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llvm-project/mlir/lib/Target/LLVMIR/ModuleTranslation.cpp
Mehdi Amini e1de2b7550 Separate the Registration from Loading dialects in the Context 
This changes the behavior of constructing MLIRContext to no longer load globally
registered dialects on construction. Instead Dialects are only loaded explicitly
on demand:
- the Parser is lazily loading Dialects in the context as it encounters them
during parsing. This is the only purpose for registering dialects and not load
them in the context.
- Passes are expected to declare the dialects they will create entity from
(Operations, Attributes, or Types), and the PassManager is loading Dialects into
the Context when starting a pipeline.

This changes simplifies the configuration of the registration: a compiler only
need to load the dialect for the IR it will emit, and the optimizer is
self-contained and load the required Dialects. For example in the Toy tutorial,
the compiler only needs to load the Toy dialect in the Context, all the others
(linalg, affine, std, LLVM, ...) are automatically loaded depending on the
optimization pipeline enabled.

To adjust to this change, stop using the existing dialect registration: the
global registry will be removed soon.

1) For passes, you need to override the method:

virtual void getDependentDialects(DialectRegistry &registry) const {}

and registery on the provided registry any dialect that this pass can produce.
Passes defined in TableGen can provide this list in the dependentDialects list
field.

2) For dialects, on construction you can register dependent dialects using the
provided MLIRContext: `context.getOrLoadDialect<DialectName>()`
This is useful if a dialect may canonicalize or have interfaces involving
another dialect.

3) For loading IR, dialect that can be in the input file must be explicitly
registered with the context. `MlirOptMain()` is taking an explicit registry for
this purpose. See how the standalone-opt.cpp example is setup:

  mlir::DialectRegistry registry;
  mlir::registerDialect<mlir::standalone::StandaloneDialect>();
  mlir::registerDialect<mlir::StandardOpsDialect>();

Only operations from these two dialects can be in the input file. To include all
of the dialects in MLIR Core, you can populate the registry this way:

  mlir::registerAllDialects(registry);

4) For `mlir-translate` callback, as well as frontend, Dialects can be loaded in
the context before emitting the IR: context.getOrLoadDialect<ToyDialect>()
2020-08-18 21:14:39 +00:00

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//===- ModuleTranslation.cpp - MLIR to LLVM conversion --------------------===//
//
// 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
//
//===----------------------------------------------------------------------===//
//
// This file implements the translation between an MLIR LLVM dialect module and
// the corresponding LLVMIR module. It only handles core LLVM IR operations.
//
//===----------------------------------------------------------------------===//
#include "mlir/Target/LLVMIR/ModuleTranslation.h"
#include "DebugTranslation.h"
#include "mlir/Dialect/LLVMIR/LLVMDialect.h"
#include "mlir/Dialect/OpenMP/OpenMPDialect.h"
#include "mlir/IR/Attributes.h"
#include "mlir/IR/Module.h"
#include "mlir/IR/StandardTypes.h"
#include "mlir/Support/LLVM.h"
#include "mlir/Target/LLVMIR/TypeTranslation.h"
#include "llvm/ADT/TypeSwitch.h"
#include "llvm/ADT/SetVector.h"
#include "llvm/Frontend/OpenMP/OMPIRBuilder.h"
#include "llvm/IR/BasicBlock.h"
#include "llvm/IR/CFG.h"
#include "llvm/IR/Constants.h"
#include "llvm/IR/DerivedTypes.h"
#include "llvm/IR/IRBuilder.h"
#include "llvm/IR/LLVMContext.h"
#include "llvm/IR/MDBuilder.h"
#include "llvm/IR/Module.h"
#include "llvm/Transforms/Utils/BasicBlockUtils.h"
#include "llvm/Transforms/Utils/Cloning.h"
using namespace mlir;
using namespace mlir::LLVM;
using namespace mlir::LLVM::detail;
#include "mlir/Dialect/LLVMIR/LLVMConversionEnumsToLLVM.inc"
/// Builds a constant of a sequential LLVM type `type`, potentially containing
/// other sequential types recursively, from the individual constant values
/// provided in `constants`. `shape` contains the number of elements in nested
/// sequential types. Reports errors at `loc` and returns nullptr on error.
static llvm::Constant *
buildSequentialConstant(ArrayRef<llvm::Constant *> &constants,
ArrayRef<int64_t> shape, llvm::Type *type,
Location loc) {
if (shape.empty()) {
llvm::Constant *result = constants.front();
constants = constants.drop_front();
return result;
}
llvm::Type *elementType;
if (auto *arrayTy = dyn_cast<llvm::ArrayType>(type)) {
elementType = arrayTy->getElementType();
} else if (auto *vectorTy = dyn_cast<llvm::VectorType>(type)) {
elementType = vectorTy->getElementType();
} else {
emitError(loc) << "expected sequential LLVM types wrapping a scalar";
return nullptr;
}
SmallVector<llvm::Constant *, 8> nested;
nested.reserve(shape.front());
for (int64_t i = 0; i < shape.front(); ++i) {
nested.push_back(buildSequentialConstant(constants, shape.drop_front(),
elementType, loc));
if (!nested.back())
return nullptr;
}
if (shape.size() == 1 && type->isVectorTy())
return llvm::ConstantVector::get(nested);
return llvm::ConstantArray::get(
llvm::ArrayType::get(elementType, shape.front()), nested);
}
/// Returns the first non-sequential type nested in sequential types.
static llvm::Type *getInnermostElementType(llvm::Type *type) {
do {
if (auto *arrayTy = dyn_cast<llvm::ArrayType>(type)) {
type = arrayTy->getElementType();
} else if (auto *vectorTy = dyn_cast<llvm::VectorType>(type)) {
type = vectorTy->getElementType();
} else {
return type;
}
} while (1);
}
/// Create an LLVM IR constant of `llvmType` from the MLIR attribute `attr`.
