doxygen/AMDGPUToROCDL_8cpp_source.html

 //===- AMDGPUToROCDL.cpp - AMDGPU to ROCDL 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/AMDGPUToROCDL/AMDGPUToROCDL.h"


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

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

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

 #include "mlir/Dialect/AMDGPU/IR/AMDGPUDialect.h"

 #include "mlir/Dialect/AMDGPU/Utils/Chipset.h"

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

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

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

 #include "mlir/IR/BuiltinTypes.h"

 #include "mlir/IR/TypeUtilities.h"

 #include "mlir/Pass/Pass.h"


 #include "../LLVMCommon/MemRefDescriptor.h"


 #include "llvm/ADT/STLExtras.h"

 #include "llvm/ADT/TypeSwitch.h"

 #include "llvm/Support/Casting.h"

 #include "llvm/Support/ErrorHandling.h"

 #include <optional>


 namespace mlir {

 #define GEN_PASS_DEF_CONVERTAMDGPUTOROCDLPASS

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

 } // namespace mlir


 using namespace mlir;

 using namespace mlir::amdgpu;


 // Define commonly used chipsets versions for convenience.

 constexpr Chipset kGfx908 = Chipset(9, 0, 8);

 constexpr Chipset kGfx90a = Chipset(9, 0, 0xa);

 constexpr Chipset kGfx942 = Chipset(9, 4, 2);

 constexpr Chipset kGfx950 = Chipset(9, 5, 0);


 /// Convert an unsigned number `val` to i32.

 static Value convertUnsignedToI32(ConversionPatternRewriter &rewriter,

                                   Location loc, Value val) {

   IntegerType i32 = rewriter.getI32Type();

   // Force check that `val` is of int type.

   auto valTy = cast<IntegerType>(val.getType());

   if (i32 == valTy)

     return val;

   return valTy.getWidth() > 32

              ? Value(LLVM::TruncOp::create(rewriter, loc, i32, val))

              : Value(LLVM::ZExtOp::create(rewriter, loc, i32, val));

 }


 static Value createI32Constant(ConversionPatternRewriter &rewriter,

                                Location loc, int32_t value) {

   Type i32 = rewriter.getI32Type();

   return LLVM::ConstantOp::create(rewriter, loc, i32, value);

 }


 static Value createI1Constant(ConversionPatternRewriter &rewriter, Location loc,

                               bool value) {

   Type llvmI1 = rewriter.getI1Type();

   return LLVM::ConstantOp::create(rewriter, loc, llvmI1, value);

 }


 /// Returns the linear index used to access an element in the memref.

 static Value getLinearIndexI32(ConversionPatternRewriter &rewriter,

                                Location loc, MemRefDescriptor &memRefDescriptor,

                                ValueRange indices, ArrayRef<int64_t> strides) {

   IntegerType i32 = rewriter.getI32Type();

   Value index;

   for (auto [i, increment, stride] : llvm::enumerate(indices, strides)) {

     if (stride != 1) { // Skip if stride is 1.

       Value strideValue =

           ShapedType::isDynamic(stride)

               ? convertUnsignedToI32(rewriter, loc,

                                      memRefDescriptor.stride(rewriter, loc, i))

               : LLVM::ConstantOp::create(rewriter, loc, i32, stride);

       increment = LLVM::MulOp::create(rewriter, loc, increment, strideValue);

     }

     index = index ? LLVM::AddOp::create(rewriter, loc, index, increment)

                   : increment;

   }

   return index ? index : createI32Constant(rewriter, loc, 0);

 }


 /// Compute the contents of the `num_records` field for a given memref

 /// descriptor - that is, the number of bytes that's one element past the

 /// greatest possible valid index into the memref.

 static Value getNumRecords(ConversionPatternRewriter &rewriter, Location loc,

                            MemRefType memrefType,

                            MemRefDescriptor &memrefDescriptor,

                            ArrayRef<int64_t> strides,

                            uint32_t elementByteWidth) {

   if (memrefType.hasStaticShape() &&

       !llvm::any_of(strides, ShapedType::isDynamic)) {

     int64_t size = memrefType.getRank() == 0 ? 1 : 0;

     ArrayRef<int64_t> shape = memrefType.getShape();

     for (uint32_t i = 0, e = memrefType.getRank(); i < e; ++i)

       size = std::max(shape[i] * strides[i], size);

     size = size * elementByteWidth;

     assert(size < std::numeric_limits<uint32_t>::max() &&

            "the memref buffer is too large");

     return createI32Constant(rewriter, loc, static_cast<int32_t>(size));

   }

   Value maxIndex;

   for (uint32_t i = 0, e = memrefType.getRank(); i < e; ++i) {

     Value size = memrefDescriptor.size(rewriter, loc, i);

     Value stride = memrefDescriptor.stride(rewriter, loc, i);

     Value maxThisDim = LLVM::MulOp::create(rewriter, loc, size, stride);

     maxIndex = maxIndex

                    ? LLVM::UMaxOp::create(rewriter, loc, maxIndex, maxThisDim)

                    : maxThisDim;

   }

   Value maxIndexI32 = convertUnsignedToI32(rewriter, loc, maxIndex);

   Value byteWidthConst = createI32Constant(rewriter, loc, elementByteWidth);

   return LLVM::MulOp::create(rewriter, loc, maxIndexI32, byteWidthConst);

 }


 static Value makeBufferRsrc(ConversionPatternRewriter &rewriter, Location loc,

                             Value basePointer, Value numRecords,

                             bool boundsCheck, amdgpu::Chipset chipset,

                             Value cacheSwizzleStride = nullptr,

                             unsigned addressSpace = 8) {

   // The stride value is generally 0. However, on MI-300 and onward, you can

   // enable a cache swizzling mode by setting bit 14 of the stride field

   // and setting that stride to a cache stride.

   Type i16 = rewriter.getI16Type();

   Value stride;

   if (chipset.majorVersion == 9 && chipset >= kGfx942 && cacheSwizzleStride) {

     Value cacheStrideZext =

         LLVM::ZExtOp::create(rewriter, loc, i16, cacheSwizzleStride);

     Value swizzleBit = LLVM::ConstantOp::create(

         rewriter, loc, i16, rewriter.getI16IntegerAttr(1 << 14));

     stride = LLVM::OrOp::create(rewriter, loc, cacheStrideZext, swizzleBit,

                                 /*isDisjoint=*/true);

   } else {

     stride = LLVM::ConstantOp::create(rewriter, loc, i16,

                                       rewriter.getI16IntegerAttr(0));

   }

   // Get the number of elements.

   // Flag word:

   // bits 0-11: dst sel, ignored by these intrinsics

   // bits 12-14: data format (ignored, must be nonzero, 7=float)

   // bits 15-18: data format (ignored, must be nonzero, 4=32bit)

   // bit 19: In nested heap (0 here)

   // bit 20: Behavior on unmap (0 means  "return 0 / ignore")

   // bits 21-22: Index stride for swizzles (N/A)

   // bit 23: Add thread ID (0)

   // bit 24: Reserved to 1 (RDNA) or 0 (CDNA)

   // bits 25-26: Reserved (0)

   // bit 27: Buffer is non-volatile (CDNA only)

   // bits 28-29: Out of bounds select (0 = structured, 1 = check index, 2 =

   //  none, 3 = either swizzles or testing against offset field) RDNA only

   // bits 30-31: Type (must be 0)

   uint32_t flags = (7 << 12) | (4 << 15);

   if (chipset.majorVersion >= 10) {

     flags |= (1 << 24);

     uint32_t oob = boundsCheck ? 3 : 2;

     flags |= (oob << 28);

   }

   Value flagsConst = createI32Constant(rewriter, loc, flags);

   Type rsrcType =

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

   Value resource = rewriter.createOrFold<ROCDL::MakeBufferRsrcOp>(

       loc, rsrcType, basePointer, stride, numRecords, flagsConst);

   return resource;

 }


 namespace {

 struct FatRawBufferCastLowering

     : public ConvertOpToLLVMPattern<FatRawBufferCastOp> {

   FatRawBufferCastLowering(const LLVMTypeConverter &converter, Chipset chipset)

       : ConvertOpToLLVMPattern<FatRawBufferCastOp>(converter),

         chipset(chipset) {}


   Chipset chipset;


   LogicalResult

   matchAndRewrite(FatRawBufferCastOp op, FatRawBufferCastOpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     Location loc = op.getLoc();

     Value memRef = adaptor.getSource();

     Value unconvertedMemref = op.getSource();

     MemRefType memrefType = cast<MemRefType>(unconvertedMemref.getType());

     MemRefDescriptor descriptor(memRef);


     DataLayout dataLayout = DataLayout::closest(op);

     int64_t elementByteWidth =

         dataLayout.getTypeSizeInBits(memrefType.getElementType()) / 8;


     int64_t unusedOffset = 0;

     SmallVector<int64_t, 5> strideVals;

     if (failed(memrefType.getStridesAndOffset(strideVals, unusedOffset)))

       return op.emitOpError("Can't lower non-stride-offset memrefs");


     Value numRecords = adaptor.getValidBytes();

     if (!numRecords)

       numRecords = getNumRecords(rewriter, loc, memrefType, descriptor,

                                  strideVals, elementByteWidth);


     Value basePointer =

         adaptor.getResetOffset()

             ? descriptor.bufferPtr(rewriter, loc, *getTypeConverter(),

                                    memrefType)

             : descriptor.alignedPtr(rewriter, loc);


     Value offset = adaptor.getResetOffset()

                        ? LLVM::ConstantOp::create(rewriter, loc, getIndexType(),

                                                   rewriter.getIndexAttr(0))

                        : descriptor.offset(rewriter, loc);


     bool hasSizes = memrefType.getRank() > 0;

     // No need to unpack() and pack() all the individual sizes and strides,

     // so we'll just extract the arrays.

     Value sizes = hasSizes

                       ? LLVM::ExtractValueOp::create(rewriter, loc, descriptor,

                                                      kSizePosInMemRefDescriptor)

                       : Value{};

     Value strides =

         hasSizes ? LLVM::ExtractValueOp::create(rewriter, loc, descriptor,

                                                 kStridePosInMemRefDescriptor)

                  : Value{};


     Value fatPtr = makeBufferRsrc(

         rewriter, loc, basePointer, numRecords, adaptor.getBoundsCheck(),

         chipset, adaptor.getCacheSwizzleStride(), /*addressSpace=*/7);


     Value result = MemRefDescriptor::poison(

         rewriter, loc,

         getTypeConverter()->convertType(op.getResult().getType()));

     SmallVector<int64_t> pos{kAllocatedPtrPosInMemRefDescriptor};

     result = LLVM::InsertValueOp::create(rewriter, loc, result, fatPtr, pos);

     result = LLVM::InsertValueOp::create(rewriter, loc, result, fatPtr,

                                          kAlignedPtrPosInMemRefDescriptor);

     result = LLVM::InsertValueOp::create(rewriter, loc, result, offset,

                                          kOffsetPosInMemRefDescriptor);

     if (hasSizes) {

       result = LLVM::InsertValueOp::create(rewriter, loc, result, sizes,

                                            kSizePosInMemRefDescriptor);

       result = LLVM::InsertValueOp::create(rewriter, loc, result, strides,

                                            kStridePosInMemRefDescriptor);

     }

     rewriter.replaceOp(op, result);

     return success();

   }

 };


 /// Define lowering patterns for raw buffer ops

 template <typename GpuOp, typename Intrinsic>

 struct RawBufferOpLowering : public ConvertOpToLLVMPattern<GpuOp> {

   RawBufferOpLowering(const LLVMTypeConverter &converter, Chipset chipset)

       : ConvertOpToLLVMPattern<GpuOp>(converter), chipset(chipset) {}


   Chipset chipset;

   static constexpr uint32_t maxVectorOpWidth = 128;


   LogicalResult

   matchAndRewrite(GpuOp gpuOp, typename GpuOp::Adaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     Location loc = gpuOp.getLoc();

     Value memref = adaptor.getMemref();

     Value unconvertedMemref = gpuOp.getMemref();

     MemRefType memrefType = cast<MemRefType>(unconvertedMemref.getType());


     if (chipset.majorVersion < 9)

       return gpuOp.emitOpError("raw buffer ops require GCN or higher");


     Value storeData = adaptor.getODSOperands(0)[0];

     if (storeData == memref) // no write component to this op

       storeData = Value();

     Type wantedDataType;

     if (storeData)

       wantedDataType = storeData.getType();

     else

       wantedDataType = gpuOp.getODSResults(0)[0].getType();


     Value atomicCmpData = Value();

     // Operand index 1 of a load is the indices, trying to read them can crash.

     if (storeData) {

       Value maybeCmpData = adaptor.getODSOperands(1)[0];

       if (maybeCmpData != memref)

         atomicCmpData = maybeCmpData;

     }


     Type llvmWantedDataType = this->typeConverter->convertType(wantedDataType);


     Type i32 = rewriter.getI32Type();


     // Get the type size in bytes.

     DataLayout dataLayout = DataLayout::closest(gpuOp);

     int64_t elementByteWidth =

         dataLayout.getTypeSizeInBits(memrefType.getElementType()) / 8;

     Value byteWidthConst = createI32Constant(rewriter, loc, elementByteWidth);


     // If we want to load a vector<NxT> with total size <= 32

     // bits, use a scalar load and bitcast it. Similarly, if bitsize(T) < 32

     // and the total load size is >= 32, use a vector load of N / (bitsize(T) /

     // 32) x i32 and bitcast. Also, the CAS intrinsic requires integer operands,

     // so bitcast any floats to integers.

