doxygen/MemRefToLLVM_8cpp_source.html

 //===- MemRefToLLVM.cpp - MemRef to LLVM dialect 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

 //

 //===----------------------------------------------------------------------===//


 #include "mlir/Conversion/MemRefToLLVM/MemRefToLLVM.h"


 #include "mlir/Analysis/DataLayoutAnalysis.h"

 #include "mlir/Conversion/ConvertToLLVM/ToLLVMInterface.h"

 #include "mlir/Conversion/LLVMCommon/ConversionTarget.h"

 #include "mlir/Conversion/LLVMCommon/Pattern.h"

 #include "mlir/Conversion/LLVMCommon/TypeConverter.h"

 #include "mlir/Conversion/MemRefToLLVM/AllocLikeConversion.h"

 #include "mlir/Dialect/Arith/IR/Arith.h"

 #include "mlir/Dialect/Func/IR/FuncOps.h"

 #include "mlir/Dialect/LLVMIR/FunctionCallUtils.h"

 #include "mlir/Dialect/LLVMIR/LLVMDialect.h"

 #include "mlir/Dialect/LLVMIR/LLVMTypes.h"

 #include "mlir/Dialect/MemRef/IR/MemRef.h"

 #include "mlir/Dialect/MemRef/Utils/MemRefUtils.h"

 #include "mlir/IR/AffineMap.h"

 #include "mlir/IR/BuiltinTypes.h"

 #include "mlir/IR/IRMapping.h"

 #include "mlir/Pass/Pass.h"

 #include "llvm/ADT/SmallBitVector.h"

 #include "llvm/Support/MathExtras.h"

 #include <optional>


 namespace mlir {

 #define GEN_PASS_DEF_FINALIZEMEMREFTOLLVMCONVERSIONPASS

 #include "mlir/Conversion/Passes.h.inc"

 } // namespace mlir


 using namespace mlir;


 namespace {


 static bool isStaticStrideOrOffset(int64_t strideOrOffset) {

   return !ShapedType::isDynamic(strideOrOffset);

 }


 static FailureOr<LLVM::LLVMFuncOp>

 getFreeFn(const LLVMTypeConverter *typeConverter, ModuleOp module) {

   bool useGenericFn = typeConverter->getOptions().useGenericFunctions;


   if (useGenericFn)

     return LLVM::lookupOrCreateGenericFreeFn(module);


   return LLVM::lookupOrCreateFreeFn(module);

 }


 struct AllocOpLowering : public AllocLikeOpLLVMLowering {

   AllocOpLowering(const LLVMTypeConverter &converter)

       : AllocLikeOpLLVMLowering(memref::AllocOp::getOperationName(),

                                 converter) {}

   std::tuple<Value, Value> allocateBuffer(ConversionPatternRewriter &rewriter,

                                           Location loc, Value sizeBytes,

                                           Operation *op) const override {

     return allocateBufferManuallyAlign(

         rewriter, loc, sizeBytes, op,

         getAlignment(rewriter, loc, cast<memref::AllocOp>(op)));

   }

 };


 struct AlignedAllocOpLowering : public AllocLikeOpLLVMLowering {

   AlignedAllocOpLowering(const LLVMTypeConverter &converter)

       : AllocLikeOpLLVMLowering(memref::AllocOp::getOperationName(),

                                 converter) {}

   std::tuple<Value, Value> allocateBuffer(ConversionPatternRewriter &rewriter,

                                           Location loc, Value sizeBytes,

                                           Operation *op) const override {

     Value ptr = allocateBufferAutoAlign(

         rewriter, loc, sizeBytes, op, &defaultLayout,

         alignedAllocationGetAlignment(rewriter, loc, cast<memref::AllocOp>(op),

                                       &defaultLayout));

     if (!ptr)

       return std::make_tuple(Value(), Value());

     return std::make_tuple(ptr, ptr);

   }


 private:

   /// Default layout to use in absence of the corresponding analysis.

   DataLayout defaultLayout;

 };


 struct AllocaOpLowering : public AllocLikeOpLLVMLowering {

   AllocaOpLowering(const LLVMTypeConverter &converter)

       : AllocLikeOpLLVMLowering(memref::AllocaOp::getOperationName(),

                                 converter) {

     setRequiresNumElements();

   }


   /// Allocates the underlying buffer using the right call. `allocatedBytePtr`

   /// is set to null for stack allocations. `accessAlignment` is set if

   /// alignment is needed post allocation (for eg. in conjunction with malloc).

   std::tuple<Value, Value> allocateBuffer(ConversionPatternRewriter &rewriter,

                                           Location loc, Value size,

                                           Operation *op) const override {


     // With alloca, one gets a pointer to the element type right away.

     // For stack allocations.

     auto allocaOp = cast<memref::AllocaOp>(op);

     auto elementType =

         typeConverter->convertType(allocaOp.getType().getElementType());

     unsigned addrSpace =

         *getTypeConverter()->getMemRefAddressSpace(allocaOp.getType());

     auto elementPtrType =

         LLVM::LLVMPointerType::get(rewriter.getContext(), addrSpace);


     auto allocatedElementPtr =

         rewriter.create<LLVM::AllocaOp>(loc, elementPtrType, elementType, size,

                                         allocaOp.getAlignment().value_or(0));


     return std::make_tuple(allocatedElementPtr, allocatedElementPtr);

   }

 };


 struct AllocaScopeOpLowering

     : public ConvertOpToLLVMPattern<memref::AllocaScopeOp> {

   using ConvertOpToLLVMPattern<memref::AllocaScopeOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(memref::AllocaScopeOp allocaScopeOp, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     OpBuilder::InsertionGuard guard(rewriter);

     Location loc = allocaScopeOp.getLoc();


     // Split the current block before the AllocaScopeOp to create the inlining

     // point.

     auto *currentBlock = rewriter.getInsertionBlock();

     auto *remainingOpsBlock =

         rewriter.splitBlock(currentBlock, rewriter.getInsertionPoint());

     Block *continueBlock;

     if (allocaScopeOp.getNumResults() == 0) {

       continueBlock = remainingOpsBlock;

     } else {

       continueBlock = rewriter.createBlock(

           remainingOpsBlock, allocaScopeOp.getResultTypes(),

           SmallVector<Location>(allocaScopeOp->getNumResults(),

                                 allocaScopeOp.getLoc()));

       rewriter.create<LLVM::BrOp>(loc, ValueRange(), remainingOpsBlock);

     }


     // Inline body region.

     Block *beforeBody = &allocaScopeOp.getBodyRegion().front();

     Block *afterBody = &allocaScopeOp.getBodyRegion().back();

     rewriter.inlineRegionBefore(allocaScopeOp.getBodyRegion(), continueBlock);


     // Save stack and then branch into the body of the region.

     rewriter.setInsertionPointToEnd(currentBlock);

     auto stackSaveOp =

         rewriter.create<LLVM::StackSaveOp>(loc, getVoidPtrType());

     rewriter.create<LLVM::BrOp>(loc, ValueRange(), beforeBody);


     // Replace the alloca_scope return with a branch that jumps out of the body.

     // Stack restore before leaving the body region.

     rewriter.setInsertionPointToEnd(afterBody);

     auto returnOp =

         cast<memref::AllocaScopeReturnOp>(afterBody->getTerminator());

     auto branchOp = rewriter.replaceOpWithNewOp<LLVM::BrOp>(

         returnOp, returnOp.getResults(), continueBlock);


     // Insert stack restore before jumping out the body of the region.

     rewriter.setInsertionPoint(branchOp);

     rewriter.create<LLVM::StackRestoreOp>(loc, stackSaveOp);


     // Replace the op with values return from the body region.

     rewriter.replaceOp(allocaScopeOp, continueBlock->getArguments());


     return success();

   }

 };


 struct AssumeAlignmentOpLowering

     : public ConvertOpToLLVMPattern<memref::AssumeAlignmentOp> {

   using ConvertOpToLLVMPattern<

       memref::AssumeAlignmentOp>::ConvertOpToLLVMPattern;

   explicit AssumeAlignmentOpLowering(const LLVMTypeConverter &converter)

       : ConvertOpToLLVMPattern<memref::AssumeAlignmentOp>(converter) {}


   LogicalResult

   matchAndRewrite(memref::AssumeAlignmentOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     Value memref = adaptor.getMemref();

     unsigned alignment = op.getAlignment();

     auto loc = op.getLoc();


     auto srcMemRefType = cast<MemRefType>(op.getMemref().getType());

     Value ptr = getStridedElementPtr(loc, srcMemRefType, memref, /*indices=*/{},

                                      rewriter);


     // Emit llvm.assume(true) ["align"(memref, alignment)].

     // This is more direct than ptrtoint-based checks, is explicitly supported,

     // and works with non-integral address spaces.

     Value trueCond =

         rewriter.create<LLVM::ConstantOp>(loc, rewriter.getBoolAttr(true));

     Value alignmentConst =

         createIndexAttrConstant(rewriter, loc, getIndexType(), alignment);

     rewriter.create<LLVM::AssumeOp>(loc, trueCond, LLVM::AssumeAlignTag(), ptr,

                                     alignmentConst);


     rewriter.eraseOp(op);

     return success();

   }

 };


 // A `dealloc` is converted into a call to `free` on the underlying data buffer.

 // The memref descriptor being an SSA value, there is no need to clean it up

 // in any way.

 struct DeallocOpLowering : public ConvertOpToLLVMPattern<memref::DeallocOp> {

   using ConvertOpToLLVMPattern<memref::DeallocOp>::ConvertOpToLLVMPattern;


   explicit DeallocOpLowering(const LLVMTypeConverter &converter)

       : ConvertOpToLLVMPattern<memref::DeallocOp>(converter) {}


   LogicalResult

   matchAndRewrite(memref::DeallocOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     // Insert the `free` declaration if it is not already present.

     FailureOr<LLVM::LLVMFuncOp> freeFunc =

         getFreeFn(getTypeConverter(), op->getParentOfType<ModuleOp>());

     if (failed(freeFunc))

       return failure();

     Value allocatedPtr;

     if (auto unrankedTy =

             llvm::dyn_cast<UnrankedMemRefType>(op.getMemref().getType())) {

       auto elementPtrTy = LLVM::LLVMPointerType::get(

           rewriter.getContext(), unrankedTy.getMemorySpaceAsInt());

       allocatedPtr = UnrankedMemRefDescriptor::allocatedPtr(

           rewriter, op.getLoc(),

           UnrankedMemRefDescriptor(adaptor.getMemref())

               .memRefDescPtr(rewriter, op.getLoc()),

           elementPtrTy);

     } else {

       allocatedPtr = MemRefDescriptor(adaptor.getMemref())

                          .allocatedPtr(rewriter, op.getLoc());

     }

     rewriter.replaceOpWithNewOp<LLVM::CallOp>(op, freeFunc.value(),

                                               allocatedPtr);

     return success();

   }

 };


 // A `dim` is converted to a constant for static sizes and to an access to the

 // size stored in the memref descriptor for dynamic sizes.

 struct DimOpLowering : public ConvertOpToLLVMPattern<memref::DimOp> {

   using ConvertOpToLLVMPattern<memref::DimOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(memref::DimOp dimOp, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     Type operandType = dimOp.getSource().getType();

     if (isa<UnrankedMemRefType>(operandType)) {

       FailureOr<Value> extractedSize = extractSizeOfUnrankedMemRef(

           operandType, dimOp, adaptor.getOperands(), rewriter);

       if (failed(extractedSize))

         return failure();

       rewriter.replaceOp(dimOp, {*extractedSize});

       return success();

     }

     if (isa<MemRefType>(operandType)) {

       rewriter.replaceOp(

           dimOp, {extractSizeOfRankedMemRef(operandType, dimOp,

                                             adaptor.getOperands(), rewriter)});

       return success();

     }

     llvm_unreachable("expected MemRefType or UnrankedMemRefType");

   }


 private:

   FailureOr<Value>

   extractSizeOfUnrankedMemRef(Type operandType, memref::DimOp dimOp,

                               OpAdaptor adaptor,

                               ConversionPatternRewriter &rewriter) const {

     Location loc = dimOp.getLoc();


     auto unrankedMemRefType = cast<UnrankedMemRefType>(operandType);

     auto scalarMemRefType =

         MemRefType::get({}, unrankedMemRefType.getElementType());

     FailureOr<unsigned> maybeAddressSpace =

         getTypeConverter()->getMemRefAddressSpace(unrankedMemRefType);

     if (failed(maybeAddressSpace)) {

       dimOp.emitOpError("memref memory space must be convertible to an integer "

                         "address space");

       return failure();

     }

     unsigned addressSpace = *maybeAddressSpace;


     // Extract pointer to the underlying ranked descriptor and bitcast it to a

     // memref<element_type> descriptor pointer to minimize the number of GEP

     // operations.