/// This currently supports integer, floating point, splat and dense element
/// attributes and combinations thereof. In case of error, report it to `loc`
/// and return nullptr.
llvm::Constant *ModuleTranslation::getLLVMConstant(llvm::Type *llvmType,
Attribute attr,
Location loc) {
if (!attr)
return llvm::UndefValue::get(llvmType);
if (llvmType->isStructTy()) {
emitError(loc, "struct types are not supported in constants");
return nullptr;
}
// For integer types, we allow a mismatch in sizes as the index type in
// MLIR might have a different size than the index type in the LLVM module.
if (auto intAttr = attr.dyn_cast<IntegerAttr>())
return llvm::ConstantInt::get(
llvmType,
intAttr.getValue().sextOrTrunc(llvmType->getIntegerBitWidth()));
if (auto floatAttr = attr.dyn_cast<FloatAttr>())
return llvm::ConstantFP::get(llvmType, floatAttr.getValue());
if (auto funcAttr = attr.dyn_cast<FlatSymbolRefAttr>())
return llvm::ConstantExpr::getBitCast(
functionMapping.lookup(funcAttr.getValue()), llvmType);
if (auto splatAttr = attr.dyn_cast<SplatElementsAttr>()) {
llvm::Type *elementType;
uint64_t numElements;
if (auto *arrayTy = dyn_cast<llvm::ArrayType>(llvmType)) {
elementType = arrayTy->getElementType();
numElements = arrayTy->getNumElements();
} else {
auto *vectorTy = cast<llvm::FixedVectorType>(llvmType);
elementType = vectorTy->getElementType();
numElements = vectorTy->getNumElements();
}
// Splat value is a scalar. Extract it only if the element type is not
// another sequence type. The recursion terminates because each step removes
// one outer sequential type.
bool elementTypeSequential =
isa<llvm::ArrayType, llvm::VectorType>(elementType);
llvm::Constant *child = getLLVMConstant(
elementType,
elementTypeSequential ? splatAttr : splatAttr.getSplatValue(), loc);
if (!child)
return nullptr;
if (llvmType->isVectorTy())
return llvm::ConstantVector::getSplat(
llvm::ElementCount(numElements, /*Scalable=*/false), child);
if (llvmType->isArrayTy()) {
auto *arrayType = llvm::ArrayType::get(elementType, numElements);
SmallVector<llvm::Constant *, 8> constants(numElements, child);
return llvm::ConstantArray::get(arrayType, constants);
}
}
if (auto elementsAttr = attr.dyn_cast<ElementsAttr>()) {
assert(elementsAttr.getType().hasStaticShape());
assert(elementsAttr.getNumElements() != 0 &&
"unexpected empty elements attribute");
assert(!elementsAttr.getType().getShape().empty() &&
"unexpected empty elements attribute shape");
SmallVector<llvm::Constant *, 8> constants;
constants.reserve(elementsAttr.getNumElements());
llvm::Type *innermostType = getInnermostElementType(llvmType);
for (auto n : elementsAttr.getValues<Attribute>()) {
constants.push_back(getLLVMConstant(innermostType, n, loc));
if (!constants.back())
return nullptr;
}
ArrayRef<llvm::Constant *> constantsRef = constants;
llvm::Constant *result = buildSequentialConstant(
constantsRef, elementsAttr.getType().getShape(), llvmType, loc);
assert(constantsRef.empty() && "did not consume all elemental constants");
return result;
}
if (auto stringAttr = attr.dyn_cast<StringAttr>()) {
return llvm::ConstantDataArray::get(
llvmModule->getContext(), ArrayRef<char>{stringAttr.getValue().data(),
stringAttr.getValue().size()});
}
emitError(loc, "unsupported constant value");
return nullptr;
}
/// Convert MLIR integer comparison predicate to LLVM IR comparison predicate.