     Type llvmBufferValType = llvmWantedDataType;

     if (atomicCmpData) {

       if (auto floatType = dyn_cast<FloatType>(wantedDataType))

         llvmBufferValType = this->getTypeConverter()->convertType(

             rewriter.getIntegerType(floatType.getWidth()));

     }

     if (auto dataVector = dyn_cast<VectorType>(wantedDataType)) {

       uint32_t vecLen = dataVector.getNumElements();

       uint32_t elemBits =

           dataLayout.getTypeSizeInBits(dataVector.getElementType());

       uint32_t totalBits = elemBits * vecLen;

       bool usePackedFp16 =

           isa_and_present<RawBufferAtomicFaddOp>(*gpuOp) && vecLen == 2;

       if (totalBits > maxVectorOpWidth)

         return gpuOp.emitOpError(

             "Total width of loads or stores must be no more than " +

             Twine(maxVectorOpWidth) + " bits, but we call for " +

             Twine(totalBits) +

             " bits. This should've been caught in validation");

       if (!usePackedFp16 && elemBits < 32) {

         if (totalBits > 32) {

           if (totalBits % 32 != 0)

             return gpuOp.emitOpError("Load or store of more than 32-bits that "

                                      "doesn't fit into words. Can't happen\n");

           llvmBufferValType = this->typeConverter->convertType(

               VectorType::get(totalBits / 32, i32));

         } else {

           llvmBufferValType = this->typeConverter->convertType(

               rewriter.getIntegerType(totalBits));

         }

       }

     }

     if (auto vecType = dyn_cast<VectorType>(llvmBufferValType)) {

       // Buffer intrinsics doesn't support 1-element vectors, cast them to

       // scalars.

       if (vecType.getNumElements() == 1)

         llvmBufferValType = vecType.getElementType();

     }


     SmallVector<Value, 6> args;

     if (storeData) {

       if (llvmBufferValType != llvmWantedDataType) {

         Value castForStore = LLVM::BitcastOp::create(

             rewriter, loc, llvmBufferValType, storeData);

         args.push_back(castForStore);

       } else {

         args.push_back(storeData);

       }

     }


     if (atomicCmpData) {

       if (llvmBufferValType != llvmWantedDataType) {

         Value castForCmp = LLVM::BitcastOp::create(

             rewriter, loc, llvmBufferValType, atomicCmpData);

         args.push_back(castForCmp);

       } else {

         args.push_back(atomicCmpData);

       }

     }


     // Construct buffer descriptor from memref, attributes

     int64_t offset = 0;

     SmallVector<int64_t, 5> strides;

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

       return gpuOp.emitOpError("Can't lower non-stride-offset memrefs");


     MemRefDescriptor memrefDescriptor(memref);


     Value ptr = memrefDescriptor.bufferPtr(

         rewriter, loc, *this->getTypeConverter(), memrefType);

     Value numRecords = getNumRecords(

         rewriter, loc, memrefType, memrefDescriptor, strides, elementByteWidth);

     Value resource = makeBufferRsrc(rewriter, loc, ptr, numRecords,

                                     adaptor.getBoundsCheck(), chipset);

     args.push_back(resource);


     // Indexing (voffset)

     Value voffset = getLinearIndexI32(rewriter, loc, memrefDescriptor,

                                       adaptor.getIndices(), strides);

     if (std::optional<int32_t> indexOffset = adaptor.getIndexOffset();

         indexOffset && *indexOffset > 0) {

       Value extraOffsetConst = createI32Constant(rewriter, loc, *indexOffset);

       voffset = voffset ? LLVM::AddOp::create(rewriter, loc, voffset,

                                               extraOffsetConst)

                         : extraOffsetConst;

     }

     voffset = LLVM::MulOp::create(rewriter, loc, voffset, byteWidthConst);

     args.push_back(voffset);


     // SGPR offset.

     Value sgprOffset = adaptor.getSgprOffset();

     if (!sgprOffset)

       sgprOffset = createI32Constant(rewriter, loc, 0);

     sgprOffset = LLVM::MulOp::create(rewriter, loc, sgprOffset, byteWidthConst);

     args.push_back(sgprOffset);


     // bit 0: GLC = 0 (atomics drop value, less coherency)

     // bits 1-2: SLC, DLC = 0 (similarly)

     // bit 3: swizzled (0 for raw)

     args.push_back(createI32Constant(rewriter, loc, 0));


     llvm::SmallVector<Type, 1> resultTypes(gpuOp->getNumResults(),

                                            llvmBufferValType);

     Operation *lowered = Intrinsic::create(rewriter, loc, resultTypes, args,

                                            ArrayRef<NamedAttribute>());

     if (lowered->getNumResults() == 1) {

       Value replacement = lowered->getResult(0);

       if (llvmBufferValType != llvmWantedDataType) {

         replacement = LLVM::BitcastOp::create(rewriter, loc, llvmWantedDataType,

                                               replacement);

       }

       rewriter.replaceOp(gpuOp, replacement);

     } else {

       rewriter.eraseOp(gpuOp);

     }

     return success();

   }

 };


 // TODO: AMDGPU backend already have all this bitpacking logic, we should move

 // it to some common place.

 ///  Vmcnt, Expcnt and Lgkmcnt are decoded as follows:

 ///     Vmcnt = Waitcnt[3:0]        (pre-gfx9)

 ///     Vmcnt = Waitcnt[15:14,3:0]  (gfx9,10)

 ///     Vmcnt = Waitcnt[15:10]      (gfx11)

 ///     Expcnt = Waitcnt[6:4]       (pre-gfx11)

 ///     Expcnt = Waitcnt[2:0]       (gfx11)

 ///     Lgkmcnt = Waitcnt[11:8]     (pre-gfx10)

 ///     Lgkmcnt = Waitcnt[13:8]     (gfx10)

 ///     Lgkmcnt = Waitcnt[9:4]      (gfx11)

 static FailureOr<unsigned> encodeWaitcnt(Chipset chipset, unsigned vmcnt,

                                          unsigned expcnt, unsigned lgkmcnt) {

   if (chipset.majorVersion < 9) {

     vmcnt = std::min(15u, vmcnt);

     expcnt = std::min(7u, expcnt);

     lgkmcnt = std::min(15u, lgkmcnt);

     return vmcnt | (expcnt << 4) | (lgkmcnt << 8);

   }

   if (chipset.majorVersion == 9) {

     vmcnt = std::min(63u, vmcnt);

     expcnt = std::min(7u, expcnt);

     lgkmcnt = std::min(15u, lgkmcnt);

     unsigned lowBits = vmcnt & 0xF;

     unsigned highBits = (vmcnt >> 4) << 14;

     unsigned otherCnts = (expcnt << 4) | (lgkmcnt << 8);

     return lowBits | highBits | otherCnts;

   }

   if (chipset.majorVersion == 10) {

     vmcnt = std::min(63u, vmcnt);

     expcnt = std::min(7u, expcnt);

     lgkmcnt = std::min(63u, lgkmcnt);

     unsigned lowBits = vmcnt & 0xF;

     unsigned highBits = (vmcnt >> 4) << 14;

     unsigned otherCnts = (expcnt << 4) | (lgkmcnt << 8);

     return lowBits | highBits | otherCnts;

   }

   if (chipset.majorVersion == 11) {

     vmcnt = std::min(63u, vmcnt);

     expcnt = std::min(7u, expcnt);

     lgkmcnt = std::min(63u, lgkmcnt);

     return (vmcnt << 10) | expcnt | (lgkmcnt << 4);

   }

   return failure();

 }


 struct MemoryCounterWaitOpLowering

     : public ConvertOpToLLVMPattern<MemoryCounterWaitOp> {

   MemoryCounterWaitOpLowering(const LLVMTypeConverter &converter,

                               Chipset chipset)

       : ConvertOpToLLVMPattern<MemoryCounterWaitOp>(converter),

         chipset(chipset) {}


   Chipset chipset;


   LogicalResult

   matchAndRewrite(MemoryCounterWaitOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     if (chipset.majorVersion >= 12) {

       Location loc = op.getLoc();

       if (std::optional<int> ds = adaptor.getDs())

         ROCDL::WaitDscntOp::create(rewriter, loc, *ds);


       if (std::optional<int> load = adaptor.getLoad())

         ROCDL::WaitLoadcntOp::create(rewriter, loc, *load);


       if (std::optional<int> store = adaptor.getStore())

         ROCDL::WaitStorecntOp::create(rewriter, loc, *store);


       if (std::optional<int> exp = adaptor.getExp())

         ROCDL::WaitExpcntOp::create(rewriter, loc, *exp);


       rewriter.eraseOp(op);

       return success();

     }


     auto getVal = [](Attribute attr) -> unsigned {

       if (attr)

         return cast<IntegerAttr>(attr).getInt();


       // This value will be clamped to the maximum value for the chipset.

       return 1024;

     };

     unsigned ds = getVal(adaptor.getDsAttr());

     unsigned exp = getVal(adaptor.getExpAttr());


     unsigned vmcnt = 1024;

     Attribute load = adaptor.getLoadAttr();

     Attribute store = adaptor.getStoreAttr();

     if (load && store) {

       vmcnt = getVal(load) + getVal(store);

     } else if (load) {

       vmcnt = getVal(load);

     } else if (store) {

       vmcnt = getVal(store);

     }


     FailureOr<unsigned> waitcnt = encodeWaitcnt(chipset, vmcnt, exp, ds);

     if (failed(waitcnt))

       return op.emitOpError("unsupported chipset");


     rewriter.replaceOpWithNewOp<ROCDL::SWaitcntOp>(op, *waitcnt);

     return success();

   }

 };


 struct LDSBarrierOpLowering : public ConvertOpToLLVMPattern<LDSBarrierOp> {

   LDSBarrierOpLowering(const LLVMTypeConverter &converter, Chipset chipset)

       : ConvertOpToLLVMPattern<LDSBarrierOp>(converter), chipset(chipset) {}


   Chipset chipset;


   LogicalResult

   matchAndRewrite(LDSBarrierOp op, LDSBarrierOp::Adaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     bool requiresInlineAsm = chipset < kGfx90a || chipset.majorVersion == 11;


     if (requiresInlineAsm) {

       auto asmDialectAttr = LLVM::AsmDialectAttr::get(rewriter.getContext(),

                                                       LLVM::AsmDialect::AD_ATT);

       const char *asmStr =

           ";;;WARNING: BREAKS DEBUG WATCHES\ns_waitcnt lgkmcnt(0)\ns_barrier";

       const char *constraints = "";

       rewriter.replaceOpWithNewOp<LLVM::InlineAsmOp>(

           op,

           /*resultTypes=*/TypeRange(), /*operands=*/ValueRange(),

           /*asm_string=*/asmStr, constraints, /*has_side_effects=*/true,

           /*is_align_stack=*/false, LLVM::TailCallKind::None,

           /*asm_dialect=*/asmDialectAttr,

           /*operand_attrs=*/ArrayAttr());

       return success();

     }

     if (chipset.majorVersion < 12) {

       constexpr int32_t ldsOnlyBitsGfx6789 = ~(0x1f << 8);

       constexpr int32_t ldsOnlyBitsGfx10 = ~(0x3f << 8);

       // Left in place in case someone disables the inline ASM path or future

       // chipsets use the same bit pattern.

       constexpr int32_t ldsOnlyBitsGfx11 = ~(0x3f << 4);


       int32_t ldsOnlyBits;

       if (chipset.majorVersion == 11)

         ldsOnlyBits = ldsOnlyBitsGfx11;

       else if (chipset.majorVersion == 10)

         ldsOnlyBits = ldsOnlyBitsGfx10;

       else if (chipset.majorVersion <= 9)

         ldsOnlyBits = ldsOnlyBitsGfx6789;

       else

         return op.emitOpError(

                    "don't know how to lower this for chipset major version")

                << chipset.majorVersion;


       Location loc = op->getLoc();

       ROCDL::SWaitcntOp::create(rewriter, loc, ldsOnlyBits);

       rewriter.replaceOpWithNewOp<ROCDL::SBarrierOp>(op);

     } else {

       Location loc = op->getLoc();

       ROCDL::WaitDscntOp::create(rewriter, loc, 0);

       ROCDL::BarrierSignalOp::create(rewriter, loc, -1);

       rewriter.replaceOpWithNewOp<ROCDL::BarrierWaitOp>(op, -1);

     }


     return success();

   }

 };


 struct SchedBarrierOpLowering : public ConvertOpToLLVMPattern<SchedBarrierOp> {

   SchedBarrierOpLowering(const LLVMTypeConverter &converter, Chipset chipset)

       : ConvertOpToLLVMPattern<SchedBarrierOp>(converter), chipset(chipset) {}


   Chipset chipset;


   LogicalResult

   matchAndRewrite(SchedBarrierOp op, SchedBarrierOp::Adaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     rewriter.replaceOpWithNewOp<ROCDL::SchedBarrier>(op,

                                                      (uint32_t)op.getOpts());

     return success();

   }

 };


 } // namespace


 /// Converts a MFMA vector operand from MLIR AMDGPU dialect convention to ROCDL

 /// and LLVM AMDGPU intrinsics convention.

 ///

 /// Specifically:

 /// 1. If the element type is bfloat16, bitcast it to i16 unless rocdl intrinsic

 /// allows bf16. Newer MFMAs support bf16 types on operand, check

 /// IntrinsicsAMDGPU.td file for reference.

 /// 2. If instead we have a more than 64-bit quantity, use a <N / 4 x i32>

 /// instead, which is what the f8f6f4 intrinsics use.

 /// 3. If `input` is a vector of N <= 8 bytes, bitcast it to a (N * 8)-bit

 /// integer.

