Optimizer/CodeGen/CodeGen.cpp

044d5b5dSValentin Clement//===-- CodeGen.cpp -- bridge to lower to LLVM ----------------------------===//
044d5b5dSValentin Clement//
044d5b5dSValentin Clement// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
044d5b5dSValentin Clement// See https://llvm.org/LICENSE.txt for license information.
044d5b5dSValentin Clement// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
044d5b5dSValentin Clement//
044d5b5dSValentin Clement//===----------------------------------------------------------------------===//
044d5b5dSValentin Clement//
044d5b5dSValentin Clement// Coding style: https://mlir.llvm.org/getting_started/DeveloperGuide/
044d5b5dSValentin Clement//
044d5b5dSValentin Clement//===----------------------------------------------------------------------===//
044d5b5dSValentin Clement
044d5b5dSValentin Clement#include "flang/Optimizer/CodeGen/CodeGen.h"
044d5b5dSValentin Clement#include "PassDetail.h"
b6e44ecdSValentin Clement#include "flang/ISO_Fortran_binding.h"
39f4ef81SValentin Clement#include "flang/Optimizer/Dialect/FIRAttr.h"
044d5b5dSValentin Clement#include "flang/Optimizer/Dialect/FIROps.h"
044d5b5dSValentin Clement#include "mlir/Conversion/ArithmeticToLLVM/ArithmeticToLLVM.h"
044d5b5dSValentin Clement#include "mlir/Conversion/LLVMCommon/Pattern.h"
044d5b5dSValentin Clement#include "mlir/Conversion/StandardToLLVM/ConvertStandardToLLVM.h"
044d5b5dSValentin Clement#include "mlir/IR/BuiltinTypes.h"
3ae8e442SValentin Clement#include "mlir/IR/Matchers.h"
044d5b5dSValentin Clement#include "mlir/Pass/Pass.h"
044d5b5dSValentin Clement#include "llvm/ADT/ArrayRef.h"
044d5b5dSValentin Clement
044d5b5dSValentin Clement#define DEBUG_TYPE "flang-codegen"
044d5b5dSValentin Clement
044d5b5dSValentin Clement// fir::LLVMTypeConverter for converting to LLVM IR dialect types.
044d5b5dSValentin Clement#include "TypeConverter.h"
044d5b5dSValentin Clement
b6e44ecdSValentin Clement/// `fir.box` attribute values as defined for CFI_attribute_t in
b6e44ecdSValentin Clement/// flang/ISO_Fortran_binding.h.
b6e44ecdSValentin Clementstatic constexpr unsigned kAttrPointer = CFI_attribute_pointer;
b6e44ecdSValentin Clementstatic constexpr unsigned kAttrAllocatable = CFI_attribute_allocatable;
b6e44ecdSValentin Clement
1e6d9c06SDiana Picusstatic mlir::LLVM::ConstantOp
1e6d9c06SDiana PicusgenConstantIndex(mlir::Location loc, mlir::Type ity,
1e6d9c06SDiana Picus                 mlir::ConversionPatternRewriter &rewriter,
1e6d9c06SDiana Picus                 std::int64_t offset) {
1e6d9c06SDiana Picus  auto cattr = rewriter.getI64IntegerAttr(offset);
1e6d9c06SDiana Picus  return rewriter.create<mlir::LLVM::ConstantOp>(loc, ity, cattr);
1e6d9c06SDiana Picus}
1e6d9c06SDiana Picus
39f4ef81SValentin Clementstatic Block *createBlock(mlir::ConversionPatternRewriter &rewriter,
39f4ef81SValentin Clement                          mlir::Block *insertBefore) {
39f4ef81SValentin Clement  assert(insertBefore && "expected valid insertion block");
39f4ef81SValentin Clement  return rewriter.createBlock(insertBefore->getParent(),
39f4ef81SValentin Clement                              mlir::Region::iterator(insertBefore));
39f4ef81SValentin Clement}
39f4ef81SValentin Clement
044d5b5dSValentin Clementnamespace {
044d5b5dSValentin Clement/// FIR conversion pattern template
044d5b5dSValentin Clementtemplate <typename FromOp>
044d5b5dSValentin Clementclass FIROpConversion : public mlir::ConvertOpToLLVMPattern<FromOp> {
044d5b5dSValentin Clementpublic:
044d5b5dSValentin Clement  explicit FIROpConversion(fir::LLVMTypeConverter &lowering)
044d5b5dSValentin Clement      : mlir::ConvertOpToLLVMPattern<FromOp>(lowering) {}
044d5b5dSValentin Clement
044d5b5dSValentin Clementprotected:
044d5b5dSValentin Clement  mlir::Type convertType(mlir::Type ty) const {
044d5b5dSValentin Clement    return lowerTy().convertType(ty);
044d5b5dSValentin Clement  }
044d5b5dSValentin Clement
df3b9810SValentin Clement  mlir::LLVM::ConstantOp
df3b9810SValentin Clement  genConstantOffset(mlir::Location loc,
df3b9810SValentin Clement                    mlir::ConversionPatternRewriter &rewriter,
df3b9810SValentin Clement                    int offset) const {
df3b9810SValentin Clement    auto ity = lowerTy().offsetType();
df3b9810SValentin Clement    auto cattr = rewriter.getI32IntegerAttr(offset);
df3b9810SValentin Clement    return rewriter.create<mlir::LLVM::ConstantOp>(loc, ity, cattr);
df3b9810SValentin Clement  }
df3b9810SValentin Clement
b6e44ecdSValentin Clement  /// Construct code sequence to extract the specifc value from a `fir.box`.
b6e44ecdSValentin Clement  mlir::Value getValueFromBox(mlir::Location loc, mlir::Value box,
df3b9810SValentin Clement                              mlir::Type resultTy,
b6e44ecdSValentin Clement                              mlir::ConversionPatternRewriter &rewriter,
b6e44ecdSValentin Clement                              unsigned boxValue) const {
df3b9810SValentin Clement    mlir::LLVM::ConstantOp c0 = genConstantOffset(loc, rewriter, 0);
b6e44ecdSValentin Clement    mlir::LLVM::ConstantOp cValuePos =
b6e44ecdSValentin Clement        genConstantOffset(loc, rewriter, boxValue);
df3b9810SValentin Clement    auto pty = mlir::LLVM::LLVMPointerType::get(resultTy);
df3b9810SValentin Clement    auto p = rewriter.create<mlir::LLVM::GEPOp>(
b6e44ecdSValentin Clement        loc, pty, mlir::ValueRange{box, c0, cValuePos});
df3b9810SValentin Clement    return rewriter.create<mlir::LLVM::LoadOp>(loc, resultTy, p);
df3b9810SValentin Clement  }
df3b9810SValentin Clement
df3b9810SValentin Clement  /// Method to construct code sequence to get the triple for dimension `dim`
df3b9810SValentin Clement  /// from a box.
df3b9810SValentin Clement  SmallVector<mlir::Value, 3>
df3b9810SValentin Clement  getDimsFromBox(mlir::Location loc, ArrayRef<mlir::Type> retTys,
df3b9810SValentin Clement                 mlir::Value box, mlir::Value dim,
df3b9810SValentin Clement                 mlir::ConversionPatternRewriter &rewriter) const {
df3b9810SValentin Clement    mlir::LLVM::ConstantOp c0 = genConstantOffset(loc, rewriter, 0);
df3b9810SValentin Clement    mlir::LLVM::ConstantOp cDims =
df3b9810SValentin Clement        genConstantOffset(loc, rewriter, kDimsPosInBox);
df3b9810SValentin Clement    mlir::LLVM::LoadOp l0 =
df3b9810SValentin Clement        loadFromOffset(loc, box, c0, cDims, dim, 0, retTys[0], rewriter);
df3b9810SValentin Clement    mlir::LLVM::LoadOp l1 =
df3b9810SValentin Clement        loadFromOffset(loc, box, c0, cDims, dim, 1, retTys[1], rewriter);
df3b9810SValentin Clement    mlir::LLVM::LoadOp l2 =
df3b9810SValentin Clement        loadFromOffset(loc, box, c0, cDims, dim, 2, retTys[2], rewriter);
df3b9810SValentin Clement    return {l0.getResult(), l1.getResult(), l2.getResult()};
df3b9810SValentin Clement  }
df3b9810SValentin Clement
df3b9810SValentin Clement  mlir::LLVM::LoadOp
df3b9810SValentin Clement  loadFromOffset(mlir::Location loc, mlir::Value a, mlir::LLVM::ConstantOp c0,
df3b9810SValentin Clement                 mlir::LLVM::ConstantOp cDims, mlir::Value dim, int off,
df3b9810SValentin Clement                 mlir::Type ty,
df3b9810SValentin Clement                 mlir::ConversionPatternRewriter &rewriter) const {
df3b9810SValentin Clement    auto pty = mlir::LLVM::LLVMPointerType::get(ty);
df3b9810SValentin Clement    mlir::LLVM::ConstantOp c = genConstantOffset(loc, rewriter, off);
df3b9810SValentin Clement    mlir::LLVM::GEPOp p = genGEP(loc, pty, rewriter, a, c0, cDims, dim, c);
df3b9810SValentin Clement    return rewriter.create<mlir::LLVM::LoadOp>(loc, ty, p);
df3b9810SValentin Clement  }
df3b9810SValentin Clement
df3b9810SValentin Clement  /// Read base address from a fir.box. Returned address has type ty.
df3b9810SValentin Clement  mlir::Value
df3b9810SValentin Clement  loadBaseAddrFromBox(mlir::Location loc, mlir::Type ty, mlir::Value box,
df3b9810SValentin Clement                      mlir::ConversionPatternRewriter &rewriter) const {
df3b9810SValentin Clement    mlir::LLVM::ConstantOp c0 = genConstantOffset(loc, rewriter, 0);
df3b9810SValentin Clement    mlir::LLVM::ConstantOp cAddr =
df3b9810SValentin Clement        genConstantOffset(loc, rewriter, kAddrPosInBox);
df3b9810SValentin Clement    auto pty = mlir::LLVM::LLVMPointerType::get(ty);
df3b9810SValentin Clement    mlir::LLVM::GEPOp p = genGEP(loc, pty, rewriter, box, c0, cAddr);
df3b9810SValentin Clement    return rewriter.create<mlir::LLVM::LoadOp>(loc, ty, p);
df3b9810SValentin Clement  }
df3b9810SValentin Clement
df3b9810SValentin Clement  mlir::Value
df3b9810SValentin Clement  loadElementSizeFromBox(mlir::Location loc, mlir::Type ty, mlir::Value box,
df3b9810SValentin Clement                         mlir::ConversionPatternRewriter &rewriter) const {
df3b9810SValentin Clement    mlir::LLVM::ConstantOp c0 = genConstantOffset(loc, rewriter, 0);
df3b9810SValentin Clement    mlir::LLVM::ConstantOp cElemLen =
df3b9810SValentin Clement        genConstantOffset(loc, rewriter, kElemLenPosInBox);
df3b9810SValentin Clement    auto pty = mlir::LLVM::LLVMPointerType::get(ty);
df3b9810SValentin Clement    mlir::LLVM::GEPOp p = genGEP(loc, pty, rewriter, box, c0, cElemLen);
df3b9810SValentin Clement    return rewriter.create<mlir::LLVM::LoadOp>(loc, ty, p);
df3b9810SValentin Clement  }
df3b9810SValentin Clement
b6e44ecdSValentin Clement  // Load the attribute from the \p box and perform a check against \p maskValue
b6e44ecdSValentin Clement  // The final comparison is implemented as `(attribute & maskValue) != 0`.
b6e44ecdSValentin Clement  mlir::Value genBoxAttributeCheck(mlir::Location loc, mlir::Value box,
b6e44ecdSValentin Clement                                   mlir::ConversionPatternRewriter &rewriter,
b6e44ecdSValentin Clement                                   unsigned maskValue) const {
b6e44ecdSValentin Clement    mlir::Type attrTy = rewriter.getI32Type();
b6e44ecdSValentin Clement    mlir::Value attribute =
b6e44ecdSValentin Clement        getValueFromBox(loc, box, attrTy, rewriter, kAttributePosInBox);
b6e44ecdSValentin Clement    mlir::LLVM::ConstantOp attrMask =
b6e44ecdSValentin Clement        genConstantOffset(loc, rewriter, maskValue);
b6e44ecdSValentin Clement    auto maskRes =
b6e44ecdSValentin Clement        rewriter.create<mlir::LLVM::AndOp>(loc, attrTy, attribute, attrMask);
b6e44ecdSValentin Clement    mlir::LLVM::ConstantOp c0 = genConstantOffset(loc, rewriter, 0);
b6e44ecdSValentin Clement    return rewriter.create<mlir::LLVM::ICmpOp>(
b6e44ecdSValentin Clement        loc, mlir::LLVM::ICmpPredicate::ne, maskRes, c0);
b6e44ecdSValentin Clement  }
b6e44ecdSValentin Clement
df3b9810SValentin Clement  template <typename... ARGS>
df3b9810SValentin Clement  mlir::LLVM::GEPOp genGEP(mlir::Location loc, mlir::Type ty,
df3b9810SValentin Clement                           mlir::ConversionPatternRewriter &rewriter,
df3b9810SValentin Clement                           mlir::Value base, ARGS... args) const {
df3b9810SValentin Clement    SmallVector<mlir::Value> cv{args...};
df3b9810SValentin Clement    return rewriter.create<mlir::LLVM::GEPOp>(loc, ty, base, cv);
df3b9810SValentin Clement  }
df3b9810SValentin Clement
1e6d9c06SDiana Picus  /// Perform an extension or truncation as needed on an integer value. Lowering
1e6d9c06SDiana Picus  /// to the specific target may involve some sign-extending or truncation of
1e6d9c06SDiana Picus  /// values, particularly to fit them from abstract box types to the
1e6d9c06SDiana Picus  /// appropriate reified structures.
1e6d9c06SDiana Picus  mlir::Value integerCast(mlir::Location loc,
1e6d9c06SDiana Picus                          mlir::ConversionPatternRewriter &rewriter,
1e6d9c06SDiana Picus                          mlir::Type ty, mlir::Value val) const {
1e6d9c06SDiana Picus    auto valTy = val.getType();
1e6d9c06SDiana Picus    // If the value was not yet lowered, lower its type so that it can
1e6d9c06SDiana Picus    // be used in getPrimitiveTypeSizeInBits.
1e6d9c06SDiana Picus    if (!valTy.isa<mlir::IntegerType>())
1e6d9c06SDiana Picus      valTy = convertType(valTy);
1e6d9c06SDiana Picus    auto toSize = mlir::LLVM::getPrimitiveTypeSizeInBits(ty);
1e6d9c06SDiana Picus    auto fromSize = mlir::LLVM::getPrimitiveTypeSizeInBits(valTy);
1e6d9c06SDiana Picus    if (toSize < fromSize)
1e6d9c06SDiana Picus      return rewriter.create<mlir::LLVM::TruncOp>(loc, ty, val);
1e6d9c06SDiana Picus    if (toSize > fromSize)
1e6d9c06SDiana Picus      return rewriter.create<mlir::LLVM::SExtOp>(loc, ty, val);
1e6d9c06SDiana Picus    return val;
1e6d9c06SDiana Picus  }
1e6d9c06SDiana Picus
044d5b5dSValentin Clement  fir::LLVMTypeConverter &lowerTy() const {
044d5b5dSValentin Clement    return *static_cast<fir::LLVMTypeConverter *>(this->getTypeConverter());
044d5b5dSValentin Clement  }
044d5b5dSValentin Clement};
044d5b5dSValentin Clement
3ae8e442SValentin Clement/// FIR conversion pattern template
3ae8e442SValentin Clementtemplate <typename FromOp>
3ae8e442SValentin Clementclass FIROpAndTypeConversion : public FIROpConversion<FromOp> {
3ae8e442SValentin Clementpublic:
3ae8e442SValentin Clement  using FIROpConversion<FromOp>::FIROpConversion;
3ae8e442SValentin Clement  using OpAdaptor = typename FromOp::Adaptor;
3ae8e442SValentin Clement
3ae8e442SValentin Clement  mlir::LogicalResult
3ae8e442SValentin Clement  matchAndRewrite(FromOp op, OpAdaptor adaptor,
3ae8e442SValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const final {
3ae8e442SValentin Clement    mlir::Type ty = this->convertType(op.getType());
3ae8e442SValentin Clement    return doRewrite(op, ty, adaptor, rewriter);
3ae8e442SValentin Clement  }
3ae8e442SValentin Clement
3ae8e442SValentin Clement  virtual mlir::LogicalResult
3ae8e442SValentin Clement  doRewrite(FromOp addr, mlir::Type ty, OpAdaptor adaptor,
3ae8e442SValentin Clement            mlir::ConversionPatternRewriter &rewriter) const = 0;
3ae8e442SValentin Clement};
3ae8e442SValentin Clement
420ad7ceSAndrzej Warzynski/// Create value signaling an absent optional argument in a call, e.g.