static llvm::CmpInst::Predicate getLLVMCmpPredicate(ICmpPredicate p) {
switch (p) {
case LLVM::ICmpPredicate::eq:
return llvm::CmpInst::Predicate::ICMP_EQ;
case LLVM::ICmpPredicate::ne:
return llvm::CmpInst::Predicate::ICMP_NE;
case LLVM::ICmpPredicate::slt:
return llvm::CmpInst::Predicate::ICMP_SLT;
case LLVM::ICmpPredicate::sle:
return llvm::CmpInst::Predicate::ICMP_SLE;
case LLVM::ICmpPredicate::sgt:
return llvm::CmpInst::Predicate::ICMP_SGT;
case LLVM::ICmpPredicate::sge:
return llvm::CmpInst::Predicate::ICMP_SGE;
case LLVM::ICmpPredicate::ult:
return llvm::CmpInst::Predicate::ICMP_ULT;
case LLVM::ICmpPredicate::ule:
return llvm::CmpInst::Predicate::ICMP_ULE;
case LLVM::ICmpPredicate::ugt:
return llvm::CmpInst::Predicate::ICMP_UGT;
case LLVM::ICmpPredicate::uge:
return llvm::CmpInst::Predicate::ICMP_UGE;
}
llvm_unreachable("incorrect comparison predicate");
}
static llvm::CmpInst::Predicate getLLVMCmpPredicate(FCmpPredicate p) {
switch (p) {
case LLVM::FCmpPredicate::_false:
return llvm::CmpInst::Predicate::FCMP_FALSE;
case LLVM::FCmpPredicate::oeq:
return llvm::CmpInst::Predicate::FCMP_OEQ;
case LLVM::FCmpPredicate::ogt:
return llvm::CmpInst::Predicate::FCMP_OGT;
case LLVM::FCmpPredicate::oge:
return llvm::CmpInst::Predicate::FCMP_OGE;
case LLVM::FCmpPredicate::olt:
return llvm::CmpInst::Predicate::FCMP_OLT;
case LLVM::FCmpPredicate::ole:
return llvm::CmpInst::Predicate::FCMP_OLE;
case LLVM::FCmpPredicate::one:
return llvm::CmpInst::Predicate::FCMP_ONE;
case LLVM::FCmpPredicate::ord:
return llvm::CmpInst::Predicate::FCMP_ORD;
case LLVM::FCmpPredicate::ueq:
return llvm::CmpInst::Predicate::FCMP_UEQ;
case LLVM::FCmpPredicate::ugt:
return llvm::CmpInst::Predicate::FCMP_UGT;
case LLVM::FCmpPredicate::uge:
return llvm::CmpInst::Predicate::FCMP_UGE;
case LLVM::FCmpPredicate::ult:
return llvm::CmpInst::Predicate::FCMP_ULT;
case LLVM::FCmpPredicate::ule:
return llvm::CmpInst::Predicate::FCMP_ULE;
case LLVM::FCmpPredicate::une:
return llvm::CmpInst::Predicate::FCMP_UNE;
case LLVM::FCmpPredicate::uno:
return llvm::CmpInst::Predicate::FCMP_UNO;
case LLVM::FCmpPredicate::_true:
return llvm::CmpInst::Predicate::FCMP_TRUE;
}
llvm_unreachable("incorrect comparison predicate");
}
static llvm::AtomicRMWInst::BinOp getLLVMAtomicBinOp(AtomicBinOp op) {
switch (op) {
case LLVM::AtomicBinOp::xchg:
return llvm::AtomicRMWInst::BinOp::Xchg;
case LLVM::AtomicBinOp::add:
return llvm::AtomicRMWInst::BinOp::Add;
case LLVM::AtomicBinOp::sub:
return llvm::AtomicRMWInst::BinOp::Sub;
case LLVM::AtomicBinOp::_and:
return llvm::AtomicRMWInst::BinOp::And;
case LLVM::AtomicBinOp::nand:
return llvm::AtomicRMWInst::BinOp::Nand;
case LLVM::AtomicBinOp::_or:
return llvm::AtomicRMWInst::BinOp::Or;
case LLVM::AtomicBinOp::_xor:
return llvm::AtomicRMWInst::BinOp::Xor;
case LLVM::AtomicBinOp::max:
return llvm::AtomicRMWInst::BinOp::Max;
case LLVM::AtomicBinOp::min:
return llvm::AtomicRMWInst::BinOp::Min;
case LLVM::AtomicBinOp::umax:
return llvm::AtomicRMWInst::BinOp::UMax;
case LLVM::AtomicBinOp::umin:
return llvm::AtomicRMWInst::BinOp::UMin;
case LLVM::AtomicBinOp::fadd:
return llvm::AtomicRMWInst::BinOp::FAdd;
case LLVM::AtomicBinOp::fsub:
return llvm::AtomicRMWInst::BinOp::FSub;
}
llvm_unreachable("incorrect atomic binary operator");
}
static llvm::AtomicOrdering getLLVMAtomicOrdering(AtomicOrdering ordering) {
switch (ordering) {
case LLVM::AtomicOrdering::not_atomic:
return llvm::AtomicOrdering::NotAtomic;
case LLVM::AtomicOrdering::unordered:
return llvm::AtomicOrdering::Unordered;
case LLVM::AtomicOrdering::monotonic:
return llvm::AtomicOrdering::Monotonic;
case LLVM::AtomicOrdering::acquire:
return llvm::AtomicOrdering::Acquire;
case LLVM::AtomicOrdering::release:
return llvm::AtomicOrdering::Release;
case LLVM::AtomicOrdering::acq_rel:
return llvm::AtomicOrdering::AcquireRelease;
case LLVM::AtomicOrdering::seq_cst:
return llvm::AtomicOrdering::SequentiallyConsistent;
}
llvm_unreachable("incorrect atomic ordering");
}
ModuleTranslation::ModuleTranslation(Operation *module,
std::unique_ptr<llvm::Module> llvmModule)
: mlirModule(module), llvmModule(std::move(llvmModule)),
debugTranslation(
std::make_unique<DebugTranslation>(module, *this->llvmModule)),
ompDialect(module->getContext()->getOrLoadDialect<omp::OpenMPDialect>()),
typeTranslator(this->llvmModule->getContext()) {
assert(satisfiesLLVMModule(mlirModule) &&
"mlirModule should honor LLVM's module semantics.");
}
ModuleTranslation::~ModuleTranslation() {
if (ompBuilder)
ompBuilder->finalize();
}
/// Get the SSA value passed to the current block from the terminator operation
/// of its predecessor.