     UnrankedMemRefDescriptor unrankedDesc(adaptor.getSource());

     Value underlyingRankedDesc = unrankedDesc.memRefDescPtr(rewriter, loc);


     Type elementType = typeConverter->convertType(scalarMemRefType);


     // Get pointer to offset field of memref<element_type> descriptor.

     auto indexPtrTy =

         LLVM::LLVMPointerType::get(rewriter.getContext(), addressSpace);

     Value offsetPtr = rewriter.create<LLVM::GEPOp>(

         loc, indexPtrTy, elementType, underlyingRankedDesc,

         ArrayRef<LLVM::GEPArg>{0, 2});


     // The size value that we have to extract can be obtained using GEPop with

     // `dimOp.index() + 1` index argument.

     Value idxPlusOne = rewriter.create<LLVM::AddOp>(

         loc, createIndexAttrConstant(rewriter, loc, getIndexType(), 1),

         adaptor.getIndex());

     Value sizePtr = rewriter.create<LLVM::GEPOp>(

         loc, indexPtrTy, getTypeConverter()->getIndexType(), offsetPtr,

         idxPlusOne);

     return rewriter

         .create<LLVM::LoadOp>(loc, getTypeConverter()->getIndexType(), sizePtr)

         .getResult();

   }


   std::optional<int64_t> getConstantDimIndex(memref::DimOp dimOp) const {

     if (auto idx = dimOp.getConstantIndex())

       return idx;


     if (auto constantOp = dimOp.getIndex().getDefiningOp<LLVM::ConstantOp>())

       return cast<IntegerAttr>(constantOp.getValue()).getValue().getSExtValue();


     return std::nullopt;

   }


   Value extractSizeOfRankedMemRef(Type operandType, memref::DimOp dimOp,

                                   OpAdaptor adaptor,

                                   ConversionPatternRewriter &rewriter) const {

     Location loc = dimOp.getLoc();


     // Take advantage if index is constant.

     MemRefType memRefType = cast<MemRefType>(operandType);

     Type indexType = getIndexType();

     if (std::optional<int64_t> index = getConstantDimIndex(dimOp)) {

       int64_t i = *index;

       if (i >= 0 && i < memRefType.getRank()) {

         if (memRefType.isDynamicDim(i)) {

           // extract dynamic size from the memref descriptor.

           MemRefDescriptor descriptor(adaptor.getSource());

           return descriptor.size(rewriter, loc, i);

         }

         // Use constant for static size.

         int64_t dimSize = memRefType.getDimSize(i);

         return createIndexAttrConstant(rewriter, loc, indexType, dimSize);

       }

     }

     Value index = adaptor.getIndex();

     int64_t rank = memRefType.getRank();

     MemRefDescriptor memrefDescriptor(adaptor.getSource());

     return memrefDescriptor.size(rewriter, loc, index, rank);

   }

 };


 /// Common base for load and store operations on MemRefs. Restricts the match

 /// to supported MemRef types. Provides functionality to emit code accessing a

 /// specific element of the underlying data buffer.

 template <typename Derived>

 struct LoadStoreOpLowering : public ConvertOpToLLVMPattern<Derived> {

   using ConvertOpToLLVMPattern<Derived>::ConvertOpToLLVMPattern;

   using ConvertOpToLLVMPattern<Derived>::isConvertibleAndHasIdentityMaps;

   using Base = LoadStoreOpLowering<Derived>;


   LogicalResult match(Derived op) const override {

     MemRefType type = op.getMemRefType();

     return isConvertibleAndHasIdentityMaps(type) ? success() : failure();

   }

 };


 /// Wrap a llvm.cmpxchg operation in a while loop so that the operation can be

 /// retried until it succeeds in atomically storing a new value into memory.

 ///

 ///      +---------------------------------+

 ///      |   <code before the AtomicRMWOp> |

 ///      |   <compute initial %loaded>     |

 ///      |   cf.br loop(%loaded)              |

 ///      +---------------------------------+

 ///             |

 ///  -------|   |

 ///  |      v   v

 ///  |   +--------------------------------+

 ///  |   | loop(%loaded):                 |

 ///  |   |   <body contents>              |

 ///  |   |   %pair = cmpxchg              |

 ///  |   |   %ok = %pair[0]               |

 ///  |   |   %new = %pair[1]              |

 ///  |   |   cf.cond_br %ok, end, loop(%new) |

 ///  |   +--------------------------------+

 ///  |          |        |

 ///  |-----------        |

 ///                      v

 ///      +--------------------------------+

 ///      | end:                           |

 ///      |   <code after the AtomicRMWOp> |

 ///      +--------------------------------+

 ///

 struct GenericAtomicRMWOpLowering

     : public LoadStoreOpLowering<memref::GenericAtomicRMWOp> {

   using Base::Base;


   LogicalResult

   matchAndRewrite(memref::GenericAtomicRMWOp atomicOp, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     auto loc = atomicOp.getLoc();

     Type valueType = typeConverter->convertType(atomicOp.getResult().getType());


     // Split the block into initial, loop, and ending parts.

     auto *initBlock = rewriter.getInsertionBlock();

     auto *loopBlock = rewriter.splitBlock(initBlock, Block::iterator(atomicOp));

     loopBlock->addArgument(valueType, loc);


     auto *endBlock =

         rewriter.splitBlock(loopBlock, Block::iterator(atomicOp)++);


     // Compute the loaded value and branch to the loop block.

     rewriter.setInsertionPointToEnd(initBlock);

     auto memRefType = cast<MemRefType>(atomicOp.getMemref().getType());

     auto dataPtr = getStridedElementPtr(loc, memRefType, adaptor.getMemref(),

                                         adaptor.getIndices(), rewriter);

     Value init = rewriter.create<LLVM::LoadOp>(

         loc, typeConverter->convertType(memRefType.getElementType()), dataPtr);

     rewriter.create<LLVM::BrOp>(loc, init, loopBlock);


     // Prepare the body of the loop block.

     rewriter.setInsertionPointToStart(loopBlock);


     // Clone the GenericAtomicRMWOp region and extract the result.

     auto loopArgument = loopBlock->getArgument(0);

     IRMapping mapping;

     mapping.map(atomicOp.getCurrentValue(), loopArgument);

     Block &entryBlock = atomicOp.body().front();

     for (auto &nestedOp : entryBlock.without_terminator()) {

       Operation *clone = rewriter.clone(nestedOp, mapping);

       mapping.map(nestedOp.getResults(), clone->getResults());

     }

     Value result = mapping.lookup(entryBlock.getTerminator()->getOperand(0));


     // Prepare the epilog of the loop block.

     // Append the cmpxchg op to the end of the loop block.

     auto successOrdering = LLVM::AtomicOrdering::acq_rel;

     auto failureOrdering = LLVM::AtomicOrdering::monotonic;

     auto cmpxchg = rewriter.create<LLVM::AtomicCmpXchgOp>(

         loc, dataPtr, loopArgument, result, successOrdering, failureOrdering);

     // Extract the %new_loaded and %ok values from the pair.

     Value newLoaded = rewriter.create<LLVM::ExtractValueOp>(loc, cmpxchg, 0);

     Value ok = rewriter.create<LLVM::ExtractValueOp>(loc, cmpxchg, 1);


     // Conditionally branch to the end or back to the loop depending on %ok.

     rewriter.create<LLVM::CondBrOp>(loc, ok, endBlock, ArrayRef<Value>(),

                                     loopBlock, newLoaded);


     rewriter.setInsertionPointToEnd(endBlock);


     // The 'result' of the atomic_rmw op is the newly loaded value.

     rewriter.replaceOp(atomicOp, {newLoaded});


     return success();

   }

 };


 /// Returns the LLVM type of the global variable given the memref type `type`.

 static Type

 convertGlobalMemrefTypeToLLVM(MemRefType type,

                               const LLVMTypeConverter &typeConverter) {

   // LLVM type for a global memref will be a multi-dimension array. For

   // declarations or uninitialized global memrefs, we can potentially flatten

   // this to a 1D array. However, for memref.global's with an initial value,

   // we do not intend to flatten the ElementsAttribute when going from std ->

   // LLVM dialect, so the LLVM type needs to me a multi-dimension array.

   Type elementType = typeConverter.convertType(type.getElementType());

   Type arrayTy = elementType;

   // Shape has the outermost dim at index 0, so need to walk it backwards

   for (int64_t dim : llvm::reverse(type.getShape()))

     arrayTy = LLVM::LLVMArrayType::get(arrayTy, dim);

   return arrayTy;

 }


 /// GlobalMemrefOp is lowered to a LLVM Global Variable.

 struct GlobalMemrefOpLowering

     : public ConvertOpToLLVMPattern<memref::GlobalOp> {

   using ConvertOpToLLVMPattern<memref::GlobalOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(memref::GlobalOp global, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     MemRefType type = global.getType();

     if (!isConvertibleAndHasIdentityMaps(type))

       return failure();


     Type arrayTy = convertGlobalMemrefTypeToLLVM(type, *getTypeConverter());


     LLVM::Linkage linkage =

         global.isPublic() ? LLVM::Linkage::External : LLVM::Linkage::Private;


     Attribute initialValue = nullptr;

     if (!global.isExternal() && !global.isUninitialized()) {

       auto elementsAttr = llvm::cast<ElementsAttr>(*global.getInitialValue());

       initialValue = elementsAttr;


       // For scalar memrefs, the global variable created is of the element type,

       // so unpack the elements attribute to extract the value.

       if (type.getRank() == 0)

         initialValue = elementsAttr.getSplatValue<Attribute>();

     }


     uint64_t alignment = global.getAlignment().value_or(0);

     FailureOr<unsigned> addressSpace =

         getTypeConverter()->getMemRefAddressSpace(type);

     if (failed(addressSpace))

       return global.emitOpError(

           "memory space cannot be converted to an integer address space");

     auto newGlobal = rewriter.replaceOpWithNewOp<LLVM::GlobalOp>(

         global, arrayTy, global.getConstant(), linkage, global.getSymName(),

         initialValue, alignment, *addressSpace);

     if (!global.isExternal() && global.isUninitialized()) {

       rewriter.createBlock(&newGlobal.getInitializerRegion());

       Value undef[] = {

           rewriter.create<LLVM::UndefOp>(global.getLoc(), arrayTy)};

       rewriter.create<LLVM::ReturnOp>(global.getLoc(), undef);

     }

     return success();

   }

 };


 /// GetGlobalMemrefOp is lowered into a Memref descriptor with the pointer to

 /// the first element stashed into the descriptor. This reuses

 /// `AllocLikeOpLowering` to reuse the Memref descriptor construction.

 struct GetGlobalMemrefOpLowering : public AllocLikeOpLLVMLowering {

   GetGlobalMemrefOpLowering(const LLVMTypeConverter &converter)

       : AllocLikeOpLLVMLowering(memref::GetGlobalOp::getOperationName(),

                                 converter) {}


   /// Buffer "allocation" for memref.get_global op is getting the address of

   /// the global variable referenced.

   std::tuple<Value, Value> allocateBuffer(ConversionPatternRewriter &rewriter,

                                           Location loc, Value sizeBytes,

                                           Operation *op) const override {

     auto getGlobalOp = cast<memref::GetGlobalOp>(op);

     MemRefType type = cast<MemRefType>(getGlobalOp.getResult().getType());


     // This is called after a type conversion, which would have failed if this

     // call fails.

