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TypeConverter.cpp
612 lines (545 loc) · 24.8 KB
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TypeConverter.cpp
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//===- TypeConverter.cpp - Convert builtin to LLVM dialect types ----------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#include "mlir/Conversion/LLVMCommon/TypeConverter.h"
#include "MemRefDescriptor.h"
#include "mlir/Conversion/LLVMCommon/MemRefBuilder.h"
#include "mlir/Dialect/LLVMIR/LLVMDialect.h"
#include "mlir/Dialect/LLVMIR/LLVMTypes.h"
#include <optional>
using namespace mlir;
/// Create an LLVMTypeConverter using default LowerToLLVMOptions.
LLVMTypeConverter::LLVMTypeConverter(MLIRContext *ctx,
const DataLayoutAnalysis *analysis)
: LLVMTypeConverter(ctx, LowerToLLVMOptions(ctx), analysis) {}
/// Create an LLVMTypeConverter using custom LowerToLLVMOptions.
LLVMTypeConverter::LLVMTypeConverter(MLIRContext *ctx,
const LowerToLLVMOptions &options,
const DataLayoutAnalysis *analysis)
: llvmDialect(ctx->getOrLoadDialect<LLVM::LLVMDialect>()), options(options),
dataLayoutAnalysis(analysis) {
assert(llvmDialect && "LLVM IR dialect is not registered");
// Register conversions for the builtin types.
addConversion([&](ComplexType type) { return convertComplexType(type); });
addConversion([&](FloatType type) { return convertFloatType(type); });
addConversion([&](FunctionType type) { return convertFunctionType(type); });
addConversion([&](IndexType type) { return convertIndexType(type); });
addConversion([&](IntegerType type) { return convertIntegerType(type); });
addConversion([&](MemRefType type) { return convertMemRefType(type); });
addConversion(
[&](UnrankedMemRefType type) { return convertUnrankedMemRefType(type); });
addConversion([&](VectorType type) { return convertVectorType(type); });
// LLVM-compatible types are legal, so add a pass-through conversion. Do this
// before the conversions below since conversions are attempted in reverse
// order and those should take priority.
addConversion([](Type type) {
return LLVM::isCompatibleType(type) ? std::optional<Type>(type)
: std::nullopt;
});
// LLVM container types may (recursively) contain other types that must be
// converted even when the outer type is compatible.
addConversion([&](LLVM::LLVMPointerType type) -> std::optional<Type> {
if (type.isOpaque())
return type;
if (auto pointee = convertType(type.getElementType()))
return LLVM::LLVMPointerType::get(pointee, type.getAddressSpace());
return std::nullopt;
});
addConversion([&](LLVM::LLVMStructType type, SmallVectorImpl<Type> &results,
ArrayRef<Type> callStack) -> std::optional<LogicalResult> {
// Fastpath for types that won't be converted by this callback anyway.
if (LLVM::isCompatibleType(type)) {
results.push_back(type);
return success();
}
if (type.isIdentified()) {
auto convertedType = LLVM::LLVMStructType::getIdentified(
type.getContext(), ("_Converted_" + type.getName()).str());
unsigned counter = 1;
while (convertedType.isInitialized()) {
assert(counter != UINT_MAX &&
"about to overflow struct renaming counter in conversion");
convertedType = LLVM::LLVMStructType::getIdentified(
type.getContext(),
("_Converted_" + std::to_string(counter) + type.getName()).str());
}
if (llvm::count(callStack, type) > 1) {
results.push_back(convertedType);
return success();
}
SmallVector<Type> convertedElemTypes;
convertedElemTypes.reserve(type.getBody().size());
if (failed(convertTypes(type.getBody(), convertedElemTypes)))
return std::nullopt;
if (failed(convertedType.setBody(convertedElemTypes, type.isPacked())))
return failure();
results.push_back(convertedType);
return success();
}
SmallVector<Type> convertedSubtypes;
convertedSubtypes.reserve(type.getBody().size());
if (failed(convertTypes(type.getBody(), convertedSubtypes)))
return std::nullopt;
results.push_back(LLVM::LLVMStructType::getLiteral(
type.getContext(), convertedSubtypes, type.isPacked()));
return success();
});
addConversion([&](LLVM::LLVMArrayType type) -> std::optional<Type> {
if (auto element = convertType(type.getElementType()))
return LLVM::LLVMArrayType::get(element, type.getNumElements());
return std::nullopt;
});
addConversion([&](LLVM::LLVMFunctionType type) -> std::optional<Type> {
Type convertedResType = convertType(type.getReturnType());
if (!convertedResType)
return std::nullopt;
SmallVector<Type> convertedArgTypes;
convertedArgTypes.reserve(type.getNumParams());
if (failed(convertTypes(type.getParams(), convertedArgTypes)))
return std::nullopt;
return LLVM::LLVMFunctionType::get(convertedResType, convertedArgTypes,
type.isVarArg());
});
// Materialization for memrefs creates descriptor structs from individual
// values constituting them, when descriptors are used, i.e. more than one
// value represents a memref.
