1cde4d5a6SJacques Pienaar //===- ModuleTranslation.cpp - MLIR to LLVM conversion --------------------===// 25d7231d8SStephan Herhut // 330857107SMehdi Amini // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. 456222a06SMehdi Amini // See https://llvm.org/LICENSE.txt for license information. 556222a06SMehdi Amini // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception 65d7231d8SStephan Herhut // 756222a06SMehdi Amini //===----------------------------------------------------------------------===// 85d7231d8SStephan Herhut // 95d7231d8SStephan Herhut // This file implements the translation between an MLIR LLVM dialect module and 105d7231d8SStephan Herhut // the corresponding LLVMIR module. It only handles core LLVM IR operations. 115d7231d8SStephan Herhut // 125d7231d8SStephan Herhut //===----------------------------------------------------------------------===// 135d7231d8SStephan Herhut 145d7231d8SStephan Herhut #include "mlir/Target/LLVMIR/ModuleTranslation.h" 155d7231d8SStephan Herhut 16c33d6970SRiver Riddle #include "DebugTranslation.h" 17ba0fa925SRiver Riddle #include "mlir/Dialect/LLVMIR/LLVMDialect.h" 1892a295ebSKiran Chandramohan #include "mlir/Dialect/OpenMP/OpenMPDialect.h" 195d7231d8SStephan Herhut #include "mlir/IR/Attributes.h" 205d7231d8SStephan Herhut #include "mlir/IR/Module.h" 21a4a42160SAlex Zinenko #include "mlir/IR/StandardTypes.h" 225d7231d8SStephan Herhut #include "mlir/Support/LLVM.h" 235d7231d8SStephan Herhut 245d7231d8SStephan Herhut #include "llvm/ADT/SetVector.h" 2592a295ebSKiran Chandramohan #include "llvm/Frontend/OpenMP/OMPIRBuilder.h" 265d7231d8SStephan Herhut #include "llvm/IR/BasicBlock.h" 275d7231d8SStephan Herhut #include "llvm/IR/Constants.h" 285d7231d8SStephan Herhut #include "llvm/IR/DerivedTypes.h" 295d7231d8SStephan Herhut #include "llvm/IR/IRBuilder.h" 305d7231d8SStephan Herhut #include "llvm/IR/LLVMContext.h" 315d7231d8SStephan Herhut #include "llvm/IR/Module.h" 325d7231d8SStephan Herhut #include "llvm/Transforms/Utils/Cloning.h" 335d7231d8SStephan Herhut 342666b973SRiver Riddle using namespace mlir; 352666b973SRiver Riddle using namespace mlir::LLVM; 36c33d6970SRiver Riddle using namespace mlir::LLVM::detail; 375d7231d8SStephan Herhut 38eb67bd78SAlex Zinenko #include "mlir/Dialect/LLVMIR/LLVMConversionEnumsToLLVM.inc" 39eb67bd78SAlex Zinenko 40a922e231SAlex Zinenko /// Builds a constant of a sequential LLVM type `type`, potentially containing 41a922e231SAlex Zinenko /// other sequential types recursively, from the individual constant values 42a922e231SAlex Zinenko /// provided in `constants`. `shape` contains the number of elements in nested 43a922e231SAlex Zinenko /// sequential types. Reports errors at `loc` and returns nullptr on error. 44a4a42160SAlex Zinenko static llvm::Constant * 45a4a42160SAlex Zinenko buildSequentialConstant(ArrayRef<llvm::Constant *> &constants, 46a4a42160SAlex Zinenko ArrayRef<int64_t> shape, llvm::Type *type, 47a4a42160SAlex Zinenko Location loc) { 48a4a42160SAlex Zinenko if (shape.empty()) { 49a4a42160SAlex Zinenko llvm::Constant *result = constants.front(); 50a4a42160SAlex Zinenko constants = constants.drop_front(); 51a4a42160SAlex Zinenko return result; 52a4a42160SAlex Zinenko } 53a4a42160SAlex Zinenko 54a4a42160SAlex Zinenko if (!isa<llvm::SequentialType>(type)) { 55a4a42160SAlex Zinenko emitError(loc) << "expected sequential LLVM types wrapping a scalar"; 56a4a42160SAlex Zinenko return nullptr; 57a4a42160SAlex Zinenko } 58a4a42160SAlex Zinenko 59a4a42160SAlex Zinenko llvm::Type *elementType = type->getSequentialElementType(); 60a4a42160SAlex Zinenko SmallVector<llvm::Constant *, 8> nested; 61a4a42160SAlex Zinenko nested.reserve(shape.front()); 62a4a42160SAlex Zinenko for (int64_t i = 0; i < shape.front(); ++i) { 63a4a42160SAlex Zinenko nested.push_back(buildSequentialConstant(constants, shape.drop_front(), 64a4a42160SAlex Zinenko elementType, loc)); 65a4a42160SAlex Zinenko if (!nested.back()) 66a4a42160SAlex Zinenko return nullptr; 67a4a42160SAlex Zinenko } 68a4a42160SAlex Zinenko 69a4a42160SAlex Zinenko if (shape.size() == 1 && type->isVectorTy()) 70a4a42160SAlex Zinenko return llvm::ConstantVector::get(nested); 71a4a42160SAlex Zinenko return llvm::ConstantArray::get( 72a4a42160SAlex Zinenko llvm::ArrayType::get(elementType, shape.front()), nested); 73a4a42160SAlex Zinenko } 74a4a42160SAlex Zinenko 75fc817b09SKazuaki Ishizaki /// Returns the first non-sequential type nested in sequential types. 76a4a42160SAlex Zinenko static llvm::Type *getInnermostElementType(llvm::Type *type) { 77a4a42160SAlex Zinenko while (isa<llvm::SequentialType>(type)) 78a4a42160SAlex Zinenko type = type->getSequentialElementType(); 79a4a42160SAlex Zinenko return type; 80a4a42160SAlex Zinenko } 81a4a42160SAlex Zinenko 822666b973SRiver Riddle /// Create an LLVM IR constant of `llvmType` from the MLIR attribute `attr`. 832666b973SRiver Riddle /// This currently supports integer, floating point, splat and dense element 842666b973SRiver Riddle /// attributes and combinations thereof. In case of error, report it to `loc` 852666b973SRiver Riddle /// and return nullptr. 