420ad7ceSAndrzej Warzynski/// `fir.absent !fir.ref<i64>` -->  `llvm.mlir.null : !llvm.ptr<i64>`
420ad7ceSAndrzej Warzynskistruct AbsentOpConversion : public FIROpConversion<fir::AbsentOp> {
420ad7ceSAndrzej Warzynski  using FIROpConversion::FIROpConversion;
420ad7ceSAndrzej Warzynski
420ad7ceSAndrzej Warzynski  mlir::LogicalResult
420ad7ceSAndrzej Warzynski  matchAndRewrite(fir::AbsentOp absent, OpAdaptor,
420ad7ceSAndrzej Warzynski                  mlir::ConversionPatternRewriter &rewriter) const override {
420ad7ceSAndrzej Warzynski    mlir::Type ty = convertType(absent.getType());
420ad7ceSAndrzej Warzynski    mlir::Location loc = absent.getLoc();
420ad7ceSAndrzej Warzynski
420ad7ceSAndrzej Warzynski    if (absent.getType().isa<fir::BoxCharType>()) {
420ad7ceSAndrzej Warzynski      auto structTy = ty.cast<mlir::LLVM::LLVMStructType>();
420ad7ceSAndrzej Warzynski      assert(!structTy.isOpaque() && !structTy.getBody().empty());
420ad7ceSAndrzej Warzynski      auto undefStruct = rewriter.create<mlir::LLVM::UndefOp>(loc, ty);
420ad7ceSAndrzej Warzynski      auto nullField =
420ad7ceSAndrzej Warzynski          rewriter.create<mlir::LLVM::NullOp>(loc, structTy.getBody()[0]);
420ad7ceSAndrzej Warzynski      mlir::MLIRContext *ctx = absent.getContext();
420ad7ceSAndrzej Warzynski      auto c0 = mlir::ArrayAttr::get(ctx, rewriter.getI32IntegerAttr(0));
420ad7ceSAndrzej Warzynski      rewriter.replaceOpWithNewOp<mlir::LLVM::InsertValueOp>(
420ad7ceSAndrzej Warzynski          absent, ty, undefStruct, nullField, c0);
420ad7ceSAndrzej Warzynski    } else {
420ad7ceSAndrzej Warzynski      rewriter.replaceOpWithNewOp<mlir::LLVM::NullOp>(absent, ty);
420ad7ceSAndrzej Warzynski    }
420ad7ceSAndrzej Warzynski    return success();
420ad7ceSAndrzej Warzynski  }
420ad7ceSAndrzej Warzynski};
420ad7ceSAndrzej Warzynski
0c4a7a52SValentin Clement// Lower `fir.address_of` operation to `llvm.address_of` operation.
044d5b5dSValentin Clementstruct AddrOfOpConversion : public FIROpConversion<fir::AddrOfOp> {
044d5b5dSValentin Clement  using FIROpConversion::FIROpConversion;
044d5b5dSValentin Clement
044d5b5dSValentin Clement  mlir::LogicalResult
044d5b5dSValentin Clement  matchAndRewrite(fir::AddrOfOp addr, OpAdaptor adaptor,
044d5b5dSValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
044d5b5dSValentin Clement    auto ty = convertType(addr.getType());
044d5b5dSValentin Clement    rewriter.replaceOpWithNewOp<mlir::LLVM::AddressOfOp>(
044d5b5dSValentin Clement        addr, ty, addr.symbol().getRootReference().getValue());
044d5b5dSValentin Clement    return success();
044d5b5dSValentin Clement  }
044d5b5dSValentin Clement};
1e6d9c06SDiana Picus} // namespace
1e6d9c06SDiana Picus
1e6d9c06SDiana Picus/// Lookup the function to compute the memory size of this parametric derived
1e6d9c06SDiana Picus/// type. The size of the object may depend on the LEN type parameters of the
1e6d9c06SDiana Picus/// derived type.
1e6d9c06SDiana Picusstatic mlir::LLVM::LLVMFuncOp
1e6d9c06SDiana PicusgetDependentTypeMemSizeFn(fir::RecordType recTy, fir::AllocaOp op,
1e6d9c06SDiana Picus                          mlir::ConversionPatternRewriter &rewriter) {
1e6d9c06SDiana Picus  auto module = op->getParentOfType<mlir::ModuleOp>();
1e6d9c06SDiana Picus  std::string name = recTy.getName().str() + "P.mem.size";
1e6d9c06SDiana Picus  return module.lookupSymbol<mlir::LLVM::LLVMFuncOp>(name);
1e6d9c06SDiana Picus}
1e6d9c06SDiana Picus
1e6d9c06SDiana Picusnamespace {
1e6d9c06SDiana Picus/// convert to LLVM IR dialect `alloca`
1e6d9c06SDiana Picusstruct AllocaOpConversion : public FIROpConversion<fir::AllocaOp> {
1e6d9c06SDiana Picus  using FIROpConversion::FIROpConversion;
1e6d9c06SDiana Picus
1e6d9c06SDiana Picus  mlir::LogicalResult
1e6d9c06SDiana Picus  matchAndRewrite(fir::AllocaOp alloc, OpAdaptor adaptor,
1e6d9c06SDiana Picus                  mlir::ConversionPatternRewriter &rewriter) const override {
1e6d9c06SDiana Picus    mlir::ValueRange operands = adaptor.getOperands();
1e6d9c06SDiana Picus    auto loc = alloc.getLoc();
1e6d9c06SDiana Picus    mlir::Type ity = lowerTy().indexType();
1e6d9c06SDiana Picus    unsigned i = 0;
1e6d9c06SDiana Picus    mlir::Value size = genConstantIndex(loc, ity, rewriter, 1).getResult();
1e6d9c06SDiana Picus    mlir::Type ty = convertType(alloc.getType());
1e6d9c06SDiana Picus    mlir::Type resultTy = ty;
1e6d9c06SDiana Picus    if (alloc.hasLenParams()) {
1e6d9c06SDiana Picus      unsigned end = alloc.numLenParams();
1e6d9c06SDiana Picus      llvm::SmallVector<mlir::Value> lenParams;
1e6d9c06SDiana Picus      for (; i < end; ++i)
1e6d9c06SDiana Picus        lenParams.push_back(operands[i]);
1e6d9c06SDiana Picus      mlir::Type scalarType = fir::unwrapSequenceType(alloc.getInType());
1e6d9c06SDiana Picus      if (auto chrTy = scalarType.dyn_cast<fir::CharacterType>()) {
1e6d9c06SDiana Picus        fir::CharacterType rawCharTy = fir::CharacterType::getUnknownLen(
1e6d9c06SDiana Picus            chrTy.getContext(), chrTy.getFKind());
1e6d9c06SDiana Picus        ty = mlir::LLVM::LLVMPointerType::get(convertType(rawCharTy));
1e6d9c06SDiana Picus        assert(end == 1);
1e6d9c06SDiana Picus        size = integerCast(loc, rewriter, ity, lenParams[0]);
1e6d9c06SDiana Picus      } else if (auto recTy = scalarType.dyn_cast<fir::RecordType>()) {
1e6d9c06SDiana Picus        mlir::LLVM::LLVMFuncOp memSizeFn =
1e6d9c06SDiana Picus            getDependentTypeMemSizeFn(recTy, alloc, rewriter);
1e6d9c06SDiana Picus        if (!memSizeFn)
1e6d9c06SDiana Picus          emitError(loc, "did not find allocation function");
1e6d9c06SDiana Picus        mlir::NamedAttribute attr = rewriter.getNamedAttr(
1e6d9c06SDiana Picus            "callee", mlir::SymbolRefAttr::get(memSizeFn));
1e6d9c06SDiana Picus        auto call = rewriter.create<mlir::LLVM::CallOp>(
1e6d9c06SDiana Picus            loc, ity, lenParams, llvm::ArrayRef<mlir::NamedAttribute>{attr});
1e6d9c06SDiana Picus        size = call.getResult(0);
1e6d9c06SDiana Picus        ty = mlir::LLVM::LLVMPointerType::get(
1e6d9c06SDiana Picus            mlir::IntegerType::get(alloc.getContext(), 8));
1e6d9c06SDiana Picus      } else {
1e6d9c06SDiana Picus        return emitError(loc, "unexpected type ")
1e6d9c06SDiana Picus               << scalarType << " with type parameters";
1e6d9c06SDiana Picus      }
1e6d9c06SDiana Picus    }
1e6d9c06SDiana Picus    if (alloc.hasShapeOperands()) {
1e6d9c06SDiana Picus      mlir::Type allocEleTy = fir::unwrapRefType(alloc.getType());
1e6d9c06SDiana Picus      // Scale the size by constant factors encoded in the array type.
1e6d9c06SDiana Picus      if (auto seqTy = allocEleTy.dyn_cast<fir::SequenceType>()) {
1e6d9c06SDiana Picus        fir::SequenceType::Extent constSize = 1;
1e6d9c06SDiana Picus        for (auto extent : seqTy.getShape())
1e6d9c06SDiana Picus          if (extent != fir::SequenceType::getUnknownExtent())
1e6d9c06SDiana Picus            constSize *= extent;
1e6d9c06SDiana Picus        mlir::Value constVal{
1e6d9c06SDiana Picus            genConstantIndex(loc, ity, rewriter, constSize).getResult()};
1e6d9c06SDiana Picus        size = rewriter.create<mlir::LLVM::MulOp>(loc, ity, size, constVal);
1e6d9c06SDiana Picus      }
1e6d9c06SDiana Picus      unsigned end = operands.size();
1e6d9c06SDiana Picus      for (; i < end; ++i)
1e6d9c06SDiana Picus        size = rewriter.create<mlir::LLVM::MulOp>(
1e6d9c06SDiana Picus            loc, ity, size, integerCast(loc, rewriter, ity, operands[i]));
1e6d9c06SDiana Picus    }
1e6d9c06SDiana Picus    if (ty == resultTy) {
1e6d9c06SDiana Picus      // Do not emit the bitcast if ty and resultTy are the same.
1e6d9c06SDiana Picus      rewriter.replaceOpWithNewOp<mlir::LLVM::AllocaOp>(alloc, ty, size,
1e6d9c06SDiana Picus                                                        alloc->getAttrs());
1e6d9c06SDiana Picus    } else {
1e6d9c06SDiana Picus      auto al = rewriter.create<mlir::LLVM::AllocaOp>(loc, ty, size,
1e6d9c06SDiana Picus                                                      alloc->getAttrs());
1e6d9c06SDiana Picus      rewriter.replaceOpWithNewOp<mlir::LLVM::BitcastOp>(alloc, resultTy, al);
1e6d9c06SDiana Picus    }
1e6d9c06SDiana Picus    return success();
1e6d9c06SDiana Picus  }
1e6d9c06SDiana Picus};
044d5b5dSValentin Clement
df3b9810SValentin Clement/// Lower `fir.box_addr` to the sequence of operations to extract the first
df3b9810SValentin Clement/// element of the box.
df3b9810SValentin Clementstruct BoxAddrOpConversion : public FIROpConversion<fir::BoxAddrOp> {
df3b9810SValentin Clement  using FIROpConversion::FIROpConversion;
df3b9810SValentin Clement
df3b9810SValentin Clement  mlir::LogicalResult
df3b9810SValentin Clement  matchAndRewrite(fir::BoxAddrOp boxaddr, OpAdaptor adaptor,
df3b9810SValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
df3b9810SValentin Clement    mlir::Value a = adaptor.getOperands()[0];
df3b9810SValentin Clement    auto loc = boxaddr.getLoc();
df3b9810SValentin Clement    mlir::Type ty = convertType(boxaddr.getType());
df3b9810SValentin Clement    if (auto argty = boxaddr.val().getType().dyn_cast<fir::BoxType>()) {
df3b9810SValentin Clement      rewriter.replaceOp(boxaddr, loadBaseAddrFromBox(loc, ty, a, rewriter));
df3b9810SValentin Clement    } else {
df3b9810SValentin Clement      auto c0attr = rewriter.getI32IntegerAttr(0);
df3b9810SValentin Clement      auto c0 = mlir::ArrayAttr::get(boxaddr.getContext(), c0attr);
df3b9810SValentin Clement      rewriter.replaceOpWithNewOp<mlir::LLVM::ExtractValueOp>(boxaddr, ty, a,
df3b9810SValentin Clement                                                              c0);
df3b9810SValentin Clement    }
df3b9810SValentin Clement    return success();
df3b9810SValentin Clement  }
df3b9810SValentin Clement};
df3b9810SValentin Clement
df3b9810SValentin Clement/// Lower `fir.box_dims` to a sequence of operations to extract the requested
df3b9810SValentin Clement/// dimension infomartion from the boxed value.
df3b9810SValentin Clement/// Result in a triple set of GEPs and loads.
df3b9810SValentin Clementstruct BoxDimsOpConversion : public FIROpConversion<fir::BoxDimsOp> {
df3b9810SValentin Clement  using FIROpConversion::FIROpConversion;
df3b9810SValentin Clement
df3b9810SValentin Clement  mlir::LogicalResult
df3b9810SValentin Clement  matchAndRewrite(fir::BoxDimsOp boxdims, OpAdaptor adaptor,
df3b9810SValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
df3b9810SValentin Clement    SmallVector<mlir::Type, 3> resultTypes = {
df3b9810SValentin Clement        convertType(boxdims.getResult(0).getType()),
df3b9810SValentin Clement        convertType(boxdims.getResult(1).getType()),
df3b9810SValentin Clement        convertType(boxdims.getResult(2).getType()),
df3b9810SValentin Clement    };
df3b9810SValentin Clement    auto results =
df3b9810SValentin Clement        getDimsFromBox(boxdims.getLoc(), resultTypes, adaptor.getOperands()[0],
df3b9810SValentin Clement                       adaptor.getOperands()[1], rewriter);
df3b9810SValentin Clement    rewriter.replaceOp(boxdims, results);
df3b9810SValentin Clement    return success();
df3b9810SValentin Clement  }
df3b9810SValentin Clement};
df3b9810SValentin Clement
df3b9810SValentin Clement/// Lower `fir.box_elesize` to a sequence of operations ro extract the size of
df3b9810SValentin Clement/// an element in the boxed value.