 ///

 /// Note that the type of `input` has already been LLVM type converted:

 /// therefore 8-bit and smaller floats are represented as their corresponding

 /// `iN` integers.

 static Value convertMFMAVectorOperand(ConversionPatternRewriter &rewriter,

                                       Location loc, Value input,

                                       bool allowBf16 = true) {

   Type inputType = input.getType();

   if (auto vectorType = dyn_cast<VectorType>(inputType)) {

     if (vectorType.getElementType().isBF16() && !allowBf16)

       return LLVM::BitcastOp::create(

           rewriter, loc, vectorType.clone(rewriter.getI16Type()), input);

     if (vectorType.getElementType().isInteger(8) &&

         vectorType.getNumElements() <= 8)

       return LLVM::BitcastOp::create(

           rewriter, loc,

           rewriter.getIntegerType(vectorType.getNumElements() * 8), input);

     if (isa<IntegerType>(vectorType.getElementType()) &&

         vectorType.getElementTypeBitWidth() <= 8) {

       int64_t numWords = llvm::divideCeil(

           vectorType.getNumElements() * vectorType.getElementTypeBitWidth(),

           32);

       return LLVM::BitcastOp::create(

           rewriter, loc, VectorType::get(numWords, rewriter.getI32Type()),

           input);

     }

   }

   return input;

 }


 /// Converts the scaled MFMA operands, `scalesA` and `scalesB`, from MLIR AMDGPU

 /// dialect convention to ROCDL and LLVM AMDGPU intrinsics convention.

 ///

 /// Specifically:

 /// 1. If `input` is a i8 value, zero extend it to i32

 /// 2. If `input` is a vector of length 4 and type i8, cast it to i32

 ///

 /// Note that the type of `input` has already been LLVM type converted:

 /// therefore 8-bit and smaller floats are represented as their corresponding

 /// `iN` integers.

 static Value castMFMAScaleOperand(ConversionPatternRewriter &rewriter,

                                   Location loc, Value input) {

   Type inputType = input.getType();

   Type outputType = rewriter.getI32Type();

   if (auto intType = dyn_cast<IntegerType>(inputType))

     return LLVM::ZExtOp::create(rewriter, loc, outputType, input);

   return LLVM::BitcastOp::create(rewriter, loc, outputType, input);

 }


 /// Push an input operand. If it is a float type, nothing to do. If it is

 /// an integer type, then we need to also push its signdness (1 for signed, 0

 /// for unsigned) and we need to pack the input 16xi8 vector into a 4xi32

 /// vector (or the 8xi8 vector into a 2xi32 one for gfx12+).

 /// We also need to convert bfloat inputs to i16 to account for the bfloat

 /// intrinsics having been defined before the AMD backend supported bfloat. We

 /// similarly need to pack 8-bit float types into integers as if they were i8

 /// (which they are for the backend's purposes).

 static void wmmaPushInputOperand(ConversionPatternRewriter &rewriter,

                                  Location loc,

                                  const TypeConverter *typeConverter,

                                  bool isUnsigned, Value llvmInput,

                                  Value mlirInput,

                                  SmallVector<Value, 4> &operands) {

   Type inputType = llvmInput.getType();

   auto vectorType = dyn_cast<VectorType>(inputType);

   if (!vectorType) {

     operands.push_back(llvmInput);

     return;

   }

   Type elemType = vectorType.getElementType();


   if (elemType.isBF16())

     llvmInput = LLVM::BitcastOp::create(

         rewriter, loc, vectorType.clone(rewriter.getI16Type()), llvmInput);

   if (elemType.getIntOrFloatBitWidth() > 8) {

     operands.push_back(llvmInput);

     return;

   }


   // We need to check the type of the input before conversion to properly test

   // for int8. This is because, in LLVM, fp8 type is converted to int8, so the

   // fp8/int8 information is lost during the conversion process.

   auto mlirInputType = cast<VectorType>(mlirInput.getType());

   bool isInputInteger = mlirInputType.getElementType().isInteger();

   if (isInputInteger) {

     // if element type is 8-bit signed or unsigned, ignore the isUnsigned flag

     bool localIsUnsigned = isUnsigned;

     if (elemType.isUnsignedInteger()) {

       localIsUnsigned = true;

     } else if (elemType.isSignedInteger()) {

       localIsUnsigned = false;

     }

     Value sign = createI1Constant(rewriter, loc, !localIsUnsigned);

     operands.push_back(sign);

   }


   int64_t numBits =

       vectorType.getNumElements() * elemType.getIntOrFloatBitWidth();

   Type i32 = rewriter.getI32Type();

   Type intrinsicInType = numBits <= 32

                              ? (Type)rewriter.getIntegerType(numBits)

                              : (Type)VectorType::get(numBits / 32, i32);

   auto llvmIntrinsicInType = typeConverter->convertType(intrinsicInType);

   Value castInput = rewriter.createOrFold<LLVM::BitcastOp>(

       loc, llvmIntrinsicInType, llvmInput);

   // The wave64-mode 16x16x16 intrinsics that take 4-bit integers only need

   // (256 / 64) * 4 = 16 bits of input (on gfx12+) but take i32 arguments.

   // Add in the zeros here.

   if (numBits < 32)

     castInput = LLVM::ZExtOp::create(rewriter, loc, i32, castInput);

   operands.push_back(castInput);

 }


 /// Push the output operand. For many cases this is only pushing the output in

 /// the operand list. But when we have f16 -> f16 or bf16 -> bf16 intrinsics,

 /// since the same numbers of VGPRs is used, we need to decide if to store the

 /// result in the upper 16 bits of the VGPRs or in the lower part. To store the

 /// result in the lower 16 bits, set subwordOffset to 1, otherwise result will

 /// be stored it in the upper part. The subwordOffset must not be set for gfx12,

 /// as the instructions have been changed to return fewer registers instead.

 static void wmmaPushOutputOperand(ConversionPatternRewriter &rewriter,

                                   Location loc,

                                   const TypeConverter *typeConverter,

                                   Value output, int32_t subwordOffset,

                                   bool clamp, SmallVector<Value, 4> &operands) {

   Type inputType = output.getType();

   auto vectorType = dyn_cast<VectorType>(inputType);

   Type elemType = vectorType.getElementType();

   if (elemType.isBF16())

     output = LLVM::BitcastOp::create(

         rewriter, loc, vectorType.clone(rewriter.getI16Type()), output);

   operands.push_back(output);

   if (elemType.isF16() || elemType.isBF16() || elemType.isInteger(16)) {

     operands.push_back(createI1Constant(rewriter, loc, subwordOffset));

   } else if (elemType.isInteger(32)) {

     operands.push_back(createI1Constant(rewriter, loc, clamp));

   }

 }


 /// Return true if `type` is the E5M2 variant of an 8-bit float that is

 /// supported by the `_bf8` instructions on the given `chipset`.

 static bool typeIsExpectedBf8ForChipset(Chipset chipset, Type type) {

   return (chipset == kGfx942 && isa<Float8E5M2FNUZType>(type)) ||

          (hasOcpFp8(chipset) && isa<Float8E5M2Type>(type));

 }


 /// Return true if `type` is the E4M3FN variant of an 8-bit float that is

 /// supported by the `_fp8` instructions on the given `chipset`.

 static bool typeIsExpectedFp8ForChipset(Chipset chipset, Type type) {

   return (chipset == kGfx942 && isa<Float8E4M3FNUZType>(type)) ||

          (hasOcpFp8(chipset) && isa<Float8E4M3FNType>(type));

 }


 /// Return the `rocdl` intrinsic corresponding to a MFMA operation `mfma`

 /// if one exists. This includes checking to ensure the intrinsic is supported

 /// on the architecture you are compiling for.

 static std::optional<StringRef> mfmaOpToIntrinsic(MFMAOp mfma,

                                                   Chipset chipset) {

   uint32_t m = mfma.getM(), n = mfma.getN(), k = mfma.getK(),

            b = mfma.getBlocks();

   Type sourceElem = getElementTypeOrSelf(mfma.getSourceA().getType());

   Type destElem = getElementTypeOrSelf(mfma.getDestC().getType());


   if (sourceElem.isF32() && destElem.isF32()) {

     if (mfma.getReducePrecision() && chipset >= kGfx942) {

       if (m == 32 && n == 32 && k == 4 && b == 1)

         return ROCDL::mfma_f32_32x32x4_xf32::getOperationName();

       if (m == 16 && n == 16 && k == 8 && b == 1)

         return ROCDL::mfma_f32_16x16x8_xf32::getOperationName();

     }

     if (m == 32 && n == 32 && k == 1 && b == 2)

       return ROCDL::mfma_f32_32x32x1f32::getOperationName();

     if (m == 16 && n == 16 && k == 1 && b == 4)

       return ROCDL::mfma_f32_16x16x1f32::getOperationName();

     if (m == 4 && n == 4 && k == 1 && b == 16)

       return ROCDL::mfma_f32_4x4x1f32::getOperationName();

     if (m == 32 && n == 32 && k == 2 && b == 1)

       return ROCDL::mfma_f32_32x32x2f32::getOperationName();

     if (m == 16 && n == 16 && k == 4 && b == 1)

       return ROCDL::mfma_f32_16x16x4f32::getOperationName();

   }


   if (sourceElem.isF16() && destElem.isF32()) {

     if (chipset >= kGfx950) {

       if (m == 32 && n == 32 && k == 16 && b == 1)

         return ROCDL::mfma_f32_32x32x16_f16::getOperationName();

       if (m == 16 && n == 16 && k == 32 && b == 1)

         return ROCDL::mfma_f32_16x16x32_f16::getOperationName();

     }

     if (m == 32 && n == 32 && k == 4 && b == 2)

       return ROCDL::mfma_f32_32x32x4f16::getOperationName();

     if (m == 16 && n == 16 && k == 4 && b == 4)

       return ROCDL::mfma_f32_16x16x4f16::getOperationName();

     if (m == 4 && n == 4 && k == 4 && b == 16)

       return ROCDL::mfma_f32_4x4x4f16::getOperationName();

     if (m == 32 && n == 32 && k == 8 && b == 1)

       return ROCDL::mfma_f32_32x32x8f16::getOperationName();

     if (m == 16 && n == 16 && k == 16 && b == 1)

       return ROCDL::mfma_f32_16x16x16f16::getOperationName();

   }


   if (sourceElem.isBF16() && destElem.isF32()) {

     if (chipset >= kGfx950) {

       if (m == 32 && n == 32 && k == 16 && b == 1)

         return ROCDL::mfma_f32_32x32x16_bf16::getOperationName();

       if (m == 16 && n == 16 && k == 32 && b == 1)

         return ROCDL::mfma_f32_16x16x32_bf16::getOperationName();

     }

     if (chipset >= kGfx90a) {

       if (m == 32 && n == 32 && k == 4 && b == 2)

         return ROCDL::mfma_f32_32x32x4bf16_1k::getOperationName();

       if (m == 16 && n == 16 && k == 4 && b == 4)

         return ROCDL::mfma_f32_16x16x4bf16_1k::getOperationName();

       if (m == 4 && n == 4 && k == 4 && b == 16)

         return ROCDL::mfma_f32_4x4x4bf16_1k::getOperationName();

       if (m == 32 && n == 32 && k == 8 && b == 1)

         return ROCDL::mfma_f32_32x32x8bf16_1k::getOperationName();

       if (m == 16 && n == 16 && k == 16 && b == 1)

         return ROCDL::mfma_f32_16x16x16bf16_1k::getOperationName();

     }

     if (m == 32 && n == 32 && k == 2 && b == 2)

       return ROCDL::mfma_f32_32x32x2bf16::getOperationName();

     if (m == 16 && n == 16 && k == 2 && b == 4)

       return ROCDL::mfma_f32_16x16x2bf16::getOperationName();

     if (m == 4 && n == 4 && k == 2 && b == 16)

       return ROCDL::mfma_f32_4x4x2bf16::getOperationName();

     if (m == 32 && n == 32 && k == 4 && b == 1)

       return ROCDL::mfma_f32_32x32x4bf16::getOperationName();

     if (m == 16 && n == 16 && k == 8 && b == 1)

       return ROCDL::mfma_f32_16x16x8bf16::getOperationName();

   }


   if (sourceElem.isInteger(8) && destElem.isInteger(32)) {

     if (chipset >= kGfx950) {

       if (m == 32 && n == 32 && k == 32 && b == 1)

         return ROCDL::mfma_i32_32x32x32_i8::getOperationName();

       if (m == 16 && n == 16 && k == 64 && b == 1)

         return ROCDL::mfma_i32_16x16x64_i8::getOperationName();

     }

     if (m == 32 && n == 32 && k == 4 && b == 2)

       return ROCDL::mfma_i32_32x32x4i8::getOperationName();

     if (m == 16 && n == 16 && k == 4 && b == 4)

       return ROCDL::mfma_i32_16x16x4i8::getOperationName();

     if (m == 4 && n == 4 && k == 4 && b == 16)

       return ROCDL::mfma_i32_4x4x4i8::getOperationName();

     if (m == 32 && n == 32 && k == 8 && b == 1)

       return ROCDL::mfma_i32_32x32x8i8::getOperationName();

     if (m == 16 && n == 16 && k == 16 && b == 1)

       return ROCDL::mfma_i32_16x16x16i8::getOperationName();

     if (m == 32 && n == 32 && k == 16 && b == 1 && chipset >= kGfx942)

       return ROCDL::mfma_i32_32x32x16_i8::getOperationName();

     if (m == 16 && n == 16 && k == 32 && b == 1 && chipset >= kGfx942)

       return ROCDL::mfma_i32_16x16x32_i8::getOperationName();

   }


   if (sourceElem.isF64() && destElem.isF64() && chipset >= kGfx90a) {

     if (m == 16 && n == 16 && k == 4 && b == 1)

       return ROCDL::mfma_f64_16x16x4f64::getOperationName();

     if (m == 4 && n == 4 && k == 4 && b == 4)

       return ROCDL::mfma_f64_4x4x4f64::getOperationName();

   }


   if (destElem.isF32() && typeIsExpectedBf8ForChipset(chipset, sourceElem)) {

     // Known to be correct because there are no scalar f8 instructions and

     // because a length mismatch will have been caught by the verifier.