     FailureOr<unsigned> maybeAddressSpace =

         getTypeConverter()->getMemRefAddressSpace(type);

     if (failed(maybeAddressSpace))

       return std::make_tuple(Value(), Value());

     unsigned memSpace = *maybeAddressSpace;


     Type arrayTy = convertGlobalMemrefTypeToLLVM(type, *getTypeConverter());

     auto ptrTy = LLVM::LLVMPointerType::get(rewriter.getContext(), memSpace);

     auto addressOf =

         rewriter.create<LLVM::AddressOfOp>(loc, ptrTy, getGlobalOp.getName());


     // Get the address of the first element in the array by creating a GEP with

     // the address of the GV as the base, and (rank + 1) number of 0 indices.

     auto gep = rewriter.create<LLVM::GEPOp>(

         loc, ptrTy, arrayTy, addressOf,

         SmallVector<LLVM::GEPArg>(type.getRank() + 1, 0));


     // We do not expect the memref obtained using `memref.get_global` to be

     // ever deallocated. Set the allocated pointer to be known bad value to

     // help debug if that ever happens.

     auto intPtrType = getIntPtrType(memSpace);

     Value deadBeefConst =

         createIndexAttrConstant(rewriter, op->getLoc(), intPtrType, 0xdeadbeef);

     auto deadBeefPtr =

         rewriter.create<LLVM::IntToPtrOp>(loc, ptrTy, deadBeefConst);


     // Both allocated and aligned pointers are same. We could potentially stash

     // a nullptr for the allocated pointer since we do not expect any dealloc.

     return std::make_tuple(deadBeefPtr, gep);

   }

 };


 // Load operation is lowered to obtaining a pointer to the indexed element

 // and loading it.

 struct LoadOpLowering : public LoadStoreOpLowering<memref::LoadOp> {

   using Base::Base;


   LogicalResult

   matchAndRewrite(memref::LoadOp loadOp, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     auto type = loadOp.getMemRefType();


     Value dataPtr =

         getStridedElementPtr(loadOp.getLoc(), type, adaptor.getMemref(),

                              adaptor.getIndices(), rewriter);

     rewriter.replaceOpWithNewOp<LLVM::LoadOp>(

         loadOp, typeConverter->convertType(type.getElementType()), dataPtr, 0,

         false, loadOp.getNontemporal());

     return success();

   }

 };


 // Store operation is lowered to obtaining a pointer to the indexed element,

 // and storing the given value to it.

 struct StoreOpLowering : public LoadStoreOpLowering<memref::StoreOp> {

   using Base::Base;


   LogicalResult

   matchAndRewrite(memref::StoreOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     auto type = op.getMemRefType();


     Value dataPtr = getStridedElementPtr(op.getLoc(), type, adaptor.getMemref(),

                                          adaptor.getIndices(), rewriter);

     rewriter.replaceOpWithNewOp<LLVM::StoreOp>(op, adaptor.getValue(), dataPtr,

                                                0, false, op.getNontemporal());

     return success();

   }

 };


 // The prefetch operation is lowered in a way similar to the load operation

 // except that the llvm.prefetch operation is used for replacement.

 struct PrefetchOpLowering : public LoadStoreOpLowering<memref::PrefetchOp> {

   using Base::Base;


   LogicalResult

   matchAndRewrite(memref::PrefetchOp prefetchOp, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     auto type = prefetchOp.getMemRefType();

     auto loc = prefetchOp.getLoc();


     Value dataPtr = getStridedElementPtr(loc, type, adaptor.getMemref(),

                                          adaptor.getIndices(), rewriter);


     // Replace with llvm.prefetch.

     IntegerAttr isWrite = rewriter.getI32IntegerAttr(prefetchOp.getIsWrite());

     IntegerAttr localityHint = prefetchOp.getLocalityHintAttr();

     IntegerAttr isData =

         rewriter.getI32IntegerAttr(prefetchOp.getIsDataCache());

     rewriter.replaceOpWithNewOp<LLVM::Prefetch>(prefetchOp, dataPtr, isWrite,

                                                 localityHint, isData);

     return success();

   }

 };


 struct RankOpLowering : public ConvertOpToLLVMPattern<memref::RankOp> {

   using ConvertOpToLLVMPattern<memref::RankOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(memref::RankOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     Location loc = op.getLoc();

     Type operandType = op.getMemref().getType();

     if (dyn_cast<UnrankedMemRefType>(operandType)) {

       UnrankedMemRefDescriptor desc(adaptor.getMemref());

       rewriter.replaceOp(op, {desc.rank(rewriter, loc)});

       return success();

     }

     if (auto rankedMemRefType = dyn_cast<MemRefType>(operandType)) {

       Type indexType = getIndexType();

       rewriter.replaceOp(op,

                          {createIndexAttrConstant(rewriter, loc, indexType,

                                                   rankedMemRefType.getRank())});

       return success();

     }

     return failure();

   }

 };


 struct MemRefCastOpLowering : public ConvertOpToLLVMPattern<memref::CastOp> {

   using ConvertOpToLLVMPattern<memref::CastOp>::ConvertOpToLLVMPattern;


   LogicalResult match(memref::CastOp memRefCastOp) const override {

     Type srcType = memRefCastOp.getOperand().getType();

     Type dstType = memRefCastOp.getType();


     // memref::CastOp reduce to bitcast in the ranked MemRef case and can be

     // used for type erasure. For now they must preserve underlying element type

     // and require source and result type to have the same rank. Therefore,

     // perform a sanity check that the underlying structs are the same. Once op

     // semantics are relaxed we can revisit.

     if (isa<MemRefType>(srcType) && isa<MemRefType>(dstType))

       return success(typeConverter->convertType(srcType) ==

                      typeConverter->convertType(dstType));


     // At least one of the operands is unranked type

     assert(isa<UnrankedMemRefType>(srcType) ||

            isa<UnrankedMemRefType>(dstType));


     // Unranked to unranked cast is disallowed

     return !(isa<UnrankedMemRefType>(srcType) &&

              isa<UnrankedMemRefType>(dstType))

                ? success()

                : failure();

   }


   void rewrite(memref::CastOp memRefCastOp, OpAdaptor adaptor,

                ConversionPatternRewriter &rewriter) const override {

     auto srcType = memRefCastOp.getOperand().getType();

     auto dstType = memRefCastOp.getType();

     auto targetStructType = typeConverter->convertType(memRefCastOp.getType());

     auto loc = memRefCastOp.getLoc();


     // For ranked/ranked case, just keep the original descriptor.

     if (isa<MemRefType>(srcType) && isa<MemRefType>(dstType))

       return rewriter.replaceOp(memRefCastOp, {adaptor.getSource()});


     if (isa<MemRefType>(srcType) && isa<UnrankedMemRefType>(dstType)) {

       // Casting ranked to unranked memref type

       // Set the rank in the destination from the memref type

       // Allocate space on the stack and copy the src memref descriptor

       // Set the ptr in the destination to the stack space

       auto srcMemRefType = cast<MemRefType>(srcType);

       int64_t rank = srcMemRefType.getRank();

       // ptr = AllocaOp sizeof(MemRefDescriptor)

       auto ptr = getTypeConverter()->promoteOneMemRefDescriptor(

           loc, adaptor.getSource(), rewriter);


       // rank = ConstantOp srcRank

       auto rankVal = rewriter.create<LLVM::ConstantOp>(

           loc, getIndexType(), rewriter.getIndexAttr(rank));

       // poison = PoisonOp

       UnrankedMemRefDescriptor memRefDesc =

           UnrankedMemRefDescriptor::poison(rewriter, loc, targetStructType);

       // d1 = InsertValueOp poison, rank, 0

       memRefDesc.setRank(rewriter, loc, rankVal);

       // d2 = InsertValueOp d1, ptr, 1

       memRefDesc.setMemRefDescPtr(rewriter, loc, ptr);

       rewriter.replaceOp(memRefCastOp, (Value)memRefDesc);


     } else if (isa<UnrankedMemRefType>(srcType) && isa<MemRefType>(dstType)) {

       // Casting from unranked type to ranked.

       // The operation is assumed to be doing a correct cast. If the destination

       // type mismatches the unranked the type, it is undefined behavior.

       UnrankedMemRefDescriptor memRefDesc(adaptor.getSource());

       // ptr = ExtractValueOp src, 1

       auto ptr = memRefDesc.memRefDescPtr(rewriter, loc);


       // struct = LoadOp ptr

       auto loadOp = rewriter.create<LLVM::LoadOp>(loc, targetStructType, ptr);

       rewriter.replaceOp(memRefCastOp, loadOp.getResult());

     } else {

       llvm_unreachable("Unsupported unranked memref to unranked memref cast");

     }

   }

 };


 /// Pattern to lower a `memref.copy` to llvm.

 ///

 /// For memrefs with identity layouts, the copy is lowered to the llvm

 /// `memcpy` intrinsic. For non-identity layouts, the copy is lowered to a call

 /// to the generic `MemrefCopyFn`.

 struct MemRefCopyOpLowering : public ConvertOpToLLVMPattern<memref::CopyOp> {

   using ConvertOpToLLVMPattern<memref::CopyOp>::ConvertOpToLLVMPattern;


   LogicalResult

   lowerToMemCopyIntrinsic(memref::CopyOp op, OpAdaptor adaptor,

                           ConversionPatternRewriter &rewriter) const {

     auto loc = op.getLoc();

     auto srcType = dyn_cast<MemRefType>(op.getSource().getType());


     MemRefDescriptor srcDesc(adaptor.getSource());


     // Compute number of elements.

     Value numElements = rewriter.create<LLVM::ConstantOp>(

         loc, getIndexType(), rewriter.getIndexAttr(1));

     for (int pos = 0; pos < srcType.getRank(); ++pos) {

       auto size = srcDesc.size(rewriter, loc, pos);

       numElements = rewriter.create<LLVM::MulOp>(loc, numElements, size);

     }


     // Get element size.

     auto sizeInBytes = getSizeInBytes(loc, srcType.getElementType(), rewriter);

     // Compute total.

     Value totalSize =

         rewriter.create<LLVM::MulOp>(loc, numElements, sizeInBytes);


     Type elementType = typeConverter->convertType(srcType.getElementType());


     Value srcBasePtr = srcDesc.alignedPtr(rewriter, loc);

     Value srcOffset = srcDesc.offset(rewriter, loc);

     Value srcPtr = rewriter.create<LLVM::GEPOp>(

         loc, srcBasePtr.getType(), elementType, srcBasePtr, srcOffset);

     MemRefDescriptor targetDesc(adaptor.getTarget());

     Value targetBasePtr = targetDesc.alignedPtr(rewriter, loc);

     Value targetOffset = targetDesc.offset(rewriter, loc);

     Value targetPtr = rewriter.create<LLVM::GEPOp>(

         loc, targetBasePtr.getType(), elementType, targetBasePtr, targetOffset);

     rewriter.create<LLVM::MemcpyOp>(loc, targetPtr, srcPtr, totalSize,

                                     /*isVolatile=*/false);

     rewriter.eraseOp(op);


     return success();

   }


   LogicalResult

   lowerToMemCopyFunctionCall(memref::CopyOp op, OpAdaptor adaptor,

                              ConversionPatternRewriter &rewriter) const {

     auto loc = op.getLoc();

     auto srcType = cast<BaseMemRefType>(op.getSource().getType());

     auto targetType = cast<BaseMemRefType>(op.getTarget().getType());


     // First make sure we have an unranked memref descriptor representation.

     auto makeUnranked = [&, this](Value ranked, MemRefType type) {

       auto rank = rewriter.create<LLVM::ConstantOp>(loc, getIndexType(),

                                                     type.getRank());

       auto *typeConverter = getTypeConverter();

       auto ptr =

           typeConverter->promoteOneMemRefDescriptor(loc, ranked, rewriter);


       auto unrankedType =

           UnrankedMemRefType::get(type.getElementType(), type.getMemorySpace());

       return UnrankedMemRefDescriptor::pack(

           rewriter, loc, *typeConverter, unrankedType, ValueRange{rank, ptr});

     };


     // Save stack position before promoting descriptors

     auto stackSaveOp =

         rewriter.create<LLVM::StackSaveOp>(loc, getVoidPtrType());


     auto srcMemRefType = dyn_cast<MemRefType>(srcType);

     Value unrankedSource =

         srcMemRefType ? makeUnranked(adaptor.getSource(), srcMemRefType)

                       : adaptor.getSource();

     auto targetMemRefType = dyn_cast<MemRefType>(targetType);

     Value unrankedTarget =

         targetMemRefType ? makeUnranked(adaptor.getTarget(), targetMemRefType)

                          : adaptor.getTarget();


     // Now promote the unranked descriptors to the stack.

     auto one = rewriter.create<LLVM::ConstantOp>(loc, getIndexType(),

                                                  rewriter.getIndexAttr(1));

     auto promote = [&](Value desc) {

       auto ptrType = LLVM::LLVMPointerType::get(rewriter.getContext());

       auto allocated =

           rewriter.create<LLVM::AllocaOp>(loc, ptrType, desc.getType(), one);

       rewriter.create<LLVM::StoreOp>(loc, desc, allocated);

       return allocated;

     };


     auto sourcePtr = promote(unrankedSource);

     auto targetPtr = promote(unrankedTarget);