df3b9810SValentin Clementstruct BoxEleSizeOpConversion : public FIROpConversion<fir::BoxEleSizeOp> {
df3b9810SValentin Clement  using FIROpConversion::FIROpConversion;
df3b9810SValentin Clement
df3b9810SValentin Clement  mlir::LogicalResult
df3b9810SValentin Clement  matchAndRewrite(fir::BoxEleSizeOp boxelesz, OpAdaptor adaptor,
df3b9810SValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
df3b9810SValentin Clement    mlir::Value a = adaptor.getOperands()[0];
df3b9810SValentin Clement    auto loc = boxelesz.getLoc();
df3b9810SValentin Clement    auto ty = convertType(boxelesz.getType());
b6e44ecdSValentin Clement    auto elemSize = getValueFromBox(loc, a, ty, rewriter, kElemLenPosInBox);
b6e44ecdSValentin Clement    rewriter.replaceOp(boxelesz, elemSize);
b6e44ecdSValentin Clement    return success();
b6e44ecdSValentin Clement  }
b6e44ecdSValentin Clement};
b6e44ecdSValentin Clement
b6e44ecdSValentin Clement/// Lower `fir.box_isalloc` to a sequence of operations to determine if the
b6e44ecdSValentin Clement/// boxed value was from an ALLOCATABLE entity.
b6e44ecdSValentin Clementstruct BoxIsAllocOpConversion : public FIROpConversion<fir::BoxIsAllocOp> {
b6e44ecdSValentin Clement  using FIROpConversion::FIROpConversion;
b6e44ecdSValentin Clement
b6e44ecdSValentin Clement  mlir::LogicalResult
b6e44ecdSValentin Clement  matchAndRewrite(fir::BoxIsAllocOp boxisalloc, OpAdaptor adaptor,
b6e44ecdSValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
b6e44ecdSValentin Clement    mlir::Value box = adaptor.getOperands()[0];
b6e44ecdSValentin Clement    auto loc = boxisalloc.getLoc();
b6e44ecdSValentin Clement    mlir::Value check =
b6e44ecdSValentin Clement        genBoxAttributeCheck(loc, box, rewriter, kAttrAllocatable);
b6e44ecdSValentin Clement    rewriter.replaceOp(boxisalloc, check);
b6e44ecdSValentin Clement    return success();
b6e44ecdSValentin Clement  }
b6e44ecdSValentin Clement};
b6e44ecdSValentin Clement
b6e44ecdSValentin Clement/// Lower `fir.box_isarray` to a sequence of operations to determine if the
b6e44ecdSValentin Clement/// boxed is an array.
b6e44ecdSValentin Clementstruct BoxIsArrayOpConversion : public FIROpConversion<fir::BoxIsArrayOp> {
b6e44ecdSValentin Clement  using FIROpConversion::FIROpConversion;
b6e44ecdSValentin Clement
b6e44ecdSValentin Clement  mlir::LogicalResult
b6e44ecdSValentin Clement  matchAndRewrite(fir::BoxIsArrayOp boxisarray, OpAdaptor adaptor,
b6e44ecdSValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
b6e44ecdSValentin Clement    mlir::Value a = adaptor.getOperands()[0];
b6e44ecdSValentin Clement    auto loc = boxisarray.getLoc();
b6e44ecdSValentin Clement    auto rank =
b6e44ecdSValentin Clement        getValueFromBox(loc, a, rewriter.getI32Type(), rewriter, kRankPosInBox);
b6e44ecdSValentin Clement    auto c0 = genConstantOffset(loc, rewriter, 0);
b6e44ecdSValentin Clement    rewriter.replaceOpWithNewOp<mlir::LLVM::ICmpOp>(
b6e44ecdSValentin Clement        boxisarray, mlir::LLVM::ICmpPredicate::ne, rank, c0);
b6e44ecdSValentin Clement    return success();
b6e44ecdSValentin Clement  }
b6e44ecdSValentin Clement};
b6e44ecdSValentin Clement
b6e44ecdSValentin Clement/// Lower `fir.box_isptr` to a sequence of operations to determined if the
b6e44ecdSValentin Clement/// boxed value was from a POINTER entity.
b6e44ecdSValentin Clementstruct BoxIsPtrOpConversion : public FIROpConversion<fir::BoxIsPtrOp> {
b6e44ecdSValentin Clement  using FIROpConversion::FIROpConversion;
b6e44ecdSValentin Clement
b6e44ecdSValentin Clement  mlir::LogicalResult
b6e44ecdSValentin Clement  matchAndRewrite(fir::BoxIsPtrOp boxisptr, OpAdaptor adaptor,
b6e44ecdSValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
b6e44ecdSValentin Clement    mlir::Value box = adaptor.getOperands()[0];
b6e44ecdSValentin Clement    auto loc = boxisptr.getLoc();
b6e44ecdSValentin Clement    mlir::Value check = genBoxAttributeCheck(loc, box, rewriter, kAttrPointer);
b6e44ecdSValentin Clement    rewriter.replaceOp(boxisptr, check);
df3b9810SValentin Clement    return success();
df3b9810SValentin Clement  }
df3b9810SValentin Clement};
df3b9810SValentin Clement
df3b9810SValentin Clement/// Lower `fir.box_rank` to the sequence of operation to extract the rank from
df3b9810SValentin Clement/// the box.
df3b9810SValentin Clementstruct BoxRankOpConversion : public FIROpConversion<fir::BoxRankOp> {
df3b9810SValentin Clement  using FIROpConversion::FIROpConversion;
df3b9810SValentin Clement
df3b9810SValentin Clement  mlir::LogicalResult
df3b9810SValentin Clement  matchAndRewrite(fir::BoxRankOp boxrank, OpAdaptor adaptor,
df3b9810SValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
df3b9810SValentin Clement    mlir::Value a = adaptor.getOperands()[0];
df3b9810SValentin Clement    auto loc = boxrank.getLoc();
df3b9810SValentin Clement    mlir::Type ty = convertType(boxrank.getType());
b6e44ecdSValentin Clement    auto result = getValueFromBox(loc, a, ty, rewriter, kRankPosInBox);
df3b9810SValentin Clement    rewriter.replaceOp(boxrank, result);
df3b9810SValentin Clement    return success();
df3b9810SValentin Clement  }
df3b9810SValentin Clement};
df3b9810SValentin Clement
ddd11b9aSAndrzej Warzynski// `fir.call` -> `llvm.call`
ddd11b9aSAndrzej Warzynskistruct CallOpConversion : public FIROpConversion<fir::CallOp> {
ddd11b9aSAndrzej Warzynski  using FIROpConversion::FIROpConversion;
ddd11b9aSAndrzej Warzynski
ddd11b9aSAndrzej Warzynski  mlir::LogicalResult
ddd11b9aSAndrzej Warzynski  matchAndRewrite(fir::CallOp call, OpAdaptor adaptor,
ddd11b9aSAndrzej Warzynski                  mlir::ConversionPatternRewriter &rewriter) const override {
ddd11b9aSAndrzej Warzynski    SmallVector<mlir::Type> resultTys;
ddd11b9aSAndrzej Warzynski    for (auto r : call.getResults())
ddd11b9aSAndrzej Warzynski      resultTys.push_back(convertType(r.getType()));
ddd11b9aSAndrzej Warzynski    rewriter.replaceOpWithNewOp<mlir::LLVM::CallOp>(
ddd11b9aSAndrzej Warzynski        call, resultTys, adaptor.getOperands(), call->getAttrs());
ddd11b9aSAndrzej Warzynski    return success();
ddd11b9aSAndrzej Warzynski  }
ddd11b9aSAndrzej Warzynski};
ddd11b9aSAndrzej Warzynski
092cee5fSValentin Clementstatic mlir::Type getComplexEleTy(mlir::Type complex) {
092cee5fSValentin Clement  if (auto cc = complex.dyn_cast<mlir::ComplexType>())
092cee5fSValentin Clement    return cc.getElementType();
092cee5fSValentin Clement  return complex.cast<fir::ComplexType>().getElementType();
092cee5fSValentin Clement}
092cee5fSValentin Clement
*f1dfc027SDiana Picus/// Compare complex values
*f1dfc027SDiana Picus///
*f1dfc027SDiana Picus/// Per 10.1, the only comparisons available are .EQ. (oeq) and .NE. (une).
*f1dfc027SDiana Picus///
*f1dfc027SDiana Picus/// For completeness, all other comparison are done on the real component only.
*f1dfc027SDiana Picusstruct CmpcOpConversion : public FIROpConversion<fir::CmpcOp> {
*f1dfc027SDiana Picus  using FIROpConversion::FIROpConversion;
*f1dfc027SDiana Picus
*f1dfc027SDiana Picus  mlir::LogicalResult
*f1dfc027SDiana Picus  matchAndRewrite(fir::CmpcOp cmp, OpAdaptor adaptor,
*f1dfc027SDiana Picus                  mlir::ConversionPatternRewriter &rewriter) const override {
*f1dfc027SDiana Picus    mlir::ValueRange operands = adaptor.getOperands();
*f1dfc027SDiana Picus    mlir::MLIRContext *ctxt = cmp.getContext();
*f1dfc027SDiana Picus    mlir::Type eleTy = convertType(getComplexEleTy(cmp.lhs().getType()));
*f1dfc027SDiana Picus    mlir::Type resTy = convertType(cmp.getType());
*f1dfc027SDiana Picus    mlir::Location loc = cmp.getLoc();
*f1dfc027SDiana Picus    auto pos0 = mlir::ArrayAttr::get(ctxt, rewriter.getI32IntegerAttr(0));
*f1dfc027SDiana Picus    SmallVector<mlir::Value, 2> rp{rewriter.create<mlir::LLVM::ExtractValueOp>(
*f1dfc027SDiana Picus                                       loc, eleTy, operands[0], pos0),
*f1dfc027SDiana Picus                                   rewriter.create<mlir::LLVM::ExtractValueOp>(
*f1dfc027SDiana Picus                                       loc, eleTy, operands[1], pos0)};
*f1dfc027SDiana Picus    auto rcp =
*f1dfc027SDiana Picus        rewriter.create<mlir::LLVM::FCmpOp>(loc, resTy, rp, cmp->getAttrs());
*f1dfc027SDiana Picus    auto pos1 = mlir::ArrayAttr::get(ctxt, rewriter.getI32IntegerAttr(1));
*f1dfc027SDiana Picus    SmallVector<mlir::Value, 2> ip{rewriter.create<mlir::LLVM::ExtractValueOp>(
*f1dfc027SDiana Picus                                       loc, eleTy, operands[0], pos1),
*f1dfc027SDiana Picus                                   rewriter.create<mlir::LLVM::ExtractValueOp>(
*f1dfc027SDiana Picus                                       loc, eleTy, operands[1], pos1)};
*f1dfc027SDiana Picus    auto icp =
*f1dfc027SDiana Picus        rewriter.create<mlir::LLVM::FCmpOp>(loc, resTy, ip, cmp->getAttrs());
*f1dfc027SDiana Picus    SmallVector<mlir::Value, 2> cp{rcp, icp};
*f1dfc027SDiana Picus    switch (cmp.getPredicate()) {
*f1dfc027SDiana Picus    case mlir::arith::CmpFPredicate::OEQ: // .EQ.
*f1dfc027SDiana Picus      rewriter.replaceOpWithNewOp<mlir::LLVM::AndOp>(cmp, resTy, cp);
*f1dfc027SDiana Picus      break;
*f1dfc027SDiana Picus    case mlir::arith::CmpFPredicate::UNE: // .NE.
*f1dfc027SDiana Picus      rewriter.replaceOpWithNewOp<mlir::LLVM::OrOp>(cmp, resTy, cp);
*f1dfc027SDiana Picus      break;
*f1dfc027SDiana Picus    default:
*f1dfc027SDiana Picus      rewriter.replaceOp(cmp, rcp.getResult());
*f1dfc027SDiana Picus      break;
*f1dfc027SDiana Picus    }
*f1dfc027SDiana Picus    return success();
*f1dfc027SDiana Picus  }
*f1dfc027SDiana Picus};
*f1dfc027SDiana Picus
092cee5fSValentin Clement/// convert value of from-type to value of to-type
092cee5fSValentin Clementstruct ConvertOpConversion : public FIROpConversion<fir::ConvertOp> {
092cee5fSValentin Clement  using FIROpConversion::FIROpConversion;
092cee5fSValentin Clement
092cee5fSValentin Clement  static bool isFloatingPointTy(mlir::Type ty) {
092cee5fSValentin Clement    return ty.isa<mlir::FloatType>();
092cee5fSValentin Clement  }
092cee5fSValentin Clement
092cee5fSValentin Clement  mlir::LogicalResult
092cee5fSValentin Clement  matchAndRewrite(fir::ConvertOp convert, OpAdaptor adaptor,
092cee5fSValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
092cee5fSValentin Clement    auto fromTy = convertType(convert.value().getType());
092cee5fSValentin Clement    auto toTy = convertType(convert.res().getType());
092cee5fSValentin Clement    mlir::Value op0 = adaptor.getOperands()[0];
092cee5fSValentin Clement    if (fromTy == toTy) {
092cee5fSValentin Clement      rewriter.replaceOp(convert, op0);
092cee5fSValentin Clement      return success();
092cee5fSValentin Clement    }
092cee5fSValentin Clement    auto loc = convert.getLoc();
092cee5fSValentin Clement    auto convertFpToFp = [&](mlir::Value val, unsigned fromBits,
092cee5fSValentin Clement                             unsigned toBits, mlir::Type toTy) -> mlir::Value {
092cee5fSValentin Clement      if (fromBits == toBits) {
092cee5fSValentin Clement        // TODO: Converting between two floating-point representations with the
092cee5fSValentin Clement        // same bitwidth is not allowed for now.
092cee5fSValentin Clement        mlir::emitError(loc,
092cee5fSValentin Clement                        "cannot implicitly convert between two floating-point "
092cee5fSValentin Clement                        "representations of the same bitwidth");
092cee5fSValentin Clement        return {};
092cee5fSValentin Clement      }
092cee5fSValentin Clement      if (fromBits > toBits)
092cee5fSValentin Clement        return rewriter.create<mlir::LLVM::FPTruncOp>(loc, toTy, val);
092cee5fSValentin Clement      return rewriter.create<mlir::LLVM::FPExtOp>(loc, toTy, val);
092cee5fSValentin Clement    };
092cee5fSValentin Clement    // Complex to complex conversion.
092cee5fSValentin Clement    if (fir::isa_complex(convert.value().getType()) &&
092cee5fSValentin Clement        fir::isa_complex(convert.res().getType())) {
092cee5fSValentin Clement      // Special case: handle the conversion of a complex such that both the
092cee5fSValentin Clement      // real and imaginary parts are converted together.
092cee5fSValentin Clement      auto zero = mlir::ArrayAttr::get(convert.getContext(),
092cee5fSValentin Clement                                       rewriter.getI32IntegerAttr(0));
092cee5fSValentin Clement      auto one = mlir::ArrayAttr::get(convert.getContext(),
092cee5fSValentin Clement                                      rewriter.getI32IntegerAttr(1));
092cee5fSValentin Clement      auto ty = convertType(getComplexEleTy(convert.value().getType()));
092cee5fSValentin Clement      auto rp = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, ty, op0, zero);
092cee5fSValentin Clement      auto ip = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, ty, op0, one);
092cee5fSValentin Clement      auto nt = convertType(getComplexEleTy(convert.res().getType()));
092cee5fSValentin Clement      auto fromBits = mlir::LLVM::getPrimitiveTypeSizeInBits(ty);
092cee5fSValentin Clement      auto toBits = mlir::LLVM::getPrimitiveTypeSizeInBits(nt);
092cee5fSValentin Clement      auto rc = convertFpToFp(rp, fromBits, toBits, nt);
092cee5fSValentin Clement      auto ic = convertFpToFp(ip, fromBits, toBits, nt);
092cee5fSValentin Clement      auto un = rewriter.create<mlir::LLVM::UndefOp>(loc, toTy);
092cee5fSValentin Clement      auto i1 =
092cee5fSValentin Clement          rewriter.create<mlir::LLVM::InsertValueOp>(loc, toTy, un, rc, zero);
092cee5fSValentin Clement      rewriter.replaceOpWithNewOp<mlir::LLVM::InsertValueOp>(convert, toTy, i1,
092cee5fSValentin Clement                                                             ic, one);
092cee5fSValentin Clement      return mlir::success();
092cee5fSValentin Clement    }
092cee5fSValentin Clement    // Floating point to floating point conversion.