     Type sourceBElem =

         cast<VectorType>(mfma.getSourceB().getType()).getElementType();

     if (m == 16 && n == 16 && k == 32 && b == 1) {

       if (typeIsExpectedBf8ForChipset(chipset, sourceBElem))

         return ROCDL::mfma_f32_16x16x32_bf8_bf8::getOperationName();

       if (typeIsExpectedFp8ForChipset(chipset, sourceBElem))

         return ROCDL::mfma_f32_16x16x32_bf8_fp8::getOperationName();

     }

     if (m == 32 && n == 32 && k == 16 && b == 1) {

       if (typeIsExpectedBf8ForChipset(chipset, sourceBElem))

         return ROCDL::mfma_f32_32x32x16_bf8_bf8::getOperationName();

       if (typeIsExpectedFp8ForChipset(chipset, sourceBElem))

         return ROCDL::mfma_f32_32x32x16_bf8_fp8::getOperationName();

     }

   }


   if (destElem.isF32() && typeIsExpectedFp8ForChipset(chipset, sourceElem)) {

     Type sourceBElem =

         cast<VectorType>(mfma.getSourceB().getType()).getElementType();

     if (m == 16 && n == 16 && k == 32 && b == 1) {

       if (typeIsExpectedBf8ForChipset(chipset, sourceBElem))

         return ROCDL::mfma_f32_16x16x32_fp8_bf8::getOperationName();

       if (typeIsExpectedFp8ForChipset(chipset, sourceBElem))

         return ROCDL::mfma_f32_16x16x32_fp8_fp8::getOperationName();

     }

     if (m == 32 && n == 32 && k == 16 && b == 1) {

       if (typeIsExpectedBf8ForChipset(chipset, sourceBElem))

         return ROCDL::mfma_f32_32x32x16_fp8_bf8::getOperationName();

       if (typeIsExpectedFp8ForChipset(chipset, sourceBElem))

         return ROCDL::mfma_f32_32x32x16_fp8_fp8::getOperationName();

     }

   }


   return std::nullopt;

 }


 static std::optional<uint32_t> mfmaTypeSelectCode(Type mlirElemType) {

   return llvm::TypeSwitch<Type, std::optional<uint32_t>>(mlirElemType)

       .Case([](Float8E4M3FNType) { return 0u; })

       .Case([](Float8E5M2Type) { return 1u; })

       .Case([](Float6E2M3FNType) { return 2u; })

       .Case([](Float6E3M2FNType) { return 3u; })

       .Case([](Float4E2M1FNType) { return 4u; })

       .Default([](Type) { return std::nullopt; });

 }


 /// If there is a scaled MFMA instruction for the input element types `aType`

 /// and `bType`, output type `destType`, problem size M, N, K, and B (number of

 /// blocks) on the given `chipset`, return a tuple consisting of the

 /// OperationName of the intrinsic and the type codes that need to be passed to

 /// that intrinsic. Note that this is also used to implement some un-scaled

 /// MFMAs, since the compiler represents the ordinary instruction as a "scaled"

 /// MFMA with a scale of 0.

 static std::optional<std::tuple<StringRef, uint32_t, uint32_t>>

 mfmaOpToScaledIntrinsic(Type aType, Type bType, Type destType, uint32_t m,

                         uint32_t n, uint32_t k, uint32_t b, Chipset chipset) {

   aType = getElementTypeOrSelf(aType);

   bType = getElementTypeOrSelf(bType);

   destType = getElementTypeOrSelf(destType);


   if (chipset < kGfx950)

     return std::nullopt;

   if (!isa<Float32Type>(destType))

     return std::nullopt;


   std::optional<uint32_t> aTypeCode = mfmaTypeSelectCode(aType);

   std::optional<uint32_t> bTypeCode = mfmaTypeSelectCode(bType);

   if (!aTypeCode || !bTypeCode)

     return std::nullopt;


   if (m == 32 && n == 32 && k == 64 && b == 1)

     return std::tuple{ROCDL::mfma_scale_f32_32x32x64_f8f6f4::getOperationName(),

                       *aTypeCode, *bTypeCode};

   if (m == 16 && n == 16 && k == 128 && b == 1)

     return std::tuple{

         ROCDL::mfma_scale_f32_16x16x128_f8f6f4::getOperationName(), *aTypeCode,

         *bTypeCode};


   return std::nullopt;

 }


 static std::optional<std::tuple<StringRef, uint32_t, uint32_t>>

 mfmaOpToScaledIntrinsic(MFMAOp mfma, Chipset chipset) {

   return mfmaOpToScaledIntrinsic(

       mfma.getSourceA().getType(), mfma.getSourceB().getType(),

       mfma.getDestC().getType(), mfma.getM(), mfma.getN(), mfma.getK(),

       mfma.getBlocks(), chipset);

 }


 static std::optional<std::tuple<StringRef, uint32_t, uint32_t>>

 mfmaOpToScaledIntrinsic(ScaledMFMAOp smfma, Chipset chipset) {

   return mfmaOpToScaledIntrinsic(smfma.getSourceA().getType(),

                                  smfma.getSourceB().getType(),

                                  smfma.getDestC().getType(), smfma.getM(),

                                  smfma.getN(), smfma.getK(), 1u, chipset);

 }


 /// Return the `rocdl` intrinsic corresponding to a WMMA operation `wmma`

 /// if one exists. This includes checking to ensure the intrinsic is supported

 /// on the architecture you are compiling for.

 static std::optional<StringRef> wmmaOpToIntrinsic(WMMAOp wmma,

                                                   Chipset chipset) {

   auto sourceVectorType = dyn_cast<VectorType>(wmma.getSourceA().getType());

   auto sourceBVectorType = dyn_cast<VectorType>(wmma.getSourceB().getType());

   auto destVectorType = dyn_cast<VectorType>(wmma.getDestC().getType());

   auto elemSourceType = sourceVectorType.getElementType();

   auto elemBSourceType = sourceBVectorType.getElementType();

   auto elemDestType = destVectorType.getElementType();


   if (elemSourceType.isF16() && elemDestType.isF32())

     return ROCDL::wmma_f32_16x16x16_f16::getOperationName();

   if (elemSourceType.isBF16() && elemDestType.isF32())

     return ROCDL::wmma_f32_16x16x16_bf16::getOperationName();

   if (elemSourceType.isF16() && elemDestType.isF16())

     return ROCDL::wmma_f16_16x16x16_f16::getOperationName();

   if (elemSourceType.isBF16() && elemDestType.isBF16())

     return ROCDL::wmma_bf16_16x16x16_bf16::getOperationName();

   if (elemSourceType.isInteger(8) && elemDestType.isInteger(32))

     return ROCDL::wmma_i32_16x16x16_iu8::getOperationName();

   if (chipset.majorVersion == 11) {

     if (elemSourceType.isInteger(4) && elemDestType.isInteger(32))

       return ROCDL::wmma_i32_16x16x16_iu4::getOperationName();

   }

   if (chipset.majorVersion >= 12) {

     if (isa<Float8E4M3FNType>(elemSourceType) &&

         isa<Float8E4M3FNType>(elemBSourceType) && elemDestType.isF32())

       return ROCDL::wmma_f32_16x16x16_fp8_fp8::getOperationName();

     if (isa<Float8E4M3FNType>(elemSourceType) &&

         isa<Float8E5M2Type>(elemBSourceType) && elemDestType.isF32())

       return ROCDL::wmma_f32_16x16x16_fp8_bf8::getOperationName();

     if (isa<Float8E5M2Type>(elemSourceType) &&

         isa<Float8E5M2Type>(elemBSourceType) && elemDestType.isF32())

       return ROCDL::wmma_f32_16x16x16_bf8_bf8::getOperationName();

     if (isa<Float8E5M2Type>(elemSourceType) &&

         isa<Float8E4M3FNType>(elemBSourceType) && elemDestType.isF32())

       return ROCDL::wmma_f32_16x16x16_bf8_fp8::getOperationName();

     if (elemSourceType.isInteger(4) && elemDestType.isInteger(32)) {

       bool isWave64 = destVectorType.getNumElements() == 4;

       // This is the ambiguous case. 8 inputs to the wave64 version means that

       // we want the 16x16x32 version, but for wave32 they mean the short form.

       bool has8Inputs = sourceVectorType.getNumElements() == 8;

       if ((isWave64 && has8Inputs) || (!isWave64 && !has8Inputs))

         return ROCDL::wmma_i32_16x16x32_iu4::getOperationName();

       return ROCDL::wmma_i32_16x16x16_iu4::getOperationName();

     }

   }

   return std::nullopt;

 }


 namespace {

 struct MFMAOpLowering : public ConvertOpToLLVMPattern<MFMAOp> {

   MFMAOpLowering(const LLVMTypeConverter &converter, Chipset chipset)

       : ConvertOpToLLVMPattern<MFMAOp>(converter), chipset(chipset) {}


   Chipset chipset;


   LogicalResult

   matchAndRewrite(MFMAOp op, MFMAOpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     Location loc = op.getLoc();

     Type outType = typeConverter->convertType(op.getDestD().getType());

     Type intrinsicOutType = outType;

     if (auto outVecType = dyn_cast<VectorType>(outType))

       if (outVecType.getElementType().isBF16())

         intrinsicOutType = outVecType.clone(rewriter.getI16Type());


     if (chipset.majorVersion != 9 || chipset < kGfx908)

       return op->emitOpError("MFMA only supported on gfx908+");

     uint32_t getBlgpField = static_cast<uint32_t>(op.getBlgp());

     if (op.getNegateA() || op.getNegateB() || op.getNegateC()) {

       if (chipset < kGfx942)

         return op.emitOpError("negation unsupported on older than gfx942");

       getBlgpField |=

           op.getNegateA() | (op.getNegateB() << 1) | (op.getNegateC() << 2);

     }

     std::optional<StringRef> maybeIntrinsic = mfmaOpToIntrinsic(op, chipset);

     std::optional<std::tuple<StringRef, uint32_t, uint32_t>>

         maybeScaledIntrinsic = mfmaOpToScaledIntrinsic(op, chipset);

     if (!maybeIntrinsic.has_value() && !maybeScaledIntrinsic.has_value())

       return op.emitOpError("no intrinsic matching MFMA size on given chipset");


     bool isScaled =

         !maybeIntrinsic.has_value() && maybeScaledIntrinsic.has_value();

     if (isScaled &&

         (adaptor.getAbid() > 0 || getBlgpField > 0 || op.getCbsz() > 0)) {

       return op.emitOpError(

           "non-default abid, blgp, and cbsz aren't supported on MFMAs that can "

           "be scaled as those fields are used for type information");

     }


     StringRef intrinsicName =

         isScaled ? std::get<0>(*maybeScaledIntrinsic) : *maybeIntrinsic;

     // Determine if we can use bf16 in the intrinsic. Newer MFMAs in gfx950+

     // allows bf16 as the input. For reference check IntrinsicsAMDGPU.td file.

     bool allowBf16 = [&]() {

       if (chipset < kGfx950)

         return false;

       if (isScaled)

         return true;

       return intrinsicName.contains("16x16x32.bf16") ||

              intrinsicName.contains("32x32x16.bf16");

     }();

     OperationState loweredOp(loc, intrinsicName);

     loweredOp.addTypes(intrinsicOutType);

     loweredOp.addOperands({convertMFMAVectorOperand(

                                rewriter, loc, adaptor.getSourceA(), allowBf16),

                            convertMFMAVectorOperand(

                                rewriter, loc, adaptor.getSourceB(), allowBf16),

                            adaptor.getDestC()});

     if (isScaled) {

       Value zero = createI32Constant(rewriter, loc, 0);

       auto [_scaledName, aTypeCode, bTypeCode] = *maybeScaledIntrinsic;

       loweredOp.addOperands({createI32Constant(rewriter, loc, aTypeCode),

                              createI32Constant(rewriter, loc, bTypeCode),

                              /*scale A byte=*/zero, /*scale A=*/zero,

                              /*scale B byte=*/zero, /*scale B=*/zero});

     } else {

       loweredOp.addOperands({createI32Constant(rewriter, loc, op.getCbsz()),

                              createI32Constant(rewriter, loc, op.getAbid()),

                              createI32Constant(rewriter, loc, getBlgpField)});

     };

     Value lowered = rewriter.create(loweredOp)->getResult(0);

     if (outType != intrinsicOutType)

       lowered = LLVM::BitcastOp::create(rewriter, loc, outType, lowered);

     rewriter.replaceOp(op, lowered);

     return success();

   }

 };


 struct ScaledMFMAOpLowering : public ConvertOpToLLVMPattern<ScaledMFMAOp> {

   ScaledMFMAOpLowering(const LLVMTypeConverter &converter, Chipset chipset)

       : ConvertOpToLLVMPattern(converter), chipset(chipset) {}


   Chipset chipset;


   LogicalResult

   matchAndRewrite(ScaledMFMAOp op, ScaledMFMAOpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     Location loc = op.getLoc();

     Type intrinsicOutType = typeConverter->convertType(op.getDestD().getType());


     if (chipset.majorVersion != 9 || chipset < kGfx950)

       return op->emitOpError("scaled MFMA only supported on gfx908+");

     std::optional<std::tuple<StringRef, uint32_t, uint32_t>>

         maybeScaledIntrinsic = mfmaOpToScaledIntrinsic(op, chipset);

     if (!maybeScaledIntrinsic.has_value())

       return op.emitOpError(

           "no intrinsic matching scaled MFMA size on given chipset");


     auto [intrinsicName, aTypeCode, bTypeCode] = *maybeScaledIntrinsic;

     OperationState loweredOp(loc, intrinsicName);

     loweredOp.addTypes(intrinsicOutType);

     loweredOp.addOperands(

         {convertMFMAVectorOperand(rewriter, loc, adaptor.getSourceA()),

          convertMFMAVectorOperand(rewriter, loc, adaptor.getSourceB()),

          adaptor.getDestC()});

     Value scalesIdxA =

         createI32Constant(rewriter, loc, adaptor.getScalesIdxA());

     Value scalesIdxB =

         createI32Constant(rewriter, loc, adaptor.getScalesIdxB());

     loweredOp.addOperands(

         {createI32Constant(rewriter, loc, aTypeCode),

          createI32Constant(rewriter, loc, bTypeCode),

          /*scales idx A=*/scalesIdxA,

          /*scales A*/

          castMFMAScaleOperand(rewriter, loc, adaptor.getScalesA()),

          /*scales idx B=*/scalesIdxB,

          /*scales B*/

          castMFMAScaleOperand(rewriter, loc, adaptor.getScalesB())});

     Value lowered = rewriter.create(loweredOp)->getResult(0);

     rewriter.replaceOp(op, lowered);

     return success();

   }

 };


 struct WMMAOpLowering : public ConvertOpToLLVMPattern<WMMAOp> {

   WMMAOpLowering(const LLVMTypeConverter &converter, Chipset chipset)

       : ConvertOpToLLVMPattern<WMMAOp>(converter), chipset(chipset) {}


   Chipset chipset;


   LogicalResult

   matchAndRewrite(WMMAOp op, WMMAOpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     Location loc = op.getLoc();

     auto outType =

         typeConverter->convertType<VectorType>(op.getDestD().getType());

     if (!outType)

       return rewriter.notifyMatchFailure(op, "type conversion failed");


     if (chipset.majorVersion != 11 && chipset.majorVersion != 12)

       return op->emitOpError("WMMA only supported on gfx11 and gfx12");


     // The WMMA operations represent vectors of bf16s as vectors of i16s, so we

     // need to bitcast bfloats to i16 and then bitcast them back.