865d7231d8SStephan Herhut llvm::Constant *ModuleTranslation::getLLVMConstant(llvm::Type *llvmType, 875d7231d8SStephan Herhut Attribute attr, 885d7231d8SStephan Herhut Location loc) { 8933a3a91bSChristian Sigg if (!attr) 9033a3a91bSChristian Sigg return llvm::UndefValue::get(llvmType); 91a4a42160SAlex Zinenko if (llvmType->isStructTy()) { 92a4a42160SAlex Zinenko emitError(loc, "struct types are not supported in constants"); 93a4a42160SAlex Zinenko return nullptr; 94a4a42160SAlex Zinenko } 955d7231d8SStephan Herhut if (auto intAttr = attr.dyn_cast<IntegerAttr>()) 965d7231d8SStephan Herhut return llvm::ConstantInt::get(llvmType, intAttr.getValue()); 97*18fc42faSAhmed Taei if (auto boolAttr = attr.dyn_cast<BoolAttr>()) 98*18fc42faSAhmed Taei return llvm::ConstantInt::get(llvmType, boolAttr.getValue()); 995d7231d8SStephan Herhut if (auto floatAttr = attr.dyn_cast<FloatAttr>()) 1005d7231d8SStephan Herhut return llvm::ConstantFP::get(llvmType, floatAttr.getValue()); 1019b9c647cSRiver Riddle if (auto funcAttr = attr.dyn_cast<FlatSymbolRefAttr>()) 1025d7231d8SStephan Herhut return functionMapping.lookup(funcAttr.getValue()); 1035d7231d8SStephan Herhut if (auto splatAttr = attr.dyn_cast<SplatElementsAttr>()) { 1042f13df13SMLIR Team auto *sequentialType = cast<llvm::SequentialType>(llvmType); 1052f13df13SMLIR Team auto elementType = sequentialType->getElementType(); 1062f13df13SMLIR Team uint64_t numElements = sequentialType->getNumElements(); 107d6ea8ff0SAlex Zinenko // Splat value is a scalar. Extract it only if the element type is not 108d6ea8ff0SAlex Zinenko // another sequence type. The recursion terminates because each step removes 109d6ea8ff0SAlex Zinenko // one outer sequential type. 110d6ea8ff0SAlex Zinenko llvm::Constant *child = getLLVMConstant( 111d6ea8ff0SAlex Zinenko elementType, 112d6ea8ff0SAlex Zinenko isa<llvm::SequentialType>(elementType) ? splatAttr 113d6ea8ff0SAlex Zinenko : splatAttr.getSplatValue(), 114d6ea8ff0SAlex Zinenko loc); 115a4a42160SAlex Zinenko if (!child) 116a4a42160SAlex Zinenko return nullptr; 1172f13df13SMLIR Team if (llvmType->isVectorTy()) 118396a42d9SRiver Riddle return llvm::ConstantVector::getSplat( 119396a42d9SRiver Riddle llvm::ElementCount(numElements, /*Scalable=*/false), child); 1202f13df13SMLIR Team if (llvmType->isArrayTy()) { 1212f13df13SMLIR Team auto arrayType = llvm::ArrayType::get(elementType, numElements); 1222f13df13SMLIR Team SmallVector<llvm::Constant *, 8> constants(numElements, child); 1232f13df13SMLIR Team return llvm::ConstantArray::get(arrayType, constants); 1242f13df13SMLIR Team } 1255d7231d8SStephan Herhut } 126a4a42160SAlex Zinenko 127d906f84bSRiver Riddle if (auto elementsAttr = attr.dyn_cast<ElementsAttr>()) { 128a4a42160SAlex Zinenko assert(elementsAttr.getType().hasStaticShape()); 129a4a42160SAlex Zinenko assert(elementsAttr.getNumElements() != 0 && 130a4a42160SAlex Zinenko "unexpected empty elements attribute"); 131a4a42160SAlex Zinenko assert(!elementsAttr.getType().getShape().empty() && 132a4a42160SAlex Zinenko "unexpected empty elements attribute shape"); 133a4a42160SAlex Zinenko 1345d7231d8SStephan Herhut SmallVector<llvm::Constant *, 8> constants; 135a4a42160SAlex Zinenko constants.reserve(elementsAttr.getNumElements()); 136a4a42160SAlex Zinenko llvm::Type *innermostType = getInnermostElementType(llvmType); 137d906f84bSRiver Riddle for (auto n : elementsAttr.getValues<Attribute>()) { 138a4a42160SAlex Zinenko constants.push_back(getLLVMConstant(innermostType, n, loc)); 1395d7231d8SStephan Herhut if (!constants.back()) 1405d7231d8SStephan Herhut return nullptr; 1415d7231d8SStephan Herhut } 142a4a42160SAlex Zinenko ArrayRef<llvm::Constant *> constantsRef = constants; 143a4a42160SAlex Zinenko llvm::Constant *result = buildSequentialConstant( 144a4a42160SAlex Zinenko constantsRef, elementsAttr.getType().getShape(), llvmType, loc); 145a4a42160SAlex Zinenko assert(constantsRef.empty() && "did not consume all elemental constants"); 146a4a42160SAlex Zinenko return result; 1472f13df13SMLIR Team } 148a4a42160SAlex Zinenko 149cb348dffSStephan Herhut if (auto stringAttr = attr.dyn_cast<StringAttr>()) { 150cb348dffSStephan Herhut return llvm::ConstantDataArray::get( 151cb348dffSStephan Herhut llvmModule->getContext(), ArrayRef<char>{stringAttr.getValue().data(), 152cb348dffSStephan Herhut stringAttr.getValue().size()}); 153cb348dffSStephan Herhut } 154a4c3a645SRiver Riddle emitError(loc, "unsupported constant value"); 1555d7231d8SStephan Herhut return nullptr; 1565d7231d8SStephan Herhut } 1575d7231d8SStephan Herhut 1582666b973SRiver Riddle /// Convert MLIR integer comparison predicate to LLVM IR comparison predicate. 