092cee5fSValentin Clement    if (isFloatingPointTy(fromTy)) {
092cee5fSValentin Clement      if (isFloatingPointTy(toTy)) {
092cee5fSValentin Clement        auto fromBits = mlir::LLVM::getPrimitiveTypeSizeInBits(fromTy);
092cee5fSValentin Clement        auto toBits = mlir::LLVM::getPrimitiveTypeSizeInBits(toTy);
092cee5fSValentin Clement        auto v = convertFpToFp(op0, fromBits, toBits, toTy);
092cee5fSValentin Clement        rewriter.replaceOp(convert, v);
092cee5fSValentin Clement        return mlir::success();
092cee5fSValentin Clement      }
092cee5fSValentin Clement      if (toTy.isa<mlir::IntegerType>()) {
092cee5fSValentin Clement        rewriter.replaceOpWithNewOp<mlir::LLVM::FPToSIOp>(convert, toTy, op0);
092cee5fSValentin Clement        return mlir::success();
092cee5fSValentin Clement      }
092cee5fSValentin Clement    } else if (fromTy.isa<mlir::IntegerType>()) {
092cee5fSValentin Clement      // Integer to integer conversion.
092cee5fSValentin Clement      if (toTy.isa<mlir::IntegerType>()) {
092cee5fSValentin Clement        auto fromBits = mlir::LLVM::getPrimitiveTypeSizeInBits(fromTy);
092cee5fSValentin Clement        auto toBits = mlir::LLVM::getPrimitiveTypeSizeInBits(toTy);
092cee5fSValentin Clement        assert(fromBits != toBits);
092cee5fSValentin Clement        if (fromBits > toBits) {
092cee5fSValentin Clement          rewriter.replaceOpWithNewOp<mlir::LLVM::TruncOp>(convert, toTy, op0);
092cee5fSValentin Clement          return mlir::success();
092cee5fSValentin Clement        }
092cee5fSValentin Clement        rewriter.replaceOpWithNewOp<mlir::LLVM::SExtOp>(convert, toTy, op0);
092cee5fSValentin Clement        return mlir::success();
092cee5fSValentin Clement      }
092cee5fSValentin Clement      // Integer to floating point conversion.
092cee5fSValentin Clement      if (isFloatingPointTy(toTy)) {
092cee5fSValentin Clement        rewriter.replaceOpWithNewOp<mlir::LLVM::SIToFPOp>(convert, toTy, op0);
092cee5fSValentin Clement        return mlir::success();
092cee5fSValentin Clement      }
092cee5fSValentin Clement      // Integer to pointer conversion.
092cee5fSValentin Clement      if (toTy.isa<mlir::LLVM::LLVMPointerType>()) {
092cee5fSValentin Clement        rewriter.replaceOpWithNewOp<mlir::LLVM::IntToPtrOp>(convert, toTy, op0);
092cee5fSValentin Clement        return mlir::success();
092cee5fSValentin Clement      }
092cee5fSValentin Clement    } else if (fromTy.isa<mlir::LLVM::LLVMPointerType>()) {
092cee5fSValentin Clement      // Pointer to integer conversion.
092cee5fSValentin Clement      if (toTy.isa<mlir::IntegerType>()) {
092cee5fSValentin Clement        rewriter.replaceOpWithNewOp<mlir::LLVM::PtrToIntOp>(convert, toTy, op0);
092cee5fSValentin Clement        return mlir::success();
092cee5fSValentin Clement      }
092cee5fSValentin Clement      // Pointer to pointer conversion.
092cee5fSValentin Clement      if (toTy.isa<mlir::LLVM::LLVMPointerType>()) {
092cee5fSValentin Clement        rewriter.replaceOpWithNewOp<mlir::LLVM::BitcastOp>(convert, toTy, op0);
092cee5fSValentin Clement        return mlir::success();
092cee5fSValentin Clement      }
092cee5fSValentin Clement    }
092cee5fSValentin Clement    return emitError(loc) << "cannot convert " << fromTy << " to " << toTy;
092cee5fSValentin Clement  }
092cee5fSValentin Clement};
092cee5fSValentin Clement
9534e361SValentin Clement/// Lower `fir.dispatch` operation. A virtual call to a method in a dispatch
9534e361SValentin Clement/// table.
9534e361SValentin Clementstruct DispatchOpConversion : public FIROpConversion<fir::DispatchOp> {
9534e361SValentin Clement  using FIROpConversion::FIROpConversion;
9534e361SValentin Clement
9534e361SValentin Clement  mlir::LogicalResult
9534e361SValentin Clement  matchAndRewrite(fir::DispatchOp dispatch, OpAdaptor adaptor,
9534e361SValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
9534e361SValentin Clement    return rewriter.notifyMatchFailure(
9534e361SValentin Clement        dispatch, "fir.dispatch codegen is not implemented yet");
9534e361SValentin Clement  }
9534e361SValentin Clement};
9534e361SValentin Clement
9534e361SValentin Clement/// Lower `fir.dispatch_table` operation. The dispatch table for a Fortran
9534e361SValentin Clement/// derived type.
9534e361SValentin Clementstruct DispatchTableOpConversion
9534e361SValentin Clement    : public FIROpConversion<fir::DispatchTableOp> {
9534e361SValentin Clement  using FIROpConversion::FIROpConversion;
9534e361SValentin Clement
9534e361SValentin Clement  mlir::LogicalResult
9534e361SValentin Clement  matchAndRewrite(fir::DispatchTableOp dispTab, OpAdaptor adaptor,
9534e361SValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
9534e361SValentin Clement    return rewriter.notifyMatchFailure(
9534e361SValentin Clement        dispTab, "fir.dispatch_table codegen is not implemented yet");
9534e361SValentin Clement  }
9534e361SValentin Clement};
9534e361SValentin Clement
9534e361SValentin Clement/// Lower `fir.dt_entry` operation. An entry in a dispatch table; binds a
9534e361SValentin Clement/// method-name to a function.
9534e361SValentin Clementstruct DTEntryOpConversion : public FIROpConversion<fir::DTEntryOp> {
9534e361SValentin Clement  using FIROpConversion::FIROpConversion;
9534e361SValentin Clement
9534e361SValentin Clement  mlir::LogicalResult
9534e361SValentin Clement  matchAndRewrite(fir::DTEntryOp dtEnt, OpAdaptor adaptor,
9534e361SValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
9534e361SValentin Clement    return rewriter.notifyMatchFailure(
9534e361SValentin Clement        dtEnt, "fir.dt_entry codegen is not implemented yet");
9534e361SValentin Clement  }
9534e361SValentin Clement};
9534e361SValentin Clement
677df8c7SValentin Clement/// Lower `fir.global_len` operation.
677df8c7SValentin Clementstruct GlobalLenOpConversion : public FIROpConversion<fir::GlobalLenOp> {
677df8c7SValentin Clement  using FIROpConversion::FIROpConversion;
677df8c7SValentin Clement
677df8c7SValentin Clement  mlir::LogicalResult
677df8c7SValentin Clement  matchAndRewrite(fir::GlobalLenOp globalLen, OpAdaptor adaptor,
677df8c7SValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
677df8c7SValentin Clement    return rewriter.notifyMatchFailure(
677df8c7SValentin Clement        globalLen, "fir.global_len codegen is not implemented yet");
677df8c7SValentin Clement  }
677df8c7SValentin Clement};
677df8c7SValentin Clement
0c4a7a52SValentin Clement/// Lower `fir.has_value` operation to `llvm.return` operation.
044d5b5dSValentin Clementstruct HasValueOpConversion : public FIROpConversion<fir::HasValueOp> {
044d5b5dSValentin Clement  using FIROpConversion::FIROpConversion;
044d5b5dSValentin Clement
044d5b5dSValentin Clement  mlir::LogicalResult
044d5b5dSValentin Clement  matchAndRewrite(fir::HasValueOp op, OpAdaptor adaptor,
044d5b5dSValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
044d5b5dSValentin Clement    rewriter.replaceOpWithNewOp<LLVM::ReturnOp>(op, adaptor.getOperands());
044d5b5dSValentin Clement    return success();
044d5b5dSValentin Clement  }
044d5b5dSValentin Clement};
044d5b5dSValentin Clement
0c4a7a52SValentin Clement/// Lower `fir.global` operation to `llvm.global` operation.
0c4a7a52SValentin Clement/// `fir.insert_on_range` operations are replaced with constant dense attribute
0c4a7a52SValentin Clement/// if they are applied on the full range.
044d5b5dSValentin Clementstruct GlobalOpConversion : public FIROpConversion<fir::GlobalOp> {
044d5b5dSValentin Clement  using FIROpConversion::FIROpConversion;
044d5b5dSValentin Clement
044d5b5dSValentin Clement  mlir::LogicalResult
044d5b5dSValentin Clement  matchAndRewrite(fir::GlobalOp global, OpAdaptor adaptor,
044d5b5dSValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
044d5b5dSValentin Clement    auto tyAttr = convertType(global.getType());
044d5b5dSValentin Clement    if (global.getType().isa<fir::BoxType>())
044d5b5dSValentin Clement      tyAttr = tyAttr.cast<mlir::LLVM::LLVMPointerType>().getElementType();
044d5b5dSValentin Clement    auto loc = global.getLoc();
044d5b5dSValentin Clement    mlir::Attribute initAttr{};
044d5b5dSValentin Clement    if (global.initVal())
044d5b5dSValentin Clement      initAttr = global.initVal().getValue();
044d5b5dSValentin Clement    auto linkage = convertLinkage(global.linkName());
044d5b5dSValentin Clement    auto isConst = global.constant().hasValue();
044d5b5dSValentin Clement    auto g = rewriter.create<mlir::LLVM::GlobalOp>(
044d5b5dSValentin Clement        loc, tyAttr, isConst, linkage, global.sym_name(), initAttr);
044d5b5dSValentin Clement    auto &gr = g.getInitializerRegion();
044d5b5dSValentin Clement    rewriter.inlineRegionBefore(global.region(), gr, gr.end());
044d5b5dSValentin Clement    if (!gr.empty()) {
044d5b5dSValentin Clement      // Replace insert_on_range with a constant dense attribute if the
044d5b5dSValentin Clement      // initialization is on the full range.
044d5b5dSValentin Clement      auto insertOnRangeOps = gr.front().getOps<fir::InsertOnRangeOp>();
044d5b5dSValentin Clement      for (auto insertOp : insertOnRangeOps) {
044d5b5dSValentin Clement        if (isFullRange(insertOp.coor(), insertOp.getType())) {
044d5b5dSValentin Clement          auto seqTyAttr = convertType(insertOp.getType());
044d5b5dSValentin Clement          auto *op = insertOp.val().getDefiningOp();
044d5b5dSValentin Clement          auto constant = mlir::dyn_cast<mlir::arith::ConstantOp>(op);
044d5b5dSValentin Clement          if (!constant) {
044d5b5dSValentin Clement            auto convertOp = mlir::dyn_cast<fir::ConvertOp>(op);
044d5b5dSValentin Clement            if (!convertOp)
044d5b5dSValentin Clement              continue;
044d5b5dSValentin Clement            constant = cast<mlir::arith::ConstantOp>(
044d5b5dSValentin Clement                convertOp.value().getDefiningOp());
044d5b5dSValentin Clement          }
044d5b5dSValentin Clement          mlir::Type vecType = mlir::VectorType::get(
044d5b5dSValentin Clement              insertOp.getType().getShape(), constant.getType());
044d5b5dSValentin Clement          auto denseAttr = mlir::DenseElementsAttr::get(
044d5b5dSValentin Clement              vecType.cast<ShapedType>(), constant.value());
044d5b5dSValentin Clement          rewriter.setInsertionPointAfter(insertOp);
044d5b5dSValentin Clement          rewriter.replaceOpWithNewOp<mlir::arith::ConstantOp>(
044d5b5dSValentin Clement              insertOp, seqTyAttr, denseAttr);
044d5b5dSValentin Clement        }
044d5b5dSValentin Clement      }
044d5b5dSValentin Clement    }
044d5b5dSValentin Clement    rewriter.eraseOp(global);
044d5b5dSValentin Clement    return success();
044d5b5dSValentin Clement  }
044d5b5dSValentin Clement
044d5b5dSValentin Clement  bool isFullRange(mlir::ArrayAttr indexes, fir::SequenceType seqTy) const {
044d5b5dSValentin Clement    auto extents = seqTy.getShape();
044d5b5dSValentin Clement    if (indexes.size() / 2 != extents.size())
044d5b5dSValentin Clement      return false;
044d5b5dSValentin Clement    for (unsigned i = 0; i < indexes.size(); i += 2) {
044d5b5dSValentin Clement      if (indexes[i].cast<IntegerAttr>().getInt() != 0)
044d5b5dSValentin Clement        return false;
044d5b5dSValentin Clement      if (indexes[i + 1].cast<IntegerAttr>().getInt() != extents[i / 2] - 1)
044d5b5dSValentin Clement        return false;
044d5b5dSValentin Clement    }
044d5b5dSValentin Clement    return true;
044d5b5dSValentin Clement  }
044d5b5dSValentin Clement
0c4a7a52SValentin Clement  // TODO: String comparaison should be avoided. Replace linkName with an
0c4a7a52SValentin Clement  // enumeration.
044d5b5dSValentin Clement  mlir::LLVM::Linkage convertLinkage(Optional<StringRef> optLinkage) const {
044d5b5dSValentin Clement    if (optLinkage.hasValue()) {
044d5b5dSValentin Clement      auto name = optLinkage.getValue();
044d5b5dSValentin Clement      if (name == "internal")
044d5b5dSValentin Clement        return mlir::LLVM::Linkage::Internal;
044d5b5dSValentin Clement      if (name == "linkonce")
044d5b5dSValentin Clement        return mlir::LLVM::Linkage::Linkonce;
044d5b5dSValentin Clement      if (name == "common")
044d5b5dSValentin Clement        return mlir::LLVM::Linkage::Common;
044d5b5dSValentin Clement      if (name == "weak")
044d5b5dSValentin Clement        return mlir::LLVM::Linkage::Weak;
044d5b5dSValentin Clement    }
044d5b5dSValentin Clement    return mlir::LLVM::Linkage::External;
044d5b5dSValentin Clement  }
044d5b5dSValentin Clement};
044d5b5dSValentin Clement
39f4ef81SValentin Clementvoid genCondBrOp(mlir::Location loc, mlir::Value cmp, mlir::Block *dest,
39f4ef81SValentin Clement                 Optional<mlir::ValueRange> destOps,
39f4ef81SValentin Clement                 mlir::ConversionPatternRewriter &rewriter,
39f4ef81SValentin Clement                 mlir::Block *newBlock) {
39f4ef81SValentin Clement  if (destOps.hasValue())
39f4ef81SValentin Clement    rewriter.create<mlir::LLVM::CondBrOp>(loc, cmp, dest, destOps.getValue(),
39f4ef81SValentin Clement                                          newBlock, mlir::ValueRange());
39f4ef81SValentin Clement  else
39f4ef81SValentin Clement    rewriter.create<mlir::LLVM::CondBrOp>(loc, cmp, dest, newBlock);
39f4ef81SValentin Clement}
39f4ef81SValentin Clement
39f4ef81SValentin Clementtemplate <typename A, typename B>
39f4ef81SValentin Clementvoid genBrOp(A caseOp, mlir::Block *dest, Optional<B> destOps,
39f4ef81SValentin Clement             mlir::ConversionPatternRewriter &rewriter) {
39f4ef81SValentin Clement  if (destOps.hasValue())
39f4ef81SValentin Clement    rewriter.replaceOpWithNewOp<mlir::LLVM::BrOp>(caseOp, destOps.getValue(),
39f4ef81SValentin Clement                                                  dest);
39f4ef81SValentin Clement  else
39f4ef81SValentin Clement    rewriter.replaceOpWithNewOp<mlir::LLVM::BrOp>(caseOp, llvm::None, dest);
39f4ef81SValentin Clement}
39f4ef81SValentin Clement
39f4ef81SValentin Clementvoid genCaseLadderStep(mlir::Location loc, mlir::Value cmp, mlir::Block *dest,
39f4ef81SValentin Clement                       Optional<mlir::ValueRange> destOps,
39f4ef81SValentin Clement                       mlir::ConversionPatternRewriter &rewriter) {
39f4ef81SValentin Clement  auto *thisBlock = rewriter.getInsertionBlock();
39f4ef81SValentin Clement  auto *newBlock = createBlock(rewriter, dest);
39f4ef81SValentin Clement  rewriter.setInsertionPointToEnd(thisBlock);
39f4ef81SValentin Clement  genCondBrOp(loc, cmp, dest, destOps, rewriter, newBlock);
39f4ef81SValentin Clement  rewriter.setInsertionPointToEnd(newBlock);
39f4ef81SValentin Clement}
39f4ef81SValentin Clement
39f4ef81SValentin Clement/// Conversion of `fir.select_case`
39f4ef81SValentin Clement///
39f4ef81SValentin Clement/// The `fir.select_case` operation is converted to a if-then-else ladder.