     VectorType rawOutType = outType;

     if (outType.getElementType().isBF16())

       rawOutType = outType.clone(rewriter.getI16Type());


     std::optional<StringRef> maybeIntrinsic = wmmaOpToIntrinsic(op, chipset);


     if (!maybeIntrinsic.has_value())

       return op.emitOpError("no intrinsic matching WMMA on the given chipset");


     if (chipset.majorVersion >= 12 && op.getSubwordOffset() != 0)

       return op.emitOpError("subwordOffset not supported on gfx12+");


     OperationState loweredOp(loc, *maybeIntrinsic);

     loweredOp.addTypes(rawOutType);


     SmallVector<Value, 4> operands;

     wmmaPushInputOperand(rewriter, loc, typeConverter, op.getUnsignedA(),

                          adaptor.getSourceA(), op.getSourceA(), operands);

     wmmaPushInputOperand(rewriter, loc, typeConverter, op.getUnsignedB(),

                          adaptor.getSourceB(), op.getSourceB(), operands);

     wmmaPushOutputOperand(rewriter, loc, typeConverter, adaptor.getDestC(),

                           op.getSubwordOffset(), op.getClamp(), operands);


     loweredOp.addOperands(operands);

     Operation *lowered = rewriter.create(loweredOp);


     Operation *maybeCastBack = lowered;

     if (rawOutType != outType)

       maybeCastBack = LLVM::BitcastOp::create(rewriter, loc, outType,

                                               lowered->getResult(0));

     rewriter.replaceOp(op, maybeCastBack->getResults());


     return success();

   }

 };


 struct TransposeLoadOpLowering

     : public ConvertOpToLLVMPattern<TransposeLoadOp> {

   TransposeLoadOpLowering(const LLVMTypeConverter &converter, Chipset chipset)

       : ConvertOpToLLVMPattern<TransposeLoadOp>(converter), chipset(chipset) {}


   Chipset chipset;


   LogicalResult

   matchAndRewrite(TransposeLoadOp op, TransposeLoadOpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     if (chipset != kGfx950)

       return op.emitOpError("Non-gfx950 chipset not supported");


     Location loc = op.getLoc();

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


     // Elements in subbyte memrefs are stored non-contiguously,

     // reject if source is sub-byte memref. Use emulated memrefs instead.

     size_t srcElementSize =

         srcMemRefType.getElementType().getIntOrFloatBitWidth();

     if (srcElementSize < 8)

       return op.emitOpError("Expect source memref to have at least 8 bits "

                             "element size, got ")

              << srcElementSize;


     auto resultType = cast<VectorType>(op.getResult().getType());

     Value srcPtr =

         getStridedElementPtr(rewriter, loc, srcMemRefType, adaptor.getSrc(),

                              (adaptor.getSrcIndices()));


     size_t numElements = resultType.getNumElements();

     size_t elementTypeSize =

         resultType.getElementType().getIntOrFloatBitWidth();


     // ROCDL transpose load intrinsics return vectors of 32-bit integers, if

     // the element size is smaller than 16 bits.

     Type rocdlResultType = VectorType::get((numElements * elementTypeSize) / 32,

                                            rewriter.getIntegerType(32));

     Type llvmResultType = typeConverter->convertType(resultType);


     switch (elementTypeSize) {

     case 4: {

       assert(numElements == 16);

       auto rocdlOp = ROCDL::ds_read_tr4_b64::create(rewriter, loc,

                                                     rocdlResultType, srcPtr);

       rewriter.replaceOpWithNewOp<LLVM::BitcastOp>(op, llvmResultType, rocdlOp);

       break;

     }

     case 6: {

       assert(numElements == 16);

       auto rocdlOp = ROCDL::ds_read_tr6_b96::create(rewriter, loc,

                                                     rocdlResultType, srcPtr);

       rewriter.replaceOpWithNewOp<LLVM::BitcastOp>(op, llvmResultType, rocdlOp);

       break;

     }

     case 8: {

       assert(numElements == 8);

       auto rocdlOp = ROCDL::ds_read_tr8_b64::create(rewriter, loc,

                                                     rocdlResultType, srcPtr);

       rewriter.replaceOpWithNewOp<LLVM::BitcastOp>(op, llvmResultType, rocdlOp);

       break;

     }

     case 16: {

       assert(numElements == 4);

       rewriter.replaceOpWithNewOp<ROCDL::ds_read_tr16_b64>(op, llvmResultType,

                                                            srcPtr);

       break;

     }

     default:

       return op.emitOpError("Unsupported element size for transpose load");

     }

     return success();

   }

 };


 struct GatherToLDSOpLowering : public ConvertOpToLLVMPattern<GatherToLDSOp> {

   GatherToLDSOpLowering(const LLVMTypeConverter &converter, Chipset chipset)

       : ConvertOpToLLVMPattern<GatherToLDSOp>(converter), chipset(chipset) {}


   Chipset chipset;


   LogicalResult

   matchAndRewrite(GatherToLDSOp op, GatherToLDSOpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     if (chipset.majorVersion < 9 || chipset.majorVersion > 10)

       return op.emitOpError("pre-gfx9 and post-gfx10 not supported");


     Location loc = op.getLoc();


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

     auto dstMemRefType = cast<MemRefType>(op.getDst().getType());


     // TODO: instead of only transfering one element per thread, we could

     // augment it to transfer multiple elements per thread by issuing multiple

     // `global_load_lds` instructions.

     Type transferType = op.getTransferType();

     int loadWidth = [&]() -> int {

       if (auto transferVectorType = dyn_cast<VectorType>(transferType)) {

         return (transferVectorType.getNumElements() *

                 transferVectorType.getElementTypeBitWidth()) /

                8;

       }

       return transferType.getIntOrFloatBitWidth() / 8;

     }();


     // Currently only 1, 2, 4, 12 and 16 byte loads are supported.

     if (!llvm::is_contained({1, 2, 4, 12, 16}, loadWidth))

       return op.emitOpError("chipset unsupported element size");


     if (chipset != kGfx950 && llvm::is_contained({12, 16}, loadWidth))

       return op.emitOpError("Gather to LDS instructions with 12-byte and "

                             "16-byte load widths are only supported on gfx950");


     Value srcPtr =

         getStridedElementPtr(rewriter, loc, srcMemRefType, adaptor.getSrc(),

                              (adaptor.getSrcIndices()));

     Value dstPtr =

         getStridedElementPtr(rewriter, loc, dstMemRefType, adaptor.getDst(),

                              (adaptor.getDstIndices()));


     rewriter.replaceOpWithNewOp<ROCDL::LoadToLDSOp>(

         op, srcPtr, dstPtr, rewriter.getI32IntegerAttr(loadWidth),

         /*offset=*/rewriter.getI32IntegerAttr(0),

         /*aux=*/rewriter.getI32IntegerAttr(0), ArrayAttr{}, ArrayAttr{},

         ArrayAttr{});


     return success();

   }

 };


 namespace {

 struct ExtPackedFp8OpLowering final

     : public ConvertOpToLLVMPattern<ExtPackedFp8Op> {

   ExtPackedFp8OpLowering(const LLVMTypeConverter &converter, Chipset chipset)

       : ConvertOpToLLVMPattern<amdgpu::ExtPackedFp8Op>(converter),

         chipset(chipset) {}

   Chipset chipset;


   LogicalResult

   matchAndRewrite(ExtPackedFp8Op op, ExtPackedFp8OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override;

 };


 struct PackedTrunc2xFp8OpLowering final

     : public ConvertOpToLLVMPattern<PackedTrunc2xFp8Op> {

   PackedTrunc2xFp8OpLowering(const LLVMTypeConverter &converter,

                              Chipset chipset)

       : ConvertOpToLLVMPattern<amdgpu::PackedTrunc2xFp8Op>(converter),

         chipset(chipset) {}

   Chipset chipset;


   LogicalResult

   matchAndRewrite(PackedTrunc2xFp8Op op, PackedTrunc2xFp8OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override;

 };


 struct PackedStochRoundFp8OpLowering final

     : public ConvertOpToLLVMPattern<PackedStochRoundFp8Op> {

   PackedStochRoundFp8OpLowering(const LLVMTypeConverter &converter,

                                 Chipset chipset)

       : ConvertOpToLLVMPattern<amdgpu::PackedStochRoundFp8Op>(converter),

         chipset(chipset) {}

   Chipset chipset;


   LogicalResult

   matchAndRewrite(PackedStochRoundFp8Op op,

                   PackedStochRoundFp8OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override;

 };


 struct ScaledExtPackedOpLowering final

     : public ConvertOpToLLVMPattern<ScaledExtPackedOp> {

   ScaledExtPackedOpLowering(const LLVMTypeConverter &converter, Chipset chipset)

       : ConvertOpToLLVMPattern<amdgpu::ScaledExtPackedOp>(converter),

         chipset(chipset) {}

   Chipset chipset;


   LogicalResult

   matchAndRewrite(ScaledExtPackedOp op, ScaledExtPackedOpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override;

 };


 struct PackedScaledTruncOpLowering final

     : public ConvertOpToLLVMPattern<PackedScaledTruncOp> {

   PackedScaledTruncOpLowering(const LLVMTypeConverter &converter,

                               Chipset chipset)

       : ConvertOpToLLVMPattern<amdgpu::PackedScaledTruncOp>(converter),

         chipset(chipset) {}

   Chipset chipset;


   LogicalResult

   matchAndRewrite(PackedScaledTruncOp op, PackedScaledTruncOpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override;

 };


 } // end namespace


 LogicalResult ExtPackedFp8OpLowering::matchAndRewrite(

     ExtPackedFp8Op op, ExtPackedFp8OpAdaptor adaptor,

     ConversionPatternRewriter &rewriter) const {

   Location loc = op.getLoc();

   if (!(chipset == kGfx942 || hasOcpFp8(chipset)))

     return rewriter.notifyMatchFailure(

         loc, "Fp8 conversion instructions are not available on target "

              "architecture and their emulation is not implemented");

   Type v4i8 =

       getTypeConverter()->convertType(VectorType::get(4, rewriter.getI8Type()));

   Type i32 = getTypeConverter()->convertType(rewriter.getI32Type());

   Type f32 = getTypeConverter()->convertType(op.getResult().getType());


   Value source = adaptor.getSource();

   auto sourceVecType = dyn_cast<VectorType>(op.getSource().getType());

   auto resultVecType = dyn_cast<VectorType>(op.getResult().getType());

   Type sourceElemType = getElementTypeOrSelf(op.getSource());

   // Extend to a v4i8

   if (!sourceVecType || sourceVecType.getNumElements() < 4) {

     Value longVec = LLVM::UndefOp::create(rewriter, loc, v4i8);

     if (!sourceVecType) {

       longVec = LLVM::InsertElementOp::create(

           rewriter, loc, longVec, source, createI32Constant(rewriter, loc, 0));

     } else {

       for (int32_t i = 0, e = sourceVecType.getNumElements(); i < e; ++i) {

         Value idx = createI32Constant(rewriter, loc, i);

         Value elem = LLVM::ExtractElementOp::create(rewriter, loc, source, idx);

         longVec =

             LLVM::InsertElementOp::create(rewriter, loc, longVec, elem, idx);

       }

     }

     source = longVec;

   }

   Value i32Source = LLVM::BitcastOp::create(rewriter, loc, i32, source);

   if (resultVecType) {

     if (typeIsExpectedBf8ForChipset(chipset, sourceElemType)) {

       rewriter.replaceOpWithNewOp<ROCDL::CvtPkF32Bf8Op>(op, f32, i32Source,

                                                         op.getIndex());

     } else if (typeIsExpectedFp8ForChipset(chipset, sourceElemType)) {

       rewriter.replaceOpWithNewOp<ROCDL::CvtPkF32Fp8Op>(op, f32, i32Source,

                                                         op.getIndex());

     }

   } else {

     if (typeIsExpectedBf8ForChipset(chipset, sourceElemType)) {

       rewriter.replaceOpWithNewOp<ROCDL::CvtF32Bf8Op>(op, f32, i32Source,

                                                       op.getIndex());