addArgumentMaterialization(
[&](OpBuilder &builder, UnrankedMemRefType resultType, ValueRange inputs,
Location loc) -> std::optional<Value> {
if (inputs.size() == 1)
return std::nullopt;
return UnrankedMemRefDescriptor::pack(builder, loc, *this, resultType,
inputs);
});
addArgumentMaterialization([&](OpBuilder &builder, MemRefType resultType,
ValueRange inputs,
Location loc) -> std::optional<Value> {
// TODO: bare ptr conversion could be handled here but we would need a way
// to distinguish between FuncOp and other regions.
if (inputs.size() == 1)
return std::nullopt;
return MemRefDescriptor::pack(builder, loc, *this, resultType, inputs);
});
// Add generic source and target materializations to handle cases where
// non-LLVM types persist after an LLVM conversion.
addSourceMaterialization([&](OpBuilder &builder, Type resultType,
ValueRange inputs,
Location loc) -> std::optional<Value> {
if (inputs.size() != 1)
return std::nullopt;
return builder.create<UnrealizedConversionCastOp>(loc, resultType, inputs)
.getResult(0);
});
addTargetMaterialization([&](OpBuilder &builder, Type resultType,
ValueRange inputs,
Location loc) -> std::optional<Value> {
if (inputs.size() != 1)
return std::nullopt;
return builder.create<UnrealizedConversionCastOp>(loc, resultType, inputs)
.getResult(0);
});
// Integer memory spaces map to themselves.
addTypeAttributeConversion(
[](BaseMemRefType memref, IntegerAttr addrspace) { return addrspace; });
}
/// Returns the MLIR context.
MLIRContext &LLVMTypeConverter::getContext() {
return *getDialect()->getContext();
}
Type LLVMTypeConverter::getIndexType() {
return IntegerType::get(&getContext(), getIndexTypeBitwidth());
}
LLVM::LLVMPointerType
LLVMTypeConverter::getPointerType(Type elementType, unsigned int addressSpace) {
if (useOpaquePointers())
return LLVM::LLVMPointerType::get(&getContext(), addressSpace);
return LLVM::LLVMPointerType::get(elementType, addressSpace);
}
unsigned LLVMTypeConverter::getPointerBitwidth(unsigned addressSpace) {
return options.dataLayout.getPointerSizeInBits(addressSpace);
}
Type LLVMTypeConverter::convertIndexType(IndexType type) {
return getIndexType();
}
Type LLVMTypeConverter::convertIntegerType(IntegerType type) {
return IntegerType::get(&getContext(), type.getWidth());
}
Type LLVMTypeConverter::convertFloatType(FloatType type) { return type; }
// Convert a `ComplexType` to an LLVM type. The result is a complex number
// struct with entries for the
// 1. real part and for the
// 2. imaginary part.