39f4ef81SValentin Clement/// Depending on the case condition type, one or several comparison and
39f4ef81SValentin Clement/// conditional branching can be generated.
39f4ef81SValentin Clement///
39f4ef81SValentin Clement/// A a point value case such as `case(4)`, a lower bound case such as
39f4ef81SValentin Clement/// `case(5:)` or an upper bound case such as `case(:3)` are converted to a
39f4ef81SValentin Clement/// simple comparison between the selector value and the constant value in the
39f4ef81SValentin Clement/// case. The block associated with the case condition is then executed if
39f4ef81SValentin Clement/// the comparison succeed otherwise it branch to the next block with the
39f4ef81SValentin Clement/// comparison for the the next case conditon.
39f4ef81SValentin Clement///
39f4ef81SValentin Clement/// A closed interval case condition such as `case(7:10)` is converted with a
39f4ef81SValentin Clement/// first comparison and conditional branching for the lower bound. If
39f4ef81SValentin Clement/// successful, it branch to a second block with the comparison for the
39f4ef81SValentin Clement/// upper bound in the same case condition.
39f4ef81SValentin Clement///
39f4ef81SValentin Clement/// TODO: lowering of CHARACTER type cases is not handled yet.
39f4ef81SValentin Clementstruct SelectCaseOpConversion : public FIROpConversion<fir::SelectCaseOp> {
39f4ef81SValentin Clement  using FIROpConversion::FIROpConversion;
39f4ef81SValentin Clement
39f4ef81SValentin Clement  mlir::LogicalResult
39f4ef81SValentin Clement  matchAndRewrite(fir::SelectCaseOp caseOp, OpAdaptor adaptor,
39f4ef81SValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
39f4ef81SValentin Clement    unsigned conds = caseOp.getNumConditions();
39f4ef81SValentin Clement    llvm::ArrayRef<mlir::Attribute> cases = caseOp.getCases().getValue();
39f4ef81SValentin Clement    // Type can be CHARACTER, INTEGER, or LOGICAL (C1145)
39f4ef81SValentin Clement    LLVM_ATTRIBUTE_UNUSED auto ty = caseOp.getSelector().getType();
39f4ef81SValentin Clement    if (ty.isa<fir::CharacterType>())
39f4ef81SValentin Clement      return rewriter.notifyMatchFailure(caseOp,
39f4ef81SValentin Clement                                         "conversion of fir.select_case with "
39f4ef81SValentin Clement                                         "character type not implemented yet");
39f4ef81SValentin Clement    mlir::Value selector = caseOp.getSelector(adaptor.getOperands());
39f4ef81SValentin Clement    auto loc = caseOp.getLoc();
39f4ef81SValentin Clement    for (unsigned t = 0; t != conds; ++t) {
39f4ef81SValentin Clement      mlir::Block *dest = caseOp.getSuccessor(t);
39f4ef81SValentin Clement      llvm::Optional<mlir::ValueRange> destOps =
39f4ef81SValentin Clement          caseOp.getSuccessorOperands(adaptor.getOperands(), t);
39f4ef81SValentin Clement      llvm::Optional<mlir::ValueRange> cmpOps =
39f4ef81SValentin Clement          *caseOp.getCompareOperands(adaptor.getOperands(), t);
39f4ef81SValentin Clement      mlir::Value caseArg = *(cmpOps.getValue().begin());
39f4ef81SValentin Clement      mlir::Attribute attr = cases[t];
39f4ef81SValentin Clement      if (attr.isa<fir::PointIntervalAttr>()) {
39f4ef81SValentin Clement        auto cmp = rewriter.create<mlir::LLVM::ICmpOp>(
39f4ef81SValentin Clement            loc, mlir::LLVM::ICmpPredicate::eq, selector, caseArg);
39f4ef81SValentin Clement        genCaseLadderStep(loc, cmp, dest, destOps, rewriter);
39f4ef81SValentin Clement        continue;
39f4ef81SValentin Clement      }
39f4ef81SValentin Clement      if (attr.isa<fir::LowerBoundAttr>()) {
39f4ef81SValentin Clement        auto cmp = rewriter.create<mlir::LLVM::ICmpOp>(
39f4ef81SValentin Clement            loc, mlir::LLVM::ICmpPredicate::sle, caseArg, selector);
39f4ef81SValentin Clement        genCaseLadderStep(loc, cmp, dest, destOps, rewriter);
39f4ef81SValentin Clement        continue;
39f4ef81SValentin Clement      }
39f4ef81SValentin Clement      if (attr.isa<fir::UpperBoundAttr>()) {
39f4ef81SValentin Clement        auto cmp = rewriter.create<mlir::LLVM::ICmpOp>(
39f4ef81SValentin Clement            loc, mlir::LLVM::ICmpPredicate::sle, selector, caseArg);
39f4ef81SValentin Clement        genCaseLadderStep(loc, cmp, dest, destOps, rewriter);
39f4ef81SValentin Clement        continue;
39f4ef81SValentin Clement      }
39f4ef81SValentin Clement      if (attr.isa<fir::ClosedIntervalAttr>()) {
39f4ef81SValentin Clement        auto cmp = rewriter.create<mlir::LLVM::ICmpOp>(
39f4ef81SValentin Clement            loc, mlir::LLVM::ICmpPredicate::sle, caseArg, selector);
39f4ef81SValentin Clement        auto *thisBlock = rewriter.getInsertionBlock();
39f4ef81SValentin Clement        auto *newBlock1 = createBlock(rewriter, dest);
39f4ef81SValentin Clement        auto *newBlock2 = createBlock(rewriter, dest);
39f4ef81SValentin Clement        rewriter.setInsertionPointToEnd(thisBlock);
39f4ef81SValentin Clement        rewriter.create<mlir::LLVM::CondBrOp>(loc, cmp, newBlock1, newBlock2);
39f4ef81SValentin Clement        rewriter.setInsertionPointToEnd(newBlock1);
39f4ef81SValentin Clement        mlir::Value caseArg0 = *(cmpOps.getValue().begin() + 1);
39f4ef81SValentin Clement        auto cmp0 = rewriter.create<mlir::LLVM::ICmpOp>(
39f4ef81SValentin Clement            loc, mlir::LLVM::ICmpPredicate::sle, selector, caseArg0);
39f4ef81SValentin Clement        genCondBrOp(loc, cmp0, dest, destOps, rewriter, newBlock2);
39f4ef81SValentin Clement        rewriter.setInsertionPointToEnd(newBlock2);
39f4ef81SValentin Clement        continue;
39f4ef81SValentin Clement      }
39f4ef81SValentin Clement      assert(attr.isa<mlir::UnitAttr>());
39f4ef81SValentin Clement      assert((t + 1 == conds) && "unit must be last");
39f4ef81SValentin Clement      genBrOp(caseOp, dest, destOps, rewriter);
39f4ef81SValentin Clement    }
39f4ef81SValentin Clement    return success();
39f4ef81SValentin Clement  }
39f4ef81SValentin Clement};
39f4ef81SValentin Clement
8c239909SValentin Clementtemplate <typename OP>
8c239909SValentin Clementvoid selectMatchAndRewrite(fir::LLVMTypeConverter &lowering, OP select,
8c239909SValentin Clement                           typename OP::Adaptor adaptor,
8c239909SValentin Clement                           mlir::ConversionPatternRewriter &rewriter) {
8c239909SValentin Clement  unsigned conds = select.getNumConditions();
8c239909SValentin Clement  auto cases = select.getCases().getValue();
8c239909SValentin Clement  mlir::Value selector = adaptor.selector();
8c239909SValentin Clement  auto loc = select.getLoc();
8c239909SValentin Clement  assert(conds > 0 && "select must have cases");
8c239909SValentin Clement
8c239909SValentin Clement  llvm::SmallVector<mlir::Block *> destinations;
8c239909SValentin Clement  llvm::SmallVector<mlir::ValueRange> destinationsOperands;
8c239909SValentin Clement  mlir::Block *defaultDestination;
8c239909SValentin Clement  mlir::ValueRange defaultOperands;
8c239909SValentin Clement  llvm::SmallVector<int32_t> caseValues;
8c239909SValentin Clement
8c239909SValentin Clement  for (unsigned t = 0; t != conds; ++t) {
8c239909SValentin Clement    mlir::Block *dest = select.getSuccessor(t);
8c239909SValentin Clement    auto destOps = select.getSuccessorOperands(adaptor.getOperands(), t);
8c239909SValentin Clement    const mlir::Attribute &attr = cases[t];
8c239909SValentin Clement    if (auto intAttr = attr.template dyn_cast<mlir::IntegerAttr>()) {
8c239909SValentin Clement      destinations.push_back(dest);
8c239909SValentin Clement      destinationsOperands.push_back(destOps.hasValue() ? *destOps
8c239909SValentin Clement                                                        : ValueRange());
8c239909SValentin Clement      caseValues.push_back(intAttr.getInt());
8c239909SValentin Clement      continue;
8c239909SValentin Clement    }
8c239909SValentin Clement    assert(attr.template dyn_cast_or_null<mlir::UnitAttr>());
8c239909SValentin Clement    assert((t + 1 == conds) && "unit must be last");
8c239909SValentin Clement    defaultDestination = dest;
8c239909SValentin Clement    defaultOperands = destOps.hasValue() ? *destOps : ValueRange();
8c239909SValentin Clement  }
8c239909SValentin Clement
8c239909SValentin Clement  // LLVM::SwitchOp takes a i32 type for the selector.
8c239909SValentin Clement  if (select.getSelector().getType() != rewriter.getI32Type())
8c239909SValentin Clement    selector =
8c239909SValentin Clement        rewriter.create<LLVM::TruncOp>(loc, rewriter.getI32Type(), selector);
8c239909SValentin Clement
8c239909SValentin Clement  rewriter.replaceOpWithNewOp<mlir::LLVM::SwitchOp>(
8c239909SValentin Clement      select, selector,
8c239909SValentin Clement      /*defaultDestination=*/defaultDestination,
8c239909SValentin Clement      /*defaultOperands=*/defaultOperands,
8c239909SValentin Clement      /*caseValues=*/caseValues,
8c239909SValentin Clement      /*caseDestinations=*/destinations,
8c239909SValentin Clement      /*caseOperands=*/destinationsOperands,
8c239909SValentin Clement      /*branchWeights=*/ArrayRef<int32_t>());
8c239909SValentin Clement}
8c239909SValentin Clement
8c239909SValentin Clement/// conversion of fir::SelectOp to an if-then-else ladder
8c239909SValentin Clementstruct SelectOpConversion : public FIROpConversion<fir::SelectOp> {
8c239909SValentin Clement  using FIROpConversion::FIROpConversion;
8c239909SValentin Clement
8c239909SValentin Clement  mlir::LogicalResult
8c239909SValentin Clement  matchAndRewrite(fir::SelectOp op, OpAdaptor adaptor,
8c239909SValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
8c239909SValentin Clement    selectMatchAndRewrite<fir::SelectOp>(lowerTy(), op, adaptor, rewriter);
8c239909SValentin Clement    return success();
8c239909SValentin Clement  }
8c239909SValentin Clement};
8c239909SValentin Clement
e3349fa1SAndrzej Warzynski/// `fir.load` --> `llvm.load`
e3349fa1SAndrzej Warzynskistruct LoadOpConversion : public FIROpConversion<fir::LoadOp> {
e3349fa1SAndrzej Warzynski  using FIROpConversion::FIROpConversion;
e3349fa1SAndrzej Warzynski
e3349fa1SAndrzej Warzynski  mlir::LogicalResult
e3349fa1SAndrzej Warzynski  matchAndRewrite(fir::LoadOp load, OpAdaptor adaptor,
e3349fa1SAndrzej Warzynski                  mlir::ConversionPatternRewriter &rewriter) const override {
e3349fa1SAndrzej Warzynski    // fir.box is a special case because it is considered as an ssa values in
e3349fa1SAndrzej Warzynski    // fir, but it is lowered as a pointer to a descriptor. So fir.ref<fir.box>
e3349fa1SAndrzej Warzynski    // and fir.box end up being the same llvm types and loading a
e3349fa1SAndrzej Warzynski    // fir.ref<fir.box> is actually a no op in LLVM.
e3349fa1SAndrzej Warzynski    if (load.getType().isa<fir::BoxType>()) {
e3349fa1SAndrzej Warzynski      rewriter.replaceOp(load, adaptor.getOperands()[0]);
e3349fa1SAndrzej Warzynski    } else {
e3349fa1SAndrzej Warzynski      mlir::Type ty = convertType(load.getType());
e3349fa1SAndrzej Warzynski      ArrayRef<NamedAttribute> at = load->getAttrs();
e3349fa1SAndrzej Warzynski      rewriter.replaceOpWithNewOp<mlir::LLVM::LoadOp>(
e3349fa1SAndrzej Warzynski          load, ty, adaptor.getOperands(), at);
e3349fa1SAndrzej Warzynski    }
e3349fa1SAndrzej Warzynski    return success();
e3349fa1SAndrzej Warzynski  }
e3349fa1SAndrzej Warzynski};
e3349fa1SAndrzej Warzynski
2a299e4fSValentin Clement/// Lower `fir.select_type` to LLVM IR dialect.