     } else if (typeIsExpectedFp8ForChipset(chipset, sourceElemType)) {

       rewriter.replaceOpWithNewOp<ROCDL::CvtF32Fp8Op>(op, f32, i32Source,

                                                       op.getIndex());

     }

   }

   return success();

 }


 LogicalResult ScaledExtPackedOpLowering::matchAndRewrite(

     ScaledExtPackedOp op, ScaledExtPackedOpAdaptor adaptor,

     ConversionPatternRewriter &rewriter) const {

   Location loc = op.getLoc();

   if (chipset != kGfx950)

     return rewriter.notifyMatchFailure(

         loc, "Scaled fp conversion instructions are not available on target "

              "architecture and their emulation is not implemented");

   Type i32 = getTypeConverter()->convertType(rewriter.getI32Type());


   Value source = adaptor.getSource();

   Value scale = adaptor.getScale();


   VectorType sourceVecType = cast<VectorType>(op.getSource().getType());

   Type sourceElemType = sourceVecType.getElementType();

   VectorType destVecType = cast<VectorType>(op.getResult().getType());

   Type destElemType = destVecType.getElementType();


   VectorType packedVecType;

   if (isa<Float8E5M2Type, Float8E4M3FNType>(sourceElemType)) {

     VectorType v4i8 = VectorType::get(4, rewriter.getI8Type());

     packedVecType = cast<VectorType>(getTypeConverter()->convertType(v4i8));

   } else if (isa<Float4E2M1FNType>(sourceElemType)) {

     VectorType v8i4 = VectorType::get(8, rewriter.getI4Type());

     packedVecType = cast<VectorType>(getTypeConverter()->convertType(v8i4));

   } else {

     llvm_unreachable("invalid element type for scaled ext");

   }


   // Extend to a packedVectorType

   if (sourceVecType.getNumElements() < packedVecType.getNumElements()) {

     Value longVec = LLVM::ZeroOp::create(rewriter, loc, packedVecType);

     if (!sourceVecType) {

       longVec = LLVM::InsertElementOp::create(

           rewriter, loc, longVec, source, createI32Constant(rewriter, loc, 0));

     } else {

       for (int32_t i = 0, e = sourceVecType.getNumElements(); i < e; ++i) {

         Value idx = createI32Constant(rewriter, loc, i);

         Value elem = LLVM::ExtractElementOp::create(rewriter, loc, source, idx);

         longVec =

             LLVM::InsertElementOp::create(rewriter, loc, longVec, elem, idx);

       }

     }

     source = longVec;

   }

   Value i32Source = LLVM::BitcastOp::create(rewriter, loc, i32, source);


   if (isa<Float8E5M2Type>(sourceElemType) && destElemType.isF32())

     rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkF32Bf8Op>(

         op, destVecType, i32Source, scale, op.getIndex());

   else if (isa<Float8E5M2Type>(sourceElemType) && destElemType.isF16())

     rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkF16Bf8Op>(

         op, destVecType, i32Source, scale, op.getIndex());

   else if (isa<Float8E5M2Type>(sourceElemType) && destElemType.isBF16())

     rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkBf16Bf8Op>(

         op, destVecType, i32Source, scale, op.getIndex());

   else if (isa<Float8E4M3FNType>(sourceElemType) && destElemType.isF32())

     rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkF32Fp8Op>(

         op, destVecType, i32Source, scale, op.getIndex());

   else if (isa<Float8E4M3FNType>(sourceElemType) && destElemType.isF16())

     rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkF16Fp8Op>(

         op, destVecType, i32Source, scale, op.getIndex());

   else if (isa<Float8E4M3FNType>(sourceElemType) && destElemType.isBF16())

     rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkBf16Fp8Op>(

         op, destVecType, i32Source, scale, op.getIndex());

   else if (isa<Float4E2M1FNType>(sourceElemType) && destElemType.isF32())

     rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkF32Fp4Op>(

         op, destVecType, i32Source, scale, op.getIndex());

   else if (isa<Float4E2M1FNType>(sourceElemType) && destElemType.isF16())

     rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkF16Fp4Op>(

         op, destVecType, i32Source, scale, op.getIndex());

   else if (isa<Float4E2M1FNType>(sourceElemType) && destElemType.isBF16())

     rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkBf16Fp4Op>(

         op, destVecType, i32Source, scale, op.getIndex());

   else

     return failure();


   return success();

 }


 LogicalResult PackedScaledTruncOpLowering::matchAndRewrite(

     PackedScaledTruncOp op, PackedScaledTruncOpAdaptor adaptor,

     ConversionPatternRewriter &rewriter) const {

   Location loc = op.getLoc();

   if (chipset != kGfx950)

     return rewriter.notifyMatchFailure(

         loc, "Scaled fp conversion instructions are not available on target "

              "architecture and their emulation is not implemented");

   Type v2i16 = getTypeConverter()->convertType(

       VectorType::get(2, rewriter.getI16Type()));

   Type i32 = getTypeConverter()->convertType(rewriter.getI32Type());


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

   Type resultElemType = getElementTypeOrSelf(resultType);

   VectorType sourceVecType = cast<VectorType>(op.getSource().getType());

   Type sourceElemType = sourceVecType.getElementType();


   Type intResultType = isa<Float4E2M1FNType>(resultElemType) ? i32 : v2i16;


   Value source = adaptor.getSource();

   Value scale = adaptor.getScale();

   Value existing = adaptor.getExisting();

   if (existing)

     existing = LLVM::BitcastOp::create(rewriter, loc, intResultType, existing);

   else

     existing = LLVM::ZeroOp::create(rewriter, loc, intResultType);


   if (sourceVecType.getNumElements() < 2) {

     Value c0 = createI32Constant(rewriter, loc, 0);

     Value elem0 = LLVM::ExtractElementOp::create(rewriter, loc, source, c0);

     VectorType v2 = VectorType::get(2, sourceElemType);

     source = LLVM::ZeroOp::create(rewriter, loc, v2);

     source = LLVM::InsertElementOp::create(rewriter, loc, source, elem0, c0);

   }


   Value sourceA, sourceB;

   if (sourceElemType.isF32()) {

     Value c0 = createI32Constant(rewriter, loc, 0);

     Value c1 = createI32Constant(rewriter, loc, 1);

     sourceA = LLVM::ExtractElementOp::create(rewriter, loc, source, c0);

     sourceB = LLVM::ExtractElementOp::create(rewriter, loc, source, c1);

   }


   Value result;

   if (sourceElemType.isF32() && isa<Float8E5M2Type>(resultElemType))

     result = ROCDL::CvtScaleF32PkBf8F32Op::create(rewriter, loc, intResultType,

                                                   existing, sourceA, sourceB,

                                                   scale, op.getIndex());

   else if (sourceElemType.isF16() && isa<Float8E5M2Type>(resultElemType))

     result = ROCDL::CvtScaleF32PkBf8F16Op::create(

         rewriter, loc, intResultType, existing, source, scale, op.getIndex());

   else if (sourceElemType.isBF16() && isa<Float8E5M2Type>(resultElemType))

     result = ROCDL::CvtScaleF32PkBf8Bf16Op::create(

         rewriter, loc, intResultType, existing, source, scale, op.getIndex());

   else if (sourceElemType.isF32() && isa<Float8E4M3FNType>(resultElemType))

     result = ROCDL::CvtScaleF32PkFp8F32Op::create(rewriter, loc, intResultType,

                                                   existing, sourceA, sourceB,

                                                   scale, op.getIndex());

   else if (sourceElemType.isF16() && isa<Float8E4M3FNType>(resultElemType))

     result = ROCDL::CvtScaleF32PkFp8F16Op::create(

         rewriter, loc, intResultType, existing, source, scale, op.getIndex());

   else if (sourceElemType.isBF16() && isa<Float8E4M3FNType>(resultElemType))

     result = ROCDL::CvtScaleF32PkFp8Bf16Op::create(

         rewriter, loc, intResultType, existing, source, scale, op.getIndex());

   else if (sourceElemType.isF32() && isa<Float4E2M1FNType>(resultElemType))

     result = ROCDL::CvtScaleF32PkFp4F32Op::create(rewriter, loc, intResultType,

                                                   existing, sourceA, sourceB,

                                                   scale, op.getIndex());

   else if (sourceElemType.isF16() && isa<Float4E2M1FNType>(resultElemType))

     result = ROCDL::CvtScaleF32PkFp4F16Op::create(

         rewriter, loc, intResultType, existing, source, scale, op.getIndex());

   else if (sourceElemType.isBF16() && isa<Float4E2M1FNType>(resultElemType))

     result = ROCDL::CvtScaleF32PkFp4Bf16Op::create(

         rewriter, loc, intResultType, existing, source, scale, op.getIndex());

   else

     return failure();


   result = rewriter.replaceOpWithNewOp<LLVM::BitcastOp>(

       op, getTypeConverter()->convertType(resultType), result);

   return success();

 }


 LogicalResult PackedTrunc2xFp8OpLowering::matchAndRewrite(

     PackedTrunc2xFp8Op op, PackedTrunc2xFp8OpAdaptor adaptor,

     ConversionPatternRewriter &rewriter) const {

   Location loc = op.getLoc();

   if (!(chipset == kGfx942 || hasOcpFp8(chipset)))

     return rewriter.notifyMatchFailure(

         loc, "Fp8 conversion instructions are not available on target "

              "architecture and their emulation is not implemented");

   Type i32 = getTypeConverter()->convertType(rewriter.getI32Type());


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

   Type resultElemType = getElementTypeOrSelf(resultType);


   Value sourceA = adaptor.getSourceA();

   Value sourceB = adaptor.getSourceB();

   if (!sourceB)

     sourceB = LLVM::UndefOp::create(rewriter, loc, sourceA.getType());

   Value existing = adaptor.getExisting();

   if (existing)

     existing = LLVM::BitcastOp::create(rewriter, loc, i32, existing);

   else

     existing = LLVM::UndefOp::create(rewriter, loc, i32);


   Value result;

   if (typeIsExpectedBf8ForChipset(chipset, resultElemType))

     result = ROCDL::CvtPkBf8F32Op::create(rewriter, loc, i32, sourceA, sourceB,

                                           existing, op.getWordIndex());

   else if (typeIsExpectedFp8ForChipset(chipset, resultElemType))

     result = ROCDL::CvtPkFp8F32Op::create(rewriter, loc, i32, sourceA, sourceB,

                                           existing, op.getWordIndex());


   result = rewriter.replaceOpWithNewOp<LLVM::BitcastOp>(

       op, getTypeConverter()->convertType(resultType), result);

   return success();

 }


 LogicalResult PackedStochRoundFp8OpLowering::matchAndRewrite(

     PackedStochRoundFp8Op op, PackedStochRoundFp8OpAdaptor adaptor,

     ConversionPatternRewriter &rewriter) const {

   Location loc = op.getLoc();

   if (!(chipset == kGfx942 || hasOcpFp8(chipset)))

     return rewriter.notifyMatchFailure(

         loc, "Fp8 conversion instructions are not available on target "

              "architecture and their emulation is not implemented");

   Type i32 = getTypeConverter()->convertType(rewriter.getI32Type());


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

   Type resultElemType = getElementTypeOrSelf(resultType);


   Value source = adaptor.getSource();

   Value stoch = adaptor.getStochiasticParam();

   Value existing = adaptor.getExisting();

   if (existing)

     existing = LLVM::BitcastOp::create(rewriter, loc, i32, existing);

   else

     existing = LLVM::UndefOp::create(rewriter, loc, i32);


   Value result;

   if (typeIsExpectedBf8ForChipset(chipset, resultElemType))

     result = ROCDL::CvtSrBf8F32Op::create(rewriter, loc, i32, source, stoch,

                                           existing, op.getStoreIndex());

   else if (typeIsExpectedFp8ForChipset(chipset, resultElemType))

     result = ROCDL::CvtSrFp8F32Op::create(rewriter, loc, i32, source, stoch,

                                           existing, op.getStoreIndex());


   result = rewriter.replaceOpWithNewOp<LLVM::BitcastOp>(

       op, getTypeConverter()->convertType(resultType), result);

   return success();

 }


 // Implement the AMDGPU_DPPLowering class that will convert the amdgpu.dpp

 // operation into the corresponding ROCDL instructions.

 struct AMDGPUDPPLowering : public ConvertOpToLLVMPattern<DPPOp> {

   AMDGPUDPPLowering(const LLVMTypeConverter &converter, Chipset chipset)

       : ConvertOpToLLVMPattern<DPPOp>(converter), chipset(chipset) {}

   Chipset chipset;


   LogicalResult

   matchAndRewrite(DPPOp DppOp, DPPOp::Adaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {


     // Convert the source operand to the corresponding LLVM type

     Location loc = DppOp.getLoc();

     Value src = adaptor.getSrc();

     Value old = adaptor.getOld();

     Type srcType = src.getType();

     Type oldType = old.getType();

     Type llvmType = nullptr;

     if (srcType.getIntOrFloatBitWidth() < 32) {

       llvmType = rewriter.getI32Type();

     } else if (isa<FloatType>(srcType)) {

       llvmType = (srcType.getIntOrFloatBitWidth() == 32)

                      ? rewriter.getF32Type()

                      : rewriter.getF64Type();

     } else if (isa<IntegerType>(srcType)) {

       llvmType = (srcType.getIntOrFloatBitWidth() == 32)

                      ? rewriter.getI32Type()

                      : rewriter.getI64Type();

     }

     auto llvmSrcIntType = typeConverter->convertType(

         rewriter.getIntegerType(srcType.getIntOrFloatBitWidth()));


     // If the source type is less of 32, use bitcast to convert it to i32.

     auto convertOperand = [&](Value operand, Type operandType) {

       if (operandType.getIntOrFloatBitWidth() <= 16) {

         if (llvm::isa<FloatType>(operandType)) {

           operand =

               LLVM::BitcastOp::create(rewriter, loc, llvmSrcIntType, operand);