     // Derive size from llvm.getelementptr which will account for any

     // potential alignment

     auto elemSize = getSizeInBytes(loc, srcType.getElementType(), rewriter);

     auto copyFn = LLVM::lookupOrCreateMemRefCopyFn(

         op->getParentOfType<ModuleOp>(), getIndexType(), sourcePtr.getType());

     if (failed(copyFn))

       return failure();

     rewriter.create<LLVM::CallOp>(loc, copyFn.value(),

                                   ValueRange{elemSize, sourcePtr, targetPtr});


     // Restore stack used for descriptors

     rewriter.create<LLVM::StackRestoreOp>(loc, stackSaveOp);


     rewriter.eraseOp(op);


     return success();

   }


   LogicalResult

   matchAndRewrite(memref::CopyOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     auto srcType = cast<BaseMemRefType>(op.getSource().getType());

     auto targetType = cast<BaseMemRefType>(op.getTarget().getType());


     auto isContiguousMemrefType = [&](BaseMemRefType type) {

       auto memrefType = dyn_cast<mlir::MemRefType>(type);

       // We can use memcpy for memrefs if they have an identity layout or are

       // contiguous with an arbitrary offset. Ignore empty memrefs, which is a

       // special case handled by memrefCopy.

       return memrefType &&

              (memrefType.getLayout().isIdentity() ||

               (memrefType.hasStaticShape() && memrefType.getNumElements() > 0 &&

                memref::isStaticShapeAndContiguousRowMajor(memrefType)));

     };


     if (isContiguousMemrefType(srcType) && isContiguousMemrefType(targetType))

       return lowerToMemCopyIntrinsic(op, adaptor, rewriter);


     return lowerToMemCopyFunctionCall(op, adaptor, rewriter);

   }

 };


 struct MemorySpaceCastOpLowering

     : public ConvertOpToLLVMPattern<memref::MemorySpaceCastOp> {

   using ConvertOpToLLVMPattern<

       memref::MemorySpaceCastOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(memref::MemorySpaceCastOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     Location loc = op.getLoc();


     Type resultType = op.getDest().getType();

     if (auto resultTypeR = dyn_cast<MemRefType>(resultType)) {

       auto resultDescType =

           cast<LLVM::LLVMStructType>(typeConverter->convertType(resultTypeR));

       Type newPtrType = resultDescType.getBody()[0];


       SmallVector<Value> descVals;

       MemRefDescriptor::unpack(rewriter, loc, adaptor.getSource(), resultTypeR,

                                descVals);

       descVals[0] =

           rewriter.create<LLVM::AddrSpaceCastOp>(loc, newPtrType, descVals[0]);

       descVals[1] =

           rewriter.create<LLVM::AddrSpaceCastOp>(loc, newPtrType, descVals[1]);

       Value result = MemRefDescriptor::pack(rewriter, loc, *getTypeConverter(),

                                             resultTypeR, descVals);

       rewriter.replaceOp(op, result);

       return success();

     }

     if (auto resultTypeU = dyn_cast<UnrankedMemRefType>(resultType)) {

       // Since the type converter won't be doing this for us, get the address

       // space.

       auto sourceType = cast<UnrankedMemRefType>(op.getSource().getType());

       FailureOr<unsigned> maybeSourceAddrSpace =

           getTypeConverter()->getMemRefAddressSpace(sourceType);

       if (failed(maybeSourceAddrSpace))

         return rewriter.notifyMatchFailure(loc,

                                            "non-integer source address space");

       unsigned sourceAddrSpace = *maybeSourceAddrSpace;

       FailureOr<unsigned> maybeResultAddrSpace =

           getTypeConverter()->getMemRefAddressSpace(resultTypeU);

       if (failed(maybeResultAddrSpace))

         return rewriter.notifyMatchFailure(loc,

                                            "non-integer result address space");

       unsigned resultAddrSpace = *maybeResultAddrSpace;


       UnrankedMemRefDescriptor sourceDesc(adaptor.getSource());

       Value rank = sourceDesc.rank(rewriter, loc);

       Value sourceUnderlyingDesc = sourceDesc.memRefDescPtr(rewriter, loc);


       // Create and allocate storage for new memref descriptor.

       auto result = UnrankedMemRefDescriptor::poison(

           rewriter, loc, typeConverter->convertType(resultTypeU));

       result.setRank(rewriter, loc, rank);

       SmallVector<Value, 1> sizes;

       UnrankedMemRefDescriptor::computeSizes(rewriter, loc, *getTypeConverter(),

                                              result, resultAddrSpace, sizes);

       Value resultUnderlyingSize = sizes.front();

       Value resultUnderlyingDesc = rewriter.create<LLVM::AllocaOp>(

           loc, getVoidPtrType(), rewriter.getI8Type(), resultUnderlyingSize);

       result.setMemRefDescPtr(rewriter, loc, resultUnderlyingDesc);


       // Copy pointers, performing address space casts.

       auto sourceElemPtrType =

           LLVM::LLVMPointerType::get(rewriter.getContext(), sourceAddrSpace);

       auto resultElemPtrType =

           LLVM::LLVMPointerType::get(rewriter.getContext(), resultAddrSpace);


       Value allocatedPtr = sourceDesc.allocatedPtr(

           rewriter, loc, sourceUnderlyingDesc, sourceElemPtrType);

       Value alignedPtr =

           sourceDesc.alignedPtr(rewriter, loc, *getTypeConverter(),

                                 sourceUnderlyingDesc, sourceElemPtrType);

       allocatedPtr = rewriter.create<LLVM::AddrSpaceCastOp>(

           loc, resultElemPtrType, allocatedPtr);

       alignedPtr = rewriter.create<LLVM::AddrSpaceCastOp>(

           loc, resultElemPtrType, alignedPtr);


       result.setAllocatedPtr(rewriter, loc, resultUnderlyingDesc,

                              resultElemPtrType, allocatedPtr);

       result.setAlignedPtr(rewriter, loc, *getTypeConverter(),

                            resultUnderlyingDesc, resultElemPtrType, alignedPtr);


       // Copy all the index-valued operands.

       Value sourceIndexVals =

           sourceDesc.offsetBasePtr(rewriter, loc, *getTypeConverter(),

                                    sourceUnderlyingDesc, sourceElemPtrType);

       Value resultIndexVals =

           result.offsetBasePtr(rewriter, loc, *getTypeConverter(),

                                resultUnderlyingDesc, resultElemPtrType);


       int64_t bytesToSkip =

           2 * llvm::divideCeil(

                   getTypeConverter()->getPointerBitwidth(resultAddrSpace), 8);

       Value bytesToSkipConst = rewriter.create<LLVM::ConstantOp>(

           loc, getIndexType(), rewriter.getIndexAttr(bytesToSkip));

       Value copySize = rewriter.create<LLVM::SubOp>(

           loc, getIndexType(), resultUnderlyingSize, bytesToSkipConst);

       rewriter.create<LLVM::MemcpyOp>(loc, resultIndexVals, sourceIndexVals,

                                       copySize, /*isVolatile=*/false);


       rewriter.replaceOp(op, ValueRange{result});

       return success();

     }

     return rewriter.notifyMatchFailure(loc, "unexpected memref type");

   }

 };


 /// Extracts allocated, aligned pointers and offset from a ranked or unranked

 /// memref type. In unranked case, the fields are extracted from the underlying

 /// ranked descriptor.

 static void extractPointersAndOffset(Location loc,

                                      ConversionPatternRewriter &rewriter,

                                      const LLVMTypeConverter &typeConverter,

                                      Value originalOperand,

                                      Value convertedOperand,

                                      Value *allocatedPtr, Value *alignedPtr,

                                      Value *offset = nullptr) {

   Type operandType = originalOperand.getType();

   if (isa<MemRefType>(operandType)) {

     MemRefDescriptor desc(convertedOperand);

     *allocatedPtr = desc.allocatedPtr(rewriter, loc);

     *alignedPtr = desc.alignedPtr(rewriter, loc);

     if (offset != nullptr)

       *offset = desc.offset(rewriter, loc);

     return;

   }


   // These will all cause assert()s on unconvertible types.

   unsigned memorySpace = *typeConverter.getMemRefAddressSpace(

       cast<UnrankedMemRefType>(operandType));

   auto elementPtrType =

       LLVM::LLVMPointerType::get(rewriter.getContext(), memorySpace);


   // Extract pointer to the underlying ranked memref descriptor and cast it to

   // ElemType**.

   UnrankedMemRefDescriptor unrankedDesc(convertedOperand);

   Value underlyingDescPtr = unrankedDesc.memRefDescPtr(rewriter, loc);


   *allocatedPtr = UnrankedMemRefDescriptor::allocatedPtr(

       rewriter, loc, underlyingDescPtr, elementPtrType);

   *alignedPtr = UnrankedMemRefDescriptor::alignedPtr(

       rewriter, loc, typeConverter, underlyingDescPtr, elementPtrType);

   if (offset != nullptr) {

     *offset = UnrankedMemRefDescriptor::offset(

         rewriter, loc, typeConverter, underlyingDescPtr, elementPtrType);

   }

 }


 struct MemRefReinterpretCastOpLowering

     : public ConvertOpToLLVMPattern<memref::ReinterpretCastOp> {

   using ConvertOpToLLVMPattern<

       memref::ReinterpretCastOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(memref::ReinterpretCastOp castOp, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     Type srcType = castOp.getSource().getType();


     Value descriptor;

     if (failed(convertSourceMemRefToDescriptor(rewriter, srcType, castOp,

                                                adaptor, &descriptor)))

       return failure();

     rewriter.replaceOp(castOp, {descriptor});

     return success();

   }


 private:

   LogicalResult convertSourceMemRefToDescriptor(

       ConversionPatternRewriter &rewriter, Type srcType,

       memref::ReinterpretCastOp castOp,

       memref::ReinterpretCastOp::Adaptor adaptor, Value *descriptor) const {

     MemRefType targetMemRefType =

         cast<MemRefType>(castOp.getResult().getType());

     auto llvmTargetDescriptorTy = dyn_cast_or_null<LLVM::LLVMStructType>(

         typeConverter->convertType(targetMemRefType));

     if (!llvmTargetDescriptorTy)

       return failure();


     // Create descriptor.

     Location loc = castOp.getLoc();

     auto desc = MemRefDescriptor::poison(rewriter, loc, llvmTargetDescriptorTy);


     // Set allocated and aligned pointers.

     Value allocatedPtr, alignedPtr;

     extractPointersAndOffset(loc, rewriter, *getTypeConverter(),

                              castOp.getSource(), adaptor.getSource(),

                              &allocatedPtr, &alignedPtr);

     desc.setAllocatedPtr(rewriter, loc, allocatedPtr);

     desc.setAlignedPtr(rewriter, loc, alignedPtr);


     // Set offset.

     if (castOp.isDynamicOffset(0))

       desc.setOffset(rewriter, loc, adaptor.getOffsets()[0]);

     else

       desc.setConstantOffset(rewriter, loc, castOp.getStaticOffset(0));


     // Set sizes and strides.

     unsigned dynSizeId = 0;

     unsigned dynStrideId = 0;

     for (unsigned i = 0, e = targetMemRefType.getRank(); i < e; ++i) {

       if (castOp.isDynamicSize(i))

         desc.setSize(rewriter, loc, i, adaptor.getSizes()[dynSizeId++]);

       else

         desc.setConstantSize(rewriter, loc, i, castOp.getStaticSize(i));


       if (castOp.isDynamicStride(i))

         desc.setStride(rewriter, loc, i, adaptor.getStrides()[dynStrideId++]);

       else

         desc.setConstantStride(rewriter, loc, i, castOp.getStaticStride(i));

     }

     *descriptor = desc;

     return success();

   }

 };


 struct MemRefReshapeOpLowering

     : public ConvertOpToLLVMPattern<memref::ReshapeOp> {

   using ConvertOpToLLVMPattern<memref::ReshapeOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(memref::ReshapeOp reshapeOp, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     Type srcType = reshapeOp.getSource().getType();


     Value descriptor;

     if (failed(convertSourceMemRefToDescriptor(rewriter, srcType, reshapeOp,

                                                adaptor, &descriptor)))

       return failure();

     rewriter.replaceOp(reshapeOp, {descriptor});

     return success();

   }


 private:

   LogicalResult

   convertSourceMemRefToDescriptor(ConversionPatternRewriter &rewriter,

                                   Type srcType, memref::ReshapeOp reshapeOp,

                                   memref::ReshapeOp::Adaptor adaptor,

                                   Value *descriptor) const {

     auto shapeMemRefType = cast<MemRefType>(reshapeOp.getShape().getType());

     if (shapeMemRefType.hasStaticShape()) {

       MemRefType targetMemRefType =

           cast<MemRefType>(reshapeOp.getResult().getType());

       auto llvmTargetDescriptorTy = dyn_cast_or_null<LLVM::LLVMStructType>(

           typeConverter->convertType(targetMemRefType));

       if (!llvmTargetDescriptorTy)

         return failure();


       // Create descriptor.