static Value getPHISourceValue(Block *current, Block *pred,
unsigned numArguments, unsigned index) {
Operation &terminator = *pred->getTerminator();
if (isa<LLVM::BrOp>(terminator))
return terminator.getOperand(index);
// For conditional branches, we need to check if the current block is reached
// through the "true" or the "false" branch and take the relevant operands.
auto condBranchOp = dyn_cast<LLVM::CondBrOp>(terminator);
assert(condBranchOp &&
"only branch operations can be terminators of a block that "
"has successors");
assert((condBranchOp.getSuccessor(0) != condBranchOp.getSuccessor(1)) &&
"successors with arguments in LLVM conditional branches must be "
"different blocks");
return condBranchOp.getSuccessor(0) == current
? condBranchOp.trueDestOperands()[index]
: condBranchOp.falseDestOperands()[index];
}
/// Connect the PHI nodes to the results of preceding blocks.
template <typename T>
static void
connectPHINodes(T &func, const DenseMap<Value, llvm::Value *> &valueMapping,
const DenseMap<Block *, llvm::BasicBlock *> &blockMapping) {
// Skip the first block, it cannot be branched to and its arguments correspond
// to the arguments of the LLVM function.
for (auto it = std::next(func.begin()), eit = func.end(); it != eit; ++it) {
Block *bb = &*it;
llvm::BasicBlock *llvmBB = blockMapping.lookup(bb);
auto phis = llvmBB->phis();
auto numArguments = bb->getNumArguments();
assert(numArguments == std::distance(phis.begin(), phis.end()));
for (auto &numberedPhiNode : llvm::enumerate(phis)) {
auto &phiNode = numberedPhiNode.value();
unsigned index = numberedPhiNode.index();
for (auto *pred : bb->getPredecessors()) {
phiNode.addIncoming(valueMapping.lookup(getPHISourceValue(
bb, pred, numArguments, index)),
blockMapping.lookup(pred));
}
}
}
}
// TODO: implement an iterative version
static void topologicalSortImpl(llvm::SetVector<Block *> &blocks, Block *b) {
blocks.insert(b);
for (Block *bb : b->getSuccessors()) {
if (blocks.count(bb) == 0)
topologicalSortImpl(blocks, bb);
}
}
/// Sort function blocks topologically.
template <typename T>
static llvm::SetVector<Block *> topologicalSort(T &f) {
// For each blocks that has not been visited yet (i.e. that has no
// predecessors), add it to the list and traverse its successors in DFS
// preorder.
llvm::SetVector<Block *> blocks;
for (Block &b : f) {
if (blocks.count(&b) == 0)
topologicalSortImpl(blocks, &b);
}
assert(blocks.size() == f.getBlocks().size() && "some blocks are not sorted");
return blocks;
}
/// Convert the OpenMP parallel Operation to LLVM IR.
LogicalResult
ModuleTranslation::convertOmpParallel(Operation &opInst,
llvm::IRBuilder<> &builder) {
using InsertPointTy = llvm::OpenMPIRBuilder::InsertPointTy;
auto bodyGenCB = [&](InsertPointTy allocaIP, InsertPointTy codeGenIP,
llvm::BasicBlock &continuationIP) {
llvm::LLVMContext &llvmContext = llvmModule->getContext();
llvm::BasicBlock *codeGenIPBB = codeGenIP.getBlock();
llvm::Instruction *codeGenIPBBTI = codeGenIPBB->getTerminator();
builder.SetInsertPoint(codeGenIPBB);
// ParallelOp has only `1` region associated with it.
auto &region = cast<omp::ParallelOp>(opInst).getRegion();
for (auto &bb : region) {
auto *llvmBB = llvm::BasicBlock::Create(
llvmContext, "omp.par.region", codeGenIP.getBlock()->getParent());
blockMapping[&bb] = llvmBB;
}
// Then, convert blocks one by one in topological order to ensure
// defs are converted before uses.
llvm::SetVector<Block *> blocks = topologicalSort(region);
for (auto indexedBB : llvm::enumerate(blocks)) {
Block *bb = indexedBB.value();
llvm::BasicBlock *curLLVMBB = blockMapping[bb];
if (bb->isEntryBlock())
codeGenIPBBTI->setSuccessor(0, curLLVMBB);
// TODO: Error not returned up the hierarchy
if (failed(convertBlock(*bb, /*ignoreArguments=*/indexedBB.index() == 0)))
return;
// If this block has the terminator then add a jump to
// continuation bb
for (auto &op : *bb) {
if (isa<omp::TerminatorOp>(op)) {
builder.SetInsertPoint(curLLVMBB);
builder.CreateBr(&continuationIP);
}
}
}
// Finally, after all blocks have been traversed and values mapped,
// connect the PHI nodes to the results of preceding blocks.
connectPHINodes(region, valueMapping, blockMapping);
};
// TODO: Perform appropriate actions according to the data-sharing
// attribute (shared, private, firstprivate, ...) of variables.