Type LLVMTypeConverter::convertComplexType(ComplexType type) {
auto elementType = convertType(type.getElementType());
return LLVM::LLVMStructType::getLiteral(&getContext(),
{elementType, elementType});
}
// Except for signatures, MLIR function types are converted into LLVM
// pointer-to-function types.
Type LLVMTypeConverter::convertFunctionType(FunctionType type) {
SignatureConversion conversion(type.getNumInputs());
Type converted =
convertFunctionSignature(type, /*isVariadic=*/false, conversion);
if (!converted)
return {};
return getPointerType(converted);
}
// Function types are converted to LLVM Function types by recursively converting
// argument and result types. If MLIR Function has zero results, the LLVM
// Function has one VoidType result. If MLIR Function has more than one result,
// they are into an LLVM StructType in their order of appearance.
Type LLVMTypeConverter::convertFunctionSignature(
FunctionType funcTy, bool isVariadic,
LLVMTypeConverter::SignatureConversion &result) {
// Select the argument converter depending on the calling convention.
auto funcArgConverter = options.useBarePtrCallConv
? barePtrFuncArgTypeConverter
: structFuncArgTypeConverter;
// Convert argument types one by one and check for errors.
for (auto [idx, type] : llvm::enumerate(funcTy.getInputs())) {
SmallVector<Type, 8> converted;
if (failed(funcArgConverter(*this, type, converted)))
return {};
result.addInputs(idx, converted);
}
// If function does not return anything, create the void result type,
// if it returns on element, convert it, otherwise pack the result types into
// a struct.
Type resultType = funcTy.getNumResults() == 0
? LLVM::LLVMVoidType::get(&getContext())
: packFunctionResults(funcTy.getResults());
if (!resultType)
return {};
return LLVM::LLVMFunctionType::get(resultType, result.getConvertedTypes(),
isVariadic);
}
/// Converts the function type to a C-compatible format, in particular using
/// pointers to memref descriptors for arguments.
std::pair<LLVM::LLVMFunctionType, LLVM::LLVMStructType>
LLVMTypeConverter::convertFunctionTypeCWrapper(FunctionType type) {
SmallVector<Type, 4> inputs;
Type resultType = type.getNumResults() == 0
? LLVM::LLVMVoidType::get(&getContext())
: packFunctionResults(type.getResults());
if (!resultType)
return {};
auto structType = resultType.dyn_cast<LLVM::LLVMStructType>();
if (structType) {
// Struct types cannot be safely returned via C interface. Make this a
// pointer argument, instead.
inputs.push_back(getPointerType(structType));
resultType = LLVM::LLVMVoidType::get(&getContext());
}
for (Type t : type.getInputs()) {
auto converted = convertType(t);
if (!converted || !LLVM::isCompatibleType(converted))
return {};
if (t.isa<MemRefType, UnrankedMemRefType>())
converted = getPointerType(converted);
inputs.push_back(converted);
}
return {LLVM::LLVMFunctionType::get(resultType, inputs), structType};
}
/// Convert a memref type into a list of LLVM IR types that will form the
/// memref descriptor. The result contains the following types:
/// 1. The pointer to the allocated data buffer, followed by
/// 2. The pointer to the aligned data buffer, followed by
/// 3. A lowered `index`-type integer containing the distance between the
/// beginning of the buffer and the first element to be accessed through the
/// view, followed by
/// 4. An array containing as many `index`-type integers as the rank of the
/// MemRef: the array represents the size, in number of elements, of the memref
/// along the given dimension. For constant MemRef dimensions, the
/// corresponding size entry is a constant whose runtime value must match the
/// static value, followed by
/// 5. A second array containing as many `index`-type integers as the rank of
/// the MemRef: the second array represents the "stride" (in tensor abstraction
/// sense), i.e. the number of consecutive elements of the underlying buffer.
/// TODO: add assertions for the static cases.
///
/// If `unpackAggregates` is set to true, the arrays described in (4) and (5)
/// are expanded into individual index-type elements.