2a299e4fSValentin Clementstruct SelectTypeOpConversion : public FIROpConversion<fir::SelectTypeOp> {
2a299e4fSValentin Clement  using FIROpConversion::FIROpConversion;
2a299e4fSValentin Clement
2a299e4fSValentin Clement  mlir::LogicalResult
2a299e4fSValentin Clement  matchAndRewrite(fir::SelectTypeOp select, OpAdaptor adaptor,
2a299e4fSValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
2a299e4fSValentin Clement    return rewriter.notifyMatchFailure(
2a299e4fSValentin Clement        select, "fir.select_type codegen is not implemented yet");
2a299e4fSValentin Clement  }
2a299e4fSValentin Clement};
2a299e4fSValentin Clement
8c239909SValentin Clement/// conversion of fir::SelectRankOp to an if-then-else ladder
8c239909SValentin Clementstruct SelectRankOpConversion : public FIROpConversion<fir::SelectRankOp> {
8c239909SValentin Clement  using FIROpConversion::FIROpConversion;
8c239909SValentin Clement
8c239909SValentin Clement  mlir::LogicalResult
8c239909SValentin Clement  matchAndRewrite(fir::SelectRankOp op, OpAdaptor adaptor,
8c239909SValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
8c239909SValentin Clement    selectMatchAndRewrite<fir::SelectRankOp>(lowerTy(), op, adaptor, rewriter);
8c239909SValentin Clement    return success();
8c239909SValentin Clement  }
8c239909SValentin Clement};
8c239909SValentin Clement
e3349fa1SAndrzej Warzynski/// `fir.store` --> `llvm.store`
e3349fa1SAndrzej Warzynskistruct StoreOpConversion : public FIROpConversion<fir::StoreOp> {
e3349fa1SAndrzej Warzynski  using FIROpConversion::FIROpConversion;
e3349fa1SAndrzej Warzynski
e3349fa1SAndrzej Warzynski  mlir::LogicalResult
e3349fa1SAndrzej Warzynski  matchAndRewrite(fir::StoreOp store, OpAdaptor adaptor,
e3349fa1SAndrzej Warzynski                  mlir::ConversionPatternRewriter &rewriter) const override {
e3349fa1SAndrzej Warzynski    if (store.value().getType().isa<fir::BoxType>()) {
e3349fa1SAndrzej Warzynski      // fir.box value is actually in memory, load it first before storing it.
e3349fa1SAndrzej Warzynski      mlir::Location loc = store.getLoc();
e3349fa1SAndrzej Warzynski      mlir::Type boxPtrTy = adaptor.getOperands()[0].getType();
e3349fa1SAndrzej Warzynski      auto val = rewriter.create<mlir::LLVM::LoadOp>(
e3349fa1SAndrzej Warzynski          loc, boxPtrTy.cast<mlir::LLVM::LLVMPointerType>().getElementType(),
e3349fa1SAndrzej Warzynski          adaptor.getOperands()[0]);
e3349fa1SAndrzej Warzynski      rewriter.replaceOpWithNewOp<mlir::LLVM::StoreOp>(
e3349fa1SAndrzej Warzynski          store, val, adaptor.getOperands()[1]);
e3349fa1SAndrzej Warzynski    } else {
e3349fa1SAndrzej Warzynski      rewriter.replaceOpWithNewOp<mlir::LLVM::StoreOp>(
e3349fa1SAndrzej Warzynski          store, adaptor.getOperands()[0], adaptor.getOperands()[1]);
e3349fa1SAndrzej Warzynski    }
e3349fa1SAndrzej Warzynski    return success();
e3349fa1SAndrzej Warzynski  }
e3349fa1SAndrzej Warzynski};
e3349fa1SAndrzej Warzynski
e3349fa1SAndrzej Warzynski/// convert to LLVM IR dialect `undef`
044d5b5dSValentin Clementstruct UndefOpConversion : public FIROpConversion<fir::UndefOp> {
044d5b5dSValentin Clement  using FIROpConversion::FIROpConversion;
044d5b5dSValentin Clement
044d5b5dSValentin Clement  mlir::LogicalResult
044d5b5dSValentin Clement  matchAndRewrite(fir::UndefOp undef, OpAdaptor,
044d5b5dSValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
044d5b5dSValentin Clement    rewriter.replaceOpWithNewOp<mlir::LLVM::UndefOp>(
044d5b5dSValentin Clement        undef, convertType(undef.getType()));
044d5b5dSValentin Clement    return success();
044d5b5dSValentin Clement  }
044d5b5dSValentin Clement};
a7a61359SValentin Clement
e3349fa1SAndrzej Warzynski/// `fir.unreachable` --> `llvm.unreachable`
32e08248SAndrzej Warzynskistruct UnreachableOpConversion : public FIROpConversion<fir::UnreachableOp> {
32e08248SAndrzej Warzynski  using FIROpConversion::FIROpConversion;
32e08248SAndrzej Warzynski
32e08248SAndrzej Warzynski  mlir::LogicalResult
32e08248SAndrzej Warzynski  matchAndRewrite(fir::UnreachableOp unreach, OpAdaptor adaptor,
32e08248SAndrzej Warzynski                  mlir::ConversionPatternRewriter &rewriter) const override {
32e08248SAndrzej Warzynski    rewriter.replaceOpWithNewOp<mlir::LLVM::UnreachableOp>(unreach);
32e08248SAndrzej Warzynski    return success();
32e08248SAndrzej Warzynski  }
32e08248SAndrzej Warzynski};
32e08248SAndrzej Warzynski
a7a61359SValentin Clementstruct ZeroOpConversion : public FIROpConversion<fir::ZeroOp> {
a7a61359SValentin Clement  using FIROpConversion::FIROpConversion;
a7a61359SValentin Clement
a7a61359SValentin Clement  mlir::LogicalResult
a7a61359SValentin Clement  matchAndRewrite(fir::ZeroOp zero, OpAdaptor,
a7a61359SValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
a7a61359SValentin Clement    auto ty = convertType(zero.getType());
a7a61359SValentin Clement    if (ty.isa<mlir::LLVM::LLVMPointerType>()) {
a7a61359SValentin Clement      rewriter.replaceOpWithNewOp<mlir::LLVM::NullOp>(zero, ty);
a7a61359SValentin Clement    } else if (ty.isa<mlir::IntegerType>()) {
a7a61359SValentin Clement      rewriter.replaceOpWithNewOp<mlir::LLVM::ConstantOp>(
a7a61359SValentin Clement          zero, ty, mlir::IntegerAttr::get(zero.getType(), 0));
a7a61359SValentin Clement    } else if (mlir::LLVM::isCompatibleFloatingPointType(ty)) {
a7a61359SValentin Clement      rewriter.replaceOpWithNewOp<mlir::LLVM::ConstantOp>(
a7a61359SValentin Clement          zero, ty, mlir::FloatAttr::get(zero.getType(), 0.0));
a7a61359SValentin Clement    } else {
a7a61359SValentin Clement      // TODO: create ConstantAggregateZero for FIR aggregate/array types.
52d813edSValentin Clement      return rewriter.notifyMatchFailure(
52d813edSValentin Clement          zero,
a7a61359SValentin Clement          "conversion of fir.zero with aggregate type not implemented yet");
a7a61359SValentin Clement    }
a7a61359SValentin Clement    return success();
a7a61359SValentin Clement  }
a7a61359SValentin Clement};
32e08248SAndrzej Warzynski
54c56347SValentin Clement// Code shared between insert_value and extract_value Ops.
54c56347SValentin Clementstruct ValueOpCommon {
54c56347SValentin Clement  // Translate the arguments pertaining to any multidimensional array to
54c56347SValentin Clement  // row-major order for LLVM-IR.
54c56347SValentin Clement  static void toRowMajor(SmallVectorImpl<mlir::Attribute> &attrs,
54c56347SValentin Clement                         mlir::Type ty) {
54c56347SValentin Clement    assert(ty && "type is null");
54c56347SValentin Clement    const auto end = attrs.size();
54c56347SValentin Clement    for (std::remove_const_t<decltype(end)> i = 0; i < end; ++i) {
54c56347SValentin Clement      if (auto seq = ty.dyn_cast<mlir::LLVM::LLVMArrayType>()) {
54c56347SValentin Clement        const auto dim = getDimension(seq);
54c56347SValentin Clement        if (dim > 1) {
54c56347SValentin Clement          auto ub = std::min(i + dim, end);
54c56347SValentin Clement          std::reverse(attrs.begin() + i, attrs.begin() + ub);
54c56347SValentin Clement          i += dim - 1;
54c56347SValentin Clement        }
54c56347SValentin Clement        ty = getArrayElementType(seq);
54c56347SValentin Clement      } else if (auto st = ty.dyn_cast<mlir::LLVM::LLVMStructType>()) {
54c56347SValentin Clement        ty = st.getBody()[attrs[i].cast<mlir::IntegerAttr>().getInt()];
54c56347SValentin Clement      } else {
54c56347SValentin Clement        llvm_unreachable("index into invalid type");
54c56347SValentin Clement      }
54c56347SValentin Clement    }
54c56347SValentin Clement  }
54c56347SValentin Clement
54c56347SValentin Clement  static llvm::SmallVector<mlir::Attribute>
54c56347SValentin Clement  collectIndices(mlir::ConversionPatternRewriter &rewriter,
54c56347SValentin Clement                 mlir::ArrayAttr arrAttr) {
54c56347SValentin Clement    llvm::SmallVector<mlir::Attribute> attrs;
54c56347SValentin Clement    for (auto i = arrAttr.begin(), e = arrAttr.end(); i != e; ++i) {
54c56347SValentin Clement      if (i->isa<mlir::IntegerAttr>()) {
54c56347SValentin Clement        attrs.push_back(*i);
54c56347SValentin Clement      } else {
54c56347SValentin Clement        auto fieldName = i->cast<mlir::StringAttr>().getValue();
54c56347SValentin Clement        ++i;
54c56347SValentin Clement        auto ty = i->cast<mlir::TypeAttr>().getValue();
54c56347SValentin Clement        auto index = ty.cast<fir::RecordType>().getFieldIndex(fieldName);
54c56347SValentin Clement        attrs.push_back(mlir::IntegerAttr::get(rewriter.getI32Type(), index));
54c56347SValentin Clement      }
54c56347SValentin Clement    }
54c56347SValentin Clement    return attrs;
54c56347SValentin Clement  }
54c56347SValentin Clement
54c56347SValentin Clementprivate:
54c56347SValentin Clement  static unsigned getDimension(mlir::LLVM::LLVMArrayType ty) {
54c56347SValentin Clement    unsigned result = 1;
54c56347SValentin Clement    for (auto eleTy = ty.getElementType().dyn_cast<mlir::LLVM::LLVMArrayType>();
54c56347SValentin Clement         eleTy;
54c56347SValentin Clement         eleTy = eleTy.getElementType().dyn_cast<mlir::LLVM::LLVMArrayType>())
54c56347SValentin Clement      ++result;
54c56347SValentin Clement    return result;
54c56347SValentin Clement  }
54c56347SValentin Clement
54c56347SValentin Clement  static mlir::Type getArrayElementType(mlir::LLVM::LLVMArrayType ty) {
54c56347SValentin Clement    auto eleTy = ty.getElementType();
54c56347SValentin Clement    while (auto arrTy = eleTy.dyn_cast<mlir::LLVM::LLVMArrayType>())
54c56347SValentin Clement      eleTy = arrTy.getElementType();
54c56347SValentin Clement    return eleTy;
54c56347SValentin Clement  }
54c56347SValentin Clement};
54c56347SValentin Clement
54c56347SValentin Clement/// Extract a subobject value from an ssa-value of aggregate type
54c56347SValentin Clementstruct ExtractValueOpConversion
54c56347SValentin Clement    : public FIROpAndTypeConversion<fir::ExtractValueOp>,
54c56347SValentin Clement      public ValueOpCommon {
54c56347SValentin Clement  using FIROpAndTypeConversion::FIROpAndTypeConversion;
54c56347SValentin Clement
54c56347SValentin Clement  mlir::LogicalResult
54c56347SValentin Clement  doRewrite(fir::ExtractValueOp extractVal, mlir::Type ty, OpAdaptor adaptor,
54c56347SValentin Clement            mlir::ConversionPatternRewriter &rewriter) const override {
54c56347SValentin Clement    auto attrs = collectIndices(rewriter, extractVal.coor());
54c56347SValentin Clement    toRowMajor(attrs, adaptor.getOperands()[0].getType());
54c56347SValentin Clement    auto position = mlir::ArrayAttr::get(extractVal.getContext(), attrs);
54c56347SValentin Clement    rewriter.replaceOpWithNewOp<mlir::LLVM::ExtractValueOp>(
54c56347SValentin Clement        extractVal, ty, adaptor.getOperands()[0], position);
54c56347SValentin Clement    return success();
54c56347SValentin Clement  }
54c56347SValentin Clement};
54c56347SValentin Clement
54c56347SValentin Clement/// InsertValue is the generalized instruction for the composition of new
54c56347SValentin Clement/// aggregate type values.
54c56347SValentin Clementstruct InsertValueOpConversion
54c56347SValentin Clement    : public FIROpAndTypeConversion<fir::InsertValueOp>,
54c56347SValentin Clement      public ValueOpCommon {
54c56347SValentin Clement  using FIROpAndTypeConversion::FIROpAndTypeConversion;
54c56347SValentin Clement
54c56347SValentin Clement  mlir::LogicalResult
54c56347SValentin Clement  doRewrite(fir::InsertValueOp insertVal, mlir::Type ty, OpAdaptor adaptor,
54c56347SValentin Clement            mlir::ConversionPatternRewriter &rewriter) const override {
54c56347SValentin Clement    auto attrs = collectIndices(rewriter, insertVal.coor());
54c56347SValentin Clement    toRowMajor(attrs, adaptor.getOperands()[0].getType());
54c56347SValentin Clement    auto position = mlir::ArrayAttr::get(insertVal.getContext(), attrs);
54c56347SValentin Clement    rewriter.replaceOpWithNewOp<mlir::LLVM::InsertValueOp>(
54c56347SValentin Clement        insertVal, ty, adaptor.getOperands()[0], adaptor.getOperands()[1],
54c56347SValentin Clement        position);
54c56347SValentin Clement    return success();
54c56347SValentin Clement  }
54c56347SValentin Clement};
54c56347SValentin Clement
3ae8e442SValentin Clement/// InsertOnRange inserts a value into a sequence over a range of offsets.
3ae8e442SValentin Clementstruct InsertOnRangeOpConversion
3ae8e442SValentin Clement    : public FIROpAndTypeConversion<fir::InsertOnRangeOp> {
3ae8e442SValentin Clement  using FIROpAndTypeConversion::FIROpAndTypeConversion;
3ae8e442SValentin Clement
3ae8e442SValentin Clement  // Increments an array of subscripts in a row major fasion.
3ae8e442SValentin Clement  void incrementSubscripts(const SmallVector<uint64_t> &dims,
3ae8e442SValentin Clement                           SmallVector<uint64_t> &subscripts) const {
3ae8e442SValentin Clement    for (size_t i = dims.size(); i > 0; --i) {
3ae8e442SValentin Clement      if (++subscripts[i - 1] < dims[i - 1]) {
3ae8e442SValentin Clement        return;
3ae8e442SValentin Clement      }
3ae8e442SValentin Clement      subscripts[i - 1] = 0;
3ae8e442SValentin Clement    }
3ae8e442SValentin Clement  }
3ae8e442SValentin Clement
3ae8e442SValentin Clement  mlir::LogicalResult
3ae8e442SValentin Clement  doRewrite(fir::InsertOnRangeOp range, mlir::Type ty, OpAdaptor adaptor,
3ae8e442SValentin Clement            mlir::ConversionPatternRewriter &rewriter) const override {
3ae8e442SValentin Clement
3ae8e442SValentin Clement    llvm::SmallVector<uint64_t> dims;
3ae8e442SValentin Clement    auto type = adaptor.getOperands()[0].getType();
3ae8e442SValentin Clement
3ae8e442SValentin Clement    // Iteratively extract the array dimensions from the type.
3ae8e442SValentin Clement    while (auto t = type.dyn_cast<mlir::LLVM::LLVMArrayType>()) {
3ae8e442SValentin Clement      dims.push_back(t.getNumElements());
3ae8e442SValentin Clement      type = t.getElementType();
3ae8e442SValentin Clement    }
3ae8e442SValentin Clement
3ae8e442SValentin Clement    SmallVector<uint64_t> lBounds;
3ae8e442SValentin Clement    SmallVector<uint64_t> uBounds;
3ae8e442SValentin Clement
3ae8e442SValentin Clement    // Extract integer value from the attribute
3ae8e442SValentin Clement    SmallVector<int64_t> coordinates = llvm::to_vector<4>(
3ae8e442SValentin Clement        llvm::map_range(range.coor(), [](Attribute a) -> int64_t {
3ae8e442SValentin Clement          return a.cast<IntegerAttr>().getInt();
3ae8e442SValentin Clement        }));
3ae8e442SValentin Clement
3ae8e442SValentin Clement    // Unzip the upper and lower bound and convert to a row major format.