159ec82e1c9SAlex Zinenko static llvm::CmpInst::Predicate getLLVMCmpPredicate(ICmpPredicate p) { 1605d7231d8SStephan Herhut switch (p) { 161ec82e1c9SAlex Zinenko case LLVM::ICmpPredicate::eq: 1625d7231d8SStephan Herhut return llvm::CmpInst::Predicate::ICMP_EQ; 163ec82e1c9SAlex Zinenko case LLVM::ICmpPredicate::ne: 1645d7231d8SStephan Herhut return llvm::CmpInst::Predicate::ICMP_NE; 165ec82e1c9SAlex Zinenko case LLVM::ICmpPredicate::slt: 1665d7231d8SStephan Herhut return llvm::CmpInst::Predicate::ICMP_SLT; 167ec82e1c9SAlex Zinenko case LLVM::ICmpPredicate::sle: 1685d7231d8SStephan Herhut return llvm::CmpInst::Predicate::ICMP_SLE; 169ec82e1c9SAlex Zinenko case LLVM::ICmpPredicate::sgt: 1705d7231d8SStephan Herhut return llvm::CmpInst::Predicate::ICMP_SGT; 171ec82e1c9SAlex Zinenko case LLVM::ICmpPredicate::sge: 1725d7231d8SStephan Herhut return llvm::CmpInst::Predicate::ICMP_SGE; 173ec82e1c9SAlex Zinenko case LLVM::ICmpPredicate::ult: 1745d7231d8SStephan Herhut return llvm::CmpInst::Predicate::ICMP_ULT; 175ec82e1c9SAlex Zinenko case LLVM::ICmpPredicate::ule: 1765d7231d8SStephan Herhut return llvm::CmpInst::Predicate::ICMP_ULE; 177ec82e1c9SAlex Zinenko case LLVM::ICmpPredicate::ugt: 1785d7231d8SStephan Herhut return llvm::CmpInst::Predicate::ICMP_UGT; 179ec82e1c9SAlex Zinenko case LLVM::ICmpPredicate::uge: 1805d7231d8SStephan Herhut return llvm::CmpInst::Predicate::ICMP_UGE; 1815d7231d8SStephan Herhut } 182e6365f3dSJacques Pienaar llvm_unreachable("incorrect comparison predicate"); 1835d7231d8SStephan Herhut } 1845d7231d8SStephan Herhut 18548fdc8d7SNagy Mostafa static llvm::CmpInst::Predicate getLLVMCmpPredicate(FCmpPredicate p) { 18648fdc8d7SNagy Mostafa switch (p) { 18748fdc8d7SNagy Mostafa case LLVM::FCmpPredicate::_false: 18848fdc8d7SNagy Mostafa return llvm::CmpInst::Predicate::FCMP_FALSE; 18948fdc8d7SNagy Mostafa case LLVM::FCmpPredicate::oeq: 19048fdc8d7SNagy Mostafa return llvm::CmpInst::Predicate::FCMP_OEQ; 19148fdc8d7SNagy Mostafa case LLVM::FCmpPredicate::ogt: 19248fdc8d7SNagy Mostafa return llvm::CmpInst::Predicate::FCMP_OGT; 19348fdc8d7SNagy Mostafa case LLVM::FCmpPredicate::oge: 19448fdc8d7SNagy Mostafa return llvm::CmpInst::Predicate::FCMP_OGE; 19548fdc8d7SNagy Mostafa case LLVM::FCmpPredicate::olt: 19648fdc8d7SNagy Mostafa return llvm::CmpInst::Predicate::FCMP_OLT; 19748fdc8d7SNagy Mostafa case LLVM::FCmpPredicate::ole: 19848fdc8d7SNagy Mostafa return llvm::CmpInst::Predicate::FCMP_OLE; 19948fdc8d7SNagy Mostafa case LLVM::FCmpPredicate::one: 20048fdc8d7SNagy Mostafa return llvm::CmpInst::Predicate::FCMP_ONE; 20148fdc8d7SNagy Mostafa case LLVM::FCmpPredicate::ord: 20248fdc8d7SNagy Mostafa return llvm::CmpInst::Predicate::FCMP_ORD; 20348fdc8d7SNagy Mostafa case LLVM::FCmpPredicate::ueq: 20448fdc8d7SNagy Mostafa return llvm::CmpInst::Predicate::FCMP_UEQ; 20548fdc8d7SNagy Mostafa case LLVM::FCmpPredicate::ugt: 20648fdc8d7SNagy Mostafa return llvm::CmpInst::Predicate::FCMP_UGT; 20748fdc8d7SNagy Mostafa case LLVM::FCmpPredicate::uge: 20848fdc8d7SNagy Mostafa return llvm::CmpInst::Predicate::FCMP_UGE; 20948fdc8d7SNagy Mostafa case LLVM::FCmpPredicate::ult: 21048fdc8d7SNagy Mostafa return llvm::CmpInst::Predicate::FCMP_ULT; 21148fdc8d7SNagy Mostafa case LLVM::FCmpPredicate::ule: 21248fdc8d7SNagy Mostafa return llvm::CmpInst::Predicate::FCMP_ULE; 21348fdc8d7SNagy Mostafa case LLVM::FCmpPredicate::une: 21448fdc8d7SNagy Mostafa return llvm::CmpInst::Predicate::FCMP_UNE; 21548fdc8d7SNagy Mostafa case LLVM::FCmpPredicate::uno: 21648fdc8d7SNagy Mostafa return llvm::CmpInst::Predicate::FCMP_UNO; 21748fdc8d7SNagy Mostafa case LLVM::FCmpPredicate::_true: 21848fdc8d7SNagy Mostafa return llvm::CmpInst::Predicate::FCMP_TRUE; 21948fdc8d7SNagy Mostafa } 220e6365f3dSJacques Pienaar llvm_unreachable("incorrect comparison predicate"); 22148fdc8d7SNagy Mostafa } 22248fdc8d7SNagy Mostafa 22360a0c612SFrank Laub static llvm::AtomicRMWInst::BinOp getLLVMAtomicBinOp(AtomicBinOp op) { 22460a0c612SFrank Laub switch (op) { 22560a0c612SFrank Laub case LLVM::AtomicBinOp::xchg: 22660a0c612SFrank Laub return llvm::AtomicRMWInst::BinOp::Xchg; 22760a0c612SFrank Laub case LLVM::AtomicBinOp::add: 22860a0c612SFrank Laub return llvm::AtomicRMWInst::BinOp::Add; 22960a0c612SFrank Laub case LLVM::AtomicBinOp::sub: 23060a0c612SFrank Laub return llvm::AtomicRMWInst::BinOp::Sub; 23160a0c612SFrank Laub case LLVM::AtomicBinOp::_and: 23260a0c612SFrank Laub return llvm::AtomicRMWInst::BinOp::And; 23360a0c612SFrank Laub case LLVM::AtomicBinOp::nand: 23460a0c612SFrank Laub return llvm::AtomicRMWInst::BinOp::Nand; 23560a0c612SFrank Laub case LLVM::AtomicBinOp::_or: 23660a0c612SFrank Laub return llvm::AtomicRMWInst::BinOp::Or; 23760a0c612SFrank Laub case LLVM::AtomicBinOp::_xor: 23860a0c612SFrank Laub return llvm::AtomicRMWInst::BinOp::Xor; 23960a0c612SFrank Laub case LLVM::AtomicBinOp::max: 24060a0c612SFrank Laub return llvm::AtomicRMWInst::BinOp::Max; 24160a0c612SFrank Laub case LLVM::AtomicBinOp::min: 24260a0c612SFrank Laub return llvm::AtomicRMWInst::BinOp::Min; 24360a0c612SFrank Laub case LLVM::AtomicBinOp::umax: 24460a0c612SFrank Laub return llvm::AtomicRMWInst::BinOp::UMax; 24560a0c612SFrank Laub case LLVM::AtomicBinOp::umin: 24660a0c612SFrank Laub return llvm::AtomicRMWInst::BinOp::UMin; 24760a0c612SFrank Laub case LLVM::AtomicBinOp::fadd: 24860a0c612SFrank Laub return llvm::AtomicRMWInst::BinOp::FAdd; 24960a0c612SFrank Laub case LLVM::AtomicBinOp::fsub: 25060a0c612SFrank Laub return llvm::AtomicRMWInst::BinOp::FSub; 25160a0c612SFrank Laub } 25260a0c612SFrank Laub llvm_unreachable("incorrect atomic binary operator"); 25360a0c612SFrank Laub } 25460a0c612SFrank Laub 25560a0c612SFrank Laub static llvm::AtomicOrdering getLLVMAtomicOrdering(AtomicOrdering ordering) { 25660a0c612SFrank Laub switch (ordering) { 25760a0c612SFrank Laub case LLVM::AtomicOrdering::not_atomic: 