// Currently defaults to shared.
auto privCB = [&](InsertPointTy allocaIP, InsertPointTy codeGenIP,
llvm::Value &vPtr,
llvm::Value *&replacementValue) -> InsertPointTy {
replacementValue = &vPtr;
return codeGenIP;
};
// TODO: Perform finalization actions for variables. This has to be
// called for variables which have destructors/finalizers.
auto finiCB = [&](InsertPointTy codeGenIP) {};
llvm::Value *ifCond = nullptr;
if (auto ifExprVar = cast<omp::ParallelOp>(opInst).if_expr_var())
ifCond = valueMapping.lookup(ifExprVar);
llvm::Value *numThreads = nullptr;
if (auto numThreadsVar = cast<omp::ParallelOp>(opInst).num_threads_var())
numThreads = valueMapping.lookup(numThreadsVar);
llvm::omp::ProcBindKind pbKind = llvm::omp::OMP_PROC_BIND_default;
if (auto bind = cast<omp::ParallelOp>(opInst).proc_bind_val())
pbKind = llvm::omp::getProcBindKind(bind.getValue());
// TODO: Is the Parallel construct cancellable?
bool isCancellable = false;
// TODO: Determine the actual alloca insertion point, e.g., the function
// entry or the alloca insertion point as provided by the body callback
// above.
llvm::OpenMPIRBuilder::InsertPointTy allocaIP(builder.saveIP());
builder.restoreIP(
ompBuilder->CreateParallel(builder, allocaIP, bodyGenCB, privCB, finiCB,
ifCond, numThreads, pbKind, isCancellable));
return success();
}
/// Given an OpenMP MLIR operation, create the corresponding LLVM IR
/// (including OpenMP runtime calls).
LogicalResult
ModuleTranslation::convertOmpOperation(Operation &opInst,
llvm::IRBuilder<> &builder) {
if (!ompBuilder) {
ompBuilder = std::make_unique<llvm::OpenMPIRBuilder>(*llvmModule);
ompBuilder->initialize();
}
return llvm::TypeSwitch<Operation *, LogicalResult>(&opInst)
.Case([&](omp::BarrierOp) {
ompBuilder->CreateBarrier(builder.saveIP(), llvm::omp::OMPD_barrier);
return success();
})
.Case([&](omp::TaskwaitOp) {
ompBuilder->CreateTaskwait(builder.saveIP());
return success();
})
.Case([&](omp::TaskyieldOp) {
ompBuilder->CreateTaskyield(builder.saveIP());
return success();
})
.Case([&](omp::FlushOp) {
// No support in Openmp runtime funciton (__kmpc_flush) to accept
// the argument list.
// OpenMP standard states the following:
// "An implementation may implement a flush with a list by ignoring
// the list, and treating it the same as a flush without a list."
//
// The argument list is discarded so that, flush with a list is treated
// same as a flush without a list.
ompBuilder->CreateFlush(builder.saveIP());
return success();
})
.Case([&](omp::TerminatorOp) { return success(); })
.Case(
[&](omp::ParallelOp) { return convertOmpParallel(opInst, builder); })
.Default([&](Operation *inst) {
return inst->emitError("unsupported OpenMP operation: ")
<< inst->getName();
});
}
/// Given a single MLIR operation, create the corresponding LLVM IR operation
/// using the `builder`. LLVM IR Builder does not have a generic interface so
/// this has to be a long chain of `if`s calling different functions with a
/// different number of arguments.
LogicalResult ModuleTranslation::convertOperation(Operation &opInst,
llvm::IRBuilder<> &builder) {
auto extractPosition = [](ArrayAttr attr) {
SmallVector<unsigned, 4> position;
position.reserve(attr.size());
for (Attribute v : attr)
position.push_back(v.cast<IntegerAttr>().getValue().getZExtValue());
return position;
};
#include "mlir/Dialect/LLVMIR/LLVMConversions.inc"
// Emit function calls. If the "callee" attribute is present, this is a
// direct function call and we also need to look up the remapped function
// itself. Otherwise, this is an indirect call and the callee is the first
// operand, look it up as a normal value. Return the llvm::Value representing
// the function result, which may be of llvm::VoidTy type.
auto convertCall = [this, &builder](Operation &op) -> llvm::Value * {
auto operands = lookupValues(op.getOperands());
ArrayRef<llvm::Value *> operandsRef(operands);
if (auto attr = op.getAttrOfType<FlatSymbolRefAttr>("callee")) {
return builder.CreateCall(functionMapping.lookup(attr.getValue()),
operandsRef);
} else {
auto *calleePtrType =
cast<llvm::PointerType>(operandsRef.front()->getType());
auto *calleeType =
cast<llvm::FunctionType>(calleePtrType->getElementType());
return builder.CreateCall(calleeType, operandsRef.front(),
operandsRef.drop_front());
}
};
// Emit calls. If the called function has a result, remap the corresponding
// value. Note that LLVM IR dialect CallOp has either 0 or 1 result.
if (isa<LLVM::CallOp>(opInst)) {
llvm::Value *result = convertCall(opInst);
if (opInst.getNumResults() != 0) {
valueMapping[opInst.getResult(0)] = result;
return success();
}
// Check that LLVM call returns void for 0-result functions.