         }

         auto llvmVecType = typeConverter->convertType(mlir::VectorType::get(

             32 / operandType.getIntOrFloatBitWidth(), llvmSrcIntType));

         Value undefVec = LLVM::UndefOp::create(rewriter, loc, llvmVecType);

         operand =

             LLVM::InsertElementOp::create(rewriter, loc, undefVec, operand,

                                           createI32Constant(rewriter, loc, 0));

         operand = LLVM::BitcastOp::create(rewriter, loc, llvmType, operand);

       }

       return operand;

     };


     src = convertOperand(src, srcType);

     old = convertOperand(old, oldType);


     // This is taken from the following file llvm/lib/Target/AMDGPU/SIDefines.h

     enum DppCtrl : unsigned {

       ROW_SHL0 = 0x100,

       ROW_SHR0 = 0x110,

       ROW_ROR0 = 0x120,

       WAVE_SHL1 = 0x130,

       WAVE_ROL1 = 0x134,

       WAVE_SHR1 = 0x138,

       WAVE_ROR1 = 0x13C,

       ROW_MIRROR = 0x140,

       ROW_HALF_MIRROR = 0x141,

       BCAST15 = 0x142,

       BCAST31 = 0x143,

     };


     auto kind = DppOp.getKind();

     auto permArgument = DppOp.getPermArgument();

     uint32_t DppCtrl = 0;


     switch (kind) {


     case DPPPerm::quad_perm:

       if (auto quadPermAttr = cast<ArrayAttr>(*permArgument)) {

         int32_t i = 0;

         for (auto elem : quadPermAttr.getAsRange<IntegerAttr>()) {

           uint32_t num = elem.getInt();

           DppCtrl |= num << (i * 2);

           i++;

         }

       }

       break;

     case DPPPerm::row_shl:

       if (auto intAttr = cast<IntegerAttr>(*permArgument)) {

         DppCtrl = intAttr.getInt() + DppCtrl::ROW_SHL0;

       }

       break;

     case DPPPerm::row_shr:

       if (auto intAttr = cast<IntegerAttr>(*permArgument)) {

         DppCtrl = intAttr.getInt() + DppCtrl::ROW_SHR0;

       }

       break;

     case DPPPerm::row_ror:

       if (auto intAttr = cast<IntegerAttr>(*permArgument)) {

         DppCtrl = intAttr.getInt() + DppCtrl::ROW_ROR0;

       }

       break;

     case DPPPerm::wave_shl:

       DppCtrl = DppCtrl::WAVE_SHL1;

       break;

     case DPPPerm::wave_shr:

       DppCtrl = DppCtrl::WAVE_SHR1;

       break;

     case DPPPerm::wave_rol:

       DppCtrl = DppCtrl::WAVE_ROL1;

       break;

     case DPPPerm::wave_ror:

       DppCtrl = DppCtrl::WAVE_ROR1;

       break;

     case DPPPerm::row_mirror:

       DppCtrl = DppCtrl::ROW_MIRROR;

       break;

     case DPPPerm::row_half_mirror:

       DppCtrl = DppCtrl::ROW_HALF_MIRROR;

       break;

     case DPPPerm::row_bcast_15:

       DppCtrl = DppCtrl::BCAST15;

       break;

     case DPPPerm::row_bcast_31:

       DppCtrl = DppCtrl::BCAST31;

       break;

     }


     // Check for row_mask, bank_mask, bound_ctrl if they exist and create

     // constants

     auto rowMask = DppOp->getAttrOfType<IntegerAttr>("row_mask").getInt();

     auto bankMask = DppOp->getAttrOfType<IntegerAttr>("bank_mask").getInt();

     bool boundCtrl = DppOp->getAttrOfType<BoolAttr>("bound_ctrl").getValue();


     // create a ROCDL_DPPMovOp instruction with the appropriate attributes

     auto dppMovOp =

         ROCDL::DPPUpdateOp::create(rewriter, loc, llvmType, old, src, DppCtrl,

                                    rowMask, bankMask, boundCtrl);


     Value result = dppMovOp.getRes();

     if (srcType.getIntOrFloatBitWidth() < 32) {

       result = LLVM::TruncOp::create(rewriter, loc, llvmSrcIntType, result);

       if (!llvm::isa<IntegerType>(srcType)) {

         result = LLVM::BitcastOp::create(rewriter, loc, srcType, result);

       }

     }


     // We are replacing the AMDGPU_DPPOp instruction with the new

     // ROCDL_DPPMovOp instruction

     rewriter.replaceOp(DppOp, ValueRange(result));

     return success();

   }

 };


 struct AMDGPUSwizzleBitModeLowering

     : public ConvertOpToLLVMPattern<SwizzleBitModeOp> {

   using ConvertOpToLLVMPattern::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(SwizzleBitModeOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     Location loc = op.getLoc();

     Type i32 = rewriter.getI32Type();

     Value src = adaptor.getSrc();

     SmallVector<Value> decomposed =

         LLVM::decomposeValue(rewriter, loc, src, i32);

     unsigned andMask = op.getAndMask();

     unsigned orMask = op.getOrMask();

     unsigned xorMask = op.getXorMask();


     // bit 15 is 0 for the BitMode swizzle.

     // https://gpuopen.com/learn/amd-gcn-assembly-cross-lane-operations/

     unsigned mask = andMask | (orMask << 5) | (xorMask << 10);

     Value maskValue = createI32Constant(rewriter, loc, mask);

     SmallVector<Value> swizzled;

     for (Value v : decomposed) {

       Value res =

           ROCDL::DsSwizzleOp::create(rewriter, loc, v.getType(), v, maskValue);

       swizzled.emplace_back(res);

     }


     Value result = LLVM::composeValue(rewriter, loc, swizzled, src.getType());

     rewriter.replaceOp(op, result);

     return success();

   }

 };


 struct AMDGPUPermlaneLowering : public ConvertOpToLLVMPattern<PermlaneSwapOp> {

   using ConvertOpToLLVMPattern::ConvertOpToLLVMPattern;


   AMDGPUPermlaneLowering(const LLVMTypeConverter &converter, Chipset chipset)

       : ConvertOpToLLVMPattern<PermlaneSwapOp>(converter), chipset(chipset) {}

   Chipset chipset;


   LogicalResult

   matchAndRewrite(PermlaneSwapOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     if (chipset < kGfx950)

       return op->emitOpError("permlane_swap is only supported on gfx950+");


     Location loc = op.getLoc();

     Type i32 = rewriter.getI32Type();

     Value src = adaptor.getSrc();

     unsigned rowLength = op.getRowLength();

     bool fi = op.getFetchInactive();

     bool boundctrl = op.getBoundCtrl();


     SmallVector<Value> decomposed =

         LLVM::decomposeValue(rewriter, loc, src, i32);


     SmallVector<Value> permuted;

     for (Value v : decomposed) {

       Value res;

       Type i32pair = LLVM::LLVMStructType::getLiteral(

           rewriter.getContext(), {v.getType(), v.getType()});


       if (rowLength == 16)

         res = ROCDL::Permlane16SwapOp::create(rewriter, loc, i32pair, v, v, fi,

                                               boundctrl);

       else if (rowLength == 32)

         res = ROCDL::Permlane32SwapOp::create(rewriter, loc, i32pair, v, v, fi,

                                               boundctrl);

       else

         llvm_unreachable("unsupported row length");


       Value vdstNew = LLVM::ExtractValueOp::create(rewriter, loc, res, {0});

       permuted.emplace_back(vdstNew);

     }


     Value result = LLVM::composeValue(rewriter, loc, permuted, src.getType());

     rewriter.replaceOp(op, result);

     return success();

   }

 };


 struct ConvertAMDGPUToROCDLPass

     : public impl::ConvertAMDGPUToROCDLPassBase<ConvertAMDGPUToROCDLPass> {

   using Base::Base;


   void runOnOperation() override {

     MLIRContext *ctx = &getContext();

     FailureOr<Chipset> maybeChipset = Chipset::parse(chipset);

     if (failed(maybeChipset)) {

       emitError(UnknownLoc::get(ctx), "Invalid chipset name: " + chipset);

       return signalPassFailure();

     }


     RewritePatternSet patterns(ctx);

     LLVMTypeConverter converter(ctx);

     populateAMDGPUToROCDLConversionPatterns(converter, patterns, *maybeChipset);

     LLVMConversionTarget target(getContext());

     target.addIllegalDialect<::mlir::amdgpu::AMDGPUDialect>();

     target.addLegalDialect<::mlir::LLVM::LLVMDialect>();

     target.addLegalDialect<::mlir::ROCDL::ROCDLDialect>();

     if (failed(applyPartialConversion(getOperation(), target,

                                       std::move(patterns))))

       signalPassFailure();

   }

 };

 } // namespace


 void mlir::populateAMDGPUMemorySpaceAttributeConversions(

     TypeConverter &typeConverter) {

   typeConverter.addTypeAttributeConversion(

       [](BaseMemRefType type, amdgpu::AddressSpaceAttr as)

           -> TypeConverter::AttributeConversionResult {

         MLIRContext *ctx = as.getContext();

         Type i64 = IntegerType::get(ctx, 64);

         switch (as.getValue()) {

         case amdgpu::AddressSpace::FatRawBuffer:

           return IntegerAttr::get(i64, 7);

         case amdgpu::AddressSpace::BufferRsrc:

           return IntegerAttr::get(i64, 8);

         case amdgpu::AddressSpace::FatStructuredBuffer:

           return IntegerAttr::get(i64, 9);

         }

         return TypeConverter::AttributeConversionResult::abort();

       });

 }


 void mlir::populateAMDGPUToROCDLConversionPatterns(LLVMTypeConverter &converter,

                                                    RewritePatternSet &patterns,

                                                    Chipset chipset) {

   populateAMDGPUMemorySpaceAttributeConversions(converter);

   patterns

       .add<FatRawBufferCastLowering,

            RawBufferOpLowering<RawBufferLoadOp, ROCDL::RawPtrBufferLoadOp>,

            RawBufferOpLowering<RawBufferStoreOp, ROCDL::RawPtrBufferStoreOp>,

            RawBufferOpLowering<RawBufferAtomicFaddOp,

                                ROCDL::RawPtrBufferAtomicFaddOp>,

            RawBufferOpLowering<RawBufferAtomicFmaxOp,

                                ROCDL::RawPtrBufferAtomicFmaxOp>,

            RawBufferOpLowering<RawBufferAtomicSmaxOp,

                                ROCDL::RawPtrBufferAtomicSmaxOp>,

            RawBufferOpLowering<RawBufferAtomicUminOp,

                                ROCDL::RawPtrBufferAtomicUminOp>,

            RawBufferOpLowering<RawBufferAtomicCmpswapOp,

                                ROCDL::RawPtrBufferAtomicCmpSwap>,

            AMDGPUDPPLowering, MemoryCounterWaitOpLowering, LDSBarrierOpLowering,

            SchedBarrierOpLowering, MFMAOpLowering, ScaledMFMAOpLowering,

            WMMAOpLowering, ExtPackedFp8OpLowering, ScaledExtPackedOpLowering,

            PackedScaledTruncOpLowering, PackedTrunc2xFp8OpLowering,

            PackedStochRoundFp8OpLowering, GatherToLDSOpLowering,

            TransposeLoadOpLowering, AMDGPUPermlaneLowering>(converter, chipset);

   patterns.add<AMDGPUSwizzleBitModeLowering>(converter);

 }

AMDGPUDialect.h

typeIsExpectedFp8ForChipset
static bool typeIsExpectedFp8ForChipset(Chipset chipset, Type type)
Return true if type is the E4M3FN variant of an 8-bit float that is supported by the _fp8 instruction...
Definition: AMDGPUToROCDL.cpp:765

kGfx942
constexpr Chipset kGfx942
Definition: AMDGPUToROCDL.cpp:42

wmmaOpToIntrinsic
static std::optional< StringRef > wmmaOpToIntrinsic(WMMAOp wmma, Chipset chipset)
Return the rocdl intrinsic corresponding to a WMMA operation wmma if one exists.
Definition: AMDGPUToROCDL.cpp:982

convertMFMAVectorOperand
static Value convertMFMAVectorOperand(ConversionPatternRewriter &rewriter, Location loc, Value input, bool allowBf16=true)
Converts a MFMA vector operand from MLIR AMDGPU dialect convention to ROCDL and LLVM AMDGPU intrinsic...
Definition: AMDGPUToROCDL.cpp:621

createI1Constant
static Value createI1Constant(ConversionPatternRewriter &rewriter, Location loc, bool value)
Definition: AMDGPUToROCDL.cpp:64

kGfx908
constexpr Chipset kGfx908
Definition: AMDGPUToROCDL.cpp:40

kGfx90a
constexpr Chipset kGfx90a
Definition: AMDGPUToROCDL.cpp:41

mfmaOpToIntrinsic
static std::optional< StringRef > mfmaOpToIntrinsic(MFMAOp mfma, Chipset chipset)
Return the rocdl intrinsic corresponding to a MFMA operation mfma if one exists.
Definition: AMDGPUToROCDL.cpp:773

wmmaPushOutputOperand
static void wmmaPushOutputOperand(ConversionPatternRewriter &rewriter, Location loc, const TypeConverter *typeConverter, Value output, int32_t subwordOffset, bool clamp, SmallVector< Value, 4 > &operands)
Push the output operand.
Definition: AMDGPUToROCDL.cpp:737

typeIsExpectedBf8ForChipset
static bool typeIsExpectedBf8ForChipset(Chipset chipset, Type type)
Return true if type is the E5M2 variant of an 8-bit float that is supported by the _bf8 instructions ...
Definition: AMDGPUToROCDL.cpp:758