25860a0c612SFrank Laub return llvm::AtomicOrdering::NotAtomic; 25960a0c612SFrank Laub case LLVM::AtomicOrdering::unordered: 26060a0c612SFrank Laub return llvm::AtomicOrdering::Unordered; 26160a0c612SFrank Laub case LLVM::AtomicOrdering::monotonic: 26260a0c612SFrank Laub return llvm::AtomicOrdering::Monotonic; 26360a0c612SFrank Laub case LLVM::AtomicOrdering::acquire: 26460a0c612SFrank Laub return llvm::AtomicOrdering::Acquire; 26560a0c612SFrank Laub case LLVM::AtomicOrdering::release: 26660a0c612SFrank Laub return llvm::AtomicOrdering::Release; 26760a0c612SFrank Laub case LLVM::AtomicOrdering::acq_rel: 26860a0c612SFrank Laub return llvm::AtomicOrdering::AcquireRelease; 26960a0c612SFrank Laub case LLVM::AtomicOrdering::seq_cst: 27060a0c612SFrank Laub return llvm::AtomicOrdering::SequentiallyConsistent; 27160a0c612SFrank Laub } 27260a0c612SFrank Laub llvm_unreachable("incorrect atomic ordering"); 27360a0c612SFrank Laub } 27460a0c612SFrank Laub 275c33d6970SRiver Riddle ModuleTranslation::ModuleTranslation(Operation *module, 276c33d6970SRiver Riddle std::unique_ptr<llvm::Module> llvmModule) 277c33d6970SRiver Riddle : mlirModule(module), llvmModule(std::move(llvmModule)), 278c33d6970SRiver Riddle debugTranslation( 27992a295ebSKiran Chandramohan std::make_unique<DebugTranslation>(module, *this->llvmModule)), 28092a295ebSKiran Chandramohan ompDialect( 28192a295ebSKiran Chandramohan module->getContext()->getRegisteredDialect<omp::OpenMPDialect>()) { 282c33d6970SRiver Riddle assert(satisfiesLLVMModule(mlirModule) && 283c33d6970SRiver Riddle "mlirModule should honor LLVM's module semantics."); 284c33d6970SRiver Riddle } 285c33d6970SRiver Riddle ModuleTranslation::~ModuleTranslation() {} 286c33d6970SRiver Riddle 2872666b973SRiver Riddle /// Given a single MLIR operation, create the corresponding LLVM IR operation 2882666b973SRiver Riddle /// using the `builder`. LLVM IR Builder does not have a generic interface so 2892666b973SRiver Riddle /// this has to be a long chain of `if`s calling different functions with a 2902666b973SRiver Riddle /// different number of arguments. 291baa1ec22SAlex Zinenko LogicalResult ModuleTranslation::convertOperation(Operation &opInst, 2925d7231d8SStephan Herhut llvm::IRBuilder<> &builder) { 2935d7231d8SStephan Herhut auto extractPosition = [](ArrayAttr attr) { 2945d7231d8SStephan Herhut SmallVector<unsigned, 4> position; 2955d7231d8SStephan Herhut position.reserve(attr.size()); 2965d7231d8SStephan Herhut for (Attribute v : attr) 2975d7231d8SStephan Herhut position.push_back(v.cast<IntegerAttr>().getValue().getZExtValue()); 2985d7231d8SStephan Herhut return position; 2995d7231d8SStephan Herhut }; 3005d7231d8SStephan Herhut 301ba0fa925SRiver Riddle #include "mlir/Dialect/LLVMIR/LLVMConversions.inc" 3025d7231d8SStephan Herhut 3035d7231d8SStephan Herhut // Emit function calls. If the "callee" attribute is present, this is a 3045d7231d8SStephan Herhut // direct function call and we also need to look up the remapped function 3055d7231d8SStephan Herhut // itself. Otherwise, this is an indirect call and the callee is the first 3065d7231d8SStephan Herhut // operand, look it up as a normal value. Return the llvm::Value representing 3075d7231d8SStephan Herhut // the function result, which may be of llvm::VoidTy type. 3085d7231d8SStephan Herhut auto convertCall = [this, &builder](Operation &op) -> llvm::Value * { 3095d7231d8SStephan Herhut auto operands = lookupValues(op.getOperands()); 3105d7231d8SStephan Herhut ArrayRef<llvm::Value *> operandsRef(operands); 3119b9c647cSRiver Riddle if (auto attr = op.getAttrOfType<FlatSymbolRefAttr>("callee")) { 3125d7231d8SStephan Herhut return builder.CreateCall(functionMapping.lookup(attr.getValue()), 3135d7231d8SStephan Herhut operandsRef); 3145d7231d8SStephan Herhut } else { 3155d7231d8SStephan Herhut return builder.CreateCall(operandsRef.front(), operandsRef.drop_front()); 3165d7231d8SStephan Herhut } 3175d7231d8SStephan Herhut }; 3185d7231d8SStephan Herhut 3195d7231d8SStephan Herhut // Emit calls. If the called function has a result, remap the corresponding 3205d7231d8SStephan Herhut // value. Note that LLVM IR dialect CallOp has either 0 or 1 result. 321d5b60ee8SRiver Riddle if (isa<LLVM::CallOp>(opInst)) { 3225d7231d8SStephan Herhut llvm::Value *result = convertCall(opInst); 3235d7231d8SStephan Herhut if (opInst.getNumResults() != 0) { 3245d7231d8SStephan Herhut valueMapping[opInst.getResult(0)] = result; 325baa1ec22SAlex Zinenko return success(); 3265d7231d8SStephan Herhut } 3275d7231d8SStephan Herhut // Check that LLVM call returns void for 0-result functions. 