///
/// template <typename Elem, typename Index, size_t Rank>
/// struct {
/// Elem *allocatedPtr;
/// Elem *alignedPtr;
/// Index offset;
/// Index sizes[Rank]; // omitted when rank == 0
/// Index strides[Rank]; // omitted when rank == 0
/// };
SmallVector<Type, 5>
LLVMTypeConverter::getMemRefDescriptorFields(MemRefType type,
bool unpackAggregates) {
if (!isStrided(type)) {
emitError(
UnknownLoc::get(type.getContext()),
"conversion to strided form failed either due to non-strided layout "
"maps (which should have been normalized away) or other reasons");
return {};
}
Type elementType = convertType(type.getElementType());
if (!elementType)
return {};
FailureOr<unsigned> addressSpace = getMemRefAddressSpace(type);
if (failed(addressSpace)) {
emitError(UnknownLoc::get(type.getContext()),
"conversion of memref memory space ")
<< type.getMemorySpace()
<< " to integer address space "
"failed. Consider adding memory space conversions.";
return {};
}
auto ptrTy = getPointerType(elementType, *addressSpace);
auto indexTy = getIndexType();
SmallVector<Type, 5> results = {ptrTy, ptrTy, indexTy};
auto rank = type.getRank();
if (rank == 0)
return results;
if (unpackAggregates)
results.insert(results.end(), 2 * rank, indexTy);
else
results.insert(results.end(), 2, LLVM::LLVMArrayType::get(indexTy, rank));
return results;
}
unsigned LLVMTypeConverter::getMemRefDescriptorSize(MemRefType type,
const DataLayout &layout) {
// Compute the descriptor size given that of its components indicated above.
unsigned space = *getMemRefAddressSpace(type);
return 2 * llvm::divideCeil(getPointerBitwidth(space), 8) +
(1 + 2 * type.getRank()) * layout.getTypeSize(getIndexType());
}
/// Converts MemRefType to LLVMType. A MemRefType is converted to a struct that
/// packs the descriptor fields as defined by `getMemRefDescriptorFields`.
Type LLVMTypeConverter::convertMemRefType(MemRefType type) {
// When converting a MemRefType to a struct with descriptor fields, do not
// unpack the `sizes` and `strides` arrays.
SmallVector<Type, 5> types =
getMemRefDescriptorFields(type, /*unpackAggregates=*/false);
if (types.empty())
return {};
return LLVM::LLVMStructType::getLiteral(&getContext(), types);
}
/// Convert an unranked memref type into a list of non-aggregate LLVM IR types
/// that will form the unranked memref descriptor. In particular, the fields
/// for an unranked memref descriptor are:
/// 1. index-typed rank, the dynamic rank of this MemRef
/// 2. void* ptr, pointer to the static ranked MemRef descriptor. This will be
/// stack allocated (alloca) copy of a MemRef descriptor that got casted to
/// be unranked.
SmallVector<Type, 2> LLVMTypeConverter::getUnrankedMemRefDescriptorFields() {
return {getIndexType(), getPointerType(IntegerType::get(&getContext(), 8))};
}
unsigned
LLVMTypeConverter::getUnrankedMemRefDescriptorSize(UnrankedMemRefType type,
const DataLayout &layout) {
// Compute the descriptor size given that of its components indicated above.
unsigned space = *getMemRefAddressSpace(type);
return layout.getTypeSize(getIndexType()) +
llvm::divideCeil(getPointerBitwidth(space), 8);
}
Type LLVMTypeConverter::convertUnrankedMemRefType(UnrankedMemRefType type) {
if (!convertType(type.getElementType()))
return {};
return LLVM::LLVMStructType::getLiteral(&getContext(),
getUnrankedMemRefDescriptorFields());
}
FailureOr<unsigned>
LLVMTypeConverter::getMemRefAddressSpace(BaseMemRefType type) {
if (!type.getMemorySpace()) // Default memory space -> 0.
return 0;
std::optional<Attribute> converted =
convertTypeAttribute(type, type.getMemorySpace());
if (!converted)
return failure();
if (!(*converted)) // Conversion to default is 0.