return success(result->getType()->isVoidTy());
}
if (auto invOp = dyn_cast<LLVM::InvokeOp>(opInst)) {
auto operands = lookupValues(opInst.getOperands());
ArrayRef<llvm::Value *> operandsRef(operands);
if (auto attr = opInst.getAttrOfType<FlatSymbolRefAttr>("callee")) {
builder.CreateInvoke(functionMapping.lookup(attr.getValue()),
blockMapping[invOp.getSuccessor(0)],
blockMapping[invOp.getSuccessor(1)], operandsRef);
} else {
auto *calleePtrType =
cast<llvm::PointerType>(operandsRef.front()->getType());
auto *calleeType =
cast<llvm::FunctionType>(calleePtrType->getElementType());
builder.CreateInvoke(
calleeType, operandsRef.front(), blockMapping[invOp.getSuccessor(0)],
blockMapping[invOp.getSuccessor(1)], operandsRef.drop_front());
}
return success();
}
if (auto lpOp = dyn_cast<LLVM::LandingpadOp>(opInst)) {
llvm::Type *ty = convertType(lpOp.getType().cast<LLVMType>());
llvm::LandingPadInst *lpi =
builder.CreateLandingPad(ty, lpOp.getNumOperands());
// Add clauses
for (auto operand : lookupValues(lpOp.getOperands())) {
// All operands should be constant - checked by verifier
if (auto constOperand = dyn_cast<llvm::Constant>(operand))
lpi->addClause(constOperand);
}
valueMapping[lpOp.getResult()] = lpi;
return success();
}
// Emit branches. We need to look up the remapped blocks and ignore the block
// arguments that were transformed into PHI nodes.
if (auto brOp = dyn_cast<LLVM::BrOp>(opInst)) {
builder.CreateBr(blockMapping[brOp.getSuccessor()]);
return success();
}
if (auto condbrOp = dyn_cast<LLVM::CondBrOp>(opInst)) {
auto weights = condbrOp.branch_weights();
llvm::MDNode *branchWeights = nullptr;
if (weights) {
// Map weight attributes to LLVM metadata.
auto trueWeight =
weights.getValue().getValue(0).cast<IntegerAttr>().getInt();
auto falseWeight =
weights.getValue().getValue(1).cast<IntegerAttr>().getInt();
branchWeights =
llvm::MDBuilder(llvmModule->getContext())
.createBranchWeights(static_cast<uint32_t>(trueWeight),
static_cast<uint32_t>(falseWeight));
}
builder.CreateCondBr(valueMapping.lookup(condbrOp.getOperand(0)),
blockMapping[condbrOp.getSuccessor(0)],
blockMapping[condbrOp.getSuccessor(1)], branchWeights);
return success();
}
// Emit addressof. We need to look up the global value referenced by the
// operation and store it in the MLIR-to-LLVM value mapping. This does not
// emit any LLVM instruction.
if (auto addressOfOp = dyn_cast<LLVM::AddressOfOp>(opInst)) {
LLVM::GlobalOp global = addressOfOp.getGlobal();
LLVM::LLVMFuncOp function = addressOfOp.getFunction();
// The verifier should not have allowed this.
assert((global || function) &&
"referencing an undefined global or function");
valueMapping[addressOfOp.getResult()] =
global ? globalsMapping.lookup(global)
: functionMapping.lookup(function.getName());
return success();
}
if (opInst.getDialect() == ompDialect) {
return convertOmpOperation(opInst, builder);
}
return opInst.emitError("unsupported or non-LLVM operation: ")
<< opInst.getName();
}
/// Convert block to LLVM IR. Unless `ignoreArguments` is set, emit PHI nodes
/// to define values corresponding to the MLIR block arguments. These nodes
/// are not connected to the source basic blocks, which may not exist yet.
LogicalResult ModuleTranslation::convertBlock(Block &bb, bool ignoreArguments) {
llvm::IRBuilder<> builder(blockMapping[&bb]);
auto *subprogram = builder.GetInsertBlock()->getParent()->getSubprogram();
// Before traversing operations, make block arguments available through
// value remapping and PHI nodes, but do not add incoming edges for the PHI
// nodes just yet: those values may be defined by this or following blocks.
// This step is omitted if "ignoreArguments" is set. The arguments of the
// first block have been already made available through the remapping of
// LLVM function arguments.
if (!ignoreArguments) {
auto predecessors = bb.getPredecessors();
unsigned numPredecessors =
std::distance(predecessors.begin(), predecessors.end());
for (auto arg : bb.getArguments()) {
auto wrappedType = arg.getType().dyn_cast<LLVM::LLVMType>();
if (!wrappedType)
return emitError(bb.front().getLoc(),
"block argument does not have an LLVM type");
llvm::Type *type = convertType(wrappedType);
llvm::PHINode *phi = builder.CreatePHI(type, numPredecessors);
valueMapping[arg] = phi;
}
}
// Traverse operations.
for (auto &op : bb) {
// Set the current debug location within the builder.
builder.SetCurrentDebugLocation(
debugTranslation->translateLoc(op.getLoc(), subprogram));
if (failed(convertOperation(op, builder)))
return failure();
}
return success();
}
/// Create named global variables that correspond to llvm.mlir.global
/// definitions.