328baa1ec22SAlex Zinenko return success(result->getType()->isVoidTy()); 3295d7231d8SStephan Herhut } 3305d7231d8SStephan Herhut 331d242aa24SShraiysh Vaishay if (auto invOp = dyn_cast<LLVM::InvokeOp>(opInst)) { 332d242aa24SShraiysh Vaishay auto operands = lookupValues(opInst.getOperands()); 333d242aa24SShraiysh Vaishay ArrayRef<llvm::Value *> operandsRef(operands); 334d242aa24SShraiysh Vaishay if (auto attr = opInst.getAttrOfType<FlatSymbolRefAttr>("callee")) 335d242aa24SShraiysh Vaishay builder.CreateInvoke(functionMapping.lookup(attr.getValue()), 336d242aa24SShraiysh Vaishay blockMapping[invOp.getSuccessor(0)], 337d242aa24SShraiysh Vaishay blockMapping[invOp.getSuccessor(1)], operandsRef); 338d242aa24SShraiysh Vaishay else 339d242aa24SShraiysh Vaishay builder.CreateInvoke( 340d242aa24SShraiysh Vaishay operandsRef.front(), blockMapping[invOp.getSuccessor(0)], 341d242aa24SShraiysh Vaishay blockMapping[invOp.getSuccessor(1)], operandsRef.drop_front()); 342d242aa24SShraiysh Vaishay return success(); 343d242aa24SShraiysh Vaishay } 344d242aa24SShraiysh Vaishay 345d242aa24SShraiysh Vaishay if (auto lpOp = dyn_cast<LLVM::LandingpadOp>(opInst)) { 346d242aa24SShraiysh Vaishay llvm::Type *ty = lpOp.getType().dyn_cast<LLVMType>().getUnderlyingType(); 347d242aa24SShraiysh Vaishay llvm::LandingPadInst *lpi = 348d242aa24SShraiysh Vaishay builder.CreateLandingPad(ty, lpOp.getNumOperands()); 349d242aa24SShraiysh Vaishay 350d242aa24SShraiysh Vaishay // Add clauses 351d242aa24SShraiysh Vaishay for (auto operand : lookupValues(lpOp.getOperands())) { 352d242aa24SShraiysh Vaishay // All operands should be constant - checked by verifier 353d242aa24SShraiysh Vaishay if (auto constOperand = dyn_cast<llvm::Constant>(operand)) 354d242aa24SShraiysh Vaishay lpi->addClause(constOperand); 355d242aa24SShraiysh Vaishay } 356d242aa24SShraiysh Vaishay return success(); 357d242aa24SShraiysh Vaishay } 358d242aa24SShraiysh Vaishay 3595d7231d8SStephan Herhut // Emit branches. We need to look up the remapped blocks and ignore the block 3605d7231d8SStephan Herhut // arguments that were transformed into PHI nodes. 361c5ecf991SRiver Riddle if (auto brOp = dyn_cast<LLVM::BrOp>(opInst)) { 362c0fd5e65SRiver Riddle builder.CreateBr(blockMapping[brOp.getSuccessor()]); 363baa1ec22SAlex Zinenko return success(); 3645d7231d8SStephan Herhut } 365c5ecf991SRiver Riddle if (auto condbrOp = dyn_cast<LLVM::CondBrOp>(opInst)) { 3665d7231d8SStephan Herhut builder.CreateCondBr(valueMapping.lookup(condbrOp.getOperand(0)), 3675d7231d8SStephan Herhut blockMapping[condbrOp.getSuccessor(0)], 3685d7231d8SStephan Herhut blockMapping[condbrOp.getSuccessor(1)]); 369baa1ec22SAlex Zinenko return success(); 3705d7231d8SStephan Herhut } 3715d7231d8SStephan Herhut 3722dd38b09SAlex Zinenko // Emit addressof. We need to look up the global value referenced by the 3732dd38b09SAlex Zinenko // operation and store it in the MLIR-to-LLVM value mapping. This does not 3742dd38b09SAlex Zinenko // emit any LLVM instruction. 3752dd38b09SAlex Zinenko if (auto addressOfOp = dyn_cast<LLVM::AddressOfOp>(opInst)) { 3762dd38b09SAlex Zinenko LLVM::GlobalOp global = addressOfOp.getGlobal(); 3772dd38b09SAlex Zinenko // The verifier should not have allowed this. 3782dd38b09SAlex Zinenko assert(global && "referencing an undefined global"); 3792dd38b09SAlex Zinenko 3802dd38b09SAlex Zinenko valueMapping[addressOfOp.getResult()] = globalsMapping.lookup(global); 3812dd38b09SAlex Zinenko return success(); 3822dd38b09SAlex Zinenko } 3832dd38b09SAlex Zinenko 38492a295ebSKiran Chandramohan if (opInst.getDialect() == ompDialect) { 38592a295ebSKiran Chandramohan if (!ompBuilder) { 3862773c692SBenjamin Kramer ompBuilder = std::make_unique<llvm::OpenMPIRBuilder>(*llvmModule); 38792a295ebSKiran Chandramohan ompBuilder->initialize(); 38892a295ebSKiran Chandramohan } 38992a295ebSKiran Chandramohan 39092a295ebSKiran Chandramohan if (isa<omp::BarrierOp>(opInst)) { 39192a295ebSKiran Chandramohan ompBuilder->CreateBarrier(builder.saveIP(), llvm::omp::OMPD_barrier); 39292a295ebSKiran Chandramohan return success(); 39392a295ebSKiran Chandramohan } 39492a295ebSKiran Chandramohan return opInst.emitError("unsupported OpenMP operation: ") 39592a295ebSKiran Chandramohan << opInst.getName(); 39692a295ebSKiran Chandramohan } 39792a295ebSKiran Chandramohan 398baa1ec22SAlex Zinenko return opInst.emitError("unsupported or non-LLVM operation: ") 399baa1ec22SAlex Zinenko << opInst.getName(); 4005d7231d8SStephan Herhut } 4015d7231d8SStephan Herhut 4022666b973SRiver Riddle /// Convert block to LLVM IR. Unless `ignoreArguments` is set, emit PHI nodes 4032666b973SRiver Riddle /// to define values corresponding to the MLIR block arguments. These nodes 4042666b973SRiver Riddle /// are not connected to the source basic blocks, which may not exist yet. 405baa1ec22SAlex Zinenko LogicalResult ModuleTranslation::convertBlock(Block &bb, bool ignoreArguments) { 4065d7231d8SStephan Herhut llvm::IRBuilder<> builder(blockMapping[&bb]); 407c33d6970SRiver Riddle auto *subprogram = builder.GetInsertBlock()->getParent()->getSubprogram(); 4085d7231d8SStephan Herhut 4095d7231d8SStephan Herhut // Before traversing operations, make block arguments available through 4105d7231d8SStephan Herhut // value remapping and PHI nodes, but do not add incoming edges for the PHI 4115d7231d8SStephan Herhut // nodes just yet: those values may be defined by this or following blocks. 4125d7231d8SStephan Herhut // This step is omitted if "ignoreArguments" is set. The arguments of the 4135d7231d8SStephan Herhut // first block have been already made available through the remapping of 4145d7231d8SStephan Herhut // LLVM function arguments. 