       Location loc = reshapeOp.getLoc();

       auto desc =

           MemRefDescriptor::poison(rewriter, loc, llvmTargetDescriptorTy);


       // Set allocated and aligned pointers.

       Value allocatedPtr, alignedPtr;

       extractPointersAndOffset(loc, rewriter, *getTypeConverter(),

                                reshapeOp.getSource(), adaptor.getSource(),

                                &allocatedPtr, &alignedPtr);

       desc.setAllocatedPtr(rewriter, loc, allocatedPtr);

       desc.setAlignedPtr(rewriter, loc, alignedPtr);


       // Extract the offset and strides from the type.

       int64_t offset;

       SmallVector<int64_t> strides;

       if (failed(targetMemRefType.getStridesAndOffset(strides, offset)))

         return rewriter.notifyMatchFailure(

             reshapeOp, "failed to get stride and offset exprs");


       if (!isStaticStrideOrOffset(offset))

         return rewriter.notifyMatchFailure(reshapeOp,

                                            "dynamic offset is unsupported");


       desc.setConstantOffset(rewriter, loc, offset);


       assert(targetMemRefType.getLayout().isIdentity() &&

              "Identity layout map is a precondition of a valid reshape op");


       Type indexType = getIndexType();

       Value stride = nullptr;

       int64_t targetRank = targetMemRefType.getRank();

       for (auto i : llvm::reverse(llvm::seq<int64_t>(0, targetRank))) {

         if (!ShapedType::isDynamic(strides[i])) {

           // If the stride for this dimension is dynamic, then use the product

           // of the sizes of the inner dimensions.

           stride =

               createIndexAttrConstant(rewriter, loc, indexType, strides[i]);

         } else if (!stride) {

           // `stride` is null only in the first iteration of the loop.  However,

           // since the target memref has an identity layout, we can safely set

           // the innermost stride to 1.

           stride = createIndexAttrConstant(rewriter, loc, indexType, 1);

         }


         Value dimSize;

         // If the size of this dimension is dynamic, then load it at runtime

         // from the shape operand.

         if (!targetMemRefType.isDynamicDim(i)) {

           dimSize = createIndexAttrConstant(rewriter, loc, indexType,

                                             targetMemRefType.getDimSize(i));

         } else {

           Value shapeOp = reshapeOp.getShape();

           Value index = createIndexAttrConstant(rewriter, loc, indexType, i);

           dimSize = rewriter.create<memref::LoadOp>(loc, shapeOp, index);

           Type indexType = getIndexType();

           if (dimSize.getType() != indexType)

             dimSize = typeConverter->materializeTargetConversion(

                 rewriter, loc, indexType, dimSize);

           assert(dimSize && "Invalid memref element type");

         }


         desc.setSize(rewriter, loc, i, dimSize);

         desc.setStride(rewriter, loc, i, stride);


         // Prepare the stride value for the next dimension.

         stride = rewriter.create<LLVM::MulOp>(loc, stride, dimSize);

       }


       *descriptor = desc;

       return success();

     }


     // The shape is a rank-1 tensor with unknown length.

     Location loc = reshapeOp.getLoc();

     MemRefDescriptor shapeDesc(adaptor.getShape());

     Value resultRank = shapeDesc.size(rewriter, loc, 0);


     // Extract address space and element type.

     auto targetType = cast<UnrankedMemRefType>(reshapeOp.getResult().getType());

     unsigned addressSpace =

         *getTypeConverter()->getMemRefAddressSpace(targetType);


     // Create the unranked memref descriptor that holds the ranked one. The

     // inner descriptor is allocated on stack.

     auto targetDesc = UnrankedMemRefDescriptor::poison(

         rewriter, loc, typeConverter->convertType(targetType));

     targetDesc.setRank(rewriter, loc, resultRank);

     SmallVector<Value, 4> sizes;

     UnrankedMemRefDescriptor::computeSizes(rewriter, loc, *getTypeConverter(),

                                            targetDesc, addressSpace, sizes);

     Value underlyingDescPtr = rewriter.create<LLVM::AllocaOp>(

         loc, getVoidPtrType(), IntegerType::get(getContext(), 8),

         sizes.front());

     targetDesc.setMemRefDescPtr(rewriter, loc, underlyingDescPtr);


     // Extract pointers and offset from the source memref.

     Value allocatedPtr, alignedPtr, offset;

     extractPointersAndOffset(loc, rewriter, *getTypeConverter(),

                              reshapeOp.getSource(), adaptor.getSource(),

                              &allocatedPtr, &alignedPtr, &offset);


     // Set pointers and offset.

     auto elementPtrType =

         LLVM::LLVMPointerType::get(rewriter.getContext(), addressSpace);


     UnrankedMemRefDescriptor::setAllocatedPtr(rewriter, loc, underlyingDescPtr,

                                               elementPtrType, allocatedPtr);

     UnrankedMemRefDescriptor::setAlignedPtr(rewriter, loc, *getTypeConverter(),

                                             underlyingDescPtr, elementPtrType,

                                             alignedPtr);

     UnrankedMemRefDescriptor::setOffset(rewriter, loc, *getTypeConverter(),

                                         underlyingDescPtr, elementPtrType,

                                         offset);


     // Use the offset pointer as base for further addressing. Copy over the new

     // shape and compute strides. For this, we create a loop from rank-1 to 0.

     Value targetSizesBase = UnrankedMemRefDescriptor::sizeBasePtr(

         rewriter, loc, *getTypeConverter(), underlyingDescPtr, elementPtrType);

     Value targetStridesBase = UnrankedMemRefDescriptor::strideBasePtr(

         rewriter, loc, *getTypeConverter(), targetSizesBase, resultRank);

     Value shapeOperandPtr = shapeDesc.alignedPtr(rewriter, loc);

     Value oneIndex = createIndexAttrConstant(rewriter, loc, getIndexType(), 1);

     Value resultRankMinusOne =

         rewriter.create<LLVM::SubOp>(loc, resultRank, oneIndex);


     Block *initBlock = rewriter.getInsertionBlock();

     Type indexType = getTypeConverter()->getIndexType();

     Block::iterator remainingOpsIt = std::next(rewriter.getInsertionPoint());


     Block *condBlock = rewriter.createBlock(initBlock->getParent(), {},

                                             {indexType, indexType}, {loc, loc});


     // Move the remaining initBlock ops to condBlock.

     Block *remainingBlock = rewriter.splitBlock(initBlock, remainingOpsIt);

     rewriter.mergeBlocks(remainingBlock, condBlock, ValueRange());


     rewriter.setInsertionPointToEnd(initBlock);

     rewriter.create<LLVM::BrOp>(loc, ValueRange({resultRankMinusOne, oneIndex}),

                                 condBlock);

     rewriter.setInsertionPointToStart(condBlock);

     Value indexArg = condBlock->getArgument(0);

     Value strideArg = condBlock->getArgument(1);


     Value zeroIndex = createIndexAttrConstant(rewriter, loc, indexType, 0);

     Value pred = rewriter.create<LLVM::ICmpOp>(

         loc, IntegerType::get(rewriter.getContext(), 1),

         LLVM::ICmpPredicate::sge, indexArg, zeroIndex);


     Block *bodyBlock =

         rewriter.splitBlock(condBlock, rewriter.getInsertionPoint());

     rewriter.setInsertionPointToStart(bodyBlock);


     // Copy size from shape to descriptor.

     auto llvmIndexPtrType = LLVM::LLVMPointerType::get(rewriter.getContext());

     Value sizeLoadGep = rewriter.create<LLVM::GEPOp>(

         loc, llvmIndexPtrType,

         typeConverter->convertType(shapeMemRefType.getElementType()),

         shapeOperandPtr, indexArg);

     Value size = rewriter.create<LLVM::LoadOp>(loc, indexType, sizeLoadGep);

     UnrankedMemRefDescriptor::setSize(rewriter, loc, *getTypeConverter(),

                                       targetSizesBase, indexArg, size);


     // Write stride value and compute next one.

     UnrankedMemRefDescriptor::setStride(rewriter, loc, *getTypeConverter(),

                                         targetStridesBase, indexArg, strideArg);

     Value nextStride = rewriter.create<LLVM::MulOp>(loc, strideArg, size);


     // Decrement loop counter and branch back.

     Value decrement = rewriter.create<LLVM::SubOp>(loc, indexArg, oneIndex);

     rewriter.create<LLVM::BrOp>(loc, ValueRange({decrement, nextStride}),

                                 condBlock);


     Block *remainder =

         rewriter.splitBlock(bodyBlock, rewriter.getInsertionPoint());


     // Hook up the cond exit to the remainder.

     rewriter.setInsertionPointToEnd(condBlock);

     rewriter.create<LLVM::CondBrOp>(loc, pred, bodyBlock, std::nullopt,

                                     remainder, std::nullopt);


     // Reset position to beginning of new remainder block.

     rewriter.setInsertionPointToStart(remainder);


     *descriptor = targetDesc;

     return success();

   }

 };


 /// RessociatingReshapeOp must be expanded before we reach this stage.

 /// Report that information.

 template <typename ReshapeOp>

 class ReassociatingReshapeOpConversion

     : public ConvertOpToLLVMPattern<ReshapeOp> {

 public:

   using ConvertOpToLLVMPattern<ReshapeOp>::ConvertOpToLLVMPattern;

   using ReshapeOpAdaptor = typename ReshapeOp::Adaptor;


   LogicalResult

   matchAndRewrite(ReshapeOp reshapeOp, typename ReshapeOp::Adaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     return rewriter.notifyMatchFailure(

         reshapeOp,

         "reassociation operations should have been expanded beforehand");

   }

 };


 /// Subviews must be expanded before we reach this stage.

 /// Report that information.

 struct SubViewOpLowering : public ConvertOpToLLVMPattern<memref::SubViewOp> {

   using ConvertOpToLLVMPattern<memref::SubViewOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(memref::SubViewOp subViewOp, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     return rewriter.notifyMatchFailure(

         subViewOp, "subview operations should have been expanded beforehand");

   }

 };


 /// Conversion pattern that transforms a transpose op into:

 ///   1. A function entry `alloca` operation to allocate a ViewDescriptor.

 ///   2. A load of the ViewDescriptor from the pointer allocated in 1.

 ///   3. Updates to the ViewDescriptor to introduce the data ptr, offset, size

 ///      and stride. Size and stride are permutations of the original values.

 ///   4. A store of the resulting ViewDescriptor to the alloca'ed pointer.

 /// The transpose op is replaced by the alloca'ed pointer.

 class TransposeOpLowering : public ConvertOpToLLVMPattern<memref::TransposeOp> {

 public:

   using ConvertOpToLLVMPattern<memref::TransposeOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(memref::TransposeOp transposeOp, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     auto loc = transposeOp.getLoc();

     MemRefDescriptor viewMemRef(adaptor.getIn());


     // No permutation, early exit.

     if (transposeOp.getPermutation().isIdentity())

       return rewriter.replaceOp(transposeOp, {viewMemRef}), success();


     auto targetMemRef = MemRefDescriptor::poison(

         rewriter, loc,

         typeConverter->convertType(transposeOp.getIn().getType()));


     // Copy the base and aligned pointers from the old descriptor to the new

     // one.

     targetMemRef.setAllocatedPtr(rewriter, loc,

                                  viewMemRef.allocatedPtr(rewriter, loc));

     targetMemRef.setAlignedPtr(rewriter, loc,

                                viewMemRef.alignedPtr(rewriter, loc));


     // Copy the offset pointer from the old descriptor to the new one.

     targetMemRef.setOffset(rewriter, loc, viewMemRef.offset(rewriter, loc));


     // Iterate over the dimensions and apply size/stride permutation:

     // When enumerating the results of the permutation map, the enumeration

     // index is the index into the target dimensions and the DimExpr points to

     // the dimension of the source memref.

     for (const auto &en :

          llvm::enumerate(transposeOp.getPermutation().getResults())) {

       int targetPos = en.index();

       int sourcePos = cast<AffineDimExpr>(en.value()).getPosition();

       targetMemRef.setSize(rewriter, loc, targetPos,

                            viewMemRef.size(rewriter, loc, sourcePos));

       targetMemRef.setStride(rewriter, loc, targetPos,

                              viewMemRef.stride(rewriter, loc, sourcePos));

     }


     rewriter.replaceOp(transposeOp, {targetMemRef});

     return success();

   }

 };


 /// Conversion pattern that transforms an op into:

 ///   1. An `llvm.mlir.undef` operation to create a memref descriptor

 ///   2. Updates to the descriptor to introduce the data ptr, offset, size

 ///      and stride.