makeBufferRsrc
static Value makeBufferRsrc(ConversionPatternRewriter &rewriter, Location loc, Value basePointer, Value numRecords, bool boundsCheck, amdgpu::Chipset chipset, Value cacheSwizzleStride=nullptr, unsigned addressSpace=8)
Definition: AMDGPUToROCDL.cpp:124

wmmaPushInputOperand
static void wmmaPushInputOperand(ConversionPatternRewriter &rewriter, Location loc, const TypeConverter *typeConverter, bool isUnsigned, Value llvmInput, Value mlirInput, SmallVector< Value, 4 > &operands)
Push an input operand.
Definition: AMDGPUToROCDL.cpp:674

getLinearIndexI32
static Value getLinearIndexI32(ConversionPatternRewriter &rewriter, Location loc, MemRefDescriptor &memRefDescriptor, ValueRange indices, ArrayRef< int64_t > strides)
Returns the linear index used to access an element in the memref.
Definition: AMDGPUToROCDL.cpp:71

convertUnsignedToI32
static Value convertUnsignedToI32(ConversionPatternRewriter &rewriter, Location loc, Value val)
Convert an unsigned number val to i32.
Definition: AMDGPUToROCDL.cpp:46

castMFMAScaleOperand
static Value castMFMAScaleOperand(ConversionPatternRewriter &rewriter, Location loc, Value input)
Converts the scaled MFMA operands, scalesA and scalesB, from MLIR AMDGPU dialect convention to ROCDL ...
Definition: AMDGPUToROCDL.cpp:657

createI32Constant
static Value createI32Constant(ConversionPatternRewriter &rewriter, Location loc, int32_t value)
Definition: AMDGPUToROCDL.cpp:58

getNumRecords
static Value getNumRecords(ConversionPatternRewriter &rewriter, Location loc, MemRefType memrefType, MemRefDescriptor &memrefDescriptor, ArrayRef< int64_t > strides, uint32_t elementByteWidth)
Compute the contents of the num_records field for a given memref descriptor - that is,...
Definition: AMDGPUToROCDL.cpp:94

mfmaTypeSelectCode
static std::optional< uint32_t > mfmaTypeSelectCode(Type mlirElemType)
Definition: AMDGPUToROCDL.cpp:918

mfmaOpToScaledIntrinsic
static std::optional< std::tuple< StringRef, uint32_t, uint32_t > > mfmaOpToScaledIntrinsic(Type aType, Type bType, Type destType, uint32_t m, uint32_t n, uint32_t k, uint32_t b, Chipset chipset)
If there is a scaled MFMA instruction for the input element types aType and bType,...
Definition: AMDGPUToROCDL.cpp:936

kGfx950
constexpr Chipset kGfx950
Definition: AMDGPUToROCDL.cpp:43

AMDGPUToROCDL.h

Chipset.h

ConversionTarget.h

getContext
static MLIRContext * getContext(OpFoldResult val)
Definition: IndexingUtils.cpp:296

LLVMDialect.h

LLVMTypes.h

kind
union mlir::linalg::@1244::ArityGroupAndKind::Kind kind

kSizePosInMemRefDescriptor
static constexpr unsigned kSizePosInMemRefDescriptor
Definition: MemRefDescriptor.h:19

kStridePosInMemRefDescriptor
static constexpr unsigned kStridePosInMemRefDescriptor
Definition: MemRefDescriptor.h:20

kOffsetPosInMemRefDescriptor
static constexpr unsigned kOffsetPosInMemRefDescriptor
Definition: MemRefDescriptor.h:18

kAllocatedPtrPosInMemRefDescriptor
static constexpr unsigned kAllocatedPtrPosInMemRefDescriptor
Definition: MemRefDescriptor.h:16

kAlignedPtrPosInMemRefDescriptor
static constexpr unsigned kAlignedPtrPosInMemRefDescriptor
Definition: MemRefDescriptor.h:17

None
@ None
Definition: MlirTblgenMain.cpp:27

clamp
static Value clamp(ImplicitLocOpBuilder &builder, Value value, Value lowerBound, Value upperBound)
Definition: PolynomialApproximation.cpp:220

max
static Value max(ImplicitLocOpBuilder &builder, Value value, Value bound)
Definition: PolynomialApproximation.cpp:212

min
static Value min(ImplicitLocOpBuilder &builder, Value value, Value bound)
Definition: PolynomialApproximation.cpp:204

ROCDLDialect.h

TypeConverter.h

TypeUtilities.h

llvm::ArrayRef
Definition: LLVM.h:48

llvm::SmallVector
Definition: LLVM.h:72

llvm::TypeSwitch
Definition: LLVM.h:82

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:104

mlir::BoolAttr
Special case of IntegerAttr to represent boolean integers, i.e., signless i1 integers.
Definition: BuiltinAttributes.h:846

mlir::Builder::getIndexAttr
IntegerAttr getIndexAttr(int64_t value)
Definition: Builders.cpp:107

mlir::Builder::getI16Type
IntegerType getI16Type()
Definition: Builders.cpp:60

mlir::Builder::getI32IntegerAttr
IntegerAttr getI32IntegerAttr(int32_t value)
Definition: Builders.cpp:199

mlir::Builder::getF32Type
FloatType getF32Type()
Definition: Builders.cpp:42

mlir::Builder::getI16IntegerAttr
IntegerAttr getI16IntegerAttr(int16_t value)
Definition: Builders.cpp:216

mlir::Builder::getI64Type
IntegerType getI64Type()
Definition: Builders.cpp:64

mlir::Builder::getI32Type
IntegerType getI32Type()
Definition: Builders.cpp:62

mlir::Builder::getIntegerType
IntegerType getIntegerType(unsigned width)
Definition: Builders.cpp:66

mlir::Builder::getI4Type
IntegerType getI4Type()
Definition: Builders.cpp:56

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

mlir::Builder::getI1Type
IntegerType getI1Type()
Definition: Builders.cpp:52

mlir::Builder::getI8Type
IntegerType getI8Type()
Definition: Builders.cpp:58

mlir::Builder::getF64Type
FloatType getF64Type()
Definition: Builders.cpp:44

mlir::ConversionPatternRewriter
This class implements a pattern rewriter for use with ConversionPatterns.
Definition: DialectConversion.h:814

mlir::ConversionPatternRewriter::replaceOp
void replaceOp(Operation *op, ValueRange newValues) override
Replace the given operation with the new values.
Definition: DialectConversion.cpp:2036

mlir::ConversionPatternRewriter::eraseOp
void eraseOp(Operation *op) override
PatternRewriter hook for erasing a dead operation.
Definition: DialectConversion.cpp:2073

mlir::ConvertOpToLLVMPattern
Utility class for operation conversions targeting the LLVM dialect that match exactly one source oper...
Definition: Pattern.h:209

mlir::ConvertOpToLLVMPattern::ConvertOpToLLVMPattern
ConvertOpToLLVMPattern(const LLVMTypeConverter &typeConverter, PatternBenefit benefit=1)
Definition: Pattern.h:215

mlir::DataLayout
The main mechanism for performing data layout queries.
Definition: DataLayoutInterfaces.h:220

mlir::DataLayout::closest
static DataLayout closest(Operation *op)
Returns the layout of the closest parent operation carrying layout info.
Definition: DataLayoutInterfaces.cpp:512

mlir::DataLayout::getTypeSizeInBits
llvm::TypeSize getTypeSizeInBits(Type t) const
Returns the size in bits of the given type in the current scope.
Definition: DataLayoutInterfaces.cpp:572

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::Location
This class defines the main interface for locations in MLIR and acts as a non-nullable wrapper around...
Definition: Location.h:76

mlir::MLIRContext
MLIRContext is the top-level object for a collection of MLIR operations.
Definition: MLIRContext.h:63

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

mlir::MemRefDescriptor::stride
Value stride(OpBuilder &builder, Location loc, unsigned pos)
Builds IR extracting the pos-th size from the descriptor.
Definition: MemRefBuilder.cpp:169

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::size
Value size(OpBuilder &builder, Location loc, unsigned pos)
Builds IR extracting the pos-th size from the descriptor.
Definition: MemRefBuilder.cpp:127

mlir::OpBuilder::createOrFold
void createOrFold(SmallVectorImpl< Value > &results, Location location, Args &&...args)
Create an operation of specific op type at the current insertion point, and immediately try to fold i...
Definition: Builders.h:519

mlir::OpBuilder::create
Operation * create(const OperationState &state)
Creates an operation given the fields represented as an OperationState.
Definition: Builders.cpp:456

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

mlir::Operation::getResult
OpResult getResult(unsigned idx)
Get the 'idx'th result of this operation.
Definition: Operation.h:407

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

mlir::Operation::getNumResults
unsigned getNumResults()
Return the number of results held by this operation.
Definition: Operation.h:404

mlir::RewritePatternSet
Definition: PatternMatch.h:806

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:716

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:519

mlir::TypeConverter::AttributeConversionResult
The general result of a type attribute conversion callback, allowing for early termination.
Definition: DialectConversion.h:115

mlir::TypeConverter::AttributeConversionResult::abort
static AttributeConversionResult abort()
Definition: DialectConversion.cpp:3609

mlir::TypeConverter
Type conversion class.
Definition: DialectConversion.h:41

mlir::TypeConverter::convertType
LogicalResult convertType(Type t, SmallVectorImpl< Type > &results) const
Convert the given type.
Definition: DialectConversion.cpp:3361

mlir::TypeConverter::addTypeAttributeConversion
void addTypeAttributeConversion(FnT &&callback)
Register a conversion function for attributes within types.
Definition: DialectConversion.h:249

mlir::TypeRange
This class provides an abstraction over the various different ranges of value types.
Definition: TypeRange.h:37

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

mlir::Type::isF64
bool isF64() const
Definition: Types.cpp:41

mlir::Type::isSignedInteger
bool isSignedInteger() const
Return true if this is a signed integer type (with the specified width).
Definition: Types.cpp:76

mlir::Type::isF32
bool isF32() const
Definition: Types.cpp:40

mlir::Type::isUnsignedInteger
bool isUnsignedInteger() const
Return true if this is an unsigned integer type (with the specified width).
Definition: Types.cpp:88

mlir::Type::isInteger
bool isInteger() const
Return true if this is an integer type (with the specified width).
Definition: Types.cpp:56

mlir::Type::isF16
bool isF16() const
Definition: Types.cpp:38

mlir::Type::getIntOrFloatBitWidth
unsigned getIntOrFloatBitWidth() const
Return the bit width of an integer or a float type, assert failure on other types.
Definition: Types.cpp:122

mlir::Type::isBF16
bool isBF16() const
Definition: Types.cpp:37

mlir::ValueRange
This class provides an abstraction over the different types of ranges over Values.
Definition: ValueRange.h:387

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:105

Pattern.h

Pass.h

BuiltinTypes.h

mlir::LLVM::getStridedElementPtr
Value getStridedElementPtr(OpBuilder &builder, Location loc, const LLVMTypeConverter &converter, MemRefType type, Value memRefDesc, ValueRange indices, LLVM::GEPNoWrapFlags noWrapFlags=LLVM::GEPNoWrapFlags::none)
Performs the index computation to get to the element at indices of the memory pointed to by memRefDes...
Definition: Pattern.cpp:478

mlir::LLVM::composeValue
Value composeValue(OpBuilder &builder, Location loc, ValueRange src, Type dstType)
Composes a set of src values into a single value of type dstType through series of bitcasts and vecto...
Definition: Pattern.cpp:439

mlir::LLVM::decomposeValue
SmallVector< Value > decomposeValue(OpBuilder &builder, Location loc, Value src, Type dstType)
Decomposes a src value into a set of values of type dstType through series of bitcasts and vector ops...
Definition: Pattern.cpp:400

mlir::amdgpu
Definition: GPUToROCDLPass.h:23

mlir::amdgpu::hasOcpFp8
bool hasOcpFp8(const Chipset &chipset)
Definition: Chipset.h:52

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:468

mlir::remark::failed
detail::InFlightRemark failed(Location loc, RemarkOpts opts)
Report an optimization remark that failed.
Definition: Remarks.h:491

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

mlir::populateAMDGPUMemorySpaceAttributeConversions
void populateAMDGPUMemorySpaceAttributeConversions(TypeConverter &typeConverter)
Remap AMDGPU memory spaces to LLVM address spaces by mapping amdgpu::AddressSpace::fat_raw_buffer to ...
Definition: AMDGPUToROCDL.cpp:1954

mlir::emitError
InFlightDiagnostic emitError(Location loc)
Utility method to emit an error message using this location.
Definition: Diagnostics.cpp:328

mlir::getElementTypeOrSelf
Type getElementTypeOrSelf(Type type)
Return the element type or return the type itself.
Definition: TypeUtilities.cpp:23

mlir::patterns
const FrozenRewritePatternSet & patterns
Definition: GreedyPatternRewriteDriver.h:283

mlir::populateAMDGPUToROCDLConversionPatterns
void populateAMDGPUToROCDLConversionPatterns(LLVMTypeConverter &converter, RewritePatternSet &patterns, amdgpu::Chipset chipset)
Note: This function will also add conversions for the AMDGPU-specific address spaces,...
Definition: AMDGPUToROCDL.cpp:1973

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:4000

mlir::OperationState
This represents an operation in an abstracted form, suitable for use with the builder APIs.
Definition: OperationSupport.h:948

mlir::amdgpu::Chipset
Represents the amdgpu gfx chipset version, e.g., gfx90a, gfx942, gfx1103.
Definition: Chipset.h:22

mlir::amdgpu::Chipset::majorVersion
unsigned majorVersion
Definition: Chipset.h:23

mlir::amdgpu::Chipset::parse
static FailureOr< Chipset > parse(StringRef name)
Parses the chipset version string and returns the chipset on success, and failure otherwise.
Definition: Chipset.cpp:14