4155d7231d8SStephan Herhut if (!ignoreArguments) { 4165d7231d8SStephan Herhut auto predecessors = bb.getPredecessors(); 4175d7231d8SStephan Herhut unsigned numPredecessors = 4185d7231d8SStephan Herhut std::distance(predecessors.begin(), predecessors.end()); 41935807bc4SRiver Riddle for (auto arg : bb.getArguments()) { 4202bdf33ccSRiver Riddle auto wrappedType = arg.getType().dyn_cast<LLVM::LLVMType>(); 421baa1ec22SAlex Zinenko if (!wrappedType) 422baa1ec22SAlex Zinenko return emitError(bb.front().getLoc(), 423a4c3a645SRiver Riddle "block argument does not have an LLVM type"); 4245d7231d8SStephan Herhut llvm::Type *type = wrappedType.getUnderlyingType(); 4255d7231d8SStephan Herhut llvm::PHINode *phi = builder.CreatePHI(type, numPredecessors); 4265d7231d8SStephan Herhut valueMapping[arg] = phi; 4275d7231d8SStephan Herhut } 4285d7231d8SStephan Herhut } 4295d7231d8SStephan Herhut 4305d7231d8SStephan Herhut // Traverse operations. 4315d7231d8SStephan Herhut for (auto &op : bb) { 432c33d6970SRiver Riddle // Set the current debug location within the builder. 433c33d6970SRiver Riddle builder.SetCurrentDebugLocation( 434c33d6970SRiver Riddle debugTranslation->translateLoc(op.getLoc(), subprogram)); 435c33d6970SRiver Riddle 436baa1ec22SAlex Zinenko if (failed(convertOperation(op, builder))) 437baa1ec22SAlex Zinenko return failure(); 4385d7231d8SStephan Herhut } 4395d7231d8SStephan Herhut 440baa1ec22SAlex Zinenko return success(); 4415d7231d8SStephan Herhut } 4425d7231d8SStephan Herhut 4432666b973SRiver Riddle /// Create named global variables that correspond to llvm.mlir.global 4442666b973SRiver Riddle /// definitions. 445efa2d533SAlex Zinenko LogicalResult ModuleTranslation::convertGlobals() { 44644fc7d72STres Popp for (auto op : getModuleBody(mlirModule).getOps<LLVM::GlobalOp>()) { 447250a11aeSJames Molloy llvm::Type *type = op.getType().getUnderlyingType(); 448250a11aeSJames Molloy llvm::Constant *cst = llvm::UndefValue::get(type); 449250a11aeSJames Molloy if (op.getValueOrNull()) { 45068451df2SAlex Zinenko // String attributes are treated separately because they cannot appear as 45168451df2SAlex Zinenko // in-function constants and are thus not supported by getLLVMConstant. 45233a3a91bSChristian Sigg if (auto strAttr = op.getValueOrNull().dyn_cast_or_null<StringAttr>()) { 4532dd38b09SAlex Zinenko cst = llvm::ConstantDataArray::getString( 45468451df2SAlex Zinenko llvmModule->getContext(), strAttr.getValue(), /*AddNull=*/false); 4552dd38b09SAlex Zinenko type = cst->getType(); 456efa2d533SAlex Zinenko } else if (!(cst = getLLVMConstant(type, op.getValueOrNull(), 457efa2d533SAlex Zinenko op.getLoc()))) { 458efa2d533SAlex Zinenko return failure(); 45968451df2SAlex Zinenko } 460250a11aeSJames Molloy } else if (Block *initializer = op.getInitializerBlock()) { 461250a11aeSJames Molloy llvm::IRBuilder<> builder(llvmModule->getContext()); 462250a11aeSJames Molloy for (auto &op : initializer->without_terminator()) { 463250a11aeSJames Molloy if (failed(convertOperation(op, builder)) || 464efa2d533SAlex Zinenko !isa<llvm::Constant>(valueMapping.lookup(op.getResult(0)))) 465efa2d533SAlex Zinenko return emitError(op.getLoc(), "unemittable constant value"); 466250a11aeSJames Molloy } 467250a11aeSJames Molloy ReturnOp ret = cast<ReturnOp>(initializer->getTerminator()); 468250a11aeSJames Molloy cst = cast<llvm::Constant>(valueMapping.lookup(ret.getOperand(0))); 469250a11aeSJames Molloy } 47068451df2SAlex Zinenko 471eb67bd78SAlex Zinenko auto linkage = convertLinkageToLLVM(op.linkage()); 472d5e627f8SAlex Zinenko bool anyExternalLinkage = 473d5e627f8SAlex Zinenko (linkage == llvm::GlobalVariable::ExternalLinkage || 474d5e627f8SAlex Zinenko linkage == llvm::GlobalVariable::ExternalWeakLinkage); 475e79bfefbSMLIR Team auto addrSpace = op.addr_space().getLimitedValue(); 476e79bfefbSMLIR Team auto *var = new llvm::GlobalVariable( 477d5e627f8SAlex Zinenko *llvmModule, type, op.constant(), linkage, 478d5e627f8SAlex Zinenko anyExternalLinkage ? nullptr : cst, op.sym_name(), 479d5e627f8SAlex Zinenko /*InsertBefore=*/nullptr, llvm::GlobalValue::NotThreadLocal, addrSpace); 480e79bfefbSMLIR Team 4812dd38b09SAlex Zinenko globalsMapping.try_emplace(op, var); 482b9ff2dd8SAlex Zinenko } 483efa2d533SAlex Zinenko 484efa2d533SAlex Zinenko return success(); 485b9ff2dd8SAlex Zinenko } 486b9ff2dd8SAlex Zinenko 4872666b973SRiver Riddle /// Get the SSA value passed to the current block from the terminator operation 4882666b973SRiver Riddle /// of its predecessor. 489e62a6956SRiver Riddle static Value getPHISourceValue(Block *current, Block *pred, 4905d7231d8SStephan Herhut unsigned numArguments, unsigned index) { 4915d7231d8SStephan Herhut auto &terminator = *pred->getTerminator(); 492d5b60ee8SRiver Riddle if (isa<LLVM::BrOp>(terminator)) { 4935d7231d8SStephan Herhut return terminator.getOperand(index); 4945d7231d8SStephan Herhut } 4955d7231d8SStephan Herhut 4965d7231d8SStephan Herhut // For conditional branches, we need to check if the current block is reached 4975d7231d8SStephan Herhut // through the "true" or the "false" branch and take the relevant operands. 