBuilder::createFor(__isl_take isl_ast_node *For) { bool Vector = PollyVectorizerChoice == VECTORIZER_POLLY; if (Vector && IslAstInfo::isInnermostParallel(For) && !IslAstInfo::isReductionParallel(For)) { int VectorWidth = getNumberOfIterations(For); if (1 < VectorWidth && VectorWidth <= 16) { createForVector(For, VectorWidth); return; } } if (IslAstInfo::isExecutedInParallel(For)) { createForParallel(For); return; } createForSequential(For, false); } void IslNodeBuilder::createIf(__isl_take isl_ast_node *If) { isl_ast_expr *Cond = isl_ast_node_if_get_cond(If); Function *F = Builder.GetInsertBlock()->getParent(); LLVMContext &Context = F->getContext(); BasicBlock *CondBB = SplitBlock(Builder.GetInsertBlock(), &*Builder.GetInsertPoint(), &DT, &LI); CondBB->setName("polly.cond"); BasicBlock *MergeBB = SplitBlock(CondBB, &CondBB->front(), &DT, &LI); MergeBB->setName("polly.merge"); BasicBlock *ThenBB = BasicBlock::Create(Context, "polly.then", F); BasicBlock *ElseBB = BasicBlock::Create(Context, "polly.else", F); DT.addNewBlock(ThenBB, CondBB); DT.addNewBlock(ElseBB, CondBB); DT.changeImmediateDominator(MergeBB, CondBB); Loop *L = LI.getLoopFor(CondBB); if (L) { L->addBasicBlockToLoop(ThenBB, LI); L->addBasicBlockToLoop(ElseBB, LI); } CondBB->getTerminator()->eraseFromParent(); Builder.SetInsertPoint(CondBB); Value *Predicate = ExprBuilder.create(Cond); Builder.CreateCondBr(Predicate, ThenBB, ElseBB); Builder.SetInsertPoint(ThenBB); Builder.CreateBr(MergeBB); Builder.SetInsertPoint(ElseBB); Builder.CreateBr(MergeBB); Builder.SetInsertPoint(&ThenBB->front()); create(isl_ast_node_if_get_then(If)); Builder.SetInsertPoint(&ElseBB->front()); if (isl_ast_node_if_has_else(If)) create(isl_ast_node_if_get_else(If)); Builder.SetInsertPoint(&MergeBB->front()); isl_ast_node_free(If); } __isl_give isl_id_to_ast_expr * IslNodeBuilder::createNewAccesses(ScopStmt *Stmt, __isl_keep isl_ast_node *Node) { isl_id_to_ast_expr *NewAccesses = isl_id_to_ast_expr_alloc(Stmt->getParent()->getIslCtx(), 0); auto *Build = IslAstInfo::getBuild(Node); assert(Build && "Could not obtain isl_ast_build from user node"); Stmt->setAstBuild(Build); for (auto *MA : *Stmt) { if (!MA->hasNewAccessRelation()) continue; auto Schedule = isl_ast_build_get_schedule(Build); auto PWAccRel = MA->applyScheduleToAccessRelation(Schedule); auto AccessExpr = isl_ast_build_access_from_pw_multi_aff(Build, PWAccRel); NewAccesses = isl_id_to_ast_expr_set(NewAccesses, MA->getId(), AccessExpr); } return NewAccesses; } void IslNodeBuilder::createSubstitutions(isl_ast_expr *Expr, ScopStmt *Stmt, LoopToScevMapT <S) { assert(isl_ast_expr_get_type(Expr) == isl_ast_expr_op && "Expression of type 'op' expected"); assert(isl_ast_expr_get_op_type(Expr) == isl_ast_op_call && "Opertation of type 'call' expected"); for (int i = 0; i < isl_ast_expr_get_op_n_arg(Expr) - 1; ++i) { isl_ast_expr *SubExpr; Value *V; SubExpr = isl_ast_expr_get_op_arg(Expr, i + 1); V = ExprBuilder.create(SubExpr); ScalarEvolution *SE = Stmt->getParent()->getSE(); LTS[Stmt->getLoopForDimension(i)] = SE->getUnknown(V); } isl_ast_expr_free(Expr); } void IslNodeBuilder::createSubstitutionsVector( __isl_take isl_ast_expr *Expr, ScopStmt *Stmt, std::vector &VLTS, std::vector &IVS, __isl_take isl_id *IteratorID) { int i = 0; Value *OldValue = IDToValue[IteratorID]; for (Value *IV : IVS) { IDToValue[IteratorID] = IV; createSubstitutions(isl_ast_expr_copy(Expr), Stmt, VLTS[i]); i++; } IDToValue[IteratorID] = OldValue; isl_id_free(IteratorID); isl_ast_expr_free(Expr); } void IslNodeBuilder::createUser(__isl_take isl_ast_node *User) { LoopToScevMapT LTS; isl_id *Id; ScopStmt *Stmt; isl_ast_expr *Expr = isl_ast_node_user_get_expr(User); isl_ast_expr *StmtExpr = isl_ast_expr_get_op_arg(Expr, 0); Id = isl_ast_expr_get_id(StmtExpr); isl_ast_expr_free(StmtExpr); LTS.insert(OutsideLoopIterations.begin(), OutsideLoopIterations.end()); Stmt = (ScopStmt *)isl_id_get_user(Id); auto *NewAccesses = createNewAccesses(Stmt, User); createSubstitutions(Expr, Stmt, LTS); if (Stmt->isBlockStmt()) BlockGen.copyStmt(*Stmt, LTS, NewAccesses); else RegionGen.copyStmt(*Stmt, LTS, NewAccesses); isl_id_to_ast_expr_free(NewAccesses); isl_ast_node_free(User); isl_id_free(Id); } void IslNodeBuilder::createBlock(__isl_take isl_ast_node *Block) { isl_ast_node_list *List = isl_ast_node_block_get_children(Block); for (int i = 0; i < isl_ast_node_list_n_ast_node(List); ++i) create(isl_ast_node_list_get_ast_node(List, i)); isl_ast_node_free(Block); isl_ast_node_list_free(List); } void IslNodeBuilder::create(__isl_take isl_ast_node *Node) { switch (isl_ast_node_get_type(Node)) { case isl_ast_node_error: llvm_unreachable("code generation error"); case isl_ast_node_mark: createMark(Node); return; case isl_ast_node_for: createFor(Node); return; case isl_ast_node_if: createIf(Node); return; case isl_ast_node_user: createUser(Node); return; case isl_ast_node_block: createBlock(Node); return; } llvm_unreachable("Unknown isl_ast_node type"); } bool IslNodeBuilder::materializeValue(isl_id *Id) { // If the Id is already mapped, skip it. if (!IDToValue.count(Id)) { auto *ParamSCEV = (const SCEV *)isl_id_get_user(Id); Value *V = nullptr; // Parameters could refere to invariant loads that need to be // preloaded before we can generate code for the parameter. Thus, // check if any value refered to in ParamSCEV is an invariant load // and if so make sure its equivalence class is preloaded. SetVector Values; findValues(ParamSCEV, SE, Values); for (auto *Val : Values) { // Check if the value is an instruction in a dead block within the SCoP // and if so do not code generate it. if (auto *Inst = dyn_cast(Val)) { if (S.contains(Inst)) { bool IsDead = true; // Check for "undef" loads first, then if there is a statement for // the parent of Inst and lastly if the parent of Inst has an empty // domain. In the first and last case the instruction is dead but if // there is a statement or the domain is not empty Inst is not dead. auto MemInst = MemAccInst::dyn_cast(Inst); auto Address = MemInst ? MemInst.getPointerOperand() : nullptr; if (Address && SE.getUnknown(UndefValue::get(Address->getType())) == SE.getPointerBase(SE.getSCEV(Address))) { } else if (S.getStmtFor(Inst)) { IsDead = false; } else { auto *Domain = S.getDomainConditions(Inst->getParent()); IsDead = isl_set_is_empty(Domain); isl_set_free(Domain); } if (IsDead) { V = UndefValue::get(ParamSCEV->getType()); break; } } } if (auto *IAClass = S.lookupInvariantEquivClass(Val)) { // Check if this invariant access class is empty, hence if we never // actually added a loads instruction to it. In that case it has no // (meaningful) users and we should not try to code generate it. if (std::get<1>(*IAClass).empty()) V = UndefValue::get(ParamSCEV->getType()); if (!preloadInvariantEquivClass(*IAClass)) { isl_id_free(Id); return false; } } } V = V ? V : generateSCEV(ParamSCEV); IDToValue[Id] = V; } isl_id_free(Id); return true; } bool IslNodeBuilder::materializeParameters(isl_set *Set, bool All) { for (unsigned i = 0, e = isl_set_dim(Set, isl_dim_param); i < e; ++i) { if (!All && !isl_set_involves_dims(Set, isl_dim_param, i, 1)) continue; isl_id *Id = isl_set_get_dim_id(Set, isl_dim_param, i); if (!materializeValue(Id)) return false; } return true; } /// @brief Add the number of dimensions in @p BS to @p U. static isl_stat countTotalDims(isl_basic_set *BS, void *U) { unsigned *NumTotalDim = static_cast(U); *NumTotalDim += isl_basic_set_total_dim(BS); isl_basic_set_free(BS); return isl_stat_ok; } Value *IslNodeBuilder::preloadUnconditionally(isl_set *AccessRange, isl_ast_build *Build, Instruction *AccInst) { // TODO: This check could be performed in the ScopInfo already. unsigned NumTotalDim = 0; isl_set_foreach_basic_set(AccessRange, countTotalDims, &NumTotalDim); if (NumTotalDim > MaxDimensionsInAccessRange) { isl_set_free(AccessRange); return nullptr; } isl_pw_multi_aff *PWAccRel = isl_pw_multi_aff_from_set(AccessRange); isl_ast_expr *Access = isl_ast_build_access_from_pw_multi_aff(Build, PWAccRel); auto *Address = isl_ast_expr_address_of(Access); auto *AddressValue = ExprBuilder.create(Address); Value *PreloadVal; // Correct the type as the SAI might have a different type than the user // expects, especially if the base pointer is a struct. Type *Ty = AccInst->getType(); auto *Ptr = AddressValue; auto Name = Ptr->getName(); Ptr = Builder.CreatePointerCast(Ptr, Ty->getPointerTo(), Name + ".cast"); PreloadVal = Builder.CreateLoad(Ptr, Name + ".load"); if (LoadInst *PreloadInst = dyn_cast(PreloadVal)) PreloadInst->setAlignment(dyn_cast(AccInst)->getAlignment()); // TODO: This is only a hot fix for SCoP sequences that use the same load // instruction contained and hoisted by one of the SCoPs. if (SE.isSCEVable(Ty)) SE.forgetValue(AccInst); return PreloadVal; } Value *IslNodeBuilder::preloadInvariantLoad(const MemoryAccess &MA, isl_set *Domain) { isl_set *AccessRange = isl_map_range(MA.getAddressFunction()); AccessRange = isl_set_gist_params(AccessRange, S.getContext()); if (!materializeParameters(AccessRange, false)) { isl_set_free(AccessRange); isl_set_free(Domain); return nullptr; } auto *Build = isl_ast_build_from_context(isl_set_universe(S.getParamSpace())); isl_set *Universe = isl_set_universe(isl_set_get_space(Domain)); bool AlwaysExecuted = isl_set_is_equal(Domain, Universe); isl_set_free(Universe); Instruction *AccInst = MA.getAccessInstruction(); Type *AccInstTy = AccInst->getType(); Value *PreloadVal = nullptr; if (AlwaysExecuted) { PreloadVal = preloadUnconditionally(AccessRange, Build, AccInst); isl_ast_build_free(Build); isl_set_free(Domain); return PreloadVal; } if (!materializeParameters(Domain, false)) { isl_ast_build_free(Build); isl_set_free(AccessRange); isl_set_free(Domain); return nullptr; } isl_ast_expr *DomainCond = isl_ast_build_expr_from_set(Build, Domain); Domain = nullptr; ExprBuilder.setTrackOverflow(true); Value *Cond = ExprBuilder.create(DomainCond); Value *OverflowHappened = Builder.CreateNot(ExprBuilder.getOverflowState(), "polly.preload.cond.overflown"); Cond = Builder.CreateAnd(Cond, OverflowHappened, "polly.preload.cond.result"); ExprBuilder.setTrackOverflow(false); if (!Cond->getType()->isIntegerTy(1)) Cond = Builder.CreateIsNotNull(Cond); BasicBlock *CondBB = SplitBlock(Builder.GetInsertBlock(), &*Builder.GetInsertPoint(), &DT, &LI); CondBB->setName("polly.preload.cond"); BasicBlock *MergeBB = SplitBlock(CondBB, &CondBB->front(), &DT, &LI); MergeBB->setName("polly.preload.merge"); Function *F = Builder.GetInsertBlock()->getParent(); LLVMContext &Context = F->getContext(); BasicBlock *ExecBB = BasicBlock::Create(Context, "polly.preload.exec", F); DT.addNewBlock(ExecBB, CondBB); if (Loop *L = LI.getLoopFor(CondBB)) L->addBasicBlockToLoop(ExecBB, LI); auto *CondBBTerminator = CondBB->getTerminator(); Builder.SetInsertPoint(CondBBTerminator); Builder.CreateCondBr(Cond, ExecBB, MergeBB); CondBBTerminator->eraseFromParent(); Builder.SetInsertPoint(ExecBB); Builder.CreateBr(MergeBB); Builder.SetInsertPoint(ExecBB->getTerminator()); Value *PreAccInst = preloadUnconditionally(AccessRange, Build, AccInst); Builder.SetInsertPoint(MergeBB->getTerminator()); auto *MergePHI = Builder.CreatePHI( AccInstTy, 2, "polly.preload." + AccInst->getName() + ".merge"); PreloadVal = MergePHI; if (!PreAccInst) { PreloadVal = nullptr; PreAccInst = UndefValue::get(AccInstTy); } MergePHI->addIncoming(PreAccInst, ExecBB); MergePHI->addIncoming(Constant::getNullValue(AccInstTy), CondBB); isl_ast_build_free(Build); return PreloadVal; } bool IslNodeBuilder::preloadInvariantEquivClass( InvariantEquivClassTy &IAClass) { // For an equivalence class of invariant loads we pre-load the representing // element with the unified execution context. However, we have to map all // elements of the class to the one preloaded load as they are referenced // during the code generation and therefor need to be mapped. const MemoryAccessList &MAs = std::get<1>(IAClass); if (MAs.empty()) return true; MemoryAccess *MA = MAs.front(); assert(MA->isArrayKind() && MA->isRead()); // If the access function was already mapped, the preload of this equivalence // class was triggered earlier already and doesn't need to be done again. if (ValueMap.count(MA->getAccessInstruction())) return true; // Check for recurrsion which can be caused by additional constraints, e.g., // non-finitie loop contraints. In such a case we have to bail out and insert // a "false" runtime check that will cause the original code to be executed. auto PtrId = std::make_pair(std::get<0>(IAClass), std::get<3>(IAClass)); if (!PreloadedPtrs.insert(PtrId).second) return false; // The exectution context of the IAClass. isl_set *&ExecutionCtx = std::get<2>(IAClass); // If the base pointer of this class is dependent on another one we have to // make sure it was preloaded already. auto *SAI = MA->getScopArrayInfo(); if (auto *BaseIAClass = S.lookupInvariantEquivClass(SAI->getBasePtr())) { if (!preloadInvariantEquivClass(*BaseIAClass)) return false; // After we preloaded the BaseIAClass we adjusted the BaseExecutionCtx and // we need to refine the ExecutionCtx. isl_set *BaseExecutionCtx = isl_set_copy(std::get<2>(*BaseIAClass)); ExecutionCtx = isl_set_intersect(ExecutionCtx, BaseExecutionCtx); } Instruction *AccInst = MA->getAccessInstruction(); Type *AccInstTy = AccInst->getType(); Value *PreloadVal = preloadInvariantLoad(*MA, isl_set_copy(ExecutionCtx)); if (!PreloadVal) return