return 0;
if (auto explicitSpace = converted->dyn_cast_or_null<IntegerAttr>())
return explicitSpace.getInt();
return failure();
}
// Check if a memref type can be converted to a bare pointer.
bool LLVMTypeConverter::canConvertToBarePtr(BaseMemRefType type) {
if (type.isa<UnrankedMemRefType>())
// Unranked memref is not supported in the bare pointer calling convention.
return false;
// Check that the memref has static shape, strides and offset. Otherwise, it
// cannot be lowered to a bare pointer.
auto memrefTy = type.cast<MemRefType>();
if (!memrefTy.hasStaticShape())
return false;
int64_t offset = 0;
SmallVector<int64_t, 4> strides;
if (failed(getStridesAndOffset(memrefTy, strides, offset)))
return false;
for (int64_t stride : strides)
if (ShapedType::isDynamic(stride))
return false;
return !ShapedType::isDynamic(offset);
}
/// Convert a memref type to a bare pointer to the memref element type.
Type LLVMTypeConverter::convertMemRefToBarePtr(BaseMemRefType type) {
if (!canConvertToBarePtr(type))
return {};
Type elementType = convertType(type.getElementType());
if (!elementType)
return {};
FailureOr<unsigned> addressSpace = getMemRefAddressSpace(type);
if (failed(addressSpace))
return {};
return getPointerType(elementType, *addressSpace);
}
/// Convert an n-D vector type to an LLVM vector type:
/// * 0-D `vector<T>` are converted to vector<1xT>
/// * 1-D `vector<axT>` remains as is while,
/// * n>1 `vector<ax...xkxT>` convert via an (n-1)-D array type to
/// `!llvm.array<ax...array<jxvector<kxT>>>`.
Type LLVMTypeConverter::convertVectorType(VectorType type) {
auto elementType = convertType(type.getElementType());
if (!elementType)
return {};
if (type.getShape().empty())
return VectorType::get({1}, elementType);
Type vectorType = VectorType::get(type.getShape().back(), elementType,
type.getNumScalableDims());
assert(LLVM::isCompatibleVectorType(vectorType) &&
"expected vector type compatible with the LLVM dialect");
auto shape = type.getShape();
for (int i = shape.size() - 2; i >= 0; --i)
vectorType = LLVM::LLVMArrayType::get(vectorType, shape[i]);
return vectorType;
}
/// Convert a type in the context of the default or bare pointer calling
/// convention. Calling convention sensitive types, such as MemRefType and
/// UnrankedMemRefType, are converted following the specific rules for the
/// calling convention. Calling convention independent types are converted
/// following the default LLVM type conversions.
Type LLVMTypeConverter::convertCallingConventionType(Type type) {
if (options.useBarePtrCallConv)
if (auto memrefTy = type.dyn_cast<BaseMemRefType>())
return convertMemRefToBarePtr(memrefTy);
return convertType(type);
}
/// Promote the bare pointers in 'values' that resulted from memrefs to
/// descriptors. 'stdTypes' holds they types of 'values' before the conversion
/// to the LLVM-IR dialect (i.e., MemRefType, or any other builtin type).
void LLVMTypeConverter::promoteBarePtrsToDescriptors(
ConversionPatternRewriter &rewriter, Location loc, ArrayRef<Type> stdTypes,
SmallVectorImpl<Value> &values) {
assert(stdTypes.size() == values.size() &&
"The number of types and values doesn't match");
for (unsigned i = 0, end = values.size(); i < end; ++i)
if (auto memrefTy = stdTypes[i].dyn_cast<MemRefType>())
values[i] = MemRefDescriptor::fromStaticShape(rewriter, loc, *this,
memrefTy, values[i]);
}
/// Convert a non-empty list of types to be returned from a function into a
/// supported LLVM IR type. In particular, if more than one value is returned,
/// create an LLVM IR structure type with elements that correspond to each of
/// the MLIR types converted with `convertType`.