498c5ecf991SRiver Riddle auto condBranchOp = dyn_cast<LLVM::CondBrOp>(terminator); 4995d7231d8SStephan Herhut assert(condBranchOp && 5005d7231d8SStephan Herhut "only branch operations can be terminators of a block that " 5015d7231d8SStephan Herhut "has successors"); 5025d7231d8SStephan Herhut assert((condBranchOp.getSuccessor(0) != condBranchOp.getSuccessor(1)) && 5035d7231d8SStephan Herhut "successors with arguments in LLVM conditional branches must be " 5045d7231d8SStephan Herhut "different blocks"); 5055d7231d8SStephan Herhut 5065d7231d8SStephan Herhut return condBranchOp.getSuccessor(0) == current 507988249a5SRiver Riddle ? condBranchOp.trueDestOperands()[index] 508988249a5SRiver Riddle : condBranchOp.falseDestOperands()[index]; 5095d7231d8SStephan Herhut } 5105d7231d8SStephan Herhut 5115e7959a3SAlex Zinenko void ModuleTranslation::connectPHINodes(LLVMFuncOp func) { 5125d7231d8SStephan Herhut // Skip the first block, it cannot be branched to and its arguments correspond 5135d7231d8SStephan Herhut // to the arguments of the LLVM function. 5145d7231d8SStephan Herhut for (auto it = std::next(func.begin()), eit = func.end(); it != eit; ++it) { 5155d7231d8SStephan Herhut Block *bb = &*it; 5165d7231d8SStephan Herhut llvm::BasicBlock *llvmBB = blockMapping.lookup(bb); 5175d7231d8SStephan Herhut auto phis = llvmBB->phis(); 5185d7231d8SStephan Herhut auto numArguments = bb->getNumArguments(); 5195d7231d8SStephan Herhut assert(numArguments == std::distance(phis.begin(), phis.end())); 5205d7231d8SStephan Herhut for (auto &numberedPhiNode : llvm::enumerate(phis)) { 5215d7231d8SStephan Herhut auto &phiNode = numberedPhiNode.value(); 5225d7231d8SStephan Herhut unsigned index = numberedPhiNode.index(); 5235d7231d8SStephan Herhut for (auto *pred : bb->getPredecessors()) { 5245d7231d8SStephan Herhut phiNode.addIncoming(valueMapping.lookup(getPHISourceValue( 5255d7231d8SStephan Herhut bb, pred, numArguments, index)), 5265d7231d8SStephan Herhut blockMapping.lookup(pred)); 5275d7231d8SStephan Herhut } 5285d7231d8SStephan Herhut } 5295d7231d8SStephan Herhut } 5305d7231d8SStephan Herhut } 5315d7231d8SStephan Herhut 5325d7231d8SStephan Herhut // TODO(mlir-team): implement an iterative version 5335d7231d8SStephan Herhut static void topologicalSortImpl(llvm::SetVector<Block *> &blocks, Block *b) { 5345d7231d8SStephan Herhut blocks.insert(b); 5355d7231d8SStephan Herhut for (Block *bb : b->getSuccessors()) { 5365d7231d8SStephan Herhut if (blocks.count(bb) == 0) 5375d7231d8SStephan Herhut topologicalSortImpl(blocks, bb); 5385d7231d8SStephan Herhut } 5395d7231d8SStephan Herhut } 5405d7231d8SStephan Herhut 5412666b973SRiver Riddle /// Sort function blocks topologically. 5425e7959a3SAlex Zinenko static llvm::SetVector<Block *> topologicalSort(LLVMFuncOp f) { 5435d7231d8SStephan Herhut // For each blocks that has not been visited yet (i.e. that has no 5445d7231d8SStephan Herhut // predecessors), add it to the list and traverse its successors in DFS 5455d7231d8SStephan Herhut // preorder. 5465d7231d8SStephan Herhut llvm::SetVector<Block *> blocks; 5475d7231d8SStephan Herhut for (Block &b : f.getBlocks()) { 5485d7231d8SStephan Herhut if (blocks.count(&b) == 0) 5495d7231d8SStephan Herhut topologicalSortImpl(blocks, &b); 5505d7231d8SStephan Herhut } 5515d7231d8SStephan Herhut assert(blocks.size() == f.getBlocks().size() && "some blocks are not sorted"); 5525d7231d8SStephan Herhut 5535d7231d8SStephan Herhut return blocks; 5545d7231d8SStephan Herhut } 5555d7231d8SStephan Herhut 5565e7959a3SAlex Zinenko LogicalResult ModuleTranslation::convertOneFunction(LLVMFuncOp func) { 5575d7231d8SStephan Herhut // Clear the block and value mappings, they are only relevant within one 5585d7231d8SStephan Herhut // function. 5595d7231d8SStephan Herhut blockMapping.clear(); 5605d7231d8SStephan Herhut valueMapping.clear(); 561c33862b0SRiver Riddle llvm::Function *llvmFunc = functionMapping.lookup(func.getName()); 562c33d6970SRiver Riddle 563c33d6970SRiver Riddle // Translate the debug information for this function. 564c33d6970SRiver Riddle debugTranslation->translate(func, *llvmFunc); 565c33d6970SRiver Riddle 5665d7231d8SStephan Herhut // Add function arguments to the value remapping table. 5675d7231d8SStephan Herhut // If there was noalias info then we decorate each argument accordingly. 5685d7231d8SStephan Herhut unsigned int argIdx = 0; 569eeef50b1SFangrui Song for (auto kvp : llvm::zip(func.getArguments(), llvmFunc->args())) { 5705d7231d8SStephan Herhut llvm::Argument &llvmArg = std::get<1>(kvp); 571e62a6956SRiver Riddle BlockArgument mlirArg = std::get<0>(kvp); 5725d7231d8SStephan Herhut 5735d7231d8SStephan Herhut if (auto attr = func.getArgAttrOfType<BoolAttr>(argIdx, "llvm.noalias")) { 5745d7231d8SStephan Herhut // NB: Attribute already verified to be boolean, so check if we can indeed 5755d7231d8SStephan Herhut // attach the attribute to this argument, based on its type. 5762bdf33ccSRiver Riddle auto argTy = mlirArg.getType().dyn_cast<LLVM::LLVMType>(); 577baa1ec22SAlex Zinenko if (!argTy.getUnderlyingType()->isPointerTy()) 578baa1ec22SAlex Zinenko return func.emitError( 5795d7231d8SStephan Herhut "llvm.noalias attribute attached to LLVM non-pointer argument"); 5805d7231d8SStephan Herhut if (attr.getValue()) 5815d7231d8SStephan Herhut llvmArg.addAttr(llvm::Attribute::AttrKind::NoAlias); 5825d7231d8SStephan Herhut } 5835d7231d8SStephan Herhut valueMapping[mlirArg] = &llvmArg; 