3ae8e442SValentin Clement    for (auto i = coordinates.rbegin(), e = coordinates.rend(); i != e; ++i) {
3ae8e442SValentin Clement      uBounds.push_back(*i++);
3ae8e442SValentin Clement      lBounds.push_back(*i);
3ae8e442SValentin Clement    }
3ae8e442SValentin Clement
3ae8e442SValentin Clement    auto &subscripts = lBounds;
3ae8e442SValentin Clement    auto loc = range.getLoc();
3ae8e442SValentin Clement    mlir::Value lastOp = adaptor.getOperands()[0];
3ae8e442SValentin Clement    mlir::Value insertVal = adaptor.getOperands()[1];
3ae8e442SValentin Clement
3ae8e442SValentin Clement    auto i64Ty = rewriter.getI64Type();
3ae8e442SValentin Clement    while (subscripts != uBounds) {
3ae8e442SValentin Clement      // Convert uint64_t's to Attribute's.
3ae8e442SValentin Clement      SmallVector<mlir::Attribute> subscriptAttrs;
3ae8e442SValentin Clement      for (const auto &subscript : subscripts)
3ae8e442SValentin Clement        subscriptAttrs.push_back(IntegerAttr::get(i64Ty, subscript));
3ae8e442SValentin Clement      lastOp = rewriter.create<mlir::LLVM::InsertValueOp>(
3ae8e442SValentin Clement          loc, ty, lastOp, insertVal,
3ae8e442SValentin Clement          ArrayAttr::get(range.getContext(), subscriptAttrs));
3ae8e442SValentin Clement
3ae8e442SValentin Clement      incrementSubscripts(dims, subscripts);
3ae8e442SValentin Clement    }
3ae8e442SValentin Clement
3ae8e442SValentin Clement    // Convert uint64_t's to Attribute's.
3ae8e442SValentin Clement    SmallVector<mlir::Attribute> subscriptAttrs;
3ae8e442SValentin Clement    for (const auto &subscript : subscripts)
3ae8e442SValentin Clement      subscriptAttrs.push_back(
3ae8e442SValentin Clement          IntegerAttr::get(rewriter.getI64Type(), subscript));
3ae8e442SValentin Clement    mlir::ArrayRef<mlir::Attribute> arrayRef(subscriptAttrs);
3ae8e442SValentin Clement
3ae8e442SValentin Clement    rewriter.replaceOpWithNewOp<mlir::LLVM::InsertValueOp>(
3ae8e442SValentin Clement        range, ty, lastOp, insertVal,
3ae8e442SValentin Clement        ArrayAttr::get(range.getContext(), arrayRef));
3ae8e442SValentin Clement
3ae8e442SValentin Clement    return success();
3ae8e442SValentin Clement  }
3ae8e442SValentin Clement};
7b5132daSValentin Clement
7b5132daSValentin Clement//
7b5132daSValentin Clement// Primitive operations on Complex types
7b5132daSValentin Clement//
7b5132daSValentin Clement
7b5132daSValentin Clement/// Generate inline code for complex addition/subtraction
7b5132daSValentin Clementtemplate <typename LLVMOP, typename OPTY>
7b5132daSValentin Clementmlir::LLVM::InsertValueOp complexSum(OPTY sumop, mlir::ValueRange opnds,
7b5132daSValentin Clement                                     mlir::ConversionPatternRewriter &rewriter,
7b5132daSValentin Clement                                     fir::LLVMTypeConverter &lowering) {
7b5132daSValentin Clement  mlir::Value a = opnds[0];
7b5132daSValentin Clement  mlir::Value b = opnds[1];
7b5132daSValentin Clement  auto loc = sumop.getLoc();
7b5132daSValentin Clement  auto ctx = sumop.getContext();
7b5132daSValentin Clement  auto c0 = mlir::ArrayAttr::get(ctx, rewriter.getI32IntegerAttr(0));
7b5132daSValentin Clement  auto c1 = mlir::ArrayAttr::get(ctx, rewriter.getI32IntegerAttr(1));
7b5132daSValentin Clement  mlir::Type eleTy = lowering.convertType(getComplexEleTy(sumop.getType()));
7b5132daSValentin Clement  mlir::Type ty = lowering.convertType(sumop.getType());
7b5132daSValentin Clement  auto x0 = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, eleTy, a, c0);
7b5132daSValentin Clement  auto y0 = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, eleTy, a, c1);
7b5132daSValentin Clement  auto x1 = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, eleTy, b, c0);
7b5132daSValentin Clement  auto y1 = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, eleTy, b, c1);
7b5132daSValentin Clement  auto rx = rewriter.create<LLVMOP>(loc, eleTy, x0, x1);
7b5132daSValentin Clement  auto ry = rewriter.create<LLVMOP>(loc, eleTy, y0, y1);
7b5132daSValentin Clement  auto r0 = rewriter.create<mlir::LLVM::UndefOp>(loc, ty);
7b5132daSValentin Clement  auto r1 = rewriter.create<mlir::LLVM::InsertValueOp>(loc, ty, r0, rx, c0);
7b5132daSValentin Clement  return rewriter.create<mlir::LLVM::InsertValueOp>(loc, ty, r1, ry, c1);
7b5132daSValentin Clement}
7b5132daSValentin Clement
7b5132daSValentin Clementstruct AddcOpConversion : public FIROpConversion<fir::AddcOp> {
7b5132daSValentin Clement  using FIROpConversion::FIROpConversion;
7b5132daSValentin Clement
7b5132daSValentin Clement  mlir::LogicalResult
7b5132daSValentin Clement  matchAndRewrite(fir::AddcOp addc, OpAdaptor adaptor,
7b5132daSValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
7b5132daSValentin Clement    // given: (x + iy) + (x' + iy')
7b5132daSValentin Clement    // result: (x + x') + i(y + y')
7b5132daSValentin Clement    auto r = complexSum<mlir::LLVM::FAddOp>(addc, adaptor.getOperands(),
7b5132daSValentin Clement                                            rewriter, lowerTy());
7b5132daSValentin Clement    rewriter.replaceOp(addc, r.getResult());
7b5132daSValentin Clement    return success();
7b5132daSValentin Clement  }
7b5132daSValentin Clement};
7b5132daSValentin Clement
7b5132daSValentin Clementstruct SubcOpConversion : public FIROpConversion<fir::SubcOp> {
7b5132daSValentin Clement  using FIROpConversion::FIROpConversion;
7b5132daSValentin Clement
7b5132daSValentin Clement  mlir::LogicalResult
7b5132daSValentin Clement  matchAndRewrite(fir::SubcOp subc, OpAdaptor adaptor,
7b5132daSValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
7b5132daSValentin Clement    // given: (x + iy) - (x' + iy')
7b5132daSValentin Clement    // result: (x - x') + i(y - y')
7b5132daSValentin Clement    auto r = complexSum<mlir::LLVM::FSubOp>(subc, adaptor.getOperands(),
7b5132daSValentin Clement                                            rewriter, lowerTy());
7b5132daSValentin Clement    rewriter.replaceOp(subc, r.getResult());
7b5132daSValentin Clement    return success();
7b5132daSValentin Clement  }
7b5132daSValentin Clement};
7b5132daSValentin Clement
7b5132daSValentin Clement/// Inlined complex multiply
7b5132daSValentin Clementstruct MulcOpConversion : public FIROpConversion<fir::MulcOp> {
7b5132daSValentin Clement  using FIROpConversion::FIROpConversion;
7b5132daSValentin Clement
7b5132daSValentin Clement  mlir::LogicalResult
7b5132daSValentin Clement  matchAndRewrite(fir::MulcOp mulc, OpAdaptor adaptor,
7b5132daSValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
7b5132daSValentin Clement    // TODO: Can we use a call to __muldc3 ?
7b5132daSValentin Clement    // given: (x + iy) * (x' + iy')
7b5132daSValentin Clement    // result: (xx'-yy')+i(xy'+yx')
7b5132daSValentin Clement    mlir::Value a = adaptor.getOperands()[0];
7b5132daSValentin Clement    mlir::Value b = adaptor.getOperands()[1];
7b5132daSValentin Clement    auto loc = mulc.getLoc();
7b5132daSValentin Clement    auto *ctx = mulc.getContext();
7b5132daSValentin Clement    auto c0 = mlir::ArrayAttr::get(ctx, rewriter.getI32IntegerAttr(0));
7b5132daSValentin Clement    auto c1 = mlir::ArrayAttr::get(ctx, rewriter.getI32IntegerAttr(1));
7b5132daSValentin Clement    mlir::Type eleTy = convertType(getComplexEleTy(mulc.getType()));
7b5132daSValentin Clement    mlir::Type ty = convertType(mulc.getType());
7b5132daSValentin Clement    auto x0 = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, eleTy, a, c0);
7b5132daSValentin Clement    auto y0 = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, eleTy, a, c1);
7b5132daSValentin Clement    auto x1 = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, eleTy, b, c0);
7b5132daSValentin Clement    auto y1 = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, eleTy, b, c1);
7b5132daSValentin Clement    auto xx = rewriter.create<mlir::LLVM::FMulOp>(loc, eleTy, x0, x1);
7b5132daSValentin Clement    auto yx = rewriter.create<mlir::LLVM::FMulOp>(loc, eleTy, y0, x1);
7b5132daSValentin Clement    auto xy = rewriter.create<mlir::LLVM::FMulOp>(loc, eleTy, x0, y1);
7b5132daSValentin Clement    auto ri = rewriter.create<mlir::LLVM::FAddOp>(loc, eleTy, xy, yx);
7b5132daSValentin Clement    auto yy = rewriter.create<mlir::LLVM::FMulOp>(loc, eleTy, y0, y1);
7b5132daSValentin Clement    auto rr = rewriter.create<mlir::LLVM::FSubOp>(loc, eleTy, xx, yy);
7b5132daSValentin Clement    auto ra = rewriter.create<mlir::LLVM::UndefOp>(loc, ty);
7b5132daSValentin Clement    auto r1 = rewriter.create<mlir::LLVM::InsertValueOp>(loc, ty, ra, rr, c0);
7b5132daSValentin Clement    auto r0 = rewriter.create<mlir::LLVM::InsertValueOp>(loc, ty, r1, ri, c1);
7b5132daSValentin Clement    rewriter.replaceOp(mulc, r0.getResult());
7b5132daSValentin Clement    return success();
7b5132daSValentin Clement  }
7b5132daSValentin Clement};
7b5132daSValentin Clement
7b5132daSValentin Clement/// Inlined complex division
7b5132daSValentin Clementstruct DivcOpConversion : public FIROpConversion<fir::DivcOp> {
7b5132daSValentin Clement  using FIROpConversion::FIROpConversion;
7b5132daSValentin Clement
7b5132daSValentin Clement  mlir::LogicalResult
7b5132daSValentin Clement  matchAndRewrite(fir::DivcOp divc, OpAdaptor adaptor,
7b5132daSValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
7b5132daSValentin Clement    // TODO: Can we use a call to __divdc3 instead?
7b5132daSValentin Clement    // Just generate inline code for now.