LogicalResult ModuleTranslation::convertGlobals() {
for (auto op : getModuleBody(mlirModule).getOps<LLVM::GlobalOp>()) {
llvm::Type *type = convertType(op.getType());
llvm::Constant *cst = llvm::UndefValue::get(type);
if (op.getValueOrNull()) {
// String attributes are treated separately because they cannot appear as
// in-function constants and are thus not supported by getLLVMConstant.
if (auto strAttr = op.getValueOrNull().dyn_cast_or_null<StringAttr>()) {
cst = llvm::ConstantDataArray::getString(
llvmModule->getContext(), strAttr.getValue(), /*AddNull=*/false);
type = cst->getType();
} else if (!(cst = getLLVMConstant(type, op.getValueOrNull(),
op.getLoc()))) {
return failure();
}
} else if (Block *initializer = op.getInitializerBlock()) {
llvm::IRBuilder<> builder(llvmModule->getContext());
for (auto &op : initializer->without_terminator()) {
if (failed(convertOperation(op, builder)) ||
!isa<llvm::Constant>(valueMapping.lookup(op.getResult(0))))
return emitError(op.getLoc(), "unemittable constant value");
}
ReturnOp ret = cast<ReturnOp>(initializer->getTerminator());
cst = cast<llvm::Constant>(valueMapping.lookup(ret.getOperand(0)));
}
auto linkage = convertLinkageToLLVM(op.linkage());
bool anyExternalLinkage =
((linkage == llvm::GlobalVariable::ExternalLinkage &&
isa<llvm::UndefValue>(cst)) ||
linkage == llvm::GlobalVariable::ExternalWeakLinkage);
auto addrSpace = op.addr_space().getLimitedValue();
auto *var = new llvm::GlobalVariable(
*llvmModule, type, op.constant(), linkage,
anyExternalLinkage ? nullptr : cst, op.sym_name(),
/*InsertBefore=*/nullptr, llvm::GlobalValue::NotThreadLocal, addrSpace);
globalsMapping.try_emplace(op, var);
}
return success();
}
/// Attempts to add an attribute identified by `key`, optionally with the given
/// `value` to LLVM function `llvmFunc`. Reports errors at `loc` if any. If the
/// attribute has a kind known to LLVM IR, create the attribute of this kind,
/// otherwise keep it as a string attribute. Performs additional checks for
/// attributes known to have or not have a value in order to avoid assertions
/// inside LLVM upon construction.
static LogicalResult checkedAddLLVMFnAttribute(Location loc,
llvm::Function *llvmFunc,
StringRef key,
StringRef value = StringRef()) {
auto kind = llvm::Attribute::getAttrKindFromName(key);
if (kind == llvm::Attribute::None) {
llvmFunc->addFnAttr(key, value);
return success();
}
if (llvm::Attribute::doesAttrKindHaveArgument(kind)) {
if (value.empty())
return emitError(loc) << "LLVM attribute '" << key << "' expects a value";
int result;
if (!value.getAsInteger(/*Radix=*/0, result))
llvmFunc->addFnAttr(
llvm::Attribute::get(llvmFunc->getContext(), kind, result));
else
llvmFunc->addFnAttr(key, value);
return success();
}
if (!value.empty())
return emitError(loc) << "LLVM attribute '" << key
<< "' does not expect a value, found '" << value
<< "'";
llvmFunc->addFnAttr(kind);
return success();
}
/// Attaches the attributes listed in the given array attribute to `llvmFunc`.
/// Reports error to `loc` if any and returns immediately. Expects `attributes`
/// to be an array attribute containing either string attributes, treated as
/// value-less LLVM attributes, or array attributes containing two string
/// attributes, with the first string being the name of the corresponding LLVM
/// attribute and the second string beings its value. Note that even integer
/// attributes are expected to have their values expressed as strings.
static LogicalResult
forwardPassthroughAttributes(Location loc, Optional<ArrayAttr> attributes,
llvm::Function *llvmFunc) {
if (!attributes)
return success();
for (Attribute attr : *attributes) {
if (auto stringAttr = attr.dyn_cast<StringAttr>()) {
if (failed(
checkedAddLLVMFnAttribute(loc, llvmFunc, stringAttr.getValue())))
return failure();
continue;
}
auto arrayAttr = attr.dyn_cast<ArrayAttr>();
if (!arrayAttr || arrayAttr.size() != 2)
return emitError(loc)
<< "expected 'passthrough' to contain string or array attributes";
auto keyAttr = arrayAttr[0].dyn_cast<StringAttr>();
auto valueAttr = arrayAttr[1].dyn_cast<StringAttr>();
if (!keyAttr || !valueAttr)
return emitError(loc)
<< "expected arrays within 'passthrough' to contain two strings";
if (failed(checkedAddLLVMFnAttribute(loc, llvmFunc, keyAttr.getValue(),
valueAttr.getValue())))
return failure();
}
return success();
}
LogicalResult ModuleTranslation::convertOneFunction(LLVMFuncOp func) {
// Clear the block and value mappings, they are only relevant within one
// function.
blockMapping.clear();
valueMapping.clear();
llvm::Function *llvmFunc = functionMapping.lookup(func.getName());
// Translate the debug information for this function.
debugTranslation->translate(func, *llvmFunc);
// Add function arguments to the value remapping table.