5845d7231d8SStephan Herhut argIdx++; 5855d7231d8SStephan Herhut } 5865d7231d8SStephan Herhut 5875d7231d8SStephan Herhut // First, create all blocks so we can jump to them. 5885d7231d8SStephan Herhut llvm::LLVMContext &llvmContext = llvmFunc->getContext(); 5895d7231d8SStephan Herhut for (auto &bb : func) { 5905d7231d8SStephan Herhut auto *llvmBB = llvm::BasicBlock::Create(llvmContext); 5915d7231d8SStephan Herhut llvmBB->insertInto(llvmFunc); 5925d7231d8SStephan Herhut blockMapping[&bb] = llvmBB; 5935d7231d8SStephan Herhut } 5945d7231d8SStephan Herhut 5955d7231d8SStephan Herhut // Then, convert blocks one by one in topological order to ensure defs are 5965d7231d8SStephan Herhut // converted before uses. 5975d7231d8SStephan Herhut auto blocks = topologicalSort(func); 5985d7231d8SStephan Herhut for (auto indexedBB : llvm::enumerate(blocks)) { 5995d7231d8SStephan Herhut auto *bb = indexedBB.value(); 600baa1ec22SAlex Zinenko if (failed(convertBlock(*bb, /*ignoreArguments=*/indexedBB.index() == 0))) 601baa1ec22SAlex Zinenko return failure(); 6025d7231d8SStephan Herhut } 6035d7231d8SStephan Herhut 6045d7231d8SStephan Herhut // Finally, after all blocks have been traversed and values mapped, connect 6055d7231d8SStephan Herhut // the PHI nodes to the results of preceding blocks. 6065d7231d8SStephan Herhut connectPHINodes(func); 607baa1ec22SAlex Zinenko return success(); 6085d7231d8SStephan Herhut } 6095d7231d8SStephan Herhut 61044fc7d72STres Popp LogicalResult ModuleTranslation::checkSupportedModuleOps(Operation *m) { 61144fc7d72STres Popp for (Operation &o : getModuleBody(m).getOperations()) 6124dde19f0SAlex Zinenko if (!isa<LLVM::LLVMFuncOp>(&o) && !isa<LLVM::GlobalOp>(&o) && 61344fc7d72STres Popp !o.isKnownTerminator()) 6144dde19f0SAlex Zinenko return o.emitOpError("unsupported module-level operation"); 6154dde19f0SAlex Zinenko return success(); 6164dde19f0SAlex Zinenko } 6174dde19f0SAlex Zinenko 618baa1ec22SAlex Zinenko LogicalResult ModuleTranslation::convertFunctions() { 6195d7231d8SStephan Herhut // Declare all functions first because there may be function calls that form a 6205d7231d8SStephan Herhut // call graph with cycles. 62144fc7d72STres Popp for (auto function : getModuleBody(mlirModule).getOps<LLVMFuncOp>()) { 6225e7959a3SAlex Zinenko llvm::FunctionCallee llvmFuncCst = llvmModule->getOrInsertFunction( 6235e7959a3SAlex Zinenko function.getName(), 6244562e389SRiver Riddle cast<llvm::FunctionType>(function.getType().getUnderlyingType())); 6255d7231d8SStephan Herhut assert(isa<llvm::Function>(llvmFuncCst.getCallee())); 626c33862b0SRiver Riddle functionMapping[function.getName()] = 6275d7231d8SStephan Herhut cast<llvm::Function>(llvmFuncCst.getCallee()); 6285d7231d8SStephan Herhut } 6295d7231d8SStephan Herhut 6305d7231d8SStephan Herhut // Convert functions. 63144fc7d72STres Popp for (auto function : getModuleBody(mlirModule).getOps<LLVMFuncOp>()) { 6325d7231d8SStephan Herhut // Ignore external functions. 6335d7231d8SStephan Herhut if (function.isExternal()) 6345d7231d8SStephan Herhut continue; 6355d7231d8SStephan Herhut 636baa1ec22SAlex Zinenko if (failed(convertOneFunction(function))) 637baa1ec22SAlex Zinenko return failure(); 6385d7231d8SStephan Herhut } 6395d7231d8SStephan Herhut 640baa1ec22SAlex Zinenko return success(); 6415d7231d8SStephan Herhut } 6425d7231d8SStephan Herhut 643efadb6b8SAlex Zinenko /// A helper to look up remapped operands in the value remapping table.` 644efadb6b8SAlex Zinenko SmallVector<llvm::Value *, 8> 645efadb6b8SAlex Zinenko ModuleTranslation::lookupValues(ValueRange values) { 646efadb6b8SAlex Zinenko SmallVector<llvm::Value *, 8> remapped; 647efadb6b8SAlex Zinenko remapped.reserve(values.size()); 648e62a6956SRiver Riddle for (Value v : values) 649efadb6b8SAlex Zinenko remapped.push_back(valueMapping.lookup(v)); 650efadb6b8SAlex Zinenko return remapped; 651efadb6b8SAlex Zinenko } 652efadb6b8SAlex Zinenko 65344fc7d72STres Popp std::unique_ptr<llvm::Module> 65444fc7d72STres Popp ModuleTranslation::prepareLLVMModule(Operation *m) { 65544fc7d72STres Popp auto *dialect = m->getContext()->getRegisteredDialect<LLVM::LLVMDialect>(); 6565d7231d8SStephan Herhut assert(dialect && "LLVM dialect must be registered"); 6575d7231d8SStephan Herhut 658bc5c7378SRiver Riddle auto llvmModule = llvm::CloneModule(dialect->getLLVMModule()); 6595d7231d8SStephan Herhut if (!llvmModule) 6605d7231d8SStephan Herhut return nullptr; 6615d7231d8SStephan Herhut 6625d7231d8SStephan Herhut llvm::LLVMContext &llvmContext = llvmModule->getContext(); 6635d7231d8SStephan Herhut llvm::IRBuilder<> builder(llvmContext); 6645d7231d8SStephan Herhut 6655d7231d8SStephan Herhut // Inject declarations for `malloc` and `free` functions that can be used in 6665d7231d8SStephan Herhut // memref allocation/deallocation coming from standard ops lowering. 6675d7231d8SStephan Herhut llvmModule->getOrInsertFunction("malloc", builder.getInt8PtrTy(), 6685d7231d8SStephan Herhut builder.getInt64Ty()); 6695d7231d8SStephan Herhut llvmModule->getOrInsertFunction("free", builder.getVoidTy(), 6705d7231d8SStephan Herhut builder.getInt8PtrTy()); 6715d7231d8SStephan Herhut 6725d7231d8SStephan Herhut return llvmModule; 6735d7231d8SStephan Herhut } 674