 /// The view op is replaced by the descriptor.

 struct ViewOpLowering : public ConvertOpToLLVMPattern<memref::ViewOp> {

   using ConvertOpToLLVMPattern<memref::ViewOp>::ConvertOpToLLVMPattern;


   // Build and return the value for the idx^th shape dimension, either by

   // returning the constant shape dimension or counting the proper dynamic size.

   Value getSize(ConversionPatternRewriter &rewriter, Location loc,

                 ArrayRef<int64_t> shape, ValueRange dynamicSizes, unsigned idx,

                 Type indexType) const {

     assert(idx < shape.size());

     if (!ShapedType::isDynamic(shape[idx]))

       return createIndexAttrConstant(rewriter, loc, indexType, shape[idx]);

     // Count the number of dynamic dims in range [0, idx]

     unsigned nDynamic =

         llvm::count_if(shape.take_front(idx), ShapedType::isDynamic);

     return dynamicSizes[nDynamic];

   }


   // Build and return the idx^th stride, either by returning the constant stride

   // or by computing the dynamic stride from the current `runningStride` and

   // `nextSize`. The caller should keep a running stride and update it with the

   // result returned by this function.

   Value getStride(ConversionPatternRewriter &rewriter, Location loc,

                   ArrayRef<int64_t> strides, Value nextSize,

                   Value runningStride, unsigned idx, Type indexType) const {

     assert(idx < strides.size());

     if (!ShapedType::isDynamic(strides[idx]))

       return createIndexAttrConstant(rewriter, loc, indexType, strides[idx]);

     if (nextSize)

       return runningStride

                  ? rewriter.create<LLVM::MulOp>(loc, runningStride, nextSize)

                  : nextSize;

     assert(!runningStride);

     return createIndexAttrConstant(rewriter, loc, indexType, 1);

   }


   LogicalResult

   matchAndRewrite(memref::ViewOp viewOp, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     auto loc = viewOp.getLoc();


     auto viewMemRefType = viewOp.getType();

     auto targetElementTy =

         typeConverter->convertType(viewMemRefType.getElementType());

     auto targetDescTy = typeConverter->convertType(viewMemRefType);

     if (!targetDescTy || !targetElementTy ||

         !LLVM::isCompatibleType(targetElementTy) ||

         !LLVM::isCompatibleType(targetDescTy))

       return viewOp.emitWarning("Target descriptor type not converted to LLVM"),

              failure();


     int64_t offset;

     SmallVector<int64_t, 4> strides;

     auto successStrides = viewMemRefType.getStridesAndOffset(strides, offset);

     if (failed(successStrides))

       return viewOp.emitWarning("cannot cast to non-strided shape"), failure();

     assert(offset == 0 && "expected offset to be 0");


     // Target memref must be contiguous in memory (innermost stride is 1), or

     // empty (special case when at least one of the memref dimensions is 0).

     if (!strides.empty() && (strides.back() != 1 && strides.back() != 0))

       return viewOp.emitWarning("cannot cast to non-contiguous shape"),

              failure();


     // Create the descriptor.

     MemRefDescriptor sourceMemRef(adaptor.getSource());

     auto targetMemRef = MemRefDescriptor::poison(rewriter, loc, targetDescTy);


     // Field 1: Copy the allocated pointer, used for malloc/free.

     Value allocatedPtr = sourceMemRef.allocatedPtr(rewriter, loc);

     auto srcMemRefType = cast<MemRefType>(viewOp.getSource().getType());

     targetMemRef.setAllocatedPtr(rewriter, loc, allocatedPtr);


     // Field 2: Copy the actual aligned pointer to payload.

     Value alignedPtr = sourceMemRef.alignedPtr(rewriter, loc);

     alignedPtr = rewriter.create<LLVM::GEPOp>(

         loc, alignedPtr.getType(),

         typeConverter->convertType(srcMemRefType.getElementType()), alignedPtr,

         adaptor.getByteShift());


     targetMemRef.setAlignedPtr(rewriter, loc, alignedPtr);


     Type indexType = getIndexType();

     // Field 3: The offset in the resulting type must be 0. This is

     // because of the type change: an offset on srcType* may not be

     // expressible as an offset on dstType*.

     targetMemRef.setOffset(

         rewriter, loc,

         createIndexAttrConstant(rewriter, loc, indexType, offset));


     // Early exit for 0-D corner case.

     if (viewMemRefType.getRank() == 0)

       return rewriter.replaceOp(viewOp, {targetMemRef}), success();


     // Fields 4 and 5: Update sizes and strides.

     Value stride = nullptr, nextSize = nullptr;

     for (int i = viewMemRefType.getRank() - 1; i >= 0; --i) {

       // Update size.

       Value size = getSize(rewriter, loc, viewMemRefType.getShape(),

                            adaptor.getSizes(), i, indexType);

       targetMemRef.setSize(rewriter, loc, i, size);

       // Update stride.

       stride =

           getStride(rewriter, loc, strides, nextSize, stride, i, indexType);

       targetMemRef.setStride(rewriter, loc, i, stride);

       nextSize = size;

     }


     rewriter.replaceOp(viewOp, {targetMemRef});

     return success();

   }

 };


 //===----------------------------------------------------------------------===//

 // AtomicRMWOpLowering

 //===----------------------------------------------------------------------===//


 /// Try to match the kind of a memref.atomic_rmw to determine whether to use a

 /// lowering to llvm.atomicrmw or fallback to llvm.cmpxchg.

 static std::optional<LLVM::AtomicBinOp>

 matchSimpleAtomicOp(memref::AtomicRMWOp atomicOp) {

   switch (atomicOp.getKind()) {

   case arith::AtomicRMWKind::addf:

     return LLVM::AtomicBinOp::fadd;

   case arith::AtomicRMWKind::addi:

     return LLVM::AtomicBinOp::add;

   case arith::AtomicRMWKind::assign:

     return LLVM::AtomicBinOp::xchg;

   case arith::AtomicRMWKind::maximumf:

     return LLVM::AtomicBinOp::fmax;

   case arith::AtomicRMWKind::maxs:

     return LLVM::AtomicBinOp::max;

   case arith::AtomicRMWKind::maxu:

     return LLVM::AtomicBinOp::umax;

   case arith::AtomicRMWKind::minimumf:

     return LLVM::AtomicBinOp::fmin;

   case arith::AtomicRMWKind::mins:

     return LLVM::AtomicBinOp::min;

   case arith::AtomicRMWKind::minu:

     return LLVM::AtomicBinOp::umin;

   case arith::AtomicRMWKind::ori:

     return LLVM::AtomicBinOp::_or;

   case arith::AtomicRMWKind::andi:

     return LLVM::AtomicBinOp::_and;

   default:

     return std::nullopt;

   }

   llvm_unreachable("Invalid AtomicRMWKind");

 }


 struct AtomicRMWOpLowering : public LoadStoreOpLowering<memref::AtomicRMWOp> {

   using Base::Base;


   LogicalResult

   matchAndRewrite(memref::AtomicRMWOp atomicOp, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     auto maybeKind = matchSimpleAtomicOp(atomicOp);

     if (!maybeKind)

       return failure();

     auto memRefType = atomicOp.getMemRefType();

     SmallVector<int64_t> strides;

     int64_t offset;

     if (failed(memRefType.getStridesAndOffset(strides, offset)))

       return failure();

     auto dataPtr =

         getStridedElementPtr(atomicOp.getLoc(), memRefType, adaptor.getMemref(),

                              adaptor.getIndices(), rewriter);

     rewriter.replaceOpWithNewOp<LLVM::AtomicRMWOp>(

         atomicOp, *maybeKind, dataPtr, adaptor.getValue(),

         LLVM::AtomicOrdering::acq_rel);

     return success();

   }

 };


 /// Unpack the pointer returned by a memref.extract_aligned_pointer_as_index.

 class ConvertExtractAlignedPointerAsIndex

     : public ConvertOpToLLVMPattern<memref::ExtractAlignedPointerAsIndexOp> {

 public:

   using ConvertOpToLLVMPattern<

       memref::ExtractAlignedPointerAsIndexOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(memref::ExtractAlignedPointerAsIndexOp extractOp,

                   OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     BaseMemRefType sourceTy = extractOp.getSource().getType();


     Value alignedPtr;

     if (sourceTy.hasRank()) {

       MemRefDescriptor desc(adaptor.getSource());

       alignedPtr = desc.alignedPtr(rewriter, extractOp->getLoc());

     } else {

       auto elementPtrTy = LLVM::LLVMPointerType::get(

           rewriter.getContext(), sourceTy.getMemorySpaceAsInt());


       UnrankedMemRefDescriptor desc(adaptor.getSource());

       Value descPtr = desc.memRefDescPtr(rewriter, extractOp->getLoc());


       alignedPtr = UnrankedMemRefDescriptor::alignedPtr(

           rewriter, extractOp->getLoc(), *getTypeConverter(), descPtr,

           elementPtrTy);

     }


     rewriter.replaceOpWithNewOp<LLVM::PtrToIntOp>(

         extractOp, getTypeConverter()->getIndexType(), alignedPtr);

     return success();

   }

 };


 /// Materialize the MemRef descriptor represented by the results of

 /// ExtractStridedMetadataOp.

 class ExtractStridedMetadataOpLowering

     : public ConvertOpToLLVMPattern<memref::ExtractStridedMetadataOp> {

 public:

   using ConvertOpToLLVMPattern<

       memref::ExtractStridedMetadataOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(memref::ExtractStridedMetadataOp extractStridedMetadataOp,

                   OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {


     if (!LLVM::isCompatibleType(adaptor.getOperands().front().getType()))

       return failure();


     // Create the descriptor.

     MemRefDescriptor sourceMemRef(adaptor.getSource());

     Location loc = extractStridedMetadataOp.getLoc();

     Value source = extractStridedMetadataOp.getSource();


     auto sourceMemRefType = cast<MemRefType>(source.getType());

     int64_t rank = sourceMemRefType.getRank();

     SmallVector<Value> results;

     results.reserve(2 + rank * 2);


     // Base buffer.