false; for (const MemoryAccess *MA : MAs) { Instruction *MAAccInst = MA->getAccessInstruction(); assert(PreloadVal->getType() == MAAccInst->getType()); ValueMap[MAAccInst] = PreloadVal; } if (SE.isSCEVable(AccInstTy)) { isl_id *ParamId = S.getIdForParam(SE.getSCEV(AccInst)); if (ParamId) IDToValue[ParamId] = PreloadVal; isl_id_free(ParamId); } BasicBlock *EntryBB = &Builder.GetInsertBlock()->getParent()->getEntryBlock(); auto *Alloca = new AllocaInst(AccInstTy, AccInst->getName() + ".preload.s2a"); Alloca->insertBefore(&*EntryBB->getFirstInsertionPt()); Builder.CreateStore(PreloadVal, Alloca); for (auto *DerivedSAI : SAI->getDerivedSAIs()) { Value *BasePtr = DerivedSAI->getBasePtr(); for (const MemoryAccess *MA : MAs) { // As the derived SAI information is quite coarse, any load from the // current SAI could be the base pointer of the derived SAI, however we // should only change the base pointer of the derived SAI if we actually // preloaded it. if (BasePtr == MA->getBaseAddr()) { assert(BasePtr->getType() == PreloadVal->getType()); DerivedSAI->setBasePtr(PreloadVal); } // For scalar derived SAIs we remap the alloca used for the derived value. if (BasePtr == MA->getAccessInstruction()) { if (DerivedSAI->isPHIKind()) PHIOpMap[BasePtr] = Alloca; else ScalarMap[BasePtr] = Alloca; } } } for (const MemoryAccess *MA : MAs) { Instruction *MAAccInst = MA->getAccessInstruction(); // Use the escape system to get the correct value to users outside the SCoP. BlockGenerator::EscapeUserVectorTy EscapeUsers; for (auto *U : MAAccInst->users()) if (Instruction *UI = dyn_cast(U)) if (!S.contains(UI)) EscapeUsers.push_back(UI); if (EscapeUsers.empty()) continue; EscapeMap[MA->getAccessInstruction()] = std::make_pair(Alloca, std::move(EscapeUsers)); } return true; } bool IslNodeBuilder::preloadInvariantLoads() { auto &InvariantEquivClasses = S.getInvariantAccesses(); if (InvariantEquivClasses.empty()) return true; BasicBlock *PreLoadBB = SplitBlock(Builder.GetInsertBlock(), &*Builder.GetInsertPoint(), &DT, &LI); PreLoadBB->setName("polly.preload.begin"); Builder.SetInsertPoint(&PreLoadBB->front()); for (auto &IAClass : InvariantEquivClasses) if (!preloadInvariantEquivClass(IAClass)) return false; return true; } void IslNodeBuilder::addParameters(__isl_take isl_set *Context) { // Materialize values for the parameters of the SCoP. materializeParameters(Context, /* all */ true); // Generate values for the current loop iteration for all surrounding loops. // // We may also reference loops outside of the scop which do not contain the // scop itself, but as the number of such scops may be arbitrarily large we do // not generate code for them here, but only at the point of code generation // where these values are needed. Loop *L = LI.getLoopFor(S.getEntry()); while (L != nullptr && S.contains(L)) L = L->getParentLoop(); while (L != nullptr) { const SCEV *OuterLIV = SE.getAddRecExpr(SE.getUnknown(Builder.getInt64(0)), SE.getUnknown(Builder.getInt64(1)), L, SCEV::FlagAnyWrap); Value *V = generateSCEV(OuterLIV); OutsideLoopIterations[L] = SE.getUnknown(V); L = L->getParentLoop(); } isl_set_free(Context); } Value *IslNodeBuilder::generateSCEV(const SCEV *Expr) { Instruction *InsertLocation = &*--(Builder.GetInsertBlock()->end()); return expandCodeFor(S, SE, DL, "polly", Expr, Expr->getType(), InsertLocation, &ValueMap); }