// If there was noalias info then we decorate each argument accordingly.
unsigned int argIdx = 0;
for (auto kvp : llvm::zip(func.getArguments(), llvmFunc->args())) {
llvm::Argument &llvmArg = std::get<1>(kvp);
BlockArgument mlirArg = std::get<0>(kvp);
if (auto attr = func.getArgAttrOfType<BoolAttr>(argIdx, "llvm.noalias")) {
// NB: Attribute already verified to be boolean, so check if we can indeed
// attach the attribute to this argument, based on its type.
auto argTy = mlirArg.getType().dyn_cast<LLVM::LLVMType>();
if (!argTy.isPointerTy())
return func.emitError(
"llvm.noalias attribute attached to LLVM non-pointer argument");
if (attr.getValue())
llvmArg.addAttr(llvm::Attribute::AttrKind::NoAlias);
}
if (auto attr = func.getArgAttrOfType<IntegerAttr>(argIdx, "llvm.align")) {
// NB: Attribute already verified to be int, so check if we can indeed
// attach the attribute to this argument, based on its type.
auto argTy = mlirArg.getType().dyn_cast<LLVM::LLVMType>();
if (!argTy.isPointerTy())
return func.emitError(
"llvm.align attribute attached to LLVM non-pointer argument");
llvmArg.addAttrs(
llvm::AttrBuilder().addAlignmentAttr(llvm::Align(attr.getInt())));
}
valueMapping[mlirArg] = &llvmArg;
argIdx++;
}
// Check the personality and set it.
if (func.personality().hasValue()) {
llvm::Type *ty = llvm::Type::getInt8PtrTy(llvmFunc->getContext());
if (llvm::Constant *pfunc =
getLLVMConstant(ty, func.personalityAttr(), func.getLoc()))
llvmFunc->setPersonalityFn(pfunc);
}
// First, create all blocks so we can jump to them.
llvm::LLVMContext &llvmContext = llvmFunc->getContext();
for (auto &bb : func) {
auto *llvmBB = llvm::BasicBlock::Create(llvmContext);
llvmBB->insertInto(llvmFunc);
blockMapping[&bb] = llvmBB;
}
// Then, convert blocks one by one in topological order to ensure defs are
// converted before uses.
auto blocks = topologicalSort(func);
for (auto indexedBB : llvm::enumerate(blocks)) {
auto *bb = indexedBB.value();
if (failed(convertBlock(*bb, /*ignoreArguments=*/indexedBB.index() == 0)))
return failure();
}
// Finally, after all blocks have been traversed and values mapped, connect
// the PHI nodes to the results of preceding blocks.
connectPHINodes(func, valueMapping, blockMapping);
return success();
}
LogicalResult ModuleTranslation::checkSupportedModuleOps(Operation *m) {
for (Operation &o : getModuleBody(m).getOperations())
if (!isa<LLVM::LLVMFuncOp, LLVM::GlobalOp>(&o) && !o.isKnownTerminator())
return o.emitOpError("unsupported module-level operation");
return success();
}
LogicalResult ModuleTranslation::convertFunctionSignatures() {
// Declare all functions first because there may be function calls that form a
// call graph with cycles, or global initializers that reference functions.
for (auto function : getModuleBody(mlirModule).getOps<LLVMFuncOp>()) {
llvm::FunctionCallee llvmFuncCst = llvmModule->getOrInsertFunction(
function.getName(),
cast<llvm::FunctionType>(convertType(function.getType())));
llvm::Function *llvmFunc = cast<llvm::Function>(llvmFuncCst.getCallee());
llvmFunc->setLinkage(convertLinkageToLLVM(function.linkage()));
functionMapping[function.getName()] = llvmFunc;
// Forward the pass-through attributes to LLVM.
if (failed(forwardPassthroughAttributes(function.getLoc(),
function.passthrough(), llvmFunc)))
return failure();
}
return success();
}
LogicalResult ModuleTranslation::convertFunctions() {
// Convert functions.
for (auto function : getModuleBody(mlirModule).getOps<LLVMFuncOp>()) {
// Ignore external functions.
if (function.isExternal())
continue;
if (failed(convertOneFunction(function)))
return failure();
}
return success();
}
llvm::Type *ModuleTranslation::convertType(LLVMType type) {
return typeTranslator.translateType(type);
}
/// A helper to look up remapped operands in the value remapping table.`
SmallVector<llvm::Value *, 8>
ModuleTranslation::lookupValues(ValueRange values) {
SmallVector<llvm::Value *, 8> remapped;
remapped.reserve(values.size());
for (Value v : values) {
assert(valueMapping.count(v) && "referencing undefined value");
remapped.push_back(valueMapping.lookup(v));
}
return remapped;
}
std::unique_ptr<llvm::Module> ModuleTranslation::prepareLLVMModule(
Operation *m, llvm::LLVMContext &llvmContext, StringRef name) {
m->getContext()->getOrLoadDialect<LLVM::LLVMDialect>();
auto llvmModule = std::make_unique<llvm::Module>(name, llvmContext);
if (auto dataLayoutAttr =
m->getAttr(LLVM::LLVMDialect::getDataLayoutAttrName()))
llvmModule->setDataLayout(dataLayoutAttr.cast<StringAttr>().getValue());
// Inject declarations for `malloc` and `free` functions that can be used in
// memref allocation/deallocation coming from standard ops lowering.
llvm::IRBuilder<> builder(llvmContext);
llvmModule->getOrInsertFunction("malloc", builder.getInt8PtrTy(),
builder.getInt64Ty());
llvmModule->getOrInsertFunction("free", builder.getVoidTy(),
builder.getInt8PtrTy());
return llvmModule;
}
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