     Value baseBuffer = sourceMemRef.allocatedPtr(rewriter, loc);

     Value alignedBuffer = sourceMemRef.alignedPtr(rewriter, loc);

     MemRefDescriptor dstMemRef = MemRefDescriptor::fromStaticShape(

         rewriter, loc, *getTypeConverter(),

         cast<MemRefType>(extractStridedMetadataOp.getBaseBuffer().getType()),

         baseBuffer, alignedBuffer);

     results.push_back((Value)dstMemRef);


     // Offset.

     results.push_back(sourceMemRef.offset(rewriter, loc));


     // Sizes.

     for (unsigned i = 0; i < rank; ++i)

       results.push_back(sourceMemRef.size(rewriter, loc, i));

     // Strides.

     for (unsigned i = 0; i < rank; ++i)

       results.push_back(sourceMemRef.stride(rewriter, loc, i));


     rewriter.replaceOp(extractStridedMetadataOp, results);

     return success();

   }

 };


 } // namespace


 void mlir::populateFinalizeMemRefToLLVMConversionPatterns(

     const LLVMTypeConverter &converter, RewritePatternSet &patterns) {

   // clang-format off

   patterns.add<

       AllocaOpLowering,

       AllocaScopeOpLowering,

       AtomicRMWOpLowering,

       AssumeAlignmentOpLowering,

       ConvertExtractAlignedPointerAsIndex,

       DimOpLowering,

       ExtractStridedMetadataOpLowering,

       GenericAtomicRMWOpLowering,

       GlobalMemrefOpLowering,

       GetGlobalMemrefOpLowering,

       LoadOpLowering,

       MemRefCastOpLowering,

       MemRefCopyOpLowering,

       MemorySpaceCastOpLowering,

       MemRefReinterpretCastOpLowering,

       MemRefReshapeOpLowering,

       PrefetchOpLowering,

       RankOpLowering,

       ReassociatingReshapeOpConversion<memref::ExpandShapeOp>,

       ReassociatingReshapeOpConversion<memref::CollapseShapeOp>,

       StoreOpLowering,

       SubViewOpLowering,

       TransposeOpLowering,

       ViewOpLowering>(converter);

   // clang-format on

   auto allocLowering = converter.getOptions().allocLowering;

   if (allocLowering == LowerToLLVMOptions::AllocLowering::AlignedAlloc)

     patterns.add<AlignedAllocOpLowering, DeallocOpLowering>(converter);

   else if (allocLowering == LowerToLLVMOptions::AllocLowering::Malloc)

     patterns.add<AllocOpLowering, DeallocOpLowering>(converter);

 }


 namespace {

 struct FinalizeMemRefToLLVMConversionPass

     : public impl::FinalizeMemRefToLLVMConversionPassBase<

           FinalizeMemRefToLLVMConversionPass> {

   using FinalizeMemRefToLLVMConversionPassBase::

       FinalizeMemRefToLLVMConversionPassBase;


   void runOnOperation() override {

     Operation *op = getOperation();

     const auto &dataLayoutAnalysis = getAnalysis<DataLayoutAnalysis>();

     LowerToLLVMOptions options(&getContext(),

                                dataLayoutAnalysis.getAtOrAbove(op));

     options.allocLowering =

         (useAlignedAlloc ? LowerToLLVMOptions::AllocLowering::AlignedAlloc

                          : LowerToLLVMOptions::AllocLowering::Malloc);


     options.useGenericFunctions = useGenericFunctions;


     if (indexBitwidth != kDeriveIndexBitwidthFromDataLayout)

       options.overrideIndexBitwidth(indexBitwidth);


     LLVMTypeConverter typeConverter(&getContext(), options,

                                     &dataLayoutAnalysis);

     RewritePatternSet patterns(&getContext());

     populateFinalizeMemRefToLLVMConversionPatterns(typeConverter, patterns);

     LLVMConversionTarget target(getContext());

     target.addLegalOp<func::FuncOp>();

     if (failed(applyPartialConversion(op, target, std::move(patterns))))

       signalPassFailure();

   }

 };


 /// Implement the interface to convert MemRef to LLVM.

 struct MemRefToLLVMDialectInterface : public ConvertToLLVMPatternInterface {

   using ConvertToLLVMPatternInterface::ConvertToLLVMPatternInterface;

   void loadDependentDialects(MLIRContext *context) const final {

     context->loadDialect<LLVM::LLVMDialect>();

   }


   /// Hook for derived dialect interface to provide conversion patterns

   /// and mark dialect legal for the conversion target.

   void populateConvertToLLVMConversionPatterns(

       ConversionTarget &target, LLVMTypeConverter &typeConverter,

       RewritePatternSet &patterns) const final {

     populateFinalizeMemRefToLLVMConversionPatterns(typeConverter, patterns);

   }

 };


 } // namespace


 void mlir::registerConvertMemRefToLLVMInterface(DialectRegistry &registry) {

   registry.addExtension(+[](MLIRContext *ctx, memref::MemRefDialect *dialect) {

     dialect->addInterfaces<MemRefToLLVMDialectInterface>();

   });

 }

AllocLikeConversion.h

ConversionTarget.h

DataLayoutAnalysis.h

MemRefUtils.h

FuncOps.h

FunctionCallUtils.h

IRMapping.h

getContext
static MLIRContext * getContext(OpFoldResult val)
Definition: IndexingUtils.cpp:295

LLVMDialect.h

LLVMTypes.h

createIndexAttrConstant
static Value createIndexAttrConstant(OpBuilder &builder, Location loc, Type resultType, int64_t value)
Definition: MemRefBuilder.cpp:100

MemRefToLLVM.h

getSizeInBytes
llvm::Value * getSizeInBytes(DataLayout &dl, const mlir::Type &type, Operation *clauseOp, llvm::Value *basePointer, llvm::Type *baseType, llvm::IRBuilderBase &builder, LLVM::ModuleTranslation &moduleTranslation)
Definition: OpenMPToLLVMIRTranslation.cpp:2859

options
static llvm::ManagedStatic< PassManagerOptions > options
Definition: PassManagerOptions.cpp:89

max
static Value max(ImplicitLocOpBuilder &builder, Value value, Value bound)
Definition: PolynomialApproximation.cpp:209

min
static Value min(ImplicitLocOpBuilder &builder, Value value, Value bound)
Definition: PolynomialApproximation.cpp:202

rewrite
static void rewrite(DataFlowSolver &solver, MLIRContext *context, MutableArrayRef< Region > initialRegions)
Rewrite the given regions using the computing analysis.
Definition: SCCP.cpp:67

ToLLVMInterface.h

TypeConverter.h

TransposeOpLowering
Rewrite AVX2-specific vector.transpose, for the supported cases and depending on the TransposeLowerin...
Definition: AVXTranspose.cpp:208

llvm::ArrayRef
Definition: LLVM.h:48

llvm::SmallVector
Definition: LLVM.h:72

mlir::Attribute
Attributes are known-constant values of operations.
Definition: Attributes.h:25

mlir::BaseMemRefType
This class provides a shared interface for ranked and unranked memref types.
Definition: BuiltinTypes.h:102

mlir::BaseMemRefType::getMemorySpaceAsInt
unsigned getMemorySpaceAsInt() const
[deprecated] Returns the memory space in old raw integer representation.
Definition: BuiltinTypes.cpp:394

mlir::BaseMemRefType::hasRank
bool hasRank() const
Returns if this type is ranked, i.e. it has a known number of dimensions.
Definition: BuiltinTypes.cpp:354

mlir::Block
Block represents an ordered list of Operations.
Definition: Block.h:33

mlir::Block::iterator
OpListType::iterator iterator
Definition: Block.h:140

mlir::Block::getArgument
BlockArgument getArgument(unsigned i)
Definition: Block.h:129

mlir::Block::back
Operation & back()
Definition: Block.h:152

mlir::Block::getTerminator
Operation * getTerminator()
Get the terminator operation of this block.
Definition: Block.cpp:246

mlir::Block::addArgument
BlockArgument addArgument(Type type, Location loc)
Add one value to the argument list.
Definition: Block.cpp:155

mlir::Block::getArguments
BlockArgListType getArguments()
Definition: Block.h:87

mlir::Block::front
Operation & front()
Definition: Block.h:153

mlir::Block::without_terminator
iterator_range< iterator > without_terminator()
Return an iterator range over the operation within this block excluding the terminator operation at t...
Definition: Block.h:209

mlir::Builder::getIndexAttr
IntegerAttr getIndexAttr(int64_t value)
Definition: Builders.cpp:104

mlir::Builder::getI32IntegerAttr
IntegerAttr getI32IntegerAttr(int32_t value)
Definition: Builders.cpp:196

mlir::Builder::getBoolAttr
BoolAttr getBoolAttr(bool value)
Definition: Builders.cpp:96

mlir::Builder::getContext
MLIRContext * getContext() const
Definition: Builders.h:56

mlir::Builder::getI8Type
IntegerType getI8Type()
Definition: Builders.cpp:59

mlir::ConversionPatternRewriter
This class implements a pattern rewriter for use with ConversionPatterns.
Definition: DialectConversion.h:809

mlir::ConversionPatternRewriter::replaceOp
void replaceOp(Operation *op, ValueRange newValues) override
Replace the given operation with the new values.
Definition: DialectConversion.cpp:1636

mlir::ConversionPatternRewriter::eraseOp
void eraseOp(Operation *op) override
PatternRewriter hook for erasing a dead operation.
Definition: DialectConversion.cpp:1665

mlir::ConversionTarget
This class describes a specific conversion target.
Definition: DialectConversion.h:940

mlir::ConvertOpToLLVMPattern
Utility class for operation conversions targeting the LLVM dialect that match exactly one source oper...
Definition: Pattern.h:143

mlir::ConvertToLLVMPatternInterface
Base class for dialect interfaces providing translation to LLVM IR.
Definition: ToLLVMInterface.h:31

mlir::ConvertToLLVMPatternInterface::ConvertToLLVMPatternInterface
ConvertToLLVMPatternInterface(Dialect *dialect)
Definition: ToLLVMInterface.h:33

mlir::DataLayout
The main mechanism for performing data layout queries.
Definition: DataLayoutInterfaces.h:201

mlir::DialectRegistry
The DialectRegistry maps a dialect namespace to a constructor for the matching dialect.
Definition: DialectRegistry.h:139

mlir::DialectRegistry::addExtension
bool addExtension(TypeID extensionID, std::unique_ptr< DialectExtensionBase > extension)
Add the given extension to the registry.
Definition: DialectRegistry.h:211

mlir::IRMapping
This is a utility class for mapping one set of IR entities to another.
Definition: IRMapping.h:26

mlir::IRMapping::lookup
auto lookup(T from) const
Lookup a mapped value within the map.
Definition: IRMapping.h:72

mlir::IRMapping::map
void map(Value from, Value to)
Inserts a new mapping for 'from' to 'to'.
Definition: IRMapping.h:30

mlir::LLVMConversionTarget
Derived class that automatically populates legalization information for different LLVM ops.
Definition: ConversionTarget.h:17

mlir::LLVMTypeConverter
Conversion from types to the LLVM IR dialect.
Definition: TypeConverter.h:35

mlir::LLVMTypeConverter::getOptions
const LowerToLLVMOptions & getOptions() const
Definition: TypeConverter.h:107

mlir::LLVMTypeConverter::convertType
LogicalResult convertType(Type t, SmallVectorImpl< Type > &results) const
Convert the given type.
Definition: DialectConversion.cpp:2820

mlir::LLVMTypeConverter::getMemRefAddressSpace
FailureOr< unsigned > getMemRefAddressSpace(BaseMemRefType type) const
Return the LLVM address space corresponding to the memory space of the memref type type or failure if...
Definition: TypeConverter.cpp:575

mlir::Location
This class defines the main interface for locations in MLIR and acts as a non-nullable wrapper around...
Definition: Location.h:66

mlir::LowerToLLVMOptions
Options to control the LLVM lowering.
Definition: LoweringOptions.h:30

mlir::LowerToLLVMOptions::allocLowering
AllocLowering allocLowering
Definition: LoweringOptions.h:49

mlir::LowerToLLVMOptions::AllocLowering::Malloc
@ Malloc
Use malloc for heap allocations.

mlir::LowerToLLVMOptions::AllocLowering::AlignedAlloc
@ AlignedAlloc
Use aligned_alloc for heap allocations.

mlir::LowerToLLVMOptions::useGenericFunctions
bool useGenericFunctions
Definition: LoweringOptions.h:51

mlir::MLIRContext
MLIRContext is the top-level object for a collection of MLIR operations.
Definition: MLIRContext.h:60

mlir::MemRefDescriptor
Helper class to produce LLVM dialect operations extracting or inserting elements of a MemRef descript...
Definition: MemRefBuilder.h:33

mlir::MemRefDescriptor::fromStaticShape
static MemRefDescriptor fromStaticShape(OpBuilder &builder, Location loc, const LLVMTypeConverter &typeConverter, MemRefType type, Value memory)
Builds IR creating a MemRef descriptor that represents type and populates it with static shape and st...
Definition: MemRefBuilder.cpp:43

mlir::MemRefDescriptor::poison
static MemRefDescriptor poison(OpBuilder &builder, Location loc, Type descriptorType)
Builds IR creating a poison value of the descriptor type.
Definition: MemRefBuilder.cpp:32

mlir::MemRefDescriptor::unpack
static void unpack(OpBuilder &builder, Location loc, Value packed, MemRefType type, SmallVectorImpl< Value > &results)
Builds IR extracting individual elements of a MemRef descriptor structure and returning them as resul...
Definition: MemRefBuilder.cpp:244

mlir::MemRefDescriptor::allocatedPtr
Value allocatedPtr(OpBuilder &builder, Location loc)
Builds IR extracting the allocated pointer from the descriptor.
Definition: MemRefBuilder.cpp:77

mlir::MemRefDescriptor::pack
static Value pack(OpBuilder &builder, Location loc, const LLVMTypeConverter &converter, MemRefType type, ValueRange values)
Builds IR populating a MemRef descriptor structure from a list of individual values composing that de...
Definition: MemRefBuilder.cpp:223

mlir::OpBuilder::InsertionGuard
RAII guard to reset the insertion point of the builder when destroyed.
Definition: Builders.h:346