7b5132daSValentin Clement    // given: (x + iy) / (x' + iy')
7b5132daSValentin Clement    // result: ((xx'+yy')/d) + i((yx'-xy')/d) where d = x'x' + y'y'
7b5132daSValentin Clement    mlir::Value a = adaptor.getOperands()[0];
7b5132daSValentin Clement    mlir::Value b = adaptor.getOperands()[1];
7b5132daSValentin Clement    auto loc = divc.getLoc();
7b5132daSValentin Clement    auto *ctx = divc.getContext();
7b5132daSValentin Clement    auto c0 = mlir::ArrayAttr::get(ctx, rewriter.getI32IntegerAttr(0));
7b5132daSValentin Clement    auto c1 = mlir::ArrayAttr::get(ctx, rewriter.getI32IntegerAttr(1));
7b5132daSValentin Clement    mlir::Type eleTy = convertType(getComplexEleTy(divc.getType()));
7b5132daSValentin Clement    mlir::Type ty = convertType(divc.getType());
7b5132daSValentin Clement    auto x0 = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, eleTy, a, c0);
7b5132daSValentin Clement    auto y0 = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, eleTy, a, c1);
7b5132daSValentin Clement    auto x1 = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, eleTy, b, c0);
7b5132daSValentin Clement    auto y1 = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, eleTy, b, c1);
7b5132daSValentin Clement    auto xx = rewriter.create<mlir::LLVM::FMulOp>(loc, eleTy, x0, x1);
7b5132daSValentin Clement    auto x1x1 = rewriter.create<mlir::LLVM::FMulOp>(loc, eleTy, x1, x1);
7b5132daSValentin Clement    auto yx = rewriter.create<mlir::LLVM::FMulOp>(loc, eleTy, y0, x1);
7b5132daSValentin Clement    auto xy = rewriter.create<mlir::LLVM::FMulOp>(loc, eleTy, x0, y1);
7b5132daSValentin Clement    auto yy = rewriter.create<mlir::LLVM::FMulOp>(loc, eleTy, y0, y1);
7b5132daSValentin Clement    auto y1y1 = rewriter.create<mlir::LLVM::FMulOp>(loc, eleTy, y1, y1);
7b5132daSValentin Clement    auto d = rewriter.create<mlir::LLVM::FAddOp>(loc, eleTy, x1x1, y1y1);
7b5132daSValentin Clement    auto rrn = rewriter.create<mlir::LLVM::FAddOp>(loc, eleTy, xx, yy);
7b5132daSValentin Clement    auto rin = rewriter.create<mlir::LLVM::FSubOp>(loc, eleTy, yx, xy);
7b5132daSValentin Clement    auto rr = rewriter.create<mlir::LLVM::FDivOp>(loc, eleTy, rrn, d);
7b5132daSValentin Clement    auto ri = rewriter.create<mlir::LLVM::FDivOp>(loc, eleTy, rin, d);
7b5132daSValentin Clement    auto ra = rewriter.create<mlir::LLVM::UndefOp>(loc, ty);
7b5132daSValentin Clement    auto r1 = rewriter.create<mlir::LLVM::InsertValueOp>(loc, ty, ra, rr, c0);
7b5132daSValentin Clement    auto r0 = rewriter.create<mlir::LLVM::InsertValueOp>(loc, ty, r1, ri, c1);
7b5132daSValentin Clement    rewriter.replaceOp(divc, r0.getResult());
7b5132daSValentin Clement    return success();
7b5132daSValentin Clement  }
7b5132daSValentin Clement};
7b5132daSValentin Clement
7b5132daSValentin Clement/// Inlined complex negation
7b5132daSValentin Clementstruct NegcOpConversion : public FIROpConversion<fir::NegcOp> {
7b5132daSValentin Clement  using FIROpConversion::FIROpConversion;
7b5132daSValentin Clement
7b5132daSValentin Clement  mlir::LogicalResult
7b5132daSValentin Clement  matchAndRewrite(fir::NegcOp neg, OpAdaptor adaptor,
7b5132daSValentin Clement                  mlir::ConversionPatternRewriter &rewriter) const override {
7b5132daSValentin Clement    // given: -(x + iy)
7b5132daSValentin Clement    // result: -x - iy
7b5132daSValentin Clement    auto *ctxt = neg.getContext();
7b5132daSValentin Clement    auto eleTy = convertType(getComplexEleTy(neg.getType()));
7b5132daSValentin Clement    auto ty = convertType(neg.getType());
7b5132daSValentin Clement    auto loc = neg.getLoc();
7b5132daSValentin Clement    mlir::Value o0 = adaptor.getOperands()[0];
7b5132daSValentin Clement    auto c0 = mlir::ArrayAttr::get(ctxt, rewriter.getI32IntegerAttr(0));
7b5132daSValentin Clement    auto c1 = mlir::ArrayAttr::get(ctxt, rewriter.getI32IntegerAttr(1));
7b5132daSValentin Clement    auto rp = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, eleTy, o0, c0);
7b5132daSValentin Clement    auto ip = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, eleTy, o0, c1);
7b5132daSValentin Clement    auto nrp = rewriter.create<mlir::LLVM::FNegOp>(loc, eleTy, rp);
7b5132daSValentin Clement    auto nip = rewriter.create<mlir::LLVM::FNegOp>(loc, eleTy, ip);
7b5132daSValentin Clement    auto r = rewriter.create<mlir::LLVM::InsertValueOp>(loc, ty, o0, nrp, c0);
7b5132daSValentin Clement    rewriter.replaceOpWithNewOp<mlir::LLVM::InsertValueOp>(neg, ty, r, nip, c1);
7b5132daSValentin Clement    return success();
7b5132daSValentin Clement  }
7b5132daSValentin Clement};
7b5132daSValentin Clement
420ad7ceSAndrzej Warzynski/// `fir.is_present` -->
420ad7ceSAndrzej Warzynski/// ```
420ad7ceSAndrzej Warzynski///  %0 = llvm.mlir.constant(0 : i64)
420ad7ceSAndrzej Warzynski///  %1 = llvm.ptrtoint %0
420ad7ceSAndrzej Warzynski///  %2 = llvm.icmp "ne" %1, %0 : i64
420ad7ceSAndrzej Warzynski/// ```
420ad7ceSAndrzej Warzynskistruct IsPresentOpConversion : public FIROpConversion<fir::IsPresentOp> {
420ad7ceSAndrzej Warzynski  using FIROpConversion::FIROpConversion;
420ad7ceSAndrzej Warzynski
420ad7ceSAndrzej Warzynski  mlir::LogicalResult
420ad7ceSAndrzej Warzynski  matchAndRewrite(fir::IsPresentOp isPresent, OpAdaptor adaptor,
420ad7ceSAndrzej Warzynski                  mlir::ConversionPatternRewriter &rewriter) const override {
420ad7ceSAndrzej Warzynski    mlir::Type idxTy = lowerTy().indexType();
420ad7ceSAndrzej Warzynski    mlir::Location loc = isPresent.getLoc();
420ad7ceSAndrzej Warzynski    auto ptr = adaptor.getOperands()[0];
420ad7ceSAndrzej Warzynski
420ad7ceSAndrzej Warzynski    if (isPresent.val().getType().isa<fir::BoxCharType>()) {
420ad7ceSAndrzej Warzynski      auto structTy = ptr.getType().cast<mlir::LLVM::LLVMStructType>();
420ad7ceSAndrzej Warzynski      assert(!structTy.isOpaque() && !structTy.getBody().empty());
420ad7ceSAndrzej Warzynski
420ad7ceSAndrzej Warzynski      mlir::Type ty = structTy.getBody()[0];
420ad7ceSAndrzej Warzynski      mlir::MLIRContext *ctx = isPresent.getContext();
420ad7ceSAndrzej Warzynski      auto c0 = mlir::ArrayAttr::get(ctx, rewriter.getI32IntegerAttr(0));
420ad7ceSAndrzej Warzynski      ptr = rewriter.create<mlir::LLVM::ExtractValueOp>(loc, ty, ptr, c0);
420ad7ceSAndrzej Warzynski    }
420ad7ceSAndrzej Warzynski    mlir::LLVM::ConstantOp c0 =
420ad7ceSAndrzej Warzynski        genConstantIndex(isPresent.getLoc(), idxTy, rewriter, 0);
420ad7ceSAndrzej Warzynski    auto addr = rewriter.create<mlir::LLVM::PtrToIntOp>(loc, idxTy, ptr);
420ad7ceSAndrzej Warzynski    rewriter.replaceOpWithNewOp<mlir::LLVM::ICmpOp>(
420ad7ceSAndrzej Warzynski        isPresent, mlir::LLVM::ICmpPredicate::ne, addr, c0);
420ad7ceSAndrzej Warzynski
420ad7ceSAndrzej Warzynski    return success();
420ad7ceSAndrzej Warzynski  }
420ad7ceSAndrzej Warzynski};
1e77b095SAndrzej Warzynski
1e77b095SAndrzej Warzynski/// Convert `!fir.emboxchar<!fir.char<KIND, ?>, #n>` into a sequence of
1e77b095SAndrzej Warzynski/// instructions that generate `!llvm.struct<(ptr<ik>, i64)>`. The 1st element
1e77b095SAndrzej Warzynski/// in this struct is a pointer. Its type is determined from `KIND`. The 2nd
1e77b095SAndrzej Warzynski/// element is the length of the character buffer (`#n`).
1e77b095SAndrzej Warzynskistruct EmboxCharOpConversion : public FIROpConversion<fir::EmboxCharOp> {
1e77b095SAndrzej Warzynski  using FIROpConversion::FIROpConversion;
1e77b095SAndrzej Warzynski
1e77b095SAndrzej Warzynski  mlir::LogicalResult
1e77b095SAndrzej Warzynski  matchAndRewrite(fir::EmboxCharOp emboxChar, OpAdaptor adaptor,
1e77b095SAndrzej Warzynski                  mlir::ConversionPatternRewriter &rewriter) const override {
1e77b095SAndrzej Warzynski    mlir::ValueRange operands = adaptor.getOperands();
1e77b095SAndrzej Warzynski    MLIRContext *ctx = emboxChar.getContext();
1e77b095SAndrzej Warzynski
1e77b095SAndrzej Warzynski    mlir::Value charBuffer = operands[0];
1e77b095SAndrzej Warzynski    mlir::Value charBufferLen = operands[1];
1e77b095SAndrzej Warzynski
1e77b095SAndrzej Warzynski    mlir::Location loc = emboxChar.getLoc();
1e77b095SAndrzej Warzynski    mlir::Type llvmStructTy = convertType(emboxChar.getType());
1e77b095SAndrzej Warzynski    auto llvmStruct = rewriter.create<mlir::LLVM::UndefOp>(loc, llvmStructTy);
1e77b095SAndrzej Warzynski
1e77b095SAndrzej Warzynski    mlir::Type lenTy =
1e77b095SAndrzej Warzynski        llvmStructTy.cast<mlir::LLVM::LLVMStructType>().getBody()[1];
1e77b095SAndrzej Warzynski    mlir::Value lenAfterCast = integerCast(loc, rewriter, lenTy, charBufferLen);
1e77b095SAndrzej Warzynski
1e77b095SAndrzej Warzynski    auto c0 = mlir::ArrayAttr::get(ctx, rewriter.getI32IntegerAttr(0));
1e77b095SAndrzej Warzynski    auto c1 = mlir::ArrayAttr::get(ctx, rewriter.getI32IntegerAttr(1));
1e77b095SAndrzej Warzynski    auto insertBufferOp = rewriter.create<mlir::LLVM::InsertValueOp>(
1e77b095SAndrzej Warzynski        loc, llvmStructTy, llvmStruct, charBuffer, c0);
1e77b095SAndrzej Warzynski    rewriter.replaceOpWithNewOp<mlir::LLVM::InsertValueOp>(
1e77b095SAndrzej Warzynski        emboxChar, llvmStructTy, insertBufferOp, lenAfterCast, c1);
1e77b095SAndrzej Warzynski
1e77b095SAndrzej Warzynski    return success();
1e77b095SAndrzej Warzynski  }
1e77b095SAndrzej Warzynski};
14867ffcSAndrzej Warzynski
14867ffcSAndrzej Warzynski/// Construct an `llvm.extractvalue` instruction. It will return value at
14867ffcSAndrzej Warzynski/// element \p x from  \p tuple.
14867ffcSAndrzej Warzynskimlir::LLVM::ExtractValueOp
14867ffcSAndrzej WarzynskigenExtractValueWithIndex(mlir::Location loc, mlir::Value tuple, mlir::Type ty,
14867ffcSAndrzej Warzynski                         mlir::ConversionPatternRewriter &rewriter,
14867ffcSAndrzej Warzynski                         mlir::MLIRContext *ctx, int x) {
14867ffcSAndrzej Warzynski  auto cx = mlir::ArrayAttr::get(ctx, rewriter.getI32IntegerAttr(x));
14867ffcSAndrzej Warzynski  auto xty = ty.cast<mlir::LLVM::LLVMStructType>().getBody()[x];
14867ffcSAndrzej Warzynski  return rewriter.create<mlir::LLVM::ExtractValueOp>(loc, xty, tuple, cx);
14867ffcSAndrzej Warzynski}
14867ffcSAndrzej Warzynski
14867ffcSAndrzej Warzynski/// Convert `fir.unboxchar` into two `llvm.extractvalue` instructions. One for
14867ffcSAndrzej Warzynski/// the character buffer and one for the buffer length.
14867ffcSAndrzej Warzynskistruct UnboxCharOpConversion : public FIROpConversion<fir::UnboxCharOp> {
14867ffcSAndrzej Warzynski  using FIROpConversion::FIROpConversion;
14867ffcSAndrzej Warzynski
14867ffcSAndrzej Warzynski  mlir::LogicalResult
14867ffcSAndrzej Warzynski  matchAndRewrite(fir::UnboxCharOp unboxchar, OpAdaptor adaptor,
14867ffcSAndrzej Warzynski                  mlir::ConversionPatternRewriter &rewriter) const override {
14867ffcSAndrzej Warzynski    MLIRContext *ctx = unboxchar.getContext();
14867ffcSAndrzej Warzynski
14867ffcSAndrzej Warzynski    mlir::Type lenTy = convertType(unboxchar.getType(1));
14867ffcSAndrzej Warzynski    mlir::Value tuple = adaptor.getOperands()[0];
14867ffcSAndrzej Warzynski    mlir::Type tupleTy = tuple.getType();
14867ffcSAndrzej Warzynski
14867ffcSAndrzej Warzynski    mlir::Location loc = unboxchar.getLoc();
14867ffcSAndrzej Warzynski    mlir::Value ptrToBuffer =
14867ffcSAndrzej Warzynski        genExtractValueWithIndex(loc, tuple, tupleTy, rewriter, ctx, 0);
14867ffcSAndrzej Warzynski
14867ffcSAndrzej Warzynski    mlir::LLVM::ExtractValueOp len =
14867ffcSAndrzej Warzynski        genExtractValueWithIndex(loc, tuple, tupleTy, rewriter, ctx, 1);
14867ffcSAndrzej Warzynski    mlir::Value lenAfterCast = integerCast(loc, rewriter, lenTy, len);
14867ffcSAndrzej Warzynski
14867ffcSAndrzej Warzynski    rewriter.replaceOp(unboxchar,
14867ffcSAndrzej Warzynski                       ArrayRef<mlir::Value>{ptrToBuffer, lenAfterCast});
14867ffcSAndrzej Warzynski    return success();
14867ffcSAndrzej Warzynski  }
14867ffcSAndrzej Warzynski};
14867ffcSAndrzej Warzynski
044d5b5dSValentin Clement} // namespace
044d5b5dSValentin Clement
044d5b5dSValentin Clementnamespace {
044d5b5dSValentin Clement/// Convert FIR dialect to LLVM dialect
044d5b5dSValentin Clement///
044d5b5dSValentin Clement/// This pass lowers all FIR dialect operations to LLVM IR dialect. An
044d5b5dSValentin Clement/// MLIR pass is used to lower residual Std dialect to LLVM IR dialect.
044d5b5dSValentin Clement///
044d5b5dSValentin Clement/// This pass is not complete yet. We are upstreaming it in small patches.
044d5b5dSValentin Clementclass FIRToLLVMLowering : public fir::FIRToLLVMLoweringBase<FIRToLLVMLowering> {
044d5b5dSValentin Clementpublic:
044d5b5dSValentin Clement  mlir::ModuleOp getModule() { return getOperation(); }
044d5b5dSValentin Clement
044d5b5dSValentin Clement  void runOnOperation() override final {
7b5132daSValentin Clement    auto mod = getModule();
7b5132daSValentin Clement    if (!forcedTargetTriple.empty()) {
7b5132daSValentin Clement      fir::setTargetTriple(mod, forcedTargetTriple);
7b5132daSValentin Clement    }
7b5132daSValentin Clement
044d5b5dSValentin Clement    auto *context = getModule().getContext();
044d5b5dSValentin Clement    fir::LLVMTypeConverter typeConverter{getModule()};
044d5b5dSValentin Clement    mlir::OwningRewritePatternList pattern(context);
df3b9810SValentin Clement    pattern.insert<
420ad7ceSAndrzej Warzynski        AbsentOpConversion, AddcOpConversion, AddrOfOpConversion,
420ad7ceSAndrzej Warzynski        AllocaOpConversion, BoxAddrOpConversion, BoxDimsOpConversion,
420ad7ceSAndrzej Warzynski        BoxEleSizeOpConversion, BoxIsAllocOpConversion, BoxIsArrayOpConversion,
420ad7ceSAndrzej Warzynski        BoxIsPtrOpConversion, BoxRankOpConversion, CallOpConversion,
*f1dfc027SDiana Picus        CmpcOpConversion, ConvertOpConversion, DispatchOpConversion,
*f1dfc027SDiana Picus        DispatchTableOpConversion, DTEntryOpConversion, DivcOpConversion,
*f1dfc027SDiana Picus        EmboxCharOpConversion, ExtractValueOpConversion, HasValueOpConversion,
*f1dfc027SDiana Picus        GlobalLenOpConversion, GlobalOpConversion, InsertOnRangeOpConversion,
*f1dfc027SDiana Picus        InsertValueOpConversion, IsPresentOpConversion, LoadOpConversion,
*f1dfc027SDiana Picus        NegcOpConversion, MulcOpConversion, SelectCaseOpConversion,
*f1dfc027SDiana Picus        SelectOpConversion, SelectRankOpConversion, SelectTypeOpConversion,
*f1dfc027SDiana Picus        StoreOpConversion, SubcOpConversion, UnboxCharOpConversion,
*f1dfc027SDiana Picus        UndefOpConversion, UnreachableOpConversion, ZeroOpConversion>(
*f1dfc027SDiana Picus        typeConverter);
*f1dfc027SDiana Picus
044d5b5dSValentin Clement    mlir::populateStdToLLVMConversionPatterns(typeConverter, pattern);
044d5b5dSValentin Clement    mlir::arith::populateArithmeticToLLVMConversionPatterns(typeConverter,
044d5b5dSValentin Clement                                                            pattern);
044d5b5dSValentin Clement    mlir::ConversionTarget target{*context};
044d5b5dSValentin Clement    target.addLegalDialect<mlir::LLVM::LLVMDialect>();
044d5b5dSValentin Clement
044d5b5dSValentin Clement    // required NOPs for applying a full conversion
044d5b5dSValentin Clement    target.addLegalOp<mlir::ModuleOp>();
044d5b5dSValentin Clement
044d5b5dSValentin Clement    // apply the patterns
044d5b5dSValentin Clement    if (mlir::failed(mlir::applyFullConversion(getModule(), target,
044d5b5dSValentin Clement                                               std::move(pattern)))) {
044d5b5dSValentin Clement      signalPassFailure();
044d5b5dSValentin Clement    }
044d5b5dSValentin Clement  }
044d5b5dSValentin Clement};
044d5b5dSValentin Clement} // namespace
044d5b5dSValentin Clement
044d5b5dSValentin Clementstd::unique_ptr<mlir::Pass> fir::createFIRToLLVMPass() {
044d5b5dSValentin Clement  return std::make_unique<FIRToLLVMLowering>();
044d5b5dSValentin Clement}