Type LLVMTypeConverter::packFunctionResults(TypeRange types) {
assert(!types.empty() && "expected non-empty list of type");
if (types.size() == 1)
return convertCallingConventionType(types.front());
SmallVector<Type, 8> resultTypes;
resultTypes.reserve(types.size());
for (auto t : types) {
auto converted = convertCallingConventionType(t);
if (!converted || !LLVM::isCompatibleType(converted))
return {};
resultTypes.push_back(converted);
}
return LLVM::LLVMStructType::getLiteral(&getContext(), resultTypes);
}
Value LLVMTypeConverter::promoteOneMemRefDescriptor(Location loc, Value operand,
OpBuilder &builder) {
// Alloca with proper alignment. We do not expect optimizations of this
// alloca op and so we omit allocating at the entry block.
auto ptrType = getPointerType(operand.getType());
Value one = builder.create<LLVM::ConstantOp>(loc, builder.getI64Type(),
builder.getIndexAttr(1));
Value allocated =
builder.create<LLVM::AllocaOp>(loc, ptrType, operand.getType(), one);
// Store into the alloca'ed descriptor.
builder.create<LLVM::StoreOp>(loc, operand, allocated);
return allocated;
}
SmallVector<Value, 4> LLVMTypeConverter::promoteOperands(Location loc,
ValueRange opOperands,
ValueRange operands,
OpBuilder &builder) {
SmallVector<Value, 4> promotedOperands;
promotedOperands.reserve(operands.size());
for (auto it : llvm::zip(opOperands, operands)) {
auto operand = std::get<0>(it);
auto llvmOperand = std::get<1>(it);
if (options.useBarePtrCallConv) {
// For the bare-ptr calling convention, we only have to extract the
// aligned pointer of a memref.
if (auto memrefType = operand.getType().dyn_cast<MemRefType>()) {
MemRefDescriptor desc(llvmOperand);
llvmOperand = desc.alignedPtr(builder, loc);
} else if (operand.getType().isa<UnrankedMemRefType>()) {
llvm_unreachable("Unranked memrefs are not supported");
}
} else {
if (operand.getType().isa<UnrankedMemRefType>()) {
UnrankedMemRefDescriptor::unpack(builder, loc, llvmOperand,
promotedOperands);
continue;
}
if (auto memrefType = operand.getType().dyn_cast<MemRefType>()) {
MemRefDescriptor::unpack(builder, loc, llvmOperand, memrefType,
promotedOperands);
continue;
}
}
promotedOperands.push_back(llvmOperand);
}
return promotedOperands;
}
/// Callback to convert function argument types. It converts a MemRef function
/// argument to a list of non-aggregate types containing descriptor
/// information, and an UnrankedmemRef function argument to a list containing
/// the rank and a pointer to a descriptor struct.
LogicalResult mlir::structFuncArgTypeConverter(LLVMTypeConverter &converter,
Type type,
SmallVectorImpl<Type> &result) {
if (auto memref = type.dyn_cast<MemRefType>()) {
// In signatures, Memref descriptors are expanded into lists of
// non-aggregate values.
auto converted =
converter.getMemRefDescriptorFields(memref, /*unpackAggregates=*/true);
if (converted.empty())
return failure();
result.append(converted.begin(), converted.end());
return success();
}
if (type.isa<UnrankedMemRefType>()) {
auto converted = converter.getUnrankedMemRefDescriptorFields();
if (converted.empty())
return failure();
result.append(converted.begin(), converted.end());
return success();
}
auto converted = converter.convertType(type);
if (!converted)
return failure();
result.push_back(converted);
return success();
}
/// Callback to convert function argument types. It converts MemRef function
/// arguments to bare pointers to the MemRef element type.
LogicalResult mlir::barePtrFuncArgTypeConverter(LLVMTypeConverter &converter,
Type type,
SmallVectorImpl<Type> &result) {
auto llvmTy = converter.convertCallingConventionType(type);
if (!llvmTy)
return failure();
result.push_back(llvmTy);
return success();
}