mlir::OpBuilder::getInsertionPoint
Block::iterator getInsertionPoint() const
Returns the current insertion point of the builder.
Definition: Builders.h:443

mlir::OpBuilder::clone
Operation * clone(Operation &op, IRMapping &mapper)
Creates a deep copy of the specified operation, remapping any operands that use values outside of the...
Definition: Builders.cpp:544

mlir::OpBuilder::setInsertionPointToStart
void setInsertionPointToStart(Block *block)
Sets the insertion point to the start of the specified block.
Definition: Builders.h:429

mlir::OpBuilder::setInsertionPoint
void setInsertionPoint(Block *block, Block::iterator insertPoint)
Set the insertion point to the specified location.
Definition: Builders.h:396

mlir::OpBuilder::setInsertionPointToEnd
void setInsertionPointToEnd(Block *block)
Sets the insertion point to the end of the specified block.
Definition: Builders.h:434

mlir::OpBuilder::createBlock
Block * createBlock(Region *parent, Region::iterator insertPt={}, TypeRange argTypes=std::nullopt, ArrayRef< Location > locs=std::nullopt)
Add new block with 'argTypes' arguments and set the insertion point to the end of it.
Definition: Builders.cpp:426

mlir::OpBuilder::create
Operation * create(const OperationState &state)
Creates an operation given the fields represented as an OperationState.
Definition: Builders.cpp:453

mlir::OpBuilder::getInsertionBlock
Block * getInsertionBlock() const
Return the block the current insertion point belongs to.
Definition: Builders.h:440

mlir::Operation
Operation is the basic unit of execution within MLIR.
Definition: Operation.h:88

mlir::Operation::getOperand
Value getOperand(unsigned idx)
Definition: Operation.h:350

mlir::Operation::getLoc
Location getLoc()
The source location the operation was defined or derived from.
Definition: Operation.h:223

mlir::Operation::getResults
result_range getResults()
Definition: Operation.h:415

mlir::RewritePatternSet
Definition: PatternMatch.h:814

mlir::RewriterBase::notifyMatchFailure
std::enable_if_t<!std::is_convertible< CallbackT, Twine >::value, LogicalResult > notifyMatchFailure(Location loc, CallbackT &&reasonCallback)
Used to notify the listener that the IR failed to be rewritten because of a match failure,...
Definition: PatternMatch.h:724

mlir::RewriterBase::splitBlock
Block * splitBlock(Block *block, Block::iterator before)
Split the operations starting at "before" (inclusive) out of the given block into a new block,...
Definition: PatternMatch.cpp:346

mlir::RewriterBase::mergeBlocks
void mergeBlocks(Block *source, Block *dest, ValueRange argValues=std::nullopt)
Inline the operations of block 'source' into the end of block 'dest'.
Definition: PatternMatch.cpp:339

mlir::RewriterBase::inlineRegionBefore
void inlineRegionBefore(Region &region, Region &parent, Region::iterator before)
Move the blocks that belong to "region" before the given position in another region "parent".
Definition: PatternMatch.cpp:372

mlir::RewriterBase::replaceOpWithNewOp
OpTy replaceOpWithNewOp(Operation *op, Args &&...args)
Replace the results of the given (original) op with a new op that is created without verification (re...
Definition: PatternMatch.h:542

mlir::TypeConverter::materializeTargetConversion
Value materializeTargetConversion(OpBuilder &builder, Location loc, Type resultType, ValueRange inputs, Type originalType={}) const
Definition: DialectConversion.cpp:2950

mlir::Type
Instances of the Type class are uniqued, have an immutable identifier and an optional mutable compone...
Definition: Types.h:74

mlir::UnrankedMemRefDescriptor
Definition: MemRefBuilder.h:158

mlir::UnrankedMemRefDescriptor::setOffset
static void setOffset(OpBuilder &builder, Location loc, const LLVMTypeConverter &typeConverter, Value memRefDescPtr, LLVM::LLVMPointerType elemPtrType, Value offset)
Builds IR inserting the offset into the descriptor.
Definition: MemRefBuilder.cpp:463

mlir::UnrankedMemRefDescriptor::allocatedPtr
static Value allocatedPtr(OpBuilder &builder, Location loc, Value memRefDescPtr, LLVM::LLVMPointerType elemPtrType)
TODO: The following accessors don't take alignment rules between elements of the descriptor struct in...
Definition: MemRefBuilder.cpp:400

mlir::UnrankedMemRefDescriptor::memRefDescPtr
Value memRefDescPtr(OpBuilder &builder, Location loc) const
Builds IR extracting ranked memref descriptor ptr.
Definition: MemRefBuilder.cpp:316

mlir::UnrankedMemRefDescriptor::setAllocatedPtr
static void setAllocatedPtr(OpBuilder &builder, Location loc, Value memRefDescPtr, LLVM::LLVMPointerType elemPtrType, Value allocatedPtr)
Builds IR inserting the allocated pointer into the descriptor.
Definition: MemRefBuilder.cpp:406

mlir::UnrankedMemRefDescriptor::setSize
static void setSize(OpBuilder &builder, Location loc, const LLVMTypeConverter &typeConverter, Value sizeBasePtr, Value index, Value size)
Builds IR inserting the size[index] into the descriptor.
Definition: MemRefBuilder.cpp:496

mlir::UnrankedMemRefDescriptor::pack
static Value pack(OpBuilder &builder, Location loc, const LLVMTypeConverter &converter, UnrankedMemRefType type, ValueRange values)
Builds IR populating an unranked MemRef descriptor structure from a list of individual constituent va...
Definition: MemRefBuilder.cpp:329

mlir::UnrankedMemRefDescriptor::poison
static UnrankedMemRefDescriptor poison(OpBuilder &builder, Location loc, Type descriptorType)
Builds IR creating an undef value of the descriptor type.
Definition: MemRefBuilder.cpp:303

mlir::UnrankedMemRefDescriptor::computeSizes
static void computeSizes(OpBuilder &builder, Location loc, const LLVMTypeConverter &typeConverter, ArrayRef< UnrankedMemRefDescriptor > values, ArrayRef< unsigned > addressSpaces, SmallVectorImpl< Value > &sizes)
Builds IR computing the sizes in bytes (suitable for opaque allocation) and appends the corresponding...
Definition: MemRefBuilder.cpp:352

mlir::UnrankedMemRefDescriptor::setAlignedPtr
static void setAlignedPtr(OpBuilder &builder, Location loc, const LLVMTypeConverter &typeConverter, Value memRefDescPtr, LLVM::LLVMPointerType elemPtrType, Value alignedPtr)
Builds IR inserting the aligned pointer into the descriptor.
Definition: MemRefBuilder.cpp:431

mlir::UnrankedMemRefDescriptor::offset
static Value offset(OpBuilder &builder, Location loc, const LLVMTypeConverter &typeConverter, Value memRefDescPtr, LLVM::LLVMPointerType elemPtrType)
Builds IR extracting the offset from the descriptor.
Definition: MemRefBuilder.cpp:453

mlir::UnrankedMemRefDescriptor::strideBasePtr
static Value strideBasePtr(OpBuilder &builder, Location loc, const LLVMTypeConverter &typeConverter, Value sizeBasePtr, Value rank)
Builds IR extracting the pointer to the first element of the stride array.
Definition: MemRefBuilder.cpp:508

mlir::UnrankedMemRefDescriptor::setStride
static void setStride(OpBuilder &builder, Location loc, const LLVMTypeConverter &typeConverter, Value strideBasePtr, Value index, Value stride)
Builds IR inserting the stride[index] into the descriptor.
Definition: MemRefBuilder.cpp:529

mlir::UnrankedMemRefDescriptor::sizeBasePtr
static Value sizeBasePtr(OpBuilder &builder, Location loc, const LLVMTypeConverter &typeConverter, Value memRefDescPtr, LLVM::LLVMPointerType elemPtrType)
Builds IR extracting the pointer to the first element of the size array.
Definition: MemRefBuilder.cpp:473

mlir::UnrankedMemRefDescriptor::alignedPtr
static Value alignedPtr(OpBuilder &builder, Location loc, const LLVMTypeConverter &typeConverter, Value memRefDescPtr, LLVM::LLVMPointerType elemPtrType)
Builds IR extracting the aligned pointer from the descriptor.
Definition: MemRefBuilder.cpp:419

mlir::ValueRange
This class provides an abstraction over the different types of ranges over Values.
Definition: ValueRange.h:381

mlir::Value
This class represents an instance of an SSA value in the MLIR system, representing a computable value...
Definition: Value.h:96

mlir::Value::getType
Type getType() const
Return the type of this value.
Definition: Value.h:129

mlir::Value::getLoc
Location getLoc() const
Return the location of this value.
Definition: Value.cpp:26

Pattern.h

Pass.h

Arith.h

MemRef.h

AffineMap.h

BuiltinTypes.h

mlir::LLVM::lookupOrCreateMemRefCopyFn
FailureOr< LLVM::LLVMFuncOp > lookupOrCreateMemRefCopyFn(Operation *moduleOp, Type indexType, Type unrankedDescriptorType)
Definition: FunctionCallUtils.cpp:216

mlir::LLVM::lookupOrCreateFreeFn
FailureOr< LLVM::LLVMFuncOp > lookupOrCreateFreeFn(Operation *moduleOp)
Definition: FunctionCallUtils.cpp:188

mlir::LLVM::isCompatibleType
bool isCompatibleType(Type type)
Returns true if the given type is compatible with the LLVM dialect.
Definition: LLVMTypes.cpp:860

mlir::LLVM::lookupOrCreateGenericFreeFn
FailureOr< LLVM::LLVMFuncOp > lookupOrCreateGenericFreeFn(Operation *moduleOp)
Definition: FunctionCallUtils.cpp:209

mlir::detail::enumerate
constexpr void enumerate(std::tuple< Tys... > &tuple, CallbackT &&callback)
Definition: Matchers.h:344

mlir::detail::divideCeil
llvm::TypeSize divideCeil(llvm::TypeSize numerator, uint64_t denominator)
Divides the known min value of the numerator by the denominator and rounds the result up to the next ...
Definition: DataLayoutInterfaces.cpp:431

mlir::memref::isStaticShapeAndContiguousRowMajor
bool isStaticShapeAndContiguousRowMajor(MemRefType type)
Returns true, if the memref type has static shapes and represents a contiguous chunk of memory.
Definition: MemRefUtils.cpp:24

mlir::scf::promote
void promote(RewriterBase &rewriter, scf::ForallOp forallOp)
Promotes the loop body of a scf::ForallOp to its containing block.
Definition: SCF.cpp:644

mlir
Include the generated interface declarations.
Definition: LocalAliasAnalysis.h:20

mlir::registerConvertMemRefToLLVMInterface
void registerConvertMemRefToLLVMInterface(DialectRegistry &registry)
Definition: MemRefToLLVM.cpp:1753

mlir::kDeriveIndexBitwidthFromDataLayout
static constexpr unsigned kDeriveIndexBitwidthFromDataLayout
Value to pass as bitwidth for the index type when the converter is expected to derive the bitwidth fr...
Definition: LoweringOptions.h:26

mlir::populateFinalizeMemRefToLLVMConversionPatterns
void populateFinalizeMemRefToLLVMConversionPatterns(const LLVMTypeConverter &converter, RewritePatternSet &patterns)
Collect a set of patterns to convert memory-related operations from the MemRef dialect to the LLVM di...
Definition: MemRefToLLVM.cpp:1667

mlir::patterns
const FrozenRewritePatternSet & patterns
Definition: GreedyPatternRewriteDriver.h:233

mlir::clone
Operation * clone(OpBuilder &b, Operation *op, TypeRange newResultTypes, ValueRange newOperands)
Definition: StructuredOpsUtils.cpp:197

mlir::get
auto get(MLIRContext *context, Ts &&...params)
Helper method that injects context only if needed, this helps unify some of the attribute constructio...
Definition: BytecodeImplementation.h:509

mlir::applyPartialConversion
LogicalResult applyPartialConversion(ArrayRef< Operation * > ops, const ConversionTarget &target, const FrozenRewritePatternSet &patterns, ConversionConfig config=ConversionConfig())
Below we define several entry points for operation conversion.
Definition: DialectConversion.cpp:3358

mlir::AllocLikeOpLLVMLowering
Lowering for AllocOp and AllocaOp.
Definition: AllocLikeConversion.h:108

mlir::LLVM::AssumeAlignTag
Definition: LLVMDialect.h:93